Title of Invention

"FUSION PROTEIN HAVING ENHANCED IN VIVO ACTIVITY OF ERYTHROPOIETIN"

Abstract This invention relates to a fusion protein having enhanced in vivo activity of human erythropoietin (EPO) and consisting of the amino acid sequence of SEQ ID No. 4, wherein a carboxy terminal peptide (CTP) of thrombopoietin (TPO) is fused with human EPO at the carboxy terminus thereof.
Full Text FUSION PROTEIN HAVING ENHANCED IN VIVO ACTIVITY OF ERYTHROPOIETIN
TECHNICAL FIELD
The present invention relates to a fusion protein having enhanced in vivo activit}' of erythropoietin (EPO, below) that is a new medicine for the treatment of anenna. Specifically, the present invention relates to a fusion protein having highly enhanced in vivo half-life and activity of erythropoietin by fusion of EPO molecule with a certain peptide that has half-life elongation activity and is derived fi-om the human body.
BACKGROUND ART
EPO, a glycoprotein having the molecular weight of 30,000 to 34,000, is a factor that stimulates production and differentiation of red blood cells. This protein acts by binding to receptors on erythrocyte precursor cells to result in increase of calcium ion concentration in a cell, increase of DNA biosynthesis, and stimulation for the formation of hemoglobin and the like. This EPO can be used for the treatment of anemia frorn renal failure, anemia of a premature baby, anemia from hypothyroidism, anemia from malnutrition, etc. The clinical use of recombinant human EPO is on the increase. However, such use may cause some inconvenience and high costs because it should be administered on the average three times a week due to its short half-life. Thus, if the in vivo activity of EPO is maintained for a long time, the administration frequency of EPO may be greatly decreased.
Efficacy of EPO is proportional to in vivo half-life thereof It is knowz. that in vivo half-life of EPO is correcated to the content of sialic acid that is located at the of carbohydrate chains of EPO. Therefore, efficacy of EPO is highly dependen on the
presence of carbohydrate chains. Since the forms of carbohydrates appear differently depending on the kind of cells where EPO is expressed, the same glycoproteins may have different carbohydrate structure if they are expressed in different cells. Although it has been recently demonstrated that some bacteria can attach the carbohydrate chains, typical bacteria, for example K coli, are known not to do. Proteins expressed in E. coli do not contain the carbohydrate chains, and thus, E. coli-derived EPO, which does not contain the carbohydrate chains, exhibits positive in vitro activity but no in vivo activity. It is because deglycosylated EPO is rapidly eliminated from the human body and has extremely short half-life, ha conclusion, the carbohydrate chains play a very important role in the activity of EPO.
Many studies have been made to enhance the activity of EPO. The main approach is substitutions of some amino acids of EPO by mutagenesis on the EPO gene. For example, PCT/US94/09257, filed by Amgen and titled "Erythropoietin analogs," discloses a method to increase in vivo half-life of EPO by increasing the carbohydrate contents through mutagenesis. Also, an attempt to increase in vivo half-Ufe of EPO was made by formation of EPO dimer. See, A. J. Sytkowski et al., J.B.C. vol. 274, No. 35, pp24773-24778. Besides, another known method is to enhance in vivo activity of EPO by fiising new amino acids, peptides, or protein fragments with EPO_ molecule in the genetic engineering manner and increasing the carbohydrate content, i.e., sialic acid content of EPO. However, ail amino acids, peptides, or heterogeneous protein fragments may not be used for this purpose. In most cases, such modifications may result in decrease or loss of inherent activity of protein and may cause a problem of antigenicity when used in vivo.
Although it is not related to EPO, fusion proteins or chimeric proteins have been studied, for example. for follicle stimulating hormone that is a kind of sex hormone. See, Furuhashi et al., 1995, Mol. Endocrinol. However, the methods have not been applied to the industry since protein modifications using a genetic enginesing method have many risks. Th2i ic in most cases, the target protein may not be remusally obtained without professiona. stalls, and on the contrary, the inherent activity of pr may be decreased or lost bv the add substitution of new amino acids.
DISCLOSURE OF THE INVENTION
The present inventors have extensively studied new methods for enhancing in vivo activity of EPO by fusing new amino acids, peptides, or protein fragments with EPO molecule, and so increasing "the carbohydrate content thereof As a result, the present inventors have discovered that a fusion protein of EPO obtained by fusing a carboxy teiminal peptide (CTP, below) of thrombopoietin (TPO, below), a protein that afready exists in the human body, with the carboxy terminal of EPO has highly enhanced in vivo half-life due to a lot of amino acids that increase glycosylation site without loss of the inherent activity of EPO, and does not cause any antigenicity when applied to the human body. Then, the present inventors have completed the present invention.
Therefore, the object of the present invention is to provide a fusion protein having enhanced in vivo activity of human EPO and containing CTP of TPO fused with human EPO at the carboxy terminal thereof
Another object of the present invention is to provide a nucleic acid encoding the fusion protein, a recombinant vector containing the nucleic acid, and a host cell line transfcrmed with the recombinant vector.
Further object of the present invention is to provide a process for preparation of the fusion protein having enhanced in vivo activity of human EPO by cultivating the transformed cell line.
First, the present invention relates to a fusion protein having enhanced in vivo art;vr> .^f human EPO and containing CTP of TPO fused with human EPO at the carboxy "li-nina' thereof The CTP preferably comprises the acids sequence of SEQ ID No. 1 :l~-i: corresponds to amino acids of positions 176 tc 353 (LT?, beiow) or parts thereof p.r-:-.c".:Li.-H' the amino acid sequence of SEQ ID No. 2 rr_L- -?—esponds to amino acids of posiiions 337 to 353 (STP, below).
Particularly, the fusion protein according to the present invention may comprise the amino acid sequence of SEQ ID No. 3 or 4.
Second, the present invention relates to a nucleic acid encoding the fusion protein, a recombinant vector containing the nucleic acid, and a host cell line, preferably CHO (Chinese hamster ovary) cell, transformed with the recombinant vector.
Third, the present invention relates to a process for preparation of the fusion protein having enhanced in vivo activity of human EPO by cultivating the transformed cell line.
Below, the present invention will be explained in more detail.
BRIEF DESCRIPTION OF THE DRAWINGS
Figures la and lb show the nucleotide and amino acid sequences of carboxy terminal peptides (LTP, STP) of TPO;
Figures 2aa and 2ab show the nucleotide and amino acid sequences of ELTP that is a fusion protein of EPO and the peptide LTP, and Figure 2b shows the nucleotide and amino acid sequences of ESTP that is a fusion protein of EPO and the peptide STP;
Figures 3a and 3b are schemes showing the procedures to prepare the expression vectors, pcDNA-ELTP and pcDNA-ESTP;
Figure 4 is an electrophoresis photograph of expressed ELTP and ESTP; and
Figure 5 is a graph showing the pharmacokinetic results of EPO, ELTP, and ESTP.

