Prevention of recurrent autoimmune diabetes in BB rats by anti-asialo-GM1 antibody

BB rats exhibit a syndrome of spontaneous diabetes that has clinical and pathological characteristics analogous to those found in human insulin-dependent diabetes mellitus (IDDM). Islet tissue transplanted into spontaneously diabetic BB rats is uniformly destroyed by a recurrence of the autoimmune response that destroyed the diabetic subject's native islets. To examine recurrent autoimmune destruction of transplanted islets, it is necessary to exclude islet damage that might result from allograft rejection. We utilized neonatal tolerance induction to prevent rejection of Wistar-Furth (WF) (RT1u) islet allografts by spontaneously diabetic BB recipients. We determined that islet-recipient treatment with anti-asialo-GM1 (anti-AGM1) antibody prevents recurrent autoimmune diabetes that would otherwise destroy transplanted WF islet grafts. Anti-AGM1 therapy significantly decreased peripheral blood natural killer (NK) cell activity. These data suggest a role for NK cells in the pathogenesis of recurrent diabetes in neonatally tolerant BB rats.     

Insulin-mimicking anti-idiotypic antibodies in development of spontaneous autoimmune diabetes in BB/E rats

BB/E rats spontaneously develop a form of autoimmune diabetes resembling insulin-dependent diabetes mellitus (IDDM) in humans. IDDM results from central destruction of the insulin-producing beta-cells of the pancreatic islets. Herein, we report that the outbreak of IDDM in BB/E rats is preceded by the spontaneous development of an anti-idiotypic antibody to a particular antibody to insulin made by the rats. This anti-idiotype, designated anti-DM-id, behaves as an antibody to the insulin-hormone receptor. Thus, a spontaneous anti-idiotypic antibody network whose products can affect the peripheral utilization of insulin seems to accompany the central destruction of beta-cells in developing IDDM.     

Macrophage-mediated islet cell cytotoxicity in BB rats

Islet cell killing mediated by natural killer cells and T-lymphocytes in diabetes-prone (DP) and diabetic BB rats has been described, but other killing mechanisms may also be involved. Histopathologic studies suggest that macrophages are the first immune cells to infiltrate islets. To determine if macrophages are the first cells mediating islet damage, macrophage-mediated cytotoxicity was evaluated in BB rats of different ages. Splenic macrophages isolated from DP rats at 33, 100, 120, and 140 days of age showed no enhanced islet killing compared with diabetes-resistant rats. Killing at diabetes onset (121 +/- 14 days) was markedly increased (43 +/- 9.3%) compared with age-matched diabetes-resistant controls (19 +/- 8.3%, P less than .001). Islet inflammation was monitored at all time points. At 120 and 140 days of age, 9 of 11 (82%) DP rats had insulitis, and cytotoxicity was increased in 6 of 11 (55%) rats, which is similar to the number of DP rats that progress to diabetes. At 100 days, 3 of 6 (50%) DP rats again showed diabetic levels of killing, even in the absence of insulitis. These data indicate that 1) islet inflammation is dissociated from clinical diabetes onset, 2) splenic macrophages may have islet-killing potential before islet inflammation, 3) macrophage-mediated islet killing is elevated in all animals immediately after diabetes onset, and 4) macrophages, in addition to natural killer cells and T-lymphocytes, are responsible for cell-mediated islet destruction and thus are candidates for the first cellular effector to result in islet killing.     

Autonomic neuropathy in BB rats and alterations in bladder function

In vivo urinary bladder function was examined in BB rats after 4 and 6 mo of diabetes, and the data were correlated with morphometric changes in the pelvic and hypogastric nerves, which constitute the micturition reflex arc. After controlled bladder distension, diabetic animals revealed irregular bladder contractions at frequencies that were reduced to 33% of normal values and with significantly increased amplitudes. The abnormal micturition in diabetic animals was elicited at moderately elevated threshold volumes. These functional abnormalities of the diabetic bladder were associated with a progressive axonopathy of afferent myelinated sensory fibers and later-occurring axonal atrophy of unmyelinated efferent preganglionic fibers. These data suggest that diabetic urinary bladder dysfunction is initiated by a visceral sensory neuropathy involving the afferent limb of the micturition reflex arc.     

