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. 2018 Jan 19;119(5):3809–3818. doi: 10.1002/jcb.26644

RBM10: Harmful or helpful‐many factors to consider

Julie J Loiselle 1, Leslie C Sutherland 1,
PMCID: PMC5901003  PMID: 29274279

Abstract

RBM10 is an RNA binding motif (RBM) protein expressed in most, if not all, human and animal cells. Interest in RBM10 is rapidly increasing and its clinical importance is highlighted by its identification as the causative agent of TARP syndrome, a developmental condition that significantly impacts affected children. RBM10's cellular functions are beginning to be explored, with initial studies demonstrating a tumor suppressor role. Very recently, however, contradictory results have emerged, suggesting a tumor promoter role for RBM10. In this review, we describe the current state of knowledge on RBM10, and address this dichotomy in RBM10 function. Furthermore, we discuss what may be regulating RBM10 function, particularly the importance of RBM10 alternative splicing, and the relationship between RBM10 and its paralogue, RBM5. As RBM10‐related work is gaining momentum, it is critical that the various aspects of RBM10 molecular biology revealed by recent studies be considered moving forward. It is only if these recent advances in RBM10 structure and function are considered that a clearer insight into RBM10 function, and the disease states with which RBM10 mutation is associated, will be gained.

Keywords: RBM5, RBM10, regulation, RNA binding proteins, SMN, TARP

1. INTRODUCTION

RNA binding proteins (RBPs) are a large and broad class of proteins that regulate all aspects of RNA metabolism.1 RBPs are, therefore, involved in regulating the nature, quantity and functionality of gene expression products. The interest in one particular RBP, RNA binding motif protein 10 (RBM10), has increased substantially in the last few years, with a greater than 50% increase in RBM10‐related PubMed‐indexed publications (ie, 34 manuscripts) since 2013.

RBM10 maps to the X‐chromosome at position p11.23.2, 3 It was first cloned from human bone marrow in 1995, within a collection of unidentified cDNAs.4 In 1996, RBM10 (as S1‐1) cDNA was cloned from rat liver in a targeted attempt to characterize a distinct subset of nuclear hnRNA‐associated proteins.5 The full‐length RBM10 transcript is approximately 3.5 kb long, divided into 24 exons, and translated into a protein of 930 amino acids.6 RBM10 is expressed in most, if not all, cells types (Gene Cards data), though one RBM10 allele is silenced in somatic female cells by X chromosome inactivation.2, 3 A requirement for RBM10 expression during development is evidenced by studies showing that loss‐of‐function mutations are the cause of TARP syndrome, an abnormal developmental syndrome usually resulting in the affected child's death before or soon after birth.6, 7, 8 RBM10 mutations are also observed in a number of cancer types.9, 10, 11, 12, 13, 14, 15 The association of RBM10 mutation with disease states is not surprising as altered RBP expression and/or function is associated with a wide spectrum of diseases, most being of neurological, muscular, sensory or neoplastic origin.16

In line with its mutational status in certain cancers, are studies that have demonstrated tumor suppressor‐associated roles for RBM10. For instance, many initial functional studies associated RBM10 expression with increased apoptosis,17 decreased cell proliferation,18 decreased colony formation,19 and decreased xenograft tumor growth.20 Counterintuitively, however, very recent studies have suggested a tumor promoter role for RBM10, and associated RBM10 expression with additional processes and mechanisms of action.21, 22 This functional dichotomy highlights the importance of not only gaining a deeper understanding of the downstream consequences of RBM10 expression, but identifying the mechanisms responsible for regulating RBM10 itself. Aspects of RBM10 regulation that have been identified, but that require further investigation include: (1) the alternative splicing of RBM10; (2) autoregulation of RBM10 at multiple levels; and (3) regulation of RBM10 by another, very homologous, RBP, RBM5.

In this review, we first describe recent advances regarding RBM10's structure and mechanism of action. We then address the dichotomy in RBM10 function, and discuss the factors by which it may be regulated. As publication of RBM10 studies is rapidly accelerating, and outcomes relating to RBM10 research can have clinical relevance, this review serves to highlight important aspects of previous RBM10‐related studies that should be taken into account in future experimental endeavors.

1.1. RBM10 primary structure

Primary structure is used to identify consensus functional motifs, and thus predict the functional characteristics of a translated protein. Coded within RBM10 are a number of different consensus functional motifs. These include; two RNA Recognition Motif (RRM) domains, an OCRE domain, a G‐patch domain, a C2H2‐type zing finger domain, a RanBP2‐type zinc finger domain, and three nuclear localization signals (NLSs) (NLS2 and NLS3 are within the RRM1 and OCRE regions, respectively) (Figure 1A).5, 23, 24 The functionality associated with many of these consensus motifs within RBM10 is beginning to be examined. For example, the three‐dimensional structure of the RBM10 OCRE‐containing globular domain can influence the interaction between RBM10 and other molecules, particularly spliceosomal complex proteins.25 Furthermore, RBM10 NLSs can work cooperatively to influence nuclear localization of RBM10.24, 26 In terms of RNA binding, the RBM10 RanBP2‐type zinc finger domain, and both RRM domains can bind RNA; however, while the RBM10 RanBP2‐type zinc finger and RRM1 domains can act together to recognize and bind specific RNA consensus sequences, the RBM10 RRM2 domain is structurally independent from both the RanBP2‐type zinc finger and RRM1 domains, and can bind independently.27, 28 Taken together, determining how each RBM10 consensus functional motif contributes to the functionality of RBM10 will enable stronger predictions regarding the impact of RBM10 mutations on RBM10 function.

Figure 1.

