Porcine Repeat Element DNA: In Situ Detection of Xenotransplanted Cells

Xenogeneic Cell Therapy: Current Progress and Future Developments in Porcine Cell Transplantation

The multitude of distinct cell types present in mature and developing tissues display unique physiologic characteristics. Cellular therapy is a novel technology with the promise of utilizing this diversity to treat a wide range of human degenerative diseases. Intractable diseases, disorders, and injuries are characterized by cell death or aberrant cellular function. Cell transplantation can replace diseased or lost tissue to provide restorative therapy for these conditions. The limited use of cell transplants as a basis for current therapy can, in part, be attributed to the lack of available human cells suitable for transplantation. This has prevented further realization of the promise of cell transplantation as a platform technology. Accordingly, cell-based therapies such as blood transfusions, for which the cells are readily available, are a standard part of current medical practice. Despite numerous attempts to expand primary human cells in tissue culture, current technological limitations of this approach in regard to proliferative capacity and maintenance of the differentiated phenotype has prevented their use for transplantation. Further, use of human stem cells for the derivation of specific cell types for transplantation is an area of future application with great potential, but hurdles remain in regard to deriving and sufficiently expanding these multi-potential cells. Thus, it appears that primary cells are at present a superior source for transplantation. This review focuses on pigs as a source of a variety of primary cells to advance cell therapy to the clinic and implement achievement of its full potential. We outline the advantages and disadvantages of xenogeneic cell therapy while underscoring the utility of transplantable porcine cells for the treatment of human disease. © 1998 Elsevier Science Inc.

Toward the survival and function of xenogeneic hepatocyte grafts

Xenogeneic hepatocyte transplantation might offer an unobtrusive alternative to whole liver allotransplantation. Having previously found that the immune response to such grafts can be controlled by immunosuppression, we sought approaches to collection and delivery that would optimize survival and function after transplantation. Porcine hepatocytes were isolated by a 2-step collagenase technique and then: 1) used immediately; 2) stored in University of Wisconsin (UW) solution at 4 degrees C; 3) cultured in supplemented Williams E medium; or 4) cryopreserved in UW solution with 10% dimethyl sulfoxide (DMSO). The fate and function of the hepatocytes was determined after they were injected into the spleens of immunodeficient mice. Freshly isolated hepatocytes had better viability (92.2 +/- 1.9%) than hepatocytes cultured for 24 hours (78.4 +/- 6.3%), hypothermically preserved in UW solution for 24 hours (85.8 +/- 3.1%), or cryopreserved (65.0 +/- 2.6%). Freshly isolated hepatocytes secreted more albumin after transplantation than hepatocytes that were cultured, hypothermically stored, or cryopreserved. In conclusion, culture and storage profoundly compromises the function of isolated hepatocytes after transplantation. Freshly isolated hepatocytes are the preferred source for transplantation.

Xenogeneic transplantation of porcine hepatocytes into the CCl4 cirrhotic rat model

Liver support using extracorporeal devices and hepatocyte transplantation has received renewed interest for the management of acute and chronic liver failure. The aim of this study was to determine whether xenogeneic porcine hepatocytes could integrate into the liver parenchyma of cirrhotic Lewis rats when administered by an intrasplenic route. Cirrhosis was induced by carbon tetrachloride (CCl4) inhalation and confirmed histologically. Freshly isolated porcine hepatocytes were infused directly into the splenic pulp at laparotomy over a 5-15-min interval. Using (111)In-labeled hepatocytes, the degree of localization of porcine hepatocytes to the spleen and liver was found to be greater than 60% in both control and cirrhotic rats. Integration of porcine hepatocytes into the rat liver parenchyma was determined by immunohistochemical staining for porcine albumin in rat liver sections. Further confirmation was provided by in situ hybridization using a porcine-specific probe that binds to a distinct repetitive element (PRE) in porcine DNA. Evidence of integrated porcine hepatocytes was seen for over 50 days in animals under cyclosporine immunosuppression. These data demonstrate the integration of xenogeneic porcine hepatocytes into the liver of the cirrhotic rat and their ability to produce porcine albumin for up to 50 days.

