AAV based gene delivery to myocardium in rodents and pigs

Objective: To optimize transgene expression levels after AAV‐mediated gene transfer different delivery methods were compared in a rat (A) and porcine (B) heterotopic heart transplantation model. Methods: (A) Heterotopic abdominal heart transplantations were performed in male Lewis rats. After harvesting the donor hearts, the viral vectors were delivered to the graft by the following methods: (1) 0.35 ml saline solution containing AAV2/9‐LacZ (2 × 10¹¹ vector genome, vg) was injected directly into the myocardium (apex) immediately after reperfusion. (2) cardioplegic solution (0.3 ml) containing AAV‐2(HBSD), 2/9‐LacZ vectors was rapidly injected into the aortic root with the pulmonary trunk clamped. Before transplantation the transfected heart was incubated for 20 min in iced cardioplegia. (3) A reperfusion system was applied: For 20 min a cold solution of cardioplegia (5 ml) and AAV‐2(HBSD) or AAV2/9‐LacZ vectors were recirculated through the donor heart. Transplanted grafts were explanted after 3 weeks. To detect and measure marker gene expression X‐gal staining or a luciferase assay was performed. In a second series we compared the effects of the transduction of PD‐L1 to LacZ using the optimum method (intraaortic root injection) in the same heart transplantation model. (B) Heterotopic abdominal HTX was performed in pigs (Landrace, 10–18 kg) following vector application to the donor heart in an in situ‐Langendorff perfusion system (AAV2/GFP and AAV2/Luciferase). Recipients were given tacrolimus (0.3 mg/kg BW), after 21 days the transplanted hearts were explanted for transgene expression analysis. In a second series we compared AAV2/9‐mediated transduction of PD‐L1 and LacZ in the in situ‐Langendorff model and consequent allogeneic heterotopic abdominal heart transplantation. Results: (A) Highest transfection efficiency was observed in the grafts treated with intracoronary infusion of AAV2/9 at the higher dosage, and the expression pattern was global and homogenous in the grafts. hPD‐L1 transduction resulted in no significant difference of survival time and signs of rejection after allogeneic rat heart transplantation. (B) AAV2‐mediated gene delivery was unable to yield sufficient transgene expression after in situ‐Langendorff perfusion of porcine hearts. AAV2/9 based gene transfer of LacZ and hPD‐L1 led to excellent myocardial gene expression lasting up to 2 months. Due to species incompatibility no protective effects were observed in our allogeneic porcine transplantation model. Conclusions: (A) We demonstrated that infusion of AAV vectors into the aortic root with the pulmonary trunk clamped is a simple and efficient method for gene delivery to the donor heart in an allogeneic rat heart transplantation setting. Gene transfer of hPD‐L1 was ineffective to protect against allorejection, on the contrary there was a trend to aggravated rejection. Therefore the exact mechanism of hPD‐L1 in allograft rejection needs further investigation. (B) The in situ‐Langendorff model was developed to allow isolated target organ perfusion with high vector concentrations under physiological conditions. Using this method AAV2/9 mediated gene delivery into porcine hearts proved effective to induce excellent marker gene expression. Expression of hPD‐L1 could also be achieved but was ineffective in pig allotransplantation due to species incompatibility. Double transgenic pig hearts (e.g. Gal‐KO+CD46) can now efficiently be transduced with hPD‐L1 or hCTLA4‐Ig to further optimize long‐term survival after pig‐to‐primate cardiac xenotransplantation.     

Nerve growth factor gene therapy using adeno-associated viral vectors prevents cardiomyopathy in type 1 diabetic mice

