Title of Invention

A METHOD FOR IDENTIFYING A CANDIDATE COMPOUND THAT EFFECTS SIGNAL GENERATED BY ACTIVATION OF THE EDG8 POLYPEPTIDE

Abstract The present invention relates to newly identified EGD8 receptors, polynucleotides encoding this receptor, polypeptides encoded by such polynucleotides, the preparation and the use of such polynucleotides and polypeptides.
Full Text

EDG8 receptor, its preparation and use
The present invention relates to newly identified EGD8 receptors, polynucleotides encoding this receptor, polypeptides encoded by such polynucleotides, the preparation and the use of such polynucleotides and polypeptides.
In an effort to identify new G-protein coupled receptors of the EDG (endothelial differentiation gene)-family a novel member of the EDG-family of G-protein coupled receptors, Human EDG8, was identified. The full-length clone was isolated and studies on chromosomal mapping, tissue expression and identification as a functional cellular receptor for sphingosine 1-phosphate were performed. Taken together, the data provide compelling evidence that EDG8 is the fifth receptor for sphingosine 1-phosphate. exclusively expressed in peripheral tissues, its presence in endothelial ceils being responsible for the broad tissue distribution.
The lysolipid phosphate mediators lysophosphatidic acid (LPA) and sphingosin 1-phosphate (S1P) have attracted increasing attention as modulators of a variety of important biological functions (Moolenaar et al., 1997; Morris, 1999; Lynch and Im, 1999) and their list of biological activities is continuously growing. Among the biological responses to LPA is platelet aggregation (Jalink et al., 1994; Siess et al., 1999; Gueguen et al., 1999), smooth muscle contraction (Tokumura et al., 1980), in vivo vasoactive effects (Tokumura et al., 1995), chemotaxis (Jalink et al., 1993), expression of adhesion molecules (Lee et al., 1998b; Rizza et al., 1999), increased tight junction permeability of endothelial cells (Schulze et al., 1997), induction of stress fibers (Gohla et a!., 1998) and many others (for review see Moolenaar et al., 1997). The biochemical signalling events that mediate the cellular
effects of LPA Include stimulation of phospholipases, mobilization of intracellular Ca2+,
inhibition of adenylyl cyclase, activation of phosphatidylinositol 3-kinase, activation of
the Ras-Raf-MAP kinase cascade and stimulation of Rho-GTPases (Moolenaar et al.,
1997).
S1P, in particular, is implicated in cell proliferation, modulation of cell motility (reviewed
in Hia et al., 1999) induction/suppression of apoptosis (Hisano et al., 1999; Xia et al.,

1999), angiogenesis (Lee et al., 1999), tumor invasiveness (Sadahira et al., 1992), platelet activation (Gueguen et al., 1999) and neurite retraction (Postma et al., 1996). Cellular signalling by S1P involves activation of PLCS and subsequent intracellular
Ca2+ release (van Koppen et al., 1996; Meyer zu Heringdorf et al., 1997; Yatomi et al., 1997a; Noh et al., 1998; Ancellin and HIa, 1999), activation of MAP-I 1995; Lee et al., 1996; An et al., 2000), activation of inward rectifying K+'-channeIs (van Koppen et al., 1996; Bunemann et al., 1996) and inhibition and/or activation of adenylyl cyclase (Lee et al.,.1996).
Both, LPA and S1P are recognized to signal cells through a set of G-protein coupled receptors (GPCRs) known as EDG (endothelial differentiation gene)-receptors. The EDG-family of GPCRs currently comprises seven human members (EDG1-7) that fall into two major groups depending on their preference for the activating lipid-ligand: EDG1, 3, 5 and 6 preferentially interact with S1P (Yatomi et al., 1997b; Lee et al.. 1998a,b; Ancellin and HIa, 1999; Yamazaki et al., 2000; Van Brooklyn et al., 2000), EDG2, 4 and 7 preferentially interact with LPA (An et al., 1998; Im et al., 2000).
The assignment of specific biological functions to certain receptor subtypes is hampered by the fact that EDG receptors are expressed in an overlapping fashion (Rizza et al., 1999; Lee et al., 1999), they activate multiple and in part redundant signal transduction pathways (Lee et al., 1996; Ancellin and HIa, 1999; Kon et al., 1999; An et al., 2000), the selectivity for their activating ligands is not absolute (Lee et al., 1998b), and medicinal chemistry is only poorly developed in that specific antagonists for dissecting the pharmacology of the individual subtypes are not available yet. An important step to shed more light on the biological role of the individual receptor subtypes would be to identify the complete set of receptors that respond to the phospholipid mediators SIP and LPA.
The present invention relates to newly identified EGD8 receptors, polynucleotides encoding this receptor, polypeptides encoded by such polynucleotides the preparation and the use of thereof.

The present invention relates to an isolated polynucleotide comprising a nucleotide sequence that has at least 90 % identity, preferably 95 % or more, most preferably 98 % identity to a nucleotide sequence encoding the polypeptide of SEQ ID NO. 2 or the corresponding fragment thereof; or a nucleotide sequence-complementary to said nucleotide sequence.
Preferably, the polynucleotide is DNA or RNA. The nucleotide sequence of the polynucleotide is at least 90 % identical to that contained in SEQ ID NO. 1.; preferably 95 % or more, most preferred 98 % or more identical to SEQ ID NO. 1. In another embodiment, the polynucleotide has the nucleotide sequence SEQ ID NO. 1. In another embodiment, the polynucleotide encodes the polypeptide of SEQ ID NO. 2 or a fragment thereof. In a special embodiment, the polynucleotide is an allel of SEQ ID NO. 1. Preferably, the polynucleotide has the same essential properties and/or biological functionality as human EDG8.
One characteristic functionality is that the polynucleotid encodes for a S1P receptor; it responds to 81P and optionally also to related phospholipids like DMS 1P or LPA.
Another aspect of the invention relates to an expression system for the expression of EDG8. The EDG8 DNA or RNA molecule comprising an expression system wherein said expression system is capable of producing a polypeptide or a fragment thereof having at least 90 % identity, preferably 95 % or more, most preferred 98 % or more identity with a nucleotide sequence encoding the polypeptide of SEQ ID NO. 2 or said fragment when said expression system is present in a compatible host cell. Preferably, the expression system is a vector. The invention relates to a host cell comprising the express/on system.
in another aspect, the invention relates to a process for producing an EDG8
polypeptide or a fragment thereof wherein a host ceil comprising the expression
system is cultured under conditions sufficient for the production of said polypeptide or
fragment thereof.
Preferably, the said polypeptide or fragment thereof is expressed at the surface of said
cell.

