Title of Invention

"A PEPTIDE THAT IS A MATURATION PRODUCT OF THE BASIC PROLIN-RICH LACRIMAL PROTEIN (BPLP)OR A PEPTIDE DERIVATIVES THEREOF"

Abstract The invention relates to a peptide that is a maturation product of the Basic Prolin-rich Lacrinal Protein (BPLP) or a peptide derivative or a mimetic of said maturation product, wherein the peptide or peptide derivative or mimetic exhibits an inhibitory property against a metallo-ectopeptidase, especially NEP and/or APN. The present invention also relates to polynucleotides coding for said peptides and to antibodies directed against said peptides. Furthermore, the present invention relates to diagnostic and therapeutic uses of human BPLP protein and inhibitory peptides derived therefrom, polypeptides coding for human BPLP protein or peptides derived therefrom as well as antibodies directed against BPLP protein or peptides derived therefrom.
Full Text Peptides derived from human BPLP protein, polvnucleotides coding for said
peptides and antibodies directed against said peptides
The present invention relates to peptides derived from human BPLP
protein, as new inhibitors of metallo-ectopeptidases. The present invention also
relates to polynucleotides coding for said peptides and to antibodies directed
against said peptides. Furthermore, the present invention relates to diagnostic
and therapeutic uses of human BPLP protein, peptides derived therefrom and
mimetics there of, polypeptides coding for human BPLP protein or peptides
derived therefrom as well as antibodies directed against BPLP protein or peptides
derived therefrom.
In a genomic' approach, an androgen-regulated gene, which is
predominantly expressed in the submandibular gland (SMG) and prostate of adult
rats, has been identified (Rosinski-Chupin et al., 1988 and European patent
0 394 424). The gene encodes a precursor protein, submandibular rat1 protein
(SMR1) giving rise to three structurally related peptides which are selectively
matured from the precursor in vivo by cleavage at multibasic sites by a paired
basic amino acid-converting enzyme (Rougeot et al., 1994).
In an approach of post-genomic and physiomic, it was established the
molecular and functional bases providing evidence for the existence in mammals
of a hormonal messenger of the intercellular communication, i.e., the final mature
peptide generated from SMR1 pre-prohormone: SMR1-Pentapeptide, named
today Sialorphin (of sequence QHNPR). Hence, sialorphin is an exocrine and
endocrine peptide-signal, whose expression is under activational androgenic
regulation and secretion is evoked under adrenergic-mediated response to
environmental stress, in male rat (Rougeot et al., 1997).
The fact that, in sexually mature male rat, the androgen-regulated
sialorphin is acutely secreted in response to environmental acute stress, led to
postulate that this signaling mediator might play a role in some physiological and
behavioral integration linked to the reproduction. Thus the same authors
investigated the effects induced by sialorphin on the male sexual behavior
pattern, which included frequency and latency of mounts, intromissions and
CONFIRMATION COPY
ejaculations, as well as socio-sexual interactions. The data obtained showed that
sialorphin has the ability to modulate, at doses related to physiological circulating
levels, the male rat mating pattern, i.e., exerting, in a dose-dependent manner, a
dual facilitative/inhibitory effect on the sexual performance, while stimulating at all
doses the apparent sexual arousal or motivation. Thus it is proposed that the:
endogenous androgen-regulated sialorphin helps modulate the adaptative
balance between excitatory and inhibitory mechanisms serving appropriate male
rat sexual response, depending on the context.
International patent application WO 01/00221 describes the use 01
maturation products of SMR1 for the treatment of impaired interpersonal and
behavioural disorders, including sexual defects.
Furthermore, these authors discovered that SMR1 maturation product:
recognize specific target sites in organs that are deeply involved in the miner?.?!
ion concentration. International patent application WO 98/37100 describes the
therapeutic use of maturation products of SMR1 for preventing or treatinp
diseases associated with a mineral ion imbalance in a human or an animal body
in response to stressful contexts, sialorphin is acutely released, rapidly
distributed and lasting taken up by its systemic membrane-associated targets
(Rougeot et al., 1997). The authors have demonstrated that the major cell surface
molecule to which sialorphin binds in vivo is the membrane-anchored
metalloecto-endopepttdase, NEP (Neutral Endopeptidase; Neprilysin EC
3.4.24.11), or enkephalinase (Rougeot et al., 2003). Moreover, sialorphin was
shown to be a physiological antagonist of the NEP activity ex vivo; and the direcl
interaction of NEP and sialorphin assessed in an in vitro assay using soluble
purified renal NEP and artificial fluorogenic DGNPA (Dansyl-Gly-(pNO2)Phe-
BAIa) as substrate provided direct evidence that siaiorphin inhibited NEP activity
(1C 50 of the sialorphin: 0.6 uM). Sialorphin, is the first physiological inhibitor of
the NEP-enkephalinase activity identified to date in rodent (Rougeot et al., 2003
and European patent application EP 1 216 707).
NEP is located at the surface of cells in nervous and systemic tissues,
where it plays an important function as an ectoenzyme catalyzing the postsecretory
processing or metabolism of a number of neuropeptides and regulatory
peptides. The main physiologically relevant substrates for NEP are the
enkephaiins, substance P and atrial natriuretic peptide (ANP). These mammalian
signal peptides are involved in the control of central and peripheral pain
perception, inflammatory phenomena, arterial tone and mineral homeostasis.
Their physiological importance and the critical role of NEP ectoenzyme in
modulating their functional potency make it important to investigate and know
their possible protection by endogenous inhibitors, from a physiological as well as
a physiopathological and therapeutic point of view.
By using different models of molecular and behavioral pharmacology, the
authors have shown that the physiological mediator, sialorphin, prevents spinal
and renal NEP from breaking down its two physiologically relevant substrates,
Substance P and Met-enkephalin in vitro. Sialorphin inhibited the breakdown of
substance P with an IC50 of 0.4-1 uM and behaved as a competitive inhibitor of
the membrane-bound NEP that originates from nervous tissues (spinal cord) or
from systemically tissues (kidney, bone, tooth, placenta, prostate, GSM,
intestine). In vivo, intravenous sialorphin elicited potent antinociceptive responses
in two behavioral rat models of injury-induced acute and tonic pain, the pin-pain
test (mechanical algesia) and formalin test (chemical algesia). The analgesia
induced by sialorphin required the activation of u- and 8-opioid receptors,
consistent with the involvement of endogenous opioid receptors in
enkephalinergic transmission. Indeed, these receptors are involved in the
transmission of the endogenous opioidergic signals such as the enkephaiins
which are inactivated by NEP and the aminopeptidase APN, and also of the
exogenous opiate, the morphine which interacts mainly with the u-opioid
receptor. It was concluded that the sialorphin protects endogenous enkephaiins
released following nociceptive stimuli by inhibiting ecto-enkephalinases, in vivo,
and thus potentialises their analgesic effect. Otherwise, the endogenous opioid
system, in particular 5-opioid-mediated pathway, has also been linked to the
etiology of depressive behavior; for instance using a model of analysis of
behavioral despair (forced swim test), the authors showed that sialorphin displays
a significative antidepressant activity in male rat. Sialorphin is the first natural
systemically active regulator of NEP activity identified to date in mammals.
Furthermore, evidence was provided that it is a new physiological modulator of
pain perception following injury, and may be the progenitor of a new class of
therapeutic molecules, as putative novel antinociceptive and antidepressive
agents (Rougeot et al., 2003 ; EP 1,343,519 and EP 1,343,520).
The powerful analgesic effect of sialorphin is associated to its capacity
to entirely protect the enkephalins from inactivation by the enkephalin-degrading
ectoenzymes. in vivo, the enkephalins are inactivated with an extraordinarily
efficiency (within few seconds) by the both ectopeptidases, NEP and APN. In
agreement, the first developed synthetic inhibitors, which are either only NEP
specific (such as Thiorphan) or APN specific (such as Bestatin) exhibit a non
significant or weak antinociceptive effect. Thus, rat sialorphin is a physiological
dual inhibitor of NEP and APN metallo-ectopeptidases; furthermore, thic
endocrine signal messenger of the adaptative response to stress is a powerful
inhibitor of painful perception in rat and its analgesic effect is more potent than
that of synthetic dual NEP/APN inhibitors such as kelatorphan, which have been
developed elsewhere by modeling methods. So, sialorphin is remarkably adapter!
in terms of specificity and bioavailability to the conformationa! and distributive,
characteristics of its targets and as a consequence is more effective from an
integrative point of view. Considering these observations, from a functional a?;
well as physiopathological and therapeutic point of view, the biologicaimportance
of the functions regulated by the rat sialorphin makes it crucial to
investigate and identify the endogenous functional homologous of rat sialorphin n
human.
Sialorphin is the only identified physiological systemically active regulate)i
of the membrane-bound enkephalinase activity in mammals. This raises the.
question of the existence of such endogenous NEP-ectopeptidase inhibitor in
human saliva and blood. No immunoreactive QHNPR peptide (sialorphin) war,
detected in male human saliva using highly sensitive and specific
radioirnmunoassay (Rougeot et al., 1994). However, bibliographical data let
suppose the presence of low molecular weight substances ( the NEP ectopeptidase activity in human, notably in the human saliva. Although
this(ese) salivary component(s) was(were) not biochemically characterized, a
gender-related difference was observed in the salivary production of this(ese)
inhibitor(s) of human enkephalin-degrading ectoenzymes (Marini and Roda,
2000). Strikingly, the situation is very similar to that one identified by the inventors
in male rat, wherein the submandibular gland and the saliva represented the
compartments of major synthesis and secretion of sialorphin, respectively.
The gene encoding the SMR1 precursor of sialorphin belongs to a
multigene family whose members have been identified in human. However, the
stricto sensu homologous human gene of rat SMR1 gene (VCSA1 coding for
SMR1) was not found in human (cDNA cloning and human genome analysis).
Furthermore, the inhibitory potency of rat sialorphin against membrane-anchored
human NEP, which is expressed by human prostate cell lines (LNCaP), exists but
is about 10-fold lower than that obtained against rodent NEP (rat, rabbit). This
apparent selectivity in the functional interaction between rat sialorphin and NEP
ectoenzyme is at least surprising considering the fact that the rat and human NEP
have relatively high amino-acid sequence analogy (about 85 %). Otherwise, the
characterization of the human genes of the multigenic family to which belongs the
gene coding for the precursor of the rat sialorphin (SMR1), revealed that it exists
in human, several genes of this family, among which three were characterized,
i.e., the genes hPB, hPBI and BPLP which are clustered in the same
chromosome region, q13-21 of Chromosome 4 (Isemura, 2000) (Isemura and
Saitoh, 1997) (Dickinson and Thiesse, 1996).
The inventors have now identified a new peptide that is considered as the
functional human homologous of the SMR1-pentapeptide sialorphin.
The numerous data collected by the inventors support that the new
peptide, of sequence QRFSR, derives from the BPLP protein ("Basic Prolin-rich
Lacrimal Protein").
The human gene BPLP codes for a polypeptide sequence of 201 aminoacids
(with the potential signal peptide of secretion) predicted from the cDNA
cloned and characterized by Dickinson and al. (Dickinson and Thiesse, 1996).
The gene BPLP is expressed in human lacrimal and submandibular glands. In the
annexed sequence listing, SEQ ID No. 1 shows the cDNA sequence coding for
BPLP, and SEQ ID No. 2 shows the BPLP aminoacid sequence.
The inventors defined consensus sites in the best conserved N-terminal
region (between the rat, mouse and human) of the secreted BPLP protein, on the
basis of the maturation processing of rat sialorphin from the SMR1 precursor.
For instance, these consensus sites were defined as signal peptide
cleavage sites in a region having the sequence required for the signal peptidase
and at paired basic residues with R-R bonds recognized as processing signal for
paired basic amino acid-convertase.
At such consensus sites, the inventors then found out a sequence
QRFSR, structurally closely related to that of rat QHNPR sialorphin.
This peptide was synthesized and analyzed for its capacity to inhibit the
degradation of the physiological NEP substrate, i.e. substance P.
This peptide was then identified as the human functional homologous of
sialorphin.
The present invention is drawn to peptides derived from human BPLP
protein, as new inhibitors of metallo-ectopeptidases.
More particularly, the present invention is drawn to maturation products of
the BPLP protein, in particular the QRFSR peptide, as well as peptide derivatives
and mimetics thereof, useful to potentialise the effects of neuroendocrine peptide
messengers which control the nociceptive transmission (e.g. enkephalins), the
well-being and/or the homeostatic exchanges of Na/Pi/Ca/hbO mainly (e.g.
natriuretic peptides).
The present invention is also drawn to polynucleotides coding for said
peptides and peptide derivatives as well as to antibodies directed against said
peptides and peptide derivatives thereof.
Furthermore, the present invention is drawn to diagnostic and therapeutic
uses of human BPLP protein, human BPLP protein-derived peptides, and
peptides derivatives and mimetics thereof, as well as diagnostic and therapeutic
uses of polynucleotides coding for human BPLP protein, human BPLP proteinderived
peptides and peptides derivatives thereof and of antibodies directed
against human BPLP protein, human BPLP protein-derived peptides and peptide
derivative thereof.
It should be understood that the peptides, proteins, or nucleic acids of the
invention are in isolated or purified form.
By « purified » and « isolated » it is meant, when referring to a protein or
peptide (including antibodies) or a nucleotide sequence, that the indicated
molecule is present in the substantial absence of other biological molecules. The
term "purified" as used herein preferably means at least 75 % by weight, more
preferably at least 85 % by weight, more preferably still at least 95 % by weight,
and most preferably at least 98 % by weight, of biological molecules of the same
type are present. An "isolated" or "purified" nucleic acid molecule which encodes
a particular polypeptide refers to a nucleic acid molecule which is substantially
free of other nucleic acid molecules that do not encode the subject polypeptide.
However, the molecule may include some additional bases or moieties which do
not deleteriously affect the basic characteristics of the composition.
Peptides
For purposes of the invention, a "peptide" is a molecule comprised of a
linear array of amino acid residues connected to each other in the linear array by
peptide bonds. Such linear array may optionally be cyclic, i.e., the ends of the
linear peptide or the side chains of amino acids within the peptide may be joined,
e.g., by a chemical bond. Such peptides according to the invention may include
from about three to about 500 amino acids, preferably from about 3 to about 100
amino acids, and most preferably from about 3 to about 50 amino acids and
especially from about 3 to 15 amino acids and may further include secondary,
tertiary or quaternary structures, as well as intermolecular associations with other
peptides or other non-peptide molecules. Such intermolecular associations may
be through, without limitation, covalent bonding (e.g., through disulfide linkages),
or through chelation, electrostatic interactions, hydrophobic interactions,
hydrogen bonding, ion-dipole interactions, dipole-dipole interactions, or any
combination of the above.
In these peptides, by N-terminal cyclization/decyclization, Glp and Gin
interconvert.
A subject of the present invention is a peptide which is derived from human
BPLP protein and which has a modulatory, especially an inhibitory activity on
metallo-ectopeptidases.
"Derived from human BPLP protein" means which comprises, consists
essentially of, or consists of a BPLP protein fragment. In a preferred embodiment,
said peptide consists of 3 to about 150 amino acids. Most preferably, said peptide
consists of less than 100 amino acids.
Particularly a subject of the present invention is a maturation product of the
BPLP protein as well as peptide derivatives there of.
More particularly, it is drawn to a peptide that is a maturation product of the
Basic Prolin-rich Lacrinal Protein (BPLP) or peptide derivative of said maturation
product, wherein the peptide or peptide derivatives exhibits an inhibitory property
against a metallo-ectopeptidase, especially NEP and/or APN, and more
particularly NEP.
A "maturation product" is a peptide that is obtained through clivage of the
BPLP protein precursor by natural maturases or prohormone converting
enzymes, or related mono or paired basic amino acid-cleaving enzymes such as
furin, PC convertases or PACE 4 (Seidah, 1995), for example.
The peptides of the invention include "peptide derivatives".
The "peptides derivatives" are peptides having amino acid substitutions
from a parent peptide, preferably from one to two amino acid substitutions from a
parent peptide particularly when said parent peptide comprises less than 15
amino acids and preferably less than 10 amino acids, but retaining the binding
specificity and/or physiological activity of the parent peptide. As used herein,
"retaining the binding specificity of the parent peptide" means being able to bind
to a monoclonal or polyclonal antibody that binds to one of the BPLP maturation
