Hyperproinsulinaemia in obese fat/fat mice associated with a carboxypeptidase E mutation which reduces enzyme activity.

Mice homozygous for the fat mutation develop obesity and hyperglycaemia that can be suppressed by treatment with exogenous insulin. The fat mutation maps to mouse chromosome 8, very close to the gene for carboxypeptidase E (Cpe), which encodes an enzyme (CPE) that processes prohormone intermediates such as proinsulin. We now demonstrate a defect in proinsulin processing associated with the virtual absence of CPE activity in extracts of fat/fat pancreatic islets and pituitaries. A single Ser202Pro mutation distinguishes the mutant Cpe allele, and abolishes enzymatic activity in vitro. Thus, the fat mutation represents the first demonstration of an obesity-diabetes syndrome elicited by a genetic defect in a prohormone processing pathway.

Quantitative lymphatic vessel trait analysis suggests Vcam1 as candidate modifier gene of inflammatory bowel disease.

Inflammatory bowel disease (IBD) is a chronic debilitating disease resulting from a complex interaction of multiple genetic factors with the environment. To identify modifier genes of IBD, we used an F2 intercross of IBD-resistant C57BL/6J-Il10(-/-) mice and IBD-susceptible C3H/HeJBir-Il10(-/-) (C3Bir-Il10(-/-)) mice. We found a prominent involvement of lymphatic vessels in IBD and applied a scoring system to quantify lymphatic vascular changes. Quantitative trait locus (QTL) analyses revealed a large-effect QTL on chromosome 3, mapping to an interval of 43.6 Mbp. This candidate interval was narrowed by fine mapping to 22 Mbp, and candidate genes were analyzed by a systems genetics approach that included quantitative gene expression profiling, search for functional polymorphisms, and haplotype block analysis. We identified vascular adhesion molecule 1 (Vcam1) as a candidate modifier gene in the interleukin 10-deficient mouse model of IBD. Importantly, VCAM1 protein levels were increased in susceptible C3H/HeJ mice, compared with C57BL/6J mice; systemic blockade of VCAM1 in C3Bir-Il10(-/-) mice reduced their inflammatory lymphatic vessel changes. These results indicate that genetically determined expression differences of VCAM1 are associated with susceptibility to colon inflammation, which is accompanied by extensive lymphatic vessel changes. VCAM1 is, therefore, a promising therapeutic target for IBD.

Murine macrophages and pancreatic beta cells. Chemotactic properties of insulin and beta-cytostatic action of interleukin 1.

This study has used in vitro techniques to investigate the potential interactions between mouse pancreatic islet cells and syngeneic macrophages (M phi). Islets strongly stimulated M phi migration from agarose microdroplets; insulin was the only one of four islet cell hormones tested that was effective individually. Chronic exposure of islet monolayers to recombinant mouse IL-1, an M phi secretory product, was not cytolytic, but inhibited insulin secretion, reduced intracellular insulin content, and produced beta cell-specific degranulation. These effects were unique to IL-1; another monokine, tumor necrosis factor, as well as the lymphokine IL-2, and lymphotoxin were all without effect on insulin secretion or monolayer viability at the concentrations tested. The potential pathological consequences of the chemoattractive action of insulin on M phi, and the inhibitory effect of IL-1 on insulin secretion, are discussed.

Glucose induces intracisternal type A retroviral gene transcription and translation in pancreatic beta cells.

