Bacterial translocation from the gastrointestinal tract in various mouse models for human diabetes.

Bacterial translocation from the gastrointestinal (GI) tract to other internal organs was examined in multiple low-dose streptozotocin-injected (M-STZ), single large-dose streptozotocin-injected (S-STZ), alloxan-injected (Alloxan), and non-obese diabetic (NOD) mice. The incidence of bacterial translocation from the GI tract to the tested organs among diabetic mice was in the order of M-STZ mice greater than S-STZ mice greater than NOD, Alloxan, and control mice. The injections of insulin to M-STZ mice did not decrease the incidence of translocation. These results suggest that bacterial translocation from the GI tract in diabetic mice is not induced by diabetes.     

Opposite effects of two metal-chelators on alloxan-induced diabetes in mice

Alloxan diabetes may be mediated by an iron-catalyzed formation of hydroxyl radicals. The iron chelators desferrioxamine and diethylenetriaminepentacetic acid (DETAPAC) which inhibit hydroxyl radical formation $\text{in vitro}$ were tested against alloxan diabetes in mice. DETAPAC inhibited while desferrioxamine stimulated the hyperglycemic response to alloxan. The diverging treatment results are discussed.     

Suppressive effects of electrolyzed reduced water on alloxan-induced apoptosis and type 1 diabetes mellitus

Electrolyzed reduced water, which is capable of scavenging reactive oxygen species, is attracting recent attention because it has shown improved efficacy against several types of diseases including diabetes mellitus. Alloxan produces reactive oxygen species and causes type 1 diabetes mellitus in experimental animals by irreversible oxidative damage to insulin-producing β-cells. Here, we showed that electrolyzed reduced water prevented alloxan-induced DNA fragmentation and the production of cells in sub-G1 phase in HIT-T15 pancreatic β-cells. Blood glucose levels in alloxan-induced type 1 diabetes model mice were also significantly suppressed by feeding the mice with electrolyzed reduced water. These results suggest that electrolyzed reduced water can prevent apoptosis of pancreatic β-cells and the development of symptoms in type 1 diabetes model mice by alleviating the alloxan-derived generation of reactive oxygen species.     

Potentiation of the hepatotoxic responses to chemicals in alloxan-diabetic rats.

Alloxan diabetes enhances the hepatotoxic response of male rats to chloroform and 1, 1, 2-trichloroethane, but not to trichloroethylene nor 1, 1, 1-trichloroethane. Insulin treatment partially protects the animals against the alloxan-induced enhancement of chloroform hepatotoxicity. Alloxan diabetes also enhances the hepatotoxic response to galactosamine but not to beryllium nor alpha-naphthylisothiocyanate.     

桑叶不同化学成分的降血糖作用

桑叶是一种重要的降血糖药用植物资源。以秋桑叶中提取的六种活性化学成分为材料,研究了六种提取物对四氧嘧啶诱导的糖尿病小鼠的降血糖效果。结果显示,各提取物均有一定的降血糖作用,其中以桑叶总多糖的功效最为显著,桑叶生物碱及桑叶黄酮苷类效果次之。     

Kinetics of lymphocytes in mice with alloxan diabetes

Alloxan diabetes (sucrose blood concentrate greater than or equal to 14 mmol/l decreased the life time of blood lymphocytes and increased the migration of these cells from lymphatic organs in BALB/c male mice. The proliferation pools of lymphoblasts and prolymphocytes in the thymus of diabetic mice were depressed, but in the lymphatic nodes remained unchanged. It has been shown that in lymphoid cells of the thymus of mice with diabetes the generation time and the time of G1- and G2-phase were significantly increased, but the time of the S-phase of the life cycle of these cells was normal. Proliferation of the lymphoid cells in lymphatic nodes was insulin-dependent. It has been shown that in the prolymphocytes of lymphatic nodes from diabetic mice the duration of the G1-phase was significantly decreased.     