The invention relates also to cells produced by this process.
The process preferably further includes recovering the polypeptide or fragment thereof from the culture.
In another aspect, the invention relates to a process for producing a cell which produces an EDG8 polypeptide or a fragment thereof comprising transforming or transfecting a host ceil with the expression system such that the host cell, under appropriate culture conditions, produces an EDG8 polypeptide or a fragment thereof.
In particular, the invention relates to an EDG8 polypeptide or a fragment thereof comprising an amino acid sequence which has at least 90 %, preferably 95 %, most preferred 98 % or more identity to the amino acid sequence SEQ ID NO. 2 or to a part of SEQ ID NO. 2. In particular the invention relates to an EDG8 polypeptide or a fragment thereof having amino acid sequence SEQ ID NO. 2 or a part thereof. In particular, the invention relates to an polypeptide encoded by SEQ ID NO. 1 or encoded by a polynucleotide that has at least 90 %, preferably 95 %, most preferred 98 % or more identity with SEQ ID NO. 1; preferably, such polypeptid has almost the same properties as human EDG 8; e.g. the same biological functionality. One characteristic functionality of human EDG8 is that the polypeptid is a S1P receptor; it responds to S1P and optionally to related phospholipids like DMS1P or LPA.
Further, the invention relates to a process for diagnosing a disease or a susceptibility to a disease related to expression or acitivity of EDG8 polypeptide comprising:
a) dermining the presence or absence of mutation in the nucleotide sequence encoding said EDG8 polypeptide in the genome of said subject; and/or
b) analyzing for the presence or amount of the EDG8 polypeptide expression in a sample derived from said subject.

In addition, the invention relates to a method for identifying compounds which bind to EDG8 polypeptide comprising:
a) contacting a cell comprising the expression system or a part of such a ceil with a candidate compound; and
b) assessing the ability of said candidate compound to bind to said cells.
Preferably, the method for identifying compounds further includes determining whether the candidate compound effects a signal generated by activation of the EDG8 polypeptide at the surface of the cell, wherein a candidate compound which effects production of said signal is identified as an agonist.
In another embodiment of the invention, the method for identifying compounds further includes determining whether the candidate compound effects a signal generated by activation of the EDG8 polypeptide at the surface of the cell, wherein a candidate compound which effects production of said signal is identified as an antagonist.
The invention also relates to an agonist or antagonist identified by such methods.
In another special embodiment of the invention, the method further includes contacting said cell with a known agonist for said EDG8 polypeptide; and determining whether the signal generated by said agonist is diminished in the presence of said candidate compound, wherein a candidate compound which effects a diminution in said signal is identified as an antagonist for said EDG8 polypeptide. The known agonist is for example S1P, LPA and/or DHS1P. The invention also relates to an antagonist identified by the method.
The invention in addition, relates to a method of preparing a phamiaceutical composition comprising
a) identifying a compound which is an agonist or an antagonist of EDG8,
b) preparing the compound, and
c) optionally mixing the compound with suitable additives.
The invention also relates to a phamnaceutical compound prepared by such a process.

The invention relates to a pharnnaceutical, connprising as active ingredient for example such identified compound, an EDG8 polypeptid or a polynucleotide encoding for EDG8 or a part thereof.
In particular, the invention relates to a pharnnaceutical, that can be used for the prevention and/or treatment of diseases associated with EDG8/S1P signal transduction, for example diseases associated with endothelial dysfunction such as for example Atheriosclerosis, Shoke, Hypertonie, coronary syndroms, cancer, thronnbolylic diseases, affected wound healing and diseases accompanied by increased cell death. In another aspect of the invention, such pharmaceutical can be used for the prevention and/or treatment of diseases associated with a dysregulation of angiogenesis, such as for example tumor growth, rheumatical arthritis and diabetic setinopathy.
The study, reported about the cloning, chromosomal mapping, tissue expression and functional identification as a receptor for S1P of a novel GPCR, EDG8, the fifth functional receptor for sphingosine 1-phosphate.
In an effort to identify new G-protein coupled receptors of the EDG-family a database search with alignments of the currently known 18 members of this receptor family was performed, comprising human EDG1-7 sequences up to the putative EDGs from Xenopus and Zebra-fish. A multiple alignment of these sequences was created by CLUSTALW and used in a PSl-BLAST search to scan translated versions of human genomic DNA sequences, which were publicly available in the different EMBL sections. For translation of DNA into protein sequences, individual protein files within two respective STOP-codon were created and ail proteins shorter than 50 amino acids were ignored. As the majority of GPCRs is unspliced searching for GPCRs within genomic sequences should bring about novel receptor proteins. Performing a PSl-BLAST search, the various cDNAs and genomic contigs, respectively, for the human EDG1-7 receptors were identified, and an additional genomic hit, highly homologous to human EDGS (51% homology), termed EDGS, The nucleotide and amino acid sequence of the new putative GPCR are depicted in Fig,1A.

