A relevant feature of aging is chronic low-grade inflammation, termed inflammaging, a key process promoting the development of all major age-related diseases. Senescent cells can acquire the senescence-associated (SA) secretory phenotype (SASP), characterized by the secretion of proinflammatory factors fuelling inflammaging. Cellular senescence is also accompanied by a deep reshaping of microRNA expression and by the modulation of mitochondria activity, both master regulators of the SASP. Here, we synthesize novel findings regarding the role of mitochondria in the SASP and in the inflammaging process and propose a network linking nuclear-encoded SA-miRNAs to mitochondrial gene regulation and function in aging cells. In this conceptual structure, SA-miRNAs can translocate to mitochondria (SA-mitomiRs) and may affect the energetic, oxidative, and inflammatory status of senescent cells. We discuss the potential role of several of SA-mitomiRs (i.e., let-7b, miR-1, miR-130a-3p, miR-133a, miR-146a-5p, miR-181c-5p, and miR-378-5p), using miR-146a as a proof-of-principle model. Finally, we propose a comprehensive, metabolic, and epigenetic view of the senescence process, in order to amplify the range of possible approaches to target inflammaging, with the ultimate goal of decelerating the aging rate, postponing or blunting the development of age-related diseases.
Fundaciò La MaratòUNIVPM1. Introduction
Aging constitutes the major risk factor for a variety of diseases with a high-incidence in the Western society. Type 2 diabetes (T2DM), metabolic syndrome, cardiovascular diseases (CVD), neurodegenerative diseases, and a plethora of common cancer types share aging as a common risk factor and therefore are often referred as aging-related diseases (ARDs). A pervasive feature of aging is a progressive and chronic state of systemic low-grade inflammation referred as inflammaging [1]. Major ARDs all share a common inflammatory background. The role of various inflammatory molecules—mainly tumor necrosis factor- (TNF-) α, interleukin- (IL-) 1b, IL-6, and transforming growth factor- (TGF-) β—in the promotion or exacerbation of a wide range of ARDs is increasingly emerging [1]. A number of mechanisms, pathways, and cell types have been shown to possibly contribute to inflammaging [2]. Initial hypothesis affirmed that inflammaging was mainly due to the long-lasting exposure to acute and chronic infections and the consequent life-long antigenic burden [3]. However, a long list of sterile potential sources of inflammatory molecules during both the cellular and the organismal aging process has been proposed [2].
The “old” free radical theory of aging (FRTA) states that organisms age because cells accumulate free radical-induced damage over time [4]. One interesting view that coupled FRTA with inflammaging is the oxi-inflammaging theory [5]. Accordingly, excessive or uncontrolled free radical production can induce an inflammatory response, and free radicals are themselves inflammation effectors. Oxidative metabolism at mitochondrial level is probably the major source of intracellular ROS production, which in turn represents a life-long-lasting stress. Aging-related ROS accumulation can contribute to telomere attrition [6], oxidative genomic damage [7], but can even act as signaling molecules in the development and maintenance of the senescent phenotype of the cell [8].
However, increasing evidence suggests oxidative stress is not per se a major determinant of aging; in fact, (i) deletion of many antioxidant enzymes increases rather than decreases life span and health span in various models of lower organisms and (ii) interventions with nonspecific antioxidant molecules do not reduce the incidence of ARDs [9–12]. On the contrary, (excessive) inflammation appears as a phenomenon that alone is sufficient to reduce both life span and fitness at old age [13, 14]. Thus, in aging cells, mitochondria-derived ROS and oxidative stress should be regarded for their role as proinflammatory triggers rather than damaging molecules that progressively disrupt cell components and cellular homeostasis alone.
MicroRNAs (miRNAs o miRs) are small noncoding RNAs involved in gene expression modulation, primarily silencing the mRNA target by binding its 3′-untranslated region (UTR) in the cytoplasm. However, increasing evidence proves that miRNAs can also exert posttranscriptional control when bound to a region outside of the 3′UTR and specifically within the 5′UTR and coding regions of the mRNA target. Moreover, in some cases, they activate transcription of a specific gene or stabilize the mRNA [15]. A single miRNA has the ability to regulate multiple targets and, in turn, a single mRNA can be targeted by several miRs [16]. Because of their regulatory functions, these small single strand RNAs are virtually implicated in all cellular processes. Over the years, a set of miRNAs with a well-recognized role in inflammaging, organismal aging, and development of ARDs has been defined [17–19]; examples are miR-146a-5p, miR-21, miR-126a-3p. Interestingly, recent studies suggest that a subset of these microRNAs can be found inside or indirectly affect the mitochondria (mitomiRs) [20]. They all have a nuclear encoding, but the existence of few small noncoding RNAs of mitochondrial origin is documented [21].
In this review, we explore the role of mitochondria in fostering “inappropriate” inflammatory responses during the aging process. We take advantage of cellular senescence as a fractal model to delineate the contribution of dysfunctional mitochondria to the inflammaging process since recent discoveries indicate that mitochondrial activities sustain or drive the inflammatory program of senescent cells. In addition, we explore mitochondria-linked mechanisms that can promote inflammaging independently of senescent cells. Finally, we explain the hypothesis that senescence-deregulated mitomiRs could directly affect mitochondrial function by targeting mtDNA, thus influencing the energetic, oxidative, and, in turn, inflammatory status of senescent cells, possibly playing a role in organismal aging.
2. Senescent Cells Fuel Inflammaging through the Senescence-Associated Secretory Phenotype
Recently, cellular senescence has been suggested as a relevant contributor to both the inflammaging and the aging process. This statement is mainly sustained by data on animal models showing that periodic clearance of senescent cells is accompanied by a mean life span and health span extension, coupled with a reduced inflammatory gene expression in multiple tissues, including kidney and the heart [22]. Senescent cells are characterized by a permanent cell cycle arrest, accompanied by morphological and gene expression changes [23]. They are usually identified by the high expression of proteins promoting cell cycle arrest, that is, p16, p21, and p53, the expression of DNA damage markers, that is, γH2AX phosphorylation, senescence-associated heterochromatin foci (SAHF), and telomere-associated DNA damage foci (TAF), and an increased activity of senescence-associated (SA) beta-galactosidase (β-Gal) [24]. Many stimuli can foster the acquisition of the senescent phenotype, for example, radiation, telomere erosion or damage, oncogenic stress, oxidative stress, and a number of DNA damaging agents [24–26]. In turn, senescent cells can acquire a proinflammatory phenotype named senescence-associated secretory phenotype (SASP). SASP consists in secretion of inflammatory cytokines, growth factors, and proteases [24]. Increased levels of SASP-related compounds have been reported in a number of human ARDs such as diabetes [27–29], atherosclerosis [30], and cancer [31]. More importantly, senescent cell accumulation in selected microenvironments—with a subsequent locally increased concentration of inflammatory cytokines—drives the pathogenesis of prototypical ARDs, that is, osteoarthritis and osteoporosis [32, 33].
A plethora of pathways and proteins has been implicated with inflammatory molecule secretion in senescent cells, for example, NF-κB, mTOR, and JAK [27, 34]. The classical SASP network relies on cell surface IL-1α as an essential cell-autonomous regulator of IL-6/IL-8 secretion [35]. However, recent findings indicate that an alternative inflammatory network is possible in senescent cells and that it is strictly dependent on mitochondrial function [36]. In addition, mitochondria appear as indispensable for the proinflammatory and the proaging features of senescent cells [37].
