Role In mRNA Stability Research Articles

Oligo-Adenine Derived Secondary Nucleic Acid Frameworks: From Structural Characteristics to Applications.

Oligo-adenine (polyA) is primarily known for its critical role in mRNA stability, translational status, and gene regulation. Beyond its biological functions, extensive research has unveiled the diverse applications of polyA. In response to environmental stimuli, single polyA strands undergo distinctive structural transitions into diverse secondary configurations, which are reversible upon the introduction of appropriate counter-triggers. In this review, we systematically summarize recent advances of noncanonical structures derived from polyA, including A-motif duplex, A-cyanuric acid triplex, A-coralyne-A duplex, and T ⋅ A-T triplex. The structural characteristics and mechanisms underlying these conformations under specific external stimuli are addressed, followed by examples of their applications in stimuli-responsive DNA hydrogels, supramolecular fibre assembly, molecular electronics and switches, biosensing and bioengineering, payloads encapsulation and release, and others. A detailed comparison of these polyA-derived noncanonical structures is provided, highlighting their distinctive features. Furthermore, by integrating their stimuli-responsiveness and conformational characteristics, advanced material development, such as pH-cascaded DNA hydrogels and supramolecular fibres exhibiting dynamic structural transitions adapting environmental cues, are introduced. An outlook for future developments is also discussed. These polyA derived, stimuli-responsive, noncanonical structures enrich the arsenal of DNA "toolbox", offering dynamic DNA frameworks for diverse future applications.

ADAR3 modulates neuronal differentiation and regulates mRNA stability and translation.

ADAR3 is a catalytically inactive member of the family of adenosine deaminases acting on RNA (ADARs). Here we have investigated its function in the context of the developing mouse brain. The expression of ADAR3 gradually increases throughout embryogenesis and drops after birth. Using primary cortical neurons, we show that ADAR3 is only expressed in a subpopulation of in vitro differentiated neurons, which suggests specific functions rather than being a general regulator of ADAR editing in the brain. The analysis of the ADAR3 interactome suggested a role in mRNA stability and translation, and we show that expression of ADAR3 in a neuronal cell line that is otherwise ADAR3-negative changes the expression and stability of a large number of mRNAs. Notably, we show that ADAR3 associates with polysomes and inhibits translation. We propose that ADAR3 binds to target mRNAs and stabilizes them in non-productive polysome complexes. Interestingly, the expression of ADAR3 downregulates genes related to neuronal differentiation and inhibits neurofilament outgrowth in vitro. In summary, we propose that ADAR3 negatively regulates neuronal differentiation, and that it does so by regulating mRNA stability and translation in an editing-independent manner.

M6A modification plays an integral role in mRNA stability and translation during pattern-triggered immunity

Plants employ distinct mechanisms to respond to environmental changes. Modification of mRNA by N 6-methyladenosine (m6A), known to affect the fate of mRNA, may be one such mechanism to reprogram mRNA processing and translatability upon stress. However, it is difficult to distinguish a direct role from a pleiotropic effect for this modification due to its prevalence in RNA. Through characterization of the transient knockdown-mutants of m6A writer components and mutants of specific m6A readers, we demonstrate the essential role that m6A plays in basal resistance and pattern-triggered immunity (PTI). A global m6A profiling of mock and PTI-induced Arabidopsis plants as well as formaldehyde fixation and cross-linking immunoprecipitation-sequencing of the m6A reader, EVOLUTIONARILY CONSERVED C-TERMINAL REGION2 (ECT2) showed that while dynamic changes in m6A modification and binding by ECT2 were detected upon PTI induction, most of the m6A sites and their association with ECT2 remained static. Interestingly, RNA degradation assay identified a dual role of m6A in stabilizing the overall transcriptome while facilitating rapid turnover of immune-induced mRNAs during PTI. Moreover, polysome profiling showed that m6A enhances immune-associated translation by binding to the ECT2/3/4 readers. We propose that m6A plays a positive role in plant immunity by destabilizing defense mRNAs while enhancing their translation efficiency to create a transient surge in the production of defense proteins.