Figure 1

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Selected RBM10 and RBM5 consensus functional motifs. Translated RBM10 (A) and RBM5 (B) exons are represented by boxes. Numbers indicated within a box designate the exon it represents within the corresponding transcript. Box size does not represent exon length. Location of RBM10 and RBM5 consensus functional motifs are indicated by the thick line above the corresponding box(es), and the type of motif is indicated. NLS refers to nuclear localization signal. Principal RBM10 alternative splice variants are also included (A), with the orange line representing the absence of a GTG RNA triplet at that location (end of exon 10)

1.2. RBM10 is more than a regulator of alternative splicing

As predicted by the consensus functional motifs in its primary sequence, RBM10 is a regulator of alternative splicing. This was first demonstrated in 2013/2014,19, 29, 30, 31 and has since been confirmed by a number of groups.18, 20, 22, 32 For instance, RBM10 is involved in the alternative splicing of pre‐mRNA from NUMB,20 FAS,31 Dlg4,30 and SMN2.32 RBM10 has even been shown to promote alternative splicing‐coupled nonsense‐mediated mRNA decay (AS‐NMD) of its own pre‐mRNA and that of RBM5.33 The interaction of RBM10 with components of spliceosomal complexes also supports a role for RBM10 as a regulator of alternative splicing.34, 35, 36

Multiple aspects of RNA metabolism can be influenced by one particular RBP, and it is becoming clear that this is the case for RBM10. For instance, although most early studies focused on the role of RBM10 as a regulator of alternative splicing, some research groups identified additional RNA regulatory roles. The first demonstration of a distinctly non‐splicing‐related role for RBM10 was a report that the rat equivalent of RBM10, S1‐1, bound the 3′UTR of the angiotensin receptor type 1 (AT‐1) transcript and increased transcript stability: this stabilization ultimately led to downregulation of AT‐1 transcription.37 Since the rat and human RBM10 amino acid sequences share 97% homology, similar functionality is predicted for human RBM10.23 In support of this prediction, our group recently identified a number of RBM10 RNA targets that are involved in numerous aspects of the control of gene expression.21 RBM10 is therefore involved in at least three different mechanisms (pre‐mRNA splicing, mRNA stabilization, and mRNA transcription) related to RNA expression.

In addition, RBM10 is involved in a number of other cellular processes that are not at all, or not directly, related to RNA metabolism. These other cellular processes were identified through various protein interaction studies. For instance, RBM10 interacts with the FilGAP protein to control FilGAP localization and function38: RBM10 is thus involved in regulating cell structure and spreading. RBM10 also interacts with the 2A‐DUB deubiquitinase protein complex, which participates in histone modifications and thus regulates gene transcription39: RBM10 may, therefore, be involved in the epigenetic regulation of gene transcription through changes in the posttranslational modification of histones. Taken together, these studies show that RBM10 is involved in a number of different mechanisms that influence more than RNA metabolism. Future studies involving RBM10 should, therefore, recognize the limitations of focusing too narrowly when examining RBM10 mechanism and function.

To note, a number of studies have attempted to identify consensus RBM10 binding sequences within RBM10 target RNAs, an outcome that would enable prediction of additional RBM10 RNA targets and the potential effects of RBM10 binding. CLIP‐Seq, PAR‐CLIP, and iCLIP were used in these target binding sequence studies,19, 22, 29, 40 and a summary of the RBM10 consensus binding sequences determined by these studies is presented in Table 1. To note, the degree of similarity between the RBM10 consensus binding sequences in the RBM10 target RNAs identified to date is minimal, a finding that may be due to differences in the target identification technique, cell type and/or specific protein isoform used in each study. RNA target identification by RBM10 may thus be dependent on a number of factors, which remain to be elucidated.

Table 1.

Summary of consensus RNA binding sequences for RBM10

Experimental technique Consensus binding sequence(s) Reference
RNA homopolymer beads poly(U) & poly(G) > poly(C) > poly(A) 5
CLIP‐Seq CUCUGAACUC CGAUCCCU 19
PAR‐CLIP and Discover computational tool a Exonic sequence: GAAGA
UGGA
UCUUCA
Intronic sequence:
UUUCU
CACCGUGG		 29, 40
PAR‐CLIP and HOMER software a UGUGGACA 28, 29
iCLIP TCCAA CCAAA
CCCCA		 22
Fluorescence anisotropy titration and chemical shift pertubations (only with RanBP2 zinc finger domain of RBM10) AGGUAA 27
RNAcompete (only with RanBP2 zinc finger and RRM1 domain of RBM10) UGUGGA 28
Scaffold independent analysis (only with RRM2 domain of RBM10) CCNC 28
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Underlined sequence indicates core motif.

a

PAR‐CLIP study by Wang et al. did not publish any consensus binding sequences. Studies by Maaskola & Rajewsky and Collins et al. applied different computation tools to the PAR‐CLIP data from Wang et al. to output potential RBM10 consensus binding sequences.

2. THE CONTRASTING EFFECTS OF RBM10 EXPRESSION

The majority of studies relating to the downstream effects associated with changes in RBM10 expression have centered on roles in the promotion of cell cycle arrest and apoptosis, largely due to RBM10's homology to RBM5, an established apoptosis modulator.23 The first functional study correlated RBM10 expression with decreased cell proliferation and increased apoptosis in hypertrophic primary chondrocytes.41 In 2012, our group confirmed that RBM10 promoted apoptosis in two human cancer cell lines, and identified a positive correlation between RBM10 expression and TNFα transcription.42 Since then, the roles of RBM10 as a promoter of apoptosis17 and an inhibitor of proliferation18, 19, 20 have been confirmed in a number of studies. In addition, correlational studies from human tissues support an apoptosis‐promoting role for RBM10, as RBM10 mRNA expression in breast cancer samples correlated with increased mRNA expression of BAX, a proapoptotic protein, and TP53, a tumor suppressor protein with transcriptional activity.43 Unexpectedly, however, the latter study also correlated RBM10 expression with increased mRNA expression of VEGF, a potent promoter of angiogenesis.43

