miR-6893-3p is a bonafide negative regulator of splicing activator, RNPS1.

RNA-binding protein with serine-rich domain 1, RNPS1, is a global guardian of splicing fidelity and has implications in cervical cancer cell progression. We previously observed elevated RNPS1 expression in cervical cancer cells compared to normal cells. To understand the mechanisms that lead to the dysregulation of RNPS1 expression in cervical cancer cells, we focused on microRNAs. Using an in silico approach, we predicted potential miRNA candidates targeting RNPS1. Among the candidate miRNAs, we found miR-6893-3p as a potential regulator of RNPS1 expression. Interestingly, the expression of miR-6893-3p is downregulated in cervical cancer cells compared to normal cells and its level is negatively correlated with the expression of RNPS1. Further, qPCR, Western blot analysis, and luciferase reporter assay confirmed that miR-6893-3p negatively regulates RNPS1 in HeLa cells. In this regard, overexpression of miR-6893-3p suppresses the endogenous mRNA and protein levels of RNPS1 in HeLa cells. Further investigation revealed that miR-6893-3p mediated regulation of RNPS1 is dependent on the binding of miR-6893-3p to a microRNA response element in the 3'UTR of RNPS1 mRNA. Furthermore, mechanistic analysis showed that targeted negative regulation of RNPS1 by miR-6893-3p occurs via enhanced mRNA degradation. Collectively, our findings establish miR-6893-3p as an important player in the post-transcriptional regulation of RNPS1 in HeLa cells. Supplementary Information: The online version contains supplementary material available at 10.1007/s13205-023-03761-2.

Serine-rich domain of RNPS1 functions in activation of alternative splicing.

RNA-binding protein with serine-rich domain 1 (RNPS1) gets deposited on the mRNA during the process of splicing and concomitantly associates with the exon junction complex (EJC). RNPS1 participates in post-transcriptional gene regulation, including constitutive and alternative splicing, transcriptional regulation and nonsense-mediated mRNA decay. In this study, we found that the tethering of RNPS1 or its isolated serine-rich domain (S domain) causes exon inclusion of an HIV-1 splicing substrate. In contrast, overexpressing the RRM domain of RNPS1 acts in a dominant negative manner and leads to the exon skipping of endogenous apoptotic pre-mRNAs (Bcl-X and MCL-1). Further, tethering of core EJC proteins, eIF4A3, MAGOH, or Y14, does not lead to exon inclusion of an HIV substrate. Together, our results demonstrate how RNPS1 and its domains are differentially involved in alternative splicing activity.

RNPS1 functions as an oncogenic splicing factor in cervical cancer cells.

Numerous recent studies suggest that cancer-specific splicing alteration is a critical contributor to the pathogenesis of cancer. RNA-binding protein with serine-rich domain 1, RNPS1, is an essential regulator of the splicing process. However, the defined role of RNPS1 in tumorigenesis still remains elusive. We report here that the expression of RNPS1 is higher in cervical carcinoma samples from The Cancer Genome Atlas (TCGA-cervical squamous cell carcinoma and endocervical adenocarcinoma) compared to the normal tissues. Consistently, the expression of RNPS1 was high in cervical cancer cells compared to a normal cell line. This study shows for the first time that RNPS1 promotes cell proliferation and colony-forming ability of cervical cancer cells. Importantly, RNPS1 positively regulates migration-invasion of cervical cancer cells. Intriguingly, depletion of RNPS1 increases the chemosensitivity against the chemotherapeutic drug doxorubicin in cervical cancer cells. Further, we characterized the genome-wide isoform switching stimulated by RNPS1 in cervical cancer cell. Mechanistically, RNA-sequencing analysis showed that RNPS1 regulates the generation of tumor-associated isoforms of key genes, particularly Rac1b, RhoA, MDM4, and WDR1, through alternative splicing. RNPS1 regulates the splicing of Rac1 pre-mRNA via a specific alternative splicing switch and promotes the formation of its tumorigenic splice variant, Rac1b. While the transcriptional regulation of RhoA has been well studied, the role of alternative splicing in RhoA upregulation in cancer cells is largely unknown. Here, we have shown that the knockdown of RNPS1 in cervical cancer cells leads to the skipping of exons encoding the RAS domain of RhoA, consequently causing decreased expression of RhoA. Collectively, we conclude that the gain of RNPS1 expression may be associated with tumor progression in cervical carcinoma. RNPS1-mediated alternative splicing favors an active Rac1b/RhoA signaling axis that could contribute to cervical cancer cell invasion and metastasis. Thus, our work unveils a novel role of RNPS1 in the development of cervical cancer.

