Functional difference between membrane-bound and soluble human thrombomodulin.

BACKGROUND: For successful xenotransplantation, in addition to α1,3-galactosyltransferase gene-knockout and human complement regulatory protein (CD46, CD55, CD59) gene insertion, cloned pigs expressing human thrombomodulin (hTM) have been produced to solve the problem of molecular incompatibility in their coagulation system. Recombinant soluble hTM (S-hTM) which has been recently approved for treatment of disseminated intravascular coagulation might be potentially available. The purpose of this study is to examine the functional difference in endothelial cells between membrane-bound hTM (MB-hTM) and S-hTM and to elucidate effective strategy using both types of hTM. METHODS: The following factors regarding coagulation and inflammation were compared between hTM-expressing pig aortic endothelial cells (PAEC) derived from cloned pig and nontransgenic PAEC in the presence of S-hTM under tumor necrosis factor-α-activated conditions; (i) clotting time (ii) pig tissue factor (TF), (iii) pig E-selectin, (iv) direct prothrombinase activity, (v) activated protein C (APC), and (vi) prothrombinase activity. RESULTS: The MB-hTM significantly suppressed the expression of pig TF and E-selectin and direct prothrombinase activity in tumor necrosis factor-α-activated PAEC, suggesting strong anti-inflammatory effect, compared to S-hTM. In contrast, S-hTM had more potent capacity to inhibit thrombin generation and to produce APC than MB-hTM, although MB-hTM had the same level of capacity as human endothelial cells. CONCLUSIONS: It was speculated that S-hTM treatment would be of assistance during high-risk periods for excessive thrombin formation (e.g., ischemia reperfusion injury or severe infection/rejection). Considering the properties of MB-hTM exhibiting anti-inflammatory function as well as APC production, hTM-expressing cloned pigs might be indispensible to long-term stabilization of graft endothelial cells.

Porcine model of hemophilia A.

Hemophilia A is a common X chromosome-linked genetic bleeding disorder caused by abnormalities in the coagulation factor VIII gene (F8). Hemophilia A patients suffer from a bleeding diathesis, such as life-threatening bleeding in the brain and harmful bleeding in joints and muscles. Because it could potentially be cured by gene therapy, subhuman animal models have been sought. Current mouse hemophilia A models generated by gene targeting of the F8 have difficulties to extrapolate human disease due to differences in the coagulation and immune systems between mice and humans. Here, we generated a porcine model of hemophilia A by nuclear transfer cloning from F8-targeted fibroblasts. The hemophilia A pigs showed a severe bleeding tendency upon birth, similar to human severe hemophiliacs, but in contrast to hemophilia A mice which rarely bleed under standard breed conditions. Infusion of human factor VIII was effective in stopping bleeding and reducing the bleeding frequency of a hemophilia A piglet but was blocked by the inhibitor against human factor VIII. These data suggest that the hemophilia A pig is a severe hemophilia A animal model for studying not only hemophilia A gene therapy but also the next generation recombinant coagulation factors, such as recombinant factor VIII variants with a slower clearance rate.

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.

Comparative study on signal transduction in endothelial cells after anti-a/b and human leukocyte antigen antibody reaction: implication of accommodation.

BACKGROUND: Recent development of immunosuppressive therapy has provided a platform for clinical human leukocyte antigen (HLA)- and ABO-incompatible kidney transplantation. However, the prognosis seems to be different between the two. Accommodation, the condition of no injury even in the presence of antidonor antibody, is one of the key factors for successful transplantation with antidonor antibody. The purpose of this study was to compare signal transduction between anti-A/B and anti-HLA antibody reaction and to elucidate the mechanisms underlying accommodation. METHODS: Blood type A- or B-transferase gene was transfected into human EA.hy926 endothelial cells. After cell sorting, A- or B-expressing cells at high levels were obtained. The effects of anti-HLA and anti-A/B antibody binding on complement-mediated cytotoxicity and signal transduction were examined. RESULTS: Preincubation with anti-HLA antibodies only at low levels (<10% of saturation level) or anti-A/B antibodies at high levels (even at near saturation levels) for 24 hr resulted in resistance to complement-mediated cytotoxicity. Anti-A/B antibody ligation inactivated ERK1/2 pathway and increased complement regulatory proteins such as CD55 and CD59, whereas anti-HLA ligation activated PI3K/AKT pathway and increased cytoprotective genes such as hemeoxygenase-1 and ferritin H. CONCLUSION: Complement inhibition by upregulation of CD55 and CD59 through ERK1/2 inactivation might play a substantial role in accommodation after ABO-incompatible transplantation, which could also explain the intriguing finding of C4d deposition in the graft without rejection.

Potential value of human thrombomodulin and DAF expression for coagulation control in pig-to-human xenotransplantation.