Our very recent work took a broader look at RBM10 function by using next‐generation sequencing to identify genes differentially expressed following modulation of RBM10 expression levels.21 Unexpectedly, but using an RBM5‐null small cell lung cancer cell line, the results suggested that RBM10 promotes many transformation‐ and hypoxia‐associated processes and events. Specifically, knockdown of RBM10 expression induced changes in gene expression predicted to reduce glycolysis, epithelial to mesenchymal transition (EMT) and angiogenesis − potentially by direct regulation of cell metabolism, specifically oxidative phosphorylation. Many recent studies support those findings: (1) the association of RBM10 with FilGAP,38 a regulator of cell spreading, supports a role for RBM10 in the regulation of EMT; (2) the phosphorylation of RBM10 by c‐SRC, and consequent involvement in the PDGF signaling pathway,44 supports a role for RBM10 in the promotion of angiogenesis; (3) the positive correlation between the mRNA expression of RBM10 and VEGF,43 an important angiogenesis promoter, also supports a role for RBM10 in the regulation of angiogenesis; and (4) the association of RBM10 with neurodegenerative disorders,19, 21 many of which involve impairment of oxidative phosphorylation, supports a role for RBM10 in the regulation of this aspect of cellular metabolism.

In fact, a pro‐transformatory role for RBM10 was previously demonstrated in embryonic stem cells and mouse mandibular cells, where knockdown of RBM10 was associated with decreased cell growth,22 suggesting that expression of RBM10 is associated with increases in cell growth. Furthermore, RBM10 knockdown in neuronal cells increased caspase activation induced by staurosporine,45 suggesting that expression of RBM10 impedes apoptosis. This functional RBM10 dichotomy was recognized by Rodor et al21 who noted RBM10 may have cell type and/or species specific roles, but was directly tackled recently by our group: we proposed a working model that describes how the regulation of RBM10 expression determines function, whether tumor suppressive or tumor promoting.21 Notably, this working model contains many hypotheses that remain to be tested. Understanding the mechanisms that regulate RBM10 expression and function would help to predict the impact of RBM10 mutation on cellular processes and thus potential patient outcomes in a disease such as cancer.

3. REGULATION OF RBM10

RBM10 mutation has particular relevance to TARP syndrome,6, 8 and may have relevance to spinal muscular atrophy (SMA).32 Unfortunately, actual changes in RBM10 expression have not been rigorously examined in either of these diseases. The fact that no significant changes in RBM10 expression have been identified in screens of other disease states likely accounts for the fact that the regulation of RBM10 expression and function has, to date, been studied very little. What is known is that posttranslationally, RBM10 can be phosphorylated by c‐Src,44 an event that may influence RBM10 localization and function; upregulation of a Src family tyrosine kinase induced translocation of RBM10 from the nucleus to the cytoplasm, which was required for RBM10's interaction with FilGAP and consequent regulation of cell spreading.38 In addition, several recent studies have identified co‐ and post‐transcriptional RBM10‐regulatory mechanisms that may have a significant influence on RBM10 function: (1) alternative splicing of RBM10; (2) autoregulation of RBM10 expression; and (3) regulation of RBM10 by the homologous RBP, RBM5. These specific regulatory mechanisms, as well as their potential functional consequences, are summarized in Figure 2, and described below in order to highlight how their consideration could impact the results of future RBM10‐related studies.

Figure 2.

Figure 2

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RBM10 interacting factors. Factors demonstrated to interact with RBM10 RNA (blue) and RBM10 protein (RNA factors in green, and protein factors in purple) are indicated. Established functional consequences of the interactions are indicated (if known). Text on arrows indicates which RBM10 isoform was involved in the study (as indicated by the referenced manuscript's published NCBI accession number or GenBank ID, when available). IP RBM10 indicates that RBM10‐interacting factors were identified by immunoprecipitation of RBM10 with an antibody with an immunogen sequence more homologous to RBM10v1 than RBM10v2 (the last 14 amino‐acids of its 81 amino acid immunogen sequence were not specific for RBM10v2) (Sigma HPA034972)

3.1. Alternative splicing of RBM10

Like 95% of multi‐exon containing transcripts,46 RBM10 can be alternatively spliced. The main RBM10 alternative splice variant, RBM10v2, is produced by alternatively splicing the fourth exon from RBM10, resulting in a protein of 853 amino acids.6, 23 As depicted in Figure 1A, the alternative splicing of exon four of RBM10 alters the sequence of RBM10 RRM1, and thus, likely, it's RNA binding characteristics.