3. Senescent Cells Bear a Distinct Metabolic Phenotype, and Mitochondrial Dysfunction Is Partly Responsible for Their Proinflammatory Program
The senescence process is accompanied by metabolic changes within the cell. Many of the proteins important for the senescence process have a pivotal metabolic function [38]. As a result, senescent cells show a distinct metabolic phenotype. They bear an active metabolic state, maybe due to the acquisition of their peculiar secretory profile, which implies a high transcriptional activity and possibly a high metabolic demand. Senescent cells increase their glucose consumption, a phenomenon not coupled by an increased energetic state. In fact, senescent cells present a strong reduction in the amount of ATP in favor of adenosine diphosphate (ADP) and adenosine monophosphate (AMP) [39]. The increases of AMP/ATP and ADP/ATP ratios are sensed by and activate AMP-activated protein kinase (AMPK). [40]. AMPK activation, in turn, can induce senescence via p53 phosphorylation [41], whose activation has been associated with the promotion of glycolysis and oxidative phosphorylation, but even to downmodulation of glycolysis [42]. Furthermore, mTOR, one of the master regulators of the SASP but even of the senescence process itself [43], is strictly linked to nutrient availability, in particular to amino acids and glucose [44]. The same nutrients promote the activation of the transcription factor NF-κB, which plays a pivotal role in the inflammatory program of both immune cells and senescent cells. NF-κB governs energy homeostasis and metabolic adaptation by controlling the balance between glycolysis and respiration for energy provision [45]. Inhibition of NF-κB diminishes oxygen consumption and causes reprogramming to aerobic glycolysis (i.e., the Warburg effect) in mouse embryonic fibroblasts (MEFs) under basal culture conditions and induced necrosis on glucose starvation [45]. This NF-κB-dependent modulation of oxidative phosphorylation system (OXPHOS) involves the p53-mediated upregulation of mitochondrial synthesis of cytochrome c oxidase 2 (SCO2) [46], a subunit of complex IV of the mitochondrial electron transport chain [46–48].
The OXPHOS is composed of complexes I-IV (the electron transport chain, ETC), located within the mitochondrial inner membrane, and generates a gradient of H+ ions, which drives the ADP phosphorylation via the ATP synthase (FoF1 ATPase—complex V) [49, 50]. During aerobic respiration, a variable percentage of electrons leaks from the ETC, particularly from complexes I and III, prematurely reduces oxygen, and generates ROS [51]. This process is exacerbated in senescent cells and leads to an overproduction of ROS.
In “usual” senescence models, mitochondria do play a fundamental role. In fact, the absence of mitochondria reduced a spectrum of senescence effectors and phenotypes while preserving ATP production via enhanced glycolysis. A plethora of senescent-associated changes was dependent on mitochondria, particularly the proinflammatory phenotype. A DNA damage response (DDR) pathway converging on mTORC1 phosphorylation promoted PGC-1β-dependent mitochondrial biogenesis, contributing to ROS-mediated activation of the DDR and cell cycle arrest. Of note, the reduction in mitochondrial content in vivo, by either mTORC1 inhibition or PGC-1β deletion, prevented senescence in the aging mouse liver [37].
A recent paper clearly shows that mitochondrial dysfunction per se is sufficient to trigger a particular form of senescence accompanied by a peculiar proinflammatory program but independent from ROS and DNA damage. In this model, mitochondrial dysfunction-associated senescence (MiDAS) lacks an IL-1/NF-κB-dependent mechanism but would involve secretion of factors other than “classical” SASP factors. Major MiDAS-associated molecules are IL-10, TNF-α, and CCL27, which are secreted in a NF-κB-independent manner. This novel senescence phenotype would result from a reduced NAD+/NADH ratio, which in turn may cause AMPK and p53 activation [36]. Of note, treatment with a NAD+ precursor delays senescence of neural and melanocyte stem cells, increasing mouse life span [52].
4. Mitochondrial Dysfunction and Damage Promote Inflammaging through ROS- and PRR-Mediated Mechanisms
Life-long stimulation of the cells of innate immunity is still one of the more consistent hypotheses regarding the cellular origin of inflammaging. Beyond bacteria- and virus-derived products, a long list of endogenous molecules can promote this inflammatory program [2]. When misplaced, many “normal” cell components are recognized as damage-associated molecular patterns (DAMPs), which are recognized by pattern recognition receptors (PRRs), a large family of proteins that include toll-like receptors (TLRs) and NOD-like receptors (NLRs). During aging, PRRs are subjected to a prolonged and increased exposure to “stress” molecules that leads to chronic inflammatory responses.
Cell injury due to various stressors can trigger the release outside of the mitochondrial matrix of mitochondrial DNA (mtDNA), N-formyl peptides and lipids, such as cardiolipin, that can act as DAMPs by activating receptors of the innate immunity [2, 53] and the inflammasomes. In particular, there is a direct link between released oxidized mtDNA, activation of NLRP3, the most studied NLR, and caspase-1-mediated maturation of IL-1β and IL-18 [54, 55]. Accordingly, increasing evidence suggests an important role of inflammasomes in major ARDs [27]. For instance, the ablation of Nlrp3 gene in mice is able to attenuate inflammaging, thus increasing health span [13]. Once activated, inflammasome promotes the transmission of the senescence bystander cells via the release of inflammatory mediators [56]. In turn, mitochondria-derived ROS can activate the inflammasome, probably through the Trx/TXNIP complex, further linking mitochondrial function to low-grade inflammation [57]. Accordingly, ROS themselves can partly mediate the senescence “bystander effect”, that is, the transition of the senescent phenotype from a SC to neighbor cells [58].
MtDNA can even bind TLR9, which senses DNA of bacterial and viral origin [59]. Because of the prokaryotic origin of mitochondria, mtDNA contains a significant number of unmethylated CpG DNA repeats, similarly to bacterial genomes. This is sufficient to trigger TLR9 activation, leading to NF-κB signaling and increased expression of proinflammatory cytokines, such as TNF-α, IL-6, and IL-1β [60]. Further, mtDNA can even activate the cytosolic DNA sensor cyclic GMP-AMP synthase (cGAS) [61]. During an infection, DNA of microbial origin by binding to cGAS activates the cGAS/stimulator of interferon gene (STING) pathway thus triggering expression of inflammatory genes. Since DNA damage plays a prominent role in the development of the SASP [62], this pathway could be considered a mediator of inflammaging. Of note, even mitochondrial DNA (mtDNA) can bind the cytosolic cGAS, suggesting that mitochondria can play a major role in the senescence/SASP process in different manners [63, 64]. Notably, mtDNA can be released into extracellular fluids as a product of tissue damage and its plasma levels increase during aging and in selected ARDs [65], supporting the notion that circulating mtDNA is part of the systemic communicome initiating and propagating inflammaging [2].
Human mtDNA consists of circular, double-stranded, supercoiled molecules that are found in each cell in one up to 10,000 copies, depending on the bioenergetic requirements of the tissue and whose number declined with aging [66]. It encodes 13 subunits of respiratory chain complexes (in addition to 2 rRNAs and 22 tRNAs), which are transcribed and translated directly within the mitochondrion by its own gene expression system. These polypeptides include indispensable components of the complex I (7 subunits—ND1-ND6, ND4L), III (apocytochromeb), IV (3 subunits—COX I–III), and of F0/F1 ATP synthase (ATPase6 and ATPase8). The mitochondrial genome has a higher mutation rate than the nuclear genome; thus, its mutations accumulate during aging [67]. However, Greaves et al. have shown that selected pathogenic mutations increase and clonally expand during aging, but not the frequency of mutation [68]. Of note, mtDNA mutation accumulation in mouse tissues is influenced by the nuclear genetic background and correlates to neither cellular ROS content nor tissue senescence [69]. Interestingly, a number of genetic variants of the mtDNA, named haplogroups, have been identified. These, each containing functional single nucleotide polymorphism (SNPs), affect the oxidative metabolism of mitochondria, and several of them are associated to extreme longevity [70]. The interaction between nuclear genes and mtDNA has been proposed as a possible mechanism explaining a favorable/unfavorable inflammaging profile and consequently successful or unsuccessful aging [71]. Overall, these data suggest that any physiological SNP or pathogenic mutation in mtDNA could induce respiration alteration with a wide range of possible resulting (pathological) phenotype, affecting in turn inflammaging and ARD development [72, 73].
