Kenneth E. Drazan

Orthotopic liver transplantation for hepatitis C : Outcome, effect of immunosuppression, and causes of retransplantation during an 8-year single-center experience

OBJECTIVE To determine the outcome of orthotopic liver transplantation (OLT) for end-stage liver disease caused by hepatitis C virus (HCV). SUMMARY BACKGROUND DATA HCV has become the leading cause of cirrhosis and hepatic failure leading to OLT. Recurrent HCV after OLT is associated with significant complications and may lead to graft loss that requires retransplantation (re-OLT). The authors studied the outcome of transplantation for HCV, the effect of primary immunotherapy, and causes of retransplantation. METHODS The authors conducted a retrospective review of their experience during an 8-year period (1990-1997), during which 374 patients underwent transplants for HCV (298 [79.6%] received one OLT; 76 [20.4%] required re-OLT). Median follow-up was 2 years (range 0 to 8.3). Immunosuppression was based on cyclosporine in 190 patients and tacrolimus in 132 patients. In a third group of patients, therapy was switched from cyclosporine to tacrolimus or from tacrolimus to cyclosporine (cyclosporine/tacrolimus group). RESULTS Overall, 1-, 2-, and 5-year actuarial patient survival rates were 86%, 82%, and 76%, respectively. The 2-year patient survival rate was 81 % in the cyclosporine group, 85% in the tacrolimus group, and 82% in the cyclosporine/tacrolimus group. In patients receiving one OLT, overall 1-, 2-, and 5-year patient survival rates were 85%, 81%, and 75%, respectively. The 2-year patient survival rate was 79% in the cyclosporine group, 84% in the tacrolimus group, and 80% in the cyclosporine/tacrolimus group. The overall graft survival rates were 70%, 65%, and 60% at 1, 2, and 5 years, respectively. The graft survival rate at 2 years was similar under cyclosporine (68.5%), tacrolimus (64%), or cyclosporine/tacrolimus (60%) therapy. Re-OLT was required in 42 (11.2%) patients for graft dysfunction in the initial 30 days after OLT. Other causes for re-OLT included hepatic artery thrombosis in 10 (2.6%), chronic rejection in 8 (2.1%), and recurrent HCV in 13 (3.4%) patients. The overall survival rates after re-OLT were 63% and 58% at 1 and 2 years. The 1-year survival rate after re-OLT was 61 % for graft dysfunction, 50% for chronic rejection, 60% for hepatic artery thrombosis, and 60% for recurrent HCV. At re-OLT, 85.3% of the patients were critically ill (United Network for Organ Sharing [UNOS] status 1); only 14.7% of the patients were UNOS status 2 and 3. In re-OLT for chronic rejection and recurrent HCV, the 1-year survival rate of UNOS 1 patients was 38.4%, compared with 87.5% for UNOS 2 and 3 patients. In patients requiring re-OLT, there was no difference in the 1-year patient survival rate after re-OLT when cyclosporine (60%), tacrolimus (63%), or cyclosporine/tacrolimus (56%) was used for primary therapy. With cyclosporine, three patients (1.5%) required re-OLT for chronic rejection versus one patient (0.7%) with tacrolimus. Re-OLT for recurrent HCV was required in four (3%) and seven (3.6%) patients with tacrolimus and cyclosporine therapy, respectively. CONCLUSIONS Orthotopic liver transplantation for HCV is performed with excellent results. There are no distinct advantages to the use of cyclosporine versus tacrolimus immunosuppression when patient and graft survival are considered. Re-OLT is an important option in the treatment of recurrent HCV and should be performed early in the course of recurrent disease. Survival after re-OLT is not distinctively affected by cyclosporine or tacrolimus primary immunotherapy. The incidence of re-OLT for recurrent HCV or chronic rejection is low after either tacrolimus or cyclosporine therapy.

Efficient gene transfer to pancreatic islets mediated by adenoviral vectors.