Diabetes is a cause of cardiac dysfunction, reduced myocardial perfusion, and ultimately heart failure. Nerve growth factor (NGF) exerts protective effects on the cardiovascular system. This study investigated whether NGF gene transfer can prevent diabetic cardiomyopathy in mice. We worked with mice with streptozotocin-induced type 1 diabetes and with nondiabetic control mice. After having established that diabetes reduces cardiac NGF mRNA expression, we tested NGF gene therapies with adeno-associated viral vectors (AAVs) for the capacity to protect the diabetic mouse heart. To this aim, after 2 weeks of diabetes, cardiac expression of human NGF or β-Gal (control) genes was induced by either intramyocardial injection of AAV serotype 2 (AAV2) or systemic delivery of AAV serotype 9 (AAV9). Nondiabetic mice were given AAV2-β-Gal or AAV9-β-Gal. We found that the diabetic mice receiving NGF gene transfer via either AAV2 or AAV9 were spared the progressive deterioration of cardiac function and left ventricular chamber dilatation observed in β-Gal-injected diabetic mice. Moreover, they were additionally protected from myocardial microvascular rarefaction, hypoperfusion, increased deposition of interstitial fibrosis, and increased apoptosis of endothelial cells and cardiomyocytes, which afflicted the β-Gal-injected diabetic control mice. Our data suggest therapeutic potential of NGF for the prevention of cardiomyopathy in diabetic subjects.     

Ex vivo intracoronary gene transfer of adeno‐associated virus 2 leads to superior transduction over serotypes 8 and 9 in rat heart transplants

Heart transplant gene therapy requires vectors with long‐lasting gene expression, high cardiotropism, and minimal pathological effects. Here, we examined transduction properties of ex vivo intracoronary delivery of adeno‐associated virus (AAV) serotype 2, 8, and 9 in rat syngenic and allogenic heart transplants. Adult Dark Agouti (DA) rat hearts were intracoronarily perfused ex vivo with AAV2, AAV8, or AAV9 encoding firefly luciferase and transplanted heterotopically into the abdomen of syngenic DA or allogenic Wistar–Furth (WF) recipients. Serial in vivo bioluminescent imaging of syngraft and allograft recipients was performed for 6 months and 4 weeks, respectively. Grafts were removed for PCR‐, RT‐PCR, and luminometer analysis. In vivo bioluminescent imaging of recipients showed that AAV9 induced a prominent and stable luciferase activity in the abdomen, when compared with AAV2 and AAV8. However, ex vivo analyses revealed that intracoronary perfusion with AAV2 resulted in the highest heart transplant transduction levels in syngrafts and allografts. Ex vivo intracoronary delivery of AAV2 resulted in efficient transgene expression in heart transplants, whereas intracoronary AAV9 escapes into adjacent tissues. In terms of cardiac transduction, these results suggest AAV2 as a potential vector for gene therapy in preclinical heart transplants studies, and highlight the importance of delivery route in gene transfer studies.     

Long-Term Gene Transfer in Porcine Myocardium After Coronary Infusion of an Adeno-Associated Virus Vector

Background. Viral vector-mediated gene transfer into the heart represents a potentially powerful tool for studying both cardiac physiology as well as gene therapy of cardiac disease. We report here the use of a defective viral vector, which expresses no viral gene products, for gene transfer into the mammalian heart. Previous studies have used recombinant viral vectors, which retained viral genes and yielded mostly short-term expression, often with significant inflammation.

Methods. An adeno-associated virus vector was used that contains no viral genes and is completely free of contaminating helper viruses. The adeno-associated virus vector was applied to rat hearts by direct intramuscular injection; adeno-associated virus was also infused into pig hearts in vivo via percutaneous intraarterial infusion into the coronary vasculature using routine catheterization techniques.

Results. Gene transfer into rat heart yielded no apparent inflammation, and expression was observed for at least 2 months after injection. Infusion into pig circumflex coronary arteries resulted in successful transfer and expression of the reporter gene in cardiac myocytes without apparent toxicity or inflammation; gene expression was observed for at least 6 months after infusion.

Conclusions. We report the use of adeno-associated virus vectors in the cardiovascular system as well as successful myocardial gene transfer after percutaneous coronary artery infusion of viral vectors in a large, clinically relevant mammalian model. These results suggest that safe and stable gene transfer can be achieved in the heart using standard outpatient cardiac catheterization techniques.     