BEST MODE FOR CARRYING OUT THE INVENTION
The present invention comprises the steps of preparation and cloning of a gene of the desired fusion protein, construction of an expression vector containing the desired gene, transformation of an animal cell, expression, purification, and biological assay.
(1) Preparation of gene
EPO cDNA may be obtained by performing the conventional PCR technique (PCR PreMix Kit of Bioneer Co.) using the complementary primers of EPO cDNA terminals (EPl and EP2) from cDNA library of human-derived fetal liver (Invitrogen Co.). TPO cDNA may be obtained using the complementary primers of TPO cDNA terminals (Tl and T2) according to the same manner.
EPl: ATGGGGGCACGAATGTCCTGCCTGGCTGG (SEQ ID No. 5)
EP2: GTCCCCTGTCCTGCAGGCCT (SEQ ID No. 6)
Tl: ATGGATCTGACTGAATTGCTCCTC (SEQ ID No. 7)
T2: TTACCCTTCCTGAGACAGATTCTGGGA (SEQ ID No. 8)
EPO cDNA and TPO cDNA obtained by PCR are cloned to pGEM-T (Promega Co.), a cloning vector, respectively. The pGEM-EPO and pGEM-TPO are then sequenced, and used as a template for the following procedures.
LTP, a CTP gene of TPO used in the present invention, may be obtained by performing PCR using pGEM-TPO as a template and primers ELI and T2.
ELI: GAGGCCTGCAGGACAGGGGACGCCCCACCCACCACAGCTGTCC (SEQ ID No. 9)
The primer ELI contains a gene extended to the position of restriction enzyme
StuI, which is located near the 3' terminal of EPO, and a part of 5' terminal of LTP gene (amino acids of positions 176 to 353 of TPO) at the same time. On the other hand, PCR is performed using pGEM-EPO as a template and primers EPl and EP2 to give EPO gene only. Thus obtained EPO and LTP genes are treated with restriction enzyme StuI, respectively. Then, fragments of EPO and LTP genes are ligated and the ligation product is used as a template in the PCR procedure using primers EPU and L2 to give a gene fragment ELTP having about 1113 bps.
EPll: TAAGCTTATGGGGGTGCACGAATGT (SEQ ID No. 10) L2: TGGATTCTTACCCTTCCTGAGACAGATTC (SEQ ID No. 11)
This gene is cloned to a cloning vector of pGEM-T and then sequenced (pGEM-ELTP, Figure 3a).
Further, the STP gene used in the present invention may be obtained by synthesis and self-priming PCR procedure. Synthesized gene fragments are the following ESI, S2, S3 and the above L2.

