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Query: UMLS:C0011860 (
type 2 diabetes
)
57,723
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A major pathological feature of noninsulin-dependent diabetes (
NIDDM
) is defective insulin-stimulated glucose transport in skeletal muscle. When
NIDDM
subjects are assessed as a group,
GLUT4
gene expression in skeletal muscle varies widely and is not different from that in controls. Thus, longitudinal studies are needed to assess whether changes in
GLUT4
expression in muscle of
NIDDM
subjects could be responsible for changes in glucose disposal. The question is timely because recent studies in transgenic mice show that increasing
GLUT4
expression can increase insulin-stimulated glucose uptake in vivo and in vitro. Here we use a longitudinal design to investigate the effects of 8 weeks of therapy with the sulfonylurea gliclazide on glycemic control, glucose tolerance, insulin-stimulated glucose disposal, and
GLUT4
expression in muscle of 10 obese
NIDDM
subjects. Subjects were on a weight-maintaining diet. Gliclazide treatment results in increased serum C-peptide, decreased hemoglobin-A1c, decreased glucose excursion on glucose tolerance test, and 35% increased insulin-stimulated glucose disposal. Gliclazide therapy is not associated with any change in DNA or protein content per g muscle or any alteration in
GLUT4
levels expressed either per microgram membrane protein or per DNA. In summary, the improvement in glycemic control and glucose disposal in
NIDDM
subjects receiving gliclazide therapy cannot be explained by increased expression of
GLUT4
in muscle. Thus, therapeutic effects on insulin-stimulated glucose disposal can be achieved in
NIDDM
subjects without altering
GLUT4
expression in muscle.
...
PMID:Sulfonylurea therapy improves glucose disposal without changing skeletal muscle GLUT4 levels in noninsulin-dependent diabetes mellitus subjects: a longitudinal study. 782 24
To assess the contribution of GLUT1 and
GLUT4
genes to
NIDDM
susceptibility in Japanese population, we performed population studies using RFLP markers. We found the strong association between XbaI polymorphism at GLUT1 gene and
NIDDM
, but no association between KpnI polymorphism at
GLUT4
gene and
NIDDM
. Based on these results, molecular scanning of GLUT1 gene was performed using SSCP and direct sequencing in Japanese population, to substantiate the gene defect predisposing to NDDM. Although silent mutations were found, the meaningful mutations within the coding regions were not demonstrated. Thus the positive association observed in population study may be spurious or due to the abnormalities in non-coding regions such as promoter or other regulatory elements at GLUT1 gene.
...
PMID:[Defects of candidate genes in Japanese NIDDM--glucose transporter gene(GLUT1 gene, GLUT4 gene)]. 798
Mechanisms causing cellular insulin resistance in gestational diabetes mellitus are not known. We, therefore, studied isolated omental adipocytes obtained during elective cesarean sections in nondiabetic (control) and GDM gravidas. Cellular insulin resistance was attributed to impaired stimulation of glucose transport; compared with control subjects, basal and maximally insulin-stimulated transport rates (per surface area) were reduced 38 and 60% in GDM patients, respectively. To determine underlying mechanisms, we assessed the number, subcellular distribution, and translocation of
GLUT4
, the predominant insulin-responsive glucose transporter isoform. The cellular content of
GLUT4
was decreased by 44% in GDM patients as assessed by immunoblot analysis of total postnuclear membranes. However, GDM patients segregated into two subgroups; half expected profound (76%) cellular depletion of
GLUT4
and half had
GLUT4
levels in the normal range. Cellular
GLUT4
was negatively correlated with adipocyte size in the control subjects and GDM patients with normal
GLUT4
(r = 0.60), but fell way below this continuum in GDM patients with low
GLUT4
, indicating that heterogeneity was not caused by differences in obesity. All GDM. distribution. In basal cells, increased amounts of
GLUT4
were detected in membranes fractionating with (such that the plasma membrane
GLUT4
level in GDM (such that the plasma membrane
GLUT4
level in GDM patients was equal to that observed in insulin-stimulated cells from control subjects). Furthermore, insulin stimulation induced translocation of
GLUT4
from low-density microsomes to plasma membranes in control subjects but did not alter subcellular distribution in GDM patients. In other experiments, cellular content of GLUT1 was normal in GDM patients, and GLUT1 did not undergo insulin-mediated recruitment to plasma membranes in either control subjects or GDM patients. A faint signal was detected for GLUT3 only in low-density microsomes and only with one of two different antibodies. In GDM, we conclude that insulin resistance in adipocytes involves impaired stimulation of glucose transport and arises from a heterogeneity of defects intrinsic to the glucose transport effector system.