Cardiospecific expression of AAV vectors

Adenoviral vectors have been set for cardiomyocyte gene therapy with considerable transfection rates. However, due to adenoviral immunogenicity, adenoviral transfected cells are frequently subject to specific cellular immune reactions leading to loss of cells and transgene expression. Non‐pathogenic adeno associated vectors lacking immunogenicity have been utilized alternately. Tropism of the most common AAV serotype 2, favoring liver of muscle transfection, has been altered by use of serotypes 1, 6 and 9. We used a model of chronic (4 weeks) regional myocardial transfection of the pig to investigate transfection efficacy of AAV vectors, which were applied to the target region by retroinfusion. Cardiac restriction was ensured by utilization of an MLC‐2v promoter‐CMV‐enhancer construct, fused to a luciferase reporter gene, the activity of which was analyzed. Compared to the wildtype (WT) AAV 2 vector, which barely exceeded background luciferase activity, a vector lacking the heparin binding site of the envelope (AAV2 ΔHep) improved expression only slightly. Substantial increase to 40 000 RLU/mg tissue) was achieved by the addition of VEGF‐A, which enhances vascular permeability. A further 15‐fold increase of luciferase activity was achieved by applying an equal amount of AAV6 virus particles to a pig heart, with a further 5–10 fold increase achieved by utilization of AAV serotype 9. Functionally relevant gene transfer was ensured by applying AAV9 hVEGF/PDGF (0.2/0.4 × 10¹³ virus particles, respectively). 4 weeks after retroinfusion into pig hearts suffering from chronic total LAD‐occlusion (induced by a reduction stent), we found a significant increase of blood flow and regional myocardial function. We conclude that AAV9 is a more efficient AAV vector when compared to WT‐ or ΔHep‐AAV2 or AAV6. Functionally relevant gene expression, as performed by VEGF‐A/PDGF transfection, opens the door for utilization of this vector system for xenotransplant organ priming.     

Sodium iodide symporter (hNIS) permits molecular imaging of gene transduction in cardiac transplantation

BACKGROUND: We evaluated the feasibility of noninvasive micro-single photon emission computed tomography (SPECT)/computed tomography (CT) imaging and quantification of cardiac gene expression after sodium iodide symporter (hNIS) gene transfer in cardiac transplantation. METHODS: Donor rat hearts were perfused ex vivo with adenovirus expressing hNIS (Ad-hNIS), Ad-Null, or University of Wisconsin (UW) solution prior to heterotopic transplantation into syngeneic recipients. In the first group of recipients, imaging of the transplanted hearts with micro-SPECT/CT on day 5 was followed by immediate explant of the organs for ex vivo analyses. Radioactivity counts in the explanted hearts were obtained ex vivo and expressed as a percentage of the injected dose per gram of tissue (%ID/g). Intensities of the SPECT images of the transplanted hearts were quantified and converted to radioactive counts using a standard equation. The second group of recipients was imaged sequentially after injection of I on days 2 to 14 after transplantation. RESULTS: Higher ex vivo radioiodine counts were noted in the hearts perfused with Ad-hNIS (1.04+/-0.2) compared to either the UW group (0.31+/-0.11, P<0.001) or the Ad-Null group (0.32+/-0.08, P<0.001). Image intensity in the Ad-NIS group (0.9+/-0.2) was also significantly higher than in the UW group (0.4+/-.03, P=0.003) or the Ad-Null group (0.5+/-0.1, P<0.05). Sequential imaging of Ad-NIS-perfused hearts between postoperative days 2 and 14 revealed peak image intensity at day 5. Overall, image intensities correlated with ex vivo counts of radioactivity (rho=0.74, P<0.05). CONCLUSIONS: These data demonstrate that hNIS gene transfer permits sequential real-time detection and quantification of reporter gene expression in the transplanted heart with micro-SPECT/CT imaging.     