Recently, a comprehensive analysis of the alternative splicing of RBM10 showed that both RBM10v1 and RBM10v2 have an additional splice variant that differs by only one RNA triplet, GTG (Figure 1B).47 This triplet is located at the very end of RBM10v1 exon ten and encodes a valine residue. RBM10 thus has four main alternative splice variants: (1) RBM10v1(V354), the longest RBM10 transcript; (2) RBM10v1(V354del), which lacks the GTG RNA triplet at the end of exon ten; (3) RBM10v2(V277), which lacks the exon 4 of RBM10v1; and (4) RBM10v2(V277del), which lacks the exon 4 of RBM10v1, and the GTG RNA triplet at the end of RBM10v1 exon ten. Importantly, the valine residue coded by the alternatively spliced GTG triplet is located in RBM10's second RRM domain, at the beginning of its second α‐helix. Two studies have predicted the impact of the presence or absence of this valine residue on RBM10 structure and function, but with contrasting results. Firstly, Tessier et al,47 using the NMR structure of the RBM10 RRM2, predicted that the presence of valine inhibits alpha‐helix formation in RBM10 RRM2 and correlated this change in +/− GTG RBM10 alternative splicing with alterations in RBM10 function. Secondly, Hernandez et al,20 using the solution structure of the RBM5 RRM2, predicted that the alternative valine residue within RBM10 was just outside of the RBM10 RRM2 alpha‐helix, on the opposite side of the RNA binding surface, and consequently that the presence or absence of valine would have little impact on RBM10 function. Interestingly, an earlier manuscript by Bechara et al19 showed that mutation of this alternatively spliced valine residue to glutamic acid did alter RBM10 function, supporting the notion that the alternative splicing of this codon could have functional implications for RBM10. In addition, our group recently showed that RBM5 can distinguish between these +/− GTG RBM10 splice variants; RBM5 specifically bound only RBM10v2(V277del).21 Taken together, these results suggest that the alternative splicing of RBM10 results in changes in protein tertiary structure that either directly (eg, +/− valine in the RRM domain) or indirectly (eg, RBM10v1 versus RBM10v2) influence function.

Future studies should, therefore, consider the RBM10 splice variant or isoform expression profile in the cell types used, prior to undertaking functional assays related to RBM10. Furthermore, it is essential to specify which particular variants or isoforms are being overexpressed or knocked down in, and which are able to be detected by, each experimental assay. This aspect of variant identification is almost always overlooked in RBM10‐related studies. Future studies that consider the expression and function of each RBM10 isoform would also be more accurate and informative. This is highlighted in Figure 2, which demonstrates that very little is known regarding RBM10‐splice variant interacting factors. In light of the fact that different isoforms may have opposing functions,21, 47 the ratio of the various RBM10 isoforms in a patient could be of predictive significance for disease incidence and/or progression.

3.2. Autoregulation of RBM10

It was very recently demonstrated that RBM10 is capable of binding its own pre‐mRNA thereby affecting alternative splicing and ultimately promoting its own nonsense‐mediated decay.33 Specifically, in HEK293 cells, RBM10 protein bound RBM10 pre‐mRNA within the 5′‐splice sites of introns 6 and 12, resulting in increased levels of the RBM10 exon 6 or exon 12 skipped variant. These exon 6 or exon 12 lacking variants are targets for NMD, and the authors demonstrated that overexpression of RBM10 ultimately negatively influenced both RBM10 mRNA and protein levels. Thus, the potentially important functional consequences of RBM10 alternative splicing, described above, can involve a level of co‐transcriptional self‐regulation. Of note, although not addressed by the authors, based on the NCBI Reference Sequence number provided, the RBM10 variant overexpressed in this study was RBM10v1(V354).

Interestingly, another very recently published study also showed that RBM10 protein is capable of binding its own mRNA, and possibly regulating its own translation. Using an RNA immunoprecipitation and next‐generation sequencing technique, RBM10 protein was shown to specifically bind the RNA of both RBM10v2 variants: RBM10v2(V277) and RBM10v2(V277del).21 As the GLC20 cells used in this study almost exclusively expressed RBM10v1 at the protein level, it was most likely RBM10v1 that was interacting with the RBM10v2 RNA. Strikingly, although RBM10v1 protein levels were substantially higher than RBM10v2 protein levels, mRNA expression levels of RBM10v1 and RBM10v2 were very similar, suggesting that the interaction of RBM10v1 protein with RBM10v2 RNA is integral to an RBM10 translational self‐regulation mechanism, at least in GLC20 cells.21 Of note, in the study by Sun et al33 described above, RBM10v1 overexpression was followed by decreased RBM10v2 expression at both the mRNA and protein levels, suggesting that multiple levels of RBM10 self‐regulation exist in HEK293 cells. Taken together, these findings suggest that RBM10v1 is capable of regulating RBM10v2 expression, but that how RBM10 autoregulation is achieved is cell type‐specific.

All of these very recent findings demonstrate that RBM10 can autoregulate its own alternative splicing, and expression at the mRNA and/or protein level. It is not unusual for an RBP to be able to regulate its own expression, especially given its RNA binding abilities. For instance, members of the Fox family, which includes RBM9 (FOX‐2), can auto‐regulate the alternative splicing of FOX mRNA.48 In fact, FOX proteins promote exon exclusion during FOX alternative splicing, resulting in a translated variant with reduced RNA binding capabilities.49 This exclusion variant represses FOX's influence on the alternative splicing of other genes, thus FOX proteins not only autoregulate their alternative splicing, but also their function.48 In addition, an antisense transcript of RBM5 can negatively affect full‐length RBM5 expression, as well as alter levels of other RBM5 alternative splice variants.50, 51 The area of RBM10 autoregulation is only beginning to be explored and many questions remain, including if RBM10v2 protein can also regulate RBM10 expression. Further studies in this area are necessary to better understand how the RBM10 splice variant and isoform expression profiles in a given system are controlled.

