Gene expression profiles define a key checkpoint for type 1 diabetes in NOD mice

cDNA microarrays with >11,000 cDNA clones from an NOD spleen cDNA library were used to identify temporal gene expression changes in NOD mice (1-10 weeks), which spontaneously develop type 1 diabetes, and changes between NOD and NOD congenic mice (NOD.Idd3/Idd10 and NOD.B10Sn-H2(b)), which have near zero incidence of insulitis and diabetes. The expression profiles identified two distinct groups of mice corresponding to an immature (1-4 weeks) and mature (6-10 weeks) state. The rapid switch of gene expression occurring around 5 weeks of age defines a key immunological checkpoint. Sixty-two known genes are upregulated, and 18 are downregulated at this checkpoint in the NOD. The expression profiles are consistent with increased antibody production, antigen presentation, and cell proliferation associated with an active autoimmune response. Seven of these genes map to confirmed diabetes susceptibility regions. Of these seven, three are excellent candidate genes not previously implicated in type 1 diabetes. Ten genes are differentially expressed between the NOD and congenic NOD at the immature stage (Hspa8, Hif1a, and several involved in cellular functions), while the other 70 genes exhibit expression differences during the mature (6-10 week) stage, suggesting that the expression differences of a small number of genes before onset of insulitis determine the disease progression.     

Systemic expression of heme oxygenase-1 ameliorates type 1 diabetes in NOD mice

Heme oxygenase-1 (HO-1) is an enzyme with potent immunoregulatory capacity. To evaluate the effect of HO-1 on autoimmune diabetes, female NOD mice at 9 weeks of age received a single intravenous injection of a recombinant adeno-associated virus bearing HO-1 gene (AAV-HO-1; 0.5 x 10(10)-2.5 x 10(10) viruses/mouse). In a dose-dependent manner, HO-1 transduction reduced destructive insulitis and the incidence of overt diabetes examined over a 15-week period. HO-1-mediated protection was associated with a lower type 1 T-helper cell (Th1)-mediated response. Adaptive transfer experiments in NOD.scid mice demonstrated that splenocytes isolated from AAV-HO-1-treated mice were less diabetogenic. Flow cytometry analysis revealed no significant difference in the percentages of CD4(+)CD25(+) regulatory T-cells between saline-treated and AAV-HO-1-treated groups. However, the CD11c(+) major histocompatibility complex II(+) dendritic cell population was much lower in the AAV-HO-1-treated group. A similar protective effect against diabetes was observed in NOD mice subjected to carbon monoxide (CO) gas (250 ppm CO for 2 h, twice per week). These data suggest that HO-1 slows the progression to overt diabetes in pre-diabetic NOD mice by downregulating the phenotypic maturity of dendritic cells and Th1 effector function. CO appears to mediate at least partly the beneficial effect of HO-1 in this disease setting.     

Glucagon receptor knockout prevents insulin-deficient type 1 diabetes in mice

OBJECTIVE

To determine the role of glucagon action in the metabolic phenotype of untreated insulin deficiency.

RESEARCH DESIGN AND METHODS

We compared pertinent clinical and metabolic parameters in glucagon receptor-null (Gcgr^−/−) mice and wild-type (Gcgr^+/+) controls after equivalent destruction of β-cells. We used a double dose of streptozotocin to maximize β-cell destruction.

RESULTS

Gcgr^+/+ mice became hyperglycemic (>500 mg/dL), hyperketonemic, polyuric, and cachectic and had to be killed after 6 weeks. Despite comparable β-cell destruction in Gcgr^−/− mice, none of the foregoing clinical or laboratory manifestations of diabetes appeared. There was marked α-cell hyperplasia and hyperglucagonemia (∼1,200 pg/mL), but hepatic phosphorylated cAMP response element binding protein and phosphoenolpyruvate carboxykinase mRNA were profoundly reduced compared with Gcgr^+/+ mice with diabetes—evidence that glucagon action had been effectively blocked. Fasting glucose levels and oral and intraperitoneal glucose tolerance tests were normal. Both fasting and nonfasting free fatty acid levels and nonfasting β-hydroxy butyrate levels were lower.