Molecular cloning, expression and generation of a polyclonal antibody specific for RNPS1.

BACKGROUND: RNA-binding protein with serine-rich domain 1 (RNPS1) is a member of a splicing-dependent mega Dalton protein complex or exon junction complex (EJC). During splicing, RNPS1 acts as a protector of global transcriptome integrity by suppressing the usage of cryptic splice sites. Additionally, RNPS1 functions in almost all stages of mRNA metabolism, including constitutive splicing, alternative splicing, translation and nonsense-mediated mRNA decay (NMD). The aim of the present study was to generate a highly specific polyclonal antibody against human RNPS1. METHODS AND RESULTS: A plasmid, pHis-TEV-RNPS1, has been constructed to overexpress recombinant RNPS1 (22-305 amino acids) by cloning the nucleotide sequence downstream of an N-terminal His-tag in the parent plasmid pHis-TEV. The recombinant plasmid was then transformed into Rosetta and expression was induced using IPTG. The His-tagged RNPS1 protein was purified using Ni-NTA affinity chromatography. The rabbit antiserum was then obtained by immunizing rabbits with the purified recombinant RNPS1 protein. The antiserum was further purified by antigen-immunoaffinity chromatography. The sensitivity and the specificity of the polyclonal antibody were assessed by enzyme-linked immunosorbent assay (ELISA) and knockdown assay. ELISA demonstrated that the antibody has a high binding affinity for RNPS1 and the usable titre is 1:2000. CONCLUSION: The antibody detected RNPS1 in human, mouse cell lines and rat tissue in Western blot. Importantly, the antibody efficiently detected the decrease in RNPS1 expression in siRNA induced knockdown assay, indicating the specificity of the antibody. The polyclonal antibody against RNPS1 will be a useful tool for performing further functional studies on RNPS1.

Functional roles of human Up-frameshift suppressor 3 (UPF3) proteins: From nonsense-mediated mRNA decay to neurodevelopmental disorders.

Nonsense-mediated mRNA decay (NMD) is a post-transcriptional quality control mechanism that eradicates aberrant transcripts from cells. Aberrant transcripts are recognized by translating ribosomes, eRFs, and trans-acting NMD factors leading to their degradation. The trans-factors are conserved among eukaryotes and consist of UPF1, UPF2, and UPF3 proteins. Intriguingly, in humans, UPF3 exists as paralog proteins, UPF3A, and UPF3B. While UPF3 paralogs are traditionally known to be involved in the NMD pathway, there is a growing consensus that there are other critical cellular functions beyond quality control that are dictated by the UPF3 proteins. This review presents the current knowledge on the biochemical functions of UPF3 paralogs in diverse cellular processes, including NMD, translation, and genetic compensation response. We also discuss the contribution of the UPF3 paralogs in development and function of the central nervous system and germ cells. Furthermore, significant advances in the past decade have provided new perspectives on the implications of UPF3 paralogs in neurodevelopmental diseases. In this regard, genome- and transcriptome-wide sequencing analysis of patient samples revealed that loss of UPF3B is associated with brain disorders such as intellectual disability, autism, attention deficit hyperactivity disorder, and schizophrenia. Therefore, we further aim to provide an insight into the brain diseases associated with loss-of-function mutations of UPF3B.

The arginine and serine-rich domains of Acinus modulate splicing.

Apoptotic chromatin condensation inducer in the nucleus (Acinus) is an RNA-binding protein that has a functional role in inducing apoptotic chromatin condensation and regulating messenger RNA (mRNA) processing. Acinus interacts with the spliceosomal machinery and is a member of the ASAP (apoptosis and splicing-associated protein complex) as well as the EJC (exon junction complex), which gets deposited onto mRNA during splicing. In this study, we have used in vivo splicing assays to characterize the function of Acinus in pre-mRNA splicing more closely. We show that full-length Acinus-S', an isoform of Acinus, does not have a role in modulating splice site selection in human immunodeficiency virus 1 minigene reporter system. In contrast, we observed that the tethering of arginine/serine (RS) and RNPS1-SAP18-binding (RSB) domains of Acinus could regulate the selection of alternative splice sites, thereby revealing the potential of Acinus in stimulating alternative splicing. Altogether, our data suggest that the RS and RSB domains play a critical role in regulating splicing activity via selection of distinct splice sites during pre-mRNA splicing.

