It has been highlighted the connections between miRNAs and ALS-related RNA-binding proteins (RBPs), TDP-43 and FUS, with essential regulatory complexes such as Drosha and in the nucleus and Dicer in the cytoplasm (Ling et al., 2010). TDP-43 and FUS are ubiquitously expressed RBPs regulating many aspects of RNA metabolism and processing. Nuclear depletion and cytoplasmic inclusion of TDP-43 is a pathological hallmark in more than 97% of ALS cases (Lagier-Tourenne et al., 2010; Taylor et al., 2016) whereas FUS inclusions are less common (Ling et al., 2013). Nuclear TDP-43 binds to the selected pri-miRNAs and promotes the cleavage of them by Drosha. Cytoplasmic TDP-43 binds to the terminal loops of the pre-miRNAs and promotes the cleavage of the specific pre-miRNAs by Dicer (Kawahara and Mieda-Sato, 2012). FUS binds the specific pri-miRNAs and cooperates with co-transcriptional Drosha recruitment on chromatin sites, which enhance the synthesis of the specific miRNAs (Morlando et al., 2012). Indeed, it has been shown that the expressions of the subsets of miRNAs are altered by knockdown of TARDBP or FUS/TLS (Kawahara and Mieda-Sato, 2012; Morlando et al., 2012). Furthermore, ALS-linked TDP-43 mutants showed the different binding patterns of mature miRNAs from wild-type and sequestered miRNAs in cytoplasmic inclusion (Paez-Colasante et al., 2020; Zuo et al., 2021). These findings indicate the link between altered miRNAs biogenesis and impaired Drosha and Dicer processing mechanism, as possible pathological implications in ALS.

Many studies have revealed that ALS is a multi-systemic disease, beyond the motor neuron system, including glial cells and muscle cells, are involved in the pathogenesis. Recently, it has been shaded light on the mechanisms underlying microRNAs dysregulation in the skeletal muscles involved in ALS pathogenesis. MiRNAs specifically expressed in the skeletal muscles have been identified as myomiRs such as miR-1, miR-133a, miR-133b, miR-206, and miR-23a, which take an important part in the molecular network controlling myogenesis via myogenic transcriptional factors (Di Pietro et al., 2018). Especially, miR-206, expressed in the skeletal muscles with physiological conditions, is involved in the maintenance of neuromuscular junctions and synapses, regulating myoblast differentiation (Toivonen et al., 2014). In addition, Williams et al. (2009) found that miR-206 suppresses the expression levels of muscular histone deacethylase 4 (HDAC4), which is an inhibitor of neuromuscular junction re-innervation via fibroblast growth factor binding protein 1 (FGFBP1), indicating the effect of miR-206 on promoting re-innervation after injury. Moreover, King et al. (2014) showed that TDP-43 associates with the mature miR-1/miR-206 family in muscle cells.

Based on these findings, Pegoraro et al. assessed the expression levels of multiple myomiRs in skeletal muscular biopsies derived from patients with sALS and fALS, including SOD1 and C9orf72 mutation carriers. They revealed that miR-1, miR-133a, and miR-133b were downregulated in muscle specimens from sALS compared to those from healthy individuals. On the other hand, miR-206 was upregulated in the muscles from patients with SOD1 and C9orf72 mutations (Pegoraro et al., 2020). Related to these myomiRs, Nie et al. (2015) showed miR-1 is required for muscle differentiation through acting on HDAC6, while miR-133 induces muscle proliferation.

Furthermore, Russell et al. (2013) showed that not only miR-206, miR-23a, miR-29b, miR-31, and miR-455 were upregulated in ALS patients compared with healthy individuals. Among these miRNAs, only miR-23a, which was also dysregulated in SOD1^G93A mice (Williams et al., 2009), was more significantly increased in the ALS than in neurological disease controls. They demonstrated that miR-23a suppresses the expression levels of peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PGC-1α), which is involved in mitochondrial biogenesis and function (Russell et al., 2013). These studies indicate that multiple myomiRs can contribute to ALS pathogenesis via functionally different roles during muscle development and re-innervation processes.

In ALS, neuroinflammation takes a significant role in the disease progression via immune system such as microglial activation and dysregulation of immune-related genes (Rinchetti et al., 2018). One of the well-studied miRNAs is the inflammatory miR-155, which is upregulated in fALS and sALS patients, and pre-symptomatic SOD1^G93A mice (Koval et al., 2013; Butovsky et al., 2015; Cunha et al., 2018). Of particular interest, Koval et al. (2013) demonstrated that the miR-155 levels in cerebrospinal fluid from ALS patients are twice as elevated as those from control individuals. Furthermore, miR-155 is involved in the elevation of proinflammatory cytokine secretion by binding to a repressor of cytokine signaling 1 (SOCS1) mRNAs (O'Connell et al., 2007, 2010; Ceppi et al., 2009). Indeed, the anti-miR-155 could significantly prolong the survival time in SOD1^G93A mice (Koval et al., 2013).

Moreover, Parisi et al. (2013, 2016) investigated the modulating role of miR-125b in the maintenance of NF-kb signals in microglia. They demonstrated that miR-125b activates NF-kb in microglia with toxic effects on surrounding motor neurons and the inhibition of this miRNA reduces the expression of the transcriptional targets of NF-kb, protecting motor neurons in SOD1^G93A mice model (Parisi et al., 2016). These results enhance the important role of inflammatory miRNAs in the connection between microglia and motor neurons, which is attracting attention as a contributor to motor neuron diseases.