12)

ESI: AGGGGAGGCCTGCAGGACAGGGGACCCTCTTCTAA (SEQ ID No.
S2: GTGGGTGTAGGATGTGTTTAGAAGAGG (SEQ ID No. 13) S3: TACACCCACTCCCAGAATCTGTCTC (SEQ ID No. 14)

1 µl (50 pmole/µl) of each 4 gene fragments is taken and PCR is performed using high fidelity Taq system of BM Co.
The gene fragment of about 50 bps (STP gene) is identified in 1% agarose gel. This gene encodes the 17 amino acids (amino acids of positions 337 to 353) of the carboxy terminal of TPO (Figure 1).
PCR is performed using pGEM-EPO as a template and primers EPl 1 and EP2 to give EPO gene only. This EPO gene and the STP gene are used as templates at the same
time and primers EPl 1 and L2 are used in a PCR using the high fidelity Taq system of BM Co. to give the desired fusion gene, ESTP gene, of about 630 bps. This gene is cloned to pGEM-T, a cloning vector, and then sequenced (pGEM-ESTP, Figure 3b).
(2) Construction of expression vector
pcDNA3.1 vector of Invitrogen Co. is used as an expression vector.
The pcDNAB.l vector is treated with restriction enzymes Hindul and BamHl to make a linear vector, and pGEM-ELTP and pGEM-ESTP are also treated with the same restriction enzymes, Hind III and Bam III, respectively. The digested pcDNA3.1, ELTP, and ESTP genes are isolated using Qiagen extraction kit on agarose gel. After each ligation of the genes, the ligation product is introduced into E. coli NM522. Plasmids are isolated from the colonies that have been formed from cultivation of the fransformed E. coli in LB-ampicillin plate overnight, and are freated with restriction enzymes, Hindlll and BamRl. Colonies having ELTP or ESTP gene are then screened by 1% agarose gel electrophoresis. These plasmids are designated as pcDNA-ELTP and pcDNA-ESTP, respectively (Figures 3a and 3b).
(3) Transformation of CHO cell and expression
CHO cells (DG44) are cultivated to a confluency of 40-80% (l~4xl05 cells/60mm dish) in a 60mm cell culture dish. 3µ£ of superfection reagent (BM Co.) and 97µ£ of cell culture medium (a-MEM with media, no serum, no antibiotics) are mixed well, and pcDNA-ELTP (=0.1µg/µl, about 2µg) and vector pLTRdhfr26 (ATCC37295, O.2µg) having dhfr gene are added thereto. The mixture is reacted for 5~10 minutes at room temperature and then added to the cells as prepared above. After one day, the rricdium is refreshed with a medium containing G418 m an amount of 500µg/µl (a-MEM without media, 10% PBS). The medium is then refreshed with the G418 medium containing 500fig/vtil of G418 for 7-10 days, during which cells without G418 resistance gene and negative control cells are completely killed. Selected cells on G418 medium are cultivated sufficiently and an expressed ELTP protein is identified using EPO ELISA kit of
BM Co. The same process is applied to ESTP expression vector and then an expressed ESTP fusion protein is also identified in the same manner.
(4) Purification of the expressed ELTP and ESTP
Affinity resin for isolation and purification is prepared using anti-EPO monoclonal antibody (R&D Co.) as follows:
0.3g of CNBr-activated Sepharose 4B is swelled for 20 minutes in ImM HCl, and the resin is moved to a column and washed with ImM HCl. The resin is washed with 4ml of coupling buffer (O.IM NaHCO3, 0.5M NaCl, pH 8.3), immediately mixed with anti-EPO monoclonal antibody (500µg/vial) contained in 4ml of coupling buffer, and reacted for 2 hours at room temperature with stirring the tube. Refreshed with blocking buffer (0.2M glycine, pH 8.0), the resin is reacted at room temperature for 2 hours with stirring the tube. Then, the resin is washed with 6.5ml of coupling buffer, 6.5ml of acetate buffer (O.IM acetic acid, 0.5M NaCl, pH 4), and 6.5ml of coupling buffer in the order. A column is prepared using such obtained resin and purification is conducted as described below.