5. A Subgroup of MicroRNAs Targets mtDNA or Nuclear mRNA with Mitochondrial Function
The miRNA machinery is known to primarily act in the cytoplasm. miRNAs have also been detected in membrane-bound compartments, such as secreted vesicles and mitochondria [74]. Through different experimental approaches in different mammalian species, a number of studies have enabled identification of “signatures” of miRNAs located in the mitochondria. To date, they are summarized under a descriptive term: mitomiRs [75]. Indeed, this name includes nuclear-encoded miRNAs that translocate into the mitochondria organelle and target either mitochondrial or nuclear mRNA. Early studies on the subject are mostly descriptive to detect the presence of microRNAs within the mitochondrion. Kren and colleagues first detected 15 nuclear-encoded mitomiRs from rat livers that seemed to be involved in the modulation of genes associated with apoptosis, cell proliferation, and differentiation [76]. Bian et al. identified a pool of 20 miRs highly expressed in mitochondria of mice liver. Interestingly, mitochondria have a unique population of miRNAs, independent of the total cellular abundance of miRs and they may be involved in the regulation of mitochondria-specific and general cellular functions [77]. For the first time, in 2011, Barrey and coworkers showed the presence of pre-miRs inside mitochondria, postulating that some pre-miRNA sequences could be processed to mature miRNAs, which could be immediately active on the mitochondrial transcripts or exported in the cytosol in order to interfere with genomic mRNA [78]. Subsequently, other groups identified new mitomiRs from HeLa [79, 80], HEK293 [80], 143B cells [81], 206ρ° cells [82], and mouse heart [83] (Tables 1 and 2). The notion emerging is that mitochondria have a discrete and unique pool of mitomiRs; the association of miRs with mitochondria is species and cell type-specific [75].
List of miRs within human mitochondria.
Barrey et al. [78]
Bandiera et al. [20]
Sripada et al. [80]
Zhang et al. [60]
Mercer et al. [81]
Dasgupta et al. [82]
Human skeletal/muscular cells
HeLa cells
HeLa/HEK293
Skeletal muscle
143B cells
206 ρ° cells
let-7b
miR-193b
miR-328-5p
let-7b-5p
miR-1
miR-16
miR-181c
let-7g
miR-197
miR-494-3p
let-7g-5p
miR-146a
mR-146a
miR-19b
miR-199a-5p
miR-513a-5p
miR-107
miR-103
miR-20a
miR-210
miR-638
miR-181a-5p
miR-23a
miR-221
miR-1201
miR-221-5p
miR-23b
miR-324-3p
miR-1246
miR-320a
miR-24
miR-324-5p
miR-1275
miR-494-3p
miR-34a
miR-365
miR-1908
miR-1275
miR-92a
miR-423-3p
miR-1972
miR-1973
miR-93
miR-484
miR-1973
miR-103
miR-486-5p
miR-1974
miR-106a
miR-490-3p
miR-1977
miR-107
miR-503
miR-1798
miR-125b
miR-501-3p
miR-125a-5p
miR-532-3p
miR-127-3p
miR-542-5p
miR-133b
miR-574-3p
miR-133a
miR-598
miR-134
miR-720
miR-149
miR-1974
miR-151-5p
miR-1979
miR-181a
miR-675∗
List of miRs within mouse and rat mitochondria.
Bian et al. [77]
Jagannathan et al. [83]
Kren et al. [76]
Das et al. [84]
Mouse liver
Mouse heart
Rat liver
Rat cardiomyocytes
let-7f-5p
let-7b
miR-151-3p
miR-1934-3p
miR-130a
miR-574-5p
miR-130a-3p
miR-181c
miR-101-5p
let-7a
miR-203-3p
miR-211-3p
miR-497
miR-148a-3p
miR-130b-3p
miR-122-5p
let-7c
miR-212-3p
miR-3072-3p
miR-188-5p
miR-200c-3p
miR-140-5p
miR-181b-5p
let-7f
miR-5112
miR-320-3p
miR-3098-5p
miR-300-3p
miR-320-3p
miR-181d-5p
miR-149-3p
miR-135a-1-3p
miR-1199-5p
miR-30c-1-3p
miR-181b-5p
miR-494-3p
miR-188-5p
miR-149-5p
miR-721
miR-5108
miR-712
miR-5131
miR-671
miR-29a-3p
miR-23b
miR-125a-3p
miR-375-3p
miR-3102-5p
miR-29c-3p
miR-1
miR-1904
miR-203-3p
miR-877-3p
miR-361-5p
miR-29a
miR-1894-3p
miR-126-3p
miR-3963
miR-432
miR-125b-5p
miR-3102-5p
miR-26a
miR-341-3p
miR-494-3p
miR-29b
miR-494
miR-23a
miR-342-3p
miR-680
miR-709
miR-1939
miR-27b
miR-423-3p
miR-689
miR-22
miR-3470a
miR-99a
miR-3081-5p
miR-690
miR-24
miR-144
miR-139-3p
miR-1895
miR-705
miR-680
miR-3107
miR-378
miR-720
miR-711
miR-21
miR-451
miR-27a
miR-1897-5p
miR-721
miR-133a-3p
miR-1224
miR-29c
miR-3085-3p
miR-720
miR-133a-5p
miR-2861
miR-30a
miR-3092
miR-762
miR-133b
miR-2137
miR-30d
miR-2145
miR-805
miR-128-3p
miR-1937c
miR-30e
miR-652-5p
miR-671-5p
miR-3095-3p
miR-466i-5p
miR-3082-5p
miR-1187
miR-1982-5p
miR-1937b
miR-705
miR-483-5p
miR-466h-3p
6. MitomiRs Targeting Mitochondrial Genome Are Deregulated by Organismal Aging or Cellular Senescence
Mitochondria maintain and express their own genome that may be regulated by microRNAs. As mtDNA encodes for 13 subunits of the electron transport chain, their regulation by mitomiRs may have profound effects on ATP synthesis and ultimately may influence the whole mitochondrial function.
Bioinformatics analysis suggested that mitomiRs can target various mitochondrial transcripts: several potential mitochondrial targets for let-7b (ATP6, ATP8, COX2, and ND5) [78] as well as for miR-146a-5p and miR-181c-5p [82] have been described; miR-133a was predicted to target ND1 [78], whereas miR-130a-3p targets COX3 [76]. Using ingenuity pathway analysis (IPA) software to analyze mtDNA targets, Jagannathan et al. observed potential interactions between all 13 mitochondrial genome-encoded electron transport chain proteins with mitomiRs. The functional significance of a specific miRNA in heart-derived mitochondria was demonstrated for the first time by Das and colleagues: miR-181c-5p originates from the nuclear genome, is processed in the cytosol, and translates to the mitochondria, where it regulates mitochondrial energy metabolism by targeting mt-COX1 mRNA. Overexpression of miR-181c-5p results in a loss of mt-COX1 protein, resulting in an imbalance among the mitochondria-encoded subunits in complex IV, thus promoting ROS generation. Perturbations induced by miR-181c-5p could have important consequences in myocardial pathophysiology [84]. More recently, in vivo administration of miR-181c-5p in rats confirmed these data leading to complex IV dysfunction, altered mitochondrial metabolism, and ROS generation, ultimately promoting heart failure [85].