products or to the BPLP maturation product receptor with an affinity that is at
least one-tenth, more preferably at least one-half, and most preferably at least as
great as that of one of the peptides that are maturation products of BPLP.
Determination of such affinity is preferably conducted under standard competitive
binding immunoassay conditions. "Retaining the physiological activity of the
parent peptide" means retaining the ability of any one of the BPLP maturation
peptides to bind and to modulate the activity of a metallo-ectopeptidase,
especially NEP and/or APN, and more particularly NEP, and so to optimize the
local and systemic nociceptive, inflammatory, anti-depressant, and/or ion
homeostatic responses to stress. Determining whether such activity is modulated
is further described later in this specification.
The peptides of the invention include peptides or peptide derivatives which
comprise, consist essentially of or consist of sequence X1-X2-Arg-Phe-Ser-Arg,
wherein X1 represents H atom or a Tyr aminoacid, X2 represents Gln or Glp
when X1 is H, or X2 represents Gln when X1 is Tyr or Cys. When the peptide of
the invention comprises or consists essentially of sequence X1-X2-Arg-Phe-Ser-
Arg, said sequence is the C-terminal part of the peptide of the invention.
Preferred peptides according to the invention comprise, consist essentially
of, or consist of sequence QRFSR.
More particularly a peptide of the invention is the peptide that consists of
sequence QRFSR (SEQ ID No. 3).
Another peptide of the invention is the peptide that consists of sequence
YQRFSR (SEQ ID No. 4).
Still another peptide of the invention is the peptide that consists of
sequence CQRFSR.
Throughout the text,
Glp is pyroglutamate,
Tyr or Y is Tyrosine,
Gin or Q is glutamine,
Arg or R is Arginine,
Phe or F is Phenylalanine,
Ser or S is Serine,
Cys or C for Cystine.
The peptides according to the present invention may be prepared in a
conventional manner by peptide synthesis in liquid or solid phase by successive
couplings of the different amino acid residues to be incorporated (from the Nterminal
end to the C-terminal end in liquid phase, or from the C-terminal end to
the N-terminal end in solid phase) wherein the N-terminal ends and the reactive
side chains are previously blocked by conventional groups.
For solid phase synthesis the technique described by Merrifield may be
used in particular. Alternatively, the technique described by Houbenweyl in 1974
may also be used.
For more details, reference may be made to WO 98/37100.
The peptides according to the present invention may also be obtained
using genetic engineering methods.
Preferred mimetics, including peptidomimetics, retain the binding
specificity and/or physiological activity of the parent peptide including peptide
derivative, as described above. As used herein, a "mimetic" is a molecule that
mimics some properties of the natural peptides, preferably their binding specificity
and physiological activity. Preferred mimetics are obtained by structural
modification of peptides according to the invention, preferably using unnatural
amino acids, D aminoacid instead of L aminoacid, conformational restraints,
isosteric replacement, cyclization, or other modifications. Other preferred
modifications include without limitation, those in which one or more amide bond is
replaced by a non-amide bond, and/or one or more amino acid side chain is
replaced by a different chemical moiety, or one or more of the N-terminus, the Cterminus
or one or more side chain is protected by a protecting group, and/or
double bonds and/or cyclization and/or stereospecificity is introduced into the
amino acid chain to increase rigidity and/or binding affinity.
Based on the crystal structure of the binding domain of the metalloectopeptidase
targeted by the peptide of the invention, mimetics can also be
obtained by means of computer-assisted drug design development (Oefner et al.
(2000); Gomeni et al. (2001); Jones et al. (2002); Kan (2002)).
Still other preferred modifications include those intented to enhance
resistance to enzymatic degradation, improvement in the bioavailability in
particular by nervous and gonad tissues and more generally in the
pharmacokinetic properties and especially comprise :
- protecting the NH2 and COOH hydrophilic groups by esterification
(COOH) with lipophilic alcohols or by amidation (COOH) and/or by acetylation
(NHs) or added carboxyalkyl or aromatic hydrophobic chain at the NH2 terminus ;
- retrain version isomers of the CO-NH amide bonds or methylation
(or ketomethylene, methyleneoxy, hydroxyethylene) of the amide functions ;
- substitution of L aminoacids for D aminoacids.
All of these variations are well known in the art. Thus, given the peptide
sequences disclosed herein, those skilled in the art are enabled to design and
produce mimetics having binding characteristics and/or physiological activities
similar to or superior to such peptides (see e.g., Horwell et al., (1996 ); Liskamp
et al., (1994); Gante et al., (1994); Seebach et al., (1996)).
As used herein, the term "BPLP-peptide" refers to BPLP protein, peptides
derived from BPLP, BPLP maturation peptides, and peptides derivatives and
mimetics, including peptidomimetics, of the invention.
The invention also relates to a molecular complex comprising :
- a metallo-ectopeptidase receptor, especially a NEP receptor or an APN
receptor, especially a NEP receptor, binding site of the BPLP-protein or
maturation products thereof, e.g. QRFSR ;
- the BPLP-protein or maturation products thereof, e.g. QRFSR.
Nucleic acids, methods of expression and methods of detection
The nucleic acids, also named polynucleotides, such as DNA or RNA
molecules, that encode the peptides, including peptides derivatives, defined
above are also part of the invention, while taking into account the degeneration of
the genetic code.
Accordingly, the present invention provides nucleic acids coding for
peptides derived from human BPLP protein, and peptides derivatives thereof.
Particularly, the present invention provides nucleic acids coding for
peptides which comprise, consist essentially of, or consist of sequence X1-X2-
Arg-Phe-Ser-Arg as above defined. When the peptide of the invention comprises
or consists essentially of sequence X1-X2-Arg-Phe-Ser-Arg, said sequence is the
C-terminal part of the peptide of the invention. In preferred embodiments, the
present invention provides acid nucleic coding for peptides which comprise,
consist essentially of, or consist of sequence QRFSR. In a most preferred
embodiment, the present invention provides a nucleic acid coding for QRFSR or
a nucleic acid coding for YQRFSR.
The nucleic acids of the invention include sequences that are hybridizable
to any of the above sequences or their complementary sequences under
standard hybridization conditions, preferably conditions of high stringency.
A nucleic acid molecule is "hybridizable" to another nucleic acid molecule,
when a single stranded form of the nucleic acid molecule can anneal to the other
nucleic acid molecule under the appropriate conditions of temperature and
solution ionic strength (see Sambrook et al., 1989). The conditions of temperature
and ionic strength determine the "stringency" of the hybridization. For preliminary
screening for homologous nucleic acids, low stringency hybridization conditions,
corresponding to a Tm (melting temperature) of 55°C, can be used, e.g., 5x SSC,
0.1 % SDS, 0.25 % milk, and no formamide ; or 30 % formamide, 5x SSC, 0.5 %
SDS). Moderate stringency hybridization conditions correspond to a higher Tm,
e.g., 40 % formamide, with 5x or 6x SCC. High stringency hybridization
conditions correspond to the highest Tm, e.g., 50 % formamide, 5x or 6x SCC.
SCC is a 0.15 M NaCI, 0.015 M Na-citrate. Hybridization requires that the two
nucleic acids contain complementary sequences, although depending on the
stringency of the hybridization, mismatches between bases are possible. The
appropriate stringency for hybridizing nucleic acids depends on the length of the
nucleic acids and the degree of complementation, variables well known in the art.
The greater the degree of similarity or homology between two nucleotide
sequences, the greater the value of Tm for hybrids of nucleic acids having those
sequences. The relative stability (corresponding to higher Tm) of nucleic acid
hybridizations decreases in the following order: RNA:RNA, DNA:RNA, DNA:DNA.
For hybrids of greater than 100 nucleotides in length, equations for calculating
Tm have been derived (see Sambrook et al., supra, 9.50-9.51). For hybridization
with shorter nucleic acids, i.e., oligonucleotides, the position of mismatches
becomes more important, and the length of the oligonucleotide determines its
specificity (see Sambrook et al., supra, 11.7-11.8). A minimum length for a
hybridizable nucleic acid is at least about 10 nucleotides ; preferably at least
about 15 nucleotides.
In a specific embodiment, the term "standard hybridization conditions"
refers to a Tm of 55°C, and utilizes conditions as set forth above. In a preferred
embodiment, the Tm is 60°C. In a more preferred embodiment, the Tm is 65°C.
In a specific embodiment, "high stringency" refers to hybridization and/or washing
conditions at 68°C in 0.2 X SSC, at 42°C in 50 % formamide, 4 X SSC, or under
conditions that afford levels of hybridization equivalent to those observed under
either of these two conditions.
The present invention further relates to vectors for cloning and/or
expression comprising a nucleic acid sequence of the invention and to host cell
comprising the nucleic acid of the invention or said vector, i.e. a host cell wherein
at least one of these vectors was transferred. The expression vector according to
the invention comprises a nucleic acid sequence encoding a peptide, including a
peptide derivative, or protein of the invention, said nucleic acid sequence being
operably linked to elements allowing its expression. Said vector advantageously
contains a promoter sequence, signals for initiation and termination of translation,
as well as appropriate regions for regulation of translation. Its insertion into the
host cell may be transient or stable. Said vector may also contain specific signals
for secretion of the translated protein.
These various control signals are selected according to the host cell and
may be inserted into vectors which self-replicate in the selected host cell, or into
vectors which integrate the genome of said host.
Host cells may be prokaryotic or eukaryotic, including but not limited to
bacteria, yeasts, plant cells, insect cells, mammalian cells, including cell lines
which are commercially available. Preferred examples for host cells are COS-1,
HEK cells, 293 cells, or CHO cells.
A subject of the present invention is also a method for producing a
recombinant BPLP-peptide, wherein said host cell is transfected with said
expression vector and is cultured under conditions allowing the expression of a
BPLP-peptide. The transfection of the host cell may be performed using any
standard technique, such as electroporation or phosphate calcium precipitation or
lipofectine®.
The protein or peptide can then be collected and purified, by means of
well-known procedures for purification : the recombinant peptide or protein may
be purified from lysates or cell extracts, from the supernatant of the culture
medium, by methods such as HPLC chromatography, immunoaffinity techniques
with specific antibodies, and the like.
The present invention further relates to methods of in vitro prognosis
and/or diagnosis wherein the nucleic acid sequences of the invention or probes or
primers derived thereof are used to detect aberrant synthesis, including abnormal
high or low synthesis, or genetic abnormalities at the BPLP gene level.
The invention thus provides an in vitro method for prognosis and/or
diagnosis of a condition involving an altered production of BPLP or of any of its
maturation products, which method comprises detecting in a biological sample of
a test subject, an abnormality in terms of quality and/or quantity in the BPLP gene
or in its transcript.
The term "prognosis" refers to the determination or confirmation of a
likelihood of a disease or condition to arise.
The present invention is more particularly directed to a method for
detecting an abnormality in the BPLP gene comprising the steps of:
- contacting a biological sample containing DMA with specific
oligonucleotides permitting the amplification of all or part of the BPLP gene, the
DMA contained in the sample having being rendered accessible, where
appropriate, to hybridization, and under conditions permitting a hybridization of
the primers with the DMA contained in the biological sample ;
- amplifying said DMA ;
- detecting the amplification products ;
- comparing the amplified products as obtained to the amplified products
obtained with a normal control biological sample, and thereby detecting a
possible abnormality in the BPLP gene.
The method of the invention can also be applied to the detection of an
abnormality in the transcript of the BPLP gene, by amplifying the mRNAs
contained in a biological sample, for example by RT-PCR.
Thus another subject of the present invention is a method for detecting an
abnormality in the BPLP transcript, as previously defined comprising the steps of:
- producing cDNA from mRNA contained in a biological sample ;
- contacting said cDNA with specific oligonucleotides permitting the
amplification of all or part of the transcript of the BPLP gene, under conditions
permitting a hybridization of the primers with said cDNA ;
- amplifying said cDNA ;
- detecting the amplification products ;
- comparing the amplified products as obtained to the amplified products
obtained with a normal control biological sample, and thereby detecting a
possible abnormality in the transcript of the BPLP gene.
This comparison of the amplified products obtained from the biological
sample with the amplified products obtained with a normal biological sample is a
quantitative comparison and/or a qualitative comparison. In this latter case,
comparison can be carried out for example by specific probe hybridization, by
sequencing or by restriction site analysis.
One skilled in the art very well knows the standard methods for analysing
the DMA contained in a biological sample and for diagnosing a genetic disorder.
Many strategies for genotypic analysis are available.
Preferably, one can use the DGGE method (Denaturing Gradient Gel
Electrophoresis), or the SSCP method (Single Strand Conformation
Polymorphism) for detecting an abnormality in the BPLP gene. Such methods are
preferably followed by direct sequencing. The RT-PCR method may be
advantageously used for detecting abnormalities in the BPLP transcript, as it
allows to visualize the consequences of a splicing mutation such as exon
skipping or aberrant splicing due to the activation of a cryptic site. This method is
preferably followed by direct sequencing as well. The more recently developed
technique using DMA chip can also be advantageously implemented for detecting
an abnormality in the BPLP gene.
These methods for detecting an abnormality in the BPLP gene, or in its
transcript, are particularly useful to identify mutations that result in nonfunctional
BPLP protein or maturation products, and are advantageous for in vitro prognosis
and/or diagnosis of diseases, wherein the BPLP gene is involved.
Examples of such diseases are diseases cited in the "therapeutic
application" section.
Antibodies and methods of detection
The present invention further provides antibodies, specifically directed
against (i.e. that specifically recognizes) the BPLP protein. The present invention
further provides antibodies, specifically directed against (i.e. that specifically
recognizes) the peptides as above defined, including peptides derivatives.
Accordingly, the present invention provides antibodies directed against
peptides derived from human BPLP protein, and peptide derivatives thereof.
More particularly, the present invention provides antibodies directed
against peptides which comprise, consist essentially of, or consist of sequence
X1-X2-Arg-Phe-Ser-Arg as above defined. When the peptide of the invention
comprises or consists essentially of sequence X1-X2-Arg-Phe-Ser-Arg, said
sequence is the C-terminal part of the peptide of the invention. In preferred
embodiments, the present invention provides antibodies directed against (i.e. that
specifically recognize) peptides which comprise, consist essentially of, or consist
of sequence QRFSR. In a most preferred embodiment, the present invention
provides antibodies directed against (i.e. that specifically recognize) QRFSR or
antibodies directed against (i.e. that specifically recognize) YQRFSR or
antibodies directed against (i.e. that specifically recognize) CQRFSR.
The term "antibody" in its various grammatical forms is used herein to refer
to immunoglobulin molecules and immunologically active portions of
immunoglobulin molecules, i.e., molecules that contain an antibody combining
site or paratope. Exemplary antibody molecules are intact immunoglobulin
molecules, substantially intact immunoglobulin molecules and portions of an
immunoglobulin molecule, including those portions known in the art as Fab, Fab1,
F(ab')2 and F(v).
Antibodies that inhibit the interaction of a BPLP maturation product or a
peptide derivative thereof with its receptor are more particularly useful.
Whereas polyclonal antibodies may be used, monoclonal antibodies are
preferred for they are more reproducible in the long run.
Procedures for raising polyclonal antibodies are also well known. Typically,
such antibodies can be raised by administering the protein or peptide, including
conjugate peptide, of the present invention subcutaneously to New Zealand white
rabbits which have first been bled to obtain pre-immune serum. The antigens can
be injected at a total volume of 50 ul per site at ten different sites or at least five
different sites. The rabbits are then bled five weeks after the first injection and
periodically boosted with the same antigen administered subcutaneously at five
fold lower concentration than the primary injection at maximum depending on
quality of the immune response three times every six weeks. A sample of serum
is then collected every 10 days after each boost. Polyclonal antibodies are then
recovered from the serum by affinity chromatography using the corresponding
antigen to capture the antibody. This and other procedures for raising polyclonal
antibodies are disclosed in E. Harlow, et. al., editors, Antibodies: A Laboratory
Manual, Cold Spring Harbor Laboratory, New York (1988).
