Guo-Du Wu

Carboxyfluorescein (CFSE) Labelling of Hepatocytes for Short-Term Localization following Intraportal Transplantation

Renewed interest in the transplantation of isolated hepatocytes into the liver as a potential therapy for liver disease has stimulated the development of methods for the identification of donor cells within the recipient organ. We describe a method for cellular tagging and in vivo identification of intraportally transplanted hepatocytes using an intracellular fluorescent dye, 5(6)-carboxyfluorescein diacetate, succinimidyl-ester (CFSE). Rat and porcine hepatocytes were isolated and labelled with CFSE. The optimal conditions for labelling consisted of a buffered saline suspension of hepatocytes (5 × 106 cells/mL) in 20.0 μM CFSE incubated for 15 min at 37°C. In vitro, labelled hepatocytes were cultured either on fibronectin-coated chamber slides or in culture flasks. Cultures were evaluated in situ by fluorescence photomicrography or by fluorescence-activated cell sorting (FACS) after cell detachment. Cell viability was assessed serially and cultured, labelled hepatocytes retained the dye for up to 3 wk (last day of study). CFSE did not effect hepatocyte viability and there was no evidence of intercellular diffusion of the dye. In vivo, syngeneic Lewis rats underwent selective portal vein infusion of freshly isolated, labelled hepatocytes (2.0 × 107 cells/2.0 mL saline/animal) into the posterior liver lobes. All recipients were sacrificed 48 h and 96 h later and their livers examined. Transplanted hepatocytes were identified by fluorescence microscopy in tissue sections and by FACS following collagenase digestion of the liver tissue. CFSE persisted in a population of viable, engrafted hepatocytes. FACS analysis demonstrated that 9 ± 3% of the hepatocytes in the posterior liver lobes were labelled 48 and 96 h after transplantation. At 96 h following transplantation, multiple engrafted hepatocytes could be observed by fluorescence microscopy around the central veins. CFSE labelling allows for both in vitro identification and in vivo localization of donor hepatocytes. Furthermore, it appears to be more stable and specific for labelling hepatocytes than other tested dyes (especially DiI).

Prevention of orthotopic liver allograft rejection in rats with a short-term brequinar sodium therapy : analysis of intragraft cytokine gene expression

Brequinar sodium (BQR) is a new immunosuppressive drug that is highly effective in preventing graft rejection in several different experimental settings, including primary allografts and xenografts. A short course of BQR treatment during the onset of allograft rejection can induce the permanent survival of liver and kidney allografts in rats. To study the molecular basis of BQR-induced prolongation of allograft survival, we analyzed the intragraft pattern of IL-1 alpha, IL-2, IL-2R, IL-4, IL-6, IL-10, and TNF gene expression in the ACI-to-LEW liver allograft model. A semiquantitative polymerase chain reaction was developed to measure cytokine gene expression in control and BQR-treated liver graft recipients at various days after transplantation. Untreated control liver allografts expressed all of the cytokines analyzed. There was a marked increase in the steady state level of transcripts for each cytokine as graft rejection proceeded. The treatment of liver graft recipients with 12 mg/kg/day of BQR on days 6, 7, and 8 after transplantation suppressed the expression of all these cytokines within 24 hr of administration. The early suppression of cytokine expression was associated with a modest but distinct reduction in the infiltration of inflammatory cells into the liver grafts. The reduction in the level of transcripts for IL-4, IL-6, and IL-10 persisted in long-term survivors (30 days after transplantation). In contrast, there was a significant increase in the level of transcripts for IL-1 alpha, IL-2, and IL-2R in these long-term survivors. Our results demonstrated clearly that the pattern of cytokine gene expression during allograft rejection is significantly altered by a 3-day course of therapy with BQR. The temporary down-regulation of cytokine gene expression may be responsible for an altered immunological state that results in the prolonged survival of liver allografts.

The prolongation of concordant hamster-to-rat cardiac xenografts by brequinar sodium.

