Controversies surrounding the treatment of the hypertensive patient with diabetes.

Diabetes mellitus without previous myocardial infarction carries the same risk of a future myocardial infarction as someone who has had one. Intense glucose, lipid, and blood pressure control in diabetic patients is advocated to reduce cardiovascular events and decrease the incidence of end-stage renal disease, retinal damage, and peripheral vascular disease. Recent studies, including the Systolic Hypertension in the Elderly Program, indicate that low-dose diuretics, compared with placebo, reduce fatal and nonfatal myocardial infarctions but not fatal and nonfatal strokes in diabetic patients. Similarly, captopril (and diuretics) compared with diuretics and beta-blockers decreased fatal and nonfatal myocardial infarctions but not fatal and nonfatal strokes in the Captopril Prevention Project. Intense blood pressure therapy with captopril and intense blood pressure therapy with atenolol equally lowered macrovascular and microvascular events compared with less intense blood pressure treatment in the United Kingdom Prospective Diabetes Study. Fewer myocardial infarctions were seen with enalapril than with nisoldipine in the Appropriate Blood Pressure Control in Diabetes trial. Intense blood pressure control with felodipine, enalapril, and hydrochlorothiazide reduced overall cardiovascular events and mortality but not myocardial infarction and strokes in the Hypertension Optimal Treatment trial. Nitrendipine alone or together with enalapril and hydrochlorothiazide decreased fatal and nonfatal strokes and cardiovascular mortality but not myocardial infarctions in the Systolic Hypertension in Europe trial. These trials, in aggregate, reinforce the importance of intense blood pressure control, which can be achieved only with combination drug therapy rather than a specific monotherapy drug class recommendation.

Hyperinsulinemia inhibits myocardial protein degradation in patients with cardiovascular disease and insulin resistance.

BACKGROUND: Insulin resistance, hyperinsulinemia, and myocardial hypertrophy frequently coexist in patients. Whether hyperinsulinemia directly affects myocardial protein metabolism in humans has not been examined, however. To test the hypothesis that hyperinsulinemia is anabolic for human heart protein, we examined the effects of insulin infusion on myocardial protein synthesis, degradation, and net balance in patients with ischemic heart disease. METHODS AND RESULTS: Eleven men (aged 57 +/- 3 years) with coronary artery disease who had fasted for 12 to 16 hours received a constant infusion of insulin (50 mU.m-2.min-1) while plasma concentrations of glucose and amino acids were kept constant. Rates of myocardial protein synthesis, degradation, and net balance were estimated from steady state extraction and isotopic dilution of L-[ring-2,6-3H]phenylalanine across the heart basally and 90 minutes into infusion. Subjects had elevated fasting plasma insulin concentrations (173 +/- 21 pmol/L) and used little exogenous glucose during insulin infusion, suggesting resistance to the effects of insulin on whole-body carbohydrate metabolism. Basally, myocardial protein degradation, as estimated by phenylalanine release (133 +/- 28 nmol/min), exceeded protein synthesis, estimated by phenylalanine uptake (31 +/- 15 nmol/min), resulting in net negative phenylalanine balance (-102 +/- 17 nmol/min). Insulin infusion reduced myocardial protein degradation by 80% but did not affect protein synthesis, returning net phenylalanine balance to neutral. CONCLUSIONS: Acute hyperinsulinemia markedly suppresses myocardial protein degradation in patients with cardiovascular disease who are resistant to its effects on whole-body glucose metabolism. This antiproteolytic action represents a potential mechanism by which hyperinsulinemia could contribute to the development of myocardial hypertrophy in patients with cardiovascular disease.

Overnight branched-chain amino acid infusion causes sustained suppression of muscle proteolysis.