Cells are cultivated in serum free medium for one day, and the medium is concentrated to about 5 folds using Centriprep (Millipore MWCO 10,000). This concentrate is loaded to a column equilibrated in advance with PBS at a flow rate of 20ml/hr, and washed again with PBS. Elution buffer (O.IM glycine, pH 2.8) is applied to the column and the eluent is immediately tifrated with IM Tris to pH7.5. The purity is at least 97% when analyzed by SDS-PAGE and silver staining (Figure 4).
(5) Activity measurement by bioassay method
In the bioassay test using mouse spleen cells treated with phenylhydrazme, the ELTP and ESTP, which are expressed and properly purified, show higher activity than EPO. It demonstrates that the fused carboxy terminals in the ELTP and ESTP may not inhibit activity of EPO itself.
(6) Pharmacokinetic experiments
Pharmacokinetic experiments are performed to mice to determine whether the prepared ELTP and ESTP actually have prolonged in vivo half-life. The candidate substance is intravenously administered to 4 mice in an amount of 20 units/mouse. In order to identify the time-lapse concentration in blood, blood is taken from the mice at an interval of 30 minutes and concentrations are measured using EIA kit of Boehringer Mannheim Co. In the pharmacokinetic experiments to mice, the candidate substances, ELTP and ESTP, show far longer half-hfe than the control EPO (Figure 5).
The present invention will be more specifically explained in the following examples. However, it should be understood that the following examples are intended to illustrate the present invention but not to limit the scope of the present invention in any manner.
Example 1: Preparation of gene
EPO cDNA was obtained by performing the conventional PCR (PCR PreMix Kit of Bioneer Co.) using the primers EPl and EP2 that are complementary to the terminals of EPO CDNA, in an amount of 50 pmole, respectively, frorh cDNA library of human-derived fetal liver (Invitrogen Co.). TPO cDNA was obtained using the primers Tl and T2, complementary to the terminals of TPO cDNA, according to the same manner. Total 30 cycles of PCR were performed using high fidelity Taq system of BM Co. under the condition of 52'C for 40 seconds for annealing, 72°C for 55 seconds, and 94°C for 20 seconds to give EPO cDNA and TPO cDNA. They were cloned to pGEM-T (Promega Co.), a cloning vector, respectively. That is, the PCR products were eluted from 1% agarose gel and ligated into pGEM-T, which was then introduced into E. coli NM522. The transformed E. coli was cultivated overnight in LB-ampicillin piate containing X-gal/IPTG. Plasmids were purified from the white colonies and treated with restnction enzymes, Sac I and SacII, to screen the colonies containing the respective cDNAs. The vectors obtained at this stage were designated as pGEM-EPO and pGEM-TPO, which were then sequenced, and used as templates for the following procedures.
LTP, CTP gene of TPO used in the present invention, was obtained by performing total 30 cycles of PCR using the high fidelity Taq system of BM Co. and using pGEM-TPO as a template and primers, ELI and T2 (50 pmole), under the condition of 50'C for 40 seconds for annealing, 12°C for 45 seconds, and 94°C for 20 seconds. The primer ELI contains a gene from the position of restriction enzyme Stul, which is located near the 3' terminal of EPO, to the 3' terminal, and a part of 5' terminal of LTP gene at the same time. A gene fi-agment of about 534 bps was identified on 1% agarose gel (LTP gene). This gene encodes the 178 amino acids of the carboxy terminal of TPO (amino acids of positions 176 to 353) (Figure 1).
On the other hand, PCR was performed using pGEM-EPO as a template and primers EPl and EP2 to give EPO gene only.
