Intracellular regulation of mRNA translation and MPS responses to exercise are mediated by mTORC1 modulation of the phosphorylation states of two downstream target substrates, p70^S6K1, and the translational repressor eukaryotic initiation factor 4E-binding protein 1 (4E-BP1) (Figure 1) [1]. However, the MAPK cascade may also play a critical role in skeletal muscle adaptations to exercise, as the activity of this signaling pathway is positively associated with muscle growth, and sensitive to inflammatory, growth factor, and cellular stress responses to exercise [35,36,37,38]. Extracellular signal-regulated kinases 1 and 2 (ERK 1/2), p38 MAPK, c-Jun NH₂-terminal kinases (JNK), and ERK 5 are the four primary components of the MAPK signaling cascade [35]. Drummond et al. [39] was the first to demonstrate in human skeletal muscle that maximal anabolic responses to resistance exercise are, in part, dependent on the co-activation of the MAPK and mTORC1 signaling cascades. Moore et al. [40] confirmed these findings in human muscle, as enhanced phosphorylation of ERK 1/2 and the 90-kDa ribosomal S6 kinase (p90^RSK) were demonstrated with concomitant elevations in MPS and mTORC1 activation during recovery from high-volume, single-joint resistance exercise. Elevated p38, JNK, and ERK 1/2 phosphorylation were also recently demonstrated in human skeletal muscle during the first several hours of recovery from high-power, multi-joint resistance exercise [41]. The authors of this study hypothesized that MAPK signaling responses during the early stages of recovery from high-intensity resistance exercise may contribute to long-term muscle adaptations to resistance training. In support of this hypothesis, the relationship between MAPK and mTORC1 signaling was recently demonstrated using a less traditional non-physiological protocol to induce muscle growth, further suggesting that MAPK signaling is intricately involved in muscle hypertrophic responses to exercise [42]. Miyazaki et al. [42] used a 10-day synergist ablation mechanical overload model to induce hypertrophy in laboratory animals. Muscle hypertrophy, increased MPS, and PI3K-independent elevations in p70^S6K1 phosphorylation (i.e., increased p70^S6K1 phosphorylation occurred before elevations in PI3K signaling) were observed in as little as 1-day of mechanical stress, with concomitant increases in the phosphorylation of mitogen activated protein kinase kinase (MEK 1/2), ERK 1/2, and the tuberous sclerosis complex 2 (TSC2), a key substrate for MEK/ERK signaling. Considering the TSC2 complex is an upstream regulator of mTORC1 and MPS, these data support the hypothesis that mTORC1 anabolic signaling responses to exercise are co-regulated by the MAPK pathway.

Based on those findings, it appears that initial MAPK, mTORC1, and MPS responses to exercise are IGF-1/PI3K-independent. However, the precise mechanism by which mechanical stressors initiate muscle anabolism is still undetermined. Spangenburg and McBride [43] demonstrated that pharmacologic inhibition of stretch activated ion channels (SAC) in laboratory animals blocked resistance exercise-induced p70^S6K1 phosphorylation [43]. Intracellular calcium flux is regulated in part by the SAC, and elevations in intracellular calcium may stimulate a calcium/calmodulin interaction with hVps34 (CaM complex/Vps34), which subsequently activates mTORC1 (3-h post-exercise) in the presence of contractile-induced elevations in intracellular AA levels [8]. Therefore, SAC-mediated increases in intracellular calcium levels may function as a critical mechanosensing mechanism contributing to the intracellular anabolic response to exercise. In fact, increasing intracellular calcium using a calcium ionophore in isolated muscle cells has been demonstrated to independently stimulate MPS [4]. Mechanically stretching these muscle cells with concomitant increases in intracellular calcium levels produced a more pronounced stimulation of MPS [4]. However, mechanical activation of mTORC1 signaling was also demonstrated despite when chelation induced a dramatic reduction in intracellular calcium concentrations [26]. Bodine et al. [28] also demonstrated that blockade of CaM using pharmacologic calceurin inhibitors, cyclosporin A and FK506, failed to inhibit muscle hypertrophy. However, the concept of calcium-mediated regulation of skeletal muscle mass remains contested [44]. Nevertheless, these findings suggest the existence of other potential mechanosensors, besides SAC-regulated calcium flux, which also act to trigger the anabolic signaling response to exercise.

