Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011854 (type 1 diabetes)
 20,749 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In this study, the in vivo effects of insulin and chronic treatment with bis(maltolato)oxovanadium (IV) (BMOV) on protein kinase B (PKB) activity were examined in the liver and skeletal muscle from two animal models of diabetes, the STZ-diabetic Wistar rat and the fatty Zucker rat. Animals were treated with BMOV in the drinking water (0.75-1 mg/ml) for 3 (or 8) weeks and sacrificed with or without insulin injection. Insulin (5 U/kg, i.v.) increased PKBalpha activity more than 10-fold and PKBbeta activity more than 3-fold in both animal models. Despite the development of insulin resistance, insulin-induced activation of PKBalpha was not impaired in the STZ-diabetic rats up to 9 weeks of diabetes, excluding a role for PKBalpha in the development of insulin resistance in type 1 diabetes. Insulin-induced PKBalpha activity was markedly reduced in the skeletal muscle of fatty Zucker rats as compared to lean littermates (fatty: 7-fold vs. lean: 14-fold). In contrast, a significant increase in insulin-stimulated PKBalpha activity was observed in the liver of fatty Zucker rats (fatty: 15.7-fold vs. lean: 7.6-fold). Chronic treatment with BMOV normalized plasma glucose levels in STZ-diabetic rats and decreased plasma insulin levels in fatty Zucker rats but did not have any effect on basal or insulin-induced PKBalpha and PKBbeta activities. In conclusion (i) in STZ-diabetic rats PKB activity was normal up to 9 weeks of diabetes; (ii) in fatty Zucker rats insulin-induced activation of PKBalpha (but not PKBbeta) was markedly altered in both tissues; (iii) changes in PKBalpha activity were tissue specific; (iv) the glucoregulatory effects of BMOV were independent of PKB activity.
Mol Cell Biochem 2001 Jul
PMID:In vivo effects of insulin and bis(maltolato)oxovanadium (IV) on PKB activity in the skeletal muscle and liver of diabetic rats. 1168 16

Dominantly inherited progressive hearing loss DFNA38 is caused by heterozygosity for a novel mutation in WFS1, the gene for recessively inherited Wolfram syndrome. Wolfram syndrome is defined by juvenile diabetes mellitus and optic atrophy and may include progressive hearing loss and other neurological symptoms. Heterozygotes for other Wolfram syndrome mutations generally have normal hearing. Dominant deafness defined by DFNA38 is more severe than deafness of Wolfram syndrome patients and lacks any syndromic features. In a six-generation kindred from Newfoundland, Canada, WFS1 Ala716Thr (2146 G-->A) was shared by all deaf members of the family and was specific to deaf individuals. The causal relationship between this missense mutation and deafness was supported by two observations based on haplotype and mutation analysis of the kindred. First, a relative homozygous for the mutation was diagnosed at age 3 years with insulin-dependent diabetes mellitus, the central feature of Wolfram syndrome. Second, two relatives with normal hearing had an identical haplotype to that defining DFNA38, with the exception of the base pair at position 2146. Other rare variants of WFS1 co-inherited with deafness in the family could be excluded as disease-causing mutations on the basis of this hearing-associated haplotype. The possibility that 'mild' mutations in WFS1 might be a cause of non-syndromic deafness in the general population should be explored.
Hum Mol Genet 2001 Oct 15
PMID:Non-syndromic progressive hearing loss DFNA38 is caused by heterozygous missense mutation in the Wolfram syndrome gene WFS1. 1170 38

After some initial disappointments, the field of gene therapy is now gaining confidence and momentum. Recent improvements in gene transfer techniques promise targeted and supra-threshold levels of transgene expression leading to the desired therapeutic effects. This increase in optimism has spread to thefield of diabetes research. Firstly, the recent developments in gene transfer techniques are now being tested on the pancreatic insulin producing beta-cell. For many gene therapy strategies in the treatment of diabetes, transfection of insulin producing cells is a prerequisite. Secondly, if efficient and safe vectors that transduce beta-cells in vivo or ex vivo are made available, autoimmune beta-cell destruction in type 1 diabetes could be prevented. In this strategy, it is envisaged that gene therapy will protect the remaining beta-cell mass in newly diagnosed diabetics or pre-diabetic individuals at a high risk of becoming diabetic from autoimmune destruction. Thirdly, attempts are being made to genetically engineer cells to become artificial beta-cells. Such cells could conceivably compensate for the lost endogeneous alpha-cell mass and restore a regulated insulin secretion. This review will attempt to predict the future of gene therapy in the treatment of diabetes.
Curr Opin Mol Ther 1999 Aug
PMID:Gene therapy in diabetes mellitus: promises and piffalls. 1171 61

