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

Obesity is associated with noninsulin-dependent diabetes mellitus (NIDDM) and coronary heart disease (CHD), and these interactions have usually been related to changes in immunoreactive insulin (IRI) levels. A role of proinsulin (PI) in this association has been suggested. We, therefore, examined IRI, PI, and true insulin levels and the PI/IRI ratio by glucose tolerance or CHD status in a cross-sectional study of 170 Japanese-American men (45-74 yr old) in whom 2 measures of adiposity (body mass index and intraabdominal fat) were made to assess potential associations in this population with a high prevalence of both NIDDM and CHD. Subjects were classified as having normal glucose tolerance (n = 58), impaired glucose tolerance (IGT; n = 55), or NIDDM (n = 57) or were classified by CHD status (without CHD, n = 127; with CHD, n = 43). A positive linear relationship existed between obesity, determined either as the body mass index or intraabdominal fat, and IRI, PI, and true insulin, but not the PI/IRI ratio. In the NIDDM subjects, PI levels were disproportionately greater than those in subjects with normal glucose tolerance or IGT, so the PI/IRI ratio was significantly greater in the NIDDM group [mean (95% confidence interval): normal glucose tolerance, 11.8% (range, 10.4-13.5); IGT, 12.8% (range, 10.8-15.1); NIDDM, 19.2% (range, 15.4-24.0); P = 0.0002] even when adjusted for obesity (P = 0.0004). In subjects with CHD compared to subjects without CHD, IRI (P = 0.0026) and true insulin levels (P = 0.0043) were increased, but PI levels were not. However, these differences were not present after adjustment for obesity. In contrast, when intraabdominal fat was adjusted for IRI or true insulin, a significant effect of intraabdominal fat on CHD risk was maintained (P = 0.045 and P = 0.029, respectively), suggesting that another factor(s) associated with central obesity may be involved in CHD risk. Thus, in Japanese-American men, elevated PI and PI/IRI ratio are markers of B-cell dysfunction, and these are not the result of obesity. An elevated true insulin level is present in those with CHD, but this appears to be the result of obesity. In contrast, central adiposity confers an additional risk for CHD independent of insulin.
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PMID:Relationship of proinsulin and insulin with noninsulin-dependent diabetes mellitus and coronary heart disease in Japanese-American men: impact of obesity--clinical research center study. 771 16

Pancreatic insulin secretion rates can be accurately derived by mathematical deconvolution of peripheral C-peptide concentrations either by using individual C-peptide kinetic parameters obtained by analysis of the decay curve of biosynthetic human C-peptide or by using published group parameters with appropriate adjustments for age and degree of obesity. Since the cross-reactivity of proinsulin and related peptides is low (< 10%) in many C-peptide assays, this experimental approach avoids the spurious increase in insulin immunoreactivity resulting from cross-reactivity with proinsulin and related peptides in the insulin assay. Application of this technique has demonstrated that the phenotypic expression of beta-cell dysfunction differs in subjects with different genetic mechanisms of non-insulin-dependent diabetes mellitus (NIDDM). Subjects who have maturity-onset diabetes of the young (MODY) due to mutations in the glucokinase gene demonstrate different patterns of altered insulin secretion when compared with subjects who have mutations in the MODY1 gene on chromosome 20. Glucokinase mutations affect the ability of the beta-cell to detect and respond to small increases in glucose above the basal level. However, compensatory mechanisms operative in vivo, which include a priming effect of glucose on insulin secretion, limit the severity of the observed insulin secretory defect, resulting in a generally mild clinical course in these subjects. In contrast, mutations in the MODY1 gene are associated with an inability to increase insulin secretion as the plasma glucose concentration increases above 7-8 mmol/l and the normal priming effect of glucose on insulin secretion is lost. These characteristics of the dose-response relationships between glucose and insulin secretion result in a more severe degree of hyperglycemia than observed in subjects with glucokinase mutations, and these subjects more frequently need insulin treatment. These alterations are evident in prediabetic subjects with normal glucose levels who carry the MODY1 mutation, suggesting that defective beta-cell function is the primary pathogenetic defect in the diabetic syndrome in these subjects. Studies performed in the classic form of NIDDM demonstrate that subjects with mild glucose intolerance and normal fasting glucose concentrations and glycosylated hemoglobin levels consistently demonstrate defective beta-cell function. These results are consistent with studies in the Zucker diabetic fatty rat, an animal model of NIDDM in which prediabetic animals demonstrate extensive alterations in expression of multiple genes involved in the regulation of insulin secretion. It thus appears that abnormal beta-cell function is present at a relatively early stage in the evolution of NIDDM, even before the onset of overt hyperglycemia.
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PMID:Lilly Lecture 1994. The beta-cell in diabetes: from molecular genetics to clinical research. 778 37

