Relevant transcriptomic data sets were sought via data mining of the Gene Expression Omnibus and ArrayExpress public repositories: up to and including September 2019. To compare disuse‐related and RET‐related transcriptional responses in the context of age, our search implemented the following inclusion criteria: (i) recruitment of healthy (i.e. uninjured and non‐diseased) volunteers aged either 18–35 years (young) and/or ≥60 years (older); (ii) employment of a disuse intervention (unilateral limb immobilization or bed rest) lasting ≥7 days and/or a RET protocol lasting ≥3 weeks; (iii) a within‐person study design in which rested (i.e. not acutely exercised) m. vastus lateralis samples were obtained both pre‐intervention and post‐intervention; and (iv) expression profiling undertaken using a non‐customized microarray (refer to original publications for RNA handling procedures). We chose to include only microarray data sets herein to limit the potential for technological bias(es) upon aggregating microarray and RNA‐sequencing data (particularly in the context of meta‐network analyses)^33,34 and because there was an insufficient number of RNA‐sequencing data sets available to conduct meta‐analyses on at the time of searching (one RET and one disuse).^25,35 In order to establish universal gene signatures of RET/disuse muscle adaptation, we did not exclude studies based on the type of disuse intervention (i.e. unilateral limb immobilization and bed rest) or RET protocol (i.e. intensity, frequency) employed. Our implemented minimum cut‐offs for the duration of disuse/RET intervention were chosen because disuse‐induced muscle atrophy is reproducibly detectable at ≥7 days,^12,14 while RET‐induced hypertrophic gains (and not swelling‐associated muscle hypertrophy)³⁶ are detectable after 3 weeks in both young and older individuals.^37,38 In total, 11 data sets (3 × disuse^21,39,40; 3 × young RET^20,23,24; 5 × older RET^{23,24,41–43}) across nine distinct studies were included in downstream analyses (Table 1).

Differential expression pre‐intervention vs. post‐intervention was first estimated per gene within each separate data set using empirical Bayes‐moderated paired t‐tests, as implemented in the limma package for R.⁴⁵ For each gene, individual (right‐tailed) P values were then aggregated using the Stouffer's method⁴⁸ to obtain a single meta‐analysis P value of its differential expression for each of the following data set combinations: (i) the three disuse data sets; (ii) the three young RET data sets, and (iii) the five older RET data sets. In all cases, meta P values were corrected using the Benjamini–Hochberg method to control for false discovery rate (FDR) and genes defined as significantly differentially expressed (DE) if they met all of the following criteria: (i) a corrected meta P value ≤ 0.1, (ii) an absolute meta (mean) log fold‐change > 0.1, and (iii) a common direction of gene log fold‐change across all pertinent data sets. This strict overall criterion for differential expression was applied to ensure the robust detection of concordant gene expression changes across individual data sets within each condition.

To gain a more holistic understanding of universal gene regulation in each condition, we complemented the gene‐level meta‐analysis with network‐level meta‐analysis. In particular, we employed a ‘consensus’ network approach using the weighted gene co‐expression network analysis package implemented in R.⁴⁹ Consensus networks comprise distinct gene clusters (‘modules’) that are commonly present in multiple independent data sets.³¹ Modules that compose a consensus network therefore represent reproducible co‐expression relationships in a given scenario that are reflective of the underlying biology rather than technical artefacts.³¹ Consensus networks were constructed for each of the following data set combinations: (i) the three disuse data sets, (ii) the three young RET data sets, and (iii) the five older RET data sets.

Initially, a signed weighted adjacency matrix (Adj) quantifying the connection strength between each pair of genes was derived for each data set as Adj = |0.5 × (1 + Corr)|^ß, where Corr is the matrix of Pearson's correlation coefficients that indicate the degree of similarity in expression pattern between any two given genes of that data set. The exponent ß was chosen per data set in accordance with the scale‐free topology criterion⁵⁰ as the lowest integer for which the corresponding scale‐free topology fitting index metric achieved an appropriately high value (≥0.8). Each adjacency matrix was then converted into a topological overlap matrix (TOM), in which each entry provides a measure of the relative interconnectedness (‘common connections’) between a given pair of genes within a given data set. For each data set combination, TOMs were made comparable via calibration by single quantile scaling, with a consensus TOM (cTOM) then defined in each case by taking the component‐wise (‘parallel’) minimum of the associated calibrated TOMs.