Short-term (3 to 4 hours) infusion of branched-chain amino acids (BCAA) has been shown to suppress muscle protein breakdown. Whether these effects are sustained with chronic elevations of BCAA is not known. In the present study, we examined the effect of an overnight (16-hour) systemic BCAA infusion on whole-body and skeletal muscle amino acid metabolism, as assessed by simultaneously measured 3H-phenylalanine and 14C-leucine kinetics in eight normal volunteers; 10 overnight-fasted subjects studied during a 4-hour saline infusion served as controls. Overnight BCAA infusion increased plasma BCAA concentrations by fivefold to eightfold, and this was associated with a 20% to 60% decline in arterial concentrations of other amino acids. For Phe, this decline was mediated by a reduction in the systemic rate of appearance ([Ra] 0.38 +/- 0.03 v 0.60 +/- 0.01 mumol/kg/min for BCAA and saline, respectively, P < .001). Endogenous Leu Ra, calculated more indirectly as the difference between the total Leu Ra and the unlabeled Leu infusion rate, did not differ between groups. In the forearm, overnight BCAA infusion resulted in a diminished net release of Phe (-3 +/- 2 v -18 +/- 4 [saline] nmol/min/100 mL, P < .02), and BCAA balance became markedly positive (751 +/- 93 v -75 +/- 30, P < .001). The diminished net forearm Phe release was accounted for by a decrease in local Phe Ra (P < .02). As with the systemic endogenous Leu Ra, forearm Leu Ra was not reproducibly affected by infused BCAA.(ABSTRACT TRUNCATED AT 250 WORDS)

Glucocorticoids antagonize insulin's antiproteolytic action on skeletal muscle in humans.

Although chronic glucocorticoid elevations cause net skeletal muscle protein loss in man, the kinetic mechanisms responsible for this catabolic effect and the capacity of insulin to overcome it remain unclear. To examine this issue, we measured basal and insulin-stimulated rates of protein synthesis and breakdown in muscle using the phenylalanine forearm kinetic method in eight normal volunteers studied postabsorptively and after 4 days of dexamethasone treatment (8 mg/day). To avoid the confounding effects of systemic insulinization, local forearm insulin levels were raised by approximately 430 pmol/L using a 150-min brachial arterial infusion of insulin (0.251 pmol/kg.min). Postabsorptively, dexamethasone produced mild hyperglycemia (P < 0.003) and a 3-fold rise in plasma insulin (P < 0.001), but no change in forearm phenylalanine balance or kinetics. Before dexamethasone treatment, local hyperinsulinemia increased forearm glucose uptake 2.5-fold and caused a positive net balance of phenylalanine due to a marked 40% inhibition of proteolysis. After dexamethasone treatment, forearm glucose uptake was modestly reduced. However, forearm net phenylalanine balance remained negative due to a striking reduction in insulin's inhibitory effect on proteolysis. We conclude that 1) the effects of glucocorticoid on basal muscle protein turnover are minimized by compensatory hyperinsulinemia, and 2) glucocorticoids cause muscle resistance to insulin's antiproteolytic action.

Insulin sensitivity of protein and glucose metabolism in human forearm skeletal muscle.

Physiologic increases of insulin promote net amino acid uptake and protein anabolism in forearm skeletal muscle by restraining protein degradation. The sensitivity of this process to insulin is not known. Using the forearm perfusion method, we infused insulin locally in the brachial artery at rates of 0.00 (saline control), 0.01, 0.02, 0.035, or 0.05 mU/min per kg for 150 min to increase local forearm plasma insulin concentration by 0, approximately 20, approximately 35, approximately 60, and approximately 120 microU/ml (n = 35). L-[ring-2,6-3H]phenylalanine and L-[1-14C]leucine were infused systemically, and the net forearm balance, rate of appearance (Ra) and rate of disposal (R(d)) of phenylalanine and leucine, and forearm glucose balance were measured basally and in response to insulin infusion. Compared to saline, increasing rates of insulin infusion progressively increased net forearm glucose uptake from 0.9 mumol/min per 100 ml (saline) to 1.0, 1.8, 2.4, and 4.7 mumol/min per 100 ml forearm, respectively. Net forearm balance for phenylalanine and leucine was significantly less negative than basal (P < 0.01 for each) in response to the lowest dose insulin infusion, 0.01 mU/min per kg, and all higher rates of insulin infusion. Phenylalanine and leucine R(a) declined by approximately 38 and 40% with the lowest dose insulin infusion. Higher doses of insulin produced no greater effect (decline in R(a) varied between 26 and 42% for phenylalanine and 30-50% for leucine). In contrast, R(d) for phenylalanine and leucine did not change with insulin. We conclude that even modest increases of plasma insulin can markedly suppress proteolysis, measured by phenylalanine R(a), in human forearm skeletal muscle. Further increments of insulin within the physiologic range augment glucose uptake but have little additional effect on phenylalanine R(a) or balance. These results suggest that proteolysis in human skeletal muscle is more sensitive than glucose uptake to physiologic increments in insulin.