3.3. Relationship between RBM10 and RBM5

RBM10 is a member of an RBP family that includes RBM5 and RBM6. Phylogenetic studies provide evidence that RBM5 is the progenitor gene.52 RBM5 maps to chromosome three at position 3p21.3 and was first cloned by Wei et al in 199653 under the name LUCA‐15. The full‐length RBM5 transcript is approximately 3 kb, divided into 25 exons, and codes for a protein of 815 amino acids (Figure 1B). To date, RBM5 has been studied more comprehensively than RBM10, and has been established as a tumor suppressor gene.23 The level of amino acid homology between RBM5 and RBM10 is approximately 50%, with RBM10v1 sharing 49% identity with RBM5, and RBM10v2 sharing 53%.23 The nucleotide sequences in exons 4, 9, and 15 are particularly different between RBM5 and RBM10 and are the main cause of the variation between both proteins.23 Of note, these non‐homologous exons are located right before consensus functional motifs, suggesting similar functionality for RBM5 and RBM10, but potentially different specificity for both RBPs.54, 55 A relationship between products from the two genes has been demonstrated in a variety of cell types. For instance, both positive and negative expression correlations have been noted: (1) in HEK293 human embryonic kidney cells, RBM10 overexpression correlated with increased RBM5 exon 6 exclusion and overall decreased RBM5 mRNA levels, whereas RBM10 knockdown correlated with a slight decrease in RBM5 exon 6 exclusion and overall higher RBM5 mRNA expression levels29, 33; (2) in SHSY5Y human neuronal cells, RBM10 knockdown correlated with increased levels of RBM5 protein45; (3) in H9c2 rat myoblast cells, RBM5 knockdown correlated with decreased RBM10 mRNA expression56; and (4) in GLC20 RBM5‐null small cell lung cancer cells, increased RBM5 expression correlated with increased protein expression of specific RBM10 splice variants.21 Of note, the first and fourth study described not only showed a correlation between RBM5 and RBM10 expression, but also direct interactions between them: (1) in HEK293 cells, RBM10 bound the RBM5 intron 5 5′‐splice site and intron 6 3′‐splice site, influencing RBM5 alternative splicing and ultimately leading to RBM5 AS‐NMD33; and (2) in GLC20 cells, RBM5 bound only one specific RBM10 splice variant, and was associated with increased protein expression of RBM10v2.21 Considered together, these results demonstrate that relationships between RBM5 and RBM10 occur across cell types and species, highlighting their potential fundamental importance to the cell.

3.4. RBM10's pro‐transformatory functions may be RBM5‐dependent

The functional consequences of the relationship between RBM5 and RBM10 have yet to be fully grasped, but our group recently presented data and a working model that link RBM5 to the regulation of RBM10 function: in an RBM5‐null environment, the putative tumor suppressor RBM10 actually promoted transformation‐associated processes.21 The working model presented by Loiselle et al33 which describes this association, is (a) comprehensive, taking into account even the most recently published findings regarding RBM10, and (b) supported by data presented in another manuscript, which was published after submission of the Loiselle et al. manuscript, that demonstrated the autoregulatory functions for RBM10 described above.

Three recent gene expression studies involving various tumor types provide in vivo data supporting the suggestion that RBM10 promotes transformation in systems where RBM5 is downregulated. Firstly, gene expression analysis of Cancer Genome Atlas (TCGA) samples from various tumor types showed that RBM10 was significantly upregulated in many cancer types, while RBM5 expression was significantly downregulated.10 Secondly, RBM10 mutations in pancreatic ductal cancer correlated with a better 5‐year survival probability14 and RBM5 mRNA and protein expression was significantly reduced in pancreatic cancers.57 Thirdly, RBM10 expression correlated with increased disease aggressiveness in metastatic melanomas58 and the RBM5 promoter region was found to be significantly mutated in metastatic melanomas,59 meaning that RBM5 expression is likely compromised in this type of cancer. Taken together, these in vivo studies and our in vitro studies suggest that RBM10 expression promotes transformation in RBM5‐reduced environments. The nature of this relationship between RBM5 and RBM10 has thus begun to be elucidated; more studies are required, however, to completely understand this association.

3.5. Clinical importance of RBM10

The clinical importance of understanding RBM10 function and regulation is highlighted in situations where RBM10 expression is disrupted. For instance, RBM10 mutations are the cause of TARP syndrome.6, 8 This condition is characterized by many developmental abnormalities, particularly craniofacial deformities such as cleft palate, glossoptosis (tongue displacement) and micrognathia (undersized jaw), which can cause difficulty eating and breathing.7 Sadly, usually due to various heart conditions associated with the disease, the affected children die before, or soon after, birth.6, 7, 8 If significant medical attention is provided, however, there have been reports of children with TARP syndrome living up to three years.8 These cases have permitted doctors to observe other phenotypic consequences of embryonic RBM10 mutations, including chronic lung disease, visual impairment, significant intellectual disability and an inability to eat or sit independently.8, 60 The severe impact of RBM10 mutations in these children strongly suggests a critical role for RBM10 in fetal development. This is supported by in vivo and in vitro findings showing RBM10 expression to be: (1) regulated during rat skeletal and cardiac muscle cell differentiation61; (2) regulated both temporally and spatially during murine midgestation embryo development6; (3) a regulator of mouse embryonic stem cell proliferation and differentiation22; and (4) able to influence the alternative splicing of SMN2.32 The latter could be of clinical relevance to patients with spinal muscular atrophy who have a homozygous deletion of SMN1, and thus rely on their SMN2 gene for all SMN protein.

RBM10 is also mutated in select cancer types. For instance, RBM10 was found to be truncated in approximately 7% of lung adenocarcinomas,9, 10, 62 with this mutation rate increasing to 21% in invasive lung adenocarcinomas.13 RBM10 mutations have also been identified in pancreatic intraductal papillary mucinous neoplasms,12 pancreatic ductal adenocarcinomas,14 colorectal cancers,11 and fatal forms of non‐anaplastic thyroid cancer.15 Despite this, in a mutational screen of 441 tumors of various cancer types including pancreatic and lung adenocarcinomas, only one breast and one prostate cancer sample, respectively, had an RBM10 mutation.63 The importance of functional RBM10 in regards to the transformed state, therefore, remains to be determined.