CONCLUSIONS

We conclude that blocking glucagon action prevents the deadly metabolic and clinical derangements of type 1 diabetic mice.The development of a radioimmunoassay for glucagon (1) established the hormonal status of this peptide (2), originally considered to be a contaminant of the insulin extraction process. Glucagon was immunocytochemically localized to pancreatic α-cells (3) and shown to be secreted in response to increased glucose need, as in starvation and exercise (4). By 1973, it was recognized that α-cell function was grossly abnormal in diabetes, particularly in type 1 diabetes (5). Here, β-cells are largely replaced by α-cells, and, without the inhibitory action of insulin, their secretion of glucagon is unrestrained, and glucagon action on the liver is unopposed. The result is a lethal hypercatabolic state. In 1973, the discovery of somatostatin (6), a potent inhibitor of glucagon secretion, made it possible to demonstrate the essential role of glucagon in the metabolic phenotype of type 1 diabetes (7–10).Those studies led to a search for a therapeutic suppressor of diabetic hyperglucagonemia or blocker of its action on the liver. In the 37 years since the discovery of somatostatin, only one other potent glucagon-suppressing substance, leptin, has been identified (11,12). By contrast, inactivators of glucagon have been less elusive. High affinity antiglucagon antibodies have benefited diabetic animals (13), as have a variety of molecules that block binding of glucagon to the glucagon receptor and/or block its signaling (14–18). Diabetic mice with glucagon receptor knockout (19) or mice treated with Gcgr antisense oligonucleotide similarly benefit from the elimination of glucagon action (20,21). Although all of the foregoing reports demonstrate that abrogation of glucagon action reduces hepatic overproduction of glucose, a potential therapeutic asset in diabetes management, none of the foregoing diabetic models studied thus far have been totally insulin-deficient, as in type 1 diabetes. In type 1 diabetes, islets are virtually devoid of β-cells, and are largely made up of hyperplastic α-cells. In contrast to normal α-cells, which are restrained by the high local concentrations of intraislet insulin (22), type 1 diabetic α-cells are unregulated, which results in inappropriate hyperglucagonemia (5). Moreover, with no insulin to oppose the hepatic actions of the hyperglucagonemia, unrestrained glycogenolysis, gluconeogenesis, ketogenesis, and hypercatabolism lead rapidly to ketoacidosis, cachexia, coma, and death.An essential role of hyperglucagonemia in the pathogenesis of this lethal syndrome has long been suspected but never fully proven. Recent studies of adenovirally induced hyperleptinemia in type 1 diabetic mice (12) indicate that glucagon suppression normalizes all metabolic parameters for more than a month despite a total absence of insulin. More recently, the same antidiabetic efficacy has been demonstrated with recombinant leptin (11,23). However, leptin-induced actions other than suppression of glucagon, such as increased insulin-like growth factor-1 (IGF-1) (12) and insulin-like growth factor-binding protein-2 (IGFBP-2) (23), may have contributed. To obtain unassailable proof that glucagon action by itself causes the lethal consequences of insulin deficiency, we induced insulin deficiency in glucagon receptor-null (Gcgr^−/−) mice. Gcgr^−/− mice were treated with streptozotocin (STZ), the most commonly used β-cytotoxins in rodents, in an effort to achieve complete insulin deficiency in the complete absence of glucagon activity. We compared the metabolic phenotype of complete β-cell destruction in mice in which glucagon action had been transgenically abrogated by knockout of the glucagon receptor (24). Because Gcgr^−/− mice are resistant to STZ-induced β-cell destruction (24), it was necessary to use a double dose of the β-cell poison STZ. Despite β-cell destruction equivalent to the wild-type (Gcgr^+/+) mice, Gcgr^−/− remained free of all manifestations of insulin deficiency.     