Inhibitor of calmodulin and cAMP phosphodiesterase activity in BB rats

Diabetes mellitus in humans is associated with increased plasma and tissue levels of cAMP and decreased cAMP phosphodiesterase (PDE) activity. Calmodulin (CM) is a low-molecular-weight protein essential for activation of cAMP PDE. The inhibitor (INH) is a low-molecular-weight substance that inhibits the activity of CM in multiple systems, including PDE. Spontaneously diabetic BB rats (SDR) and their nondiabetic littermates (NDR) were used in this study. Holtzman rats were rendered diabetic by streptozocin (STZ). STZ-induced diabetic rats (STZ-DR) and BB rats were studied with and without the benefit of insulin therapy. Calmodulin was assayed both by bioassay and by specific radioimmunoassay. The inhibitor was bioassayed by its ability to inhibit CM-activated PDE. Results showed that both spontaneous and STZ-induced diabetes are associated with a decrease in activity of the low-Michaelis constant (Km) cAMP PDE in the liver (39%, SDR; 70% STZ-DR). Calmodulin activity was also decreased in the livers of both animals (13%, SDR; 68%, STZ-DR). Similar data were obtained for NDRs. The inhibitor, on the other hand, was increased in the livers of untreated SDRs and STZ-DRs (155%, SDR; 125%, STZ-DR). No change was noted for NDRs. All these changes were restored toward normal after treatment with insulin. These data suggest that in diabetes the defect in the cAMP PDE-CM-INH system is demonstrated in both an environmental model, as illustrated by STZ-DRs, and a genetic model, as shown by SDRs and NDRs. The inhibitor activity, however, is not changed significantly in NDRs. We speculate that the inhibitor activity plays a role in dictating whether the genetic NDR will or will not become clinically diabetic.     

Thymectomy and radiation-induced type 1 diabetes in nonlymphopenic BB rats

Spontaneous type 1 diabetes in BB rats is dependent on the RT1(u) MHC haplotype and homozygosity for an allele at the Lyp locus, which is responsible for a peripheral T-lymphopenia. Genetic studies have shown that there are other, as yet unidentified, genetic loci contributing to diabetes susceptibility in this strain. BB rats carrying wild-type Lyp alleles are not lymphopenic and are resistant to spontaneous diabetes (DR). Here we show that thymectomy and exposure to one sublethal dose of gamma-irradiation (TX-R) at 4 weeks of age result in the rapid development of insulitis followed by diabetes in 100% of DR rats. Administration of CD4(+)45RC(-) T-cells from unmanipulated, syngeneic donors immediately after irradiation prevents the disease. Splenic T-cells from TX-R-induced diabetic animals adoptively transfer type 1 diabetes to T-deficient recipients. ACI, WF, WAG, BN, LEW, PVG, and PVG.RT1(u) strains are resistant to TX-R-induced insulitis/diabetes. Genetic analyses revealed linkage between regions on chromosomes 1, 3, 4, 6, 9, and 16, and TX-R-induced type 1 diabetes in a cohort of nonlymphopenic F(2) (Wistar Furth x BBDP) animals. This novel model of TX-R-induced diabetes in nonlymphopenic BB rats can be used to identify environmental and cellular factors that are responsible for the initiation of antipancreatic autoimmunity.     

The alloimmune response and effector mechanisms of allograft rejection

Allograft rejection is the consequence of the recipient's alloimmune response to nonself antigens expressed by donor tissues. Allospecific T lymphocytes are activated by donor peptides which are presented in the context of major histocompatibility complex molecules by either donor or recipient antigen presenting cells. Antigen presenting cells also provide essential costimulatory signals which are required for T cell proliferation and differentiation into either helper or effector lymphocytes. Effector mechanisms of allograft rejection include those mediated by cytotoxic T lymphocytes, macrophages, natural killer cells, and B lymphocytes. Importantly, alloimmune responses are controlled by regulatory molecules which include membrane receptors and cytokines. Novel insights into the interactions between antigen presenting cells and T lymphocytes, and further understanding of how alloimmune responses are regulated, will help in developing effective antirejection and tolerance-inducing strategies.     