Genetic manipulation of pancreatic islets before transplantation has the potential to alter cellular immunity as well as islet function. The purpose of this study was to examine the feasibility of gene transfer to islets, using replication-defective adenoviral vectors. Newborn mouse islets were infected with AdHCMVsp1LacZ vector encoding Escherichia coli beta-galactosidase (beta-gal). Islets were cocultured with vector, at virus-to-target cell ratios of 10:1, for 1 hr. Gene transfer was assessed by specific histochemical stain for beta-gal (X-gal). Islet DNA and RNA were analyzed by Southern and PCR for beta-gal and adeno sequences, and recombinant protein production by western and ONPG assays. Islet integrity after gene transfer was assessed by static incubations and transplantation to nondiabetic and to diabetic mice. Southern analysis and PCR confirmed the presence of E coli beta-galactosidase and the E4 adeno DNA in infected islets, but not in controls. Reverse-transcription PCR and western analysis demonstrated expression and protein production of inserted E coli beta-galactosidase, but not E4 message. Insulin release in response to static incubations was unimpaired in infected islets. Syngeneic islet grafts stained positively for insulin for up to 7 days. Transplanted, genetically manipulated islets functioned similarly to control islets in reversing murine drug-induced diabetes. Thus, gene transfer into islets can be accomplished using adenovirus-based vectors. The capacity of this virus to infect non-dividing cells allows insertion of cDNA into pancreatic islets, with potential application to the transplant setting.

A simple model to estimate survival after retransplantation of the liver

To formulate a model predicting survival after liver retransplantation, we analyzed in detail the last 150 cases of hepatic retransplantation at UCLA. Cox proportional hazards regression analysis identified five variables that demonstrated independent simultaneous prognostic value in estimating patient survival after retransplantation: (1) age group (pediatric or adult), (2) recipient requiring preoperative mechanical ventilation, (3) donor organ cold ischemia > or =12 hr, (4) preoperative serum creatinine, and (5) preoperative serum total bilirubin. The Cox regression equation that predicts survival based on these covariates was simplified by assigning individual patients a risk classification based on a 5-point scoring system. We demonstrate that this system can be employed to identify a subgroup of patients in which the expected outcome is too poor to justify retransplantation. These findings may assist in the rational selection of patients suitable for retransplantation.

Adenovirus-mediated p53 gene delivery inhibits 9L glioma growth in rats

Adenoviral vectors have recently been shown to effectively deliver genes into a variety of tissues. Since these vectors have some advantages over the more extensively investigated retroviruses, we studied the effect of two replication-defective adenovectors bearing human wild type tumor suppressor gene p53 (Adp53) and Escherichia coli beta-galactosidase gene (AdLacZ) on 9L glioma cells. Successful in vitro gene transfer was shown by DNA polymerase chain reaction (PCR), and expression was confirmed by reverse transcriptase RNA PCR and Western blot analyses. Transduction of 9L cells with the Adp53 inhibited cell growth and induced phenotypic changes consistent with cell death at low titers, while AdLacZ caused cytopathic changes only at high titers. Stereotactic injection of AdLacZ (10(7) plaque forming units) into tumor bed stained 25 to 30% of tumor cells at the site of vector delivery. Injection of Adp53 (10(7) plaque forming units), but not AdLacZ (controls), into established 4-day old 9L glioma brain tumors decreased tumor volume by 40% after 14 days. As a step toward gene therapy of brain tumors using replication-defective adenoviruses, these data support the use of tumor suppressor gene transfer for in vivo treatment of whole animal brain tumor models.

Adenovirus-mediated gene transfer in the transplant setting. II. Successful expression of transferred cDNA in syngeneic liver grafts.