The phospholipid enzyme PLD and subsequent product PA may also play a role in mechanotransduced activation of mTORC1 signaling. In a series of in vitro and in vivo laboratory animal experiments, Hornberger et al. [3] demonstrated that: (1) elevations in PA concentrations activated mTORC1 signaling; (2) the PLD isozymes (PLD1 and PLD2) are localized at the z-line of the sarcomere, a central site for contractile force transmission; (3) mechanical stress via eccentric loading stimulated PLD activation, PA accumulation, and mTORC1 signaling; and (4) pharmacologic inhibition of PLD blocked mechanical stress-induced elevations in PA concentrations and mTORC1 signaling. In a subsequent study, O’Neil et al. [45] demonstrated that mechanical stress-induced PA accumulation was necessary to stimulate mTORC1 activity and consequent muscle hypertrophy using a similar scientific approach. Furthermore, anabolic signaling responses to elevations in PA concentrations were independent of IFG-1/PI3K signaling, as growth factor signaling was blocked pharmacologically. The mechanism by which this occurs appears to be through a direct activation of the mTOR kinase, as PA competitively binds with the FKBP12-rapamycin binding domain on mTOR [46]. These data indicate that mTORC1 activation in response to mechanical loading is PLD-dependent, which may, in part, contribute to exercise-induced muscle hypertrophy. Although these mechanisms will likely be explored in greater detail in future studies, it is important to note that PA-mediated anabolic intracellular signaling has not been thoroughly examined in human skeletal muscle. Furthermore, though studies suggest that PLD and subsequent PA serve a critical regulatory role in mTORC1 signaling following resistance exercise, it must be recognized that stimulation of mTORC1 in response to other mitogen stimuli is also PLD/PA-dependent [47].

Leucine is an established insulin secretagogue [68], and acute administration of excess leucine stimulates an increase in plasma insulin, resulting in enhanced mTORC1 signaling and MPS (Figure 2) [69,70]. The stimulation of MPS attributed to insulin occurs upstream of mTORC1 through PI3K and subsequent phosphorylation of protein kinase B (PKB/Akt). Under that regulatory control, Akt indirectly stimulates mTORC1 by phosphorylating TSC2, thereby activating the GTPase protein, Ras homolog enriched with brain (RHEB) [71]. Pharmacologic inhibition of insulin secretion fails to block leucine mediated mTORC1 signaling in laboratory animals [52,69]. These data suggest that AA stimulate anabolic signaling through both an insulin-dependent and independent mechanism. However, intracellular signaling and MPS responses to insulin inhibition were lower in comparison to animals with normal insulin function. As such, the degree to which leucine stimulates mTORC1 signaling may rely to an extent upon concomitant increases in insulin concentrations. More specifically, using an animal model, Crozier et al. [72] demonstrated that early stimulation of MPS in response to leucine administration was not reliant on insulin, but maximal stimulation of mTORC1 was dependent on elevations in circulating insulin concentrations. Pharmacologic-induced insulinemia in humans also fails to potentiate MPS responses to AA provision [73]. However, similar to the study by Crozier et al. [72], the stimulation of the mTORC1 was insulin-dependent, which suggest that a dissociative relationship between anabolic intracellular signaling and MPS responses to AA and insulin manipulations may exit [73].

