Paul T. Loughna

Effects of leucine and its metabolite β-hydroxy-β-methylbutyrate on human skeletal muscle protein metabolism

•  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.

The effect of hypokinesia and hypodynamia on protein turnover and the growth of four skeletal muscles of the rat.

An animal suspension model has been used to simulate the weightlessness experienced during space travel. This procedure results in a reduction in the normal shortening (i.e. hypokinesia) and force generation functions of hind limb muscles (i.e. hypodynamia). The ensuing muscle atrophy was studied over 12 days in different muscle types. Slow muscles (e.g. the soleus) underwent a more pronounced atrophy than intermediate (i.e. gastrocnemius) and fast phasic muscles (e.g. extensor digitorum longus). In all muscle types inactivity resulted in a smaller accumulation of DNA and losses of RNA and protein after 5 days. The latter arose from a decrease in the rate of protein synthesis (measured in vivo) and an increase in protein breakdown. Increased specific activities of cathepsins B and D also supported the view that there is an increased proteolysis after hypokinesia and hypodynamia.When the inactive soleus was simultaneously held in a lengthened (stretched) state the atrophy was prevented through a large increase in the fractional rate of protein synthesis. Protein degradation remained elevated with stretch, thereby slowing the growth of these muscles relative to those in pair-fed, ambulatory controls. The much smaller atrophy of the tibialis anterior and extensor digitorum longus muscles in suspended only limbs represented an underestimate of the true atrophic effects of hypokinesia and hypodynamia. In this model gravity pulls the suspended foot into a plantar flexed position, thereby permanently stretching and protecting such flexor muscles. When this influence of stretch was removed a greater atrophy ensued, mainly due to the loss of the stretch-induced stimulation of protein synthesis. Despite this, the inactive fast-twitch muscles still exhibited less atrophy than the gastrocnemius and soleus muscles.

Temperature acclimation: improved sustained swimming performance in carp at low temperatures

At low temperatures, the reduction in mechanical power output of the aerobic muscle forces cold-blooded animals, such as carp, to recruit their rapidly fatiguing anaerobic fibers at relatively slow swimming speeds. Previous experimental data have suggested that changes in the biochemistry and morphology of the aerobic muscle during cold acclimation might increase its output of mechanical power. The present experiments show that, because of these changes, carp can swim faster at low temperature using only their aerobic muscle, which results in an increase in their sustainable swimming speed. By modifying their musculature, cold-blooded animals can achieve some independence from the effects of seasonal changes in environmental temperature.

Passive stretch modulates denervation induced alterations in skeletal muscle myosin heavy chain mRNA levels.

Abstract. The effect of denervation and denervation combined with immobilisation in either the shortened or lengthened position (passive stretch) upon myosin heavy chain (MyHC) mRNA levels was examined in three rat hind-limb muscles with differing phenotypes. Denervation alone caused a reduction in type I and type IIa MyHC transcripts in all three muscles. In contrast denervation caused a 72% increase in type IIb in the slow postural soleus muscle only which was prevented by immobilisation in the lengthened position. In the same muscle passive stretch also significantly retarded the effects of denervation upon the type I transcript (from 38% below control levels to 24% below) and type IIa transcript (from 59% to 32% below control levels). The levels of both type I and IIa transcripts, in the fast phasic plantaris muscle, were both unaffected by stretch combined with denervation when compared to denervation alone. In the mixed gastrocnemius muscle stretch affected the level of the type I but not the type IIa transcript. These data suggest that passive stretch can modulate MyHC gene expression independently of innervation but that it does so in a muscle-specific manner.

Cyclic stretch reduces myofibrillar protein synthesis despite increases in FAK and anabolic signalling in L6 cells