Hydropathy analysis (hydrophobicity plot not shown) suggests a seven transmembrane protein with three alternating extra- and intracellular loops, assumed to be the heptahelix structure common to GPCRs.
To shed more light on the relationships involved in the molecular evolution of the EDG-receptor family, a grow tree phylogram was constructed using the neighbor joining method (GCG software) (Fig.lB) (Comparison of amino acid sequences). According to this phylogenetic tree, the human EDG-family can be divided into two distinct groups: EDG1, 3, 5 and 6 belonging to one, EDG2, 4 and 7 belonging to the other group. These two groups are discriminated further by their preference for different lipid ligands: EDG1, 3, 5, 6 are preferentially stimulated by sphingosin 1-phosphate (S1P) (Yatomi et a!., 1997b; Lee et al., 1998a,b; Ancellin and HIa, 1999; Yamazaki et al., 2000; Van Brooklyn et al., 2000), EDG2,4 and 7 by lysophosphatidic acid (LPA) (Hecht et a!.. 1996; An et al., 1998; Im et al, 2000). The newly identified EDG8 exhibited highest similarity (86.8% aminoacid identity) to the rat nrg1-protein (Fig. 18), a GPCR recently cloned by EST-expression profiling from a rat PC12 cell library (Glickman et a!., 1999), which probably represents the rat homologue of human EDG8. In the report of Glickman, however, the authors did not address the question of the activating ligand of this receptor. The high similarity between EDG8 and the known sphingosin 1-phosphate (S1P) receptors EDG1, 3 and 5 (48-51%) (Fig. 1C) led to test the hypothesis that EDG8 may be a functional SI P-receptor. In testing for SIP receptor activity, the EDG8 cDNA was introduced into Chinese hamster ovary (CHO) cells by transient transfection. CHO cells were chosen as they exhibit minimal responses to sphingosin 1-phosphate in concentrations up to 1 μM but respond to S1P after transfection with the S1P preferring receptors EDG 1, 3 and 5 (Okamoto et al., 1998; Kon et al., 1999). To test functional receptor activity the
mobilization of [Ca2+]! was monitored for three reasons:
1.) SIP has been reported to increase Ca2+ in many cell types (Ghosh etal., 1990; Zangetal., 1991; Durieuxetal., 1993; Chaoetal., 1994; Gosh etal., 1994; Mattieet al., 1994; Meyer zu Heringdorf et al., 1996; Okajima etal., 1996; van Koppen etal., 1996; Tornquist et a!., 1997; Yatomi et al., 1997; Noh et al., 1998; An et al., 1999 ) 2.) the identification of EDG1, 3, 5 and 6 as receptors for SI P has provided the molecular basis for a GPCR mediated mechanism and the receptors are known to

mediate intracellular Ca2+.release through either PTX-sensitive GQJ proteins or the
PTX-insensitive Gaq/i 1 pathway (Okamoto et al., 1998; Kon et al., 1999; Gonda et ah,
1999)
3.) all currently known S1P-responding EDG-receptors (except EDG6) are present in
endothelial cells (A. Niedernberg et al., submitted), in which intracellular Ca2+ release is a major pathway in the generation of NO, an important factor in vascular biology.
Thus, identification of the complete set of S1P receptors, involved in intracellular Ca2+ mobilization could help clarify the role of the individual subtypes in endothelial cell signalling.
Fig.2 depicts measurement of the intracellular Ca2+ concentration, mediated by SIP via the putative S1P receptor EDG8. Forsake of comparison, the S1P-receptors
EDG1, 3, 5, and 6, which have been reported to mobilize [Ca2+], were included.
[Ca2+] were recorded as real time measurements using the Fluorescence plate
imaging reader (FLIPR, Molecular Devices). Initially, CHO cells transfected with empty vector DNA were stimulated with different concentrations of SIP (10,100,1000 nM), None of the applied SIP concentrations was capable of eliciting significant rises in
intracellular Ca2+ (Fig. 2A), suggesting that S1P receptors are not expressed in CHO cells or, if expressed are unable to signal via the endogeneous Goq pathway. To
address this issue, the G protein chimera Gaq15, which confers onto Gi coupled
receptors the ability to stimulate the Gq pathway, and Ga16. which links Gi- and Gs
coupled receptors to PLCS and subsequent intracellular Ca2+-mobilization were used. Upon stimulation with SIP, Gq15- and G16 transfected CHO cells did not give rise to
significant increases in [Ca2+]j (Fig. 2A). However, transient transfection of CHO-cells with the cDNAs coding for the EDG1, 3 and 5 receptor conferred SIP-responsiveness to the cells; it was confinned that EDG1, 3 and 5 mobilize [Ca2+]j in response to SI P (Fig. 2B, C, D) (Kon et al., 1999). As already known for a large number of Gq-coupled receptors, coexpression of Gaq augments the EDG1 and 5-mediated Ca2+-response
as compared with the Ca2+ signal induced by stimulation of endogeneous Goq. In