Type 1 diabetes results from the loss of insulin-producing pancreatic beta cells following the action of beta-cell-specific autoimmune responses. One possible treatment for type 1 diabetes is the development of beta-cell substitutes by introducing an insulin-producing gene into non-beta cells, which would evade the beta-cell-specific autoimmune attack. However, this approach has been hampered by the absence of (1) an appropriate glucose-sensing system to regulate insulin gene transcription; (2) enzymes that process proinsulin to insulin; and (3) glucose-regulatable exocytosis in the target cells. Recent attempts to solve these problems have sought new methods for effective gene transfer and have addressed issues such as the expression and release of insulin in response to the physiological stimulus of glucose, the production of biologically active insulin, and the selection of an ideal target cell for the expression of the insulin gene.
Trends Mol Med 2002 Feb
PMID:Recent advances in insulin gene therapy for type 1 diabetes. 1181 71

Recent reports indicate successful transduction of pancreatic islets using recombinant adeno-associated viral (rAAV) vectors. This advance offers new possibilities in rendering islets resistant to rejection and recurrence of autoimmune destruction in the setting of islet transplantation as treatment of type 1 diabetes. Most gene delivery approaches using islets have thus far involved transduction with a single gene. However, the concomitant delivery of more than one gene encoding cytoprotective and/or immunoregulatory molecules may offer superior clinical utility. Here, we have generated a bicistronic rAAV (serotype 2) vector incorporating a viral internal ribosome entry site (IRES), derived from polio virus type 1, to allow for translation of two coupled cDNAs from a single mRNA transcript. Our study demonstrates the ability of this vector to produce significant expression of two reporter proteins in human and mouse islets in vitro. This expression did not interfere with beta-cell function. Transduction was maintained in vivo following transplantation of mouse islets. These data are the first report of efficient islet cell transduction with two genes using a single bicistronic rAAV vector and have direct implications for strategies aimed at enhancing islet transplant survival.
Mol Ther 2002 Feb
PMID:Transduction of human and mouse pancreatic islet cells using a bicistronic recombinant adeno-associated viral vector. 1182 22

The heart, like other organs, possesses an internal circadian clock. These clocks provide the selective advantage of anticipation, enabling the organ to prepare for a given stimulus, thereby optimizing the appropriate response. The heart in diabetes is associated with alterations in morphology, gene expression, metabolism and contractile performance. The present study investigated whether diabetes also alters the circadian clock in the heart. Insulin-dependent diabetes mellitus was induced in rats by treatment with streptozotocin (STZ; 65 mg/kg). STZ increased humoral (glucose and non-esterified fatty acids) and heart gene expression (myosin heavy chain beta, pyruvate dehydrogenase kinase 4 and uncoupling protein 3) markers of diabetes. The circadian patterns of gene expression of seven components of the mammalian clock (bmal1, clock, cry1, cry2, per1, per2 and per3), as well as three clock output genes (dbp, hlf and tef), were compared in hearts isolated from control and STZ-induced diabetic rats. All components of the clock investigated possessed circadian rhythms of gene expression. In the hearts isolated from STZ-induced diabetic rats, the phases of these circadian rhythms were altered (approximately 3 h early) compared to those observed for control hearts. The clock in the heart has therefore lost normal synchronization with its environment during diabetes. Whether this loss of synchronization plays a role in the development of contractile dysfunction of the heart in diabetes remains to be determined.
J Mol Cell Cardiol 2002 Feb
PMID:Alterations of the circadian clock in the heart by streptozotocin-induced diabetes. 1185 61

Almost all major causes of ill-health and premature death in human societies worldwide - including cancer, cardiovascular disease, diabetes and many infectious diseases - are, at least in part, genetically determined. Typically, risk of succumbing to one of these illnesses is thought to depend on both the individual repertoire of variation within a number of key susceptibility genes and the history of exposure to relevant environmental factors. For many of these conditions, the molecular basis of disease pathogenesis remains obscure. This represents a major obstacle to development of improved, rational strategies for disease treatment, prevention and eradication. It is easy therefore to appreciate the importance attached to efforts to deliver more comprehensive understanding of the molecular basis of disease pathogenesis. Nor is it hard to understand that identification of major susceptibility genes should highlight those components of molecular machinery that are critical for the preservation of normal health. The benefits promised are great, but progress to gene identification in multifactorial traits has been rather disappointing to date. Why is this? This review aims to answer this question by describing current and future approaches to gene discovery in multifactorial traits. The examples quoted will mostly relate to type 2 diabetes, but the issues and approaches are generic, and apply equally to other multifactorial traits in the endocrine and metabolic arena - type 1 diabetes; obesity; hyperlipidaemia; autoimmune thyroid disease; polycystic ovarian syndrome - and beyond.
J Mol Endocrinol 2002 Feb
PMID:Susceptibility gene discovery for common metabolic and endocrine traits. 1185 95

