Growth, reproductive performance, carcass characteristics and meat quality in F1 and F2 progenies of somatic cell-cloned pigs.

The objective of this study was to examine the health and meat production of cloned sows and their progenies in order to demonstrate the application of somatic cell cloning to the pig industry. This study compared the growth, reproductive performance, carcass characteristics and meat quality of Landrace cloned sows, F1 progenies and F2 progenies. We measured their body weight, growth rate and feed conversion and performed a pathological analysis of their anatomy to detect abnormalities. Three of the five cloned pigs were used for a growth test. Cloned pigs grew normally and had characteristics similar to those of the control purebred Landrace pigs. Two cloned gilts were bred with a Landrace boar and used for a progeny test. F1 progenies had characteristics similar to those of the controls. Two of the F1 progeny gilts were bred with a Duroc or Large White boar and used for the progeny test. F2 progenies grew normally. There were no biological differences in growth, carcass characteristics and amino acid composition among cloned sows, F1 progenies, F2 progenies and conventional pigs. The cloned sows and F1 progenies showed normal reproductive performance. No specific abnormalities were observed by pathological analysis, with the exception of periarteritis in the F1 progenies. All pigs had a normal karyotype. These results demonstrate that cloned female pigs and their progenies have similar growth, reproductive performance and carcass quality characteristics and that somatic cell cloning could be a useful technique for conserving superior pig breeds in conventional meat production.

Production of cloned pigs expressing human thrombomodulin in endothelial cells.

For long-term xenograft survival, coagulation control is one of the remaining critical issues. Our attention has been directed toward human thrombomodulin (hTM), because it is expected to exhibit the following beneficial effects on coagulation control and cytoprotection: (i) to solve the problem of molecular incompatibility in protein C activation; (ii) to exert a role as a physiological regulator, only when thrombin is formed; (iii) to suppress direct prothrombinase activity; and (iv) to have anti-inflammatory properties. hTM gene was transfected into pig (Landrace/Yorkshire) fibroblasts using pCAGGS expression vector and pPGK-puro vector. After puromycin selection, only fibroblasts expressing a high level of hTM were collected by cell sorting and then applied to nuclear transfer. Following electroactivation and subsequent culture, a total of 1547 cleaved embryos were transferred to seven surrogate mother pigs. Two healthy cloned piglets expressing hTM were born, successfully grew to maturity and produced normal progeny. Immunohistochemical staining of organs from F1 generation pigs demonstrated hTM expression in endothelial cells as well as parenchymal cells. High expression was observed particularly in endothelial cells of kidney and liver. Aortic endothelial cells from cloned pigs were found to express hTM levels similar to human umbilical vein endothelial cells (HUVEC) and to make it possible to convert protein C into activated protein C. The blockade of human endothelial cell protein C receptor (hEPCR) significantly reduced APC production in HUVEC, but not in hTM-PAEC. Although no bleeding tendency was observed in hTM-cloned pigs, activated partial thromboplastin time (APTT) was slightly prolonged and soluble hTM was detected in pig plasma. hTM was expressed in platelets and mononuclear cells, but not in RBC. Cloned pigs expressing hTM in endothelial cells at a comparable level to HUVEC were produced. As complete suppression of antigen-antibody reaction in the graft is essential for accurate assessment of transgene related to coagulation control, production of genetically engineered pigs expressing hTM and complement regulatory protein based on galactosyltransferase knockout is desired.

Successful cross-breeding of cloned pigs expressing endo-beta-galactosidase C and human decay accelerating factor.

BACKGROUND: For successful organ xenotransplantation, genetically engineered pigs have been actively produced. Our attention has focused on (i) reduction of alphaGal expression by its digestion enzyme, endo-beta-galactosidase C (EndoGalC), and (ii) inhibition of complement activation by human decay accelerating factor (hDAF). Cell sorting and nuclear transfer enabled the effective production of cloned pigs expressing transgene at high levels. We report the successful cross-breeding of pigs expressing EndoGalC and hDAF. METHODS: After hDAF and EndoGalC genes were transfected into pig fibroblasts from the fetus of Landrace x Yorkshire and Meishan, respectively, transfected cells expressing transgenes effectively were collected using a cell sorter. Cloned pigs were produced using the technology of somatic cell nuclear transfer. After cross-breeding of cloned pigs, kidneys expressing both EndoGalC and hDAF were transplanted into baboons to examine the efficacy of gene transduction. RESULTS: Well-designed cloned pigs were produced by cross-breeding. alphaGal expression levels in cloned pigs were reduced up to 2 to 14%, compared to that in wild-type pigs. hDAF expression reached about 10- to 70-fold, compared to that in human umbilical vein endothelial cells. No congenital deformity was observed. There was no problem of increased stillbirth rate or growth retardation. Hyperacute rejection could be avoided in such a cloned pig to baboon kidney transplantation without any treatment for anti-pig antibody removal. However, grafts suffered from fibrin deposition as early as 1 h after transplantation, and were rejected after 1 week. CONCLUSIONS: Using a cell sorting system for effective collection of transfected cells, two types of cloned pigs were produced with a very high level of hDAF expression and a low level of alphaGal expression. Such genetic modification was effective in preventing hyperacute rejection, but there was an immediate lapse into procoagulation after transplantation, resulting in acute vascular rejection. Effective suppression of antibody binding to the graft would be necessary, even if a high level of hDAF is expressed.