case of EDG3, additional exogeneously added Goq did not further improve the signal
intensity. These results are in agreement with the findings reported by Kon et al. (1999), who showed that the EDG3-subtype causes the most robust enhancement, of intracellular Ga2+.
In case of EDG6, Yamazaki et al. (2000) obtained an S1 P-induced mobilization of [Ca2+]j but we failed to detect a significant Ca2+ increase above basal levels in the
absence of any cotransfected G-protein a subunit (Fig. 2E). The reason for this discrepancy could be the cellular background (CHO cells in this study vs. K562 cells in
Yamazaki et al.), as they reported a pertussis toxin (PTX)-sensitive Ca2+-response,
indicating the involvement of Gi-type G-proteins. In this case the Ca2+ signal would be
elicited by Sy, released from activated Gajfiy heterotrimers. The Goj-induced Ca2+
signals are known to be much smaller in intensity as compared with the Ca2+ signals induced by bona-fide Gq-linked receptors (Kostenis et al., 1997). It may be that
detection of such [Ca2+]j concentrations is beyond the sensitivity of the FLIPR system. EDG8 did not release [Ca2+]j when stimulated with SIP (10, 100, and 1000 nM)
(Fig.2F), but gained the ability to mobilize Ca2+ upon cotransfection with Ga16, a G-
protein a subunit, known to couple GPCRs from different functional classes to the Gq-PLCS pathway or Goq15, a mutant G-protein a subunit that confers-onto Gi-linked
receptors the ability to stimulate Gq (Conklin et al., 1993). These results show that
EDG8 is a functional receptor for SIP and that EDG8-lnduced Ca2+ responses are due to a non-Gq pathway, probably the activation of phospholipase CB2 by By subunits of the Gi proteins. Furthermore, these results provide additional evidence that the SlP-preferring EDG-receptors couple differentially to the Gq and Gi pathways:
EDG3 ist the most potent Ca2+-mobilizing receptor and overexpression of Goq does
not further improve Ca2+ signalling; EDG1 and 5 induce moderate Ca2+-increases. that can be significantly improved by cotransfection of Goq or a chimeric Goqi5
protein; EDG8-mediated Ga2+.responses require cotransfection of Gaqi5 or Ga16.
To check, whether the EDG8 receptor also reacts to related lysophospholipid mediators, we examined the abilities of lysophosphatidic acid (LPA), dihydrosphingosin

1-phosphate (DHS1P), sphingosylphosphorylcholine (SPC) and
lysophosphatidylcholine (LPC) to increase intracellular Ca2+ in CHO cells transiently transfected with the EDG8 receptor and the G-protein a subunits Ga16 and Gaqi5
(Fig.3). Besides S1P, which was the most potent activator of EDG8. LPAand DHS1P
evoked [Ca2+] creases in concentrations of 100 and 1000 nM. SPC and LPC,
respectively, failed to generate any significant response in concentrations up to 1 μM. These data show that EDG8 is a S1P preferring receptor, but also responds to related phospholipids like DHS1P or LPA, as has also been reported for EDG1, which is a high affinity receptor for S1P and a low affinity receptor for LPA (Lee et al., 1998b). Therefore, EDG8 receptor has the characteristic functionality to respond to SIP and related phospholipids like DMS 1P or LPA. The response to SIP and other related phospholipides can for example be determined as described in Example 3. Cells containing the respective Ga can be obtained as described in Example 2.
Next, the expression pattern of the EDG8 gene in human tissues was investigated by Northern blot analysis (Fig.4). Tissues positive for EDG8 RNA were skeletal muscle, heart and kidney, lower abundance of RNA was seen in liver and placenta, no signal was detected in brain, thymus, spleen, lung and peripheral blood leukocytes. In all tissues a single RNA transcript of 5.5 kb was observed after hybridization with a DIG-labelled EDG8 antisense RNA probe. EDG8 exhibits highest similarity to the rat nrgl-GPCR (Glickman et al., 1999) with an amino acid identity of 86.8% (Fig.lB) suggesting that it may be the human homolog of the rat nrgi protein. However, the expression pattern of human EDG8 is quite different from the rat nrg1-receptor,
which is found almost exclusively in brain (Glickman et a!., 1999), This finding suggests that EDG8 may represent a closely related but entirely different receptor from nrgi, rather than the human homolog. Never the less, it does not rule out the possibility that EDG8 and nrgi are homologs with entirely different, species-dependent expression patterns.
As the first member of the EDG-family of GPCRs - EDG1 - was originally cloned as an endothelial differentiation gene from phorbol-myristic-acetate-treated differentiating

human endothelial cells (Hla and Maciag, 1990) and subsequently cloned from a human umbilical vein endothelial cell library exposed to fluid shear stress as an upregulated gene it is reasonable to assume that EDG receptors play an important role in the regulation of endothelial function. Therefore, the presence of EDG8 transcripts in several human endothelial cell lines was analyzed. RT-PCR analysis of human umbilival vein endothelial cells (HUVECs), human coronary artery endothelial cells (HCAECs), human microvascular endothelial cells of the lung (HMVEC-L) and human pulmonary artery endothelial cells (HPAEC) revealed EDG8 expression in all cell lines tested (Fig.SA). In Fig.SB it is shown that EDG8 specific primers indeed solely amplify EDG8 sequences and none of the related EDG1.7 sequences. These findings suggest that the presence of EDG8 in different peripheral organs may be due to its localization in endothelial cells; it does not rule out, however, that EDG8 transcripts occur in cell types other than endothelial cells.
The expression of EDG8 in addition to EDG1, 3, and 5 (Rizza et al, 1999) in HUVECS and several other endothelial cell lines is intriguing in view of all the reports regarding S1P effects on endothelial cell signalling. Hisano et al, (1999) reported that S1P protects HUVECS from apoptosis induced by withdrawal of growth factors and stimulates HUVEC DNA synthesis; the authors derived a model for cell-cell interactions between endothelial cells and platelets but the S1P-receptor responsible for HUVEC-protection of apoptosis could not be identified. Rizza et al, 1999 reported that SIP plays a role in endothelial cell leukocyte interaction in that SIP induces expression of ceil adhesion molecules in human aortic endothelial cells, allowing monocytes and neutrophils to attach. These effects were blocked by pertussis toxin, suggesting the involvement of a Gi-coupled 31P receptor. The responsible SIP-receptor subtype, however, could not be identified and the EDG8 receptor was not included at the time of this study. Expression profiling of all EDG receptors in individual cell lines and the use of EDG receptor subtype selective compounds will clearly be necessary to help determine the role of the individual SIP receptors in endothelial cell signalling mechanisms.
Finally, the mapping of EDG receptors in genomic sequences allowed to derive the chromosomal localization for four genes of this family (Tab.1). Interestingly, so far, four