A "monoclonal antibody" in its various grammatical forms refers to a
population of antibody molecules that contain only one species of antibody
combining site capable of immunoreacting with a particular epitope. A monoclonal
antibody thus typically displays a single binding affinity for any epitope with which
it immunoreacts. A monoclonal antibody may therefore contain an antibody
molecule having a plurality of antibody combining sites, each immunospecific for
a different epitope, e.g. a bispecific monoclonal antibody.
Laboratory methods for preparing monoclonal antibodies are well known in
the art (see, for example, Harlow et al., supra). Monoclonal antibodies (Mabs)
may be prepared by immunizing a mammal, e.g. a mouse, rat, rabbit, goat,
human and the like, against the purified BPLP protein, BPLP maturation products
or peptide derivatives thereof, including conjugated BPLP-peptides. The
antibody-producing cells in the immunized mammal are isolated and fused with
myeloma or heteromyeloma cells to produce hybrid cells (hybridoma). The
hybridoma cells producing the monoclonal antibodies are used as a source of the
desired monoclonal antibody.
While Mabs can be produced by hybridoma culture, the invention is not to
be so limited. Also contemplated is the use of Mabs produced by an expressing
nucleic acid cloned from a hybridoma. That is, the nucleic acid expressing the
molecules secreted by a hybridoma can be transferred into another cell line to
produce a transformant. The transformant is genotypically distinct from the
original hybridoma but is also capable of producing antibody molecules of this
invention, including immunologically active fragments of whole antibody
molecules, corresponding to those secreted by the hybridoma. In addition, the
literature provides methods for forming chimeric antibodies, humanized
antibodies, single chain antibodies and the like variations on a basic
immunoreactive antibody fragment. All of these are considered within the scope
of the invention insofar as a class and specificity of antibody is disclosed and
claimed, regardless of the precise variant structure that one skilled in the art may
construct.
The present invention further relates to an in vitro method for diagnosis,
prognosis or determination of the evolution of a condition involving an altered
production (i.e. a decrease or an increase of production in comparison to a
control subject) of BPLP or of any of its maturation products. The method
comprises detecting, or quantifying in a biological sample of a test subject, a
BPLP protein or maturation products thereof, especially QRFSR, compared with
the same in a biological sample of a control subject.
Examples of such conditions are diseases cited in the "therapeutic
applications" section.
A "biological sample" is a fluid from a subject, including serum, blood,
spinal fluid, cerebrospinal fluid, urine, milk, saliva or a tissue extract or a tissue or
organ biopsy such as brain, spinal cord, bone tissue, kidney, prostate, placenta,
dental tissue, glandular mucosa of stomach, intestine, salivary gland tissue,
mammary glands, for example.
"A subject" or "a patient" is a vertebrate, e.g. a mammal, preferably a
human being, regardless of his/her age, sex and general condition. Children and
infants are also encompassed. The test subject may be asymptomatic, may be
considered likely to develop the disease or condition. Subjects with a suspicion of
a target disorder or subjects who have already shown symptoms of the disease
or condition can also be tested.
The "control subject" may be a healthy subject or a subject without any
apparent disorder that can involve the BPLP protein or one of its maturation
products. In order to determine the evolution of a condition involving the BPLP
protein or one of its maturation products, it may be very useful to test a subject for
the expression of BPLP protein or a maturation products thereof, and to monitor
the effect of a drug or the spreading of the condition, by testing him/her a second
time, e.g. a few weeks later. In that case the results of the second test are
compared with the results of the first test, and in general also with the results
obtained with a "healthy" subject. The "control subject" then refers either to the
same test subject or to a "healthy subject".
The term "diagnosis" refers to the determination or the confirmation of a
disease or condition in a subject.
The term "prognosis" refers to the determination or confirmation of a
likelihood of a disease or condition to arise.
The "expression or production of a BPLP protein or a maturation product
thereof" may be determined by assaying the BPLP protein or a maturation
products thereof.
Such assay methods comprise contacting a biological sample with a
binding partner capable of selectively interacting with a BPLP protein or
maturation products thereof, especially QRFSR, present in the sample. The
binding partner is generally an antibody, that may be polyclonal or monoclonal,
preferably monoclonal.
Methods for producing antibodies as described above in accordance with
therapy can also be easily adapted to produce antibodies useful for the diagnostic
or prognostic methods according to the invention.
For example, the presence or production of BPLP protein or of any of its
maturation products, or a mutated form of the protein or of the maturation
product, can be detected by incubating a biological sample with an antibody that
specifically recognizes the BPLP protein or an antibody that specifically
recognizes a maturation product thereof, especially QRFSR, e.g. using standard
electrophoretic and liquid or solid immunodiagnostic techniques, including
immunoassays such as competition, direct reaction, or sandwich type assays.
Such assays include, but are not limited to, Western blots; agglutination tests;
enzyme-labeled and mediated immunoassays, such as ELISAs; biotin/avidin type
assays; radioimmunoassay such as those using radioiodinated or tritiated BPLP
protein or any of its maturation products, especially QRFSR ;
immunoelectrophoresis; immunoprecipitation, etc. The reactions generally include
revealing labels such as fluorescent, chemiluminescent, radioactive, enzymatic
labels or dye molecules, or other methods for detecting the formation of a
complex between the antigen and the antibody or antibodies reacted therewith.
The aforementioned assays generally involve separation of unbound BPLP
protein or unbound maturation products thereof, especially unbound QRFSR,
from the bound BPLP protein or maturation products, especially QHNPR, to the
specific antibody which is immobilized on a solid phase. Solid supports which can
be used in the practice of the invention include supports such as nitrocellulose
(e.g., in membrane or microtiter well form); polyvinylchloride (e.g., sheets or
microtiter wells); polystyrene latex (e.g., beads or microtiter plates); polyvinylidine
fluoride; diazotized paper; nylon membranes; activated beads, magnetically
responsive beads, and the like.
Thus, in one particular embodiment, the presence of bound BPLP protein
or maturation products thereof, especially QRFSR, from a biological sample can
be readily detected using a secondary binder comprising another antibody, that
can be readily conjugated to a detectable enzyme label, such as horseradish
peroxidase, alkaline phosphatase or urease, using methods known to those of
skill in the art. An appropriate enzyme substrate is then used to generate a
detectable signal, such as a chromogenic or fluorogenic signal for example. In
other related embodiments, competitive-type ELISA techniques can be practiced
using methods known to those skilled in the art.
The above-described assay reagents, including the antibodies, can be
provided in kits, with suitable instructions and other necessary reagents, in order
to conduct immunoassays as described above. The kit can also contain,
depending on the particular immunoassay used, suitable labels and other
packaged reagents and materials (i.e. wash buffers and the like). Standard
immunoassays, such as those described above, can be conducted using these
kits.
Gene therapy
In accordance with the present invention, the modulation of the membrane
metallopeptidase activity may be achieved by modifying (i.e. increasing or
decreasing) the amount of BPLP protein, maturation products thereof in the cells
of a patient and release therefrom, or expressing and possibly releasing a
peptide, including peptide derivative, as defined above. Increasing of the amount
of BPLP protein or maturation products thereof in the cells of a patient and
possibly release therefrom, expressing and possibly releasing a peptide as
defined above including a peptide derivative, may be performed by transfecting
the cells with BPLP expressing vector or a vector that expresses a BPLP protein,
a BPLP maturation product or a peptide as defined above, including a peptide
derivative, e.g. in the form of a naked DMA or as a viral vector.
Preferably, the nucleic acid of this invention forms part of a vector. Such
vector is a nucleic acid comprising a coding sequence operatively associated with
sequences that control expression of the protein or peptide in a cell transfected
with the vector.
The use of such a vector indeed makes it possible to improve the
administration of the nucleic acid into the cells of the subject and especially to the
cells to be treated, and also to increase its stability in the said cells, which makes
it possible to obtain a durable therapeutic effect. Furthermore, it is possible to
introduce several nucleic acid sequences into the same vector, which also
increases the efficacy of the treatment.
The vector used may be of diverse origin, as long as it is capable of
transforming animal cells, preferably human cells. In a preferred embodiment of
the invention, a viral vector is used which can be chosen from adenoviruses,
retroviruses, adeno-associated viruses (AAV), lentivirus, herpes virus,
cytomegalovirus (CMV), vaccinia virus and the like. Vectors derived from
adenoviruses, retroviruses or AAVs, HIV-derived retroviral vectors, incorporating
heterologous nucleic acid sequences have been described in the literature.
The present invention therefore also relates to any recombinant virus
comprising, inserted into its genome, nucleic acid sequence that encodes the
BPLP protein, a BPLP maturation product or a peptide as defined above,
including a peptide derivative.
Advantageously, the recombinant virus according to the invention is a
defective virus, devoid of at least the sequences necessary for the replication of
the said virus in the infected cell.
It is particularly advantageous to use the nucleic acid sequences of the
invention in a form incorporated in an adenovirus, an AAV or a defective
recombinant retrovirus.
Targeted gene delivery is described in International Pat. Publication WO
95/28494, published October 1995.
Alternatively, the vector can be introduced in vivo by lipofection. For the
past decade, there has been increasing use of liposomes for encapsulation and
transfection of nucleic acids in vitro. Information regarding liposome is provided in
the "pharmaceutical composition" section of the present application as well.
It is also possible to introduce the vector in vivo as a naked DNA plasmid.
Naked DNA vectors for gene therapy can be introduced into the desired host cells
by methods known in the art, e.g., transfection, electroporation, microinjection,
transduction, cell fusion, DEAE dextran, calcium phosphate precipitation,
Lipofectamine®, use of a gene gun, or use of a DNA vector transporter.
Pharmaceutical compositions
The BPLP-peptides (that is to say the BPLP protein, peptides derived from
BPLP, maturation products, peptides defined above, including peptide derivatives
and mimetics), or the nucleic acids that encode such BPLP-peptides and
antibodies against said BPLP-peptides can be formulated in pharmaceutical
compositions in association with a pharmaceutically acceptable carrier. For
instance the pharmaceutical compositions are suitable for a1 topical, oral,
sublingual, parenteral, intranasal, intravenous, intramuscular, subcutaneous,
transcutaneous or intraocular administration and the like.
A subject matter of the invention is also a pharmaceutical composition
comprising a polymer of said BPLP-peptide or mimetic thereof.
Preferably, the nucleic acid forms part of a vector expressing said nucleic
acid.
Preferably, the pharmaceutical compositions contain vehicles which are
pharmaceutically acceptable for a formulation capable of being injected.
The suitable pharmaceutical compositions may be in particular isotonic,
sterile, saline solutions (monosodium or disodium phosphate, sodium, potassium,
calcium or magnesium chloride and the like or mixtures of such salts), or dry,
especially freeze-dried compositions which upon addition, depending on the
case, of sterilized water or physiological saline, permit the constitution of
injectable solutions.
The doses of BPLP-peptide, antibodies or nucleic acid used for the
administration can be adapted as a function of various parameters, and in
particular as a function of the mode of administration used, of the relevant
pathology, or alternatively of the desired duration of treatment.
To prepare pharmaceutical compositions for peptide therapy, an effective
amount of the BPLP-peptide may be dissolved or dispersed in a pharmaceutically
acceptable carrier or aqueous medium.
Examples of pharmaceutical formulations are provided hereafter.
Pharmaceutical compositions comprise an effective amount of the BPLPpeptide,
nucleic acid or antibodies, in a pharmaceutically acceptable carrier or
aqueous medium.
"Pharmaceutically" or "pharmaceutically acceptable" refer to molecular
entities and compositions that do not produce an adverse, allergic or other
untoward reaction when administered to an animal, including a human, as
appropriate.
As used herein, a "pharmaceutically acceptable carrier" includes any and
all solvents, dispersion media, coatings, antibacterial and antifungal agents,
isotonic and absorption delaying agents and the like. The use of such media and
agents for pharmaceutical active substances is well known in the art. Except
insofar as any conventional media or agent is incompatible with the active
ingredient, its use in the therapeutic compositions is contemplated.
Supplementary active ingredients can also be incorporated into the compositions.
The pharmaceutical forms suitable for injectable use include sterile
aqueous solutions or dispersions ; formulations including sesame oil, peanut oil
or aqueous propylene glycol ; and sterile powders for the extemporaneous
preparation of sterile injectable solutions or dispersions. In all cases, the form
must be sterile and must be fluid to the extent that easy syringability exists. It
must be stable under the conditions of manufacture and storage and must be
preserved against the contaminating action of microorganisms, such as bacteria
and fungi.
Solutions of the active compounds as free base or pharmacologically
acceptable salts can be prepared in water suitably mixed with a surfactant, such
as hydroxypropylcellulose. Dispersions can also be prepared in glycerol, liquid
polyethylene glycols, and mixtures thereof and in oils. Under ordinary conditions
of storage and use, these preparations contain a preservative to prevent the
growth of microorganisms.
The carrier can also be a solvent or dispersion medium containing, for
example, water, ethanol, polyol (for example, glycerol, propylene glycol, and
liquid polyethylene glycol, and the like), suitable mixtures thereof, and vegetables
oils. The proper fluidity can be maintained, for example, by the use of a coating,
such as lecithin, by the maintenance of the required particle size in the case of
dispersion and by the use of surfactants. The prevention of the action of
microorganisms can be brought about by various antibacterial and antifungal
agents, for example, parabens, chlorobutanol, phenol, sorbic acid, thimerosal,
and the like. In many cases, it will be preferable to include isotonic agents, for
example, sugars or sodium chloride. Prolonged absorption of the injectable
compositions can be brought about by the use in the compositions of agents
delaying absorption, for example, aluminium monostearate and gelatin.
Sterile injectable solutions are prepared by incorporating the active
compounds in the required amount in the appropriate solvent with a variety of the
other ingredients enumerated above, as required, followed by filtered sterilization.
Generally, dispersions are prepared by incorporating the various sterilized active
ingredients into a sterile vehicle which contains the basic dispersion medium and
the required other ingredients from those enumerated above. In the case of
sterile powders for the preparation of sterile injectable solutions, the preferred
methods of preparation are vacuum-drying and freeze-drying techniques which
yield a powder of the active ingredient plus any additional desired ingredient from
a previously sterile-filtered solution thereof.
Upon formulation, solutions will be administered in a manner compatible
with the dosage formulation and in such amount as is therapeutically effective.
The formulations are easily administered in a variety of dosage forms, such as
the type of injectable solutions described above, but drug release capsules and
the like can also be employed.
For parenteral administration in an aqueous solution, for example, the
solution should be suitably buffered if necessary and the liquid diluent first
rendered isotonic with sufficient saline or glucose. These particular aqueous
solutions are especially suitable for intravenous, intramuscular, subcutaneous
and intraperitoneal administration. In this connection, sterile aqueous media
which can be employed will be known to those of skill in the art in light of the
present disclosure. For example, one dosage could be dissolved in 1 ml of
isotonic NaCI solution and either added to 1000 ml of hypodermoclysis fluid or
injected at the proposed site of infusion, (see for example, "Remington's
Pharmaceutical Sciences" 15th Edition, pages 1035-1038 and 1570-1580). Some
variation in dosage will necessarily occur depending on the condition of the
subject being treated. The person responsible for administration will, in any event,
determine the appropriate dose for the individual subject.
The BPLP-peptide of interest may be formulated within a therapeutic
mixture to comprise about 0.0001 to 100 milligrams, or about 0.001 to 0.1
milligrams, or about 0.1 to 1.0 or even about 1 milligram to 10 milligrams or even