Hypocholesterolemic activity of indigenous probiotic isolate Saccharomyces cerevisiae ARDMC1 in a rat model.

The aim of this study was to investigate probiotic attributes of Saccharomyces cerevisiae ARDMC1 isolated from traditional rice beer starter cake and its hypocholesterolemic effects on Wistar rats fed a high-cholesterol diet. The indigenous isolate ARDMC1 showed potential probiotic characteristics such as tolerance to simulated gastrointestinal stress conditions, autoaggregation properties, and adhesion to intestinal epithelium Caco-2 cell line. In addition, ARDMC1 isolate exhibited in vitro cholesterol assimilation properties in media supplemented with cholesterol. Furthermore, administration of probiotic isolate to rats fed a hypercholesterolemic diet resulted in significant reduction of serum total cholesterol, low-density lipoprotein cholesterol, and triglyceride at the end of 42 days. The present study envisages ARDMC1 as a promising starter culture for the preparation of functional foods with properties to combat cardiovascular diseases.

Multifaceted Regulation of Gene Expression by the Apoptosis- and Splicing-Associated Protein Complex and Its Components.

The differential deposition of RNA-binding proteins (RBPs) on pre-mRNA mediates the processes of gene expression. One of the complexes containing RBPs that play a crucial part in RNA metabolism is the apoptosis-and splicing-associated protein (ASAP) complex. In this review, we present a summary of the structure of ASAP complex and its localization. Also, we discuss the findings by different groups on various functions of the subunits of the ASAP complex in RNA metabolism. The subunits of the ASAP complex are RNPS1, Acinus and SAP18. Originally, the ASAP complex was thought to link RNA processing with apoptosis. Further studies have shown the role of these components in RNA metabolism of cells, including transcription, splicing, translation and nonsense-mediated mRNA decay (NMD). In transcription, RNPS1 is involved in preventing the formation of R-loop, while Acinus and SAP18 suppress transcription with the help of histone deacetylase. On the one hand, individual components of the ASAP complex, namely RNPS1 and Acinus act as splicing activators, whereas on the other hand, in-vitro assay shows that the ASAP complex behaves as splicing repressor. In addition, the individual members of the ASAP complex associates with the exon junction complex (EJC) to play roles in splicing and translation. RNPS1 increases the translation efficiency by participating in the 3'end processing and polysome association of mRNAs. Similarly, during NMD RNPS1 aids in the recruitment of decay factors by interacting with EJC.

In silico analysis of 5'-UTRs highlights the prevalence of Shine-Dalgarno and leaderless-dependent mechanisms of translation initiation in bacteria and archaea, respectively.

In prokaryotes, a heterogeneous set of protein translation initiation mechanisms such as Shine-Dalgarno (SD) sequence-dependent, SD sequence-independent or ribosomal protein S1 mediated and leaderless transcript-dependent exists. To estimate the distribution of coding sequences employing a particular translation initiation mechanism, a total of 107 prokaryotic genomes were analysed using in silico approaches. Analysis of 5'-untranslated regions (UTRs) of genes reveals the existence of three types of mRNAs described as transcripts with and without SD motif and leaderless transcripts. Our results indicate that although all the three types of translation initiation mechanisms are widespread among prokaryotes, the number of SD-dependent genes in bacteria is higher than that of archaea. In contrast, archaea contain a significantly higher number of leaderless genes than SD-led genes. The correlation analysis between genome size and SD-led & leaderless genes suggests that the SD-led genes are decreasing (increasing) with genome size in bacteria (archaea). However, the leaderless genes are increasing (decreasing) in bacteria (archaea) with genome size. Moreover, an analysis of the start-codon biasness confirms that among ATG, GTG and TTG codons, ATG is indeed the most preferred codon at the translation initiation site in most of the coding sequences. In leaderless genes, however, the codons GTG and TTG are also observed at the translation initiation site in some species contradicting earlier studies which suggested the usage of only ATG codon. Henceforth, the conventional mechanism of translation initiation cannot be generalized as an exclusive way of initiating the process of protein biosynthesis in prokaryotes.