Each cTOM was then converted into a consensus dissimilarity measure (dis‐cTOM = 1 − cTOM), with consensus networks consequently built for each data set combination via hierarchical clustering of their respective dis‐cTOMs using average linkage as a distance metric. The modules of each consensus network were subsequently determined using the cutreeDynamic algorithm,⁵¹ with a minimum module size of 50 genes selected so as to obtain moderately large and distinct modules in each instance, minimizing potential transcriptional noise that can occur when detecting gene modules in smaller‐sized data sets.^52,53 Finally, the composite expression of genes within a given consensus module was calculated on a per data set basis by taking the first principal component of module gene expression: herein referred to as the module ‘eigengene’. Each data set therefore has an eigengene per module of its associated consensus network.³² Modules within each consensus network were consequently merged if they were highly correlated (minimum eigengene correlation across its data sets > 0.75).

After constructing each consensus network, network‐level meta‐analysis was undertaken in similar fashion to above, but with the focus instead being on establishing differentially regulated consensus modules within each network. As such, differential regulation pre‐intervention vs. post‐intervention was first estimated per module eigengene of each individual data set. Then, the individual (right‐tailed) P values of differential eigengene expression in each data set were aggregated per consensus module to calculate a single, corrected meta‐analysis P value of that module's differential regulation. In any case, a consensus module was defined as being significantly differentially regulated using the same criteria as outlined above, but with the requisite for criterion (iii) instead being a common direction of eigengene change across all pertinent data sets, rather than a common direction of gene log fold‐change.

To determine common and uniquely regulated genes across conditions of interest, we utilized the rank–rank hypergeometric overlap (RRHO) algorithm,⁵⁴ in which genes were ranked on sign of meta log fold‐change multiplied by the negative log10 of their corrected meta P value. Specific comparisons made were as follows: (i) young RET vs. disuse and (ii) young RET vs. older RET. In each case, commonly regulated genes were defined as those significantly DE in both conditions and present within the optimal overlapping gene set(s) between conditions. Uniquely regulated genes in each case were then defined as those significantly DE in a single condition and not present within the optimal overlapping gene set(s) between conditions. When comparing between young RET and disuse, commonly regulated genes were further defined on the basis of concordant vs. divergent regulation.

Inferring common and unique regulation at the network‐level is slightly more intricate than is at the individual gene‐level. Indeed, because network construction and module detection are unsupervised processes, individual networks are highly unlikely to be direct mirror images of one another in terms of their precise module compositions. Even then, module labels are arbitrary, and so, it would not necessarily hold true that (e.g.) module ‘M1’ in one network would equal module ‘M1’ of another network. There is also the potential that a particular set of genes form a module in one network but not another due to unique underlying biology in a given condition. To therefore make individual consensus networks more aligned to one another for comparison, we consequently utilized the weighted gene co‐expression network analysis matchLabels function.⁵⁵ With this function, module gene compositions are compared between a ‘reference’ and ‘source’ network using Fisher's exact test. Modules in the source network are then subsequently renamed in line with the module labels of the reference network so that modules between networks with a significant number of overlapping genes also then have the same label (but such that no two modules of the source network are renamed with the same label of the reference network). Thus, modules with the same label in both networks have a significant number of overlapping genes, but not necessarily identical gene compositions, and modules with labels unique to a single network are not recapitulated in the other network.⁵⁵ Clearly, this can be done only for two networks at any one time. Because our aim was to compare the young RET consensus network with both the disuse and older RET consensus networks, the young RET consensus network was thus used as the reference network, and modules of the disuse and older RET consensus networks were relabelled to be in line with those comprising the young RET consensus network. Note, it does not necessarily then hold true that the disuse and older RET consensus networks are comparable with one another. However, comparing these conditions was not the aim of this work. After this module calibration process, we were then able to make inferences on (un)common and unique module regulation by comparing across the differentially regulated consensus modules of: (i) the young RET and disuse networks and (ii) the young RET and older RET networks.