On the contrary, when miR-1 localizes into mitochondria, it promotes mitochondrial translation of ND1 and COX1 mtDNA-encoded transcripts while repressing its nuclear DNA-encoded targets in the cytoplasm. In this way, miR-1 enhances protein synthesis and ATP production, required for muscle cell differentiation [74]. This study suggests the possibility that the localization and relative abundance of a specific microRNA in the cytoplasm and mitochondria determines its different role in the regulation of specific targets and in the coordination of mitochondrial activities [86].
Another study showed that miR-1, together with other two mitomiRs, miR-133a and let-7b, is essential for adult skeletal muscle differentiation and maintenance; for this reason, they are called myomiRs [87, 88]. Muscles contain a high mitochondrial content, in order to provide massive demand of ATP for movement, postural maintenance, and respiration. During aging, skeletal muscle mitochondria revealed a progressive decline in respiratory chain function, a phenomenon associated with insulin resistance and type 2 diabetes mellitus [89]. These miRs seem to modulate some key proteins of OXPHOS complexes, so their deregulation may affect ETC functionality. Of note, some of these myomiRs are released in circulation after physical exercise [90]. Physical activity is associated to a plethora of beneficial effects and the underlying mechanisms are not fully understood. For instance, high-intensity aerobic interval exercise is associated with wide proteomic changes in the muscle of old subjects, with evident phenotypic gains in muscle mitochondrial function. Noticeable, mRNA expression changes do not overlap protein expression changes, suggesting that enhanced protein translation, but possibly even epigenetic mechanisms influence such positive adaptation [91].
Another remarkable study showed a redistribution of mitomiRs in the diabetic heart. Cardiac tissue is rich in mitochondria with spatially distinct subpopulations: subsarcolemmal mitochondria (SSM), located beneath the cell membrane, and interfibrillar mitochondria (IFM), situated between the myofibrils. MitomiRs were differentially regulated in the two mitochondrial subpopulations in diabetes relative to control. In addition, mitomiR-378-3p is highly expressed in diabetic IFM (versus IFM control) and targets mt-ATP6 with a concomitant reduction in the functionality of the ATP synthase. In vivo, miR-378-3p antagomir delivery led to the preservation of ATP6 protein levels in diabetic IFM, similar to nondiabetic control. Interestingly, miR-378-3p antagomir resulted in an increase of ATP synthase activity, which was significantly decreased in diabetic [83]. MiR-378-3p is located in the first intron of the peroxisome proliferator-activated receptor gamma (Ppargc1b) gene, which encodes for PGC-1β. PGC-1β is preferentially expressed in tissues with relatively high mitochondrial content, and miR-378-3p is coexpressed with its host gene and seems to counterbalance the metabolic actions of PGC-1β. Mice genetically lacking miR-378-3p exhibit enhanced mitochondrial fatty acid metabolism and elevated oxidative capacity of insulin-target tissues [92], proving its key role in mitochondrial respiration.
According to their role in age-related diseases, for example, heart failure and diabetes [18–20, 74, 85, 93], many mitomiRs have been described to be deregulated during organismal and cellular aging (SA-miRs). Thus, it has been hypothesized that SA-miRs and mtDNA-targeting mitomiRs play a major role in the mitochondrial dysfunction observed in both cellular senescence and the inflammaging process [94]. Notably, among all mitomiRs targeting mitochondrial genome, a subset of miRs has been associated to inflammatory processes, that is, miR-130a-3p [95] or to both inflammation and aging, that is, let-7b [96, 97], miR-146a-5p [98], miR-181c-5p [99, 100], miR-133a [101, 102], and miR-1 [103, 104].
MiR-146a-5p is one of the best-characterized miRNAs involved in both SASP and inflammaging. NF-κB activation initiates the transcription of proinflammatory cytokines and of miR-146, which in turn directly targets IRAK1 and TRAF6, two key adaptor molecules in the TLR/NF-κB pathway, trying to switch off the proinflammatory signal at the end of inflammatory response. While this mechanism efficiently regulates immune system responses [105], in senescent cells, its increase is insufficient to ameliorate the SASP [93, 106, 107]. As each miRNA has multiple targets, sustained and chronic expression of miR-146a-5p in senescent cells could affect many pathways other than the proinflammatory ones. In fact, mir-146a-5p has the mitochondrial encoded proteins ND1, ND2, ND4, ND5, and ND6, as well as ATP8 as putative and potential targets, suggesting that senescence may affect epigenetically the expression and function of complexes I and V. Of note, complex I is the most relevant one in determining ROS production in dysfunctional mitochondria [108]. In addition, miR-146a-5p can even target superoxide dismutase- (SOD-) 2, a major mitochondrial antioxidant enzyme [109] and Bcl-2, a known determinant of mitochondrial dynamics, involved in the regulation of mitochondrial fusion and fission [94]. Thus, it is easy to speculate that senescence-regulated miRNAs, which are transcribed with the goal of ameliorating inflammation, could also influence mitochondrial behavior, with a still unknown positive or negative effect on mitochondrial oxidative and energetic functions.
7. Conclusions and Future Prospects
Recent discoveries suggest that mitochondria are major determinants of aging. Senescent cells carry dysfunctional mitochondria, which are partly responsible for their proinflammatory program. Aged, dysfunctional, or damaged mitochondria can promote inflammaging even through continuous immune system stimulation. In the complex picture of the dynamic interaction between nucleus and mitochondria, microRNAs should be considered as new, relevant players. Despite the few data available on this specific topic, emerging evidence and bioinformatics studies indicate that miRNAs of nuclear origin profoundly affect mitochondrial function. This phenomenon seems to be of particular importance for the aging process, considering that many senescence-associated miRNAs have got or may have targets within mtDNA. Overall, a comprehensive view of the epigenetic and nonepigenetic mechanisms triggered by the senescence process is of importance to understand the overall phenotype of aged cells, which behave differently from a transcriptional, metabolic, energetic, and oxidative point of view (Figure 1). Such holistic view could eventually extend the spectrum of possibilities to target senescent cells and, more in general, the aging process, especially considering that miRNA-based, epigenetic therapies are already in progress in order to functionally reprogram target cells to a desired phenotype.
Potential effect of senescence-associated epigenetic rearrangement on mitochondrial function. Different damaging stimuli can induce senescence. Senescent cells bear peculiar metabolism and gene expression, which underlie a chronic proinflammatory program (SASP). This is accompanied by changes in the expression of a number of senescence-associated microRNAs (SA-miRNAs). Dysfunctional mitochondria play a major role in the promotion of the SASP. In turn, several SA-miRNAs can translocate to mitochondria (mitomiRs) and could target a plethora of mRNA with an important role within mitochondria, including transcripts derived from mitochondrial DNA (mtDNA). In this framework, we hypothesize a major role for SA-mitomiRs in determining the energetic, metabolic, and inflammatory status of senescent cells, mainly through their ability to regulate mtDNA-derived proteins.
Cutting-edge technologies such as ultradeep sequencing and single-cell RNAseq will help to disentangle the importance of SA-mitomiRs in the aging process at both cellular and population level thus accumulating knowledge to better define dynamics underlying the epigenetic regulation of mitochondrial function in healthy aging and major ARDs.
Conflicts of Interest
The authors have no conflicts of interests.
Authors’ Contributions
All authors contributed significantly to the manuscript.
Acknowledgments
This work was supported by grants from UNIVPM to MRR and from Fundaciò La Maratò de TV3 to AC.