Islet transplantation in spontaneously diabetic BB/Wor rats

We investigated the effectiveness of islet transplantation as therapy in an animal model of spontaneous type I (insulin-dependent) diabetes mellitus. Grafting MHC-matched and -mismatched islets with the spontaneously diabetic BB rat as a model has been previously reported to result in recurrence of the disease in the grafted tissue. When transplanted with nonimmunogenic islets isolated by nonenzymatic culture, we found that MHC-matched grafts proved to be susceptible to disease recurrence when allowed to remain in situ until ketosis developed in the host. Conversely, the MHC-mismatched grafts did not succumb to the disease process despite the destruction of the beta-cell population of the endogenous pancreas. Four manifestly hyperglycemic BB/Wor rats received sufficient islet mass by allotransplantation to reverse this state. All four animals had ameliorated conditions, and three of the four were restored to a normoglycemic state. Recurrence of diabetes in the BB rat was not observed.     

Hypersecretion of gastric somatostatin in spontaneously diabetic BB rats

We previously reported that the BB diabetic rat is characterized by a reduction in pancreatic immunoreactive somatostatin (SLI) content, delta-cell mass, and delta-cell secretory reserve. Despite this, portal plasma SLI levels are elevated in diabetic animals and normalized by insulin therapy. These findings comprise indirect evidence for SLI hypersecretion by the gut in untreated BB rats. This study was undertaken with isolated stomach perfusions to investigate directly the secretory status of gastric delta-cells in this diabetic model. Isolated stomachs of three groups of insulin-treated diabetic, untreated diabetic, and nondiabetic control rats were perfused in situ under basal and glucagon-stimulated (5 nM) conditions. Untreated diabetic BB rats exhibited significant enhancement of basal and glucagon-stimulated gastric SLI release. Insulin treatment reduced gastric SLI release to significantly subnormal levels. More than 95% of basal and stimulated SLI released in diabetic BB and normal control rats coeluted with synthetic somatostatin-14 on Sephadex G-50 columns. We conclude that basal and stimulated gastric SLI release is increased in untreated BB rats and is suppressed with insulin therapy, gastric delta-cell hyperfunction accounts for portal vein hypersomatostatinemia characteristic of untreated diabetic BB rats, and somatostatin-14 is the main molecular form of SLI released from normal and diabetic stomachs.     

Specific class II histocompatibility gene polymorphism in BB rats

The BB rat spontaneously develops insulin-dependent diabetes mellitus of autoimmune etiology. From breeding studies, one of the genes necessary for the development of diabetes in these animals is linked to RT1, the rat major histocompatibility complex. To better define the BB rat's RT1-linked diabetogenic gene (RT1-DM), we have used restriction endonucleases BamH1 and EcoR1 in conjunction with an I-A alpha (class II mouse major histocompatibility complex) gene probe to study RT1 class II gene polymorphisms among diabetes-prone BB rats and the related non-diabetes-prone BBN rats. Both BB and BBN rats are indistinguishable RT1u by serologic methods. Four polymorphic chromosome types (la, lb, lla, and llb) were recognized among the control BBN rats. In contrast, all BB rats were homozygous (lla/lla). From the multiple breeding programs involved, we hypothesize that the BB rat's RT1-linked diabetogenic gene is linked to an l-A alpha-defined gene of the type lla chromosome. The ability to split the RT1u of BB rats will provide a powerful tool to localize and characterize RT1-DM.     

Macrophage effector mechanisms in melanoma in an experimental study.

BACKGROUND: The tumor-bearing state is known to induce immune dysfunction that contributes to increased infectious complications and tumor progression. However, the mechanisms underlying this immunosuppression remain unclear. HYPOTHESIS: Macrophage (MO) dysfunction may play a role in tumor-induced immunosuppression. DESIGN AND MAIN OUTCOME MEASURES: Using a murine model, this study investigated the effects of melanoma growth on peritoneal macrophage effector molecule and prostaglandin production, MO-mediated cytotoxicity, and candidacidal mechanisms. Female C57BL/6 mice were inoculated with 106 B16 melanoma cells or a salt solution subcutaneously. Mice were euthanized 3 weeks later and peritoneal MOs were harvested and assayed for nitric oxide, superoxide anion, tumor necrosis factor alpha, and prostaglandin E(2)production. Macrophage-mediated cytotoxicity against B16 melanoma targets and MO candidacidal mechanisms were also measured. RESULTS: Macrophage production of nitric oxide, superoxide anion, and tumor necrosis factor alpha were significantly decreased, while prostaglandin E(2)production was increased in MOs from melanoma-bearing mice. Concomitantly, MO-mediated cytotoxicity and candidacidal mechanisms were significantly impaired. CONCLUSIONS: Melanoma growth leads to decreased MO effector molecule production, increased prostaglandin E(2)production, and impaired MO cytotoxic and candidacidal mechanisms. These results may help explain the observed increased infectious complications in the tumor-bearing host. Strategies aimed at restoring MO function may have therapeutic potential.     

