Mechanisms of ageing: growth hormone, dietary restriction, and metformin.

Tackling the mechanisms underlying ageing is desirable to help to extend the duration and improve the quality of life. Life extension has been achieved in animal models by suppressing the growth hormone-insulin-like growth factor 1 (IGF-1) axis and also via dietary restriction. Metformin has become the focus of increased interest as a possible anti-ageing drug. There is some overlap in the postulated mechanisms of how these three approaches could produce anti-ageing effects, with convergence on common downstream pathways. In this Review, we draw on evidence from both animal models and human studies to assess the effects of suppression of the growth hormone-IGF-1 axis, dietary restriction, and metformin on ageing.

Metformin to reduce metabolic complications and inflammation in patients on systemic glucocorticoid therapy: a randomised, double-blind, placebo-controlled, proof-of-concept, phase 2 trial.

BACKGROUND: An urgent need to reduce the metabolic side-effects of glucocorticoid overexposure has been recognised, as glucocorticoid excess can lead to Cushing's syndrome, which is associated with high morbidity. We aimed to evaluate the potential of metformin to reverse such effects while sparing the anti-inflammatory benefits of glucocorticoids. METHODS: We did a randomised, double-blind, placebo-controlled, proof-of-concept, phase 2 trial involving four hospitals in the UK. Patients without diabetes were eligible if they were between the ages of 18 and 75 years with an inflammatory disease treated with continuous prednisolone (≥20 mg/day for ≥4 weeks and remaining on ≥10 mg/day for the subsequent 12 weeks, or its cumulative dose-equivalent). Eligible patients were randomly allocated (1:1) to either the metformin or placebo groups, using a computer-generated randomisation table stratified according to age and BMI. Metformin and placebo were administered orally for 12 weeks in escalating doses: 850 mg/day for the first 5 days, 850 mg twice a day for the next 5 days, and 850 mg three times a day subsequently. The primary outcome was the between-group difference in visceral-to-subcutaneous fat area ratio over 12 weeks, assessed by CT. Secondary outcomes included changes in metabolic, bone, cardiovascular, and inflammatory parameters over 12 weeks. Our analysis followed a modified intention-to-treat principle for the primary outcome. This study is registered with ClinicalTrials.gov, NCT01319994. FINDINGS: Between July 17, 2012, and Jan 14, 2014, 849 patients were assessed for study eligibility, of which 53 were randomly assigned to receive either metformin (n=26) or placebo (n=27) for 12 weeks. 19 patients in the metformin group and 21 in the placebo group were eligible for the primary outcome analysis. Both groups received an equivalent cumulative dose of glucocorticoids (1860 mg prednisolone-equivalent [IQR 1060-2810] in the metformin group vs 1770 mg [1020-2356] in the placebo group); p=0·76). No change in the visceral-to-subcutaneous fat area ratio between the treatment groups was observed (0·11, 95% CI -0·02 to 0·24; p=0·09), but patients in the metformin group lost truncal subcutaneous fat compared with the placebo group (-3835 mm2, 95% CI -6781 to -888; p=0·01). Improvements in markers of carbohydrate, lipid, liver, and bone metabolism were observed in the metformin group compared with the placebo group. Additionally, those in the metformin group had improved fibrinolysis, carotid intima-media thickness, inflammatory parameters, and clinical markers of disease activity. The frequency of pneumonia (one event in the metformin group vs seven in the placebo group; p=0·01), overall rate of moderate-to-severe infections (two vs 11; p=0·001), and all-cause hospital admissions due to adverse events (one vs nine; p=0·001) were lower in the metformin group than in the placebo group. Patients in the metformin group had more events of diarrhoea than the placebo group (18 events vs eight; p=0·01). INTERPRETATION: No significant changes in the visceral-to-subcutaneous fat area ratio between the treatment groups were observed; however, metformin administration did improve some of the metabolic profile and clinical outcomes for glucocorticoid-treated patients with inflammatory disease, which warrants further investigation. FUNDING: Barts Charity and Merck Serono.

Metformin prevents metabolic side effects during systemic glucocorticoid treatment.

