UMLS:C0028754 - FACTA Search

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Query: UMLS:C0028754 (obesity)
124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

After three decades of physiological research, the precise nature of the genetic lesion in Zucker fatty (fa/fa) rats remains unknown. Several methods have been used to identify preobese rats to detect the earliest phenotypic effects of the fa mutation. Most of these methods have used phenotypic characteristics that are not reliable until the second week of life, when increased adiposity is already evident. We have used a restriction fragment length polymorphism (RFLP) for a human genomic DNA probe (VC85) that is tightly linked to the fa locus on rat chromosome 5 to genotype the F2 progeny of a Zucker (13M) x Brown Norway (BN) fa/+ F1 intercross. Sixty-four rats, comprising five litters, were killed at 5-6 wk of age. DNA was isolated either from tail at age 4-7 days (36 rats) or from organs at the time of death (28 rats). Adiposity was scored using inguinal fat pad weight as a percentage of body weight. RFLP analysis was > 99% accurate in identifying obese (fa/fa) rats. This molecular genetic method can be used to genotype fatty rats from an appropriate genetic cross at any age, even prenatally. Moreover, this method can distinguish heterozygous from homozygous littermates, enabling an analysis of gene dosage effects.
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PMID:A molecular genetic method for genotyping fatty (fa/fa) rats. 809 75

Lethal yellow (Ay) is a mutation at the mouse agouti (a) locus that is associated with an all-yellow coat color, obesity, diabetes, tumors in heterozygotes, and preimplantation embryonic lethality in homozygotes. Previously, we cloned and characterized the wild-type agouti gene and demonstrated that it expresses a 0.8-kb mRNA in neonatal skin. In contrast, Ay expresses a 1.1-kb transcript that is ectopically overexpressed in all tissues examined. The Ay mRNA is identical to the wild-type a transcript for the entire coding region, but the 5'-untranslated sequence of the a gene has been replaced by novel sequence. Here, we demonstrate that the novel 5' sequence in the Ay mRNA corresponds to the 5'-untranslated sequence of another gene that is normally tightly linked to a in mouse chromosome 2. This other gene (Raly) has the potential to encode a novel RNA-binding protein that is normally expressed in the preimplantation embryo, throughout development, and in all adult tissues examined. Importantly, the Ay mutation disrupts the structure and expression of the Raly gene. The data suggest that the Ay mutation arose from a DNA structural alteration that affects the expression of both agouti and Raly. We propose that the dominant pleiotropic effects associated with Ay may result from the ectopic overexpression of the wild-type a gene product under the control of the Raly promoter and that the recessive embryonic lethality may be the result of the lack of Raly gene expression in the early embryo.
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PMID:The embryonic lethality of homozygous lethal yellow mice (Ay/Ay) is associated with the disruption of a novel RNA-binding protein. 831 10

A special subphenotype of the fragile X syndrome is reported which is characterised by extreme obesity with a full, round face, small, broad hands/feet, and regional skin hyperpigmentation. It resembles the Prader-Willi syndrome (PWS) and might therefore be named 'Prader-Willi-like'. Unlike the PWS, these PW-like fragile X patients lack the neonatal hypotonia with feeding problems during infancy followed by hyperphagia from toddlerhood. We describe five new fragile X patients and present a clinical update of three previously described patients with the PW-like phenotype. In one family, segregation of either the classical Martin-Bell or the PW-like phenotype was observed and in another family there was repeated transmission of the PW-like phenotype. Previously, one of the patients had been misdiagnosed as having classical PWS, based on clinical findings. Molecular studies of the FMR-1 gene showed the typical full mutations as seen in fragile X syndrome males. Molecular analysis of the 15q11-13 region, which is deleted in the majority of classical PWS patients, did not show any detectable abnormalities. In a group of 26 patients with suspected Prader-Willi syndrome but without detectable molecular abnormalities of chromosome 15, one fragile X patient was found. These clinical and molecular findings illustrate the necessity to perform DNA analysis of the FMR-1 gene in mentally retarded patients presenting with a PW phenotype but without the PWS specific cytogenetic/molecular abnormalities of chromosome 15.
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PMID:Clinical and molecular studies in fragile X patients with a Prader-Willi-like phenotype. 801 84