The effect of platelet-derived growth factor ligands in rat cardiac allograft vasculopathy and fibrosis

BACKGROUND: In chronic rejection, parenchymal fibrosis and cardiac allograft vasculopathy (CAV) characterized by neointimal growth are the leading causes of graft loss for heart transplant recipients. During alloimmune responses a variety of cytokines, adhesion proteins, and growth factors, such as platelet-derived growth factor (PDGF), are up-regulated. The PDGF family (AA, AB, BB, CC, DD), which acts mainly on connective tissue cells, is considered to be a potent mitogenic and chemotactic factor for fibroblasts and vascular smooth muscle cells. In this study, we evaluated the effects of PDGF ligands in chronic rejection. METHODS: Heterotopic heart transplantations were performed between fully major histocompatability complex-mismatched Dark Agouti to Wistar Furth rats receiving cyclosporine immunosuppression. Allograft coronary arteries were perfused with a recombinant adeno-associated virus (AAV) encoding enhanced green fluorescence protein (EGFP) as a control gene or PDGF-A, -B, -C, -D. Allografts were harvested at 100 days for morphometric analysis of CAV and fibrosis. RESULTS: AAV-mediated transgene expression was detected by EGFP immunoreactivity across the graft section (at 100 days) in AAV EGFP-perfused allografts. AAV PDGF-A, -C, and -D perfusion resulted in accelerated CAV and fibrosis. In contrast, AAV PDGF-B perfusion did not induce arteriosclerotic changes or fibrosis in cardiac allografts. CONCLUSIONS: AAV PDGF-A, -C, and -D overexpression accelerated the development of chronic rejection, whereas PDGF-B did not. Our results suggested that more targeted therapy with monoclonal antibodies blocking the active sites of PDGF-A, -C, and -D may produce beneficial effects on heart transplant survival.     

Immunogenicity of L(d+) transgenic mouse hearts

BACKGROUND: C57BL/6 mice transfected with the L(d) gene coupled to the alpha-myosin heavy chain promoter result in transgenic mice with L(d) antigen expressed only on cardiac tissue. These transgenic animals allow the examination of immune reactivity against cardiac L(d) by "self" or by adoptively transferred L(d) specific 2C cells, and the response of nontransgenic C57BL/6 mice to the transplanted L(d+) heart. METHODS: Na?ve cardiac L(d+) transgenic mice were examined for evidence of L(d) "autoimmunity." Forty million fresh 2C cells or 2C cells sensitized in vitro for 7 days against Balb/c (L(d+)) + interleukin-2 were also given intravenously to L(d+) transgenic mice. At 5 and 12 days after injection, heart-infiltrating lymphocytes were analyzed by fluorescence-activated cell sorter. The L(d+) transgenic hearts were also transplanted to syngeneic L(d-) nontransgenic C57BL/6 to evaluate the heart's immunogenicity. RESULTS: Na?ve L(d+) transgenic mice did not exhibit any evidence of lymphocytic infiltration on histologic examination. Adoptive transfer of either fresh or in vitro sensitized 2C cells was also unable to reject the native L(d+) heart in transgenic mice (100% of the mice survived long term [more than 60 days]). Sensitization of the L(d+) transgenic mice with a Balb/c skin graft and interleukin-2 pump infusion (7 days) beginning 1 day before 2C cell injection also did not promote rejection of the native L(d+) heart. However, fluorescence-activated cell sorter analysis did reveal that a significantly greater number of in vitro sensitized 2C cells homed to the L(d+), but not L(d-), heart after both 5 and 12 days (P <.01, P <.001). In contrast, C57BL/6 mice rejected the L(d+) (C57BL/6 background) transgenic heart in a mean survival time of 17 +/- 9.7 days (P <.01), whereas a syngeneic C57BL/6 heart transplant was accepted indefinitely. Lymphocytic infiltration consistent with rejection was present in all animals receiving an Ld+ transgenic heart transplant, whereas no infiltrate was present in those receiving a syngeneic C57BL/6 heart transplant. CONCLUSIONS: Although the class I L(d) transgene is not recognized in its native host, its immunogenicity is shown by the homing of anti-L(d) 2C cells to the heart in situ and rejection of L(d+) heart grafts when transplanted into syngeneic C57BL/6 mice.     