The functional characteristics of DE genes and differentially regulated consensus network modules were derived by testing their comprising gene lists for both Gene Ontology enrichment and pathway enrichment, using the Enrichr web server.⁵⁶ In the case of Gene Ontology analysis, we focused on enrichment for Biological Process terms.⁵⁷ For pathway analysis, we focused on enrichment for terms contained within the Reactome Pathway Database.⁵⁸ In all instances, terms with a Benjamini–Hochberg corrected P value < 0.05 were defined as being enriched.

In order to identify candidate regulatory molecules of muscle (mal)adaptation to RET and/or disuse, we first deduced consensus hub genes contained within our differentially regulated consensus network modules.^32,59 In line with the overarching concept of consensus network analysis, consensus hub genes represent module hub genes that are common in multiple independent data sets, the identification of which can be more useful than a gene‐level meta‐analysis P value for identifying biologically meaningful gene lists.³² Here, hub genes in consensus modules were derived using the consensus module membership metric—a measure that is strongly related to the ‘intramodular connectivity’ metric (another common measure traditionally used for the purposes of hub gene feature selection), but with the added benefit of being more suitable for candidate gene screening during network‐based meta‐analyses.^32,60 In brief, a module membership value for each gene was first calculated on a per data set basis as the correlation between its individual gene expression profile in that data set and the data set‐specific module eigengene (with associated P values being one‐sided to account for the fact that signed networks were constructed). Then, a consensus module membership value for each gene was derived as the Z‐score obtained from aggregating its gene–eigengene correlation across each pertinent data set using Stouffer's method.³² Consensus module genes with a consensus module membership value above the 85th percentile were then defined as consensus hub genes. Finally, we overlaid gene‐level and network‐level feature selections, which in the context of transcriptomic meta‐analysis may be a particularly useful approach to take when attempting to prioritize for the most biologically relevant candidate targets, because resultant genes are inherently characterized by robust regulation and interlinkage.³² Visualizations were generated using Cytoscape (v3.7.1).⁶¹

At the individual gene‐level, we observed that (i) most gene changes are unique to disuse or RET in isolation and (ii) genes that do overlap are predominantly DE in the same direction, while a limited number of overlapping genes display inverse expression patterns between disuse and RET (Figure 1, Table S3). Disuse was uniquely characterized by up‐regulation of genes involved in protein ubiquination and mitotic cell cycle, while RET alone was characterized by up‐regulation of angiogenesis‐related genes (Figure 1, Table S3). Disuse and RET both resulted in up‐regulation of genes involved in immune signalling, some were the same genes while some were unique to each condition. Similarly, certain genes involved in ECM organization were up‐regulated by both disuse and RET, whereas others were only up‐regulated by RET (Figure 1, Table S3). Thus, while divergent muscle growth responses to disuse vs. RET might be partially underpinned by distinct immune system/ECM remodelling molecular responses, some pleiotropic regulation might exist within commonly regulated aspects of these pathways. Lastly, disuse and RET induced inverted expression profiles for 59 genes (Figure 1, Table S3). Eighteen were genes down‐regulated by disuse but up‐regulated by RET, which were heavily enriched for mitochondrial respiration processes (Figure 1, Table S3). A further 41 genes were up‐regulated by disuse but down‐regulated by RET, but these failed to cluster to any functional terms (Figure 1, Table S3). Interestingly, among the top five ranked DE genes in both conditions (i.e. top 5 down‐regulated by RET and top 5 up‐regulated by disuse of inverted responses) was myostatin (MSTN), a key molecule involved in the regulation of skeletal muscle mass^62,63 (Figure 1).

Enlarge this image.

1 Figure. Comparison of gene‐level expression changes with RET vs. disuse. Venn diagram illustrates the degree of overlap between RET‐induced and disuse‐induced transcriptomic changes for all possible permutations, as determined via rank–rank hypergeometric overlap (RRHO) analysis. Outer boxes provide representative summaries of enriched Gene Ontology/Reactome Pathway terms for genes pertaining to each given scenario. The top 5 common and uniquely regulated genes when ranked by meta log2 fold‐change (as based on RRHO results) are provided within associated segment of the Venn diagram. Note: for concordant and discordant RRHO gene lists, only the intersection of top 5 ranking genes across each associated scenario is provided. ECM, extracellular matrix; RET, resistance exercise training.