about 10 to 100 milligrams per dose or so. Multiple doses can also be
administered. Preferred dosages are from about 0.1 μg/kg to about 1 mg/kg,
more preferably from about 1 μg/kg to about 100 μg/kg, and most preferably from
about 10 ug/kg to about 100 μg/kg.
In addition to the formulations for parenteral administration, such as
intravenous or intramuscular injection, other pharmaceutically acceptable forms
include, e.g. tablets or other solids for oral administration ; liposomal formulations;
time release capsules ; and any other form currently used, including creams.
Other routes of administration are contemplated, including nasal solutions
or sprays, aerosols or inhalants, or vaginal or rectal suppositories and pessaries
or cream, and long-acting delivery polymers.
In certain embodiments, the use of liposomes and/or nanoparticles is
contemplated for the introduction of BPLP-peptide agents, as well as nucleic acid
vectors or antibodies into host cells.
The invention also relates to pharmaceutical compositions above defined
further comprising a second pharmaceutical agent that acts synergistically with
BPLP-peptide.
Therapeutic applications
The BPLP-peptides described above, antibodies against said BPLPpeptides
or nucleic acids coding for said BPLP-peptides are useful in the
prevention or treatment of diseases or disorders, wherein a modulation of the
activity of a membrane metallo-ectopeptidase is sought, more particularly a
membrane-zinc metallopeptidase, such as NEP and APN.
Natural NEP substrates are mainly the peptide hormones : Enkephalins,
Substance P, Bradykinin, Angiotensin II and Atrial Natriuretic Peptide which play
key role in the control of central and peripheral pain perception, inflammatory
phenomena, mineral exchange and/or arterial tone (Roques et al., 1993).
More particularly, neutral endopeptidase, NEP 24-11, is distributed both in
nervous and peripheral tissues of mammals, and in the periphery it is particularly
abundant in the kidney and placenta. In these tissues the cell-surface
metallopeptidase NEP participates in the postsecretory processing and
metabolism of neuropeptides, systemic immunoregulatory peptides and peptidehormones.
By controlling the active levels of circulating or secreted regulatory
peptides, NEP modulates their physiological receptor-mediated action. Hence,
the membrane-anchored NEP is involved in regulating the activity of : potent
vasoactive peptides such as Substance P, Bradykinin (BK), Atrial Natriuretic
peptide (ANP), and Angiotensin II (All) ; potent inflammatory/immunoregulatory
peptides such as Substance P and BK and fMet-Leu-Phe (fMLP) ; potent opioid
neuropeptides such as Met and Leu-Enkephalins (Enk) and potent mineral
exchange and fluid homeostasis regulatory peptides such as ANP, C-type
Natriuretic Peptide (CNP) and B-type Natriuretic Peptide (BNP). However the
levels of these peptides are changed through the NEP-induced
formation/degradation only in regions where they are tonically released or where
their release is triggered by a stimulus.
From an integrative point of view, the NEP biological activity is to control
the active levels of peptidergic signals involved in arterial tension regulation, in
inflammatory phenomena and in water-mineral homeostasis, as well as, in the
control of pain processing. From a clinical point of view, this substantiates the fact
that NEP is an important drug target in various disease states. For example, by
inhibiting NEP, thereby increasing the levels and duration of action of central or
peripheral endogenous opioids, an analgesic effect or an anti-depressant effect
could be obtained, or by inhibiting endogenous All formation and substance P,
BK and ANP inactivation, antihypertensive, natriuretic and diuretic agents could
be obtained. The main advantage of modifying the concentrations of endogenous
peptides by use of NEP inhibitors is that the pharmacological effects are induced
only at receptor stimulated by the natural effectors, and are critically dependent
on the tonic or stimulus-evoked release of the natural effectors happening upon
environmental, behavioral and physiopathological stressful situations (Roques et
al, 1993).
Examples of mammalian membrane metallopeptidases besides NEP are
ECE (Endothelin-Converting Enzymes), in particular ECE1 and ECE2, the
erythrocyte cell-surface antigen KELL and the product of PEX gene associated
with X-linked hypophosphatemic rickets, as well as ACE (Angiotensin Converting
Enzyme) and APN (Aminopeptidase N).
Inhibition of ACE and/or ECE has a significant application in the treatment
of hypertension and the prevention and treatment of atherosclerosis.
Inhibition of APN in conjunction with NEP has significant application in the
treatment of pain and depression.
Inhibition of related membrane metallopeptidases has therapeutic effects
in the treatment of tumors, namely ovarian, colorectal, brain, lung, pancreas,
gastric and melanoma cancers, and reducing the incidence of metastasis,
atherosclerosis and/or hypertension. Inhibitions of related membrane
metallopeptidases has also therapeutic effects in pain controlling. Such
antinociceptive effects on acute pain are analgesic effects but also effects on
chronic inflammatory pain such as arthritis or inflammatory bowel disease.
Furthermore, inhibition of bacterial or viral metallopeptidase is expected to
have anti-infection effects.
Metallopeptidases playing an important role in pathogen host tissue
invasion and immunological and inflammatory processes, for example those of
Streptococcus pyogenes, Pseudomonas aeruginosa, Porphyromonas gingivalis
and Legionella pneumophila.
Furthermore, bacterial metallopeptidases, especially ztncmetallopeptidases
play an important role in the diseases caused by proteolytic
toxins, such as the toxins of B. anthracis (Anthrax Lethal factor) and the
neurotoxins of C. tetanum and botulinum.
Other metallopeptidases play an important role in various infections such
as infections caused by HIV (FR 2 707 169).
The importance of proteinase inhibitors for the treatment of bacterial or
viral diseases may be found in J. Potempa and J. Travis.
The different roles of metallopeptidases are disclosed in Turner et al, 2001;
Kenny et al, 1977; Kenny et al, 1987 ; Beaumont et al, 1996.
One object of the present invention is the use of the above described
therapeutic peptides or nucleic acids as analgesic agents or anti-depressant
agents by inhibiting NEP and APN at peripheral, spinal and/or supraspina! levels
and thereby increasing the levels and duration of action of central or peripheral
endogenous opioids, including enkephalins.
The prevention or treatment of pain, especially acute and chronic pain,
visceral inflammatory and neuropathic pain, is contemplated.
The prevention or treatment of any hydro-mineral imbalance is also an aim
of the invention. Among target disorders'one may cite bone, teeth, kidney,
parathyroid, pancreas, intestine, stomach mucosa, prostate, and salivary gland
disorders that are caused by hydro-mineral imbalance.
In particular, the disorder may be selected from the group consisting of
hyper or hypo-parathyroid ism, osteoporosis, pancreatitis, submandibular gland
lithiasis, nephrolithiasis and osteodystrophy.
The prevention or treatment of impaired interpersonal and behavioural
disorders is of further interest. Various mental disorders are described in WO
02/051434.
In particular the invention is drawn at any disorder selected from the group
consisting of avoidance disorder, decreased awareness disorder, autistic
disorder, attention deficit hyperactivity disorder, arousal disorder, hospitalism,
impaired interpersonal functioning and relationship to the external world, schizoid
personality disorder, schizophrenia, depressive disorder, decreased interest in
environment, impaired social activity linked to sexuality, and impaired sexual
behaviour, including untimely ejaculation and hyperactive sexual.
Diseases wherein a modulation of a membrane metallopeptidase is sought
also include hypertension, aterosclerosis, tumor, inflammatory arthritis and bowel
disease.
Treatment of infections is also encompassed. Especially, the importance of
proteinase inhibitors for the treatment of bacterial or virai diseases may be found
in J. Potempa and Travis.
The BPLP-peptides, antibodies or nucleic acids described above are also
useful for controlling immuno-inflammatory responses.
The BPLP-peptides, antibodies or nucleic acids as defined above are also
useful as a natriuretic agent or a diuretic agent.
Another object of the present invention is the use of the above described
peptides or nucleic acids as a substitute in the treatment of drug abuse, notably
morphine drug abuse.
Indeed, studies have suggested that the vulnerability to drug abuse and
the development of reward and drug dependence is at least in part, a result of
pre-existent or induced modifications and/or defect of the endogenous opioid
system. In this regard, using BPLP-peptide or nucleic acid to potentiate the
effects of endogenous enkephalins will reduce the various side-effects (somatic
signs of withdrawal) produced by interruption of chronic morphine or heroin
administration.
According to the invention, reducing the inhibitory effect of the BPLPpeptides
on NEP may be desired, e.g. by using an antibody against the BPLP
protein or peptides. This enhancement of NEP activity is particularly
advantageous in the treatment of neurodegenerative diseases such as a disease
or disorder associated with amyloidosis. Indeed it has been shown that inhibitors
of neprilysin (a neutral endopeptidase, NEP or enkephalinase) by synthetic
inhibitor, raises amyloid B levels (Newell et al, 2003). Leissring et al, 2003 further
reported that transgenic overexpression of neprilysin in neurons significantly
reduces brain AB levels, retards or completely prevents amyloid plaque formation
and its associated cytopathology, and rescues the premature lethality present in
amyloid precursor protein transgenic mice.
A disease or disorder is associated with amyloidosis when amyloid
deposits or amyloid plaques are found in or in proximity to tissues affected by the
disease, or when the disease is characterized by overproduction of a protein that
is or can become insoluble. The amyloid plaques may provoke pathological
effects directly or indirectly by known or unknown mechanisms. Examples of
amyloid diseases include, but are not limited to, systemic diseases, such as
chronic inflammatory illnesses, multiple myeloma, macroglobulinemia, familial
amyloid polyneuropathy (Portuguese) and cardiomyopathy (Danish), systemic
senile amyloidosis, familial amyloid polynephropathy (Iowa), familial amyloidosis
(Finnish), Gerstmann-Straussler-Scheinker syndrome, familial amyloid
nephropathy with urticaria and deafness (Muckle-Wells syndrome), medullary
carcinoma of thyroid, isolated atrial amyloid, and hemodialysis-associated
amyloidosis (HAA); and neurodegenerative diseases.
The term "neurodegenerative disease" refers to a disease or disorder of
the nervous system, particularly involving the brain, that manifests with symptoms
characteristic of brain or nerve dysfunction, e.g., short-term or long-term memory
lapse or defects, dementia, cognition defects, balance and coordination
problems, and emotional and behavioral deficiencies. The present invention is
more particularly concerned with neurodegenerative diseases that are associated
with amyloidosis. Such diseases are "associated with amyloidosis" when
histopathological (biopsy) samples of brain tissue from subjects who demonstrate
such symptoms would reveal amyloid plaque formation. As biopsy samples from
brain, especially human brain, are obtained with great difficulty from living
subjects or might not be available at all, often the association of a symptom or
symptoms of neurodegenerative disease with amyloidosis is based on criteria
other than the presence of amyloid deposits, such as plaques or fibrils, in a
biopsy sample.
In a specific embodiment, according to the present invention the
neurodegenerative disease is Alzheimer's disease (AD). In other embodiments,
the disease may be the rare Swedish disease characterized by a double KM to
NL mutation in amyloid precursor protein (APP) near the amino-terminus of the
pAP portion of APP. Another such disease is hereditary cerebral hemorrhage with
amyloidosis (HCHA or HCHWA)-Dutch type. Other such diseases known in the
art and within the scope of the present invention include, but are not limited to,
sporadic cerebral amyloid angiopathy, hereditary cerebral amyloid angiopathy,
Down's syndrome, Parkinson-dementia of Guam, and age-related asymptomatic
amyloid angiopathy.
In a further aspect, the neurodegenerative disease is a subacute
spongiform encephalopathy, such as but not limited to, scrapie, Creutzfeldt-Jakob
disease, Gerstmann-Straussler disease, kuru, chronic wasting disease of muledeer
and elk, bovine spongiform encephalopathy of cattle, and mink transmissible
encephalopathy.
The invention further relates to the use of an agent that modulates the
interaction between endogenous BPLP protein or maturation product, e.g.
QRFSR, and a membrane metallopeptidase for the preparation of a therapeutic
composition for preventing or treating diseases wherein a modulation of the
activity of said membrane metallopeptidase is sought.
Screening methods
The methods that allow a person skilled in the art to select and purify
candidate compounds that bind to the same targets and have an agonist or an
antagonist biological activity of the BPLP protein or maturation products thereof,
e.g. the QRFSR peptide, are described hereunder.
The candidate compound may be a protein, a peptide, a hormone, an
antibody or a synthetic compound which is either a peptide or a non peptidic
molecule, such as any compound that can be synthesized by the conventional
methods of organic chemistry.
The invention provides an in vitro method for screening compounds for
their ability to bind to the NEP binding site for the BPLP protein or a maturation
product thereof, e.g. the QRFSR peptide, comprising the steps of:
a) incubating a candidate compound with a NEP expressing cell, in the
presence of the BPLP protein or a maturation product thereof, e.g. the QRFSR
peptide, or any peptide retaining the binding specificity or the physiological
activity of BPLP protein or of its maturation products, e.g. the peptide YQRFSR;
b) determining the ability of the candidate compound to compete with
the BPLP protein or a maturation product thereof, e.g. the QRFSR peptide or with
the peptide retaining the binding specificity or the physiological activity of BPLP
protein or of its maturation products, e.g. the peptide YQRFSR, for binding to
NEP.
Binding assays of the candidate compound are generally performed at 4°C
to 25°C or 37°C.
The NEP expressing cell may be in a cell culture, such as a confluent
target cell culture monolayer, or a target organ specimen or a tissue sample (e.g.
cryosections, slices, membrane preparations or crude homogenates) that
contains NEP binding sites for the BPLP protein or a maturation product thereof,
e.g. the QRFSR peptide.
A preferred tissue sample that is used in the screening methods according
to the present invention is a membrane preparation or slices of spinal cord from a
mammal, a tissue known to be appropriated for NEP activity measurement.
Other preferred tissue samples that can be used in the screening methods
according to the present invention are all peripheral tissue preparations that are
known to be enriched in NEP-'peptidase and/or to be targets for the BPLP protein
or a maturation product thereof, e.g. the QRFSR peptide. For example one may
use mammal renal outer medulla, placenta, testis, prostate and bone. For
example, such a procedure can be applied to tissues and/or cells of mouse, rat or
human origin or cell lines transfected with metallo-ectopeptidase cDNA, in
particular NEP cDNA, especially human NEP cDNA.
The BPLP-protein or maturation product thereof (or the peptide that retains
the binding specificity or the physiological activity of the BPLP protein or of its
matured products) is preferably labeled, e.g. by a radioactive (32P, 35S, 3H, 125I
etc...) or non-radioactive label (digoxigenin, CyDye-europium, fluorescein etc..). It
is then incubated with the NEP expressing cell during a time sufficient and under
conditions for the specific binding to take place.
The label specifically bound to the cel! may then be quantified in the
presence of various concentrations of said candidate compound, for example
from10-10to10-5M.
Accordingly, the present invention further provides a process for screening
a compound that specifically bind to the NEP binding sites for the BPLP protein,
or maturation product thereof comprising the steps of:
a) preparing a cell culture or preparing an organ specimen or a tissue
sample (such as cryosections or slices or membrane preparations or crude
homogenates) containing NEP binding sites for the BPLP protein or maturation
products thereof ;
b) adding the candidate compound to be tested in competition with halfsaturation
concentration of labeled protein or maturation product thereof (or a
peptide that retains the binding specificity or the physiological activity of the BPLP
protein or of its matured products);
c) incubating the cell culture, organ specimen or tissue sample of step
a) in the presence of the candidate compound during a time sufficient and under
conditions for the specific binding to take place ;
d) quantifying the label specifically bound to the cell culture, organ
specimen or tissue sample in the presence of various concentrations of candidate
compound (preferably 10"10 to 10"5 M).
In said above process, a half saturating concentration is the concentration
of the labeled BPLP protein or maturation product thereof, e.g. the QRFSR
peptide (or the peptide that retains the binding specificity or the physiological
activity of the BPLP protein or of its matured products) which binds 50 % of the
NEP binding sites.
This process also allows to define the relative affinity of the candidate
compound compared to the BPLP protein, or maturation products, e.g. QRFSR
affinity (or the peptide that retains the binding specificity or the physiological
activity of the BPLP protein or of its matured products).
Another object of the present invention is a process for determining the
relative affinity of ligand compounds that specifically bind to the NEP binding sites
for the BPLP protein, or maturation products, (or the peptide that retains the
binding specificity or the physiological activity of the BPLP protein or of its