FranceschiC.CampisiJ.Chronic inflammation (inflammaging) and its potential contribution to age-associated diseases201469Supplement 1S4S910.1093/gerona/glu0572-s2.0-84900988267FranceschiC.GaragnaniP.VitaleG.CapriM.SalvioliS.Inflammaging and ‘Garb-aging’201728319921210.1016/j.tem.2016.09.0052-s2.0-8500595902127789101FranceschiC.BonafèM.ValensinS.OlivieriF.De LucaM.OttavianiE.De BenedictisG.Inflamm-aging: an evolutionary perspective on immunosenescence20009082442541091196310.1111/j.1749-6632.2000.tb06651.xHarmanD.Aging: a theory based on free radical and radiation chemistry195611329830010.1093/geronj/11.3.29813332224De la FuenteM.MiquelJ.An update of the oxidation-inflammation theory of aging: the involvement of the immune system in oxi-inflamm-aging200915263003302610.2174/1381612097890581102-s2.0-7044943138719754376SerraV.GruneT.SitteN.SaretzkiG.von ZglinickiT.Telomere length as a marker of oxidative stress in primary human fibroblast cultures20009083273301091197810.1111/j.1749-6632.2000.tb06666.xHegdeM. L.HegdeP. M.ArijitD.BoldoghI.MitraS.Human DNA glycosylase NEIL1’s interactions with downstream repair proteins is critical for efficient repair of oxidized DNA Base damage and enhanced cell survival20122456457810.3390/biom204056423926464PassosJ. F.NelsonG.WangC.RichterT.SimillionC.ProctorC. J.MiwaS.OlijslagersS.HallinanJ.WipatA.SaretzkiG.RudolphK. L.KirkwoodT. B.von ZglinickiT.Feedback between p21 and reactive oxygen production is necessary for cell senescence2010634710.1038/msb.2010.52-s2.0-7714916481120160708PérezV. I.BokovA.Van RemmenH.MeleJ.RanQ.IkenoY.RichardsonA.Is the oxidative stress theory of aging dead?20091790101005101410.1016/j.bbagen.2009.06.0032-s2.0-6994909118219524016SessoH. D.ChristenW. G.BubesV.SmithJ. P.MacFadyenJ.SchvartzM.MansonJ. E.GlynnR. J.BuringJ. E.GazianoJ. M.Multivitamins in the prevention of cardiovascular disease in men: the physicians’ health study II randomized controlled trial2012308171751176010.1001/jama.2012.148052-s2.0-8486830716223117775RautiainenS.LeeI. M.RistP. M.GazianoJ. M.MansonJ. E.BuringJ. E.SessoH. D.Multivitamin use and cardiovascular disease in a prospective study of women2015101114415210.3945/ajcn.114.0883102-s2.0-8491961934025527758BjelakovicG.NikolovaD.GluudC.Antioxidant supplements and mortality2014171404410.1097/MCO.00000000000000092-s2.0-8489099494224241129YoumY. H.GrantR. W.McCabeL. R.AlbaradoD. C.NguyenK. Y.RavussinA.PistellP.NewmanS.CarterR.LaqueA.MünzbergH.RosenC. J.IngramD. K.SalbaumJ. M.DixitV. D.Canonical Nlrp3 inflammasome links systemic low-grade inflammation to functional decline in aging201318451953210.1016/j.cmet.2013.09.0102-s2.0-8488516722224093676JurkD.WilsonC.PassosJ. F.OakleyF.Correia-MeloC.GreavesL.SaretzkiG.FoxC.LawlessC.AndersonR.HewittG.PenderS. L.FullardN.NelsonG.MannJ.van de SluisB.MannD. A.von ZglinickiT.Chronic inflammation induces telomere dysfunction and accelerates ageing in mice20142417210.1038/ncomms51722-s2.0-8490348554224960204VasudevanS.TongY.SteitzJ. A.Switching from repression to activation: microRNAs can up-regulate translation200731858581931193410.1126/science.11494602-s2.0-3674902690618048652BrevingK.Esquela-KerscherA.The complexities of microRNA regulation: mirandering around the rules20104281316132910.1016/j.biocel.2009.09.0162-s2.0-7795438572919800023OlivieriF.RippoM. R.MonsurròV.SalvioliS.CapriM.ProcopioA. D.FranceschiC.MicroRNAs linking inflamm-aging, cellular senescence and cancer20131241056106810.1016/j.arr.2013.05.0012-s2.0-8488819775323688930OlivieriF.SpazzafumoL.BonafèM.RecchioniR.PrattichizzoF.MarcheselliF.MicolucciL.MensàE.GiulianiA.SantiniG.GobbiM.LazzariniR.BoemiM.TestaR.AntonicelliR.ProcopioA. D.BonfigliA. R.MiR-21-5p and miR-126a-3p levels in plasma and circulating angiogenic cells: relationship with type 2 diabetes complications2015634353723538210.18632/oncotarget.61642-s2.0-8494688783826498351PrattichizzoF.GiulianiA.De NigrisV.PujadasG.CekaA.La SalaL.GenoveseS.TestaR.ProcopioA. D.OlivieriF.CerielloA.Extracellular microRNAs and endothelial hyperglycaemic memory: a therapeutic opportunity?201618985586710.1111/dom.126882-s2.0-8497758924627161301BandieraS.HaneinS.LyonnetS.Henrion-CaudeA.Mitochondria as novel players of the cellular RNA interference201128638, article le1910.1074/jbc.L111.2402592-s2.0-8005302047221926178ShindeS.BhadraU.A complex genome-microRNA interplay in human mitochondria201520151320638210.1155/2015/2063822-s2.0-8493307368525695052BakerD. J.WijshakeT.TchkoniaT.LeBrasseurN. K.ChildsB. G.van de SluisB.KirklandJ. L.van DeursenJ. M.Clearance of p16Ink4a-positive senescent cells delays ageing-associated disorders2011479737223223610.1038/nature106002-s2.0-8085513877522048312BeauséjourC. M.KrtolicaA.GalimiF.NaritaM.LoweS. W.YaswenP.CampisiJ.Reversal of human cellular senescence: roles of the p53 and p16 pathways20032216421242221291291910.1093/emboj/cdg4172-s2.0-0041966056ChildsB. G.DurikM.BakerD. J.van DeursenJ. M.Cellular senescence in aging and age-related disease: from mechanisms to therapy201521121424143510.1038/nm.40002-s2.0-8494955589726646499HewittG.JurkD.MarquesF. D.Correia-MeloC.HardyT.GackowskaA.AndersonR.TaschukM.MannJ.PassosJ. F.Telomeres are favoured targets of a persistent DNA damage response in ageing and stress-induced senescence2012370810.1038/ncomms17082-s2.0-8485935238522426229FumagalliM.RossielloF.ClericiM.BarozziS.CittaroD.KaplunovJ. M.BucciG.DobrevaM.MattiV.BeausejourC. M.HerbigU.LongheseM. P.d'Adda di FagagnaF.Telomeric DNA damage is irreparable and causes persistent DNA-damage-response activation201214435536510.1038/ncb24662-s2.0-8485937298622426077PrattichizzoF.De NigrisV.La SalaL.ProcopioA. D.OlivieriF.CerielloA.