Inflammatory biomarker, neopterin, suppresses B lymphopoiesis for possible facilitation of granulocyte responses, which is severely altered in age-related stromal-cell-impaired mice, SCI/SAM

Neopterin is produced by monocytes and is a useful biomarker of inflammatory activation. We found that neopterin enhanced in vivo and in vitro granulopoiesis triggered by the stromal-cell production of cytokines in mice. The effects of neopterin on B lymphopoiesis during the enhancement of granulopoiesis were determined using the mouse model of senescent stromal-cell impairment (SCI), a subline of senescence-accelerated mice (SAM). In non-SCI mice (a less senescent stage of SCI mice), treatment with neopterin decreased the number of colonies, on a semisolid medium, of colony-forming units of pre-B-cell progenitors (CFU-preB) from unfractionated bone marrow (BM) cells, but not that from a population rich in pro-B and pre-B cells without stromal cells. Neopterin upregulated the expression of genes for the negative regulators of B lymphopoiesis such as tumor necrosis factor-alpha (TNF-alpha ), interleukin-6 (IL-6), and transforming growth factor-beta (TGF-beta) in cultured stromal cells, implying that neopterin suppressed the CFU-preB colony formation by inducing negative regulators from stromal cells. The intraperitoneal injection of neopterin into non-SCI mice resulted in a marked decrease in the number of femoral CFU-preB within 1 day, along with increases in TNF-alpha and IL-6 expression levels. However, in SCI mice, in vivo and in vitro responses to B lymphopoiesis and the upregulation of cytokines after neopterin treatment were less marked than those in non-SCI mice. These results suggest that neopterin predominantly suppressed lymphopoiesis by inducing the production of negative regulators of B lymphopoiesis by stromal cells, resulting in the selective suppression of in vivo B lymphopoiesis. These results also suggest that neopterin facilitated granulopoiesis in BM by suppressing B lymphopoiesis, thereby contributing to the potentiation of the inflammatory process; interestingly, such neopterin function became impaired during senescence because of attenuated stromal-cell function, resulting in the downmodulation of the host-defense mechanism in the aged.     

Commonalities of genetic resistance to spontaneous autoimmune and free radical--mediated diabetes

ALR/Lt, a NOD-related mouse strain, was selected for resistance to alloxan free radical-mediated diabetes (ALD). Despite extensive genomic identity with NOD (>70%), ALR mice display strong resistance to autoimmune type 1 diabetes (T1D) due to both an unusual elevation in systemic antioxidant defenses and a reduction in cellular ROS production that extends to the beta cell level. Reciprocal backcross to NOD previously linked the ALR-derived T1D resistance to Chr. 3, 8, and 17 as well as to the ALR mt-Nd2(a) allele encoded by the mitochondrial genome (mtDNA). To determine whether any of the ALR-derived loci protecting against T1D also protected against ALD, 296 six-week-old F2 mice from reciprocal outcrosses were alloxan-treated and assessed for diabetes onset, and a genome-wide scan (GWS) was conducted. GWS linked mt-Nd2 as well as three nuclear loci with alloxan-induced diabetes. A dominant ALR-derived ALD resistance locus on Chr. 8 colocalized with the ALR-derived T1D resistance locus identified in the previous backcross analysis. In contrast, whereas ALR contributed a novel T1D resistance locus on Chr. 3 marked by Susp, a more proximal ALR-derived region marked by Il-2 contributed ALD susceptibility, not resistance. In addition, a locus was mapped on Chr. 2, where heterozygosity provided heightened susceptibility. Tests for alloxan sensitivity in ALR conplastic mice encoding the NOD mt-Nd2(c) allele and NOD mice congenic for the protective Chr. 8 locus supported our mapping results. Alloxan sensitivity was increased in ALR.mt(NOD) mice, whereas it was decreased by congenic introduction of ALR genome on Chr. 8 into NOD. These data demonstrate both similarities and differences in the genetic control of T1D versus ROS-induced diabetes.     