Regulated interleukin-10 expression prevents chronic rejection of transplanted hearts

OBJECTIVE: Interleukin-10 is a pleiotrophic cytokine with variable effects on the alloimmune response, depending on the experimental model system. The purpose of this study was to determine the role of regulated interleukin-10 expression on the development of chronic rejection in heart transplantation, or cardiac allograft vasculopathy. METHODS: Donor hearts from B6.C-H2(bm12) mice were transplanted into wild-type and interleukin-10 transgenic recipients. In interleukin-10 transgenic recipients, murine interleukin-10 cytokine is produced under the control of human interleukin-2 promoter. Donor hearts were sacrificed at days 7 and 24. No immunosuppression was used. Intimal proliferation was measured morphometrically. Intragraft cellular infiltrate was defined by both immunohistochemistry and flow cytometry. Intracellular cytokine staining assay was performed to determine both the type and source of intragraft cytokines. RESULTS: Hearts transplanted into wild-type recipients developed severe cardiac allograft vasculopathy by 24 days. Intimal lesions were absent in the donor hearts transplanted into interleukin-10 transgenic recipients. The number of graft-infiltrating T lymphocytes and the percentage of interleukin-2/interferon-gamma producing T lymphocytes were markedly reduced in interleukin-10 transgenic recipients. Finally, the overexpression of interleukin-10 resulted in the decline of graft-infiltrating macrophages at all time points. CONCLUSIONS: Regulated expression of interleukin-10 inhibits cardiac allograft vasculopathy development via reduction of mononuclear cell recruitment and alteration of their cytokine profile. This strategy may prove beneficial in controlling the alloimmune response in solid organ transplants.     

Ex vivo and systemic transfer of adenovirus-mediated CTLA4Ig gene combined with a short course of FK506 therapy prolongs islet graft survival

Adenovirus-mediated CTLA4Ig gene transfer has been reported to enhance graft survival in several rodent transplantation models. In this study, we investigated the efficacy of ex vivo and systemic transfer of the CTLA4Ig gene by adenoviral vectors in pancreatic islet allo-transplantation. Islet grafts from BN rats were transplanted to chemically induced diabetic LEW rats. First, ex vivo CTLA4Ig gene transfer into isolated islets was performed prior to transplantation. Survival of transduced grafts under the kidney capsule was slightly prolonged (8.6+/-1.3 days) compared with survival of untransduced grafts (6.7+/-1.2 days); when combined with a short course of FK506, graft survival was further extended (32.6+/-10.7 days vs. 13.7+/-1.0 days with FK506 alone). Secondly, systemic gene transfer was accomplished by intravenous administration immediately after the transplantation procedure. In these animals, islet grafts under the kidney capsule survived longer (15.2+/-3.3 days) than in controls (6.7+/-1.2 days), and when FK506 was administered perioperatively, all the islet grafts survived for more than 100 days. In systemically transduced recipients, the survival of islet grafts transplanted into the liver was not significantly different from that of the grafts placed under the kidney capsule. In order to examine organ-specific immunogenicity, heterotopic BN cardiac grafts were transplanted to LEW rats intra-abdominally, with the virus transferred systemically as in the islet model. In contrast to the islet grafts, all the cardiac grafts were accepted for longer than 100 days, even without FK506 therapy. Finally, the LEW recipients with long-surviving islet or cardiac grafts were re-transplanted with islet grafts from the same donor strain (BN) on day 100. The second islet grafts survived longer than 100 days in half of the cardiac recipients, but consistently failed in the islet recipients. We conclude that in this transplant model, CTLA4Ig gene transfer and FK506 treatment synergistically improved islet graft survival, systemic transfer of the gene was more effective than ex vivo transfer to the islets, and donor-specific tolerance could not be achieved for islet transplantation but was achieved for cardiac transplantation.     