C57BL/KsJ (BKs) and CBA/J, but not C57BL/6J (B6) mice are susceptible to the diabetogenic action of the obesity gene, "diabetes" (db). BKs and CBA/J, but not B6 mice, constitutively express intracisternal type A particles (IAP), an endogenous class of retrovirus, in beta cells and in cortical thymocytes. IAP genetic expression in these cell types included production of the group-specific antigen, p73, as well as higher-molecular mass p73-related antigens (p114-120). We used islet culture techniques to show that both transcription and translation of IAP genomes in beta cells in enhanced by glucose. Maintenance of CBA/J islets for 48 h in 16.5 mM glucose-containing medium effected a fivefold induction of IAP protein synthesis in comparison to islets cultured in low- (5.5 mM) glucose medium. Analysis of RNA from 16.5 mM glucose-cultured islets revealed induction of 7.2 and 5.4 kbp transcripts known to code for p73 and the p114-120 polypeptides, respectively. This induction in CBA/J islets was 10-15-fold on a tissue basis, and 5-7-fold on an RNA basis. Glucose induction of preproinsulin mRNA levels was also analyzed in the same samples. Islets cultured in 16.5 mM glucose showed an eightfold higher level on a tissue basis, and a fourfold increase in terms of total recovered RNA. Comparison of these glucose-inducible parameters in islets isolated from the diabetes-susceptible BKs strain vs. the resistant B6 strain revealed that expression of the group-specific retroviral p73 antigen was limited to BKs beta cells. This inbred strain control of p73 expression was also found in cortical thymocytes, with B6 thymocytes producing a 117 kD component to the exclusion of p73, while both components were expressed in thymocytes from normal BKs mice. In comparison to normal BKs males, thymocytes from four week-old genetically diabetic (db/db) BKs males showed no change in labeling of p117, but showed a sharply diminished incorporation into p73. This suggested that accelerated thymic involution characteristic of db/db mice may entail selective elimination of p73-producing cells. The possibility that glucose-stressed BKs pancreatic beta cells are marked for autoimmune elimination by the elaboration of p73 or other IAP-related proteins is discussed.

MHC antigen induction by interferon gamma on cultured mouse pancreatic beta cells and macrophages. Genetic analysis of strain differences and discovery of an "occult" class I-like antigen in NOD/Lt mice.

This study provides a basis for understanding the wide variations reported in the literature in IFN-gamma inducibility of class II MHC antigens on murine beta cells. Inducibility is not an intrinsic property of all mouse beta cells, but instead depends upon strain- (and tissue-) specific response modifying factors. This was demonstrated by comparison of constitutive and IFN-gamma-induced class I and class II MHC gene products on cultured islet cell monolayers. Islet cultures were established from autoimmune diabetes-prone NOD/Lt mice, diabetes-resistant NON/Lt and CBA/J mice, as well as F1 hybrids between these latter two strains and NOD/Lt. Cultures of peritoneal macrophages (M phi) from each strain were established as controls. After 3 wk of culture (with incubation in the presence or absence of IFN-gamma during the last 6 d), constitutive expression as well as IFN-gamma induction of class I MHC antigen expression was demonstrated on NOD/Lt and NON/Lt islet cells by antibody plus complement-mediated cytotoxicity. Although CBA/J islets and M phi did not maintain constitutive class I or class II antigen expression in culture in the absence of IFN-gamma, class I H-2Kk antigen was IFN-gamma inducible. Whereas IFN-gamma-induced class II I-Ak antigen on CBA/J M phi, it failed to induce this antigen on CBA/J islets. In contrast, I-A antigens were IFN-gamma inducible on NOD/Lt and NON/Lt islets and M phi. In (CBA x NOD)F1 hybrids, loss of IFN-gamma inducibility of the I-ANOD product established that suppression was mediated by a trans-acting factor from the CBA/J genome. In the course of these studies, IFN-gamma inducibility of a crossreactive occult class I-like antigen on both NOD/Lt islet cell and M phi cultures was unexpectedly detected when mAb 28-13-3 (public specificity 39, reactive with H-2Kb,f) was used as a negative control. Although not detectable by cytofluorographic analysis of freshly isolated NOD/Lt splenic leukocytes, occult antigen could be induced on NOD/Lt peritoneal macrophages (M phi) cultured for 3 d in IFN-gamma. Time course of induction showed the occult antigen to be distinct from NOD/Lt class I and II gene products. In both islet cell and M phi cultures established from (CBA x NOD)F1 hybrids, trans-suppressive factor(s) from the CBA/J genome not only suppressed IFN-gamma-induced expression of I-ANOD, but additionally suppressed occult antigen induction. Backcross of F1 to both parental strains indicated that the occult locus was on Chr 17, tightly linked to MHC.(ABSTRACT TRUNCATED AT 400 WORDS)

Use of recombinant congenic and congenic strains of NOD mice to identify a new insulin-dependent diabetes resistance gene.