Network‐level meta‐analysis revealed similar themes as the gene‐level approach. Both disuse and RET were characterized by separate up‐regulation of immune signalling networks, common up‐regulation of further immunity pathways and ECM organization networks, and inverse (down‐regulated by disuse and up‐regulated by RET) regulation of a mitochondrial function network (Figure 2A, Table S4). Additionally, network meta‐analysis revealed a divergent disuse vs. RET profile characterized by a disuse up‐regulated ‘translation‐related’ molecular network (M18) that was down‐regulated by RET (Figure 2A, Table S4). Next, we derived hub genes of differentially regulated consensus modules by screening for genes with robustly high intramodule membership, returning a base list of candidate regulatory molecules of muscle adaptation (708 and 319 hub genes in the young disuse and RET networks, respectively) (Table S5). For the three consensus modules with altered regulation in the disuse and RET networks (M4, M15, and M18), we further prioritized hub genes for those displaying a high intramodular hub status under both conditions. All three modules each had at least one gene with shared hub gene status across both respective networks, with the overlap reaching significance in two modules (M4 and M15) (Figures 2B–3D). Common hub genes identified in the divergent disuse vs. RET profile were as follows: COX4I1 (Cytochrome c oxidase subunit 4 isoform 1), ENDOG (Endonuclease G), MRPL12 (Mitochondrial Ribosomal Protein L12), NDUFV2 (NADH:Ubiquinone Oxidoreductase Core Subunit V2) and GOT2 (Glutamic‐Oxaloacetic Transaminase 2) for mitochondrial responses, and ZMYND11 (Zinc Finger MYND‐Type Containing 11) for translational regulation (Figures 2B and 3C, Table S5). We further screened our base candidate gene lists for module hub genes contained within the corresponding RRHO gene list (e.g. for a module up‐regulated only in the RET network vs. disuse network, we considered the RRHO gene list uniquely up‐regulated by RET vs. disuse, etc.) (Table S5). For consensus modules across the disuse and RET networks, COX4I1, ENDOG, and GOT2 were highlighted among inverted mitochondrial responses (Figure 2B), and COL1A1 (Collagen type 1 alpha 1), COL1A2 (Collagen type 1 alpha 1), COL5A2 (Collagen type 5 alpha 2), CTSK (Cathepsin K), DAB2 (Disabled homologue 2), EEF1A1 (Eukaryotic translation elongation factor 1 alpha 1), HTRA1 (HtrA Serine Peptidase 1), SPARC (Secreted protein acidic and rich in cysteine), TYROBP (TYRO protein tyrosine kinase binding protein) highlighted among the commonly regulated ECM/immune responses after disuse and RET (Figure 2D, Table S5).

Enlarge this image.

2 Figure. Consensus network analysis of RET vs. disuse responses in young muscle. Panel (A): Consensus modules shown are those differentially regulated by RET and/or disuse in young muscle. Red and blue shading denote significant up‐regulation and down‐regulation following each condition (vs. baseline), respectively. In all cases, functional summaries are representative of enriched Gene Ontology/Reactome Pathway terms for each given module. Also provided is the top ranked hub gene for each module per consensus network. Panels (B)–(D): Hub gene network visualizations for consensus modules concordantly or inversely regulated by RET and disuse in young muscle. Each visualization illustrates all corresponding hub genes of the given consensus module on a per condition basis, with dual‐coloured nodes thus representing genes that are overlapping consensus module hubs for both given conditions. Red borders (if any) illustrate the overlapping hub genes in each case that also appear among the corresponding list of RRHO genes for that particular scenario (e.g. up‐regulated by RET but down‐regulated by disuse). RET, resistance exercise training; RRHO, rank–rank hypergeometric overlap.

Enlarge this image.