Activation of beta2-adrenergic receptor plays a pivotal role in generating the protective effect of ischemic preconditioning in rat hearts

BACKGROUND: Ischemic preconditioning (IPC) protects hearts against ischemia by reducing infarct size. However, IPC does not preserve cardiac function, such as left ventricular peak developed pressure (LVPDP). Moreover, IPC fails to protect the post-myocardial infarct (MI) heart. DESIGN: Rat hearts were transfected with beta2-adrenergic receptor (B2AR) cDNA by the hemagglutinating virus of Japan-liposome method. After the gene transfer, the hearts were perfused in a Langendorff mode and preconditioned with two cycles of 5 min of ischemia and reperfusion. After 20 min of global ischemia, the hearts were reperfused under aerobic conditions for 90 min. LVPDP was measured as an indicator of the cardiac function. RESULTS: LVPDP of ischemic hearts was well preserved by the combination treatment of IPC and gene transfer of B2AR, but not IPC or gene transfer of B2AR alone. Moreover, the treatment was beneficial to even the post-MI heart. On the contrary, gene transfer of beta-adrenergic receptor kinase 1 (BARK1) reduced the protective effect of IPC. We also found that the mRNA ratio of B2AR and BARK1 was well correlated with the preservation of the LVPDP. CONCLUSIONS: The combination treatment of IPC and gene transfer of B2AR protects cardiac function against ischemia and it shows the beneficial effect also in post-MI hearts.     

Expression of fetal isoforms of actin after transplantation injury

Trauma and injury to transplanted organs in the early post-transplant period are significant factors that affect long-term graft survival. Fetal isoforms of actin are integral members of the immediate early gene family and are expressed in response to free radical injury. We therefore studied actin gene expression in heart transplantation to determine if reperfusion injury activates fetal isoforms of actins. Heterotopic cardiac transplantations were performed in mice. mRNA was extracted from allo- and isografted hearts as well as from normal hearts and spleen. Northern hybridization with actin cDNA to alpha and beta/gamma actin mRNA was performed and analyzed by densitometry. The beta/gamma actin gene expression in the transplanted hearts was found to be significantly elevated within 48 h after transplantation. Analysis of beta/gamma actin gene expression in isografts substantiates the possibility of de novo increase in actin expression.Our studies demonstrate for the first time that fetal isoforms of actin are induced in the allograft heart after transplantation.     

Pseudotyped adeno‐associated viral vector tropism and transduction efficiencies in murine wound healing

Cell specific gene transfer and sustained transgene expression are goals of cutaneous gene therapy for tissue repair and regeneration. Adeno‐associated virus serotype 2 (AAV2/2) mediated gene transfer to the skin results in stable transgene expression in the muscle fascicles of the panniculus carnosus in mice, with minimal gene transfer to the dermal or epidermal elements. We hypothesized that pseudotyped AAV vectors may have a unique and characteristic tropism and transduction efficiency profile for specific cells in the cutaneous wounds. We compared transduction efficiencies of cells in the epidermis, cells in the dermis, and the fascicles of the panniculus carnosus by AAV2/2 and three pseudotyped AAV vectors, AAV2/5, AAV2/7, and AAV2/8 in a murine excisional wound model. AAV2/5 and AAV2/8 result in significantly enhanced transduction of cells both in the epidermis and the dermis compared to AAV2/2. AAV2/5 transduces both the basilar and supra‐basilar keratinocytes. In contrast, AAV2/8 transduces mainly supra‐basilar keratinocytes. Both AAV2/7 and AAV2/8 result in more efficient gene transfer to the muscular panniculus carnosus compared to AAV2/2. The capsid of the different pseudotyped AAV vectors produces distinct tropism and efficiency profiles in the murine wound healing model. Both AAV2/5 and AAV2/8 administration result in significantly enhanced gene transfer. To further characterize cell specific transduction and tropism profiles of the AAV pseudotyped vectors, we performed in vitro experiments using human and mouse primary dermal fibroblasts. Our data demonstrate that pseudotyping strategy confers a differential transduction of dermal fibroblasts, with higher transduction of both human and murine cells by AAV2/5 and AAV2/8 at early and later time points. At later time points, AAV2/2 demonstrates increased transduction. Interestingly, AAV2/8 appears to be more efficacious in transducing human cells as compared to AAV2/5. The pseudotype‐specific pattern of transduction and tropism observed both in vivo and in vitro suggests that choice of AAV vectors should be based on the desired target cell and the timing of transgene expression in wound healing for gene transfer therapy in dermal wounds.     