Muscle protein synthesis is increased after exercise, but evidence is now accruing that during muscular activity it is suppressed. In life, muscles are subjected to shortening forces due to contraction, but may also be subject to stretching forces during lengthening. It would be biologically inefficient if contraction and stretch have different effects on muscle protein turnover, but little is known about the metabolic effects of stretch. To investigate this, we assessed myofibrillar and sarcoplasmic protein synthesis (MPS, SPS, respectively) by incorporation of [1‐13C]proline (using gas chromatography–mass spectrometry) and anabolic signalling (by phospho‐immunoblotting and kinase assays) in cultured L6 skeletal muscle cells during 30 min of cyclic stretch and over 30 min intervals for up to 120 min afterwards. SPS was unaffected, whereas MPS was suppressed by 40 ± 0.03% during stretch, before returning to basal rates by 90–20 min afterwards. Paradoxically, stretch stimulated anabolic signalling with peak values after 2–30 min: e.g. focal adhesion kinase (FAK Tyr576/577; +28 ± 6%), protein kinase B activity (Akt; +113 ± 31%), p70S6K1 (ribosomal S6 kinase Thr389; 25 ± 5%), 4E binding protein 1 (4EBP1 Thr37/46; 14 ± 3%), eukaryotic elongation factor 2 (eEF2 Thr56; −47 ± 4%), extracellular regulated protein kinase 1/2 (ERK1/2 Tyr202/204; +65%± 9%), eukaryotic initiation factor 2α (eIF2α Ser51; −20 ± 5%, P < 0.05) and eukaryotic initiation factor 4E (eIF4E Ser209; +33 ± 10%, P < 0.05). After stretch, except for Akt activity, stimulatory phosphorylations were sustained: e.g. FAK (+26 ± 11%) for ≥30 min, eEF2 for ≥60 min (peak −45 ± 4%), 4EBP1 for ≥90 min (+33 ± 5%), and p70S6K1 remained elevated throughout (peak +64 ± 7%). Adenosine monophosphate‐activated protein kinase (AMPK) phosphorylation was unchanged throughout. We report for the first time that acute cyclic stretch specifically suppresses MPS, despite increases in activity/phosphorylation of elements thought to increase anabolism.

Two myogenic regulatory factor transcripts exhibit muscle-specific responses to disuse and passive stretch in adult rats.

Levels of myogenic regulatory factor (MRF) transcripts are altered in a muscle‐specific manner in response to hind limb immobilisation of adult male rats, for a 2 day period, in either a lengthened or shortened position which result in passive stretch or disuse atrophy respectively. Myogenin transcript levels were dramatically elevated in the stretched plantaris but not soleus, whereas the MRF4 transcript was significantly elevated in soleus but not plantaris. Levels of myogenin mRNA were unaffected by disuse in either muscle and MRF4 was markedly lower in plantaris in response to disuse.

The expression of the myogenic regulatory factors in denervated and normal muscles of different phenotypes

The nerve is known to play a pivotal role in the diversification of muscle fibre types postnatally. Reducing neuronal activity in a slow muscle such as the soleus by denervation, switches on genes associated with a fast muscle phenotype. On the other hand, denervating a fast muscle such as the extensor digitorum longus (EDL) induces the conversion of fast fibres to a ‘slower’ contractile phenotype. The myogenic regulatory factors (MRFs) are proposed as the regulators of muscle phenotype as MyoD and myogenin have been shown to differentially accumulate in fast and slow muscle upon the induction of fibre type transformation. The denervation model has been used in the present study to induce changes in MRF expression in the muscles of the lower hindlimb which have distinct phenotypic characteristics. The level of MRF expression in pairs of denervated and innervated soleus, EDL, tibialis anterior (TA), plantaris and gastrocnemius muscles has been determined by Northern analysis and compared. The present study has shown that each muscle responds differently to denervation with respect to the increases in MRF expression. Fast muscles responded very quickly to denervation by increasing the level of MRF transcripts while slow muscles did not show significant increases in expression after 48 h denervation. The innervated EDL (fast) and soleus (slow) muscle differed with respect to the level of MRF-4 expressed, MRF-4 being expressed at higher levels in the slow muscle compared to the fast, suggesting that MRF-4 is important in the maintenance of a slow muscle phenotype. Moreover, MRF-4 and myogenin show the greatest fold increases in expression in the fast muscles examined. MyoD and Myf 5 show less dramatic increase in expression in response to denervation but exhibit the greatest fold increases in the fast muscles compared to slow.