Remapping the insulin gene/IDDM2 locus in type 1 diabetes

Type 1 diabetes susceptibility at the IDDM2 locus was previously mapped to a variable number tandem repeat (VNTR) 5' of the insulin gene (INS). However, the observation of associated markers outside a 4.1-kb interval, previously considered to define the limits of IDDM2 association, raised the possibility that the VNTR association might result from linkage disequilibrium (LD) with an unknown polymorphism. We therefore identified a total of 177 polymorphisms and obtained genotypes for 75 of these in up to 434 pedigrees. We found that, whereas disease susceptibility did map to within the 4.1-kb region, there were two equally likely candidates for the causal variant, -23HphI and +1140A/C, in addition to the VNTR. Further analyses in 2,960 pedigrees did not support the difference in association between VNTR lineages that had previously enabled the exclusion of these two polymorphisms. Therefore, we were unable to rule out -23HphI and +1140A/C having an etiological effect. Our mapping results using robust regression methods show how precisely a variant for a common disease can be mapped, even within a region of strong LD, and specifically that IDDM2 maps to one or more of three common variants in a approximately 2-kb region of chromosome 11p15.     

Adiponectin receptor 1 gene (ADIPOR1) as a candidate for type 2 diabetes and insulin resistance

Considerable data support adiponectin as an important adipose-derived insulin sensitizer that enhances fatty acid oxidation and alters hepatic gluconeogenesis. Adiponectin acts by way of two receptors, ADIPOR1 and ADIPOR2. ADIPOR1 is widely expressed in tissues, including muscle, liver, and pancreas, and binds the globular form of adiponectin with high affinity. To test the hypothesis that sequence variations in or near the ADIPOR1 gene contribute to the risk of developing type 2 diabetes and the metabolic syndrome, we screened the eight exons (including the untranslated exon 1) of the ADIPOR1 gene with flanking intronic sequences and the 5' and 3' flanking sequences. We identified 22 single nucleotide polymorphisms (SNPs) in Caucasian and African-American subjects, of which a single nonsynonymous SNP (N44K) in exon 2 was present only in African-American subjects. We typed 14 sequence variants that had minor allele frequencies >5%. No SNP was associated with type 2 diabetes in Caucasians or African Americans, and no SNP was a determinant of insulin sensitivity or insulin secretion among nondiabetic members of high-risk Caucasian families. However, the two alleles of a SNP in the 3' untranslated region were expressed unequally, and ADIPOR1 mRNA levels were significantly lower among transformed lymphocytes from diabetic African-American individuals than among control cell lines. This altered gene expression might suggest a role for ADIPOR1 in the metabolic syndrome.     

Association studies of genetic variation in the WFS1 gene and type 2 diabetes in U.K. populations

Mutations in the WFS1 gene cause beta-cell death, resulting in a monogenic form of diabetes known as Wolfram syndrome. The role of variation in WFS1 in type 2 diabetes susceptibility is not known. We sequenced the WFS1 gene in 29 type 2 diabetic probands and identified 12 coding variants. We used 152 parent-offspring trios to look for familial association; the R allele at residue 456 (P = 0.04) and the H allele at residue 611 (P = 0.05) as well as the R456-H611 haplotype (P = 0.032) were overtransmitted to affected offspring from heterozygous parents. In a further cohort of 327 type 2 diabetic subjects and 357 normoglycemic control subjects, the H611 allele and the R456-H611 haplotype were present in more type 2 diabetic subjects than control subjects (one-tailed P = 0.06 and P = 0.023, respectively). In a combined analysis, the H611 allele was present in 60% of all diabetes chromosomes and 55% of all control chromosomes (odds ratio [OR] 1.24 [95% CI 1.03-1.48], P = 0.02), and the R456-H611 haplotype was significantly more frequent in type 2 diabetic subjects than in control subjects (60 vs. 54%, OR 1.29 [95% CI 1.08-1.54], P = 0.0053). Our results provide the first evidence that variation in the WFS1 gene may influence susceptibility to type 2 diabetes.     