Bacterial phagocytosis and intracellular killing by alveolar macrophages in BB rats

Diabetic patients and animals show an increased susceptibility to bacterial infections due to impaired bactericidal function of various host-defense mechanisms. In our study, we examined the ability of alveolar macrophages (AMs) of the diabetic BB rat to phagocytize and kill Staphylococcus aureus bacteria. Groups of spontaneously diabetic BB rats with variable severity of diabetes were used and compared with non-diabetes-prone BB rats. AMs obtained from diabetic insulin-deficient BB rats showed a markedly decreased capacity to phagocytize and kill bacteria, a defect that was partially corrected after a period of aggressive insulin treatment. Glucose-intolerant BB rats and diabetes-prone BB rats who did not develop diabetes showed a normal AM function compared to non-diabetes-prone BB rats. The impaired phagocytotic and bactericidal functions of AMs appeared to be caused by a cellular abnormality associated with the degree of insulin deficiency.     

Dendritic cells and scavenger macrophages in pancreatic islets of prediabetic BB rats

Insulin-dependent diabetes mellitus (IDDM) is an autoimmune disease whose notorious pathologic feature is insulitis accompanied by destruction of beta-cells. In this morphological study, we examined the pancreatic events during the onset of diabetes in spontaneously diabetic BB/Organon rats. Dendritic cells were the first cells to accumulate around the islets, followed by lymphocytes. Scavenger macrophages and MHC class II-positive beta-cells were only seen late in the disease. These observations suggest a role for antigen-presenting dendritic cells in the onset of the beta-cell-specific autoimmune reaction and emphasize the necessity to distinguish between the several monocyte-macrophage subtypes in studies on the pathogenesis of IDDM.     

Immunological and metabolic concomitants of cyclosporin prevention of diabetes in BB rats

The metabolic and immunological effects of cyclosporin given to prevent diabetes in BB rats were examined. Diabetes-prone (BBdp) and normal (BBn) BB rats received either oral cyclosporin (10 mg X kg-1 X day-1 or its vehicle from age 30-150 days. Six of 21 (29%) vehicle-treated rats became glycosuric, with hyperglycemia, weight loss, and unremitting insulin requirements, and showed destruction of islet beta-cells. Five of 24 (21%) cyclosporin-treated rats became glycosuric, but none demonstrated weight loss, all required insulin only intermittently after onset, and all showed persistence of islet beta-cells. Cyclosporin induced hypoinsulinemic glucose intolerance in BBn rats. Cyclosporin inhibited the normal rise with age of peripheral blood lymphocyte cell numbers, identified with monoclonal antibodies. OX19+ (pan-T) and W3/25+ helper T-lymphocytes were affected, and there was an increase in the large W3/13+ OX19- population characteristic of BBdp rats; in addition, this subset appeared in BBn rats. Cyclosporin also caused the appearance and/or increase in both BBdp and BBn rats of W3/25+ OX19- and OX8+ OX19- subsets. Suppressor/cytotoxic (OX8+) T-lymphocytes and Ia+ cells were less affected. The incidence of hyperglycemia and glycosuria was therefore unaltered by cyclosporin, although the diabetic syndrome was milder. BBn rats receiving cyclosporin showed glucose intolerance, suggesting that in BBdp rats, the net effects of immunosuppression on beta-cell destruction may have been counterbalanced by the direct effect on the same cells. The attenuation of diabetes in BBdp rats occurred through further immunosuppression rather than by correction of its preexisting immunodeficiency.     