Growth hormone stimulates skeletal muscle protein synthesis and antagonizes insulin's antiproteolytic action in humans.

We examined the effects of a combined, local intra-arterial infusion of growth hormone (GH) and insulin on forearm glucose and protein metabolism in seven normal adults. GH was infused into the brachial artery for 6 h with a dose that, in a previous study, stimulated muscle protein synthesis (phenylalanine Rd) without affecting systemic GH, insulin, or insulinlike growth factor I concentrations. For the last 3 h of the GH infusion, insulin was coinfused with a dose that, in the absence of infused GH, suppressed forearm muscle proteolysis by 30-40% without affecting systemic insulin levels. Measurements of forearm glucose, amino acid balance, and [3H]phenylalanine and [14C]leucine kinetics were made at 3 and 6 h of the infusion. Glucose uptake by forearm tissues in response to GH and insulin did not change significantly between 3 and 6 h. By 6 h, the combined infusion of GH and insulin promoted a significantly more positive net balance of phenylalanine, leucine, isoleucine, and valine (all P less than 0.05). The change in net phenylalanine balance was due to a significant increase in phenylalanine Rd (51%, P less than 0.05) with no observable change in phenylalanine Ra. For leucine, a stimulation of leucine Rd (50%, P less than 0.05) also accounted for the change in leucine net balance, with no suppression of leucine Ra. The stimulation of Rd, in the absence of an observed effect on Ra, suggests that GH blunts the action of insulin to suppress proteolysis in addition to blunting insulin's action on Rd.

Recurrent Cushing's disease with low adrenal androgen production.

A 33 year old woman presented with recurrent Cushing's disease 4 years after complete remission induced by pituitary surgery. On relapse she exhibited the unusual pattern of elevated indices of cortisol secretion with markedly suppressed serum DHEA-S; urinary 17-ketosteroid excretion was also below the normal range. Biochemical testing was otherwise consistent with ACTH-mediated hypercortisolism, and adrenal histopathology showed bilateral hyperplasia with no evidence of tumor. This case illustrates that serum DHEA-S is not an infallible guide to the differential diagnosis of Cushing's syndrome, and it supports the existence of a pituitary-secreted adrenal androgen stimulating factor that is distinct from ACTH.

Effect of infused branched-chain amino acids on muscle and whole-body amino acid metabolism in man.

1. Using the forearm balance method, together with systemic infusions of L-[ring-2,6-3H]phenylalanine and L-[1-14C]leucine, we examined the effects of infused branched-chain amino acids on whole-body and skeletal muscle amino acid kinetics in 10 postabsorptive normal subjects; 10 control subjects received only saline. 2. Infusion of branched-chain amino acids caused a four-fold rise in arterial branched-chain amino acid levels and a two-fold rise in branched-chain keto acids; significant declines were observed in circulating levels of most other amino acids, including phenylalanine, which fell by 34%. Plasma insulin levels were unchanged from basal levels (8 +/- 1 mu-units/ml). 3. Whole-body phenylalanine flux, an index of proteolysis, was significantly suppressed by branched-chain amino acid infusion (P less than 0.002), and forearm phenylalanine production was also inhibited (P less than 0.03). With branched-chain amino acid infusion total leucine flux rose, with marked increments in both oxidative and non-oxidative leucine disposal (P less than 0.001). Proteolysis, as measured by endogenous leucine production, showed a modest 12% decrease, although this was not significant when compared with saline controls. The net forearm balance of leucine and other branched-chain amino acids changed from a basal net output to a marked net uptake (P less than 0.001) during branched-chain amino acid infusion, with significant stimulation of local leucine disposal. Despite the rise in whole-body non-oxidative leucine disposal, and in forearm leucine uptake and disposal, forearm phenylalanine disposal, an index of muscle protein synthesis, was not stimulated by infusion of branched-chain amino acids. 4. The results suggest that in normal man branched-chain amino acid infusion suppresses skeletal muscle proteolysis independently of any rise of plasma insulin. Muscle branched-chain amino acid uptake rose dramatically in the absence of any apparent increase in muscle protein synthesis, as measured by phenylalanine disposal, or in branched-chain keto acid release. Thus, an increase in muscle branched-chain amino acid concentrations and/or local branched-chain amino acid oxidation must account for the increased disposal of branched-chain amino acids.