Most viral gene delivery syslems utilized to date have demonstrated significant limitations in practicality and safety due to the level and duration of recombinant transgene expression as well as their induction of host immunogenicity to vector proteins. Recombinant adeno-associated virus (rAAV) vectors appear to offer a vehicle for safe, long-term therapeutic gene transfer; factors afforded through the propensity of rAAV to establish long-term latency without deleterious effects on the host cell and the relative non-immunogenicity of the virus or viral expressed transgenes. The principal historical limitation of this vector system, efficiency of rAAV-mediated transduction, has recently observed a dramatic increase as the titer, purity, and production capacity of rAAV preparations have improved. In terms of systems that could benefit from such improvements, rAAV gene therapy to enhance solid organ transplantation would appear an obvious choice with islet transplantation forming a promising candidate due to the ability to perform viral transductions ex vivo. Currently, islet transplantation can be used to treat type 1 diabetes yet persisting alloimmune and autoimmune responses represent major obstacles to the clinical success for this procedure. The delivery of transgenes capable of interfering with antigenic recognition and/or cell death [e.g., Fas ligand (FasL), Bcl-2, Bcl-XL] as well as imparting tolerance/immunoregulation [e.g., interleukin(IL)-4, IL-10, transforming growth factor (TGF)-beta], or cytoprotection [e.g., heme oxygenase-1 (HO-1), catalase, manganese superoxide dismutase (MnSOD)] may prevent recurrent type 1 diabetes in islet transplantation and offer a promising form of immunotherapy. Research investigations utilizing such systems may also provide information vital to understanding the immunoregulatory mechanisms critical to the development of both alloimmune and autoimmune islet cell rejection mechanisms and recurrent type 1 diabetes.
Curr Mol Med 2001 May
PMID:Adeno-associated virus (AAV) as a vehicle for therapeutic gene delivery: improvements in vector design and viral production enhance potential to prolong graft survival in pancreatic islet cell transplantation for the reversal of type 1 diabetes. 1189 74

There are diverse strategies for gene therapy of diabetes mellitus. Prevention of beta-cell autoimmunity is a specific gene therapy for prevention of type 1 (insulin-dependent) diabetes in a preclinical stage, whereas improvement in insulin sensitivity of peripheral tissues is a specific gene therapy for type 2 (non-insulin-dependent) diabetes. Suppression of beta-cell apoptosis, recovery from insulin deficiency, and relief of diabetic complications are common therapeutic approaches to both types of diabetes. Several approaches to insulin replacement by gene therapy are currently employed: 1) stimulation of beta-cell growth, 2) induction of beta-cell differentiation and regeneration, 3) genetic engineering of non-beta cells to produce insulin, and 4) transplantation of engineered islets or beta cells. In type 1 diabetes, the therapeutic effect of beta-cell proliferation and regeneration is limited as long as the autoimmune destruction of beta cells continues. Therefore, the utilization of engineered non-beta cells free from autoimmunity and islet transplantation with immunological barriers are considered potential therapies for type 1 diabetes. Proliferation of the patients' own beta cells and differentiation of the patients' own non-beta cells to beta cells are desirable strategies for gene therapy of type 2 diabetes because immunological problems can be circumvented. At present, however, these strategies are technically difficult, and transplantation of engineered beta cells or islets with immunological barriers is also a potential gene therapy for type 2 diabetes.
Curr Mol Med 2001 Jul
PMID:Gene therapy for diabetes mellitus. 1189 81

Interleukin 1 (IL-1) is a pleiotropic cytokine with the potential to destroy pancreatic beta-cells, and thought to be involved in the pathogenesis of type I diabetes mellitus. Expression of inducible nitric oxide synthase (iNOS) and subsequent NO formation induced by IL-1beta may impair an islet function in rodents. Inhibition of iNOS may protect against cytokine-induced beta-cell suppression, although cytokines might also induce NO-independent impairment. To examine the role of NO in the IL-1beta treated cells, rat islets were treated with various concentrations (0, 0.5, 5, 50, 500 pmol/L) of IL-1beta with or without NG-monomethyl-L-arginine (NMMA; a competitive inhibitor of nitiric oxide synthase) for 2 or 6 h. Insulin secretion was stimulated in islets treated with 5, 50, and 500 pmol/ L of IL-1beta for 2 h and 0.5 pmol/L for 6 h, respectively. The stimulatory effect of IL-1beta on the insulin secretion of rat islets was not prevented by NMMA. Nitrate concentration was increased in a time- and concentration-dependent manner. Nitrate production was inhibited by NMMA. iNOS mRNA expression was increased at concentrations more than 5 pmol/L of IL-1beta in a dose dependent manner. iNOS mRNA was detectable after 2 h and peaked at 6 h but decreased after 24 h. These results suggested that the stimulatory effect of IL-1beta on the insulin secretion of rat islets is independent of iNOS-related NO production of IL-1beta and the enzyme activity of nitric oxide synthase.
Exp Mol Med 2002 Mar 31
PMID:The stimulatory effect of IL-1beta on the insulin secretion of rat pancreatic islet is not related with iNOS pathway. 1198 73


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