Insulin-dependent diabetes mellitus (IDDM) in NOD/Lt mice represents a complex polygenic disease. NOR/Lt is a recombinant congenic strain (RCS) in which limited regions of the NOD/Lt genome have been replaced by genome from the C57BL/KsJ strain. NOR mice are insulitis resistant and diabetes free despite genetic identity with NOD at numerous chromosomal regions containing previously described insulin-dependent diabetes (Idd) genes, including the strongly diabetogenic H2g7 major histocompatibility complex (MHC) haplotype. The present study revealed BKs-derived genome on segments of chromosomes (Chr) 1, 2, 4, 5, 7, 11, 12, and 18, approximating 11.6% of the total NOR genome analyzed. (NOD x NOR)F2 segregation analysis was employed to identify chromosomal regions in NOR containing Idd resistance alleles. IDDM developed in 33% (10/30) of F1 females, and 29.3% (36/123) of F2 females aged to 1 yr. A previously unrecognized diabetes resistance locus (designated Idd13r) strongly protective in homozygous state was identified on NOR Chr 2 in linkage with the Il1 alpha structural gene. The existence of this locus was confirmed by construction of a NOD stock congenic for NOR-derived markers on Chr 2. Our analysis shows the utility of RCS and congenic stocks for the identification and isolation of non-MHC genes with strong antidiabetogenic functions.

B lymphocytes are essential for the initiation of T cell-mediated autoimmune diabetes: analysis of a new "speed congenic" stock of NOD.Ig mu null mice.

The T lymphocytes mediating autoimmune destruction of pancreatic beta cells in the nonobese diabetic (NOD) mouse model of insulin-dependent diabetes mellitus (IDDM) may be generated due to functional defects in hematopoietically derived antigen-presenting cells (APC). However, it has not been clear which particular subpopulations of APC (B lymphocytes, macrophages, and dendritic cells) contribute to the development and activation of diabetogenic T cells in NOD mice. In the current study we utilized a functionally inactivated immunoglobulin (Ig) mu allele (Ig mu null) to generate a "speed congenic" stock of B lymphocyte-deficient NOD mice that are fixed for linkage markers delineating previously identified diabetes susceptibility (Idd) genes. These B lymphocyte NOD.Ig mu null mice had normal numbers of T cells but were free of overt IDDM and insulitis resistant, while the frequency of disease in the B lymphocyte intact segregants was equivalent to that of standard NOD mice in our colony. Thus, B lymphocytes play a heretofore unrecognized role that is essential for the initial development and/or activation of beta cell autoreactive T cells in NOD mice.

Interleukin 4 reverses T cell proliferative unresponsiveness and prevents the onset of diabetes in nonobese diabetic mice.

Beginning at the time of insulitis (7 wk of age), CD4+ and CD8+ mature thymocytes from nonobese diabetic (NOD) mice exhibit a proliferative unresponsiveness in vitro after T cell receptor (TCR) crosslinking. This unresponsiveness does not result from either insulitis or thymic involution and is long lasting, i.e., persists until diabetes onset (24 wk of age). We previously proposed that it represents a form of thymic T cell anergy that predisposes to diabetes onset. This hypothesis was tested in the present study by further investigating the mechanism responsible for NOD thymic T cell proliferative unresponsiveness and determining whether reversal of this unresponsiveness protects NOD mice from diabetes. Interleukin 4 (IL-4) secretion by thymocytes from > 7-wk-old NOD mice was virtually undetectable after treatment with either anti-TCR alpha/beta, anti-CD3, or Concanavalin A (Con A) compared with those by thymocytes from age- and sex-matched control BALB/c mice stimulated under identical conditions. NOD thymocytes stimulated by anti-TCR alpha/beta or anti-CD3 secreted less IL-2 than did similarly activated BALB/c thymocytes. However, since equivalent levels of IL-3 were secreted by Con A-activated NOD and BALB/c thymocytes, the unresponsiveness of NOD thymic T cells does not appear to be dependent on reduced IL-2 secretion. The surface density and dissociation constant of the high affinity IL-2 receptor of Con A-activated thymocytes from both strains are also similar. The patterns of unresponsiveness and lymphokine secretion seen in anti-TCR/CD3-activated NOD thymic T cells were also observed in activated NOD peripheral spleen T cells. Exogenous recombinant (r)IL-2 only partially reverses NOD thymocyte proliferative unresponsiveness to anti-CD3, and this is mediated by the inability of IL-2 to stimulate a complete IL-4 secretion response. In contrast, exogenous IL-4 reverses the unresponsiveness of both NOD thymic and peripheral T cells completely, and this is associated with the complete restoration of an IL-2 secretion response. Furthermore, the in vivo administration of rIL-4 to prediabetic NOD mice protects them from diabetes. Thus, the ability of rIL-4 to reverse completely the NOD thymic and peripheral T cell proliferative defect in vitro and protect against diabetes in vivo provides further support for a causal relationship between this T cell proliferative unresponsiveness and susceptibility to diabetes in NOD mice.