Poly (A)-specific ribonuclease deficiency impacts oogenesis in zebrafish

Poly (A)-specific ribonuclease (PARN) is the most important 3′–5′exonuclease involved in the process of deadenylation, the removal of poly (A) tails of mRNAs. Although PARN is primarily known for its role in mRNA stability, recent studies suggest several other functions of PARN including a role in telomere biology, non-coding RNA maturation, trimming of miRNAs, ribosome biogenesis and TP53 function. Moreover, PARN expression is de-regulated in many cancers, including solid tumours and hematopoietic malignancies. To better understand the in vivo role of PARN, we used a zebrafish model to study the physiological consequences of Parn loss-of-function. Exon 19 of the gene, which partially codes for the RNA binding domain of the protein, was targeted for CRISPR-Cas9-directed genome editing. Contrary to the expectations, no developmental defects were observed in the zebrafish with a parn nonsense mutation. Intriguingly, the parn null mutants were viable and fertile, but turned out to only develop into males. Histological analysis of the gonads in the mutants and their wild type siblings revealed a defective maturation of gonadal cells in the parn null mutants. The results of this study highlight yet another emerging function of Parn, i.e., its role in oogenesis.

Dynamically regulated transcription factors are encoded by highly unstable mRNAs in the Drosophila larval brain.

The level of each RNA species depends on the balance between its rates of production and decay. Although previous studies have measured RNA decay across the genome in tissue culture and single-celled organisms, few experiments have been performed in intact complex tissues and organs. It is therefore unclear whether the determinants of RNA decay found in cultured cells are preserved in an intact tissue, and whether they differ between neighboring cell types and are regulated during development. To address these questions, we measured RNA synthesis and decay rates genome wide via metabolic labeling of whole cultured Drosophila larval brains using 4-thiouridine. Our analysis revealed that decay rates span a range of more than 100-fold, and that RNA stability is linked to gene function, with mRNAs encoding transcription factors being much less stable than mRNAs involved in core metabolic functions. Surprisingly, among transcription factor mRNAs there was a clear demarcation between more widely used transcription factors and those that are expressed only transiently during development. mRNAs encoding transient transcription factors are among the least stable in the brain. These mRNAs are characterized by epigenetic silencing in most cell types, as shown by their enrichment with the histone modification H3K27me3. Our data suggest the presence of an mRNA destabilizing mechanism targeted to these transiently expressed transcription factors to allow their levels to be regulated rapidly with high precision. Our study also demonstrates a general method for measuring mRNA transcription and decay rates in intact organs or tissues, offering insights into the role of mRNA stability in the regulation of complex developmental programs.

Evidence for Epistatic Interaction between HLA-G and LILRB1 in the Pathogenesis of Nonsegmental Vitiligo.

Vitiligo is the most frequent cause of depigmentation worldwide. Genetic association studies have discovered about 50 loci associated with disease, many with immunological functions. Among them is HLA-G, which modulates immunity by interacting with specific inhibitory receptors, mainly LILRB1 and LILRB2. Here we investigated the LILRB1 and LILRB2 association with vitiligo risk and evaluated the possible role of interactions between HLA-G and its receptors in this pathogenesis. We tested the association of the polymorphisms of HLA-G, LILRB1, and LILRB2 with vitiligo using logistic regression along with adjustment by ancestry. Further, methods based on the multifactor dimensionality reduction (MDR) approach (MDR v.3.0.2, GMDR v.0.9, and MB-MDR) were used to detect potential epistatic interactions between polymorphisms from the three genes. An interaction involving rs9380142 and rs2114511 polymorphisms was identified by all methods used. The polymorphism rs9380142 is an HLA-G 3'UTR variant (+3187) with a well-established role in mRNA stability. The polymorphism rs2114511 is located in the exonic region of LILRB1. Although no association involving this SNP has been reported, ChIP-Seq experiments have identified this position as an EBF1 binding site. These results highlight the role of an epistatic interaction between HLA-G and LILRB1 in vitiligo pathogenesis.

A second type of N7-guanine RNA cap methyltransferase in an unusual locus of a large RNA virus genome.