BACKGROUND: Problems of coagulation disorder remain to be resolved in pig-to-primate xenotransplantation. Molecular incompatibilities in the coagulation systems between pigs and humans, such as the thrombomodulin (TM)-protein C system or direct prothrombinase activity, have been suggested as possible causes. Coagulation and complement activation are closely related to each other. The purpose of this study was to elucidate the protective effects on the coagulation system of the expression of human TM and decay accelerating factor (hDAF) (for inhibition of complement activation) in pig endothelial cells. METHODS: Human aortic endothelial cells (HAEC), porcine aortic endothelial cells (PAEC), hDAF-expressing PAEC (hDAF-PAEC), hDAF/Endo-beta-galactosidase C-expressing PAEC (hDAF/EndoGalC-PAEC), hTM-expressing PAEC (hTM-PAEC), hDAF/hTM expressing-PAEC (hDAF/hTM-PAEC), and hDAF/EndoGalC/hTM-expressing PAEC (hDAF/EndoGalC/hTM-PAEC) were used in this study. Coagulation activity was examined by clotting, activated protein C (APC), and thrombin generation assay. RESULTS: A large difference was observed in clotting time of human plasma when exposed to PAEC (170 s) and HAEC (1020 s). hTM expression on PAEC was proven to produce a comparable level of APC to that produced by HAEC, which prolonged the clotting time, though not to the level of HAEC. Pretreatment with human sera considerably shortened the clotting time in PAEC (80 s). hDAF-PAEC significantly inhibited such a shortening of clotting time by reductions in tissue factor expression and thrombin generation. Thrombin generation through direct prothrombinase activity, which was detected only in PAEC, could be suppressed by hTM expression. Suppression of antibody binding and complement activation improved clotting time not in PAEC, but in PAEC expressing hTM. CONCLUSIONS: In addition to effective suppression of antibody-induced complement activation, hTM expression in PAEC may be essential for regulating procoagulant activity in xenotransplantation.

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.

Effects of caffeine treatment on aged porcine oocytes: parthenogenetic activation ability, chromosome condensation and development to the blastocyst stage after somatic cell nuclear transfer.

The possibility of using aged porcine oocytes treated with caffeine, which inhibits the decrease in M-phase promoting factor activity, for pig cloning was evaluated. Cumulus-oocyte complexes (COCs) were cultured initially for 36 h and subsequently with or without 5 mM caffeine for 24 h (in total for 60 h: 60CA+ or 60CA- group, respectively). As a control group, COCs were cultured for 48 h without caffeine (48CA-). The pronuclear formation rates at 10 h after electrical stimulation in the 60CA+ and 60CA- groups decreased significantly (p < 0.05) compared with the 48CA- group. However, the fragmentation rate was significantly higher (p < 0.05) in the 60CA- group than in the 60CA+ and 48CA- groups. When the stimulated oocytes were cultured for 6 days, the 60CA+ group showed significantly lower blastocyst formation and higher fragmentation or degeneration rates (p < 0.05) than the 48CA- group. However, the number of total cells in blastocysts was not affected by maturation period or caffeine treatment. When somatic cell nuclei were injected into the non-enucleated oocytes and exposed to cytoplasm for a certain duration (1-11 h) before the completion of maturation (48 or 60 h), the rate of nuclear membrane breakdown after exposure to cytoplasm for 1-2 h in the 60CA- oocytes was significantly lower (p < 0.05) than in the other experimental groups. The rate of scattered chromosome formation in the same 60CA- group tended to be lower (p = 0.08) than in the other groups. After the enucleation and transfer of nuclei, blastocyst formation rates in the 60CA+ and 60CA- groups were significantly lower (p < 0.05) than in the 48CA- group. Blastocyst quality did not differ among all the groups. These results suggest that chromosome decondensation of the transplanted somatic nucleus is affected by both the duration of exposure to cytoplasm and the age of the recipient porcine oocytes, and that caffeine treatment promotes nuclear remodelling but does not prevent the decrease in the developmental ability of cloned embryos caused by oocyte aging.

A novel method for the production of transgenic cloned pigs: electroporation-mediated gene transfer to non-cultured cells and subsequent selection with puromycin.

Puromycin N-acetyl transferase gene (pac), of which the gene product catalyzes antibiotic puromycin (an effective inhibitor of protein synthesis), has been widely used as a dominant selection marker in embryonic stem (ES) cell-mediated transgenesis. The present study is the first to report on the usefulness of puromycin for production of enhanced green fluorescent protein (EGFP) transgenic piglets after somatic cell cloning and embryo transfer. Somatic cells isolated from porcine fetuses at 73 days of gestation were immediately electroporated with a transgene (pCAG-EGFPac) carrying both EGFP cDNA and pac. This procedure aims to avoid aging effects thought to be generated during cell culture. The recombinant cells were selected with puromycin at a low concentration (2 microg/ml), cultured for 7 days, and then screened for EGFP expression before somatic cell cloning. The manipulated embryos were transplanted into the oviducts of 14 foster mother sows. Four of the foster sows became pregnant and nine piglets were delivered. Of the nine piglets, eight died shortly after birth and one grew healthy after weaning. Results indicate that puromycin can be used for the selection of recombinant cells from noncultured cells, and moreover, may confer the production of genetically engineered newborns via nuclear transfer techniques in pigs.