Separation of mitochondrial membranes of Neurospora crassa. II. Submitochondrial localization of the isoleucine-valine biosynthetic pathway.

Separation of Neurospora mitochondrial outer membranes from the inner membrane/matrix fraction was effected by digitonin treatment and discontinuous density gradient centrifugation. The solubilization of four isoleucine-valine biosynthetic enzymes was studied as a function of digitonin concentration and time of incubation in the detergent. The kinetics of the appearance of valine biosynthetic function in fractions outside of the inner membrane/matrix fraction, coupled with enzyme solubilization patterns similar to that for the matrix marker, mitochondrial malate dehydrogenase, indicate that the four isoleucine-valine pathway enzymes are localized in the mitochondrial matrix.

Three recessive loci required for insulin-dependent diabetes in nonobese diabetic mice.

A polygenic basis for susceptibility to insulin-dependent diabetes in nonobese diabetic (NOD) mice has been established by outcross to a related inbred strain, nonobese normal (NON). Analysis of first and second backcross progeny has shown that at least three recessive genes are required for development of overt diabetes. One, Idd-1s, is tightly linked to the H-2K locus on chromosome 17; another, Idd-2s, is localized proximal to the Thy-1/Alp-1 cluster on chromosome 9. Segregation of a third, Idd-3s, could be shown in a second backcross. Neither Idd-1s nor Idd-2s could individually be identified as the locus controlling insulitis; leukocytic infiltrates in pancreas were common in most asymptomatic BC1 mice. Both F1 and BC1 mice exhibited the unusually high percentage of splenic T lymphocytes characteristic of NOD, suggesting dominant inheritance of this trait. The polygenic control of diabetogenesis in NOD mice, in which a recessive gene linked to the major histocompatibility complex is but one of several controlling loci, suggests that similar polygenic interactions underlie this type of diabetes in humans.

Peptides, enzymes and obesity: new insights from a 'dead' enzyme.

The identification of the fat mutation, which causes obesity in mice, as a defect in carboxypeptidase E (CPE) has raised more questions than answers. CPE is required for the processing of numerous neuroendocrine peptides and a mutation that inactivates CPE was predicted to be lethal. However, Cpe(fat) mutated mice live and become obese. So, why are mice with the Cpe(fat) mutation viable, and why does obesity develop as a consequence of the pleiotropic effects of this mutant allele? Recently, several new members of the carboxypeptidase family have been discovered, of which at least one, CPD, can partially compensate by contributing to neuroendocrine peptide processing. Obesity due to the Cpe(fat) mutation is not caused by increased food consumption but, rather, is a result of defective nutrient partitioning, the exact mechanism of which remains to be elucidated.

Obesity-induced diabetes (diabesity) in C57BL/KsJ mice produces aberrant trans-regulation of sex steroid sulfotransferase genes.