Polymerase chain reaction assays for the diagnosis of infection with the porcine endogenous retrovirus and the detection of pig cells in human and nonhuman recipients of pig xenografts

BACKGROUND

Pigs offer an unlimited source of xenografts for humans. However, recipients of pig xenografts are inevitably exposed to the porcine endogenous retrovirus (PERV), which is carried in the pig germline. The ability of PERV to infect human cells in vitro has heightened safety concerns regarding the transmission of PERV to pig xenograft recipients.

METHODS

In response to the need to establish laboratory tests for the surveillance of PERV infection, we have developed polymerase chain reaction (PCR) assays to detect PERV pol and gag sequences by using conserved primers and probes. In addition, we have developed a PCR assay to detect pig-specific mitochondrial DNA (mtDNA) sequences as a marker of pig cells.

RESULTS

Analysis of assay sensitivities using cloned target copies in a background of human DNA demonstrated a detection threshold of 1, 5, and 1 copy for the PERV gag, pol, and pig mtDNA PCR assays, respectively. All three PCR assays gave negative results on peripheral blood lymphocyte samples from 69 humans, as well as 6 baboons and 6 macaques, demonstrating 100% specificity. The PERV and pig mtDNA assays were integrated into a simple testing algorithm that allows the differentiation between pig cell microchimerism and true xenogeneic infection. To allow for monitoring of PERV expression, a reverse transcriptase-PCR assay was also developed to detect cell-free PERV RNA.

CONCLUSION

The use of the diagnostic tests described here will help define the risks of PERV transmission associated with the use of pig xenografts in humans and nonhuman primates.

Fetal pig neural cells as a restorative therapy for neurodegenerative disease

With proper immunosuppression, interspecies transplantation of porcine as well as other species of neural cells survive, mature, and integrate into the host in a manner which reconstructs much of the appropriate neural circuitry. These transplants have been shown to alleviate many of the symptoms of various disorders of the central nervous system. In this study, we addressed immunological and maturation issues with regards to intracerebral transplantation of fetal porcine neural cells. First, we compared fetal neural xenograft survival in athymic nude rats versus rats immunosuppressed with cyclosporin A and found that there is little discernible difference between porcine grafts in the 2 recipients. We also found that ectopic transplantation of cells isolated from the porcine striatal primordium can survive and develop into grafts composed of both neuronal and glial phenotypes within the rat hippocampus. This fact raises the possibility that cells of a particular neurotransmitter type (e.g., GABAergic cells) developing from the striatal precursor cells can be transplanted outside the striatum of the adult brain and have physiological effects.

A molecular epidemiological probe for pig microchimerism

We have cloned and characterized a single-copy DNA sequence from the porcine alpha-1,3-galactosyltransferase gene that corresponds to a 547-base pair intron separating exons 3 and 4 of the protein coding domain. Polymerase chain reaction amplification of this sequence from flanking oligonucleotides generates a species-specific DNA probe (pgt34) capable of recognizing 50 pg chimeric template DNA at a pig to human cellular ratio of 1/10,000. Homologous DNA sequence is not identified in the macaque, baboon, or human genome by Southern hybridization. Analysis of a discordant model of pig to baboon xenotransplantation demonstrates peripheral blood microchimerism in the presence of a functioning pig kidney xenograft and persistence of microchimerism in lymphatic tissue after graft removal. This probe should be useful for tracking the fate of porcine cells in patients undergoing xenotransplantation of whole organs or free tissues such as pancreatic islet cells and should facilitate studies of microchimerism in experimental models of pig to monkey xenotransplantation.

Reduction of serum cholesterol in Watanabe rabbits by xenogeneic hepatocellular transplantation

Transplantation of xenogeneic hepatocytes would provide a novel therapy for liver disease and would help to solve the problem of an insufficient supply of donor organs. We have tested whether xenogeneic cells infused into the liver could correct the metabolic defect in the Watanable heritable hyperlipidemic (WHHL) rabbit, an animal model for homozygous familial hypercholesterolemia, and we have investigated whether the infused cells traverse the lining of the portal vasculature. We find that porcine hepatocytes are localized in the hepatic sinusoids after surgery and subsequently migrate out of the vessels and integrate into the hepatic parenchyma. The integrated porcine hepatocytes provide functional LDL receptors that lower serum cholesterol in the WHHL rabbit by 30-60% for at least 100 days.