matured products), said process comprising the steps a), b), c) and d) of the
above process for each candidate compound and further comprising the step e)
of comparing the affinity of each candidate compound quantified in step d) to the
one of the other candidate compounds.
Another object of the present invention is a process for determining the
affinity of a compound that specifically binds to the NEP binding site for the BPLP
protein or maturation products thereof, comprising the steps of:
a) preparing a cell culture or preparing an organ specimen or a tissue
sample (such as cryosections or slices or membrane preparations or crude
homogenates) containing NEP binding sites for the BPLP protein or maturation
products thereof;
b) adding the candidate compound which has previously been labeled
with a radioactive or a nonradioactive label;
c) incubating the cell culture, organ specimen or tissue sample of step
a) in the presence of the labeled candidate compound during a time sufficient and
under conditions for the specific binding to take place ; and
d) quantifying the label specifically bound to the cell culture, organ
specimen or tissue sample in the presence of various concentrations of the
labeled candidate compound (preferably 10~10 to 10~5 M).
The candidate c'ompound is preferably labeled, e.g. by a radioactive (32P,
s 3H 125| etc... ) or non-radioactive label (digoxigenin, CyDye-europium,
fluorescein etc..). It is then incubated with the NEP expressing cell during a time
sufficient and under conditions for the specific binding to take place.
One may further compare the affinity of each candidate compound
quantified to the one of the other candidate compounds, so that the relative
affinity of candidate compound that specifically binds to the NEP binding site for
the BPLP protein or a maturation product thereof, e.g. the QRFSR peptide, is
determined.
The invention further provides an in vitro method for screening compounds
for their ability to act as agonists or antagonists of the BPLP protein or maturation
products thereof on NEP activity, which method comprises the steps of:
a) incubating a candidate compound with a NEP expressing cell, in the
presence of (i) the BPLP protein or a maturation product thereof, e.g. the QRFSR
peptide, or any peptide retaining the binding specificity or the physiological
activity of the BPLP protein or of its matured products, and (ii) a NEP substrate ;
b) determining the endoproteolysis of the NEP substrate by the NEP,
wherein an increased endoproteolysis in the presence of the candidate
compound, in comparison with the endoproteolysis in the absence of the
candidate compound, is indicative of an antagonist activity; while a decreased
endoproteolysis in the presence of the candidate compound, in comparison with
the endoproteolysis in the absence of the candidate compound, is indicative of an
agonist activity.
As used herein, an agonist of a BPLP protein or maturation product thereof
is a molecule which has the ability to inhibit a metallo-ectopeptidase activity,
especially NEP or APN activity.
As used herein, an antagonist of a BPLP protein or maturation product
thereof is a molecule which has the ability to increase a metallo-peptidase
activity, especially NEP or APN activity.
Furthermore, the agonist or antagonist activity of the candidate compound
can be assessed in determining the metabolic changes induced by this candidate
compound on its target, such as the synthesis and/or release of the primary or
secondary messenger metabolites as a result of a transduction signal via the
protein kinases or adenylate cyclase and the activation of a protein of the G
family.
In particular embodiments, the present invention also pertains to a process
for screening a compound that is an agonist of the BPLP protein or a maturation
product thereof, comprising the steps of:
a) preparing a cell culture or preparing an organ specimen or a tissue
sample (such as cryosections or slices or membrane preparations or crude
homogenates) containing NEP binding sites for the BPLP protein or a maturation
product thereof;
b) incubating the cell culture, organ specimen or tissue sample of step a)
at concentrations allowing measurement of NEP enzymatic activity in the
presence of the candidate compound (preferably 10~10 to 10'5 M), a half-saturating
concentration of the BPLP protein or a maturation product thereof (or any peptide
retaining the binding specificity or the physiological activity of the BPLP protein or
of its matured products) and a NEP substrate during a time sufficient for the
endoproteolysis of the NEP substrate to take place under initial velocity
conditions ;
c) quantifying the activity of the NEP present in the biological material of
step a) by measuring the levels of NEP substrate endoproteolysis, respectively in
the presence or in the absence of the candidate compound and in the presence
or in the absence of the BPLP protein or a maturation product thereof, or the
peptide retaining the binding specificity or the physiological activity of the BPLP
protein or of its matured products.
In said above process, a half-saturating concentration is the concentration
of the BPLP protein or a maturation product thereof which results in a reduction
by half of the degradation of the NEP substrate.
Another object of the present invention comprises a process for screening
a compound that is an antagonist of the BPLP protein or a maturation product
thereof, comprising the steps of:
a) preparing a cell culture or preparing an organ specimen or a tissue
sample (cryosections or slices or membrane preparations or crude homogenates)
containing NEP binding sites for the BPLP protein or a maturation product
thereof;
b) incubating the cell culture, organ specimen or tissue sample of step a)
at concentrations allowing measurement of NEP enzymatic activity under initial
velocity conditions in the presence of a submaximal concentration of the BPLP
protein or a maturation product thereof (or any peptide retaining the binding
specificity or the physiological activity of the BPLP protein or of its matured
products) and a NEP substrate, in the presence of the candidate compound
during a time sufficient for the endoproteolysis of the NEP substrate to take place
under initial velocity conditions ;
c) quantifying the activity of the NEP present in the biological material of
step a) by measuring the levels of NEP substrate endoproteolysis, respectively in
the presence or in the absence of the candidate compound and in the presence
or in the absence of the BPLP protein or a maturation product thereof, or the
peptide retaining the binding specificity or the physiological activity of the BPLP
protein or of its matured products.
In a preferred embodiment of said above process, a submaximal
concentration is a concentration of peptide which results in a reduction by at least
50 % and preferably by at least 75 % of the degradation of the substrate.
The below examples and figures illustrate the invention without limiting its
scope.
LEGENDS TO THE FIGURES :
Figure 1 shows representative cation-exchange HPLC profile of 3HYQRFSR
marker added to 2.5 ml salivary methanol-acid extract corresponding to
2.5 ml human saliva. The recovery of the major radioactive peak was evaluated
at 75-84 % (dotted bars).
Figure 2 shows representative cation-exchange HPLC profile of a salivary
methanol-acid extract obtained from 7 ml human saliva. Fractions were analyzed
for their inhibitory potency of substance P endoproteolysis by human ectoendopeptidase
activity (LNCaP cell line).
Figure 3 is a representative reverse phase HPLC profile of the major
HPLC-EC active 13-14 fractions (dotted bars). Fractions were analyzed for their
inhibitory potency of substance P endoproteolysis by'human ecto-endopeptidase
activity (LNCaP cell line).
Figure 4 is a representative reverse phase HPLC profile of the major
HPLC-RP active fractions. Fractions were analyzed for their inhibitory potency of
substance P endoproteolysis by human ecto-endopeptidase activity (black bars)
and their absorbance at 274 nm (black line).
Figure 5 shows the effect of BPLP-QRFSR peptide on the breakdown of
substance P by human ecto-endopeptidase activity (LNCaP cell line), the
effective concentration of QRFSR peptide ranged from 1 to 25 uM and being halfmaximal
at 11 uM.
Figure 6 shows the effect of YQRFSR derivative of hBPLP-QRFSR peptide
on the breakdown of substance P by human ecto-endopeptidase activity (LNCaP
cell line), the effective concentration of YQRFSR peptide ranged from 5 to 50 uM
and being half-maximal at 30 uM.
Figure 7 shows the effect of YQRFSR derivative of hBPLP-QRFSR peptide
on the breakdown of substance P by rat NEP ecto-endopeptidase activity (renal
tissue), the effective concentration of YQRFSR peptide ranged from 5 to 75 uM
and being half-maximal at 38 uM.
Figure 8 is a RP-HPLC chromatographic analysis of the YQRFSR peptide.
The YQRFSR peptide (175 uM) was not metabolized by human cell surface
endopeptidases, in vitro, whilst it inhibited by 70% the substance P
endoproteolysis mediated by human NEP ectoendopeptidase. The RP-HPLC
chromatographic characteristics revealed that:
1/ the YQRFSR peptide is not metabolized by human cell membranes
containing NEP; 93 % was recovered as intact peptide against 94 % in absence
of metabolizing membranes;
21 in the same experimental conditions the YQRFSR peptide inhibits by
70% the endoproteolysis of substance P by these human cell membranes.
Figure 9 shows the inhibitory effect of QRFSR-peptide on the breakdown
of substance P by recombinant human NEP. Concentration-dependent inhibitory
effect of QRFSR-Peptide on soluble recombinant human NEP activity and no
effect of QRFSR-peptide on the endoproteolysis of substance P by soluble
recombinant hDPPIV activity.
Figure 10 shows the inhibitory effect of QRFSR-peptide on the breakdown
of APN synthetic substrate by cell surface human APN. Concentration-dependent
inhibition by QRFSR-peptide of the cleavage of Ala-pNA chromogenic substrate
by cell surface HEK- hAPN.
Figure 11 shows the inhibitory effect of QRFSR-peptide on the breakdown
of NEP synthetic substrate by cell surface human NEP. Concentration-dependent
inhibition by QRFSR-peptide of the cleavage of Mca-BK2 fluorogenic substrate by
cell surface HEK- hNEP.
Figure 12 shows the in vivo effect of YQRFSR-peptide on the time spent
by rat in paw licking of the formalin-injected hind paw; Mean ± SEM.
Figure 13 shows the in vivo effect of YQRFSR-peptide on the number of
pain spasms following hind paw formalin injection; Mean ± SEM.
Figure 14 shows the in vivo effect of YQRFSR-peptide on the index of pain
spasms during the 60 minute post injection of formalin. The analgesia induced by
QRFSR-derived peptide requires the activation of endogenous opioid receptors.
EXAMPLES :
The study was designed to search natural metallo-ectopeptidases,
especially NEP and/or APN inhibitor particularly in the human salivary secretions.
The strategy for the detection and isolation of this product was based on the
isolation of salivary low-molecular-mass components, which inhibit the
endoproteolysis of NEP-sensitive substrate by human cells expressing the
membrane-anchored human NEP. The inventors have developed the models of
functional detection (membranes preparations of LNCaP and HEK human cells
expressing NEP) and of molecular isolation (HPLC chromatography systems), for
the identification by sequence analysis of the natural endogenous NEP
ectopeptidase inhibitor(s) in human, i.e., the endogenous salivary functional
homologue(s) of the rat sialorphin.
EXAMPLE 1 : Human saliva preparation
The protocol of clinical research established with the "centre de recherche
Vaccinale et Biomedicale" of the Pasteur Institute, assession number: 2045,
received the agreement of the CCPPRB committee (PARIS-COCHIN) and
samplings of the human saliva from 10 healthy male volunteers, began in May
2003 and continued in October 2003. The saliva was collected into previously
cooled "microsorp" tubes containing aprotinin (1000KIU/ml) Pefabloc (0.4 mM)
and HCI (0.1N) final concentration; this medium assuming to inhibit proteolysis
activities. Thus saliva samples were stored at -80°C until the methanol-extraction
procedure was performed.
EXAMPLE 2 : Materials and experimental models for NEP inhibition
1- Sources of human ectopeptidases NEP and APN:
Several Human cell lines have been described as expressing NEP as well
as other members of the metalloecto-peptidase family; among them there are an
osteobtaste cell line, MG-63 (osteosarcoma), a trophoblaste cell line, BeWo
(placenta! choriocarcinoma), an prostate epithelial cell line, LNCaP
(adenocarcinoma) and an enterocyte cell line, Caco-2 (colorecta!
adenocarcinoma). Culture conditions in defined medium useful for the cellular
pharmacology analyses were first developed. Secondly, the inventors have
confirmed by using Northern blot and immunocytochemical analyses that the
LNCaP and BeWo were the only cell lines able to express NEP (ARNm and cell
surface protein) in defined medium culture conditions (i.e., RPMI containing
insulin, transferin and selenium, GIBCO) and after induction by DHT
(dihydrotestosterone) and forskolin, respectively. And finally, in the experimental
model of static incubations of membrane preparations originating from these
cells, the inventors have defined the parameters allowing to analyze the human
NEP-mediated endoproteolysis of substance P in the conditions of initial velocity
measurement i.e. 100 pM / min / μg LNCaP cell membrane proteins (10-fold
lower specific activity for BeWo). The LNCaP membrane activity was inhibited in
the presence of specific synthetic NEP inhibitor, such as thiorphan (62 % for
maximum inhibitory potency at 500nM). In contrast, bestatin (25μM) and captopril
(10μM) which block the aminopeptidase (APN, APB.) and angiotensin-converting
enzyme (ACE) activities, respectively, did not inhibit the substance P hydrolysis
by cell surface ectopeptidases; thus indicating that in the experimental conditions,
the extra cellular breakdown of substance P was mainly caused by the NEP
endopeptidase activity located at the surface of these cells.
In addition, in vitro model using the membrane preparations of transfected
HEK cells with human NEP cDNA or human APN cDNA (HEK cells do not
express these metalloectopeptidases) and soluble recombinant human NEP or
soluble recombinant human DPP IV (Dipeptidyiaminopeptidase IV) (without the
N-terminal cytosol and transmembrane segment) have also been developed.
2- Substrates and inhibitors:
In vitro, membrane amino- and endo-ectopeptidase activities of human cell
membranes are assayed in vitro by measuring the breakdown of the following
synthetic and natural substrates:
a/ Synthetic specific fluorogenic or chromogenic substrates:
- Mca-R-P-P-G-F-S-A-F-K (Dnp)-OH and/or Suc-A-A-F-Amc (NEP) (R&D
systems and Bachem)
- Ac-A-Amc or Ala-pNA(APN) (Bachem)
b/ Physiological substrates:
- Modified tritiated substance P [(3,4 H)Pro -Sar -Met(O2) ]-Substance P
(DuPont-NEN) and Native Substance P: R-P-K-P-Q-Q-F-F-G-L-M (NEP-DPPIVACE)
(Peninsula-Biovalley)
- Native Met-enkephalin: Y-G-G-F-M (NEP-APN) (Peninsula-Biovalley)
Measuring the hydrolysis of these substrates by cell-membrane peptidases in the
presence and absence of different available selective synthetic peptidase
inhibitors assessed the specificity of the peptidase assay:
- Thiorphan, Phosphoramidon (NEP) (Sigma and Roche)
- Bestatin, Amastatin (APN) (Calbiochem)
- DPPIV inhibitor II (DPPIV) (Calbiochem)
- Captopril (ACE) (Sigma)
3- Measurement of peptidase activities
The ectopeptidase activities were measured according to the protocol
developed and established for the functional characterization of the rat sialorphin
(Rougeot et al., 2003). Briefly, for membrane preparations, the cells were
homogenised at 4°C in 10 volumes (vol./wt.) of 50mM Tris/HCI buffered at pH 7.1.
A first centrifugation at 1000 X g and 5°C for 5 min allows to remove the cellular
debris and the nuclei in the pellet. A second centrifugation at 100 000 X g and 5°C
for 30 min concentrates the membrane fraction in the pellet, which will be
superficially washed three times in cold Tris/HCI buffer, resuspended in fresh
buffer, aliquoted and stored at-80°C while waiting to be used as enzyme source.
Proteins determination was carried out using the Bio-Rad DC protein assay with
Bovine Serum Albumin (BSA) as the standard.
Hydrolysis of substrates was measured by monitoring the metabolism rate
in conditions of initial velocity measurement in the presence and absence of
specific inhibitors. These were added to the preincubation medium. The standard
reaction mixture consisted of cell membranes in a final volume of 200 ul Tris-HCI
50 mM pH 6.5-7.2. The substrate was added after preincubation for 10 min and
the digestion carried out for 20 min at 25°C in a constantly shaken water bath.
The reaction was terminated by cooling to 4°C and adding HCI (0.3N final
concentration). The reaction tubes were then centrifuged (4700 X g for 15 min at
4°C) and the remaining intact substrate and its metabolites measured.
In the case of the use of natural substrates, substance P or Metenkephalin,
the products of the reaction are isolated and quantified according to
their differential hydrophobic characteristics:
- C-18 Sep-Pak cartridges (Waters) were used to analyse the hydrolysis of
radiolabeled substance P. The 3H metabolites were isolated by elution with H2O-
0.1% TFA and then with 25% methanol-0.1% TFA (4 ml each). The intact tritiated
substrate was eluted with 75-100 % methanol-0.1% TFA (4 ml).
- RP-HPLC coupled to a spectrophotometer was used to analyse the
hydrolysis of Met-enkephalin, (C-18 LUNA column, AIT). Elution with a 30-min
linear gradient from 0.1% TFA in water to 0.1% TFA in 100% acetonitrile, at 1
ml/min, separated the two Met-enkephalin metabolites (YGG: 5.8 ± 0.2; FM: 12.8
± 0.1 min retention time) and the intact substrate (YGGFM: 18.8 ± 0.2 min). Their
identities and relative quantities (peak height) were checked by monitoring the
column outflow at 264 nm (L3000, Merck).
- The disappearance of the initial Met-enkephalin substrate was also
quantified by radioimmunoassay (RIA). The assay used anti-Met enkephalin
antiserum (Gros et al., 1978) and 125!-Met-enkephalin (80 TBq/mmol, MEN); it
detected nanomolar concentrations of Met-enkephalin in the presence of
micromolar concentrations of Tyr-Gly-Gly and Phe-Met metabolites. The
radioactivity of each fraction was determined by liquid scintillation spectrometry.
In the case of the use of synthetic substrates, the kinetics of appearance of
the fluorescent signal (intensity and polarization) was directly analyzed by using a