The diabetes (db) gene is a recessive obesity mutation in the mouse capable of producing diabetes only through interaction with heretofore undefined modifiers in the genetic background of certain inbred strains. Here we identify the genetic map locations of androgen and estrogen sulfotransferase genes important in maintaining the balance of active sex steroids in the liver. The Std locus encoding dehydroepiandrosterone sulfotransferase was mapped to proximal Chromosome 7, and the Ste locus encoding estrogen sulfotransferase was mapped to Chromosome 5. The db mutation in the diabetes-susceptible C57BL/KsJ strain aberrantly regulated mRNA transcript levels from these two loci. Hepatic Ste mRNA transcripts were increased from undetectable levels in normal males and females to high levels in db/db mice of both sexes. An anomalous suppression of Std transcription was observed in db/db females, but not in normal females. These reciprocal changes in mRNA concentrations in mutant females were reflected by an induction of a high affinity estrogen sulfotransferase activity and a concomitant loss of dehydroepiandrosterone sulfotransferase activity. These db gene-elicited effects were specific for the sex steroid sulfotransferases since other potential sex steroid metabolizing enzymes (phenol sulfotransferase, sex steroid sulfohydrolase, and UDP-glucuronyltransferase) were unaffected. These aberrant changes would virilize hepatic metabolism in females by increasing the ratio of active androgens to estrogens. In human females, non-insulin-dependent diabetes mellitus often develops when visceral obesity and hyperinsulinemia are associated with hyperandrogenization. This study demonstrates that background modifier genes interacting deleteriously with an obesity mutation are not necessarily defective alleles. Rather, some are functional genes whose regulation has been altered by pleiotropic effects of the obesity gene.

Beta cell expression of endogenous xenotropic retrovirus distinguishes diabetes-susceptible NOD/Lt from resistant NON/Lt mice.

Endogeneous retroviral expression in beta cells is a feature of prediabetes in nonobese diabetic (NOD) mice. The purpose of this study was to characterize the class-specific pattern of retroviral gene expression in NOD/Lt beta cells versus a related, but diabetes-resistant strain, NON/Lt. Electron microscopic comparison of beta cells from both strains indicated low constitutive expression of the intracisternal type A (IAP) retroviral class. However, NOD beta cells, in contrast to NON beta cells, expressed an additional intracisternal retroviral form resembling a type C particle. Antibodies against both IAP and type C were detected in NOD, with the humoral response to type C, but not IAP, preceding decline in beta cell function. RNA was extracted from freshly isolated islets from NOD and NON males. Comparative Northern blot analysis of total type C retroviral gene expression using a gag-pol DNA probe corroborated expression of endogenous type C proviruses in both NOD and NON islet cells and thymus. Use of class-specific retroviral probes identified the class of expressed endogenous retrovirus distinguishing the two inbred strains. The single ecotropic provirus present in both the NOD and NON genome (Emv-30) was not expressed in islets or thymus of either strain. Comparison of endogenous xenotropic provirus content by Southern blot analysis revealed two unique xenotropic loci (Xmv-65, -66) in NOD; 8.4 and 3.0 kb xenotropic envelope (env) RNA transcripts were detected in NOD, but not NON islets and thymus. NON contained three xenotropic loci common to other inbred strains (Xmv-21, -25, and -28). Both strains were partially characterized for content of recombinant (polytropic and modified polytropic) proviruses. IAP RNA expression was common to both NOD and NON islets and hence could not be specifically associated with the unique intracisternal type C particle found in NOD, but not NON beta cells. In conclusion, this study shows that expression of xenotropic type C but not IAP distinguishes retroviral activity in NOD/Lt versus NON/Lt beta cells. The potential pathogenic role of retroviral gene expression in NOD beta cells is discussed.

Genetic and pathogenic basis of autoimmune diabetes in NOD mice.

Non-obese diabetic (NOD) mice are an excellent model of T-cell mediated autoimmune insulin-dependent diabetes in humans. Recent studies in NOD mice have shown that this disease is a result of epistatic interactions between multiple genes, both inside and outside the major histocompatibility complex (MHC), generating T cells reactive against an expanding repertoire of autoantigens.

An epithelial cell line with chronic polyoma infection established from a spontaneous mouse pancreatic adenocarcinoma.

The establishment of an epithelial cell line from a mouse pancreatic adenocarcinoma is described. The cell line, designated LTPA, was aneuploid and exhibited many transformed growth properties (rapid growth rate, failure to show density-dependent inhibition of growth, ability to grow in defined medium). A type C oncornavirus was isolated from the culture medium, and electron microscopy also revealed the presence of intracisternal type A particles. LTPA cells carried a persistent polyoma infection which produced only low levels of cytopathic effects. A mycoplasmal contamination was also carried. When injected s.c. into Swiss nu/nu mice, LTPA cells formed ductular structures which were destroyed by inflammatory reactions within 3 weeks.