3 Figure. Comparison of gene‐level expression changes in young vs. older muscle following RET. Panel (A): Venn diagrams depicting the degree of overlap between up‐regulated and down‐regulated genes post‐RET in young vs. older muscle, as based on RRHO analyses. Panel (B): Representative enriched Gene Ontology/Reactome Pathway terms for common and uniquely regulated genes post‐RET in young vs. older muscle. A number of genes enriched in a given term are provided within associated boxes of the heatmap. Strength of colour shading depicts the magnitude of enrichment significance, given by the negative log10 of that term's enrichment FDR P value (with darker shading analogous with a stronger FDR P value). Panel (C): Top 5 common and uniquely regulated genes (up‐regulated and down‐regulated) per age group, ranked by meta log2 fold‐change (as based on RRHO results). Lighter shading denotes differential regulation for that age group, with darker shading indicating gene is among the top 5 ranked by meta log2 fold‐change for a given scenario (e.g. uniquely up‐regulated post‐RET in young vs. older muscle). RET, resistance exercise training.

Virtually all genes up‐regulated by RET in older muscle were also up‐regulated in young muscle, but a substantial number of genes (n = 140) up‐regulated post‐RET in younger muscle were not similarly up‐regulated in older muscle (Figure 3A, Table S1). Genes up‐regulated by RET in young and older muscle were primarily involved in ECM organization, axon guidance, and the regulation of angiogenesis (Figure 3B, Table S3). The 140 genes uniquely up‐regulated post‐RET in younger muscle clustered to additional ECM organization processes, as well as immune‐related signalling pathways (Figure 3B, Table S3). Interestingly, 11 of the 140 uniquely up‐regulated young RET genes aligned to ECM organization, some of which have established roles in mechanical force transmission [integrin subunits ITGAM (Integrin Subunit Alpha M), ITGAE (Integrin Alpha E), and ITGB2 (Integrin Subunit Beta 2)], regenerative pathways [TNC (Tenascin C)], and collagen reinforcing processes [PLOD2 (Procollagen‐lysine, 2‐oxogluterate 5‐dioxygenase 2)] (Figure 3B, Table S3). Additionally, 28 of the 140 genes uniquely up‐regulated in young RET muscle aligned to the immune system, including several caspase proteolytic enzymes [CASP1 (Caspase 1) and CASP3 (Caspase 1)]. Within the top 5 ranked genes uniquely up‐regulated in young RET muscle, the highest‐ranked gene was the myosin binding protein MYBPH and also included two inflammation/immune‐related transcripts [CCL8 (Chemokine ligand 8) and CXCL10 (C‐X‐C Motif Chemokine Ligand 10)] (Figure 3C). Despite the clear young muscle‐specific ECM signature, several collagens were also commonly regulated in both young and older muscle following RET [COL1A1 (Collagen Type I Alpha 1 Chain), COL1A2 (Collagen Type I Alpha 2 Chain), COL3A1 (Collagen Type III Alpha 1 Chain), and COL4A2 (Collagen Type IV Alpha 1 Chain)] (Figure 3C). Substantially, fewer genes were down‐regulated by RET in both younger and older muscle (Figure 3A, Table S1), all of which failed to cluster to any functional terms (Figure 3B, Table S3).

At the network‐level, similar to gene‐level analysis, only young muscle displayed a post‐RET up‐regulation of genes comprising several immune signalling molecular networks and ECM organizational response (Figure 4A, Table S4). However, network analysis provided functional insight into down‐regulated RET genes, with both younger and older RET being characterized by the down‐regulation of similar ‘ubiquination/RNA processing’‐related molecular networks (M13) (Figure 4A, Table S4), the common hub genes of which were identified to be PWP1 (Periodic Typtophan Protein 1), PSMB1 (Proteasome 20S Subunit Beta 1) and RAF1 (c‐RAF) (Figure 4B, Table S5). Overlaying corresponding consensus module hub gene and RRHO gene lists further identified ARF3 (ADP‐ribosylation factor 3), ARPC1B (Actin Related Protein 2/3 Complex Subunit 1B), BPHL (Biphenyl Hydrolase Like), CAP1 (Cyclase Associated Actin Cytoskeleton Regulatory Protein 1), EMP1 (Epithelial Membrane Protein 1), HIF1A (Hypoxia‐Inducible Factor 1‐alpha), LST1 (Leukocyte Specific Transcript 1), RAB31 (Ras‐related protein Rab31), SERPINI1 (Serpin Family I Member 1), TUFM (Tu Translation Elongation Factor), and VIM (Vimentin) as prime candidates of RET‐induced muscle remodelling specifically in younger age (Table S5).