To determine if increased secretion of amylin can be implicated in the pathogenesis of non-insulin-dependent diabetes mellitus (NIDDM) in vitro and in vivo, we studied its relationships to insulin in insulin-resistant rats with and without NIDDM. In obesity-associated and dexamethasone-induced insulin resistance without diabetes, basal and stimulated secretion of amylin and insulin by isolated pancreata were proportionately elevated, leaving the amylin-to-insulin ratio (A/I) unchanged. By contrast, whenever diabetes occurred in dexamethasone-treated rats or in spontaneously diabetic obese insulin-resistant ZDF-drt male rats, a doubling of A/I was invariably observed due to an increase in amylin without a proportional increase in insulin secretion. Correction of dexamethasone-induced hyperglycemia with the glucocorticord receptor antagonist RU-486 was accompanied by a decline in A/I. Longitudinal in vivo studies demonstrated in both spontaneous and dexamethasone-induced models of NIDDM an increase in plasma A/I at the onset of hyperglycemia. In dexamethasone-induced diabetes, the increased A/I was associated with a high proamylin mRNA relative to proinsulin mRNA. We conclude that amylin and insulin expression and secretion rise in concert in compensated insulin-resistant states, but when hyperglycemia is present the increase in amylin exceeds that of insulin. Although a role of an increased A/I in the pathogenesis of NIDDM has not been established directly, these studies indicate that such a role could be possible.
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PMID:Amylin-insulin relationships in insulin resistance with and without diabetic hyperglycemia. 810 94

Recent data suggest that proinsulin is strongly associated with cardiovascular risk factors in diabetic subjects. However, this relationship has not been examined in nondiabetic subjects. Therefore, we examined the relation of proinsulin to lipids, obesity (body mass index), and waist-to-hip ratio in 260 nondiabetic individuals from the San Antonio Heart Study, a population-based study of diabetes and cardiovascular disease. Proinsulin was measured by radioimmunoassay, and insulin was measured by a Linco radioimmunoassay that does not cross-react with proinsulin. Fasting insulin was significantly associated with body mass index (0.42), waist-to-hip ratio (r = 0.30), triglyceride (r = 0.29), high-density lipoprotein cholesterol (r = -0.20), and systolic blood pressure (r = 0.16) but not significantly related to diastolic blood pressure (r = 0.11). Fasting proinsulin was significantly associated with body mass index (r = 0.19), waist-to-hip ratio (r = 0.25), triglyceride (r = 0.41), systolic blood pressure (r = 0.19), and diastolic blood pressure (r = 0.15). Proinsulin was more strongly related to increased triglyceride than insulin despite its weaker relationship to obesity. In multivariate analyses, proinsulin continued to be significantly related to triglyceride concentrations (explaining 23.1% of the variance) and to systolic blood pressure (explaining 4.0% of the variance), even after adjusting for insulin. These observations suggest that proinsulin should be measured in addition to insulin in epidemiological studies. Proinsulin may be a marker for metabolic decompensation in prediabetic subjects.
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PMID:Relationship of proinsulin and insulin to cardiovascular risk factors in nondiabetic subjects. 834 41

IPI, 32-33 SPI, and insulin were measured by specific assays and related to plasma glucose and BMI in diet-treated type II diabetic subjects (FPG 7.3 +/- 1.8 mM) and nondiabetic control subjects, both fasting and during a 12-mM hyperglycemic clamp. In both groups, BMI correlated with fasting plasma insulin (rs = 0.76, P < 0.001 and 0.50, P < 0.01, respectively) and IPI (rs = 0.49, P = 0.03 and rs = 0.69, P < 0.001, respectively). Accounting for obesity, fasting plasma insulin was subnormal in diabetic subjects (58% of control group, 1 SD range, 49-68%), but did not correlate with FPG. In contrast, fasting plasma IPI correlated with FPG in the diabetic patients (rs = 0.47, P < 0.05). In all subjects, 64% of the variance in plasma IPI was explained by BMI and FPG. Fasting 32-33 SPI was similar in the two groups. In response to a hyperglycemic clamp, the diabetic subjects had subnormal insulin concentrations (geometric means 71 and 214 pM, P < 0.001), but normal IPI concentrations (11.6 and 14.2 pM, respectively). Reduction of 32-33 SPI concentrations in diabetic subjects was intermediate (7.3 and 13.2 pM, P < 0.05). In diabetic subjects both fasting and clamp responses were subnormal for insulin but apparently normal for IPI. The major defect in pancreatic function is an impaired insulin response to glucose, and this, rather than an increase in proinsulin secretion, gives rise to the relative increase in proinsulin.
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PMID:Normal proinsulin responses to glucose in mild type II subjects with subnormal insulin response. 842 Aug 13