multi-well spectrofluorimeter; the intensity of the signal is directly proportional to
the quantity of metabolites formed during the reaction.
EXAMPLE 3 : Human saliva purification and chromatoaraphv
The protocol of extraction and purification of the human salivary
components mimicked the one that was developed and established for the
molecular characterization of the sialorphin from rat saliva (Rougeot et al., 1994),
and the extracts and chromatographic fractions were analyzed for their capacity
to inhibit the hydrolysis of the physiological substrate, substance P, by the human
cell membranes containing NEP.
Extraction and purification of the human salivary compounds potentially
regulators of enkephalinase activity. Briefly, following defrosted at +4°C, the
saliva samples were treated according to the following procedure:
- Methanol-acid extraction procedure: Extraction of low molecular-mass
components in methanol-acid at 4°C; to 1 volume of saliva was added 4 volumes
of methanol containing 0,1 % trifluoroacetic acid (TFA) solution. This first step
realizes the elimination of proteins of high molecular weight (including the
degrading enzymes), which are inactivated and precipitated in acid and methanol
medium respectively and allows the solubilization of the salivary constituents of
small molecular weight ( and centrifuged for 15 min at +4°C and 12OOO g; the methanol was removed
from the supernatant after lyophilization at -110 °C.
- HPLC cation-exchange chromatographv (HPLC-EC): The methanolextracted
saliva was solubilized in the solvent A, i.e., ammonium acetate 10 mM
pH 4.3, and injected into a HEMA-IEC BIO-1000 carboxymethyl column (Alltech).
Components were eluted and isolated according to their cationic characteristic, in
a two-step linear gradient of 10-500 mM and 500-900 mM ammonium acetate pH
4.7, respectively and at a 1 ml / min flow rate. Fractions of 2 ml were collected
and tested after lyophilization for their inhibitory potency of the human
ectopeptidase activity (LNCaP).
Quality and recovery of extraction and successive chromatographies were
estimated using an internal standard (the tritiated peptide: 3H-YQRFSR) added to
a representative salivary sample, as illustrated in Figure 1; the recovery of the
marker added to sample extracted corresponding to 2.5 ml of human saliva was
evaluated at 75-84%. HPLC cation-exchange chromatography of methanol44
extracted saliva (Figure 2; representative profile of a salivary extract
corresponding to 7 ml of human saliva) clearly revealed the presence of two
major molecular salivary components, which were eluted within the first-step
ammonium acetate gradient profile (10-500 mM) at retention times of 26-28 and
36-38 min respectively and that inhibited by >_ 90% the endoproteolysis of
substance P by human membrane-bound peptidases (The 2 active peaks
visualized figure 2 with the retention times of 6 and 48 min correspond to the
exclusion and total volume of the column, respectively).
- HPLC reverse-phase Chromatographies (RP-HPLC). The active fractions
of the previous HPLC-EC were solubilized in the solvent A [0,1 % TFA in H2O]
and injected into a Synergi Max-RP column (Phenomenex). Sample components
were eluted (1 ml/min) with a linear gradient of 1-99 % solvent B [acetonitrile-
TFA, 100-0.1, by vol.]. Fractions of 1 ml were collected and analyzed after
lyophilization for their inhibitory potency towards the cell surface human
ectopeptidase activity (LNCaP). The recovery of the internal marker was
evaluated at 61 %. Fractionation by RP-HPLC (Figure 3), of the active molecular
forms isolated from fractions 13-14 (26-28 min-retention time) of the previous
HPLC-EC, showed the presence of two major molecular populations inhibiting the
human endopeptidase activity, and that were eluted within the acetonitrile
gradient profile at retention times of 23-25 and 28-30 min, respectively.
These fractions underwent further purification procedure on a new synergi
Max-RP-HPLC column through elution with a linear gradient of 1-99 % solvent B
[100% methanol-0.1% TFA]. Column eluates were collected in microsorb tubes at
1-min intervals and the fractions were tested after lyophilisation for their NEP
inhibitory activity. As shown in figure 4, two major molecular forms, which
inhibited the endoproteolysis of substance P by human ectopeptidases, were thus
isolated with retention times of 20-21 and 29-30 min respectively, and their amino
acid sequences were determined.
- Ciphergen ProteinChip and amino-acid sequence analyses. N-terminal
sequence analysis was performed by automated Edman degradation using
Applied Biosystems peptide sequanators (plate-forme d'Analyse et de
Microsequencage des Proteines, Institut Pasteur). The molecular form eluting
from the ultimate RP-HPLC at 18 min-retention time (fraction 20) corresponded to
690 and 769.5 Da molecular mass and to the following sequence of five amino
acid residues: QRFSR. That one eluting at 26 min-retention time (fraction 28)
corresponded to two molecular components of 622-666 Da and 6495 Da,
respectively; the amino-acid determination of the highest molecular mass
indicated that it corresponds to a salivary Basic Praline-Rich Polypeptide
sequence, the human PRP-E of 61 amino-acid sequence (Isemura et al., 1982).
By analogy with the rat salivary sialorphin, these data provide direct
evidence for the existence of a human salivary sialorphin-like, a QRFSR
pentapeptide of structure and function closely related to those of rat QHNPR
pentapeptide and which is secreted into the human salivary secretions; they
support that QRFSR is the mature product proteolyticaliy processed from a
precursor protein in a fashion similar to the maturation pathway of SMR1 and
peptide-hormone precursors. Furthermore, as for the QHNPR rat peptide, the
excreted QRFSR peptide seems to be accumulated in the human salivary
secretions under different forms, among which the free forms including probably
an acetate salt form and the complex forms involving high hydrophobic
interactions with salivary PRP-E.
EXAMPLE 4 : Synthesis and testing of QRFSR peptide
The QRFSR peptide was synthesized and analyzed for its capacity to
inhibit the degradation of the physiological NEP substrate, the substance P, in
vitro, in the experimental model of static incubation of human LNCaP cell
membranes. The peptide QRFSR, inhibited the extra-cellular endoproteolysis of
substance P mediated by human NEP expressed at the surface of human
prostate epithelial cells. The effective concentration for QRFSR ranged from 1 to
25 uM, and being half-maximal (IC50) at 11 (M (Figure 5). Surprisingly, but in
redundant way with regard to what was observed with rat sialorphin towards the
human NEP, the inhibitory efficiency of the QRFSR human peptide towards the
rat renal NEP activity is at least 10-fold lower than that obtained towards the
human cell surface NEP (LNCaP). Strikingly, the derivative peptide YQRFSR,
which has been synthesized for tritium labeling and immunogenic conjugation for
the development of antibody and immunoassay detection system, appeared to
exhibit a relatively similar inhibitory efficacy towards both human and rat ectoendopeptidase
activities (Figures 6 and 7).
(Table Removed)
undetermined
undetermined
Besides, the QRGPR peptide (20 - 90 uM) which could be potentially
maturated from hPB gene products, had no effect on substance P
endoproteolysis induced by LNCaP human cell membranes; this result lets the
inventors to propose that the nature of three central amino acids of the natural
NEP-inhibitor pentapeptide (common Q-Nterminal and R-Cterminal) is
determining signature for the affinity and/or specifity of their functional interaction
with NEP ectoendopeptidase. Furthermore, in spite of the strong primary aminoacid
sequence analogy between the rat and human NEP (•£ 85 %), the inventors
observed a relative specificity in the functional interaction of both natural inhibitorpentapeptides,
respectively the rat QHNPR and human QRFSR. All these results
provide evidence for the existence of a conformational specificity in the
secondary and tertiary of both ectoenzymes; the crystal structure determination of
the binary complex formed with the sialorphin or its derivatives and the human
NEP should allow to gain insight into the binding mode of these natural
competitive inhibitors.
The inventors used the tritiated 3H-YQRFSR peptide to establish the
pharmacokinetic and pharmacodynamic parameters, of this human functional
peptidornimetic of rat sialorphin in vivo in adult male rat (biodistributionbioavailability-
clearance) as well as to define its metabolism mechanism and
turnover in vivo and in vitro, (Figure 8). The RP-HPLC chromatographic
characteristics revealed that:
- the YQRFSR peptide is not metabolized by human cell membranes
containing NEP, indeed 93 % was recovered as intact peptide against 94 % in
absence of metabolizing membranes,
- in the same experimental conditions, the YQRFSR peptide inhibits by
70% the endoproteolysis of substance P by these human cell membranes.
Therefore, YQRFSR is useful for investigating the analgesic activity of the
BPLP maturation products in behavioral rat models of acute pain, e.g., the Pin
pain test and Formalin test, which have been studied for the functional
characterization of the sialorphin in vivo (Rougeot et al., 2003).
EXAMPLE 5 : Further characterization of QRFSR peptides in vitro
The inhibitory specificity of the QRFSR-peptide was assessed by
measuring the endoproteolysis of substance P (SP) in an in vitro enzyme-assay
using purified soluble human NEP and human DPPIV (without the N-termina!
cytosol and transmembrane segment). Using the selective recombinant hNEP
assay, the molecular interaction of human QRFSR-peptide with hNEP was
established, providing direct evidence that the peptide inhibited hNEP activity: as
shown on Figure 9, QRFSR-peptide prevented the NEP mediatedendoproteolysis
of SP by 90%; its inhibitory potency was strictly concentration
dependent (r2= 0.99, n=18), ranged from 5 to 50 μM and was half-maximal at 29
± 1 uM. in contrast, the breakdown of SP by recombinant hDPPIV was not
prevented by 25 or 50 uM QRFSR-peptide, indicating that the inhibitory potency
of the QRFSR-peptide on the SP-catabolizing cell surface ectoenzymes in vitro,
is simply due to its specific interaction with NEP-ectopeptidase. Furthermore,
from studies monitoring the in vivo metabolism of SP, it appears likely that the
QRFSR-peptide, like rat QHNPR-sialorphin, does not entirely protect endogenous
SP from cleavage by the spinal SP-inactivating ectopeptidases, and therefore
would not potentiate SP-mediated nociception in vivo.
The enkephalins are inactivated in vivo with remarkable efficiency (within a
few seconds) by both ectopeptidases, NEP and APN. Owing to the
complementary role of NEP and APN in enkephalin inactivation, only mixed NEPAPN
synthetic inhibitors induce antinociceptive responses in various pain models.
Thus, the inhibitory specificity of QRFSR-peptide was assessed in an
enzyme-assay using membrane preparations of recombinant HEK human cells
expressing selectively either human membrane-anchored NEP or APN. These
transfected-cell models were developed in the laboratory. Membrane amino- and
endo-ectopeptidase activities of human cell membranes were assayed in vitro by
measuring the breakdown of artificial specific fluorogenic substrates, the NEP
substrate used was: Mca-R-P-P-G-F-S-A-F-K-(Dnp)-OH (Mca-BK2) and the APN
substrate was: Ala-pNA. Using the selective membrane-anchored hNEP assay,
the inventors found that the inhibition by the QRFSR-peptide of Mca-BK2
endoproteolysis by NEP is concentration dependent (r2= 0.88, n = 29
determination points) and the effective doses ranged from 5 to 50 μM. Using the
selective membrane-anchored hAPN assay, the inventors have demonstrated
that QRFSR-peptide inhibits the Ala-pNA cleavage by hAPN at 10 to 90 uM
effective doses (r2 = 0.93, n=22 determination points) (see Figures 10 and 11).
(Table Removed)
These results indicate that the human QRFSR-pentapeptide is an efficient
dual inhibitor of NEP and APN ectopeptidase activities, in vitro. Furthermore,
owing to the complementary role of NEP and APN in enkephalin inactivation and
by analogy with rat sialorphin which exerts a powerful analgesic activity, the
combined biological and genomic information accrued led the inventors to
propose that the QRFSR-peptide, by inhibiting enkephalin-inactivating NEP-APN
ectopeptidases, potentiates enkephalin-dependent antinociceptive mechanisms,
in vivo.
EXAMPLE 6 : Functional characterization of QRFSR peptide in vivo
In spite of the strong primary amino-acid sequence analogy between the
rat and human NEP (2 85 %), the inventors observed a relative speciesselectivity
in the inhibitory potency of both inhibitor-pentapeptides, respectively
the rat QHNPR and human QRFSR. Strikingly, the derivative peptide YQRFSR,
which was synthesized for tritium labeling, appeared to exhibit a relatively similar
inhibitory efficacy towards both human and rat ectoendopeptidases (range of
effective concentrations between 5 and 50 μM). Thus, the antinociceptive
potency of the QRFSR-derived peptide was investigated in the behavioral rat
model of acute pain, i.e., the formalin test, which was used for the in vivo
characterization of rat sialorphin action (Rougeot et al., 2003). Systemic
administration of 0.5 and 1 mg/kg YQRFSR-peptide inhibited the early phase
(first 20 min after formalin injection) of paw licking of the formalin-injected hind
paw. For instance, it significantly reduced the time spent by treated rats in paw
licking from 144 ± 17 s, n= 8 (vehicle) to 97 ± 14 s, n=8 (0.5 mg/kg) (p=0.05) and
to 84 ± 13 s, n=8 (1 mg/kg) (p = 0.02 by Dunnett t-Test). Surprisingly, in contrast
to rat siaiorphin-treated rats, the YQRFSR peptide-treated rats spent significantly
less time in paw licking during the late phase (40 to 60 min after formalin
injection) of the formalin test (vehicle-treated rats: 63 ±13 s vs. 1mg/kg treatedrats:
9 ± 3 s, p = 0.001). Although less potent than rat sialorphin, in term of
effective doses (100-200 μg/kg, iv), the QRFSR-derived peptide seems to be as
efficient in its pain-suppressive potency (1 mg/kg, iv), as the synthetic mixed
NEP-APN inhibitor RB101 (2.5-5mg/kg, iv) in the formalin-induced pain model.
These data (as presented on Figures 12, 13 and 14) clearly indicate that
the YQRFSR-peptide inhibits nociception induced by acute and long-acting
chemical stimuli.
Its analgesic potency is almost as efficient as 3 mg/kg morphine dose.
Furthermore, the analgesia induced by the QRFSR-derived peptide in the
chemical-evoked pain behaviour is totally reversed in the presence of an opioid
receptor antagonist, the nalaxone, which is consistent with an involvement of the
endogenous opioidergic pathways in its analgesic effect.
REFERENCES
Beaumont et al, (1996) zinc metallopeptidases in health and disease, 105-
129).
Dickinson, D. P., Thiesse, M., 1996. cDNA cloning of an abundant human
lacrimal gland mRNA encoding a novel tear protein. Curr Eye Res. 15(4), 377-
386.
Gante etal., Angew. Chem. Int. Ed. Engl. 33: 1699 (1994)
Gomeni R. et al., Computer-assisted drug development ; an emerging
technology for designing first-time-in-man and proof-of-concept studies from
preclinical experiments. Eur. J. of Pharmaceutical Sciences (2001) 261-270
Horwell etal., Bioorg. Med. Chem. 4: 1573 (1996)
Ise'mura, S., Saitoh, E., 1997. Nucleotide sequence of gene PBI encoding
a protein homologous to salivary proline-rich protein P-B. J Biochem (Tokyo).
121(6), 1025-1030.
Isemura, S., 2000. Nucleotide sequence of gene PBII encoding salivary
proline-rich protein P-B. J Biochem (Tokyo). 127(3), 393-398.
Isemura, S., Saitoh, E., Sanada, K., 1982. Fractionation and
characterization of basic proline-rich peptides of human parotid saliva and the
amino acid sequence of proline-rich peptide P-E. J Biochem (Tokyo). 91(6),
2067-2075.
Jones E. et al., Drug discovery technology. Start-up shourcase and
structure-based drug design. Drugs, Sept. 2002 ; 5(9):894-895
Kan, impact of recombinant DMA technology and protein engineering on
structure-based drug design : case studies of HIV-1 and HCMY proteases (2002).
Kenny et al, (1977) Proteinases in mammalian cells and tissues
Kenny et al, (1987) Mammalian ectoenzymes
Leissring et al., (2003) Enhanced Proteolysis of p-amyloid in APP
transgenic mice prevents plaque formation, secondary pathology, and premature
death, Neuron., 40, 1087-1093
Liskamp et al., Reel. Trav. Chim. Pays- Bas 1: 113 (1994)
Marini, M., Roda, L G., 2000. Enkephalin-degrading enzymes and their
inhibitors in human saliva. Peptides. 21(1), 125-135.
Newell et al., (2003) Thiorphan-induced neprilysin inhibition raises amyloid
P levels in rabbit cortex and cerebrospinal fluid, Neuroscience letters 350, 178-
180
Oefner C. et al. Structure of human Neutral Endopeptidase (Neprilysin)
complexed with Phosphnomidon, J. Mol. Biol. (2000), 296, 341-349
Potempa J. and Travis. J., Proteinases as virulence factors in bacterial
diseases and as potential targets for therapeutic interaction with proteinase
inhibitors. In proteases as targets for therapy. 99, 159-188, Eds K. Helm, B.D.
Korant and J.C. Cheronis - Spinger Handbook Exp. Pharm. 140.
Roques et al. (1993) Pharmacological Reviews 45, 87-146
Rosinski-Chupin, I., Tronik, D., Rougeon, F., 1988. High level of
accumulation of a mRNA coding for a precursor-like protein in the submaxillary
gland of male rats. Proc Natl Acad Sci USA. 85(22), 8553-8557.
Rougeot, C., Messaoudi, M., Hermitte, V., Rigault, A. G., Blisnick, T.,
Dugave, C., Desor, D., Rougeon, F., 2003. Sialorphin, a natural inhibitor of rat
membrane-bound neutral endopeptidase that displays analgesic activity. Proc
Natl Acad Sci USA. 100(14), 8549-8554.
Rougeot, C., Rosinski-Chupin, I., Njamkepo, E., Rougeon, F., 1994.
Selective processing of submandibular rat 1 protein at dibasic cleavage sites.
Salivary and bloodstream secretion products. Eur J Biochem. 219(3), 765-773.
Rougeot, C., Vienet, R., Cardona, A., Le Doledec, L, Grognet, J. M.,
Rougeon, F., 1997. Targets for SMR1-pentapeptide suggest a link between the
circulating peptide and mineral transport. Am J Physiol. 273(4 Pt 2), R1309-1320.
Sambrook et al., (1989) Molecular Cloning: A Laboratory Manual, Second
Edition Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York
Seebach et al., Helv. Chim. Acta 79: 913 (1996)
Seidah et al., (1995) the mammalian family of subtilisin/Kexin-like, Proprotein
Convertases. Intramolecular chaperones and Protein foliding ; 9, 181-203
Turner et al. (2001) Bioessays, 23, 261-9
