Li et al. showed that miR-193b-3p is downregulated in SOD1^G93A mice as well as in patients with ALS. They showed that miR-193b-3p, which targets tuberous sclerosis 1 (TSC1) and regulates the activity of mechanistic target of rapamycin complex 1 (mTORC1), induces cell death using mouse motor neuron-like cells (NSC-34 cells). Since miR-193b-3p downregulates autophagy mechanism, reducing this miRNA is required for cell survival by promoting autophagy through TSC1-mTORC1 pathway (Li et al., 2017). Additionally, they found that miR-183b-5p regulates apoptosis and necrosis pathways by targeting RIP kinase 1 (RIPK) and programmed cell death 4 (PDCD4), suggesting the role of miR-183b-5p as a mediator of programmed neuronal death (Li et al., 2020). These studies indicate the link between regulating miRNAs and cell survival as a common mechanism in ALS regardless of gene mutations, which provides a future perspective for therapeutic strategy.

Several studies focused on the serum and plasma from patients with sALS and fALS, and demonstrated the alteration of miRNAs expression profiles. Freishmidt et al. reported that 24 miRNAs were downregulated in serum from fALS patients and/or asymptomatic ALS mutation carriers. Of interest, GDCGG and SGGC motifs were independently identified as highly enriched in these downregulated miRNAs (Freischmidt et al., 2014). The same authors also revealed that miR-1825 and miR-1234-3p were downregulated in serum from sALS patients (Freischmidt et al., 2015). These studies showed that homogenous miRNAs, which have consistent sequence motifs, are downregulated in ALS caused by different genes. Reheja et al. revealed that seven miRNAs: miR-1, miR-19a-3p, miR-133b, miR-133a-3p, miR-144-5p, miR-192-3p, and miR-192-5p were upregulated and six miRNAs: miR-139-5p, miR-320a, miR-320b, miR-320c, miR-425-5p, and let-7d-3p were downregulated in ALS patients in comparison with healthy controls and neurological disease controls such as Alzheimer's disease and multiple sclerosis. They also demonstrated that the alteration of these miRNAs levels was associated with clinical parameters over time, suggesting that they could act as prognostic markers (Raheja et al., 2018).

Magen et al. evaluated the plasma miRNAs as candidates for prognostic biomarkers in 252 patients with ALS. They demonstrated that the expression levels of miR-181, which is enriched in neurons and hematopoietic tissues, are stable during the course of disease. Then, the authors showed that high levels of miR-181 predict shorter survival time compared to low levels of miR-181 (low miR-181, median 38.9-month, high miR-181, median: 28.8-month, log-rank χ² = 16.7, p = 0.0001), suggesting that miR-181 functions as a potential prognostic biomarker for ALS. Moreover, they revealed that the evaluation of miR-181 can enhance the prognostic value of neurofilament light chain (NfL), a protein biomarker already known in ALS. The authors stratified samples from 243 patients into tertiles according to NfL levels. Importantly, higher miR-181 levels predicted shorter survival duration in the intermediate NfL level (HR = 2.37, 95% CI: 1.4–4.02, p = 0.001). Within the intermediate NfL tertile, lower miR-181 group had median 18-month longer survival duration than higher miR-181 group (log-rank χ² = 51.1, p < 0.0001), it could not be detected by NfL alone assessment (Magen et al., 2021). Thus, the joint of miRNA–protein biomarker approach provides a more accurate prognostication compared to measuring individual one and enhances the potential significance of miRNAs as adjuvant diagnostic tools.

As attention has been focused on the cerebrospinal fluid (CSF) as the source that most reflects the neuropathophysiological status of CNS, studies targeting miRNAs in CSF have been attempted (Freischmidt et al., 2013; Benigni et al., 2016; Waller et al., 2017; Yelick et al., 2020). Freischmidt et al. evaluated whether the TDP-43 binding microRNAs identified in cell lines are dysregulated in sALS patients. They revealed that downregulation of miR-132-5p/3p and miR-574-5p/3p was apparent in ALS patients, including those with TARDBP, FUS, and C9orf72 mutations, but not in those with SOD1 mutation (Freischmidt et al., 2013). Yelick et al. demonstrated the downregulation of miR-124-3p with spinal motor neuron-derived exosomes in SOD1^G93A mice, including the pre-symptomatic stage. Also, in their study, miR-124-3p levels in CSF exosomes from sALS patients showed a significant positive correlation between CSF exosomal miR-124-3p levels and clinical functional score in ALS (ALSFRS-R) (Yelick et al., 2020). These miRNAs' diagnostic and prognostic utility requires further validation.

There are still two major problems with the use of miRNA-based biomarkers as diagnostic tools for ALS. First, it is unclear whether the altered levels of miRNAs detected in patients truly reflect neurodegeneration due to ALS. The majority of patients with sporadic ALS are elderly and have other diseases, which may affect the composition of their miRNAs. Second, miRNAs are unstable and easily degraded, causing the difficulty treating as biomarkers than proteins. In particular, it is known that the conditions of centrifugation and/or temperature after sample collection can much affect the quality of RNAs (McDonald et al., 2011; Kirschner et al., 2013). Currently, miRNA-based biomarkers are not superior to other biomarkers. In order to make the most effective and accurate use of miRNAs in the diagnostic field, as the first step, we may need to seek a way to combine with other established biomarkers, such as NfL.