In vitro studies suggest that hVps34 and MAP4K3 also contribute to insulin-independent, AA-induced regulation of mTORC1 signaling [6,7,9]. The hVps34 protein is a novel class 3 PIK that lies upstream of mTORC1. The activity of this lipid kinase is regulated in part by AA concentrations: hVps34 activity is attenuated with nutrient depletion, whereas increasing AA concentrations activates hVps34, phosphorylates p70^SK1, and inhibits 4E-BP1 [6]. MacKenzie et al. [8] demonstrated that not only do contractile-induced elevations in leucine stimulate hVps34 activity, but sustained (3-h) provision of leucine to isolated muscle cells activates hVps34, which the authors suggest may prolong mTORC1 stimulation and contribute to long-term muscle hypertrophy. Gulati et al. [74] also demonstrated that elevations in AA concentrations modulate cellular calcium flux, causing the aforementioned CaM complex/Vps34 interaction and concomitant activation of mTORC1. In addition, MAP4K3, which was recently identified in Drosophila, is required for AA-induced stimulation of p70^SK1 and 4E-BP1 through mTORC1 [9]. However, the mechanism by which MAP4K3 responds to fluctuations in AA concentrations to modulate mTORC1 activity is not well described. More importantly, not all studies support the interaction between these unique nutrient sensors, AA, and mTORC1 activity [75], and no studies have clearly identified the role of hVps34 and MAP4K3 in anabolic intracellular signaling and MPS in human skeletal muscle [76].

The functions of the Rag subfamily of Ras small GTPase proteins are associated with AA-mediated mTORC1 activation. Two independent groups of the four Rag GTPases that mammalian cells express (RagA, RagB, RagC, and RagD) modulate anabolic cell signaling through mTORC1 by functioning as heterodimers and binding with the mTORC1 associated protein Raptor. Raptor acts as an adaptor protein, recruiting substrates for mTORC1 phosphorylation, primarily p70^SK1 and 4E-BP1 [10,66,77]. However, Rag interaction with mTORC1 does not directly activate the mTOR kinase; rather Rag proteins modulate cellular translocation of mTORC1 to the lysosome that facilitates an mTOR and RHEB interaction, which in the presence of elevated AA concentrations, results in RHEB-induced activation of mTORC1. Leucyl-tRNA synthetase (LRS) may be a novel AA sensing mechanism that functions in concert with Rag to activate mTORC1, as Han et al. [78] recently demonstrated that LRS binds directly with Rag, subsequently mediating GTPase activation and mTORC1 signaling in an AA-dependent manner. As such, Rag-mediated mTORC1 translocation and subsequent activation in response to AA sufficiency may prove to be the primary mechanism responsible for increased MPS following AA administration.

Muscle intracellular AA transport proteins function as critical links connecting anabolic intracellular signaling to manipulations in AA concentrations by shuttling AA across cell membranes [79,80]. System L (L-type amino acid transporter 1(LAT1)/solute-linked carrier (SLC) 7A5 and CD98/SLC3A2 heterodimeric complex) and system A (sodium-coupled neutral AA transporters (SNAT2/SLC38A2)) transporters are involved in the regulation of intracellular AA concentrations by transporting large neutral AA (e.g., branched-chain amino acids) into muscle cells [81]. The expression and function of LAT1/CD98 and SNAT2 are positively associated with muscle growth, mTORC1 activation, and MPS [82,83]. In response to elevations in extracellular AA concentrations, SNAT2 increases glutamine influx, stimulating the LAT1/CD98-regulated bitransport system that exports glutamine out of the cell in exchange for leucine.

Interactions between dietary AA manipulations and transporter-mediated anabolic intracellular signaling in human skeletal muscle have recently been investigated in a series of studies by Drummond et al. [11,12,67]. Intracellular leucine kinetics, MPS, mTORC1 signaling, and AA transporter expression were determined in healthy young adults before and after consuming a 10 g EAA supplement [12]. EAA ingestion resulted in increased leucine delivery to the muscle, intramuscular leucine concentrations, MPS, and mTORC1 activation. The anabolic response to EAA administration occurred with concomitant increases in LAT1 and SNAT2 expression suggesting a unique regulatory mechanism that may contribute AA-induced stimulation of MPS by enhancing the availability of AA. Drummond et al. [67] also demonstrated that 7 days of bed in older adults attenuates MPS, mTORC1 signaling, and LAT1 and SNAT2 protein content responses to EAA ingestion. These data demonstrate that relatively short periods of physical inactivity may contribute to age-related muscle loss by further desensitizing aging skeletal muscle to the potent anabolic stimulus of AA. Whether other conditions associated with muscle loss such as those experienced with weight loss in response to extended periods of energy deficiency result in similar patterns of AA transporter expression, mTORC1 signaling, and MPS responses to dietary AA manipulations has not been determined.