Genetic control of pathogenesis of diabetes in C3H mice. Influence of the major histocompatibility complex.

Inbred strains of genetically diabetic (db/db) male mice with H-2b haplotype were heretofore found resistant to the diabetogenic action of the db mutation, whereas C3HeB/FeJ-db/db males with H-2k haplotype were susceptible. To determine whether the major histocompatibility complex was linked to diabetes predisposition, we mated C3H.SW/SnJ females (H-2b haplotype) with C3HeB/FeJ- +/db males, identified the +/db heterozygotes in the F1 generation (all H-2b/H-2k), and intercrossed these to produce F2 db/db male offspring that were classed and studied according to the three segregating H-2 genotypes. We found an accelerated diabetes pathogenesis in terms of early onset of severe hyperglycemia, destruction of pancreatic beta cells, and mortality that was not linked to H-2. Of 9 F2 male diabetics with H-2b/H-2b genotype, 14 with H-2b/H-2k genotype, and 5 with H-2k/H-2k genotype, all showed a more severe syndrome than did the grandparental-type C3HeB/FeJ-db/db males. We conclude that on the C3H inbred background, the major histocompatibility complex is not a major background modifier of the diabetes syndrome. The complexity of the results suggests residual non-H-2-related genetic variance between the two grandparental C3H stocks, with C3H.SW/SnJ females possessing diabetes susceptibility factors apparently lacking in C3HeB/FeJ (a stock bred to be free of the milk-borne mouse mammary tumor virus). Since C3H.SW/SnJ females transmitted to F2 males unknown diabetogenic factor(s) that did not appear to segregate, inheritance of a virus was suggested.(ABSTRACT TRUNCATED AT 250 WORDS)

The influence of genetic background on the expression of mutations at the diabetes locus in the mouse IV. Male lethal syndrome in CBA/Lt mice.

To assess whether db-induced pathogenetic changes in beta-cells were restricted to mice with H-2d haplotype, the db gene from BL/Ks was transferred into the CBA/Lt subline (H-2k). A marked sexual dimorphism was observed in the diabetes syndrome in db/db animals. Young adult db/db males exhibited an early onset and completely lethal diabetes (100% mortality by 6 mo). At 3 mo db/db males were moderately obese (43 +/- 4 g) but severely hyperglycemic (475 +/- 69 mg/dl blood glucose) and hyperglucagonemic. Islets were atrophic, showing variable leukocytic infiltration. Although hyperinsulinemic at 2 mo, mutant males had only normal or below normal plasma insulin at 4 mo. Electron microscopic examination confirmed beta-cell necrosis and the appearance, in prenecrotic beta-cells, of numerous intracisternal type A (retrovirus) particles (IAP). In contrast, db/db females became increasingly obese with age but remained healthy, suffering no mortality in 6 mo. These mice were only transiently hyperglycemic and were able to sustain hyperinsulinemia. Light and electron microscopy revealed beta-cell hypertrophy that was not accompanied by increased numbers of IAP or by necrosis. Retrovirus infection therefore seemed a consequence rather than a cause of hyperglycemia. Ovariectomy coupled with testosterone injection failed to induce severe diabetes in females; castration failed to moderate male diabetes. Instead, biweekly injections of 25 micrograms each of 17 beta-estradiol and progesterone effected complete diabetes remission in males. Experiments using cultured CBA/J islet cells did not support the hypothesis that ovarian steroids were directly protective at the beta-cell level. This study shows that db gene-induced pathogenesis is not restricted to mice with the H-2d haplotype, and that sex steroids are important modifiers of syndrome severity.

Resistance of ALR/Lt islets to free radical-mediated diabetogenic stress is inherited as a dominant trait.