Insulitis and diabetes in NOD mice reduced by prophylactic insulin therapy

Intensive insulin therapy in patients with recently diagnosed insulin-dependent diabetes mellitus (IDDM) has been reported to result in a prolonged increase in endogenous insulin-secreting capacity. Because the clinical onset of IDDM occurs only after most insulin-secreting beta-cells have been destroyed, we tested whether prophylactic insulin therapy might prevent IDDM in nonobese diabetic (NOD) mice. One hundred fourteen NOD mice were randomized at weaning into a protamine zinc pork insulin-treated (I) group or a placebo-treated (P) group given insulin diluent. All insulin treatments were adjusted to the maximum tolerable dosages and continued until 180 days of age. The cumulative IDDM frequency within the female I group was significantly less (3 of 34, 8%) than in female P controls (17 of 26, 65%; P less than 0.0001). This beneficial effect was limited to females, however, because the frequency of IDDM in male I mice (3 of 32, 9%) was not significantly different from the frequency in male P controls (1 of 22, 5%; P less than 0.5). Pancreatic histological examinations of nondiabetic animals revealed that insulin treatment resulted in significant reductions in islet cell inflammation and damage and improvements in insulin content. In summary, NOD mice given insulin therapy from weaning until 180 days of age had significantly lower frequencies of diabetes and pancreatic insulitis than sex-matched control littermates treated with insulin diluent. These results suggest that prophylactic insulin therapy to prevent IDDM in humans should be considered for clinical trials.     

Blockade of tumor necrosis factor-related apoptosis-inducing ligand exacerbates type 1 diabetes in NOD mice

Tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL) is expressed in different tissues and cells, including pancreas and lymphocytes, and can induce apoptosis in various tumor cells but not in most normal cells. The specific roles of TRAIL in health and disease remain unclear. Here we show by cDNA array analyses that TRAIL gene expression is upregulated in pancreatic islets during the development of autoimmune type 1 diabetes in nonobese diabetic (NOD) mice and in Min6 islet beta-cells activated by TNF-alpha + interferon-gamma. However, stimulation of freshly isolated pancreatic islets or Min6 cells with TRAIL did not induce their apoptosis. TRAIL blockade exacerbates the onset of type 1 diabetes in NOD.Scid recipients of transferred diabetogenic T-cells and in cyclophosphamide-treated NOD mice. TRAIL inhibits the proliferation of NOD diabetogenic T-cells by suppressing interleukin (IL)-2 production and cell cycle progression, and this inhibition can be rescued in the presence of exogenous IL-2. cDNA array and Western blot analyses indicate that TRAIL upregulates the expression of the cdk inhibitor p27(kip1). Our data suggest that TRAIL is an important immune regulator of the development of type 1 diabetes.     

Analysis of the mouse CD30 gene: a candidate for the NOD mouse type 1 diabetes locus Idd9.2

Members of the tumor necrosis factor receptor superfamily play an important role in the initiation, expansion, and termination of an immune response. It has recently been demonstrated that one member of this family, CD30, plays a central role in maintaining peripheral tolerance by controlling the expansion of autoreactive CD8+ T-cells. In the present study, Cd30 was mapped to a 5.6-cM interval on chromosome 4 containing the type 1 diabetes susceptibility locus Idd9.2. We determined the intron/exon structure of Cd30 and sequenced the exons, as well as 1.8 kb of the 5' putative promoter region, from 6 different mouse strains. Remarkably, 63 sequence variants, both coding and noncoding, were found. A total of 27 sequence variants, 4 of which were nonsynonymous, were found between the diabetes susceptible NOD strain and the resistant B10 strain. Of these sequence variants, 19 are within the promoter region. However, no difference between NOD and the congenic strain NOD.B10 Idd9R1, which has the B10 allele of Cd30, was observed in CD30 expression at either the mRNA or protein level. Given its role in protecting against autoimmunity, one or more of the coding variants within CD30 is a good candidate for the Idd9.2 etiological variant.     

Gene expression profiling in the remnant kidney model of wild type and kinin B1 and B2 receptor knockout mice

Angiotensin-converting enzyme inhibitors are the most efficient pharmacologic agents to delay the development of end-stage renal disease (ESRD). This is a multipharmacologic approach that inhibits angiotensin II formation while increasing kinin concentrations. Considerable attention has been focused on the role of decreased angiotensin II levels; however, the role of increased kinin levels is gaining in interest. Kinins affect cellular physiology by interacting with one of two receptors being the more inducible B1 and the more constitutive B2 receptors. This study utilizes the mouse remnant kidney of 20 weeks duration as a model of ESRD. Whole mouse genome microarrays were used to evaluate gene expression in the remnant kidneys of wild type, B1 and B2 receptor knockout animals. The microarray data indicate that gene families involved in vascular damage, inflammation, fibrosis, and proteinuria were upregulated, whereas gene families involved in cell growth, metabolism, lipid, and protein biosynthesis were downregulated in the remnant kidneys. Interestingly, the microarray analyses coupled to histological evaluations are suggestive of a possible protective role of kinins operating through the B2 receptor subtype in this model of renal disease. The results highlight the potential of microarray technology for unraveling complex mechanisms contributing to chronic renal failure.     