We claim:
1. An isolated or purified peptide that is a maturation product of the Basic Prolin-rich
Lacrimal Protein (BPLP) or a peptide derivative of said maturation product, wherein the
peptide or peptide derivative exhibits a modulatory, especially an inhibitory property
against a metallo-ectopeptidase, said peptide including from about 3 to 15 amino acids
and being obtained through cleavage of the BPLP protein precursor by furin, PC
convertase or PACE4, and said peptide derivative deriving from said peptide by one or
two amino acid substitutions and retaining the binding specificity and/or physiological
activity of said peptide, wherein said peptide or peptide derivative comprises the
sequence Xl-X2-Arg-Phe-Ser-Arg, wherein :
- XI represents H atom or a Tyr amino acid or a Cys amino acid,
X2 represents Gin or GIp when X1 is H, or X2 represents Gin when X1 is Tyr, wherein said sequence Xl-X2-Arg-Phe-Ser-arg is the C-terminal part of said peptide.
2. The peptide as claimed in claim 1, wherein said metallo-ectopeptidase is NEP or APN.
3. The peptide as claimed in claim 1, which consists of sequence QRFSR (SEQ ID No. 3).
4. The peptide as claimed in claim 1, which consists of sequence YQRFSR (SEQ ID No. 4).
5. The peptide as claimed in claim 1, which consists of sequence CQRFSR (SEQ ID No. 5).
6. An isolated or purified nucleic acid that encodes a peptide as claimed in any of claim 1 to 5.