EDG-receptors including EDG8 are located on chromosome 19. In addition, the genomic sequence allowed the determination of the structure of the genes; the S IP-preferring receptors EDG1, 3, 5 and 8 are intronless as opposed to the LPA-preferring subtypes 2, 4 and 7, that contain an intron in the open reading frame in TMVI. These data suggest that in addition to the activating ligand and the degree of homology, the two subclasses of lysophospholipid receptors can be discriminated further by their genomic structure. The genomic structure of new potential EDG/LPA-receptor family members may also help predict the nature of the activating lipid ligand.
In conclusion, a new member of the EDG-family of G-protein coupled receptor, human EDG8, was isolated. This receptor functions as a cellular receptor for sphingosine 1-phosphate. EDG8 could exclusively be detected in peripheral tissues like skeletal muscle, heart and kidney and several human endothelial cell lines. It is conceivable that the expression in endothelial cells may account for the broad tissue distribution of this receptor. The existence of at least eight EDG-receptors for lysophospholipids suggests that receptor subtype selective agonists and antagonists will essentially be necessary for a better understanding of the biology of lysophospholipids and their respective receptors.
Figure legends
Fig.lA: The nucleotide and deduced amino acid sequence of human EDG8. The deduced amino acid sequence is shown below the nucleotide sequence with the nucleotide positions indicated on the left.
Fig. 1B: Phylogenetic tree of the EDG-family of receptors. The phylogenetic tree depicted was derived by the neighbor joining method method performed with the GCG program.
Fig.lC: Alignment of the amino acid sequence of human EDG8 with the other EDG-family members. The amino acid sequence of EDG8 is compared with the EDG1-7 polypeptides (EDG1: accession number M 31210, EDG2: accession number U 80811,

EDG3: accession number X 83864, EDG4: accession number AF 011466, EDG5: accession number AF 034780, EDG6: AJ 000479, EDG7: accession number AF 127138). The approximate boundanes of the seven putative transmembrane domains are boxed. Gaps are introduced to optimize the alignment. '
Fig.2A-F: Mobilization of intracellular Ca2+ by S1P (10, 100 and 1000 nM) mediated by the EDG1,3,5,6 and 8 receptor in CHO cells, cotransfected with empty vector DNA as a control or the indicated G-protein a subunits.
A: S1P-induced Ca2+'-response in CHO cells transfected with vector DNA alone or the
G protein a subunits Gq, G16 and Gqi5. B-F; SlP-induced Ca2+.response in CHO cells transfected with the indicated EDG-receptor subtypes. Agonist-mediated changes
of intracellular Ca2+ were measured with the FLIPR using the Ca2+-sensitive dye FLU04 as described in Experimental procedures. Fluorescence of transfected cells loaded with FLU04 was recorded before and after addition of S1P, applied in the indicated concentrations. Data are expressed as means of quadruplicate determinations in a single experiment. An additional experiment gave similar results.
Fig.3: Effects of S1P, LPA and related lysophospholipid mediators on EDGB-mediated
increase in intracellular Ca2+. CHO-cells were cotransfected with EDG8 and the G
protein a subunits Gqi5 (upper panel) and G16 (lower panel) and rises in [Ca2+]i were recorded with the FLIPR as described in Experimental procedures. The different lipids were applied in concentrations of 10,100 and 1000 nM, respectively. Data are means of quadruplicate determinations of a representative experiment. Two additional experiments gave similar results.
Fig.4: Northern blot analysis of EDG8 in human tissues. Poly(A)+ RNA (1pg) from various human tissues (human multiple tissue Northern blots, CLONTECH) was hybridized with probes specific to human EDG8 (upper panel) and S-actin (lower panel) on a nylon membrane. The origin of each RNA is indicated at the top, the molecular mass of standard markers in kilobases (kb) is shown on the left.

Fig.SA: Reverse transcriptase-polymerase chain reaction (RT-PCR) analysis of EDG8 in different human endothelial cell lines (HUVECS: human umbilical vein endothelial cells; HCAEC: human coronary artery endothelial cells; HMVEC-L; human microvascular endothelial cells from lung; HPAEC; human pulmonary artery endothelial cells). EDG8-specific transcripts were detected in all endothelial cell lines. Agarose gel electrophoresis of the PCR products after 35 cycles of amplification with the GC-melt kit (as described in Experimental Procedures) is shown. Amplification with EDG8-specific primers yields a 522 bp EDGB-fragment as indicated by the arrow. The EDG8 plasmid served as a template for the positive control, H2O was used instead of plasmid DNA as a negative control.
Fig.5B: PCR analysis of EDG8 primers for specificity of amplification of EDG8 sequences. Primers, specific for the EDG8 sequence, were checked for potential amplification of the related EDG1-7 sequences, using the respective plasmids as templates. Agarose gel electrophoresis of the PCR products after 35 cycles of amplification with the GC-me!t kit (as described in Experimental Procedures) is shown. The EDG8 specific 522 bp band occurred only when EDG8 was used as a template. H2O was used instead of plasmid DNA as a negative control.
Fig.6: Experiments were performed according to example 3. Instead of lipids, a lipid library was used.
Fig.6A+B: Library plattes with rat EDG8 (r EDG8) and qi5.
Fig.6A; qiS background.
Fig.6B: Measurement with rEDG8.
Fig.eC: Fluorescence change counts.
Fig.7: Experiments were performed according to example 3. Instead of Lipids, a lipid library was used.