GLUT4
content in adipocytes is profoundly depleted in approximately 50% of GDM patients, whereas all patients are found to exhibit a novel abnormality in
GLUT4
subcellular distribution. This latter defect is characterized by accumulation of
GLUT4
in membranes cofractionating with plasma membranes and high-density microsomes in basal cells and absence of translocation in response to insulin. The data suggest that abnormalities in cellular traffic or targeting relegate
GLUT4
to a membrane compartment from which insulin cannot recruit transporters to the cell surface and have important implications regarding skeletal muscle insulin resistance in GDM and
NIDDM
.
...
PMID:Multiple defects in the adipocyte glucose transport system cause cellular insulin resistance in gestational diabetes. Heterogeneity in the number and a novel abnormality in subcellular localization of GLUT4 glucose transporters. 824 23
Sulfonylurea drugs are widely used in the therapy of
NIDDM
. The improvement of glucose tolerance after long-term treatment of
NIDDM
patients with the drug can be explained by stimulation of glucose utilization in peripheral tissues that are characterized by insulin resistance in these patients. We studied whether the novel sulfonylurea drug, glimepiride, stimulates glucose transport into isolated insulin-resistant rat adipocytes. After long-term incubation of the cells in primary culture with high concentrations of glucose, glutamine, and insulin, stimulation of glucose transport by insulin was significantly reduced both with respect to maximal responsiveness (65% decrease of Vmax) and sensitivity (2.6-fold increase of ED50) compared with adipocytes cultured in medium containing a low concentration of glucose and no insulin. This reflects insulin resistance of glucose transport. In contrast, both responsiveness and sensitivity of glucose transport toward stimulation by glimepiride were only marginally reduced in insulin-resistant adipocytes (15% decrease of Vmax; 1.2-fold increase of ED50) versus control cells. Glimepiride, in combination with glucose and glutamine during the primary culture, caused desensitization of the glucose transport system toward stimulation by insulin, but to a lesser degree than insulin itself (50% reduction of Vmax; ninefold increase of ED50). Again, the maximal responsiveness and sensitivity of glucose transport toward stimulation by glimepiride were only slightly diminished. The presence of glimepiride during primary culture did not antagonize the induction of insulin resistance of glucose transport. The stimulation of glucose transport in insulin-resistant adipocytes by glimepiride is caused by translocation of glucose transporters from low-density microsomes to plasma membranes as demonstrated by subcellular fractionation and immunoblotting with anti-GLUT1 and anti-
GLUT4
antibodies. Immunoprecipitation of
GLUT4
from 32Pi- and [35S]methionine-labeled adipocytes revealed that the insulin resistance of
GLUT4
translocation is accompanied by increased (three- to fourfold) phosphorylation of
GLUT4
in both low-density microsomes and plasma membranes. Short-term treatment of desensitized adipocytes with glimepiride or insulin reduced
GLUT4
phosphorylation by approximately 70 and 25%, respectively, in both fractions. We conclude that glimepiride activates glucose transport by stimulation of GLUT1 and
GLUT4
translocation in rat adipocytes via interference at a site downstream of the putative molecular defect in the signaling cascade between the insulin receptor and the glucose transport system induced by high concentrations of glucose and insulin. The molecular site of glimepiride action is related to
GLUT4
phosphorylation/dephosphorylation, which may regulate glucose transporter activity and translocation.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:The sulfonylurea drug, glimepiride, stimulates glucose transport, glucose transporter translocation, and dephosphorylation in insulin-resistant rat adipocytes in vitro. 824 32
A primary human skeletal muscle culture (HSMC) system, which retains cellular integrity and insulin responsiveness for glucose transport was employed to evaluate glucose transport regulation. As previously reported, cells cultured from non-insulin-dependent diabetic (
NIDDM
) subjects displayed significant reductions in both basal and acute insulin-stimulated transport compared to nondiabetic controls (NC). Fusion/differentiation of NC and
NIDDM
HSMC in elevated media insulin (from 22 pM to 30 microM) resulted in increased basal transport activities but reduced insulin-stimulated transport, so that cells were no longer insulin responsive. After fusion under hyperinsulinemic conditions, GLUT1 protein expression was elevated in both groups while
GLUT4
protein level was unaltered. Fusion of HSMC under hyperglycemic conditions (10 and 20 mM) decreased glucose transport in NC cells only when combined with hyperinsulinemia. Hyperglycemia alone down-regulated transport in HSMC of
NIDDM
, while the combination of hyperglycemia and hyperinsulinemia had greater effects. In summary: (a) insulin resistance of glucose transport can be induced in HSMC of both NC and
NIDDM
by hyperinsulinemia and is accompanied by unaltered
GLUT4
but increased GLUT1 levels; and (b) HSMC from
NIDDM
subjects demonstrate an increased sensitivity to impairment of glucose transport by hyperglycemia. These results indicate that insulin resistance in skeletal muscle can be acquired in NC and
NIDDM
from hyperinsulinemia alone but that
NIDDM
is uniquely sensitive to the additional influence of hyperglycemia.