In this study we determined whether alterations in the expression of GLUT4, the major insulin-regulatable glucose transporter, in skeletal muscle could explain the insulin-resistant glucose uptake characteristic of both dietary-induced and genetic obesity. GLUT1 expression was measured for comparison. To assess glucose transporter protein levels in dietary-induced obesity, postnuclear membranes were prepared from hindlimb muscle of Sprague-Dawley rats fed chow ad libitum (control), a high calorie/carbohydrate diet, or a high fat (80%) diet for 7 weeks. Immunoblotting revealed that GLUT4 protein levels decreased 34% in high fat-fed rats, but were unaltered in high calorie/carbohydrate-fed obese rats compared to control values. GLUT4 mRNA per DNA decreased 47% in muscle of high fat-fed rats compared to that in control or high calorie-fed rats; GLUT1 mRNA was reduced 31%, and actin mRNA tended to decrease (29%). To assess GLUT4 and GLUT1 expression in genetic obesity, similar studies were carried out in 5- and 20-week-old lean and obese Zucker rats as well as in 20-week-old obese Zucker rats 36 h after streptozotocin injection to lower insulin levels. GLUT4 protein and mRNA levels were unaltered in hindlimb muscle of obese Zucker rats at either age or in the acutely diabetic state, whereas GLUT1 protein and mRNA levels decreased 40-45%. Comparison of these results with recent data in adipocytes demonstrates tissue-specific regulation of expression of GLUT4 and GLUT1. Thus, obesity due to high fat feeding, but not that due to high calorie/carbohydrate feeding or genetics, is associated with pretranslational suppression of GLUT4 expression in skeletal muscle. In at least some forms of obesity, the level of GLUT4 expression in muscle appears to be only one factor in, or may even be unrelated to, the degree of insulin-responsive glucose transport in vivo.
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PMID:Suppression of GLUT4 expression in skeletal muscle of rats that are obese from high fat feeding but not from high carbohydrate feeding or genetic obesity. 841 18

Corticotropin-releasing factor (CRF) appears to regulate several physiological systems that display prominent abnormalities in Zucker fatty (fa/fa) rats, including the hypothalamic-pituitary-adrenal axis, the autonomic nervous system, and feeding behavior. Moreover, central administration of CRF ameliorates the obese phenotype. In light of these observations, the gene for CRF is a plausible candidate for the defective gene in the Zucker fatty rat. We report here the use of molecular genetic linkage analysis to test the hypothesis that fa is a mutant allele of the CRF gene. A restriction fragment length polymorphism for CRF between Zucker (13M) and Brown Norway (BN) DNA allowed us to examine segregation of 13M and BN CRF alleles relative to fa in 58 obese (fa/fa) F2 progeny of a 13MBN fa/+F1 intercross. If fa = CRF, all animals homozygous for the fatty mutation should be homozygous for the 13M CRF allele. However, only 10/58 fa/fa animals were homozygous for the 13M CRF allele, indicating that fa and CRF are not allelic. Thus, although CRF may be important in the physiology of Zucker rat obesity, fa is not a CRF mutation. Using a mouse C57BL/6J Spretus F1 x C57BL DBA/2J F1 intercross, we were able to demonstrate that the mouse CRF gene is linked to the carbonic anhydrase II (Car-2) gene on mouse chromosome 3, in a region of synteny-homology with rat chromosome 2. Thus the rat CRF gene is probably located on chromosome 2.
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PMID:The Zucker fatty (fa) gene is not a mutation of corticotropin-releasing factor. 843 Aug 72

Insulin resistance is an essential feature of a great variety of clinical disorders, like diabetes mellitus, obesity, essential hypertension, and is primarily due to a defect in hormone action at the cellular level. In the past decade application of novel research techniques including recombinant DNA technology have paved the way to understand the mechanisms of insulin action and its alterations at the molecular level. The first step in insulin action is the activation of the insulin receptor. The insulin receptor is a tetrameric protein consisting of two extracellular alpha- and two transmembrane beta-subunits. Binding of insulin to the alpha-subunit causes autophosphorylation of the intracellular beta-subunit region on tyrosine residues thereby activating the receptor. How the hormonal signal is subsequently transduced within the cell is still quiet unclear. The activated insulin receptor appears to couple to cytosolic receptor substrates which can affect different signaling cascades eliciting the pleiotropic hormone response on cell metabolism and growth. Most proteins involved in the signal transduction pathway of insulin are not known yet, but each of them might play a role in the various forms of insulin resistance. Taking the insulin receptor as an exemplary protein involved in insulin action we review molecular mechanisms regulating insulin receptor activity, gene expression, and the role of natural occurring insulin receptor gene mutations in patients with insulin resistant diabetes mellitus. It is outlined how the combination of both clinical medicine and molecular biology not only helps to understand insulin action and the pathogenesis of insulin resistance, but also leads to new avenues in the differential diagnosis, therapy, and possibly prevention of this heterogenous but most frequent metabolic and endocrine disorder.
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PMID:Molecular biology of insulin resistance. 847 20