Enlarge this image.

4 Figure. Consensus network analysis of RET responses in young muscle vs. older muscle. Panel (A): Consensus modules shown are those differentially regulated by RET in young muscle and/or older muscle. Red and blue shading denote significant up‐regulation and down‐regulation following RET (vs. baseline), respectively. In all cases, functional summaries are representative of enriched Gene Ontology/Reactome Pathway terms for each given module. Also provided is the top ranked hub gene for each module per consensus network. Panel (B): Hub gene network visualization for M13; the consensus modules concordantly down‐regulated by RET in young and older muscle. Visualization illustrates all corresponding hub genes of the given consensus module on a per age basis, with dual‐coloured nodes thus representing genes that are overlapping consensus module hubs for both ages. Red borders (if any) illustrate the overlapping hub genes in each case that also appear among the corresponding list of RRHO genes for that particular scenario (i.e. commonly down‐regulated by RET in both young and older muscle). RET, resistance exercise training.

Disuse and RET elicit opposing muscle phenotypes (i.e. atrophy and hypertrophy, respectively),^37,64 thus one might anticipate opposing transcriptional responses. Consistent with this notion, we illustrate that declines in a subset of mitochondrial genes and increases in some translational regulation genes in response to disuse occur in a directly opposing manner following RET. However, we also find that the majority of gene changes induced by disuse and RET are entirely distinct from one another, implying muscle adaptations to unloading vs. loading are largely separate molecular processes. Thus, a key finding from our meta‐analysis is that the mechanisms of disuse are not simply the converse of RET and cannot be derived from studying muscle loading alone. These observations of RET failing to target all the molecular changes associated with disuse, might reflect reports that RET is incompletely effective at countering disuse atrophy¹⁸ and provides a robust molecular platform from which to determine the precise disuse‐RET relationship.

Mitochondria are critical organelles regulating muscle metabolism, health, and function.⁶⁵ Indeed, mitochondrial dynamics and/or respiratory capacity decrease during disuse⁶⁶ and increase during RET.⁶⁷ Our findings support and extend recent meta‐analyses reporting down‐regulated mitochondrial profiles in disuse alone,²⁸ by establishing an opposing mitochondrial profile between disuse and RET and establishing a putative molecular basis for divergent mitochondrial adaptations. We identified COX4I1 as one of the top genes in the divergent mitochondrial response to disuse and RET. COX4I1 is an isoform of electron transport chain complex IV, which is often used as a common marker of mitochondrial content⁶⁸ and mitochondrial oxidative metabolism.⁶⁹ Given that complex IV is a terminal electron acceptor for the proton motive force driving ATP production,⁷⁰ it is plausible that COX4I1 mechanistically contributes to enhanced mitochondrial respiratory capacity following RET.⁶⁷ GOT2, which acts within the malate–aspartate shuttle wherein NADH electrons are delivered to electron transport chain complex I,^71–73 was also identified as displaying a divergent response to disuse and RET. While a paucity of data exists in healthy humans, in type II diabetics (typically characterized by impaired mitochondrial function),^74,75 GOT2 expression is lower compared with control patients, which is also increased after endurance exercise training.⁷³ These observations suggest that: (i) prominent opposing transcriptional profiles could partially explain impaired (disuse) vs. improved (RET) mitochondrial respiratory function and/or dynamics; and (ii) interventions targeting mitochondria, such as electron donors, might reproduce some of the beneficial health effects of RET during disuse.