Fig.7A+B: Library plates with human EDG8 (hEDG8) and qi5,
Fig.7A: q15 background.
Fig.TB: Measurement with hEDG8
Fig.7C: Fluourescence change counts.
Fig.8: Antagonism of S1P activation of rat and human EDG8.
Transiently transfected CHO cells expressing rat EDG8 and Gαqi5 (A) and HEK 293 cells expressing human EDG8 and Gαqi5 (B) were incubated with test compounds, namely , 0.1 μM Leukotriene B4, 1 pM 2-DHLA-PAF (1-0-Hexadecyl-2-0-dihomo-y-linolenoyl-sn-glycero-3-phophorylcholine), 1μM C2 Dihydroceramide, 0.1 μM 15(S) HEDE (15{S)-Hydroxyelcosa-11Z,13E-dienoic acid), 1μM PAF C16 (1-0-Hexadecyl-2-O-acetyl-sn-glycero-3-phosphorylcholine), IμM 16,16 Dimethyl PGE2(16,16-Dimethyl-Prostaglandin Ez) 12, 0.1 μM (R)-HETE (12(R)-Hydroxyeicosa-5Z,8Z,10E,14Z-tetraenioc acid), 1μM 8-epi-PGF2a (8epi-Prostaglandin Fza) 0.1 pM Leukotoxin A ((+) 9,10-EODE) or with solvent buffer for 3 min and then challenged with 1 pM SIP (sphingosine 1-phosphate). Peak fluorescence counts of cells prelncubated with solvent buffer and then stimulated with 1 pM SIP were set 100 %. Fluorescence change counts were recorded with the FLIPR as described in detail in Experimetal procedures. Data are means + SE of 2-3 independent experiments.
Fig.9: Inhibition of SIP mediated intracellular calcium release by suramin and NF023 (8,8'-(carbonylbis(imino-3,1-phenylene))bis-(1,3,5-naphatlenetrisulfonic acid)) in cells transiently cotransfected with with human EDG8 and Goqi5 (A) and rat EDG8 and Goqi5 (B). Transfected cells were first treated with the indicated concentrations of the
inhibitor or solvent buffer for 3 minutes (NF023 and suramin did not show any effect on
2+ [Ca mobilization during the preincubation period). Cells were then stimulated with

2+
1|JM S1P and in [Ca ],- measured with the FLiPR as described in the method section. Peak fluorescence counts were normalized and background responses of Gαqi5 -transfected cells were subtracted. S1P-mediated calcium release in the absence of inhibitor was set 100%. Data are means + SE of 4-7 independent experiments.
TABLE 1: Chromosomal localization, gene structure and accession number of the respective EDG genomic clones
Mapping of EDG receptors in genomic sequences allowed to derive a chromosomal assignment for EDG1, 2, 4-8. The chromosomal localization of EDG3 was obtained from Yamagutchi et al (1996). Genomic sequences also revealed EDG1, 3, 5, 6 and 8 to be unspliced as opposed to EDG2. 4 and 7, which contain an intron in their open reading frame (ORF).


Examples
Example 1; Molecular cioning of the human EDG8 receptor. As the putative human EDG8 sequence is intronless, we cloned the receptor from human genomic DNA (CLONTECH, Palo Alto, CA, 94303-4230) via polymerase chain reaction (PCR). PCR conditions, established to amplify the EDG8 sequence were 94X. 1 min followed by 35 cycles of 94"C. 30sec, 68C, 3 min, using GC-Melt Kit (CLONTECH, Palo Alto.CA). Primers designed to amplify the EDG8 sequence contained a Hindlll site in the forward, and a EcoRl site in the reverse primer, respectively. The 1197 bp PCR product was cloned into the pCDNA3.1(+) mammalian expression vector (Invitrogen, Carlsbad, California) and sequenced in both directions.
Example 2: Cell culture and Transfection.
CH0-K1 cells were grown in basal ISCOVE medium supplemented with 10% fetal bovine serum at 37°C in a humidified 5% C02 incubator. For transfections, 2x105 cells were seeded into 35-mm dishes. About 24 hr later cells were transiently transfected at 50-80% confluency with the indicated receptor and G-protein constructs (1pg of piasmid DNA each) using the Lipofectamine transfection reagent and the supplied protocol (GIBCO). 18-24 hr after transfection cells were seeded into 96well plates at a density of 50.000 cells per well and cultured for 18-24 additional hr until used in the functional FLIPR assays.
The cDNA for Gal 6 was cloned from TF1 cells by RT-PCR and ligated into the pCDNA1.1 mammalian expression vector (Invitrogen). Murine wild type Gaq was cloned from cells by RT-PCR and inserted into the BamHI-Nsil-sites of pCDNAI.1. To create the C-terminally modified Gαqi5 subunit, in which the last five aa of wt Gaq were replaced with the correspoding Ga,- sequence, a 175-bp Bglll-Nsil fragment was replaced, in a two piece ligation, with a synthetic DNA fragment, containing the desired codon changes. The correctness of all PCR-derived sequences was verified by sequencing in both directions.
Example 3: Fluorometric Imaging Plate Reader (FLiPR) Assay.