Conventional immunoassays to quantify insulin concentration do not differentiate between insulin and proinsulin. Thus, previous conclusions as to the relationship between the development of hyperglycemia in patients with noninsulin-dependent diabetes mellitus (NIDDM) and pancreatic insulin secretory function may have been confounded by not being able to determine the contribution made by plasma proinsulin to the putative measurements of plasma insulin concentration in these patients. The current study was initiated to address this issue by making specific measurements of plasma insulin, proinsulin, and C-peptide concentrations in 42 individuals: 14 with normal glucose tolerance, 12 with impaired glucose tolerance (IGT), and 16 with NIDDM. The study population was further subdivided into a nonobese (body mass index, < 30 kg/m2) and an obese (body mass index, > 30 kg/m2) group. Mixed meals were given at 0800, 1200, and 1800 h, and blood was removed at 0800 h (before the meal) and at hourly intervals from then until 1600 h. Plasma glucose concentrations throughout the sampling period were slightly, but significantly (P < 0.01), greater in patients with IGT than in normal individuals. Patients with NIDDM had markedly elevated glycemic excursions, greater than either of the other two groups (P < 0.002). Both plasma immunoreactive insulin and C-peptide concentrations from 0800-1600 h were higher (P < 0.002-0.001) in patients with either IGT or NIDDM than in the group with normal glucose tolerance. Although day-long plasma immunoreactive insulin and C-peptide concentrations were higher, on the average, in patients with IGT compared to those with NIDDM, the difference was not statistically significant. Plasma proinsulin concentrations were highest in patients with NIDDM (P < 0.002), lower in those with normal glucose tolerance (P < 0.002), and intermediate in patients with IGT. When the calculated "true" insulin concentration was determined by taking the proinsulin content into consideration, patients with IGT had the highest day-long levels, with the lowest values found in the control population (P < 0.002). Although absolute values varied as a function of obesity, the generalizations outlined above were found in both weight groups. These results show that ambient plasma proinsulin concentrations increase as glucose tolerance declines. However, true plasma insulin concentrations in response to mixed meals remain highest in patients with IGT, lowest in normal individuals, and intermediate in patients with NIDDM. Thus, previous conclusions that absolute day-long plasma insulin concentrations are not lower than normal in patients with NIDDM do not appear to result from an inability to differentiate true insulin from proinsulin.
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PMID:Plasma insulin, C-peptide, and proinsulin concentrations in obese and nonobese individuals with varying degrees of glucose tolerance. 842 Nov 1

A familial complex chromosomal rearrangement (CCR) was ascertained through a mentally retarded, dysmorphic individual. Carriers of the CCR have the karyotype 46,XX or XY, t(6;15)(q16;q21), ins(3;6)(q12;q14q16), and malsegregation of the CCR resulted in loss of the segment 6q14 to 6q16 in the proband, and in an additional copy of the same segment in three members of the extended family. The proband has features similar to other reported cases with deletion of 6q1. The individuals with duplication of 6q14 to 6q16 have moderate mental retardation, short stature, obesity, microcephaly, brachycephaly, a short smooth philtrum, central hair whorl, simian creases, 5th finger brachydactyly and skeletal disproportion. In the 4-generation family, CCR carriers have a 20% empiric risk of phenotypically abnormal livebirths.
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PMID:Familial complex chromosomal rearrangement resulting in duplication/deletion of 6q14 to 6q16. 850 Feb 57

GENETIC PREDISPOSITION: Insulin resistance and reactive hyperinsulinemia occur not only with obesity, impaired glucose tolerance or non-insulin-dependent (type 2) diabetes mellitus, but also in many non-obese, non-diabetic patients with essential hypertension and their currently normotensive, lean, young offspring, as well as in some other conditions known to promote hypertension. Insulin resistance impairs glucose tolerance, while insulin resistance and/or hyperinsulinemia promote dyslipidemia, body fat deposition and probably atherogenesis. Therefore, the common coexistence of a genetic predisposition for hypertension with insulin resistance helps to explain the frequent, although temporally often dissociated, occurrence of hypertension together with dyslipidemia, obesity and type 2 diabetes in a given patient. INSULIN RESISTANCE AND HYPERINSULINEMIA AS SLOW PRESSOR MECHANISMS: In the pathogenesis of hypertension, inappropriate vasoconstriction (due to an imbalance of vasoactive substances and/or raised cytosolic calcium) and/or structural vasculopathy is particularly important. Among the mosaic of assumed pressor mechanisms, distinct Na+ retention is almost invariably involved in diabetes mellitus, while sympathetic activation tends to occur in essential hypertension, particularly in association with obesity. Insulin resistance may develop as a consequence of an intracellular excess of Ca2+ or a decrease in Mg2+, an impaired insulin-mediated rise in skeletal muscle blood flow, increased sympathetic activity or excess body weight. Acute hyperinsulinemia causes arterial vasodilation on one hand and increases sympathetic activity and renal Na+ reabsorption on the other. Chronically, hyperinsulinemia may promote cardiovascular muscle cell proliferation and atherogenesis, while insulin resistance may be associated with certain transmembraneous cation transporters, leading to an increase in cytosolic Ca2+. Hyperinsulinemia and/or insulin resistance may also be associated with an increased blood pressure sensitivity to high salt intake. In the mosaic of many different blood pressure-raising mechanisms, insulin resistance and/or hyperinsulinemia is likely to represent an amplifying slow or very slow pressor factor.
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PMID:Insulin resistance and hyperinsulinemia in hypertension. 857 90