OBJECTIVES: Patients receiving glucocorticoid treatment are prone to develop metabolic complications. In preclinical studies, metformin prevented the development of the metabolic syndrome during glucocorticoid excess. We herein investigated the metabolic effect of metformin during glucocorticoid treatment in non-diabetic patients. METHODS: In a double-blind, placebo-controlled trial, patients starting glucocorticoid treatment (prednisone, prednisolone or methylprednisolone) for four weeks were randomised to concomitantly receive metformin (850 mg once daily for one week followed by 850 mg twice daily for three weeks) or placebo. All patients underwent a standardised oral glucose tolerance test at baseline and after four weeks. The primary endpoint was change in the 2-h area under the curve (AUC) of glucose during the oral glucose tolerance test between baseline and four weeks. RESULTS: 29 of 34 randomised non-diabetic patients completed the trial (17 metformin and 12 placebo). In patients allocated to placebo, median glucose 2-h AUC increased from baseline to four weeks (836 (IQR 770-966) to 1202 (1009-1271) mmol/L per min; P = 0.01). In contrast, glucose levels remained similar to baseline in the metformin group (936 (869-1003) to 912 (825-1011) mmol/L per min; P = 0.83). This change within four weeks was different between both groups (P = 0.005). Glucocorticoid equivalent doses were similar in both groups (placebo: 980.0 (560.0-3259.8) mg/28 days; metformin: 683.0 (437.5-1970.5) mg/28 days; P = 0.26). CONCLUSIONS: In this first randomised controlled trial of metformin targeting metabolic complications in patients needing glucocorticoid therapy, we observed a beneficial effect of metformin on glycaemic control. Metformin thus seems to be a promising drug for preventing metabolic side effects during systemic glucocorticoid treatment.

Increased Population Risk of AIP-Related Acromegaly and Gigantism in Ireland.

The aryl hydrocarbon receptor interacting protein (AIP) founder mutation R304* (or p.R304* ; NM_003977.3:c.910C>T, p.Arg304Ter) identified in Northern Ireland (NI) predisposes to acromegaly/gigantism; its population health impact remains unexplored. We measured R304* carrier frequency in 936 Mid Ulster, 1,000 Greater Belfast (both in NI) and 2,094 Republic of Ireland (ROI) volunteers and in 116 NI or ROI acromegaly/gigantism patients. Carrier frequencies were 0.0064 in Mid Ulster (95%CI = 0.0027-0.013; P = 0.0005 vs. ROI), 0.001 in Greater Belfast (0.00011-0.0047) and zero in ROI (0-0.0014). R304* prevalence was elevated in acromegaly/gigantism patients in NI (11/87, 12.6%, P < 0.05), but not in ROI (2/29, 6.8%) versus non-Irish patients (0-2.41%). Haploblock conservation supported a common ancestor for all the 18 identified Irish pedigrees (81 carriers, 30 affected). Time to most recent common ancestor (tMRCA) was 2550 (1,275-5,000) years. tMRCA-based simulations predicted 432 (90-5,175) current carriers, including 86 affected (18-1,035) for 20% penetrance. In conclusion, R304* is frequent in Mid Ulster, resulting in numerous acromegaly/gigantism cases. tMRCA is consistent with historical/folklore accounts of Irish giants. Forward simulations predict many undetected carriers; geographically targeted population screening improves asymptomatic carrier identification, complementing clinical testing of patients/relatives. We generated disease awareness locally, necessary for early diagnosis and improved outcomes of AIP-related disease.

Metformin--mode of action and clinical implications for diabetes and cancer.