Enhanced alloxan-induced beta-cell damage and delayed recovery from hyperglycemia in mice lacking extracellular-superoxide dismutase.

Alloxan is a diabetogenic agent which apparently acts through formation of superoxide radicals formed by redox cycling. Superoxide radicals are also formed by a variety of mechanisms in hyperglycemia. We exposed extracellular-superoxide dismutase (EC-SOD) null mutant and wild-type mice to alloxan, and followed up both the initial diabetes induction and the long-term course of the hyperglycemia. The null mutant mice responded with a modestly enhanced hyperglycemia compared to the wild type controls. In the long-term follow-up all mice eventually regained glycemic control, although it took longer for individuals with higher initial hyperglycemia. This delaying effect of the hyperglycemia was much more pronounced in the null mutant mice. These data suggest that the difference in initial diabetes induction between the groups is due to interception by EC-SOD of extracellular superoxide radicals produced by alloxan. The delayed recovery in the null mutant mice suggests that superoxide radicals released as a result of hyperglycemia impair beta-cell regeneration and that EC-SOD provides some protection. Mouse islets were found to contain little EC-SOD, whereas the content of the cytosolic Cu- and Zn-containing SOD was very high. This low EC-SOD activity may contribute to the high alloxan susceptibility of beta-cells, and may also cause a high susceptibility to superoxide radicals produced by activated inflammatory leukocytes and in hyperglycemia.     

Protective effect of glutathione and selenium against alloxan induced lipid peroxidation and loss of antioxidant enzymes in erythrocytes

Alloxan is a diabetogenic drug and is known to induce diabetes through generation of free radicals. The toxic oxygen species can be detoxified by antioxidant enzyme system and thus reduce the deleterious effect of lipid peroxidation. Erythrocytes exposed to alloxan induced lipid peroxidationin vivo as well asin vitro. Although alloxan treatment produced a deleterious effect on antioxidant enzymes, pretreatment with glutathione and selenium led to a recovery of the activities of superoxide dismutase and glutathione peroxidase. However, catalase activity increased on alloxan treatment. Alloxan reduced blood glucose level significantly within 60 min but thereafter a slow and steady rise was observed.     

蒲桃仁提取物降血糖作用的实验研究

采用四氧嘧啶糖尿病小鼠模型及肾上腺素和葡萄糖引起的高血糖小鼠模型,观察蒲桃仁乙醇提取物对实验动物的降血糖效果。蒲桃仁乙醇提取物对四氧嘧啶所致糖尿病小鼠模型、肾上腺素和葡萄糖引起的高血糖模型小鼠有明显的降血糖作用,但对正常小鼠血糖无明显影响。     

The role of endogenous glucocorticoids in lymphocyte development in melanocortin receptor 2-deficient mice

Glucocorticoids are extensively used in anti-inflammatory therapy and are thought to contribute to the steady-state regulation of hematopoiesis and lymphopoiesis. We have previously established MC2R(-/-) mice, a model of familial glucocorticoid deficiency, that show several similarities to patients with this disease, including undetectable levels of corticosterone, despite high levels of ACTH and unresponsiveness to ACTH. In this study, we analyzed the possible roles of endogenous glucocorticoids in hematopoiesis and lymphopoiesis in MC2R(-/-) and CRH(-/-) mice as models of chronic adrenal insufficiency. Our analysis of total peripheral blood cell counts revealed that the number of lymphocytes was increased and the number of erythrocytes was slightly, but significantly, decreased in MC2R(-/-) mice. Numbers of immature double negative (CD4(-) CD8(-)) thymocytes, transitional type 1 B cells in the spleen, and pre-B cells in the bone marrow, were significantly increased in MC2R(-/-) mice, suggesting that endogenous glucocorticoids contribute to steady-state regulation of lymphopoiesis. Oral glucocorticoid supplementation reversed peripheral blood cell counts and reduced numbers of T and B cells in the thymus and the spleen. T cells in the thymus and B cells in the spleen were also increased in CRH(-/-) mice, another animal model of chronic adrenal insufficiency. MC2R(-/-) mice were sensitive to age-related thymic involution, but they were resistant to fasting-associated thymic involution. Our data support the idea that endogenous glucocorticoids contribute to stress-induced as well as steady-state regulation of hematopoiesis and lymphopoiesis.     