Recently, the presence of small dense low density lipoprotein (LDL) has been postulated to be a stronger risk factor for coronary heart disease than large LDL. While small dense LDL has been associated with individual components of the insulin resistance syndrome such as hypertension, high triglyceride level, low high density (HDL) cholesterol, and diabetes mellitus, there has been little work exploring whether LDL size is decreased in subjects with multiple metabolic disorders. We examined the association of LDL size and pattern to specific insulin (which does not cross-react with proinsulin), proinsulin, increased triglyceride, decreased HDL, hypertension and impaired glucose tolerance in 488 non-diabetic subjects from the San Antonio Heart Study. LDL size was significantly related to specific insulin, proinsulin and the fasting proinsulin/insulin ratio. Small dense LDL was significantly associated with high triglyceride level, decreased HDL cholesterol, hypertension and impaired glucose tolerance. LDL size (A) decreased in a stepwise fashion with increasing number of the metabolic disorders described above (zero 262.6 +/- 9.4; one 257.0 +/- 9.3; two 256.4 +/- 9.4; three 249.0 +/- 9.1; and four 244.9 +/- 9.0). These results were similar in men and women and in non-Hispanic whites and Mexican Americans. The association between LDL size and the number of metabolic disorders remained statistically significant even after adjustment for obesity, body fat distribution, gender, ethnicity, proinsulin and insulin concentrations. Furthermore, decreases in LDL size are also significantly associated with both a selective beta-cell defect (as estimated by the fasting proinsulin/insulin ratio) and insulin resistance (as estimated by the fasting insulin concentrations) although the association was somewhat stronger for the latter. We conclude that small dense LDL may form part of the insulin resistance syndrome in non-diabetic subjects.
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PMID:A preponderance of small dense LDL is associated with specific insulin, proinsulin and the components of the insulin resistance syndrome in non-diabetic subjects. 858 43

Controversy persists about whether hyperinsulinemia and hyperproinsulinemia are independent risk markers for coronary atherosclerosis. A common limitation of most previous studies has been imprecise categorization of disease status in normal and coronary artery disease (CAD) groups. We assessed the relationship of pancreatic beta-cell secretory products and premature CAD in a case-control study of 134 nondiabetic subjects, aged < or = 55 years old, carefully defined for CAD status by catheterization and/or thallium stress studies. Case patients comprised 66 patients with premature CAD, and control subjects (non-CAD group) included 68 patients without CAD but with traditional CAD risk factors and chest pain and/or abnormal electrocardiograms but normal catheterization and/or thallium stress studies. In addition to the CAD and non-CAD group comparison, both groups were compared with a reference group of 27 mixed lean and obese control volunteers. All CAD and non-CAD patients had a 3-h 75-g oral glucose tolerance test with measurement of fasting and post-glucose load immunoreactive insulin (IRI), specific insulin (INS), proinsulin-like material (PI), and C-peptide. Increased fasting insulin and fasting proinsulin levels both were statistically significantly associated with higher odds of being in either the premature CAD and the non-CAD groups when compared with the reference group in a polychotomous logistic regression model (odds ratio of at least 1.20 for a 20% increase in each beta-cell secretory product in both comparisons, P < 0.05). However, increased pancreatic beta-cell secretory hormone levels did not show a statistically significant relative risk for being in the premature CAD group when compared with the non-CAD group. After adjustment for BMI, all statistically significant associations disappeared for IRI, INS, and PI when the odds favoring being in the CAD and non-CAD groups were compared versus the reference group. Furthermore, the odds of being in the premature CAD and non-CAD groups when compared with the reference group were not significantly associated to the ratio of PI to insulin and C-peptide. Thus, although there is a statistically significant association between the odds of having premature CAD with elevated insulin and proinsulin levels compared with the reference group, these findings are equally common in subjects with traditional CAD risk factors without detectable CAD. Furthermore, the association of higher insulin and proinsulin levels with the likelihood of a patient having or not having CAD disappears after adjustment for BMI, suggesting that insulin and proinsulin are not independent risk markers but are primarily dependent on obesity.
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PMID:Are insulin and proinsulin independent risk markers for premature coronary artery disease ? 863 46


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