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– 129 – Trends in Korean Animal Biotechnology Transgenic Goats Production of Human Granulocyte Colony-Stimulating Factor using Goat b-casein Promoter (Meddy) (Source of information: 12 May 1999. Korea Herald Newspaper; 2003 Hanmi Company report. Patents WO0015808, US6635474) The pharmaceutical company Hanmi has produced the transgenic goat “Meddy” (inh collaboration with KAIST, KRIBB, and ChungNam National University) which produced human granulocyte colony-stimulating factor (hG-CSF), one of the hematopoietic factors that control the differentiation of pluripotent stem cells into many kinds of blood cells during hematopoiesis (Ko et al., 2000). It also plays a key role in the stimulation of proliferation and differentiation for other types of blood cells, in addition to granulocytes and macrophages. This is a promising drug for many kinds of disorders related to reduction of neutrophil and other blood cell levels. If the materials derived from the goat’s milk are effective, the price of G-CSF will be decreased. Humans produce on the average only small amounts of G-CSF, which has made the protein extremely expensive for white-cell-deficient cancer patients. The cost of producing G- CSF from genetically altered animals is one-tenth of the cost of obtaining it from mammalian cells, the method commonly used in advanced countries. The hG-CSF gene was subcloned into plasmid pGbc behind the 1.7 kb sequence of the goat b-casein promoter and named pGbc-hG- CSF. The expression cassette of pGbc-hG-CSF was microinjected into fertilized mouse eggs and goat eggs. One mouse and two transgenic goats named Meddy and Serry were identified by PCR analysis and Southern blotting. According to Hanmi, the company has established a method of purifying G-CSF from the milk of transgenic goats and has produced the fourth generation of Meddy, confirming the stable transfer of the G-CSF gene. Currently, one gram of G-CSF costs about KRW 900 million, and the global market for the protein is estimated at USD1.4 billion each year, according to KAIST. The Korean market for the protein is estimated at KRW 15 billion. Each injection of G-CSF (400 micrograms) costs around KRW 260,000. Hanmi is currently working on large-scale breeding of the transgenic goat and is planning clinical trials with purified G-CSF in 2005. CONCLUSION Transgenic animal research has received firm support from the Korean government since the late 1990s and will be given a major stimulus in 2005 with the launching of the national grants program. Although the technology has yet to produce a final product, there have been several successfully created transgenic farm animals. It is expected that the first successful product that can undergo clinical trials will be produced within the next few years. REFERENCES Datamonitor. Therapeutic Proteins: Strategic Market Analysis and Forecast to 2010. 2002. Dimond P.F. Transgenic technology in the production of therapeutic proteins. Innovations in Pharmaceutical Technology 1996; 92–97. Egrie J.C., Browne J.K. Development and characterization of novel erythropoiesis stimulating protein (NESP). Nephrology Dialysis Transplantation 2001; 16: 3–13. Fisher J.W. Erythropoietin: physiology and pharmacology update. Experimental Biology and Medicine 2003; 228: 1–14. Greer J.W., Milam R.A., Eggers P.W. Trends in use, cost, and outcomes of human recombinant erythropoietin, 1989–98. Health Care Finanial Revue 1999; 20(3): 55–62. GTC company press release 2004. http://www.gtc-bio.com/pressreleases/pr022704.html. 2004. Hammer R.E., Pursel V.G., Rexroad C.E. Jr., Wall R.J., Bolt D.J., Ebert K.M., Palmiter R.D., Brinster R.L. Production of transgenic rabbits, sheep and pigs by microinjection. Nature 1985; 315(6021): 680–683. Houdebine L.M. Transgenic animal bioreactors. Transgenic Research 2000; 9: 305–320.
Business Potential for Agricultural Biotechnology Products Jelkmann W. Erythropoietin: structure, control of production, and function. Physiology Revue 1992; 72: 449–489. Kim S.J., Sohn B.H., Jeong S., Pak K.W., Park J.S., Park I.Y., Lee T.H., Choi Y.H., Lee C.S., Han Y.M., Yu D.Y., Lee K.K. High-level expression of human lactoferrin in milk of transgenic mice using genomic lactoferrin sequence. Journal of Biochemistry (Tokyo) 1999; 126(2): 320–325. Ko J.H., Lee C.S., Kim K.H., Pang M.G., Koo J.S., Fang N., Koo D.B., Oh K.B., Youn W.S., Zheng G.D., Park J.S., Kim S.J., Han Y.M., Choi I.Y., Lim J., Shin S.T., Jin S.W., Lee K.K., Yoo O.J. Production of biologically active human granulocyte colony stimulating factor in the milk of transgenic goat. Transgenic Research 2000; 9(3): 215–222. Krimpenfort P., Rademakers A., Eyestone W., van der Schans A., van den Broek S., Kooiman P., Kootwijk E., Platenburg G., Pieper F., Strijker R. Generation of transgenic dairy cattle using “in vitro” embryo production. Biotechnology 1991; 9(9): 844–847. Paleyanda R.K., Velander W.H., Lee T.K., Scandella D.H., Gwazdauskas F.C., Knight J.W., Hoyer L.W., Drohan W.N., Lubon H. Transgenic pigs produce functional human factor VIII in milk. Nature Biotechnology 1997; 15(10): 971–975. Piletz J.E., Heinlen M., Ganschow R.E. Biochemical characterization of a novel whey protein from murine milk. Journal of Biolological Chemistry 1981; 256: 11509–11516. Reichenstein M., Gottlieb H., Damari G.M., Iavnilovitch E., Barash I. A new beta-lactoglobulinbased vector targets luciferase cDNA expression to the mammary gland of transgenic mice. Transgenic Research 2001; 10: 445–456. Rural Development Administration. Establishment of safety control system for genetically modified agricultural products (article in Korean). 2005. Schnieke A.E., Kind A.J., Ritchie W.A., Mycock K., Scott A.R., Ritchie M., Wilmut I., Colman A., Campbell K.H. Human factor IX transgenic sheep produced by transfer of nuclei from transfected fetal fibroblasts. Science 1997; 278(5346): 2130–2133. Shibata J., Hasegawa J., Siemens H.J., Wolber E., Dibbelt L., Li D., Katschinski D.M., Fandrey J., Jelkmann W., Gassmann M., Wenger R.H., Wagner K.F. Hemostasis and coagulation at a hematocrit level of 0.85: functional consequences of erythrocytosis. Blood 2003; 101(11): 4416–4422. Tsakiris D. Morbidity and mortality reduction associated with the use of erythropoietin. Nephron 2000; 85: 2–8. Van Berkel P.H.C., Welling M.M., Geerts M., van Veen H.A., Ravensbergen B., Salaheddine M., Pauwels E.K., Pieper F., Nuijens J.H., Nibbering P.H. Large scale production of recombinant human lactoferrin in the milk of transgenic cows. Nat. Biotechnology 2002; 20: 484– 487. Wright G., Carver A., Cottom D., Reeves D., Scott A., Simons P., Wilmut I., Garner I., Colman A. High level expression of active human alpha-1-antitrypsin in the milk of transgenic sheep. Biotechnology 1991; 9(9): 830–834. – 130 –
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From: Business Potential for Agricu
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Report of the APO Multi-country Stu
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Part IV Appendices 5. Agricultural
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Part I Summary of Findings
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Business Potential for Agricultural
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Thurs., 26 May Forenoon Visit Taida
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