Genes involved in translational regulation were also identified as up‐regulated by disuse and down‐regulated by RET. While seemingly paradoxical given that translation is a key process driving MPS⁷⁶ and, therefore, hypertrophy,^77,78 RET‐induced decreases in translational regulation might reflect increased translational efficiency, as previously shown.^25,79 Such improved translational efficiency would reduce dependency on up‐regulation of proteins involved in the translation machinery to optimize anabolism. Corroborating this theory, a recent meta‐analysis (which had a significantly broader inclusion criteria and focused on differential gene analysis alone) also identified an inverted ‘mRNA metabolism’ signature between disuse and RET.²⁸ Thus, alternate regulation of translational machinery presents as a robust molecular feature of disuse vs. RET. We also identified MSTN as one of the top genes displaying an increase in response to disuse and a decrease in response to RET, supporting previous findings.²⁸ Myostatin is one of the best‐described regulators of muscle mass, playing a key role in muscle atrophy by synergistically impairing anabolic Akt signalling while activating the catabolic ubiquitin proteasome pathway to promote a negative net protein balance.⁶² Targeted analyses have previously reported lowered myostatin expression after RET and increased expression post‐immobilization in young, healthy volunteers.^80,81 These observations suggest that interventions targeting translational regulation might also be efficacious during disuse. Notably, inhibition of myostatin has very recently been shown to ameliorate muscle loss in rodents subject to disuse in spaceflight,⁸² suggesting further clinical trials are warranted, as previously suggested.^62,63

Physiologically, RET can induce muscle hypertrophy in youth³⁷ and in older age.⁸³ However, muscle growth responses to RET are suboptimal in older age (termed ‘anabolic resistance’ to RET),^79,84 albeit through incompletely defined mechanisms. In line with age‐related responses to loading in rodents,⁸⁵ we found the young RET response to be characterized by a much more substantial transcriptional response (i.e. 140 uniquely up‐regulated genes in young vs. only 17 in older muscle), that encapsulates most of the older RET profile. Thus, while insufficient data on protein metabolism and/or muscle mass within our analyses precludes functional associations between transcriptional changes and true anabolic resistance (i.e. blunted RET‐induced muscle protein synthesis/growth responses), our findings suggest that anabolic resistance to RET might be partly underpinned by a concomitant age‐related insensitivity to RET at the transcriptional level.

Remodelling of the ECM plays a pivotal role in muscle maintenance⁸⁶ and, accordingly, RET‐responsive genes commonly regulated in both age groups included ECM‐related collagens. Therefore, ageing muscle appears to retain capacity for RET‐induction of some individual ECM collagens, similarly to young people. However, muscular benefits of functional ECM are not limited to maintaining physical integrity via structural collagens. Indeed, mechanical forces exerted during exercise are transduced through the ECM into focal adhesion structures, for conversion to biochemical signals (‘mechanotransduction’^86,87). In this context, several genes uniquely up‐regulated in younger muscle that map to ECM‐related pathway terms also have established roles in mechanotransduction. These included integrin‐related genes (ITGAM, ITGB2, and ITGAE); ECM‐linked transmembrane components that mechanically mediate wide‐ranging cellular processes^88–90 including muscle metabolic health, structural integrity, and growth.⁹¹ Other mechanotransduction associated genes showing this trend included PLOD2, a collagen crosslinking molecule providing tensile integrity and collagen organization,⁹² and TNC, that supports muscle matrix remodelling⁹³ and displays abnormal muscle damage/repair responses in older muscle.⁹⁴ Network analysis corroborated young RET muscle‐specific mechanotransduction signatures, including overlapping young‐specific hub/RRHO features VIM (involved in hypertrophic signalling downstream of the integrin cascade⁹⁵) and ARPC1B (an Arp2/3 subunit required for normal integrin adhesome assembly⁹⁶). Lastly, the top up‐regulated gene in young, but not older RET responses was the myosin binding protein, MYBPH. While relatively uncharacterized, MYBPH up‐regulation is a feature of severe myopathy,^97,98 thus the reasons for increased MYBPH in healthy muscle RET responses is unclear. However, MYBPH also functions in the integrin associated Rho kinase 2 > cofilin2 pathway,^97,99 further implicating abnormal mechanotransduction in ageing muscle RET responses. Combined, these findings suggest some older muscle collagens respond appropriately to RET, but faltering ECM‐connected transmembrane components might functionally manifest as disorganized ECM and impair mechanically mediated remodelling/growth pathways. Targeting this force transduction axis might, therefore, represent a promising avenue for targeted therapeutic strategies.