“Inflammaging” as a druggable target: a senescence-associated secretory phenotype—centered view of type 2 diabetes2016201610181032710.1155/2016/18103272-s2.0-8497531830227340505PalmerA. K.TchkoniaT.LeBrasseurN. K.ChiniE. N.XuM.KirklandJ. L.Cellular senescence in type 2 diabetes: a therapeutic opportunity20156472289229810.2337/db14-18202-s2.0-8496207968326106186ZhuY.ArmstrongJ. L.TchkoniaT.KirklandJ. L.Cellular senescence and the senescent secretory phenotype in age-related chronic diseases201417432432810.1097/MCO.00000000000000652-s2.0-8490229736724848532ChildsB. G.BakerD. J.WijshakeT.ConoverC. A.CampisiJ.van DeursenJ. M.Senescent intimal foam cells are deleterious at all stages of atherosclerosis2016354631147247710.1126/science.aaf66592-s2.0-8499273036327789842CampisiJ.Aging, cellular senescence, and cancer201375168570510.1146/annurev-physiol-030212-1836532-s2.0-8487363853223140366JeonO. H.KimC.LabergeR. M.DemariaM.RathodS.VasserotA. P.ChungJ. W.KimD. H.PoonY.DavidN.BakerD. J.van DeursenJ. M.CampisiJ.ElisseeffJ. H.Local clearance of senescent cells attenuates the development of post-traumatic osteoarthritis and creates a pro-regenerative environment201723677578110.1038/nm.432428436958FarrJ. N.XuM.WeivodaM. M.MonroeD. G.FraserD. G.OnkenJ. L.NegleyB. A.SfeirJ. G.OgrodnikM. B.HachfeldC. M.LeBrasseurN. K.DrakeM. T.PignoloR. J.PirtskhalavaT.TchkoniaT.OurslerM. J.KirklandJ. L.KhoslaS.Targeting cellular senescence prevents age-related bone loss in mice20172391072107910.1038/nm.438528825716XuM.TchkoniaT.DingH.OgrodnikM.LubbersE. R.PirtskhalavaT.WhiteT. A.JohnsonK. O.StoutM. B.MezeraV.GiorgadzeN.JensenM. D.LeBrasseurN. K.KirklandJ. L.JAK inhibition alleviates the cellular senescence-associated secretory phenotype and frailty in old age201511246E6301E631010.1073/pnas.15153861122-s2.0-8496639760326578790OrjaloA. V.BhaumikD.GenglerB. K.ScottG. K.CampisiJ.Cell surface-bound IL-1α is an upstream regulator of the senescence-associated IL-6/IL-8 cytokine network200910640170311703610.1073/pnas.09052991062-s2.0-7035012510619805069WileyC. D.VelardeM. C.LecotP.LiuS.SarnoskiE. A.FreundA.ShirakawaK.LimH. W.DavisS. S.RamanathanA.GerencserA. A.VerdinE.CampisiJ.Mitochondrial dysfunction induces senescence with a distinct secretory phenotype201623230331410.1016/j.cmet.2015.11.0112-s2.0-8495795242926686024Correia-MeloC.MarquesF. D.AndersonR.HewittG.HewittR.ColeJ.CarrollB. M.MiwaS.BirchJ.MerzA.RushtonM. D.CharlesM.JurkD.TaitS. W.CzapiewskiR.GreavesL.NelsonG.Bohlooly-YM.Rodriguez-CuencaS.Vidal-PuigA.MannD.SaretzkiG.QuaratoG.GreenD. R.AdamsP. D.von ZglinickiT.KorolchukV. I.PassosJ. F.Mitochondria are required for pro-ageing features of the senescent phenotype201635772474210.15252/embj.2015928622-s2.0-8495906503726848154WileyC. D.CampisiJ.From ancient pathways to aging cells-connecting metabolism and cellular senescence20162361013102110.1016/j.cmet.2016.05.0102-s2.0-8497551026627304503ZwerschkeW.MazurekS.StöcklP.HütterE.EigenbrodtE.Jansen-DürrP.Metabolic analysis of senescent human fibroblasts reveals a role for AMP in cellular senescence2003376240341110.1042/bj200308162-s2.0-0346256784HardieD. G.CarlingD.CarlsonM.The AMP-activated/SNF1 protein kinase subfamily: metabolic sensors of the eukaryotic cell?199867182185510.1146/annurev.biochem.67.1.8212-s2.0-0031717105JonesR. G.PlasD. R.KubekS.BuzzaiM.MuJ.XuY.BirnbaumM. J.ThompsonC. B.AMP-activated protein kinase induces a p53-dependent metabolic checkpoint200518328329310.1016/j.molcel.2005.03.0272-s2.0-2084444923815866171Puzio-KuterA. M.The role of p53 in metabolic regulation20112438539110.1177/19476019114097382-s2.0-8005303616521779507LabergeR. M.SunY.OrjaloA. V.PatilC. K.FreundA.ZhouL.CurranS. C.DavalosA. R.Wilson-EdellK. A.LiuS.LimbadC.DemariaM.LiP.HubbardG. B.IkenoY.JavorsM.DesprezP. Y.BenzC. C.KapahiP.NelsonP. S.CampisiJ.MTOR regulates the pro-tumorigenic senescence-associated secretory phenotype by promoting IL1A translation20151781049106110.1038/ncb31952-s2.0-8493875187326147250ZhangX. D.QinZ. H.WangJ.The role of p53 in cell metabolism20103191208121210.1038/aps.2010.1512-s2.0-7795639195720729871MauroC.LeowS. C.AnsoE.RochaS.ThotakuraA. K.TornatoreL.MorettiM.De SmaeleE.BegA. A.TergaonkarV.ChandelN. S.FranzosoG.NF-κB controls energy homeostasis and metabolic adaptation by upregulating mitochondrial respiration201113101272127910.1038/ncb23242-s2.0-8005353960521968997LearyS. C.Redox regulation of SCO protein function: controlling copper at a mitochondrial crossroad20101391403141610.1089/ars.2010.31162-s2.0-7795708527120136502MatobaS.KangJ. G.PatinoW. D.WraggA.BoehmM.GavrilovaO.HurleyP. J.BunzF.HwangP. M.p53 regulates mitochondrial respiration200631257801650165310.1126/science.11268632-s2.0-3374514929116728594TornatoreL.ThotakuraA. K.BennettJ.MorettiM.FranzosoG.The nuclear factor kappa B signaling pathway: integrating metabolism with inflammation2012221155756610.1016/j.tcb.2012.08.0012-s2.0-8486786747722995730ReidR. A.MoyleJ.MitchellP.Synthesis of adenosine triphosphate by a protonmotive force in rat liver mitochondria1966212257258597011410.1038/212257a02-s2.0-0014018142BraticI.TrifunovicA.Mitochondrial energy metabolism and ageing201017976-796196710.1016/j.bbabio.2010.01.0042-s2.0-7795373376220064485LiuY.FiskumG.SchubertD.Generation of reactive oxygen species by the mitochondrial electron transport chain200280578078710.1046/j.0022-3042.2002.00744.x2-s2.0-003631902111948241ZhangH.RyuD.WuY.GarianiK.WangX.LuanP.D'AmicoD.RopelleE. R.LutolfM. P.AebersoldR.SchoonjansK.MenziesK. J.AuwerxJ.NAD+ repletion improves mitochondrial and stem cell function and enhances life span in mice201635262921436144310.1126/science.aaf26932-s2.0-8496503427527127236FangC.WeiX.WeiY.Mitochondrial DNA in the regulation of innate immune responses201671111610.1007/s13238-015-0222-92-s2.0-8495436750126498951ZhouR.YazdiA. S.MenuP.TschoppJ.A role for mitochondria in NLRP3 inflammasome activation2011469732922122510.1038/nature096632-s2.0-7865139323921124315NakahiraK.HaspelJ. A.RathinamV. A.LeeS. J.DolinayT.LamH. C.EnglertJ. A.RabinovitchM.CernadasM.KimH. P.FitzgeraldK. A.RyterS. W.ChoiA. M.Autophagy proteins regulate innate immune responses by inhibiting the release of mitochondrial DNA mediated by the NALP3 