Prevention of type I diabetes in NOD mice by adjuvant immunotherapy

The nonobese diabetic (NOD) mouse is an excellent model of insulin-dependent (type I) human diabetes mellitus. We report that a single injection of complete Freund's adjuvant (CFA) given at an early age (5 wk) prevented the appearance of diabetes and greatly increased the life span of NOD mice without additional therapy. No treated mouse developed hyperglycemia by the age of 12 mo (n = 13), whereas all untreated mice died of diabetes before 8 mo of age (n = 38). All CFA-treated mice were alive and healthy at 12 mo of age. Some CFA-treated NOD mice that were monitored for long-term survival are still alive with no sign of disease at 18 mo of age (n = 5). Administration of CFA resulted in decreased in vitro splenic lymphocyte proliferative responses to alloantigen and mitogen. Cell-mixing experiments indicated that antigen-nonspecific inhibitory cells were elicited in the spleen and increased in the bone marrow. These regulatory cells were Thy-1- and nonadherent to nylon wool, as has been described for natural suppressor (NS) cells. These data lend support to a relationship between the boosting of endogenous NS activity and the establishment of tolerance to self in the context of autoimmunity. Our results suggest that early nonspecific immunotherapy of genetically predisposed individuals could prevent the development of autoimmune diabetes.     

Association of adiponectin mutation with type 2 diabetes: a candidate gene for the insulin resistance syndrome

Adiponectin, also referred to as AdipoQ or ACRP30, is a plasma protein produced and secreted exclusively from adipose tissue. The protein contains a collagen-like domain and a C1q-like globular domain. A protease-generated globular segment enhances fatty acid oxidation in muscles, thereby modulating lipid and glucose metabolism. Plasma adiponectin levels are inversely correlated with the severity of insulin resistance. A recent genome-wide scan study mapped a susceptibility locus for type 2 diabetes and the metabolic syndrome to chromosome 3q27, where the adiponectin gene is located. Here, we screened Japanese patients with type 2 diabetes and age- and BMI-matched nondiabetic control subjects for mutations in adiponectin gene. We identified four missense mutations (R112C, I164T, R221S, and H241P) in the globular domain. Among these mutations, the frequency of I164T mutation was significantly higher in type 2 diabetic patients than in age- and BMI- matched control subjects (P < 0.01). Furthermore, plasma adiponectin concentrations of subjects carrying I164T mutation were lower than those of subjects without the mutation. All the subjects carrying I164T mutation showed some feature of metabolic syndrome, including hypertension, hyperlipidemia, diabetes, and atherosclerosis. Our findings suggest that I164T mutation is associated with low plasma adiponectin concentration and type 2 diabetes.     

Interferon-gamma receptor signaling is dispensable in the development of autoimmune type 1 diabetes in NOD mice

There have been two previous conflicting reports that the development of T-cell-mediated autoimmune diabetes (type 1 diabetes) was respectively unaffected or inhibited in NOD mice genetically deficient in the T-helper (Th) 1 cytokine interferon (IFN)-gamma or the alpha-chain subunit of its receptor. Our goal was to resolve this conundrum by congenically transferring, from a 129 donor strain to the NOD background, a functionally inactivated gene for the beta-chain signaling (located on chromosome 16) rather than the alpha-chain ligand binding domain (located on chromosome 10) of the IFN-gamma receptor. These NOD.IFNgammaRBnull mice were characterized by normal patterns of leukocyte development and T-cells that produced greatly enhanced levels of the putatively type 1 diabetes-protective Th2 cytokine interleukin (IL)-4. However, despite being unable to respond to the primary Thl cytokine IFN-gamma and having T-cells that produce greatly enhanced levels of IL-4, NOD.IFNgammaRBnull mice remained highly susceptible to type 1 diabetes. This result indicated that the previously reported inhibition of type 1 diabetes in NOD mice carrying a functionally inactivated IFN-gamma receptor alpha-chain gene may have been due to a closely linked and previously unidentified diabetes resistance allele. Furthermore, our results indicate that the pathogenicity of diabetogenic T-cells in NOD mice is not dampened by an inability to respond to IFN-gamma and a concurrent shift to greatly enhanced Th2 cytokine production. This finding calls into question whether clinical protocols designed to shift beta-cell autoreactive T-cells from a Thl to Th2 cytokine production profile will truly be safe and efficacious in blocking the development of type 1 diabetes in humans.     