Another functional class of diminished age‐related transcriptional responses to RET was inflammatory pathways. The presence of chronic low‐grade inflammation is well‐established in the aetiology of ageing muscle decline,¹⁰⁰ which would narrow the physiological inflammatory range and manifest as a loss of RET‐induced inflammation gene signatures, as observed herein. Interrogation of individual inflammatory‐responsive genes identified caspase activation as a central theme. Caspases stimulate essential proteolysis, removing non‐functional myofibrillar proteins to facilitate deposition of new proteins for hypertrophic adaptation,¹⁰¹ such that impaired caspase transcript activation in ageing could hinder effective sarcomere remodelling during RET. Moreover, two of the top up‐regulated genes in young RET muscle were inflammatory chemokine transcripts CCL8 and CXCL10, the abnormal regulation of which associates with ageing muscle regenerative decline (CCL8¹⁰²) and impaired macrophage > satellite‐cell‐mediated myogenesis (CXCL10¹⁰³). Overall, a consistent pattern emerges where failure to mount proper RET‐induced inflammatory responses could hinder ageing muscle regenerative capacity and growth responses.¹⁰⁴

Young muscle also exhibited consistent RET up‐regulation of genes involved in immune‐related signalling, which was absent in older muscle. It is well‐established that the immune system plays an integral role in RET‐induced muscle hypertrophy, in part through mediating satellite‐cell dependent muscle repair and regeneration.¹⁰⁵ These findings thus provide further support to the transcriptional theme that poorer RET adaptation of older muscle may be underpinned, at least in part, by age‐related impairments in muscle regenerative capacity.¹⁰⁶ Across the three immune‐specific network modules uniquely up‐regulated post‐RET in young muscle (M14, M20, and M28), we identified three hub genes that were also robustly up‐regulated at the gene‐level exclusively in young muscle following RET, namely, HIF1A, SERPINI1 (both M14), and LST1 (M20). The identification of the oxygen‐sensitive subunit of the HIF‐1 transcription factor, HIF1A, is notable for its expression in nearly all innate and adaptive immune populations¹⁰⁷ and its expression in most tissues including skeletal muscle.¹⁰⁸ HIF‐1 regulates the transcription of >100 genes, many of which promote angiogenesis to increase nutrient and oxygen transport capacity to muscle. Signalling downstream of HIF1A is also proposed to facilitate muscle regeneration/growth by driving proliferation of satellite cells.¹⁰⁹ As such, HIF1A could represent a promising candidate for understanding attenuated adaptations of older muscle to RET.

Variability across study protocols is a common caveat of meta‐analyses and, despite strict inclusion/exclusion criteria, the duration of the disuse and RET programmes differed between studies within our analyses. Nonetheless, a critical criterion was capturing atrophic/hypertrophic phenotypes to which transcriptional profiles could be associated. Minimum disuse/RET duration cut‐offs were, therefore, implemented that were sufficient to obtain muscle mass changes, as opposed to precisely matching intervention durations. It is also unfortunate that detailed physiological data (e.g. individual changes in muscle mass, strength and/or metabolism) was not sufficiently available across our analysed data sets to assess for molecular markers that associate with the magnitude of interindividual variability in physiological responses to disuse and RET, as previously reported for the ageing exercise response.^23,110 Achieving this would promote identification of candidate molecules that account for the well‐established variance in adaptive responses to disuse and/or exercise training^14,111,112 to identify the most promising therapeutic targets. Towards this end, future clinical studies would benefit from complementing health outcome measures with OMIC measurements to unlock the significant mechanistic potential of randomized controlled trials.

In summary, we provide the first integrated gene‐level and network‐level meta‐analytical approach to elucidate robust molecular signatures and candidate drivers of muscle adaptation to disuse and RET in the context of age. Our findings show that limited gene features display inverted profiles to disuse vs. RET, but for the most part, transcriptional responses to disuse and RET are entirely distinct, suggesting muscle loading/unloading are largely independent molecular processes. We also identify diminished expression of ECM‐linked mechanotransduction and inflammatory pathways as key features of ageing muscle RET adaptations. By overlaying gene‐level and network‐level feature selections, we further identify candidate therapeutic targets characterized by robust regulation (gene‐level) and interlinkage (network‐level), which may aid the mitigation of, or accelerate recovery from, muscle disuse atrophy and potentially wider‐ranging atrophic diseases (e.g. COX4I1, GOT2, and ENDOG), and/or optimize RET‐induced hypertrophy across the lifespan (e.g., HIF1A).