Oxygen concentration modulates the differentiation of muscle stem cells toward myogenic and adipogenic fates

The physiological oxygen concentration of many tissues is far lower than that in which cells are typically cultured in vitro and this may inadvertently influence the proliferation and differentiation potential of many cell types. Muscle derived stem cells, known as satellite cells are responsible for the maintenance and repair of muscle tissue post-natally and in vivo would be exposed to oxygen concentrations of ∼2-5%. Relatively few studies describe the function of these cells in large animal models and here we investigate the influence oxygen concentration has on modulating porcine muscle derived stem cell fate. We compared cells derived from two metabolically distinct muscles, the diaphragm and the hind limb semi-membranosus (SM) muscle. The two sub-populations responded differently to culture at atmospheric (∼20%) and physiological (∼5%) oxygen concentration. While myogenesis was enhanced in both populations at low oxygen, noticeably diaphragm derived cells exhibited greater myotube formation, than those from SM. The trans-differentiation of cells derived from these two sources was similarly affected, with considerable differences seen in adipogenic and neuronal tendencies. In addition to the effect of oxygen on cell phenotype, the expression of key signalling proteins varied between the two sub-populations during early time-points of induced differentiation, suggesting altered regulation of muscle specific stem cells under these conditions. While differences in muscle stem cell potential requires further investigation, the culture of cells in physiological oxygen concentration appears as fundamental to recreating the micro-environmental niche as routinely used factors such as cytokines, substrata and matrices.

Adult-Onset Obesity Reveals Prenatal Programming of Glucose-Insulin Sensitivity in Male Sheep Nutrient Restricted during Late Gestation

Background Obesity invokes a range of metabolic disturbances, but the transition from a poor to excessive nutritional environment may exacerbate adult metabolic dysfunction. The current study investigated global maternal nutrient restriction during early or late gestation on glucose tolerance and insulin sensitivity in the adult offspring when lean and obese. Methods/Principal Findings Pregnant sheep received adequate (1.0M; CE, n = 6) or energy restricted (0.7M) diet during early (1–65 days; LEE, n = 6) or late (65–128 days; LEL, n = 7) gestation (term ∼147 days). Subsequent offspring remained on pasture until 1.5 years when all received glucose and insulin tolerance tests (GTT & ITT) and body composition determination by dual energy x-ray absorptiometry (DXA). All animals were then exposed to an obesogenic environment for 6–7 months and all protocols repeated. Prenatal dietary treatment had no effect on birth weight or on metabolic endpoints when animals were ‘lean’ (1.5 years). Obesity revealed generalised metabolic ‘inflexibility’ and insulin resistance; characterised by blunted excursions of plasma NEFA and increased insulinAUC (from 133 to 341 [s.e.d. 26] ng.ml−1.120 mins) during a GTT, respectively. For LEL vs. CE, the peak in plasma insulin when obese was greater (7.8 vs. 4.7 [s.e.d. 1.1] ng.ml−1) and was exacerbated by offspring sex (i.e. 9.8 vs. 4.4 [s.e.d. 1.16] ng.ml−1; LEL male vs. CE male, respectively). Acquisition of obesity also significantly influenced the plasma lipid and protein profile to suggest, overall, greater net lipogenesis and reduced protein metabolism. Conclusions This study indicates generalised metabolic dysfunction with adult-onset obesity which also exacerbates and ‘reveals’ programming of glucose-insulin sensitivity in male offspring prenatally exposed to maternal undernutrition during late gestation. Taken together, the data suggest that metabolic function appears little compromised in young prenatally ‘programmed’ animals so long as weight is adequately controlled. Nutritional excess in adulthood exacerbates any programmed phenotype, indicating greater vigilance over weight control is required for those individuals exposed to nutritional thrift during gestation.

Alterations in the mRNA levels of two metabolic enzymes in rat skeletal muscle during stretch-induced hypertrophy and disuse atrophy.

Changes in carbonic anhydrase III (CAIII: normally predominant in slow type 1 fibres) and phosphoglucoisomerase (PGI: normally predominant in fast type 2 fibres) mRNAs were studied in rat slow postural soleus and fast phasic plantaris muscles which had been immobilised in shortened (disuse) and lengthened (passive stretch) positions for 2 and 5 days. Our results provide evidence that limb immobilisation in both positions affects the expression of these metabolic enzymes. Muscle disuse resulted in considerable loss of CAIII mRNA in soleus but not in plantaris, whereas, PGI mRNA levels were unaffected in soleus but declined in plantaris after 2 days. Passive stretch caused an increase in CAIII mRNA in soleus muscles after 2 days, although this was not maintained after 5 days when a decrease was observed, and an increase in plantaris muscles after 5 days. In contrast, PGI mRNA declined in both muscles. These results indicate that immobilisation of muscles in the shortened and lengthened positions affects the levels of transcripts of these soluble enzymes in different ways and these effects are muscle specific.