Adiponectin, a fat cell product, influences the earliest lymphocyte precursors in bone marrow cultures by activation of the cyclooxygenase-prostaglandin pathway in stromal cells

Adiponectin, an adipocyte-derived hormone, is attracting considerable interest as a potential drug for diabetes and obesity. Originally cloned from human s.c. fat, the protein is also found in bone marrow fat cells and has an inhibitory effect on adipocyte differentiation. The aim of the present study is to explore possible influences on lymphohematopoiesis. Recombinant adiponectin strongly inhibited B lymphopoiesis in long-term bone marrow cultures, but only when stromal cells were present and only when cultures were initiated with the earliest category of lymphocyte precursors. Cyclooxygenase inhibitors abrogated the response of early lymphoid progenitors to adiponectin in stromal cell-containing cultures. Furthermore, PGE(2), a major product of cyclooxygenase-2 activity, had a direct inhibitory influence on purified hematopoietic cells, suggesting a possible mechanism of adiponectin action in culture. In contrast to lymphopoiesis, myelopoiesis was slightly enhanced in adiponectin-treated bone marrow cultures, and even when cultures were initiated with single lymphomyeloid progenitors. Finally, human B lymphopoiesis was also sensitive to adiponectin in stromal cell cocultures. These results suggest that adiponectin can negatively and selectively influence lymphopoiesis through induction of PG synthesis. They also indicate ways that adipocytes in bone marrow can contribute to regulation of blood cell formation.     

Serum xanthine dehydrogenase of carbon tetrachloride-induced hepatotoxicity in alloxan-diabetic rats.

Xanthine dehydrogenase activity was determined in blood serum of rats in which diabetes had been induced by alloxan administration. The results show that there is no statistical significance in the difference found for normal and diabetic rats. Alloxan produced an inhibition in the enzyme activity in animals in which a carbon tetrachloride hepatotoxicity had been induced.     

Osteoclast activity modulates B-cell development in the bone marrow

B-cell development is dependent on the interactions between B-cell precursors and bone marrow stromal cells, but the role of osteoclasts (OCLs) in this process remains unknown. B lymphocytopenia is a characteristic of osteopetrosis, suggesting a modulation of B lymphopoiesis by OCL activity. To address this question, we first rescued OCL function in osteopetrotic oc/oc mice by dendritic cell transfer, leading to a restoration of both bone phenotype and B-cell development. To further explore the link between OCL activity and B lymphopoiesis, we induced osteopetrosis in normal mice by injections of zoledronic acid (ZA), an inhibitor of bone resorption. B-cell number decreased specifically in the bone marrow of ZA-treated mice. ZA did not directly affect B-cell differentiation, proliferation and apoptosis, but induced a decrease in the expression of CXCL12 and IL-7 by stromal cells, associated with reduced osteoblastic engagement. Equivalent low osteoblastic engagement in oc/oc mice confirmed that it resulted from the reduced OCL activity rather than from a direct effect of ZA on osteoblasts. These dramatic alterations of the bone microenvironment were disadvantageous for B lymphopoiesis, leading to retention of B-cell progenitors outside of their bone marrow niches in the ZA-induced osteopetrotic model. Altogether, our data revealed that OCLs modulate B-cell development in the bone marrow by controlling the bone microenvironment and the fate of osteoblasts. They provide novel basis for the regulation of the retention of B cells in their niche by OCL activity.     