...
PMID:Glucose transport in cultured human skeletal muscle cells. Regulation by insulin and glucose in nondiabetic and non-insulin-dependent diabetes mellitus subjects. 867 52
Insulin resistance of muscle glucose metabolism is a hallmark of
NIDDM
. The obese Zucker (fa/fa) rat--an animal model of muscle insulin resistance--was used to test whether acute (100 mg/kg body wt for 1 h) and chronic (5-100 mg/kg for 10 days) parenteral treatments with a racemic mixture of the antioxidant alpha-lipoic acid (ALA) could improve glucose metabolism in insulin-resistant skeletal muscle. Glucose transport activity (assessed by net 2-deoxyglucose [2-DG] uptake), net glycogen synthesis, and glucose oxidation were determined in the isolated epitrochlearis muscles in the absence or presence of insulin (13.3 nmol/l). Severe insulin resistance of 2-DG uptake, glycogen synthesis, and glucose oxidation was observed in muscle from the vehicle-treated obese rats compared with muscle from vehicle-treated lean (Fa/-) rats. Acute and chronic treatments (30 mg.kg-1.day-1, a maximally effective dose) with ALA significantly (P < 0.05) improved insulin-mediated 2-DG uptake in epitrochlearis muscles from the obese rats by 62 and 64%, respectively. Chronic ALA treatment increased both insulin-stimulated glucose oxidation (33%) and glycogen synthesis (38%) and was associated with a significantly greater (21%) in vivo muscle glycogen concentration. These adaptive responses after chronic ALA administration were also associated with significantly lower (15-17%) plasma levels of insulin and free fatty acids. No significant effects on glucose transporter (
GLUT4
) protein level or on the activities of hexokinase and citrate synthase were observed. Collectively, these findings indicate that parenteral administration of the antioxidant ALA significantly enhances the capacity of the insulin-stimulatable glucose transport system and of both oxidative and nonoxidative pathways of glucose metabolism in insulin-resistant rat skeletal muscle.
...
PMID:The antioxidant alpha-lipoic acid enhances insulin-stimulated glucose metabolism in insulin-resistant rat skeletal muscle. 869 Jan 47
The effect of insulin to acutely stimulate glucose uptake into muscle and adipose tissue is essential for normal glucose homeostasis. The
GLUT4
glucose transporter is a major mediator of this action, and insulin recruits
GLUT4
from an intracellular pool to the plasma membrane. An important pathologic feature of obesity,
NIDDM
, and to a lesser extent IDDM is resistance to insulin-stimulated glucose uptake. Investigations of the mechanisms have revealed tissue-specific regulation of
GLUT4
with decreased gene expression in adipose cells but not in skeletal muscle. This has led to the hypothesis that alterations in the trafficking of the
GLUT4
vesicle or in the exposure or activation of the
GLUT4
transporter may cause insulin resistance in skeletal muscle in obesity and diabetes. Exercise training increases
GLUT4
expression in muscle in association with enhanced glucose tolerance in vivo. Transgenic mice have been created to investigate other approaches to improve insulin action on glucose transport. Overexpression of
GLUT4
in adipocytes of transgenic mice increases the proportion of
GLUT4
on the plasma membrane and enhances insulin sensitivity in vivo. Altering insulin signaling by overexpressing p21ras in adipocytes of transgenic mice results in increased
GLUT4
on the plasma membrane in the absence of insulin and increases insulin sensitivity in vitro and in vivo. Thus, glucose transport is a pivotal step in whole-body insulin action. Strategies to increase the number of
GLUT4
transporters that are functionally inserted in the plasma membrane in muscle and adipocytes may lead to new therapies to treat or prevent
NIDDM
.