Caspase-1 is not required for type 1 diabetes in the NOD mouse

Interleukin (IL)-1 beta and IL-18 are two cytokines associated with the immunopathogenesis of diabetes in NOD mice. Both of these cytokines are cleaved by caspase-1 to their biologically active forms. IL-1 is a proinflammatory cytokine linked to beta-cell damage, and IL-18 stimulates production of interferon (IFN)gamma in synergy with IL-12. To examine the effects produced by caspase-1 deficiency on diabetes development in NOD/Lt mice, a disrupted Casp1 gene was introduced by a speed congenic technique. Casp1(-/-) bone marrow-derived macrophages stimulated with lipopolysaccharide produced no detectable IL-18, fourfold lower IL-1 beta, and 20-30% less IL-1 alpha than macrophages from wild-type Casp1(+/+) or Casp1(+/-) controls. Unexpectedly, despite reduced IL-1 and IL-18, there was no change in the rate of diabetes or in total incidence as compared with that in wild-type NOD mice. IL-1 reportedly makes an important pathological contribution in the multidose streptozotocin model of diabetes; however, there was no difference in sensitivity to streptozotocin between NOD mice and NOD.Casp1(-/-) mice at 40 mg/kg body wt or at 25 mg/kg body wt dosage levels. These findings show that caspase-1 processing of IL-1 beta and IL-18 is not absolutely required for mediation of spontaneous or chemically induced diabetes pathogenesis in the NOD mouse.     

The role of insulin receptor substrate-1 gene (IRS1) in type 2 diabetes in Pima Indians

The insulin receptor substrate-1 (IRS1) is a critical element in insulin-signaling pathways, and mutations in the IRS1 gene have been reported to have a role in determining susceptibility to traits related to type 2 diabetes. In gene expression studies of tissue biopsies from nondiabetic Pima Indians, IRS1 mRNA levels were reduced in adipocytes from obese subjects compared with lean subjects, and IRS1 mRNA levels were also reduced in skeletal muscle from insulin-resistant subjects compared with insulin-sensitive subjects (all P < 0.05). Based on these expression differences and the known physiologic role of IRS1, this gene was investigated as a candidate gene for susceptibility to type 2 diabetes in Pima Indians, a population with an extremely high incidence and prevalence of type 2 diabetes. Thirteen variants were identified, and among these variants, several were in complete linkage disequilibrium. Four genotypically unique variants were further genotyped in 937 DNA samples from full-heritage Pima Indians. Three of the variants were modestly associated with type 2 diabetes (P < 0.05), one of which was additionally associated with 2-h plasma insulin and glucose as well as insulin action at physiologic and maximally stimulating insulin concentrations (all P < 0.05). The association of variants in IRS1 with type 2 diabetes and type 2 diabetes-related phenotypes and the differential expression of IRS1 in adipocytes and skeletal muscle suggest a role of this gene in the pathogenesis of type 2 diabetes in Pima Indians.     