7. A DNA expression vector, which vector comprises a nucleic acid as claimed in claim 6 which is operably linked to a promoter sequence, and which further contains signals for initiation and termination of translation.

Documents:

5282-DELNP-2006-Abstract-(14-09-2009).pdf

5282-delnp-2006-abstract.pdf

5282-DELNP-2006-Claims-(14-09-2009).pdf

5282-DELNP-2006-Claims-(26-04-2010).pdf

5282-DELNP-2006-Claims-(29-04-2010).pdf

5282-delnp-2006-claims.pdf

5282-DELNP-2006-Correspondence-Others-(14-09-2009).pdf

5282-DELNP-2006-Correspondence-Others-(26-03-2010).pdf

5282-DELNP-2006-Correspondence-Others-(26-04-2010).pdf

5282-DELNP-2006-Correspondence-Others-(29-04-2010).pdf

5282-delnp-2006-correspondence-others.pdf

5282-delnp-2006-description (complete).pdf

5282-delnp-2006-drawings.pdf

5282-DELNP-2006-Form-1-(14-09-2009).pdf

5282-delnp-2006-form-1.pdf

5282-delnp-2006-form-13.pdf

5282-delnp-2006-form-18.pdf

5282-DELNP-2006-Form-2-(14-09-2009).pdf

5282-delnp-2006-form-2.pdf

5282-DELNP-2006-Form-3-(14-09-2009).pdf

5282-delnp-2006-form-3.pdf

5282-delnp-2006-form-5.pdf

5282-DELNP-2006-GPA-(26-04-2010).pdf

5282-delnp-2006-gpa.pdf

5282-delnp-2006-pct-210.pdf

5282-delnp-2006-pct-304.pdf

5282-DELNP-2006-Petition-137-(14-09-2009).pdf


Patent Number 240957
Indian Patent Application Number 5282/DELNP/2006
PG Journal Number 25/2010
Publication Date 18-Jun-2010
Grant Date 10-Jun-2010
Date of Filing 13-Sep-2006
Name of Patentee INSTITUT PASTEUR
Applicant Address 28 RUE DU, DOCTEUR ROUX, F-75724, PARIS CEDEX 15 FRANCE
Inventors:
# Inventor's Name Inventor's Address
1 ROUGEOT CATHERINE LIEU DIT DE TALOU-39 ROUTE DE CHOISEL, F-78460 CHEVREUSE FRANCE
2 HUAULME JEAN-FRANCOIS READ AS 125BIS RUE DE PICUPS 75012,PARIS, FRANCE
3 UNGEHEUER MARIE-NOELLE 12 RUE DE BENODET, F-78310 MAUREPAS FRANCE
4 WISNER ANNE 1 RUE DES DEUX FRERES, F-94230 CACHAN FRANCE
5 DUFOUR EVELYNE 12-14 RUE J.B. POTIN, F-92170 VANVES FRANCE
PCT International Classification Number C07K 7/06
PCT International Application Number PCT/IB2005/000700
PCT International Filing date 2005-03-18
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 04290754.3 2004-03-19 EUROPEAN UNION