• Journal of Plant Biotechnology
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• v.32 no.4
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• pp.233-241
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• 2005

Plants have considerable advantages for the production of antigenic proteins because they provide an inexpensive source of protein and an easy administration of vaccine. Since a publication describing edible plant vaccine of HBsAg in 1992, a number of laboratories around the world have studied the use of plants as the bioreactor to produce antigenic proteins of human or animal pathogens. Over the last ten years, these works have been mainly focused on three major strategies for the production of antigenic proteins in plants: stable genetic transformation of either the nuclear or plastid genome, or transient expression in plants using viral vectors. As many antigenic proteins have been expressed in tobacco, also several laboratories have succeeded to express genes encoding antigenic proteins in other crop plants: potato, tomato, maize, carrot, soybean and spinach. At present many works for the production of edible plant vaccine against bacteria-mediated diseases have mostly performed the studies of enterotoxins and adhesion proteins. Also the development of new-type antigens (pili, flagella, surface protein, other enterotoxin and exotoxin etc.) is required for various targets and more efficacy to immunize against microorganism pathogens. Many works mostly studied in experimental animals had good results, and phase I clinical trial of LTB clearly indicated its immunogenic ability. On the other hand, edible plant vaccines have still problems remained to be solved. In addition to the accumulation of sufficient antigen in plants, human health, environment and agriculture regulation should be proven. Also oral tolerance, the physiological response to food antigens and commensal flora is the induction of a state of specific immunological unresponsiveness, needs to be addressed before plant-derived vaccine becomes a therapeutic option.

• Reproductive and Developmental Biology
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• v.32 no.3
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• pp.159-166
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• 2008

We report here the generation of transgenic chickens that produce human Thrombopoietin (hTPO) using replication-defective Moloney murine leukemia virus (MoMLV)-based vectors packaged with vesicular stomatitis virus G glycoprotein (VSV-G). For the retrovirus vectors, we used hCMV (human Cytomegalovirus) internal promoter to drive the hTPO gene. After confirming the expression of the hTPO gene in various target cells, the concentrated solution of recombinant retrovirus was injected beneath the blastoderm of non-incubated chicken embryos (stage X). The biological activity of the recombinant hTPO in target cell was significantly higher than its commercially available counterpart. Out of 132 injected eggs, 11 chicks hatched after 21 days of incubation and 4 hatched chicks were found to express vector-encoded hTPO gene. However, 3 out of the 4 transgenics died within one month of hatching. The major significance of this study is that it is one of the very few successful reports on the production of transgenic chickens as bioreactors aiming mass production of commercially valuable and biological active human cytokine proteins.