Activity of NAD- and NADP-dependent malate dehydrogenase isoenzymes in the myocardium of rabbits with alloxan diabetes]

Isoenzymes NAD-and NaDP MDH were detected in the cardiac muscle of rabbits by disc electrophoresis in polyacrylamide gel. Alloxan diabetes proved to be accompanied by a significant reduction in the activity of mitochondrial NADP MDH (in the reaction of malic decarboxylation) and its increase in cytozol. The activity of NAD-MDH (in the reaction of oxyacetate reduction) was also decreased in various isoenzymes in the myocardium (particularly in the mitochondria) in diabetes. Insulin restored the correlation of the activities of the isoenzymes NAD- and NADP-MDH in the cytostructures of the myocardium disturbed in diabetes.     

Changes of pyruvate dehydrogenase in brain during alloxan diabetes

Alloxan diabetes causes a decrease in the active form of pyruvate dehydrogenase in rat brain. The effect is severe in the cerebellum and brain stem compared to cerebral hemispheres. The changes observed in the total form are not as significant as those found in the active (dephosphorylated) form. The effects are reversed after administration of insulin to diabetic animals. The severity of diabetes was also found to affect the activity of pyruvate dehydrogenase with inverse correlation. There was a gradual increase in the proportion of active (dephosphorylated) form with increase of time after the onset of diabetes.     

B lymphopoiesis is upregulated after orchiectomy and is correlated with estradiol but not testosterone serum levels in aged male rats.

Previous studies have shown that B lymphopoiesis is augmented after androgen withdrawal in male mice. As an analogy to the skeletal system, some effects of androgens on the proliferation of B cells may be mediated via aromatization into estrogens in vivo. The aim of the present study was to assess the effects of androgen withdrawal on B lymphopoiesis in bone marrow of aged male rats sequentially over a period of 9 months, and to correlate the flow-cytometric findings with changes in systemic levels of sex steroids. We first showed that androgen withdrawal is associated with enhanced B lymphopoiesis in bone marrow of 4-month-old male orchiectomized (ORX) rats, and that the changes in the bone marrow B cell compartment in ORX animals can be reversed by testosterone supplementation. In a subsequent, sequential experiment, we found that orchiectomy induced a sustained rise in Thy 1.1+/CD45R+ bone marrow cells committed for the B cell lineage that lasted for several months in 13-month-old aged rats. In a stepwise model of multiple regression analysis using estradiol, free and total testosterone as independent variables, estradiol was the strongest predictor of the percentage of B precursor cells in bone marrow in aged SHAM and ORX rats. Free and total testosterone did not correlate with B lymphopoiesis in aged SHAM rats. The current experiment has clearly shown that androgen withdrawal upregulates the number of B lineage cells over several months in rat bone marrow. Furthermore, our results provide evidence that estradiol may play an important role as a physiological suppressor of B lymphopoiesis in aged male rats.     

Depression of estrogen-induced uterine peroxidase in alloxan-diabetic rats

The influence of alloxan diabetes on reproductive function and the estradiol-stimulated increase in uterine peroxidase was investigated. Alloxan monohydrate in a dose of 75 mg/kg body weight effectively produced permanent diabetes. In adult rats, 20 days of diabetes resulted in cessation of the estrous cycle and a significant reduction in the gain of body weight, the weights of anterior pituitary gland, ovary, uterus, the level of serum progesterone and the activity of the estradiol-stimulated uterine peroxidase (P less than 0.05). After 10 days of insulin treatment, the ovarian weight, the estrous cycle and the level of ovarian hormones were restored to normal whereas the uterine weight and the estradiol-stimulated uterine peroxidase activity were only partially recovered. Persistent depression of the uterine response in the insulin-treated diabetic rats to both endogenous and exogenous ovarian hormone stimulation suggests that the uterus was directly affected by diabetes. The direct effect of diabetes upon the uterus was further demonstrated in the ovariectomized immature rat in which diabetes depressed the stimulatory action of estradiol on both uterine weight and uterine peroxidase activity.