Thus obtained EPO and LTP genes were treated with restriction enzyme Stul, respectively. Then, fragments of EPO and LTP genes were purified by Qiagen extraction kit and ligated with a ligase. The ligation product of EPO and LTP genes was used as a template in total 30 cycles of PCR procedure using primers EPl 1 and L2 (50 pmole) and using the high fidelity Taq system of BM Co. under the condition of 55°C for 40 seconds for annealing, 72°C for 60 seconds, and 94°C for 20 seconds to give the desired fiision gene of ELTP having about 1113 bps. This gene was cloned to a cloning vector of pGEM-T in the same manner as above and then sequenced (pGEM-ELTP, Figure 3a).
STP gene was obtained by synthesis and self-priming PCR procedure. Synthesized DNA fragments were ESI, S2, S3 and L2. lµl (50 pmole/µl) of each of the 4 DNA fragments was taken and total 15 cycles of PCR were performed using the high fidelity Taq system of BM Co. under the condition of 55°C for 40 seconds for annealing, 72"C for 40 seconds, and 94°C for 20 seconds. A gene fragment of about 50 bps was identified on 1% agarose gel (STP gene). Tnis gene encodes the 17 amino acids of the carboxy terminal of TPO (amino acids of positions 337 to 353) (Figure 1).
PCR was performed using pGEM-EPO as a template and primers EPl 1 and EP2 in
the same manner as above to give EPO gene only. This EPO gene and the STP gene were used as templates at the same time and primers of EPl 1 and L2 were used in total 30 cycles of PCR using high fidelity Taq system of BM Co. under the condition of 58'C for 40 seconds for annealing, 72°C for 50 seconds, and 94°C for 20 seconds to give the desired fusion gene, ESTP gene, of about 630 bps. This gene was cloned to pGEM-T, a cloning vector, and then sequenced (pGEM-ESTP, Figure 3b).
Example 2: Construction of expression vectors pcDNA-ELTP and pcDNA-ESTP
pcDNA3.1 vector of Invifrogen Co. was used as an expression vector. ELTP and ESTP genes that are cloned to pGEM-T vector contain Hindlll and BamHl recognition sites at terminals, respectively. pcDNA3.1, pGEM-ELTP and pGEM-ESTP were treated with restriction enzymes, Hindlll and BamHl, respectively. The linearized pcDNA3.1, ELTP, and ESTP genes were isolated using Qiagen extraction kit on agarose gel. After ligation of pcDNA3.1 with ELTP or ESTP, the ligation product was introduced into E. coli NM522. Plasmids were isolated from the colonies that had been formed from cultivation of the transformed E. coli in LB-ampicillin plate overnight, and were treated with restriction enzymes, Hindlll and BamHl. Colonies having ELTP or ESTP gene were then screened by 1% agarose gel electrophoresis. These plasmids were designated as pcDNA-ELTP and pcDNA-ESTP, respectively (Figure 3).
Example 3: Transformation of CHO cell and expression
CHO cells (DG44) were cultivated to a confluency of 40-80% (1-4x10^ cells/60mm dish) in a 60mm cell culture dish. 3µl of superfection reagent (BM Co.) and 91 id. of ceil culture medium (a-MEM with media, no serum, no antibiotics) were mixed well, and plasmid pcDNA-ELTP (=0.1µg/µl, about 2µg) and vector pLTRdhfi-26 (ATCC37295, 0.2µg) having dhfr gene were added thereto. The mixture was reacted for 5~I0 minutes at room temperature and then added to the cells as prepared above. After one day, the medium was refreshed with a medium containing G418 in an amount of 500µg/µl (a-MEM without media, 10% FBS). The medium was then refreshed with the
G418 medium containing 500/ig/rai of G418 for 7-10 days, during which cells without G418 resistance gene and negative control cells were completely killed. Selected cells on G418 medium were cultivated sufficiently and an expressed ELTP protein was identified using EPO ELISA kit of BM Co. The same process was applied to pcDNA-ESTP.
Example 4: Purification of the expressed fusion proteins