...
PMID:Lilly lecture 1995. Glucose transport: pivotal step in insulin action. 886 74
The abnormalities of the membrane carrier proteins, mainly of glucose transporters were screened in
NIDDM
patients. Several polymorphisms that result in amino acid substitutions have been identified in GLUT2 and
GLUT4
genes. However no significant associations have been found between
NIDDM
and these polymorphisms. Although the screening of ATP-sensitive potassium channel gene that has recently been isolated in pancreatic beta cells is now in progress, so far no abnormalities of the membrane carrier proteins have been reported to contribute in the causes of
NIDDM
.
...
PMID:[Membrane carrier proteins and NIDDM]. 890 34
Polymorphic variation of genes encoding the glucose transporters glycoproteins (GLUT) may contribute to the genetic susceptibility to type 2 (non-insulin-dependent) diabetes. In this study we evaluated the allele and genotype frequencies of GLUT1 and
GLUT4
restriction fragment length polymorphism (RFLP), revealed by digestion with XbaI for GLUT1 and KpnI for
GLUT4
, in Caucasian, Chinese, Japanese, Asian Indian and American black populations. No differences of the KpnI GLUT 4 RFLP were found between control and diabetic subjects in any ethnic group or when all data are combined. In contrast, positive results were found for the XbaI RFLP: (1) most ethnic groups showed an association of allele 1 with
type 2 diabetes
, and this association was maintained when all groups were analysed together; (2) after stratifying for sex and obesity, this association was significant only for overweight/obese women. This joint analysis suggests that GLUT1 polymorphism may contribute to susceptibility to
type 2 diabetes
in some populations, and especially in overweight/obese women.
...
PMID:Genetic contribution of polymorphism of the GLUT1 and GLUT4 genes to the susceptibility to type 2 (non-insulin-dependent) diabetes mellitus in different populations. 890 24
Previous studies have shown that T3 coordinately stimulates
GLUT4
-glucose transporter messenger RNA (mRNA) and protein expression in mixed fiber-type skeletal muscle of the rat and produces a concomitant elevation in basal (noninsulin mediated) glucose uptake. The aim of the present study was to 1) determine the precise mechanism(s) for the T3-induced expression of
GLUT4
in skeletal muscle, and 2) investigate the potential benefits of T3 on
noninsulin dependent diabetes mellitus
(
NIDDM
). Ten daily ip injections of T3 (100 micrograms/100 g BW) administered to hypothyroid male Sprague-Dawley rats, increased both
GLUT4
mRNA and transcription approximately 70% (P < 0.05) in mixed fiber-type hindlimb skeletal muscle. Transcriptional induction was subsequently defined to be restricted to red (oxidative) muscle fibers (2.5-fold; P < 0.05), whereas
GLUT4
protein was increased in both red and white (glycolytic) skeletal muscle.
GLUT4
mRNA and protein expression were similarly inducible in the skeletal muscle of insulin-resistant Zucker rats. More importantly, T3 treatment totally ameliorated hyperinsulinemia in obese animals (P < 0.001), although their moderately elevated plasma glucose levels were not significantly altered. In conclusion, regulation of
GLUT4
expression by T3 was shown to lie at the transcriptional level in red skeletal muscle, whereas in white muscle fiber types, it appears to operate via an alternative posttranscriptional mechanism. These data also support the potential of hormonally inducing glucose transporter expression in insulin-resistant muscle. However, high levels of T3 are associated with a number of adverse side-effects, in particular the stimulation of hepatic gluconeogenesis. Nevertheless, future studies may demonstrate, e.g. subthyrotoxic levels, to be similarly effective but without side effects, and thus perhaps find a clinical application in reducing both hyperinsulinemia and hyperglycemia in
NIDDM
.
...
PMID:Effects of thyroid hormone on GLUT4 glucose transporter gene expression and NIDDM in rats. 904 28
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