Adeno-associated virus-mediated CTLA4Ig gene transfer protects MHC-mismatched renal allografts from chronic rejection

Short-term results of renal transplantation have improved considerably in the past 20 yr; however, similar improvements in long-term outcome have not been achieved. The primary cause of late graft loss is chronic rejection that might be treated by gene therapeutic approaches. Ideally, one would like to impair locally the contact between transplant antigen and the host immune system without compromising the generalized immune competence of the recipient. This can be achieved by local expression of the therapeutic protein in the site of interest using gene therapy. Here it is shown that chronic allograft rejection can be prevented effectively by local delivery of recombinant adeno-associated virus (AAV) vectors that encode the CTLA4Ig immunosuppressant protein to the donor kidney in a fully MHC-mismatched rat strain combination. AAV CTLA4Ig prevented progressive proteinuria and protected transplant kidneys from renal structural injury. A population of anergic T cells with regulatory activity, which eventually were responsible for the induction of tolerance, were found in recipient lymph nodes and in the graft as long as 120 d after transplantation. These data indicate that AAV-mediated CTLA4Ig gene transfer to donor graft represents a promising tool to prevent the onset of chronic rejection and circumvent the unwanted systemic adverse effects of the administration of immunomodulatory protein.     

Hepatocyte-based gene therapy

Hepatocyte-based gene therapy may be used to replace a missing gene product, confer proliferating ability to cultured hepatocytes, prevent allograft rejection, massively repopulate the host liver, or grow xenogeneic hepatocytes in mammalian liver. Gene transfer into isolated hepatocytes can be accomplished via nonviral or viral vectors, the viral vectors being more useful at this time. Common recombinant viruses that integrate into the host genome include murine leukemia retroviruses and lentiviruses, adenoassociated virus, and the T-antigen-deleted SV40 virus. Episomal viruses, such as adenoviruses, permit efficient gene transfer, but the transgene is lost upon proliferation of the transplanted hepatocyte in the host. Hybrid viruses that combine the high transduction efficiency of adenoviral vectors and the integrative capacity of other vectors, such as adenoassociated viruses, have been designed. Massive repopulation of the liver by transplanted hepatocytes can be achieved if a mitotic stimulus to the transplanted cells is combined with prevention of proliferation of the host hepatocytes. Treatment with a plant alkaloid or retrorsine, or preparative irradiation of the liver can be used to inhibit host hepatocellular proliferation, while partial hepatectomy, expression of Fas ligand, or thyroid hormone administration can be used as a mitotic stimulus to the transplanted cells. Received: July 4, 2000 / Accepted: October 13, 2000     

Gene transfection of beta 2-adrenergic receptor into the normal rat heart enhances cardiac response to beta-adrenergic agonist.

BACKGROUND: Beta-adrenergic receptor system has a major role in cardiac contraction. If the receptor can be increased by gene transfection by means of intracoronary infusion of beta 2-adrenergic receptor to the hearts in which the receptor is down-regulated, this maneuver may improve the cardiac function and may be applied as one therapeutic approach during cardiopulmonary bypass or percutaneous cardiopulmonary support. Methods and results: The beta 2-adrenergic receptor complementary DNA was transfected in vivo to the normal rat heart by intracoronary infusion by means of a hemagglutinating virus of Japan liposome method, and the transfected heart was transplanted into the abdomen of another rat. Four days after transfection, the sarcolemma of the cardiomyocytes was well labeled by immunohistochemical labeling. Expression of beta-adrenergic receptor in the heart was approximately 4 times greater than that in control hearts (134 +/- 42 vs 33 +/- 4 fmol/mg protein) according to a ligand binding assay. The cardiac response of the transfected heart to isoproterenol was shown to be enhanced in a Langendorff perfusion system: after isoproterenol, developed pressure and maximal derivative of the left ventricle were greater than in the control heart (200 +/- 12 vs 174 +/- 6 mm Hg and 4110 +/- 130 vs 3491 +/- 255 mm Hg/sec), and the minimal derivative of the left ventricle was markedly smaller (-3040 +/- 267 vs -2528 +/- 131 mm Hg/sec). CONCLUSIONS: These results indicate that expression of beta 2-adrenergic receptor was approximately 4 times greater than in normal rat hearts by gene transfection using a hemagglutinating virus of Japan liposome method, and the transfected hearts demonstrated marked enhancements in cardiac response to beta-agonist, suggesting that transfer of this gene by intracoronary infusion has potential as a novel approach to enhance cardiac function.     