肝细胞特异性HuR基因敲除小鼠模型的表型研究

目的 探讨肝细胞特异性敲除HuR基因对小鼠肝脏功能的影响。方法 从美国Jackson实验室引进LoxP标记的人抗原R（human antigen R,HuR）基因小鼠（HuR^fl/fl）和Alb-Cre转基因小鼠。杂交后,经数代选育配种,建立肝细胞特异性HuR基因敲除小鼠（HuR^LKO）模型。PCR技术鉴别小鼠基因型,蛋白免疫印迹和免疫荧光实验检验小鼠肝脏的HuR表达水平,同时HE染色观察肝脏结构变化。高脂喂养HuR^fl/fl/Alb-Cre和HuR^fl/fl两组小鼠,观察小鼠体重、肝重和肝体比变化,提取血清检测肝脏损伤和脂肪代谢相关指标。结果 PCR成功检测筛选子代小鼠基因型,包括HuR^fl/fl/Alb-Cre和HuR^fl/fl小鼠。蛋白免疫印迹实验和免疫荧光实验证明小鼠肝细胞特异性HuR基因敲除成功。HE染色结果提示HuR^LKO小鼠的肝细胞出现变性水肿、局部坏死。高脂喂养实验提示两组小鼠在肝重、肝体比、AST、ALT、HDL-C、血糖上的差异具有统计学意义（P＜0.05）,但在体重、TG、LDL-C的差异没有统计学意义（P＞0.05）。结论 HuR基因是维持小鼠肝细胞功能的必要基因,Cre-LoxP技术可成功构建HuR^LKO小鼠模型,且特异性高,表型明显,为研究HuR在肝脏各项疾病的发生发展中所扮演的角色,提供了一个很好的疾病模型。     

Association of common variation in the HNF1alpha gene region with risk of type 2 diabetes

It is currently unclear how often genes that are mutated to cause rare, early-onset monogenic forms of disease also harbor common variants that contribute to the more typical polygenic form of each disease. The gene for MODY3 diabetes, HNF1alpha, lies in a region that has shown linkage to late-onset type 2 diabetes (12q24, NIDDM2), and previous association studies have suggested a weak trend toward association for common missense variants in HNF1alpha with glucose-related traits. Based on genotyping of 79 common SNPs in the 118 kb spanning HNF1alpha, we selected 21 haplotype tag single nucleotide polymorphisms (SNPs) and genotyped them in >4,000 diabetic patients and control subjects from Sweden, Finland, and Canada. Several SNPs from the coding region and 5' of the gene demonstrated nominal association with type 2 diabetes, with the most significant marker (rs1920792) having an odds ratio of 1.17 and a P value of 0.002. We then genotyped three SNPs with the strongest evidence for association to type 2 diabetes (rs1920792, I27L, and A98V) in an additional 4,400 type 2 diabetic and control subjects from North America and Poland and compared our results with those of the original sample and of Weedon et al. None of the results were consistently observed across all samples, with the possible exception of a modest association of the rare (3-5%) A98V variant. These results indicate that common variants in HNF1alpha either play no role in type 2 diabetes, a very small role, or a role that cannot be consistently observed without consideration of as yet unmeasured genetic or environmental modifiers.     

Novel leptin receptor mutation in NOD/LtJ mice suppresses type 1 diabetes progression: II. Immunologic analysis

Recently, we identified in normally type 1 diabetes-prone NOD/LtJ mice a spontaneous new leptin receptor (LEPR) mutation (designated Lepr(db-5J)) producing juvenile obesity, hyperglycemia, hyperinsulinemia, and hyperleptinemia. This early type 2 diabetes syndrome suppressed intra-islet insulitis and permitted spontaneous diabetes remission. No significant differences in plasma corticosterone, splenic CD4(+) or CD8(+) T-cell percentages, or functions of CD3(+) T-cells in vitro distinguished NOD wild-type from mutant mice. Yet splenocytes from hyperglycemic mutant donors failed to transfer type 1 diabetes into NOD.Rag1(-/-) recipients over a 13-week period, whereas wild-type donor cells did so. This correlated with significantly reduced (P < 0.01) frequencies of insulin and islet-specific glucose-6-phosphatase catalytic subunit-related protein-reactive CD8(+) T-effector clonotypes in mutant mice. Intra-islet insulitis was also significantly suppressed in lethally irradiated NOD-Lepr(db-5J)/Lt recipients reconstituted with wild-type bone marrow (P < 0.001). In contrast, type 1 diabetes eventually developed when mutant marrow was transplanted into irradiated wild-type recipients. Mitogen-induced T-cell blastogenesis was significantly suppressed when splenic T-cells from both NOD/Lt and NOD-Lepr(db-5J)/Lt donors were incubated with irradiated mutant peritoneal exudate cells (P < 0.005). In conclusion, metabolic disturbances elicited by a type 2 diabetes syndrome (insulin and/or leptin resistance, but not hypercorticism) appear to suppress type 1 diabetes development in NOD-Lepr(db-5J)/Lt by inhibiting activation of T-effector cells.