Brequinar sodium (BQR) prevents cell proliferation by virtue of its inhibition of de novo pyrimidine biosynthesis. The immunosuppressive activity of BQR is highly effective in prolonging heart, liver, and kidney allograft survival in the rat. In these experiments, we have tested the ability of BQR to prevent the rejection of concordant cardiac xenografts. LEW inbred rats transplanted with heterotopic hamster hearts were treated orally with brequinar sodium as a single agent. The survival of the cardiac xenografts was significantly prolonged with a variety of treatment regimens. The most effective treatment was the daily oral administration of BQR at 3 mg/kg. At this level, the median graft survival was approximately 25 days. Four animals had hamster heart xenografts that functioned for more than 90 days. The prolonged survival of the xenografts was associated with relatively constant plasma drug levels of approximately 1 to 3 μg/ml and a marked suppression of IgM production. At rejection, there was a significant rise in IgM levels compared with those of recipients with stable xenografts. In vitro MLR responses were effectively inhibited by BQR, with an IC50 of 0.08 μg/ml. The results of these experiments demonstrate that BQR is a new immunosuppressive agent that is highly effective as a single agent in prolonging the survival of hamster-to-rat cardiac xenografts. The prolonged xenograft survival is associated with effective suppression of rat antihamster antibody production, suggesting that brequinar sodium may be an important addition to multidrug immunosuppressive regimes designed to prevent B and T lymphocyte—mediated immune responses.

Genetic control of the humoral immune response to xenografts. II. Monoclonal antibodies that cause rejection of heart xenografts are encoded by germline immunoglobulin genes.

The early phases of the rejection of xenografts exchanged between closely related species are dominated by a vigorous humoral immune response. We have recently used a linker-mediated polymerase chain reaction (LM-PCR) to generate Ig heavy and light chain-specific cDNA libraries to examine the Ig gene control of a prototypic IgM monoclonal antibody, HAR-1, that causes the hyperacute rejection of hamster xenografts. Recombinant clones from the library were screened directly from bacterial colonies by PCR and the nucleic acid sequences of the clones established. Our results demonstrate that the HAR-1 hybridoma is encoded by Ig VH and JH genes in a germline configuration. Comparison of the cDNA sequence for HAR-1 VH with the germline equivalent of this gene isolated from newborn LEW liver (provisionally designated VHHAR-1) showed that the two VH sequences share a nucleic acid identity of 99.3%. Similarly, the HAR-1 monoclonal uses a Ig JH gene that is 98.2% identical with the JH1 nucleic acid sequence available in the GeneBank. The use of Ig VH and JH genes in a germline configuration is similar to that seen with polyreactive natural antibodies to infectious agents and autoantibodies. These humoral responses are thought to be the result of the stimulation of a T cell-independent subset of B cells, the B-1a/B-1b subset, that is responsible for producing antibodies that serve as a primitive humoral (natural antibody) defense mechanism against infectious diseases. Our results suggest that the humoral component of the rejection of xenografts in the hamster-to-rat model may represent the stimulation of this type of B cell antibody response by xenogeneic target antigens that share antigenic epitopes with bacteria and other infectious agents.

Genetic control of the humoral immune responses to xenografts. I: Functional characterization of rat monoclonal antibodies to hamster heart xenografts

The rejection of cardiac xenografts in the hamster-to-rat combination is characterized by the production of IgM antibodies that result in the rapid loss of the graft. We have recently produced rat monoclonal antibodies (mAb) to hamster heart xenografts in an attempt to develop reagents for use in identifying the target antigens for this reaction and to study the nature of the genetic control of the humoral response. The monoclonals were created by the fusion of myeloma cells with splenic lymphocytes from LEW rat recipients of hamster cardiac xenografts. The hybridomas were screened for antibody production, reactivity to hamster cell surface antigens, and the ability to mediate hyperacute rejection of hamster heart xenografts. A panel of monoclonal antibodies has been identified that are capable of inducing hyperacute rejection. All of these mAbs are IgM and bind strongly to hamster vascular endothelium. None of the mAbs were lymphocytotoxic or bound to hamster lymphocytes or erythrocytes. Immunopathologic studies demonstrated that these mAbs react specifically with hamster vascular endothelium and mediate a complement-dependent humoral reaction leading to the destruction of the cardiac xenografts. One of the mAbs (designated as HAR-1) has been characterized in detail. HAR-1 detects antigens distributed in the vascular endothelium, epithelium of bronchi in the lung, small intestine, tubules of kidney, and selective components of lymphoid organs--e.g., the stromal cells of the spleen and thymic medullary epithelium. Western blot analysis of hamster heart proteins with HAR-1 showed multiple bands with two major bands migrating at 80 kDa and 48 kDa. Absorption of the HAR-1 antibody with 48 individual carbohydrate molecules demonstrated that the strongest reactivity of the antibody is with a sialyl-Lea carbohydrate antigen.