ALS/Lt and ALR/Lt are inbred mouse strains selected for susceptibility and resistance to alloxan (AL)-induced diabetes. Within 24-h after AL administration in vivo, ALS/Lt islets were distinguished from ALR/Lt islets by more extensive necrotic changes. Within 7 days post-AL, ALS/Lt mice exhibited hyperglycemia and hypoinsulinemia, whereas ALR/Lt mice maintained normal plasma insulin and glucose levels. We have recently shown that resistance in ALR/Lt correlated with constitutively elevated systemic (and pancreatic) free radical defense status. In the present report, we examined whether ability to detoxify free radical stress extended to the level of ALR/Lt pancreatic islets. Cultured ALS/Lt islets exposed for 5 min to increasing (0-3 mmol/l) AL concentrations in vitro exhibited an 80% decline in numbers of intact islets after a subsequent 6-day culture period, as well as a 75% reduction in islet insulin content and a 94% decrease in glucose-stimulated insulin secretory capacity. In contrast, ALR/Lt islets remained viable and retained glucose-stimulated insulin secretory capacity as well as normal insulin content. This ALR/Lt islet resistance extended to hydrogen peroxide, a free radical generator whose entry into beta-cells is not dependent on glucose transporters. The elevated antioxidant defenses previously found in ALR/Lt pancreas were extended to isolated islets, which exhibited significantly higher glutathione and Cu-Zn superoxide dismutase 1 levels compared with ALS/Lt islets. A dominant genetic trait from ALR/Lt controlling this unusual AL resistance was indicated by the finding that reciprocal F1 mice of both sexes were resistant to AL administration in vivo. A backcross to ALS/Lt showed 1:1 segregation for susceptibility/resistance, indicative of a single gene controlling the phenotype. In conclusion, the ALR/Lt mouse may provide important insight into genetic mechanisms capable of rendering islets strongly resistant to free radical-mediated damage.

Comparison of cytokine effects on mouse pancreatic alpha-cell and beta-cell lines. Viability, secretory function, and MHC antigen expression.

Cytokine effects on permanent cell lines of transformed mouse pancreatic alpha- and beta-cells were compared. The beta-tumor cell 1 (beta TC1) line (from an adenoma created in transgenic mice expressing the SV40 large T-antigen oncogene under control of the rat insulin II promoter) produced insulin predominantly, although small quantities of intracellular glucagon (100:1 insulin to glucagon) were detectable by radioimmunoassay. The alpha TC1 line (from an adenoma created in transgenic mice expressing the SV40 large T-antigen oncogene under control of the rat preproglucagon promoter) produced not only glucagon but also considerable quantities of insulin (4:1 glucagon to insulin) and preproinsulin mRNA. We therefore cloned alpha TC1 cells and obtained 12 glucagon-producing clonal cell lines that did not produce levels of insulin detectable by radioimmunoassay. Analysis by Northern blotting of total RNA from two lines, alpha TC1 clones 6 and 9, confirmed the absence of preproinsulin mRNA. No somatostatin or pancreatic polypeptide was detected by immunohistochemical staining in alpha TC1 clones 6 or 9 or beta TC1 cells. Rat recombinant gamma-interferon (IFN-gamma; 5-250 U/ml) or mouse recombinant interleukin 1 (IL-1; 1-25 U/ml) individually inhibited DNA synthesis in beta TC1 cells after 3 days of treatment. The two cytokines in combination acted synergistically to further depress DNA synthesis and increase cytotoxicity. In contrast, alpha TC1 clone 9 cells were not sensitive to inhibition of DNA synthesis by each cytokine individually, although glucagon synthesis was inhibited. The combination of these cytokines caused marked inhibition of DNA and glucagon syntheses in alpha TC1 clone 9 cells. alpha TC1 clone 9 cells were somewhat more resistant to the cytotoxic action of the combined cytokines than were beta TC1 cells. Incubation with 50 U/ml IFN-gamma induced class II MHC molecules (I-Ab, I-Ad, and I-Ed) and enhanced the constitutive expression of class I molecules (H-2Kb and H-2Kd) on the cell surfaces of beta TC1, uncloned alpha TC1, and alpha TC1 clones 6 and 9. Thus, these cell lines are heterozygous for MHC alleles derived from both parental strains used in the construction of the transgenic mice [C57BL/6J (H-2b) and DBA/2J (H-2d)]. Class II gene transcription induced by IFN-gamma was confirmed in beta TC1 and alpha TC1 clone 9 cells by Northern blot analysis with A alpha-, A beta-, E alpha, and E beta-DNA probes.(ABSTRACT TRUNCATED AT 400 WORDS)