Reduced skeletal muscle mass coupled with an increase in body fat is among the most debilitating and consistent changes associated with aging. Age-related muscle loss is referred to as sarcopenia, which is clinically defined as presentation with muscle mass at least two standard deviations below the average muscle mass of a younger adult 35 years of age [86]. The rate of skeletal muscle loss can be much as 1% per year after 30 years of age, which continues until the end of life [87]. Although the etiology of sarcopenia is multifaceted, the most evident metabolic explanation for the decline in muscle mass is an imbalance between rates of MPS and proteolysis [88]. The reduction in muscle mass with aging can degrade strength, metabolic rate, aerobic capacity, and muscular function, thereby reducing quality of life [89], and predisposing elderly individuals to illness, fractures, and other chronic metabolic conditions such as obesity and type 2 diabetes [90], which ultimately increase mortality [91].

Multiple reports have demonstrated that aging skeletal muscle is desensitized to exogenous AA administration [61,92,93]. In fact, anabolic resistance to AA is considered a major contributor to age-related muscle loss [61]. However, this phenomenon may be overcome by manipulating the leucine content of an AA supplement or of a protein containing meal [61,62]. In a recent review, Breen and Phillips [94] hypothesized the existence of a leucine threshold, which must be surpassed to maximize MPS and mTORC1 signaling. They suggest that this threshold differs between young and aging muscle, where 1 g of leucine combined with resistance exercise in young adults is sufficient to stimulate MPS above resting conditions [56], but 2 g of leucine may be required to stimulate MPS above resting conditions in older adults after resistance exercise [95]. Interestingly, and in contrast to young adults [56], MPS in older adults reaches maximal stimulation after resistance exercise when approximately 4 g of leucine (40 g whey protein) is consumed. These findings are not only consistent with earlier reports in older adults [61,62] but also similar to recent data from our laboratory that suggest that leucine requirements may not only be dependent on age but also perhaps by the metabolic demand for energy and AA [60].

Evidence also demonstrates that MPS and mTORC1 signaling responses to resistance exercise are blunted in older compared to younger adults [96,97,98]. A recent report suggests that AA transporter expression may be a contributing factor to age-related anabolic resistance to mechanical loading [11]. Drummond et al. [11] demonstrated increased LAT1 expression with concomitant elevations in mTORC1 signaling in young adults, yet no changes in transporter expression and anabolic signaling in older adults following a bout of resistance exercise. However, manipulating the volume of mechanical overload may prove to be an effective compensatory strategy against anabolic resistance to exercise, which may contribute to the conservation of muscle mass [96,97]. Fry et al. [99] demonstrated that combining low-intensity, high-volume resistance exercise with blood flow restriction (i.e., leg blood flow was restricted using a lower extremity pressure cuff; Kaatsu-Master Mini, Tokyo, Japan), stimulated marked increases in MPS and mTORC1 signaling in older adults; although the practical applications (e.g., access to pressure cuffs and potential for discomfort) of blood flow restricted exercise may be limiting. Other studies recommend that older adults perform low-intensity, high-volume resistance exercise to muscle failure to impose a cumulative mechanical load that is greater than those typically observed with high-intensity, low-volume resistance exercise [18]. Therefore, low-intensity, high-volume exercise to muscle failure or perhaps when safely combined with blood flow restriction may be an effective anabolic stimulus and form of exercise therapy for older adults to perform in comparison to conventional resistance exercise training [97]. Furthermore, the most effective strategy against age-related muscle loss is arguably the combination of exercise with AA (or high-quality protein) supplementation, as there is no shortage of reports that demonstrate acute mTORC1 and MPS responses to exercise and AA and protein consumption are more pronounced in older adults when these anabolic stimuli are combined [11,12,76,95,100]. Whether acute anabolic intracellular signaling and MPS responses result in long-term conservation of muscle mass following structured, low-intensity, high-volume exercise training with optimized nutritional support has not been determined.