inflammasome201112322223010.1038/ni.19802-s2.0-7995164203221151103AcostaJ. C.BanitoA.WuestefeldT.GeorgilisA.JanichP.MortonJ. P.AthineosD.KangT. W.LasitschkaF.AndrulisM.PascualG.MorrisK. J.KhanS.JinH.DharmalingamG.SnijdersA. P.CarrollT.CapperD.PritchardC.InmanG. J.LongerichT.SansomO. J.BenitahS. A.ZenderL.GilJ.A complex secretory program orchestrated by the inflammasome controls paracrine senescence201315897899010.1038/ncb27842-s2.0-8488139920623770676LaneT.FlamB.LockeyR.KolliputiN.TXNIP shuttling: missing link between oxidative stress and inflammasome activation201345010.3389/fphys.2013.000502-s2.0-8487947807023520439NelsonG.KucheryavenkoO.WordsworthJ.von ZglinickiT.The senescent bystander effect is caused by ROS-activated NF-κB signalling2017In press2883784510.1016/j.mad.2017.08.005LamphierM. S.SiroisC. M.VermaA.GolenbockD. T.LatzE.TLR9 and the recognition of self and non-self nucleic acids200610821314310.1196/annals.1348.0052-s2.0-33845636049ZhangJ. Z.LiuZ.LiuJ.RenJ. X.SunT. S.Mitochondrial DNA induces inflammation and increases TLR9/NF-κB expression in lung tissue201433481782410.3892/ijmm.2014.16502-s2.0-8489957036524535292YuanL.MaoY.LuoW.WuW.XuH.WangX. L.ShenY. H.Palmitic acid dysregulates the Hippo-YAP pathway and inhibits angiogenesis by inducing mitochondrial damage and activating the cytosolic DNA sensor cGAS-STING-IRF3 signaling mechanism201729236150021501510.1074/jbc.M117.80400528698384GlückS.GueyB.GulenM. F.WolterK.KangT. W.SchmackeN. A.BridgemanA.RehwinkelJ.ZenderL.AblasserA.Innate immune sensing of cytosolic chromatin fragments through cGAS promotes senescence20171991061107010.1038/ncb358628759028de GalarretaM. R.LujambioA.DNA sensing in senescence20171991008100910.1038/ncb360328855731YangH.WangH.RenJ.ChenQ.ChenZ. J.cGAS is essential for cellular senescence201711423E4612E462010.1073/pnas.170549911428533362LamN. Y.RainerT. H.ChiuR. W.JoyntG. M.LoY. M.Plasma mitochondrial DNA concentrations after trauma200450121321610.1373/clinchem.2003.0257832-s2.0-164253345914709653StoccoD. M.CascaranoJ.WilsonM. A.Quantitation of mitochondrial DNA, RNA, and protein in starved and starved-refed rat liver197790229530610.1002/jcp.10409002152-s2.0-0017335331838779TrifunovicA.Mitochondrial DNA and ageing200617575-661161710.1016/j.bbabio.2006.03.0032-s2.0-3374561738416624248GreavesL. C.NooteboomM.ElsonJ. L.TuppenH. A.TaylorG. A.CommaneD. M.ArasaradnamR. P.KhrapkoK.TaylorR. W.KirkwoodT. B.MathersJ. C.TurnbullD. M.Clonal expansion of early to mid-life mitochondrial DNA point mutations drives mitochondrial dysfunction during human ageing2014109, article e100462010.1371/journal.pgen.10046202-s2.0-8490758725425232829YaoY. G.EllisonF. M.McCoyJ. P.ChenJ.YoungN. S.Age-dependent accumulation of mtDNA mutations in murine hematopoietic stem cells is modulated by the nuclear genetic background200716328629410.1093/hmg/ddl4572-s2.0-3384731235817185390De BenedictisG.RoseG.CarrieriG.De LucaM.FalconeE.PassarinoG.BonafeM.MontiD.BaggioG.BertoliniS.MariD.MattaceR.FranceschiC.Mitochondrial DNA inherited variants are associated with successful aging and longevity in humans199913121532153610463944SalvioliS.CapriM.ValensinS.TieriP.MontiD.OttavianiE.FranceschiC.Inflamm-aging, cytokines and aging: state of the art, new hypotheses on the role of mitochondria and new perspectives from systems biology200612243161317110.2174/1381612067779474702-s2.0-3374717222916918441SalvioliS.CapriM.SantoroA.RauleN.SeviniF.LukasS.LanzariniC.MontiD.PassarinoG.RoseG.De BenedictisG.FranceschiC.The impact of mitochondrial DNA on human lifespan: a view from studies on centenarians20083674074910.1002/biot.2008000462-s2.0-4894911916418548739KhrapkoK.VijgJ.Mitochondrial DNA mutations and aging: devils in the details?2009252919810.1016/j.tig.2008.11.0072-s2.0-5934908654919110336ZhangX.ZuoX.YangB.LiZ.XueY.ZhouY.HuangJ.ZhaoX.ZhouJ.YanY.ZhangH.GuoP.SunH.GuoL.ZhangY.FuX. D.MicroRNA directly enhances mitochondrial translation during muscle differentiation2014158360761910.1016/j.cell.2014.05.0472-s2.0-8490538981425083871GeigerJ.DalgaardL. T.Interplay of mitochondrial metabolism and microRNAs201774463164610.1007/s00018-016-2342-72-s2.0-8498346208127563705KrenB. T.WongP. Y.SarverA.ZhangX.ZengY.SteerC. J.MicroRNAs identified in highly purified liver-derived mitochondria may play a role in apoptosis200961657210.4161/rna.6.1.7534BianZ.LiL. M.TangR.HouD. X.ChenX.ZhangC. Y.ZenK.Identification of mouse liver mitochondria-associated miRNAs and their potential biological functions20102091076107810.1038/cr.2010.1192-s2.0-7795634385120733615BarreyE.Saint-AuretG.BonnamyB.DamasD.BoyerO.GidrolX.Pre-microRNA and mature microRNA in human mitochondria201165, article e2022010.1371/journal.pone.00202202-s2.0-7995757534421637849BandieraS.RübergS.GirardM.CagnardN.HaneinS.ChrétienD.MunnichA.LyonnetS.Henrion-CaudeA.Nuclear outsourcing of RNA interference components to human mitochondria201166, article e2074610.1371/journal.pone.00207462-s2.0-7995873757321695135SripadaL.TomarD.PrajapatiP.SinghR.SinghA. K.SinghR.Systematic analysis of small RNAs associated with human mitochondria by deep sequencing: detailed analysis of mitochondrial associated miRNA201279, article e4487310.1371/journal.pone.00448732-s2.0-8486630015522984580MercerT. R.NephS.DingerM. E.CrawfordJ.SmithM. A.ShearwoodA. M.HaugenE.BrackenC. P.RackhamO.StamatoyannopoulosJ. A.FilipovskaA.MattickJ. S.The human mitochondrial transcriptome2011146464565810.1016/j.cell.2011.06.0512-s2.0-8005200790121854988DasguptaN.PengY.TanZ.CiraoloG.WangD.LiR.miRNAs in mtDNA-less cell mitochondria20151, article 1500410.1038/cddiscovery.2015.427551440JagannathanR.ThapaD.NicholsC. E.ShepherdD. L.StrickerJ. C.CrostonT. L.BaselerW. A.LewisS. E.MartinezI.HollanderJ. M.Translational regulation of the mitochondrial genome following redistribution of mitochondrial microRNA in the diabetic heart20158678580210.1161/CIRCGENETICS.115.0010672-s2.0-8495014065526377859DasS.FerlitoM.KentO. A.Fox-TalbotK.WangR.LiuD.RaghavachariN.YangY.WheelanS. J.MurphyE.SteenbergenC.Nuclear miRNA regulates the mitochondrial genome