Twenty-four hours after transfection, cells were splitted into 96-well. black-wall microplates (Corning) at a density of 50,000 cells per well. 18-24 hr later, cells were loaded with 95μ| of HBSS containing 20 mM Hepes, 2.5 mM probenecid, 4ΜM fluorescent calcium indicator dye Fluo4 (Molecular Probes) and 1% fetal bovine serum for 1 h{37°C, 5% CO2). Cells were washed three times with HBSS containing 20 mM Hepes and 2.5 mM probenecid in a cell washer. After the final wash, the solution was aspirated to a residual volume of 100μl per 96 well. Lipid ligands were dissolved in DMSO as 2 mM stock solutions (treated with ultrasound when necessary) and diluted at least 1:100 into HBSS containing 20 mM HEPES, 2,5 mM probenecid and 0.4 mg/ml fatty acid free bovine serum albumine. Lipids were aliquoted as 2X solutions into a 96 well plate prior to the assay. The fluorometric imaging plate reader (FLIPR, Molecular Devices) was programmed to transfer 100 pi from each well of the ligand microplate to each well of the cellplate and to record fluorescence during 3 min in 1 second intervals during the first minute and 3 second intervals during the last two minutes. Total fluorescence counts from the 18-s to 37-s time points are used to determine agonist activity. The instrument software normalizes the fluorescent reading to give equivalent initial readings at time zero.
Example 4: Northem Blot analysis.
Human multiple tissue Northern blots were purchased from CLONTECH (Palo Alto, CA, 94303-4230, USA) antisense RNA probes were generated by subcloning nucleotides 279-1197 of the coding region into the Bam Hi-Eco Rl sites of the expression vector PSPT18 (Roche Diagnostics, Mannheim, Germany) and subsequent random priming with a DIG-RNA Labeling kit (Roche Diagnostics, Mannheim, Germany), using T7 RNA polymerase. Hybridization was carried out at 68°C for 16 h in hybridization buffer (Dig Easy Hyb Roche Diagnostics, Mannheim, Germany). Each blot was washed , blocked and detected as indicated in the standard protocol with the DIG Wash and Block Buffer set (Roche Diagnostics, Mannheim, Germany) and treated with 1 ml CSPD ready-to-use(Roche Diagnostics, Mannheim, Germany) for 15 min , 37°C and developed for 5 min on the Lumiimager (Roche). Finally, each blot was

stripped (50 % formamid,5% SDS, 50 mM Tris/HCI pH 7,5 ; 80°C, 2x 1 hour) and rehybridized with a GAPDH antisense RNA probe as an internal standard.
Example 5; RNA Extraction and RT-PCR.
RNA was prepared from different endothelial cell lines (HUVECS, HCAEC, HMVEC-L, HPAEC) using the TRlzol reagent (Hersteller, Lok.). Briefly, for each endothelial cell line, cells of a subconfluent 25 cm2 tissue culture flask were collected in 2,5ml TRlzol and total RNAs were extracted according to the supplied protocol. The purity of the RNA preparation was checked by veryfying the absence of genomic DNA. An aliquot of RNA, corresponding to ~5(jg, was used for the cDNA generation using MMLV reverse transcriptase and the RT-PCR kit from STRATAGENE. RT-PCR was carried out in a volume of 50 pi, the RT-PCR conditions were set to 65°C for 5 min, 15min at RT, 1 hour at 37°C, 5 min at 90°C, chill on ice.
The cDNA templates for the PCR reactions (35 cycles of 94°C for 30 sec, 68'C for 3 min) were the reverse transcribed products of RNAs isolated from human endothelial cell lines (HUVECS,HCAEC, HMVEC-L, HPAEC). Typically. 1-5 μl of reverse transcribed cDNAs were used as templates for the PCR reactions.
Example 6; Sources of materials.
1-oleoyl-LPA, sphlngosin 1-phosphate (S1P), dihydrosphingosin 1-phosphate (DHS1P), lysophosphatidylcholine (LPC), sphingosylphosphorylcholine (SPC) and fatty acid free BSA were from SIGMA (P.O.Box 14508, St. Louis, Missouri 63178). CH0-K1 cells were obtained from the American Type culture collection (ATCC, Manassas, Virginia), cell culture media and sera from GIBCO BRL (Gaithersburg, MD), the Ca fluorescent dye FLU04 and pluronic acid from Molecular devices (Sunnyvale CA 94089-1136, USA) human northern blot membrane from CLONTECH (1020 East Meadow Circle, Palo Alto, California 94303-4230, USA.), commercially available cDNAs (heart, fetal heart, left atrium, left ventricle, kidney, brain, liver, lung, aorta) from Invitrogen, oligonucleotides from MWG-Biotech AG (Ebersberg, Germany), the RT-PCR kit from SIGMA, the GC-melt PCR kit from Clontech (Palo Alto, CA), the expression plasmid pcDNA3.1 for EDG8 and pCDNALI for expression of G-protein a

subunitsfrom Invitrogen (Carlsbad, CA 92008), competent DHSafrom GIBCO and MC 1063 from Invitrogen.
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List of non-standard abbreviations:
SIP, sphingosine 1-phosphate; LPA. lysophosphatidic acid; dHS1P, dihydro sphingosine 1-phosphate; SPC, sphingosylphosphoryicholine; LPC, lysophosphatidylcholine; GPCR, G-protein-coupled receptor; G-protein, guanine nucleotide-binding protein; [Ca^""],-, intracellular Calcium concentration, RT-PCR, reverse transcription polymerase chain reaction; bp, base pair; ORF, open reading frame; EST, expressed sequence tag; FAF-BSA, fatty acid free bovine serum albumine; HUVECS. Human umbilical vein endothelial cells; HCAEC, human coronary artery endothelial cells; HMVEC-L, human microvascular endothelial cells from lung; HPAEC, human pulmonary artery endothelial cells.
Table 2:
SEQ ID NO. 1: Nucleotide sequence of human EDG8