These experiments establish a model for gene transfer to transplanted liver grafts ex vivo using adenoviral vectors. Rat liver grafts (n = 8) were harvested, and preserved in UW or lactated Ringers. The grafts were infected ex-vivo via portal vein perfusion with replication-defective Ad vectors encoding the beta-galactosidase (beta-gal) gene diluted in UW solution. The infected grafts were stored at 4 degrees C for 1 hr, then transplanted into syngeneic hosts. Liver biopsies were taken at 1, 7, and 15 days after transplantation. Infection rate was assessed by histochemical staining for beta-gal. Liver DNA and RNA were assayed for the beta-gal sequences, and recombinant protein production measured at 24 hr and 7 days after transplantation. Under conditions mimicking liver graft cold storage, efficient gene transfer was achieved with an infection rate of 10-15%, as assessed by X-gal staining. Viral DNA and RNA presence in the graft was confirmed; gene expression with protein production were verified by western blots and a functional protein assay. All studies were negative in control livers. Gene expression persisted for at least 2 weeks after transplantation. We conclude that efficient adenovirus-mediated gene insertion and expression of gene products can be accomplished in whole-liver grafts under hypothermic preservation conditions currently used in clinical transplantation.

ADENOVIRAL - P53 GENE TRANSFER TO ORTHOTOPIC AND PERITONEAL MURINE BLADDER CANCER

PURPOSE This study was designed to examine the potential for adenoviral-mediated gene therapy in primary and metastatic bladder cancer. MATERIALS AND METHODS Orthotopic and intraperitoneal bladder tumors were established after delivery of 1 x 10(6) MBT-2 cells into syngeneic mice. Gene transfer was accomplished via intravesical or intraperitoneal instillation by using an E-1 deleted adenovirus encoding LacZ or human p53. Successful tumor transduction was confirmed in tumor DNA and mRNA by polymerase chain reaction. Detection of recombinant gene product was detected by histochemical staining (X-gal) and Western blot. RESULTS Palpable tumors developed 18 days following implantation. LacZ and p53 mRNA were present in tumor and adjacent normal tissue after bladder and intraperitoneal vector administration. Recombinant gene products were identified by histochemistry and Western blot. CONCLUSION Bladder tumor-directed gene transfer using adenoviral vectors is an efficient and powerful tool for evaluating the adjuvant role of therapeutic gene products.

Adenoviral-Mediated Gene Transfer to Bladder in Vivo

This study was designed to examine the potential for gene therapy in bladder in vivo using adenoviral vectors. Gene transfer to rat bladders was accomplished via direct intravesical instillation using a replication-defective adenoviral vector containing a marker gene encoding for Escherichia coli beta-galactosidase (beta-gal). Successful gene transfer was confirmed by analyzing bladder samples for DNA and RNA using polymerase chain reaction (PCR) with primers specific for beta-gal and adeno sequences, detecting beta-gal in full-thickness bladder wall using specific histochemical staining (X-gal) and documenting recombinant protein production. Bladder architecture was preserved, without evidence of distant spread of virus as assessed by PCR. Gene expression was evident for at least 7 days. In summary, bladder cells can be genetically altered using replication-deficient adenoviral vectors via simple intravesical instillation of vector. Introduction of exogenous genetic material is a potentially powerful therapeutic modality for immunomodulation of bladder neoplasms.

Regeneration-induced accelerated rejection in reduced-size liver grafts.

Liver regenerative processes are associated with enhanced expression of alloantigens. Accordingly, we tested the hypothesis that such enhanced surface expression of alloantigens during regeneration of reduced-size liver grafts is associated with accelerated rejection. Our OLT model was LEW (RT1) to BN (RT1n), with donor liver resected by 50%. The study group consisted of reduced-size allografts. Control groups were syngeneic reduced-size isografts and full-size allografts. Reduced-size isograft recipients survived indefinitely. Both isografts and allografts regenerated to their prereduction size within 12 days. Recipients of reduced-size allografts died of accelerated rejection within 12.2 +/- 0.8 days, significantly earlier than recipients receiving full-size allografts (36.2 +/- 4.1 days, P < 0.01). The accelerated rejection in the regenerating allografts was mediated both by cellular and humoral mechanisms, evidenced by earlier lymphocytic invasion of the graft, enhanced donor MHC class II expression, and the emergence of IgM antibodies, directed specifically against donor endothelial antigens. These data suggest that regeneration of reduced-size allografts is accompanied by accelerated cellularly and humorally mediated alloreactivity. Recipients of reduced-size allografts may, therefore, benefit from more potent immunosuppression during the period of active liver regeneration.