in the heart2012110121596160310.1161/CIRCRESAHA.112.2677322-s2.0-8486227980522518031DasS.BedjaD.CampbellN.DunkerlyB.ChennaV.MaitraA.SteenbergenC.miR-181c regulates the mitochondrial genome, bioenergetics, and propensity for heart failure in vivo201495, article e9682010.1371/journal.pone.00968202-s2.0-8490102029024810628NouwsJ.ShadelG. S.Micromanaging mitochondrial translation2014158347747810.1016/j.cell.2014.07.0102-s2.0-8490539635125083863MitchelsonK. R.QinW. Y.Roles of the canonical myomiRs miR-1, -133 and -206 in cell development and disease20156316220810.4331/wjbc.v6.i3.16226322174LinS.LuoW.YeY.BekeleE. J.NieQ.LiY.ZhangX.Let-7b regulates myoblast proliferation by inhibiting IGF2BP3 expression in dwarf and normal chicken2017847710.3389/fphys.2017.0047728736533WredenbergA.FreyerC.SandströmM. E.KatzA.WibomR.WesterbladH.LarssonN. G.Respiratory chain dysfunction in skeletal muscle does not cause insulin resistance2006350120220710.1016/j.bbrc.2006.09.0292-s2.0-3374904126916996481DenhamJ.PrestesP. R.Muscle-enriched microRNAs isolated from whole blood are regulated by exercise and are potential biomarkers of cardiorespiratory fitness2016719610.3389/fgene.2016.001962-s2.0-8500643475027895662RobinsonM. M.DasariS.KonopkaA. R.JohnsonM. L.ManjunathaS.EspondaR. R.CarterR. E.LanzaI. R.KSN.Enhanced protein translation underlies improved metabolic and physical adaptations to different exercise training modes in young and old humans201725358159210.1016/j.cmet.2017.02.00928273480CarrerM.LiuN.GrueterC. E.WilliamsA. H.FrisardM. I.HulverM. W.Bassel-DubyR.OlsonE. N.Control of mitochondrial metabolism and systemic energy homeostasis by microRNAs 378 and 378201210938153301533510.1073/pnas.12076051092-s2.0-8486654618722949648PrattichizzoF.GiulianiA.RecchioniR.BonafèM.MarcheselliF.De CarolisS.CampanatiA.GiuliodoriK.RippoM. R.BrugèF.TianoL.MicucciC.CerielloA.OffidaniA.ProcopioA. D.OlivieriF.Anti-TNF-α treatment modulates SASP and SASP-related microRNAs in endothelial cells and in circulating angiogenic cells2016711119451195810.18632/oncotarget.78582-s2.0-8496280870826943583RippoM. R.OlivieriF.MonsurròV.PrattichizzoF.AlbertiniM. C.ProcopioA. D.MitomiRs in human inflamm-aging: a hypothesis involving miR-181a, miR-34a and miR-146a20145615416310.1016/j.exger.2014.03.0022-s2.0-8490184353824607549SuS.ZhaoQ.HeC.HuangD.LiuJ.ChenF.ChenJ.LiaoJ. Y.CuiX.ZengY.YaoH.SuF.LiuQ.JiangS.SongE.miR-142-5p and miR-130a-3p are regulated by IL-4 and IL-13 and control profibrogenic macrophage program20156, article 852310.1038/ncomms95232-s2.0-8494327927926436920TengG. G.WangW. H.DaiY.WangS. J.ChuY. X.LiJ.Let-7b is involved in the inflammation and immune responses associated with helicobacter pylori infection by targeting toll-like receptor 4201382, article e5670910.1371/journal.pone.00567092-s2.0-8487424120223437218NishinoJ.KimI.ChadaK.MorrisonS. J.Hmga2 promotes neural stem cell self-renewal in young but not old mice by reducing p16Ink4a and p19Arf expression2008135222723910.1016/j.cell.2008.09.0172-s2.0-5374909806118957199OlivieriF.LazzariniR.BabiniL.PrattichizzoF.RippoM. R.TianoL.Di NuzzoS.GraciottiL.FestaR.BrugèF.OrlandoP.SilvestriS.CapriM.PalmaL.MagnaniM.FranceschiC.LittarruG. P.ProcopioA. D.Anti-inflammatory effect of ubiquinol-10 on young and senescent endothelial cells via miR-146a modulation20136341042010.1016/j.freeradbiomed.2013.05.0332-s2.0-8487980377823727324ZhangL.LiY. J.WuX. Y.HongZ.WeiW. S.MicroRNA-181c negatively regulates the inflammatory response in oxygen-glucose-deprived microglia by targeting toll-like receptor 42015132671372310.1111/jnc.130212-s2.0-8492458159825545945GuoD.YeY.QiJ.TanX.ZhangY.MaY.LiY.Age and sex differences in microRNAs expression during the process of thymus aging201749540941910.1093/abbs/gmx02928369179SinghJ.BoopathiE.AddyaS.PhillipsB.RigoutsosI.PennR. B.RattanS.Aging-associated changes in microRNA expression profile of internal anal sphincter smooth muscle: role of microRNA-133a20163115G964G97310.1152/ajpgi.00290.20162-s2.0-8499548701227634012BeslerC.UrbanD.WatzkaS.LangD.RommelK. P.KandolfR.KlingelK.ThieleH.LinkeA.SchulerG.AdamsV.LurzP.Endomyocardial miR-133a levels correlate with myocardial inflammation, improved left ventricular function, and clinical outcome in patients with inflammatory cardiomyopathy201618121442145110.1002/ejhf.5792-s2.0-8497828610327292200MagentaA.DellambraE.CiarapicaR.CapogrossiM. C.Oxidative stress, microRNAs and cytosolic calcium homeostasis201660320721710.1016/j.ceca.2016.04.0022-s2.0-8496357727627103406GeorgantasR. W.StreicherK.GreenbergS. A.GreenleesL. M.ZhuW.BrohawnP. Z.HiggsB. W.CzapigaM.MorehouseC. A.AmatoA.RichmanL.JallalB.YaoY.RanadeK.Inhibition of myogenic microRNAs 1, 133, and 206 by inflammatory cytokines links inflammation and muscle degeneration in adult inflammatory myopathies20146641022103310.1002/art.382922-s2.0-8489865757324757153BoldinM. P.TaganovK. D.RaoD. S.YangL.ZhaoJ. L.KalwaniM.Garcia-FloresY.LuongM.DevrekanliA.XuJ.SunG.TayJ.LinsleyP. S.BaltimoreD.miR-146a is a significant brake on autoimmunity, myeloproliferation, and cancer in mice201120861189120110.1084/jem.201018232-s2.0-79958257077OlivieriF.LazzariniR.RecchioniR.MarcheselliF.RippoM. R.Di NuzzoS.AlbertiniM. C.GraciottiL.BabiniL.MariottiS.SpadaG.AbbatecolaA. M.AntonicelliR.FranceschiC.ProcopioA. D.MiR-146a as marker of senescence-associated pro-inflammatory status in cells involved in vascular remodelling20133541157117210.1007/s11357-012-9440-82-s2.0-8488522874322692818BhaumikD.ScottG. K.SchokrpurS.PatilC. K.OrjaloA. V.RodierF.LithgowG. J.CampisiJ.MicroRNAs miR-146a/b negatively modulate the senescence-associated inflammatory mediators IL-6 and IL-820091440241110.18632/aging.10004220148189MurphyM. P.How mitochondria produce reactive oxygen species200941711131906148310.1042/BJ200813862-s2.0-58249093939JiG.LvK.ChenH.WangT.WangY.ZhaoD.QuL.LiY.MiR-146a regulates SOD2 expression in H2O2 stimulated PC12 cells201387, article e6935110.1371/journal.pone.00693512-s2.0-84880710983