4. CONCLUSION

RBM10‐related studies are rapidly gaining momentum. Even in the past year, knowledge regarding RBM10 has significantly expanded; it is now established that RBM10 has a number of alternative splice variants, is autoregulated, and interacts with RBM5. There is thus an intricate system regulating RBM10 expression and function which is only beginning to be revealed. Future studies in this area could include determining: (1) the function of each RBM10 splice variant; (2) the mechanism of action of each RBM10 splice variant (eg, if all splice variants have alternative splicing capabilities); (3) which RBM10 splice variants are posttranscriptionally modified; and (4) the factors that regulate RBM10 splice variant expression. More studies are also required to fully understand the nature of the relationship between RBM5 and RBM10, how their interactions are regulated, and how these may vary between cell types and disease states. In addition, future work could include examining if/how expression of RBM6, another RBM5 family member, influences RBM10 expression and function. Interestingly, knockdown of RBM5, RBM10, and RBM6 was necessary to demonstrate the ability of RBM5 to modulate FAS alternative splicing, suggesting a potential relationship between all three family members.64

In sum, by considering the various aspects of RBM10 regulation that are described in this review, in future RBM10‐related experimental endeavors, a much clearer insight into RBM10 function, and influence on disease states, will be gained. Ultimately, this may lead to the development of novel and effective treatment options for these diseases.

ACKNOWLEDGMENT

JJL was supported by an Alexander Graham Bell Canada Graduate Scholarship from the Natural Sciences and Engineering Research Council of Canada (NSERC). LCS is currently supported by the Northern Cancer Foundation and the NEO Kids Foundation.

Loiselle JJ, Sutherland LC. RBM10: Harmful or helpful‐many factors to consider. J Cell Biochem. 2018;119: 3809–3818. https://doi.org/10.1002/jcb.26644

