Key points• The branched-chain amino acid (BCAA) leucine acts as both a 'trigger' for the initiation of protein synthesis, and as a substrate for newly synthesized protein.• As a BCAA, leucine can be metabolized within skeletal muscle, leaving open the possibility that leucine metabolites might possess anabolic properties.• One metabolite in particular, β-hydroxy-β-methylbutyrate (HMB), has shown positive effects on lean body mass and strength following exercise, and in disease-related muscle wasting, yet its impact on acute human muscle protein turnover is undefined.• We report here that HMB stimulates muscle protein synthesis to a similar extent to leucine.HMB was also found to decrease muscle protein breakdown.• Our observation that HMB enhances muscle protein anabolism may partly (or wholly) underlie its pre-defined anabolic/anti-catabolic supplemental efficacy in humans.Abstract Maintenance of skeletal muscle mass is contingent upon the dynamic equilibrium (fasted losses-fed gains) in protein turnover. Of all nutrients, the single amino acid leucine (Leu) possesses the most marked anabolic characteristics in acting as a trigger element for the initiation of protein synthesis. While the mechanisms by which Leu is 'sensed' have been the subject of great scrutiny, as a branched-chain amino acid, Leu can be catabolized within muscle, thus posing the possibility that metabolites of Leu could be involved in mediating the anabolic effect(s) of Leu. Our objective was to measure muscle protein anabolism in response to Leu and its metabolite HMB. Using [1,2-13 C 2 ]Leu and [ 2 H 5 ]phenylalanine tracers, and GC-MS/GC-C-IRMS we studied the effect of HMB or Leu alone on MPS (by tracer incorporation into myofibrils), and for HMB we also measured muscle proteolysis (by arteriovenous (A-V) dilution). Orally consumed 3.42 g free-acid (FA-HMB) HMB (providing 2.42 g of pure HMB) exhibited rapid bioavailability in plasma and muscle and, similarly to 3.42 g Leu, stimulated muscle protein synthesis (MPS; HMB +70% vs. Leu +110%). While HMB and Leu both increased anabolic signalling (mechanistic target of rapamycin; mTOR), this was more pronounced with Leu (i.e. p70S6K1 signalling ≤90 min vs. ≤30 min for HMB). HMB consumption also attenuated muscle protein breakdown (MPB; −57%) in an insulin-independent manner. We conclude that exogenous HMB induces acute muscle anabolism (increased MPS and reduced MPB) albeit perhaps via distinct, and/or additional mechanism(s) to Leu.
Striated muscle is a tissue in which gene expression is influenced to a large extent by mechanical signals. This includes the regulation of gene expression-associated muscle fiber phenotype determination, which depends on which protein isoform genes are transcribed, as well as muscle fiber mass accretion, which appears to involve some translational regulation. Although muscle synthesizes a set of highly specialized proteins it has a remarkable ability to adapt by expressing different isoforms of the same protein so that it acquires the appropriate contractile characteristics. Our work has focused on the myosin heavy chain (HC) genes as these encode the myosin cross bridge, which is responsible for muscle intrinsic velocity of contraction and economy of force development. RNA analyses after cast immobilization of the limb with the muscle in the lengthened or shortened position and/or with electrical stimulation were used to determine the effects of altered mechanical signals on gene transcription. When the soleus muscle was immobilized in the shortened position in the young animal it did not fully differentiate into a slow postural-type muscle. Even in the adult, the soleus muscle if deprived of stretch and contractile activity switches back to transcribing the fast myosin HC gene. The converse was true when the fast rabbit tibialis anterior was subjected to immobilization in the lengthened position and/or electrical stimulation. Both stretch alone and stimulation alone caused repression of the fast type and activation of the slow myosin genes. The reprogramming of the fast muscle was more complete when the stretch was combined with stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)
The identification of genes that regulate fetal growth will help establish the reasons for intrauterine growth restriction. Most autosomal genes are expressed biallelically, but some are imprinted, expressed only from one parental allele. Imprinted genes are associated with fetal growth and development. The growth of the fetus in utero relies on effective nutrient transfer from the mother to the fetus via the placenta. Some current research on the genetic control of fetal growth has focused on genes that display imprinted expression in utero. The expression levels of four imprinted genes, the paternally expressed insulin growth factor 2 (IGF2), the mesoderm-specific transcript isoform 1 (MEST); the maternally expressed pleckstrin homology-like domain, family A, member 2 (PHLDA2); and the polymorphically imprinted insulin-like growth factor 2 (IGF2R) gene are all known to have roles in fetal growth and were studied in the placentae of 200 white European, normal term babies. The quantitative expression analysis with real-time PCR showed the maternally expressing PHLDA2 but not the paternally expressing IGF2 and MEST, nor the polymorphic maternally expressing IGF2R placental levels to have a statistically significant effect on birth weight. PHLDA2 expression levels are negatively correlated with size at birth. These data implicate PHLDA2 as an imprinted gene important in fetal growth and also as a potential marker of fetal growth.
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