Growth Hormone Regulation of p85α Expression and Phosphoinositide 3-Kinase Activity in Adipose Tissue

Rincon, Juan-Pablo del; Iida, Keiji; Gaylinn, Bruce D.; McCurdy, Carrie E.; Leitner, J. Wayne; Barbour, Linda A.; Kopchick, John J.; Friedman, Jacob E.; Draznin, Boris; Thorner, Michael O.

doi:10.2337/db06-0299

Cited by 143 publications

(111 citation statements)

References 48 publications

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“…The increased FFAs may affect insulin sensitivity by competition with glucose for substrate oxidation, impairment of insulin signaling, altering b-cell function, or triggering monocyte-macrophage accumulation in adipose tissue (2,4,5). Further, GH directly alters the insulin signal cascade activity in mice, but studies on humans have not supported these observations (6,7,8). Data regarding the effects of GH on circulating adipokines in human subjects are sparse and the results often contrast those obtained from animal models (9).…”

Section: Introductionmentioning

confidence: 73%

Inflammatory adipokines contribute to insulin resistance in active acromegaly and respond differently to different treatment modalities

Olarescu

Ueland

Godang

et al. 2014

European Journal of Endocrinology

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Background: Active acromegaly is associated with insulin resistance, but it is uncertain whether inflammation in adipose tissue is a contributing factor. Aim: To test if GH/IGF1 promotes inflammation in adipocytes, and if this is relevant for systemic insulin resistance in acromegaly. Furthermore, to investigate the effect of treatment modalities (transsphenoidal surgery (TS), somatostatin analogs (SAs), and pegvisomant (PGV)) on glucose metabolism and inflammatory biomarkers in acromegaly. Methods: The in vitro effects of GH/IGF1 on gene expression of adipokines in human adipocytes were investigated. Body composition, glucose metabolism, and circulating adipokines (adiponectin (AD), high-molecular weight AD (HMWAD), leptin, vascular endothelial growth factor-A (VEGF-A), monocyte chemotactic protein 1 (MCP1), and thioredoxin (TRX)) were measured in 37 patients with active acromegaly before and after treatment. Results: In vitro GH, but not IGF1, increased VEGF and MCP1 in human adipocytes. In all treatment groups, body fat increased and IGF1 decreased to the same extent. Fasting glucose decreased in the TS (PZ0.016) and PGV (PZ0.042) groups, but tended to increase in the SA group (PZ0.078). Insulin and HOMA-IR decreased in both TS and SA groups, while the PGV group showed no changes. Serum VEGF and MCP1 decreased significantly in the TS group only (PZ0.010, PZ0.002), while HMWAD increased with PGV treatment only (PZ0.018). A multivariate analysis model identified the changes in GH and VEGF as predictors of improvement in HOMA-IR after treatment (R

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Section: Introductionmentioning

confidence: 73%

Inflammatory adipokines contribute to insulin resistance in active acromegaly and respond differently to different treatment modalities

Olarescu

Ueland

Godang

et al. 2014

European Journal of Endocrinology

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“…The specific mechanisms responsible for insulin resistance caused by growth hormone remain unknown. While some recent findings suggest that phosphoinositide 3-kinase plays a pivotal role [29,30], others argue against this [27,28]. Obesity can also lead to an insulin-resistant state; thus, one might expect that growth hormone treatment of obese mice would exacerbate insulin resistance.…”

Section: Discussionmentioning

confidence: 99%

Growth hormone improves body composition, fasting blood glucose, glucose tolerance and liver triacylglycerol in a mouse model of diet-induced obesity and type 2 diabetes

et al. 2009

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Aims/hypothesis Growth hormone has been used experimentally in two studies to treat individuals with type 2 diabetes, with both reporting beneficial effects on glucose metabolism. However, concerns over potential diabetogenic actions of growth hormone complicate its anticipated use to treat type 2 diabetes. Thus, an animal model of type 2 diabetes could help evaluate the effects of growth hormone for treating this condition. Methods Male C57BL/6J mice were placed on a high-fat diet to induce obesity and type 2 diabetes. Starting at 16 weeks of age, mice were treated once daily for 6 weeks with one of four different doses of growth hormone. Body weight, body composition, fasting blood glucose, insulin, glucose tolerance, liver triacylglycerol, tissue weights and blood chemistries were determined. Results Body composition measurements revealed a dosedependent decrease in fat and an increase in lean mass. Analysis of fat loss by depot revealed that subcutaneous and mesenteric fat was the most sensitive to growth hormone treatment. In addition, growth hormone treatment resulted in improvement in glucose metabolism, with the highest dose normalising glucose, glucose tolerance and liver triacylglycerol. In contrast, insulin levels were not altered by the treatment, nor did organ weights change. However, fasting plasma leptin and resistin were significantly decreased after growth hormone treatment. Conclusions/interpretation Growth hormone therapy improves glucose metabolism in this mouse model of obesity and type 2 diabetes, providing a means to explore the molecular mechanism(s) of this treatment.

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“…Hyperglycemia was observed in some patients enrolled in studies with an anti-IGF1R antibody (Haluska et al 2006, Lacy et al 2008. This is likely to be a consequence of a compensatory increase in the circulating concentration of GH after IGF1 blockade, with the consequent increase in GH-induced insulin resistance (del Rincon et al 2007). Hyperglycemia, hypertriglyceridemia, and hypercholesterolemia were also observed in about 20% of patients treated with the mTOR inhibitors (Bellmunt et al 2008).…”

Section: Drugs Used To Treat Pc May Cause Diabetesmentioning

confidence: 99%

Diabetes and pancreatic cancer

Cui¹,

Andersen²

2012

Endocrine-Related Cancer

123

100

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Epidemiological studies clearly indicate that the risk of pancreatic cancer (PC) is increased in diabetic patients, but most studies focus on overall diabetes or type 2 diabetes mellitus (T2DM), and there are few studies on the risks of type 1 and type 3c (secondary) diabetes. Possible mechanisms for increased cancer risk in diabetes include cellular proliferative effects of hyperglycemia, hyperinsulinemia, and abnormalities in insulin/IGF receptor pathways. Recently, insulin and insulin secretagogues have been observed to increase the PC risk, while metformin treatment reduces the cancer risk in diabetic subjects. In addition, anticancer drugs used to treat PC may either cause diabetes or worsen coexisting diabetes. T3cDM has emerged as a major subset of diabetes and may have the highest risk of pancreatic carcinoma especially in patients with chronic pancreatitis. T3cDM is also a consequence of PC in at least 30% of patients. Distinguishing T3cDM from the more prevalent T2DM among new-onset diabetic patients can be aided by an assessment of clinical features and confirmed by finding a deficiency in postprandial pancreatic polypeptide release. In conclusion, diabetes and PC have a complex relationship that requires more clinical attention. The risk of developing PC can be reduced by aggressive prevention and treatment of T2DM and obesity and the prompt diagnosis of T3cDM may allow detection of a tumor at a potentially curable stage.

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Growth Hormone Regulation of p85α Expression and Phosphoinositide 3-Kinase Activity in Adipose Tissue

Cited by 143 publications

References 48 publications

Inflammatory adipokines contribute to insulin resistance in active acromegaly and respond differently to different treatment modalities

Inflammatory adipokines contribute to insulin resistance in active acromegaly and respond differently to different treatment modalities

Growth hormone improves body composition, fasting blood glucose, glucose tolerance and liver triacylglycerol in a mouse model of diet-induced obesity and type 2 diabetes

Diabetes and pancreatic cancer

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