Xenoantibodies to pig endothelium are expressed in germline configuration and share a conserved immunoglobulin VH gene structure with antibodies to common infectious agents.

BACKGROUND The rejection of pig xenografts in humans is initiated by preformed antibodies that may be related to the natural antibodies that formulate a first line of defense against infectious agents. Immunoglobulin gene variable domains encoding the antibodies that react with similar epitopes expressed on xenoantigens and bacteria may share structurally similar antigen-binding site configurations. METHODS We sequenced the VH immunoglobulin genes and germline progenitors of two rat monoclonal antibodies that recognize pig xenoantigens. Nucleic and amino acid sequences of these xenoantibodies were compared with immunoglobulin genes encoding antibodies that react with bacteria or viruses. RESULTS AND CONCLUSIONS VH genes encoding rat anti-pig xenoantibodies are expressed in germline configuration and share structural similarities, including identical amino acids in key antigenic contact sites that define antibody canonical structural groups, with antibodies to infectious agents.

The humoral response to xenografts is controlled by a restricted repertoire of immunoglobulin VH genes.

BACKGROUND The early phases of the host immune response to xenografts are dominated by anti-donor antibodies. The immunological pathways responsible for mediating the host humoral responses to xenografts are largely unknown, and this report addresses the nature of the immunoglobulin genes controlling the host antibody response to xenografts. METHODS cDNA libraries established from rat anti-hamster monoclonal antibodies and splenic lymphocytes from LEW rats rejecting hamster heart xenografts were used to clone, sequence, and identify the immunoglobulin genes responsible for encoding rat xenoantibodies to hamster heart grafts. Libraries for germline variable region heavy chain (VH) genes encoding the anti-hamster xenograft antibodies were established by genomic DNA cloning and analyzed by nucleotide sequencing. The frequency of Ig VH gene usage for controlling the antibody responses to hamster xenografts was examined by colony-filter dot hybridization. The nucleic acid structure of these genes was then compared to their genomic progenitors to identify the number and structural diversity expressed by the Ig VH genes used to mediate the response. RESULTS Rat monoclonal antibodies selected for their ability to precipitate the rejection of hamster xenografts exclusively use a closely related group of VH genes. The VH genes used by these antibodies are restricted to a single family of germline genes (VHHAR) for which 15 family members have been identified. The frequency of VHHAR gene usage in splenic IgM-producing B cells from LEW rats rapidly expands from 0.8% in naive animals to 13% in recipients 4 days after xenotransplantation. cDNA libraries expressing VHHAR genes were established from splenic lymphocytes derived from naive or xenograft recipients at 4 and 21 days after transplantation. Examination of 20 cDNA clones revealed that the majority (75%) of these clones express VHHAR genes displaying limited somatic mutation. CONCLUSIONS The use of a closely related group of Ig VH genes in a germline configuration to control the early humoral response to xenografts suggests that this response may represent the utilization of a primitive, T cell-independent pathway of antibody production by the graft recipients.

Genetic control of the humoral responses to xenografts. III. Identification of the immunoglobulin V(H) genes responsible for encoding rat immunoglobin G xenoantibodies to hamster heart grafts.