Viral IL-10 gene therapy inhibits TNF-α and IL-1β, not IL-6, in the newborn endotoxemic mouse

Abstract Introduction : Modulation of the inflammatory cascade within the liver of critically ill infants may improve the chance of survival. Using gene therapy, the authors hypothesized that augmented local production of the counter-regulatory cytokine viral interleukin-10 (IL-10) in vivo will modulate the critical cytokines in the inflammatory response. The purpose of the present study was to determine whether replication-defective adenovirus-mediated viral IL-10 (vIL-10) gene transfer and expression within the liver can achieve this goal in newborn mice. Materials and Methods : Four-week-old Balbc mice were administered (intraperitoneally) 1 × 10 9 plaque-forming units (pfu) per milliliter of an adenovirus vector (E1ab-deleted) that encodes the sv40 promoter and the BCRF1 cDNA, or of control vector dl434 that expresses no foreign gene. Forty-eight hours later the mice were challenged with 50 μg/kg of lipopolysaccharide; (LPS) they were killed 1, 2, 6, or 24 hours later (six at each time point). Southern blot analysis was performed on genomic DNA isolated from the liver, lung, and kidney to assess gene transfer of BCRF1. Homogenized liver protein was analyzed for tumor necrosis factor-α (TNF-α), IL-1β, IL-6, and recombinant vIL-10. Results : Southern blot analysis confirmed successful gene transfer to the liver but not to the lung, kidney, or dl434-transduced liver in mice that received adenovectors. Viral IL-10 levels within the liver ranged from 14 to 18 ng/mL. In controls, INF-α production was elevated at early time points, to 18,000 pg/mL, but decreased rapidly by 24 hours after LPS challenge. The TNF-α levels of animals treated with Ad5svBCRF1 were significantly lower than those of controls throughout the course of study ( P P P Conclusion : In vivo administration of adenovectors encoding BCRF1 to newborn mice results in efficient hepatic transduction and expression of recombinant vIL-10. The Kupffer cell response to LPS is suppressed with respect to TNF-α and IL-1β, but not IL-16. In vivo modulation of hepatic cytokine responses is achievable using gene products that mimic cellular cytokines. This is an effective model for the selective evaluation of therapeutic gene products for gene therapy of sepsis.

Adenovirus-mediated gene transfer in the transplant setting. I. Conditions for expression of transferred genes in cold-preserved hepatocytes.

Transplantation of genetically modified hepatocytes has been suggested as a therapeutic modality for impaired hepatocellular function. This study examined adenoviral-mediated gene transfer to isolated hepatocytes, under conditions mimicking clinical transplant preservation. Isolated rat hepatocytes were infected using replication-defective adenoviral vectors with an expression cassette containing the beta-galactosidase gene driven by a CMV promoter. Hepatocytes were infected in suspension immediately after isolation, then either cultured or transplanted immediately into a syngeneic host. Gene transfer efficiency was assessed by histochemical staining and FACS analysis for the gene product. The presence of viral DNA and mRNA, as well as viral-derived protein production, were assayed. Efficiency of gene transfer was examined as a function of several preservation conditions. Infection efficiency was best in cells preserved in UW solution, correlated directly with virus:hepatocyte ratio and with length of exposure to virus. Successful infection resulted in significant viral-derived protein production, persisting for at least two weeks in culture. These results demonstrate the versatility of adenoviral vectors in accomplishing rapid and efficient gene transfer into nondividing hepatocytes during cold preservation. Such genetically modified hepatocytes have potential use for immediate transplantation, without the need for further manipulation.