REFERENCES

  • 1. Glisovic T, Bachorik JL, Yong J, Dreyfuss G. RNA‐binding proteins and post‐transcriptional gene regulation. FEBS Lett. 2008; 582:1977–1986. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 2. Coleman MP, Ambrose HJ, Carrel L, Nemeth AH, Willard HF, Davies KE. A novel gene, DXS8237E, lies within 20kb upstream of UBE1 in Xp11.23 and has a different X inactivation status. Genomics. 1996; 31:135–138. [DOI] [PubMed] [Google Scholar]
  • 3. Thiselton DL, McDowall J, Brandau O, et al. An integrated, functionally annotated gene map of the DXS8026‐ELK1 interval on human Xp11.3‐Xp11.23: potential hotspot for neurogenetic disorders. Genomics. 2002; 79:560–572. [DOI] [PubMed] [Google Scholar]
  • 4. Nagase T, Seki N, Tanaka A, Ishikawa K, Nomura N. Prediction of the coding sequences of unidentified human genes. IV. The coding sequences of 40 new genes (KIAA0121‐KIAA0160) deduced by analysis of cDNA clones from human cell line KG‐1. DNA Res. 1995; 2:167–210. [DOI] [PubMed] [Google Scholar]
  • 5. Inoue A, Takahashi KP, Kimura M, Watanabe T, Morisawa S. Molecular cloning of a RNA binding protein, S1‐1. Nucleic Acids Res. 1996; 24:2990–2997. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 6. Johnston JJ, Teer JK, Cherukuri PF, et al. Massively parallel sequencing of exons on the X chromosome identifies RBM10 as the gene that causes a syndromic form of cleft palate. Am J Hum Genet. 2010; 86:743–748. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 7. Gorlin RJ, Cervenka J, Anderson RC, Sauk JJ, Bevis WD. Robin's syndrome. A probably X‐linked recessive subvariety exhibiting persistence of left superior vena cava and atrial septal defect. Am J Dis Child. 1970; 119:176–178. [PubMed] [Google Scholar]
  • 8. Gripp KW, Hopkins E, Johnston JJ, Krause C, Dobyns WB, Biesecker LG. Long‐term survival in TARP syndrome and confirmation of RBM10 as the disease‐causing gene. Am J Med Genet A 155A. 2011; (10):2516–2520. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 9. Imielinski M, Berger AH, Hammerman PS, et al. Mapping the hallmarks of lung adenocarcinoma with massively parallel sequencing. Cell. 2012; 150:1107–1120. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 10. Sebestyen E, Singh B, Minana B, et al. Large‐scale analysis of genome and transcriptome alterations in multiple tumors unveils novel cancer‐relevant splicing networks. Genome Res. 2016; 26:732–744. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 11. Giannakis M, Mu XJ, Shukla SA, et al. Genomic Correlates of Immune‐Cell Infiltrates in Colorectal Carcinoma. Cell Rep. 2016; 15:857–865. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12. Furukawa T, Kuboki Y, Tanji E, et al. Whole‐exome sequencing uncovers frequent GNAS mutations in intraductal papillary mucinous neoplasms of the pancreas. Sci Rep. 2011; 1:161. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13. Vinayanuwattikun C, Le Calvez‐Kelm F, Abedi‐Ardekani B, et al. Elucidating genomic characteristics of lung cancer progression from In situ to invasive adenocarcinoma. Sci Rep. 2016; 6:31628. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 14. Witkiewicz AK, McMillan EA, Balaji U, et al. Whole‐exome sequencing of pancreatic cancer defines genetic diversity and therapeutic targets. Nat Commun. 2015; 6:6744. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 15. Ibrahimpasic T, Xu B, Landa I, et al. Genomic alterations in fatal forms of non‐anaplastic thyroid cancer: identification of MED12 and RBM10 as novel thyroid cancer genes associated with tumor virulence. Clin Cancer Res. 2017; 23:5970–5980. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 16. Lukong KE, Chang KW, Khandjian EW, Richard S. RNA‐binding proteins in human genetic disease. Trends Genet. 2008; 24:416–425. [DOI] [PubMed] [Google Scholar]
  • 17. Wang K, Bacon ML, Tessier JJ, Rintala‐Maki ND, Tang V, Sutherland LC. RBM10 modulates apoptosis and influences TNF‐alpha gene expression. J Cell Death. 2012; 5:1–19. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 18. Zhao J, Sun Y, Huang Y, et al. Functional analysis reveals that RBM10 mutations contribute to lung adenocarcinoma pathogenesis by deregulating splicing. Sci Rep. 2017; 7:40488. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 19. Bechara EG, Sebestyen E, Bernardis I, Eyras E, Valcarcel J. RBM5, 6, and 10 differentially regulate NUMB alternative splicing to control cancer cell proliferation. Mol Cell. 2013; 52:720–733. [DOI] [PubMed] [Google Scholar]
  • 20. Hernandez J, Bechara E, Schlesinger D, Delgado J, Serrano L, Valcarcel J. Tumor suppressor properties of the splicing regulatory factor RBM10. RNA Biol. 2016; 13:466–472. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 21. Loiselle JJ, Roy JG, Sutherland LC. RBM10 promotes transformation‐associated processes in small cell lung cancer and is directly regulated by RBM5. PLoS ONE. 2017; 12:e0180258. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 22. Rodor J, FitzPatrick DR, Eyras E, Caceres JF. The RNA‐binding landscape of RBM10 and its role in alternative splicing regulation in models of mouse early development. RNA Biol. 2017; 14:45–57. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 23. Sutherland LC, Rintala‐Maki ND, White RD, Morin CD. RNA binding motif (RBM) proteins: a novel family of apoptosis modulators? J Cell Biochem. 2005; 94:5–24. [DOI] [PubMed] [Google Scholar]
  • 24. Xiao SJ, Wang LY, Kimura M, et al. S1‐1/RBM10: multiplicity and cooperativity of nuclear localisation domains. Biol Cell. 2013; 105:162–174. [DOI] [PubMed] [Google Scholar]
  • 25. Martin BT, Serrano P, Geralt M, Wuthrich K. Nuclear magnetic resonance structure of a novel globular domain in RBM10 containing OCRE, the octamer repeat sequence motif. Structure. 2016; 24:158–164. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 26. Inoue A, Tsugawa K, Tokunaga K, et al. S1‐1 nuclear domains: characterization and dynamics as a function of transcriptional activity. Biol Cell. 2008; 100:523–535. [DOI] [PubMed] [Google Scholar]
  • 27. Nguyen CD, Mansfield RE, Leung W, et al. Characterization of a family of RanBP2‐type zinc fingers that can recognize single‐stranded RNA. J Mol Biol. 2011; 407:273–283. [DOI] [PubMed] [Google Scholar]
  • 28. Collins KM, Kainov YA, Christodolou E, et al. An RRM‐ZnF RNA recognition module targets RBM10 to exonic sequences to promote exon exclusion. Nucleic Acids Res. 2017; 45:6761 –6774. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 29. Wang Y, Gogol‐Doring A, Hu H, et al. Integrative analysis revealed the molecular mechanism underlying RBM10‐mediated splicing regulation. EMBO Mol Med. 2013; 5:1431–1442. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 30. Zheng S, Damoiseaux R, Chen L, Black DL. A broadly applicable high‐throughput screening strategy identifies new regulators of Dlg4 (Psd‐95) alternative splicing. Genome Res. 2013; 23:998–1007. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 31. Inoue A, Yamamoto N, Kimura M, Nishio K, Yamane H, Nakajima K. RBM10 regulates alternative splicing. FEBS Lett. 2014; 588:942–947. [DOI] [PubMed] [Google Scholar]