BACKGROUND We have previously reported that the early phases of the immune response of rats to hamster xenografts are characterized by the production of IgM xenoantibodies encoded by a restricted group of Ig germline V(H) genes (V(H)HAR family). In the later phases of the reaction, an IgM to IgG isotype switch occurs and our study examines the structure of the rearranged V(H)HAR genes used to encode IgG antibodies after this isotype switch. METHODS A quantitative polymerase chain reaction was used to investigate the changes in the levels of V(H)HAR+ IgG mRNA seen after xenotransplantation. cDNA libraries specific for V(H)HAR+ Iggamma chain were established from total RNA extracted from splenocytes of naive rats and xenograft recipients of hamster hearts at days 4, 8, 21, and 28 posttransplantation. Colony filter hybridization was used to estimate the relative frequency of the use of individual V(H)HAR+ IgG subclasses. Selected IgG clones from day 21 cDNA libraries were sequenced and analyzed for VH-D-J(H) gene usage and antibody combining site structure. RESULTS The level of mRNA for V(H)HAR+ IgG increased 6-fold in xenograft recipients at day 21 post-transplantation when compared with naive animals. The relative frequency of isotype usage for V(H)HAR+ IgG1 antibodies alone increased from 22.3% at day 0 to 37.4% at day 21 PTx. Ten IgG clones from the day 21 cDNA libraries have been sequenced for the rearranged V(H)-D-J(H) genes. Thirty percent (3/10) of these IgG clones used V(H)HAR genes for the coding of heavy chain variable region with limited numbers of nucleic acid substitutions (>98% identity with their germline progenitors) although others demonstrated increased variation in nucleotide sequences (95-97% identity) when compared with germline V(H) genes. Analysis of the canonical binding site structure from the predicted amino acid sequences demonstrated that the majority of IgG clones (9/10) displayed a similar pattern of conserved configurations for their combining sites. CONCLUSIONS The change in IgM to IgG antibody production in the later stages of the humoral immune response of rats to hamster xenografts is associated with an IgM to IgG isotype switch and an increased production of antibodies of the IgG1 isotype. Rat anti-hamster IgG xenoantibodies continue to express the V(H)HAR family of V(H) genes, many in their original germline configuration, to encode antibody recognition of the hamster target antigens. There are, however, a majority of antibodies for which the V(H) genes express evidence of increased nucleic acid sequence variation when compared to currently available germline sequences. The source of this variation is not known but may represent the expression of as yet unidentified germline genes and/or the introduction of T cell-driven somatic mutations. Despite the appearance of this variation, the unusual level of conservation in key antigen binding sites within the V(H) region suggests the variation, independent of its origin, may have a limited influence on the restricted nature of the host antibody response to xenografts.

The prevention of accelerated cardiac allograft rejection in sensitized recipients after treatment with brequinar sodium.

Brequinar sodium (BQR) is a novel immunosuppressive agent that is highly effective in preventing B lymphocyte-mediated antibody production. We have examined the effects of BQR treatment in sensitized recipients on graft survival, donor-specific antibody responses (IgM and IgG), and the appearance of immunopathological lesions present in the grafts. LEW rat recipients were sensitized with single ACI skin graft on day 7 and received heterotopic ACI cardiac grafts on day 0. The recipients rejected the cardiac grafts in an accelerated fashion at day 2.5 post-transplantation, compared to day 7.0 in unsensitized recipients. The animals were treated with low (3 mg/kg/day) or high (12 mg/kg/3× weekly) doses of BQR during skin graft sensitization and/or after challenge with ACI heart allografts. All groups treated with BQR showed significant prolongation of graft survival in the sensitized recipients. The best survival was observed following high-dose BQR therapy during both sensitization and effector phases (median survival time = 40.0 days, P ≪ 0.001). Daily treatment with BQR (3 mg/kg/day) prevented IgM (but not IgG) antibody responses. Treatment with higher doses of BQR (12 mg/kg/3× weekly) before and after skin graft sensitization was effective in preventing both IgM and IgG production. In general, BQR treatment resulted in effective suppression of anti-donor antibody responses, stable graft function, and a reduction in the severity of the acute vascular lesions in the graft. The effectiveness of BQR in preventing accelerated graft rejection when used at 12 mg/kg/3× weekly was comparable to that seen with treatment of sensitized animals with CsA at 15 mg/kg/day for 30 days. Daily treatment with cyclophosphamide at 5 or 15 mg/kg/day was ineffective for preventing graft rejection in sensitized recipients. These results indicated that BQR may provide an important addition to treatment protocols designed to prevent transplantation rejection in presensitized patients. BQR has the ability to significantly inhibit host cellular and humoral immune responses to the donor graft and this facet of the immunosuppressive activity of the drug may be responsible for preventing this aggressive form of rejection.