Affinity resin for isolation and purification was prepared using anti-EPO monoclonal antibody (R&D Systems Co.) as follows:
0.3g of CNBr-activated Sepharose 4B was swelled for 20 minutes in ImM HCl, and the resin was moved to a column and washed with ImM HCl. The resin was washed with 4ml of coupling buffer (O.IM NaHCOj, 0.5M NaCl, pH 8.3), immediately mixed with anti-EPO monoclonal antibody (500µg/vial) contained in 4ml of coupling buffer in a tube, and reacted for 2 hours at room temperature with stirring the tube. Refreshed with blocking buffer (0.2M glycine, pH 8.0), the resin was reacted at room temperature for 2 hours with stirring the tube. Then, the resin was washed with 6.5ml of coupling buffer, 6.5ml of acetate buffer (O.IM acetic acid, 0.5M NaCl, pH 4), and 6.5ml of coupling buffer in the order. A column was prepared using such obtained resin and purification was conducted as described below.
Cells were cultivated in serum free medium for one day, and the medium was concentrated to about 5 folds using Centriprep (Millipore, MWCO 10,000). This concentrate was loaded to a column equilibrated in advance with PBS at a flow rate of 20ml/hr, and washed again with PBS. Elution buffer (O.IM glycine, pH 2.8) was applied to the column and the eluent was immediately titrated with IM Tris to pH 7.5. SDS-PAGE results of the purified ELTP and ESTP are shown in Figure 4. The purity was at least 97% when analyzed by SDS-PAGE and silver staining.
Example 5: Activity measurement by bioassay method
Phenylhydrazine was injected to a mouse once a day for 2 days at a dose of
60mg/kg. After 3 days, enlarged spleen was separated and ground with a homogenizer to obtain spleen cells. The spleen cells were diluted to 6x10* cells/ml and 100µ,l of the cell solution was introduced into each well of a 96 well plate. 0-500 mU/ml of authentic EPO and 100 mU/ml of the expressed fusion protein were added to each well, and the plate was allowed to stand at 37oC for 22 hours in a CO2 incubator. 50µl of dimethyl 3[H]-thymidine (20µCi/ml) was added to each well, further reacted for 2 hours in the same incubator, and the reaction solution was then adsorbed onto a glass filter (Nunc 1-73164) per each well. The filters were washed with physiological saline 3 times and the amount of radioactivity of each filter was measured using p counter. The activities of the fusion proteins, ELTP and EST? were shown to be comparable to or higher than that of authentic EPO, which demonstrated that the carboxy terminals fused into EPO did not inhibit activity of EPO itself.
Example 6: Pharmacokinetic experiments
Pharmacokinetic experiments were performed to mice to determine whether the prepared candidate substance actually has prolonged in vivo half-life. The fusion protein purified according to the process of Example 5 was intravenously administered to 4 mice in an amount of 20 units/mouse. In order to identify the time-lapse concentration in blood, blood was taken from the mice at an interval of 30 minutes and concentrations were measured using EIA kit of Boehringer Mannheim Co. The results are shown in Figure 5. As can be seen from Figure 5, ELTP and ESTP show about three times longer half-life than the control, EPO, respectively (half-life of EPO was 22 minutes, that of ELTP was 60 minutes, and that of ESTP was 57 minutes).
INDUSTRIAL APPLICABILITY
The fusion proteins according to the present invention have highly increased in vivo half-life of EPO due to the presence of amino acids that increase the carbohydrate chains without influencing the inlierent activity of EPO. Further, the fusion proteins do not
cause any problem of antigenicity when applied to the human body since the fused peptide, LTP or STP, is a peptide that already exists in the body.