  • 32. Sutherland LC, Thibault P, Durand M, et al. Splicing arrays reveal novel RBM10 targets, including SMN2 pre‐mRNA. BMC Mol Biol. 2017; 18:19. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 33. Sun Y, Bao Y, Han W, et al. Autoregulation of RBM10 and cross‐regulation of RBM10/RBM5 via alternative splicing‐coupled nonsense‐mediated decay. Nucleic Acids Res. 2017; 45:8524–8540. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 34. Deckert J, Hartmuth K, Boehringer D, et al. Protein composition and electron microscopy structure of affinity‐purified human spliceosomal B complexes isolated under physiological conditions. Mol Cell Biol. 2006; 26:5528–5543. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 35. Behzadnia N, Golas MM, Hartmuth K, et al. Composition and three‐dimensional EM structure of double affinity‐purified, human prespliceosomal A complexes. EMBO J. 2007; 26:1737–1748. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 36. Rappsilber J, Ryder U, Lamond AI, Mann M. Large‐scale proteomic analysis of the human spliceosome. Genome Res. 2002; 12:1231–1245. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 37. Mueller CF, Berger A, Zimmer S, Tiyerili V, Nickenig G. The heterogenous nuclear riboprotein S1‐1 regulates AT1 receptor gene expression via transcriptional and posttranscriptional mechanisms. Arch Biochem Biophys. 2009; 488:76–82. [DOI] [PubMed] [Google Scholar]
  • 38. Yamada H, Tsutsumi K, Nakazawa Y, Shibagaki Y, Hattori S, Ohta Y. Src family tyrosine kinase signaling regulates FilGAP through association with RBM10. PLoS ONE. 2016; 11:e0146593. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 39. Zhu P, Zhou W, Wang J. A histone H2A deubiquitinase complex coordinating histone acetylation and H1 dissociation in transcriptional regulation. Mol Cell. 2007; 27:609–621. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 40. Maaskola J, Rajewsky N. Binding site discovery from nucleic acid sequences by discriminative learning of hidden Markov models. Nucleic Acids Res. 2014; 42:12995–13011. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 41. James CG, Ulici V, Tuckermann J, Underhill TM, Beier F. Expression profiling of Dexamethasone‐treated primary chondrocytes identifies targets of glucocorticoid signalling in endochondral bone development. BMC Genomics. 2007; 8:205. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 42. Wang K, Bacon ML, Tessier JJ, Rintala‐Maki ND, Tang V, Sutherland LC. RBM10 modulates apoptosis and influences TNA‐a gene expression. Journal of Cell Death. 2012; 5:1–19. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 43. Martinez‐Arribas F, Agudo D, Pollan M, et al. Positive correlation between the expression of X‐chromosome RBM genes (RBMX, RBM3, RBM10) and the proapoptotic Bax gene in human breast cancer. J Cell Biochem. 2006; 97:1275–1282. [DOI] [PubMed] [Google Scholar]
  • 44. Amanchy R, Zhong J, Molina H, et al. Identification of c‐Src tyrosine kinase substrates using mass spectrometry and peptide microarrays. J Proteome Res. 2008; 7:3900–3910. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 45. Jackson TC, Du L, Janesko‐Feldman K, et al. The nuclear splicing factor RNA binding motif 5 promotes caspase activation in human neuronal cells, and increases after traumatic brain injury in mice. J Cereb Blood Flow Metab. 2015; 35:655–666. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 46. Pan Q, Shai O, Lee LJ, Frey BJ, Blencowe BJ. Deep surveying of alternative splicing complexity in the human transcriptome by high‐throughput sequencing. Nat Genet. 2008; 40:1413–1415. [DOI] [PubMed] [Google Scholar]
  • 47. Tessier SJ, Loiselle JJ, McBain A, et al. Insight into the role of alternative splicing within the RBM10v1 exon 10 tandem donor site. BMC Res Notes. 2015; 8:46. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 48. Damianov A, Black DL. Autoregulation of Fox protein expression to produce dominant negative splicing factors. RNA. 2010; 16:405–416. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 49. Nakahata S, Kawamoto S. Tissue‐dependent isoforms of mammalian Fox‐1 homologs are associated with tissue‐specific splicing activities. Nucleic Acids Res. 2005; 33:2078–2089. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 50. Rintala‐Maki ND, Sutherland LC. Identification and characterisation of a novel antisense non‐coding RNA from the RBM5 gene locus. Gene. 2009; 445:7–16. [DOI] [PubMed] [Google Scholar]
  • 51. Mourtada‐Maarabouni M, Sutherland LC, Williams GT. Candidate tumour suppressor LUCA‐15 can regulate multiple apoptotic pathways. Apoptosis. 2002; 7:421–432. [DOI] [PubMed] [Google Scholar]
  • 52. Vlasschaert C, Xia X, Coulombe J, Gray DA. Evolution of the highly networked deubiquitinating enzymes USP4, USP15, and USP11. BMC Evol Biol. 2015; 15:230. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 53. Wei MH, Latif F, Bader S, et al. Construction of a 600‐kilobase cosmid clone contig and generation of a transcriptional map surrounding the lung cancer tumor suppressor gene (TSG) locus on human chromosome 3p21.3: progress toward the isolation of a lung cancer TSG. Cancer Res. 1996; 56:1487–1492. [PubMed] [Google Scholar]
  • 54. Scherly D, Boelens W, Dathan NA, van Venrooij WJ, Mattaj IW. Major determinants of the specificity of interaction between small nuclear ribonucleoproteins U1A and U2B” and their cognate RNAs. Nature. 1990; 345:502–506. [DOI] [PubMed] [Google Scholar]
  • 55. Query CC, Bentley RC, Keene JD. A common RNA recognition motif identified within a defined U1 RNA binding domain of the 70K U1 snRNP protein. Cell 1989; 57:89–101. [DOI] [PubMed] [Google Scholar]
  • 56. Loiselle JJ, Tessier SJ, Sutherland LC. Post‐transcriptional regulation of Rbm5 expression in undifferentiated H9c2 myoblasts. In Vitro Cell Dev Biol Anim. 2016; 52:327–336. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 57. Peng J, Valeshabad AK, Li Q, Wang Y. Differential expression of RBM5 and KRAS in pancreatic ductal adenocarcinoma and their association with clinicopathological features. Oncol Lett. 2013; 5:1000–1004. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 58. Garrisi VM, Strippoli S, De SS, et al. Proteomic profile and in silico analysis in metastatic melanoma with and without BRAF mutation. PLoS ONE. 2014; 9:e112025. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 59. Smith KS, Yadav VK, Pedersen BS, et al. Signatures of accelerated somatic evolution in gene promoters in multiple cancer types. Nucleic Acids Res. 2015; 43:5307–5317. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 60. Powis Z, Hart A, Cherny S, et al. Clinical diagnostic exome evaluation for an infant with a lethal disorder: genetic diagnosis of TARP syndrome and expansion of the phenotype in a patient with a newly reported RBM10 alteration. BMC Med Genet. 2017; 18:60. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 61. Loiselle JJ, Sutherland LC. Differential downregulation of Rbm5 and Rbm10 during skeletal and cardiac differentiation. In Vitro Cell Dev Biol Anim. 2014; 50:331–339. [DOI] [PubMed] [Google Scholar]
  • 62.TCGA (2014) Comprehensive molecular profiling of lung adenocarcinoma. Nature. 2014; 511:543–550. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 63. Kan Z, Jaiswal BS, Stinson J, et al. Diverse somatic mutation patterns and pathway alterations in human cancers. Nature. 2010; 466:869–873. [DOI] [PubMed] [Google Scholar]
  • 64. Bonnal S, Martinez C, Forch P, Bachi AW, Wilm M, Valcarcel J. RBM5/Luca‐15/H37 regulates Fas alternative splice site pairing after exon definition. Mol Cell. 2008; 32:81–95. [DOI] [PubMed] [Google Scholar]

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