Claims:
1. An isolated polynucleotide comprising a nucleotide sequence that has at least
90 % identity to a nucleotide sequence encoding the polypeptide of SEQ ID NO. 2 or the corresponding fragment thereof; or a nucleotide sequence complementary to said nucleotide sequence.
2. The polynucleotide of claim 1 which is DNA or RNA.
3. The polynucleotide of claim 1 or 2, wherein said nucleotide sequence is at least 90 % identical to that contained in SEQ ID NO. 1,
4. The polynucleotide of claim 3 wherein said nucleotide sequence is contained in SEQ ID NO. 1.
5. The polynucleotide with sequence SEQ ID NO. 1.
6. The polynucleotide as claimed in claims 1 to 5, wherein said encoding nucleotide sequence encodes the polypeptide of SEQ ID NO, 2 or a fragment thereof.
7. The polynucleotide as claimed in claims 1 to 6 having almost the same biological functionality as EDG8.
8. EDG8 DNA or RNA molecule comprising an expression system wherein said expression system is capable of producing a polypeptide or a fragment thereof having at least 90 % identity with a nucleotide sequence encoding the polypeptide of SEQ ID NO. 2 or said fragment when said expression system is present in a compatible host cell.
9. A host cell comprising the expression system of claim 8.

10. A process for producing an EDG8 polypeptide or fragment comprising culturing a host cell as claimed in claim 9 under conditions sufficient for the production of said polypeptide or fragment.
11. The process of claim 10 wherein said polypeptide or fragment is expressed at the surface of said cell.
12. Cells produced by the process of claim 11.
13. The process of claim 10 which further includes recovering the polypeptide or fragment from the culture.
14. A process for producing a cell which produces a EDG8 polypeptide or a fragment thereof comprising transforming or transfecting a host cell with the expression system as claimed in claim 8 such that the host cell, under appropriate culture conditions, produces a EDG8 polypeptide or fragment.
15. EDG8 polypeptide or a fragment thereof comprising an amino acid sequence which is at least 90 % identical to the amino acid sequence contained in SEQ ID NO. 2.
16. Polypeptide of claim 15 which comprises the amino acid sequence of SEQ ID NO. 2, or a fragment thereof.

17. EDG8 Polypeptide or fragment prepared by the method of claim 13.
18. A process for diagnosing a disease or a susceptibility to a disease related to expression or acitivity of EDG8 polypeptide comprising:

a) determining the presence or absence of mutation in the nucleotide sequence encoding said EDG8 polypeptide in the genome of said subject; and/or
b) analyzing for the presence or amount of the EDG8 polypeptide expression in a sample derived from said subject.

19. A method for identifying compounds which bind to EDG8 polypeptide comprising:
a) tacting a cell as claimed in claim 12 or a part thereof with a candidate compound; and
b) assessing the ability of said candidate compound to bind to said cells.

20. The method as claimed in claim 19 which further includes determining whether the candidate compound effects a signal generated by activation of the EDG8 polypeptide at the surface of the cell, wherein a candidate compound which effects production of said signal is identified as an agonist.
21. The method as claimed In claim 19 which further includes determining whether the candidate compound effects a signal generated by activation of the EDG8 polypeptide at the surface of the cell, wherein a candidate compound which effects production of said signal is identified as an antagonist.
22. An agonist Identified by the method of claim 20.

23. An antagonist identified by the method of claim 21.
24. The method of claim 19 which further includes contacting said ceil with a known agonist for said EDG8 polypeptide; and determining whether the signal generated by said agonist is diminished in the presence of said candidate compound, wherein a candidate compound which effects a diminution in said signal is identified as an antagonist for said EDG8 polypeptide.
25. A method as claimed in claim 24, wherein the known agonist is SIP, LPA and/or DHS1P.

26. An antagonist identified by the method of claim 24 or 25.
27. Method of preparing a phannaceutical composition comprising

a) identifying a compound which is an agonist or an antagonist of EDG8,
b) preparing the compound, and
c) optionally mixing the compound with suitable additives.

28. Pharmaceutical composition prepared by a process of claim 27.
29. Phamnaceutical composition containing an EDG8 polypeptide or a part tliereof having EDG8 functionality.
30. Pharmaceutical composition containing a polynucleotide encoding for EDG8 or a part thereof encoding for a peptide with EDG8 functionality.

31. An isolated polynucleotide substantially as herein described with reference to the accompanying drawings.


Documents:

in-pct-2002-1734-che-abstract.pdf

in-pct-2002-1734-che-claims filed.pdf

in-pct-2002-1734-che-claims granted.pdf

in-pct-2002-1734-che-correspondnece-others.pdf

in-pct-2002-1734-che-correspondnece-po.pdf

in-pct-2002-1734-che-description(complete)filed.pdf

in-pct-2002-1734-che-description(complete)granted.pdf

in-pct-2002-1734-che-drawings.pdf

in-pct-2002-1734-che-form 1.pdf

in-pct-2002-1734-che-form 26.pdf

in-pct-2002-1734-che-form 3.pdf

in-pct-2002-1734-che-form 5.pdf

in-pct-2002-1734-che-other document.pdf


Patent Number 209512
Indian Patent Application Number IN/PCT/2002/1734/CHE
PG Journal Number 50/2007
Publication Date 14-Dec-2007
Grant Date 04-Sep-2007
Date of Filing 22-Oct-2002
Name of Patentee M/S. SANOFI-AVENTIS DEUTSCHLAND GMBH
Applicant Address Bruningstrasse 50 65929 Frankfurt
Inventors:
# Inventor's Name Inventor's Address
1 KOSTENIS, Evi Deutschherrenufer 35 60594 Frankfurt am Main
PCT International Classification Number C07K 14/705
PCT International Application Number PCT/EP2001/004283
PCT International Filing date 2001-04-14
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 00108858.2 2000-04-26 EUROPEAN UNION
2 00116589.3 2000-08-01 EUROPEAN UNION