We Claim:
1. A fusion protein having enhanced in vivo activity of human erythropoietin (EPO) and consisting of the amino acid sequence of SEQ ID No. 4, wherein a carboxy terminal peptide (CTP) of thrombopoietin (TPO) is fused with human EPO at the carboxy terminus thereof.
2. A nucleic acid encoding the fusion protein as claimed in claim 1,
3. A process for preparation of a fusion protein having enhanced in vivo activity of human EPO comprising

a) introducing the nucleic acid according to claim 2 into a vector to obtain a recombinant vector;
b) transforming a host cell line with the recombinant vector to obtain a transformant; and
c) cultivating the transformant.
4. A fusion protein substantially as herein described with reference to the foregoing description, tables and the accompanying drawing.

Documents:

813-DEL-2002-Abstract-(17-09-2010).pdf

813-DEL-2002-Abstract-(20-05-2011).pdf

813-del-2002-abstract.pdf

813-del-2002-assignment.pdf

813-DEL-2002-Claims-(17-09-2010).pdf

813-DEL-2002-Claims-(20-05-2011).pdf

813-del-2002-claims.pdf

813-DEL-2002-Correspondence Others-(20-05-2011).pdf

813-DEL-2002-Correspondence-Others-(14-07-2010).pdf

813-DEL-2002-Correspondence-Others-(17-09-2010)--.pdf

813-DEL-2002-Correspondence-Others-(17-09-2010)-.pdf

813-DEL-2002-Correspondence-Others-(17-09-2010).pdf

813-del-2002-correspondence-others.pdf

813-del-2002-correspondence-po.pdf

813-del-2002-description (complete).pdf

813-DEL-2002-Form-1-(17-09-2010).pdf

813-del-2002-form-1.pdf

813-del-2002-form-13-(10-09-2009).pdf

813-DEL-2002-Form-13-(17-09-2010).pdf

813-del-2002-form-18.pdf

813-DEL-2002-Form-2-(17-09-2010).pdf

813-del-2002-form-2.pdf

813-DEL-2002-Form-3-(14-07-2010).pdf

813-del-2002-form-3.pdf

813-del-2002-form-5.pdf

813-Del-2002-Form-6.pdf

813-del-2002-gpa.pdf

813-DEL-2002-Petition 137-(17-09-2010).pdf


Patent Number 248554
Indian Patent Application Number 813/DEL/2002
PG Journal Number 30/2011
Publication Date 29-Jul-2011
Grant Date 25-Jul-2011
Date of Filing 02-Aug-2002
Name of Patentee CJ CHEILJEDANG CORP.
Applicant Address CJ BUILDING, 500,5-GA, NAMDAEMUN-RO, JUNG-GU, SEOUL 100-802, REPUBLIC OF KOREA.
Inventors:
# Inventor's Name Inventor's Address
1 JI-SOOK PARK SIYOUNG APT. #101-801, CHOONGGYE-DONG, NOWON-KU, SEOUL 139-220, REPUBLIC OF KOREA.
2 KI-WAN KIM #201, 414-9, HONGEUN 3-DONG, SEODAEMUN-KU, SEOUL 120-848, REPUBLIC OF KOREA.
3 DONG-EOK LEE PLAZA APT. #10-807, GARAK 2-DONG, SONGPA-KU, SEOUL 138-746, REPUBLIC OF KOREA.
4 MYUNG-SUK OH 374, DEOKPYUNG-RI, MAJANG-MYUN, ICHEON-SHI, KYUNGGI-DO 467-812, REPUBLIC OF KOREA.
5 BO-SUP CHUNG GREEN PARK B-202, 719, ANYANG 3-DONG, MANAN-KU, ANYANG-SHI, KYUNGGI-DO 430-013, REPUBLIC OF KOREA.
PCT International Classification Number C12N 15/12
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 NA