Effect of starvation on human muscle protein metabolism and its response to insulin.

Although starvation is known to impair insulin-stimulated glucose disposal, whether it also induces resistance to insulin's antiproteolytic action on muscle is unknown. To assess the effect of fasting on muscle protein turnover in the basal state and in response to insulin, we measured forearm amino acid kinetics, using [3H]phenylalanine (Phe) and [14C]leucine (Leu) infused systemically, in eight healthy subjects after 12 (postabsorptive) and 60 h of fasting. After a 150-min basal period, forearm local insulin concentration was selectively raised by approximately 25 muU/ml for 150 min by intra-arterial insulin infusion (0.02 mU.kg-1. min-1). The 60-h fast increased urine nitrogen loss and whole body Leu flux and oxidation (by 50-75%, all P less than 0.02). Post-absorptively, forearm muscle exhibited a net release of Phe and Leu, which increased two- to threefold after the 60-h fast (P less than 0.05); this effect was mediated exclusively by accelerated local rates of amino acid appearance (Ra), with no reduction in rates of disposal (Rd). Local hyperinsulinemia in the postabsorptive condition caused a twofold increase in forearm glucose uptake (P less than 0.01) and completely suppressed the net forearm output of Phe and Leu (P less than 0.02). After the 60-h fast, forearm glucose disposal was depressed basally and showed no response to insulin; in contrast, insulin totally abolished the accelerated net forearm release of Phe and Leu. The action of insulin to reverse the augmented net release of Phe and Leu was mediated exclusively by approximately 40% suppression of Ra (P less than 0.02) rather than a stimulation of Rd. We conclude that in short-term fasted humans 1) muscle amino acid output accelerates due to increased proteolysis rather than reduced protein synthesis, and 2) despite its catabolic state and a marked impairment in insulin-mediated glucose disposal, muscle remains sensitive to insulin's antiproteolytic action.

Measurement of L-[1-14C]leucine kinetics in splanchnic and leg tissues in humans. Effect of amino acid infusion.

Although whole-body leucine flux is widely measured to study body protein turnover in humans, the contribution of specific tissues to the total-body measurement remains unknown. By combining the organ-balance technique with the systemic infusion of L-[1-14C]leucine, we quantitated leucine production and disposal by splanchnic and leg tissues and by the whole body, simultaneously, in six normal men before and during amino acid infusion. At steady state, disposal of arterial leucine by splanchnic and leg tissues was calculated from the percent extraction (E) of L-[1-14C]leucine counts: uptake = E x [Leu]a x flow. Tissue release of cold leucine (from protein turnover) into vein was calculated as the difference between leucine uptake and the net tissue leucine balance. In the postabsorptive state, despite substantial (P less than .01) extraction of L-[1-14C]leucine by splanchnic (23 +/- 1%) and leg (18 +/- 2%) tissues, net leucine balance across both tissue beds was small, indicating active simultaneous disposal and production of leucine at nearly equivalent rates. Splanchnic tissues accounted for approximately 50% of the measured total-body leucine flux. During amino acid infusion, the net leucine balance across splanchnic and leg tissues became positive, reflecting not only an increase in leucine uptake but also a marked suppression (by approximately 50%, P less than .02) of cold leucine release. This reduction in splanchnic and leg leucine release was indicated by a sharp decline in whole-body endogenous leucine flux.(ABSTRACT TRUNCATED AT 250 WORDS)