NIDDM is a heterogeneous disease and subgroups of NIDDM include MODY (Maturity Onset Diabetes of the Young), Malnutrition-related diabetes (MRDM) and Fibrocalculus pancreatic diabetes (FCPD). Endocrine cell population is relatively unchanged in NIDDM: B-cells are reduced by up to 30% and A-cells increased by 10%. Islet amyloid is found in 96% of subjects occupying up to 80% of the islet associated with a reduction in B-cells. Amyloid formation is unlikely to cause diabetes but progressive accumulation increases the severity of the disease. Islet amyloid is formed from the islet amyloid polypeptide (IAPP), a normal constituent of B-cells, co-secreted with insulin. The causal factors for IAPP fibrillogenesis are unknown but abnormal synthesis or overproduction could be involved: stimulation of B-cell secretion in NIDDM by obesity, hyperglycaemia or suphonylurea therapy may promote amyloidosis and further aggravate islet pathology. A mutation of the glucokinase gene in MODY leads to diminished B-cell secretion but not amyloid formation. Diabetes and mutations of mitochondrial DNA is associated with poorly developed islet structure. Exocrine pancreatic size is reduced and there is evidence of sub-clinical chronic pancreatitis in NIDDM. In MRDM and FCPD, chronic pancreatitis and exocrine necrosis is associated with reduced insulin secretion. Unlike cystic fibrosis where islet amyloid is present in diabetic individuals, amyloid is absent from subjects with FCPD. Pathological changes in the exocrine and endocrine pancreas in NIDDM results from and contributes to the pathophysiology of insulin secretion in NIDDM.
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PMID:Pancreatic pathology in non-insulin dependent diabetes (NIDDM). 852 18

We identified three families having a mutation in the mitochondrial tRNA(LEU(UUR)) gene at bp 3243 in 300 patients with non-insulin dependent diabetes mellitus (NIDDM), who had first degree relatives of patients with NIDDM. We found six individuals with diabetes, one with impaired glucose tolerance (IGT), and five with normal glucose tolerance (NGT) among three families. Insulin secretory response to oral glucose load was impaired in six diabetics, but was normal in IGT and NGT, and the proportion of mutant DNA in the blood did not always associate with the severity of glucose intolerance. Furthermore, both gender and obesity may influence the clinical expression of diabetes in three pairs with an age-matched brother-sister relationship with similar high mutation rate in blood samples. Thus, although patients with mitochondrial gene mutation had a high frequency of diabetes, the proportion of mutant DNA evaluated by blood samples may not necessarily indicate glucose intolerance in the members with the mutation. Unidentified factors including gender, aging, and obesity may alter the clinical manifestation of diabetes.
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PMID:Clinical and laboratory characteristics in the families with diabetes and a mitochondrial tRNA(LEU(UUR)) gene mutation. 859 2

Studies with human adipose tissue have demonstrated the presence of key enzymes of fat synthesis. However, long-term regulation of these enzymes has not been reported. To address this issue, we used human adipocytes in primary culture. Human adipose tissue was obtained from abdominal fat of patients undergoing abdominal surgery. Adipocytes were isolated by collagenase digestion and cultured in media supplemented with 1% fetal bovine serum. To evaluate metabolic activity of cultured cells, we assessed the following during the culture: DNA pattern, cell size, glucose consumption and activities for two lipogenic enzymes, fatty acid synthase (FAS) and glycerol-3-phosphate dehydrogenase (GPDH). Analysis of DNA pattern showed that human adipocytes cultured under the above condition did not undergo cell apoptosis. In addition, no significant change in the cell size occurred during 22 d of culture. Glucose consumption by cultured cells was also constant during the culture and was 60% greater in the presence of 10 nmol/L of insulin. Treatment of cultured human adipocytes with insulin for 3-22 d increased GPDH and FAS activity by 60% and 2.8-fold, respectively, compared to cells cultured without insulin. Furthermore, the increase in FAS activity due to insulin treatment was dose dependent and maximal at 10 nmol/L. Our studies show for the first time that human adipocytes can be maintained viable and metabolically active for 2-3 wk in culture. Interestingly, cultured cells remain responsive to insulin. Therefore, this system will allow further characterization of long-term regulation of lipogenesis in human adipocytes and will be useful for developing pharmacological treatments of obesity.
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PMID:Insulin increases lipogenic enzyme activity in human adipocytes in primary culture. 861 89

The product of the obese (ob) gene, leptin, is a secreted protein that is important in the regulation of body weight. Mice with mutations in the ob gene are obese and diabetic and manifest reduced physical as well as metabolic activity. In this study, we tested the possibility that mutations in the OB gene may contribute to human obesity. We report the isolation and partial sequence of the human OB gene and the screening of 105 obese patients for mutations in the protein coding sequence using the technique of single-strand conformational polymorphism. No coding sequence polymorphism was found, suggesting that mutations in the coding sequence of the OB gene do not constitute a common cause of increased body weight in humans. We also identified a highly polymorphic simple dinucleotide repeat DNA polymorphism in this gene that will be useful for genetic studies.
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PMID:Absence of mutations in the human OB gene in obese/diabetic subjects. 862 Oct 22

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