Composite ''Thymoheart'' Transplantation Improves Cardiac Allograft Survival

We have generated a novel composite organ, the thymoheart, which facilitates the contemporaneous transfer of fully vascularized and functional donor thymic tissue to the host at the time of cardiac transplantation. Composite thymoheart allografts were prepared in MHC-inbred miniature swine by implanting autologous thymic tissue into donor hearts 60-90 days before organ procurement. Thymoheart allografts and unmanipulated control hearts were then transplanted into three groups, each treated with the same 12 days of cyclosporine. MHC-matched thymohearts transplanted into euthymic recipients had a minimum survival ranging between 72 and 194 days vs. 42-64 days for unmanipulated control hearts (p = 0.02). MHC class I-disparate thymohearts transplanted into euthymic recipients had a minimum survival ranging between 64 and 191 days vs. 30-55 days for unmanipulated control hearts (p = 0.01). MHC class I-disparate thymohearts transplanted into thymectomized recipients survived between 41 and 70 days vs. 8-27 days for unmanipulated control hearts (p = 0.01). Cellular and humoral functional assays, and skin grafting, confirmed the presence of donor-specific hyporesponsiveness in long-term thymoheart allografts recipients. The transfer of vascularized, functional donor thymic tissue to the host at the time of cardiac transplantation may provide a novel approach to the induction of tolerance in human heart transplant recipients.     

Intrathymic alloantigen-mediated, tolerant, completely major histocompatibility complex-mismatched mouse hearts are specifically rejected by adoptively transferred anti-class I L(d+)-specific 2C cells

BACKGROUND: Tolerance to cardiac allografts can be induced in mice and rats by the injection of donor alloantigen into the thymus in combination with a CD4 T-cell-depleting antibody. CD8(+) cells in these animals are hyporesponsive to graft-specific alloantigens. Most of the CD8(+) T cells in the transgenic 2C mouse express a T-cell receptor specific for the class I major histocompatibility complex L(d+) locus. This study was designed to determine whether the adoptive transfer of these 2C T cells could precipitate rejection of a tolerant, completely major histocompatibility complex-mismatched L(d+) or L(d-) heart. METHODS: C57BL/6 mice (L(d-)) were given 10 x 10(6) cells of BALB/c (L(d+)) or dm2 (BALB/c background lacking L(d) [L(d-)]) splenocytes intrathymically and GK1. 5 (10 mg/kg) intraperitoneally. Twenty-one days later, BALB/c or dm2 hearts were transplanted. On the day of transplantation or after long-term allograft acceptance, recipients received naive 2C cells or 2C cells sensitized by in vitro mixed lymphocyte culture with BALB/c (L(d+)). RESULTS: Mean survival time of BALB/c cardiac allografts in untreated C57BL/6 mice was 7.3 days, although 73% of the mice that were pretreated with BALB/c splenocytes IT plus GK1.5 accepted the donor antigen-specific heart allografts indefinitely. All recipients that were pretreated with the intrathymic plus GK1.5 and that were injected with naive 2C cells at the time of heart transplantation experienced rejection of the BALB/c (L(d+)), but not the dm2 (L(d-)) hearts. In contrast, naive 2C cells could not reject tolerant (>30 days acceptance) BALB/c (L(d+)) hearts. 2C cells sensitized in vitro against L(d) were able to reject established BALB/c hearts but could not reject the L(d-) dm2 hearts. CONCLUSIONS: L(d)-specific 2C T-cell receptor transgenic T cells that are adoptively transferred to recipients will precipitate the rejection of accepted hearts that express class I L(d+) in mice rendered tolerant by an intrathymic injection of alloantigen plus anti-CD4 monoclonal antibodies.