Biochemical studies of RT6 alloantigens in BB/Wor and normal rats. Evidence for intact unexpressed RT6a structural gene in diabetes-prone BB rats

Lymphocytes bearing the T-lymphocyte differentiation antigen RT6 play an important immunoregulatory role in the development of autoimmune diabetes in BB rats. Immunofluorescence studies suggest that diabetes-prone (DP)- but not diabetes-resistant (DR)-BB rat lymphocytes fail to express RT6 antigen during ontogeny. Two alloantigenic forms of the molecule exist, i.e., RT6.1 and RT6.2; both are linked to cell membranes by a phosphatidylinositol (PI) linkage. In these studies, PI-phospholipase C (PLC) treatment of lymphocytes from BB and normal rats followed by immunoabsorption and sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of released proteins with anti-RT6 allotype-specific monoclonal antibodies was performed. RT6.1 in several nondiabetic rat strains was found to consist of a family of nonglycosylated and variably glycosylated molecules: an N-Glycanase-resistant 24,000- to 26,000-Mr peptide and four N-Glycanase-sensitive peptides of 29,000, 31,000, 33,000, and 34,000 Mr. In contrast, RT6.2 was found to be a 24,000- to 26,000-Mr nonglycosylated polypeptide. The electrophoretic pattern of RT6.1 was observed to be the same when the antigen was extracted from W3/25+ (CD4+) versus W3/25- T lymphocytes or from resting versus mitogen-activated cells. A pattern of bands characteristic of the RT6.1 antigen found in normal rat strains was detected after PLC treatment or detergent solubilization of lymphocytes obtained from DR rats. In contrast, no evidence of either RT6 species was found after PLC or detergent treatment of comparable numbers of T lymphocytes from DP-BB rats. Interestingly, T lymphocytes from Wistar-Furth (RT6.2+) x DP (RT6-) F1 crosses were observed to coexpress both RT6.2 and RT6.1 molecules, with the electrophoretic pattern of RT6.1 being similar to that obtained in DR and other rat strains. This study provides biochemical evidence that DP rats may have an intact RT6a structural gene.     

Unaltered class II histocompatibility antigens and pathogenesis of IDDM in BB rats

The BB rat spontaneously develops insulin-dependent diabetes mellitus (IDDM) as an autoimmune abnormality involving the class II molecules of the major histocompatibility complex (MHC). The rat MHC (RT1 complex) encodes two class II loci, RT1.B and RT1.D. The possibility that variant or unique class II MHC molecules may be associated with IDDM susceptibility was directly examined by determining the nucleotide sequences of class II mRNAs and/or cDNAs from the diabetes-prone (DP) BB rat, the diabetes-resistant (DR) BB rat, the normal histocompatible Wistar-Furth (WF) rat, and the Lewis rat. Sequence analysis indicates that the beta-chains of the RT1.B and RT1.D molecules of the u haplotype from DP-BB, DR-BB, and WF rats are identical but that they are different from other rat alleles and published mouse class II sequences. At the nucleotide level, the NH2-terminal domain of RT1.D beta of the BB and WF rats differs by a single silent nucleotide substitution. Comparisons with the sequences of the Lewis rat indicate hypervariable allelic differences and that the u and I haplotypes are remarkably similar. These findings establish that the class II molecules of the DP-BB rat are not variant or unique and that unaltered class II molecules of the u haplotype support the autoimmune response in the BB rat.     

Time course of islet cell antibodies in diabetic and nondiabetic BB rats

The BB rat develops a spontaneous type I diabetic syndrome with anti-islet autoimmunity. Sera from diabetic and nondiabetic BB rats (from diabetes-prone litters), nondiabetic BB rats (from low-risk lines), and nondiabetes-prone Sprague-Dawley rats were collected twice a week from age 40 days to 160 days. Sera were tested for: (1) complement-dependent toxicity to 51Cr-labeled islet cells in vitro; (2) immunoglobulin binding to RIN-5 F insulinoma cells; and (3) ability to selectively suppress insulin secretion from normal islets in vitro. All sera from rats that subsequently became diabetic or glucose-intolerant were toxic to islet cells from various rat strains in the presence of complement. They were toxic neither to hepatocytes nor to fibroblasts. The toxic potency was associated with the globulin fraction. It was, in most cases, maximal either before or immediately after the onset of the disease. Sera from the nondiabetes-susceptible BB rats and the rats which, in diabetes-prone litters, died too early to be classified tended toward greater toxicity to islets. Immunoglobulins from diabetic sera bound to RIN-5 F cells more than did the serum globulins from other groups, their maximal binding capacity occurring after the onset of diabetes. Furthermore, BB diabetic sera were capable of selectively inhibiting the insulin secretion from normal rat islets in vitro either in the presence or, in some cases, in the absence of complement. The A- and D-cell functions were not suppressed. The combination of such results suggests the presence of one or more antibodies capable of binding to beta cells, inhibiting their function, and inducing their lysis.(ABSTRACT TRUNCATED AT 250 WORDS)