Metformin has been the mainstay of therapy for diabetes mellitus for many years; however, the mechanistic aspects of metformin action remained ill-defined. Recent advances revealed that this drug, in addition to its glucose-lowering action, might be promising for specifically targeting metabolic differences between normal and abnormal metabolic signalling. The knowledge gained from dissecting the principal mechanisms by which metformin works can help us to develop novel treatments. The centre of metformin's mechanism of action is the alteration of the energy metabolism of the cell. Metformin exerts its prevailing, glucose-lowering effect by inhibiting hepatic gluconeogenesis and opposing the action of glucagon. The inhibition of mitochondrial complex I results in defective cAMP and protein kinase A signalling in response to glucagon. Stimulation of 5'-AMP-activated protein kinase, although dispensable for the glucose-lowering effect of metformin, confers insulin sensitivity, mainly by modulating lipid metabolism. Metformin might influence tumourigenesis, both indirectly, through the systemic reduction of insulin levels, and directly, via the induction of energetic stress; however, these effects require further investigation. Here, we discuss the updated understanding of the antigluconeogenic action of metformin in the liver and the implications of the discoveries of metformin targets for the treatment of diabetes mellitus and cancer.

Sympathetic activation and vasoregulation in response to carbohydrate ingestion in patients with congestive heart failure.

BACKGROUND: In normal individuals, carbohydrate ingestion increases sympathetic vasoconstrictor activity but causes net vasodilatation in the same vascular bed. This study quantified the effects of carbohydrate ingestion on muscle sympathetic nerve activity (MSNA) and vasoregulation in patients with congestive heart failure (CHF). We hypothesized that high resting levels of MSNA in patients with CHF would blunt further increases in MSNA following carbohydrate ingestion and that their sympathetic activation would restrain vasodilatation. METHODS: Eleven patients with treated severe CHF and 11 age- and body mass index-matched normal controls (NCs) were studied for 2 hours after a high-carbohydrate meal. MSNA was measured by peroneal microneurography and calf blood flow by venous occlusion plethysmography. RESULTS: Patients with CHF had higher (P < 0.03) baseline MSNA (67 ± 4.0 bursts/100 beats) than NCs (51 ± 5.8 bursts/100 beats) and lower (P < 0.001) baroreflex sensitivity (2.1 ± 0.58 ms/mm Hg) than NCs (7.4 ± 1.2 ms/mm Hg). Carbohydrate ingestion was associated with a significant increase in MSNA (P < 0.05) and calf blood flow (P < 0.01) with unchanged blood pressure in CHF patients. The magnitude of responses in CHF patients was not significantly different from that in NCs, but vasodilatation was delayed significantly (by 30 minutes). CONCLUSIONS: Despite considerable resting sympathoexcitation and reduced baroreflex sensitivity, patients with CHF exhibited further increases in MSNA after carbohydrate ingestion, achieving levels similar to those after myocardial infarction. They also had temporally delayed vasodilatation, which could contribute to cachexia and muscle weakness in CHF patients. These observations suggest that high-carbohydrate meals may adversely affect CHF patients via altered autonomic tone and blood-flow patterns.

An endocrinologist's guide to the clock.

CONTEXT: It has long been recognized that a "biological clock" residing in the suprachiasmatic nucleus controls circadian or daily variations in physiological processes. Old observations are now being revisited after the discovery of the cellular mechanism of timekeeping, the molecular clock, an autoregulatory feedback loop of transcription factors that cycles over a period of approximately 24 h. Its functioning or breakdown impinges upon the physiology and pathophysiology of numerous systems, including the endocrine system and metabolism. Here we provide an introduction to those aspects of the clock most relevant to the endocrinologist. EVIDENCE ACQUISITION: Articles were identified by searching PubMed using the search terms "circadian" and "clock" and refining results to include articles relating to endocrinology and metabolism. EVIDENCE SYNTHESIS: We discuss current understanding of the mechanisms through which hormonal and metabolic axes fall under the influence of the circadian clock. Of particular interest is the complex interaction of genetic and environmental factors in determining health or disease states. CONCLUSIONS: Research into the molecular clock provides a novel window onto endocrine and metabolic disease. These advances present new avenues for diagnostic and therapeutic strategies.

Takotsubo cardiomyopathy: a review of the literature.

Although takotsubo cardiomyopathy is a rare entity, it is an important differential in patients presenting with symptoms, signs, and electrocardiographic changes suggestive of an acute myocardial infarction. Since it was first recognized in 1991, it has gained increasing attention worldwide; however, its etiology and consequently the optimal management still remains unclear. Here, the authors provide a review of the current literature accompanied with images of a typical case from our department.