The order Nidovirales is a diverse group of (+)RNA viruses, with a common genome organization and conserved set of replicative and editing enzymes. In particular, RNA methyltransferases play a central role in mRNA stability and immune escape. However, their presence and distribution in different Nidovirales families is not homogeneous. In Coronaviridae, the best characterized family, two distinct methytransferases perform methylation of the N7-guanine and 2'-OH of the RNA-cap to generate a cap-1 structure (m7GpppNm). The genes of both of these enzymes are located in the ORF1b genomic region. While 2'-O-MTases can be identified for most other families based on conservation of both sequence motifs and genetic loci, identification of the N7-guanine methyltransferase has proved more challenging. Recently, we identified a putative N7-MTase domain in the ORF1a region (N7-MT-1a) of certain members of the large genome Tobaniviridae family. Here, we demonstrate that this domain indeed harbors N7-specific methyltransferase activity. We present its structure as the first N7-specific Rossmann-fold (RF) MTase identified for (+)RNA viruses, making it remarkably different from that of the known Coronaviridae ORF1b N7-MTase gene. We discuss the evolutionary implications of such an appearance in this unexpected location in the genome, which introduces a split-off in the classification of Tobaniviridae.

The RNA-Binding Landscape of HAX1 Protein Indicates Its Involvement in Translation and Ribosome Assembly.

HAX1 is a human protein with no known homologues or structural domains. Mutations in the HAX1 gene cause severe congenital neutropenia through mechanisms that are poorly understood. Previous studies reported the RNA-binding capacity of HAX1, but the role of this binding in physiology and pathology remains unexplained. Here, we report the transcriptome-wide characterization of HAX1 RNA targets using RIP-seq and CRAC, indicating that HAX1 binds transcripts involved in translation, ribosome biogenesis, and rRNA processing. Using CRISPR knockouts, we find that HAX1 RNA targets partially overlap with transcripts downregulated in HAX1 KO, implying a role in mRNA stabilization. Gene ontology analysis demonstrated that genes differentially expressed in HAX1 KO (including genes involved in ribosome biogenesis and translation) are also enriched in a subset of genes whose expression correlates with HAX1 expression in four analyzed neoplasms. The functional connection to ribosome biogenesis was also demonstrated by gradient sedimentation ribosome profiles, which revealed differences in the small subunit:monosome ratio in HAX1 WT/KO. We speculate that changes in HAX1 expression may be important for the etiology of HAX1-linked diseases through dysregulation of translation.

Molecular Insights into mRNA Polyadenylation and Deadenylation

Poly(A) tails are present on almost all eukaryotic mRNAs, and play critical roles in mRNA stability, nuclear export, and translation efficiency. The biosynthesis and shortening of a poly(A) tail are regulated by large multiprotein complexes. However, the molecular mechanisms of these protein machineries still remain unclear. Recent studies regarding the structural and biochemical characteristics of those protein complexes have shed light on the potential mechanisms of polyadenylation and deadenylation. This review summarizes the recent structural studies on pre-mRNA 3′-end processing complexes that initiate the polyadenylation and discusses the similarities and differences between yeast and human machineries. Specifically, we highlight recent biochemical efforts in the reconstitution of the active human canonical pre-mRNA 3′-end processing systems, as well as the roles of RBBP6/Mpe1 in activating the entire machinery. We also describe how poly(A) tails are removed by the PAN2-PAN3 and CCR4-NOT deadenylation complexes and discuss the emerging role of the cytoplasmic poly(A)-binding protein (PABPC) in promoting deadenylation. Together, these recent discoveries show that the dynamic features of these machineries play important roles in regulating polyadenylation and deadenylation.

Y-Complex Proteins Show RNA-Dependent Binding Events at the Cell Membrane and Distinct Single-Molecule Dynamics.

Bacteria are dependent on rapid alterations in gene expression. A prerequisite for rapid adaptations is efficient RNA turnover, with endonuclease RNase Y playing a crucial role in mRNA stability as well as in maturation. In Bacillus subtilis, RNase Y in turn interacts with the so-called “Y-complex” consisting of three proteins, which play important functions in sporulation, natural transformation and biofilm formation. It is thought that the Y-complex acts as an accessory factor in RNase Y regulation but might also have independent functions. Using single-molecule tracking, we show that all three Y-complex proteins exhibit three distinct mobilities, including movement through the cytosol and confined motion, predominantly at membrane-proximal sites but also within the cell center. A transcriptional arrest leads to a strong change in localization and dynamics of YmcA, YlbF and YaaT, supporting their involvement in global RNA degradation. However, Y-complex proteins show distinguishable protein dynamics, and the deletion of yaaT or ylbF shows a minor effect on the dynamics of YmcA. Cell fractionation reveals that YaaT displays a mixture of membrane association and presence in the cytosol, while YlbF and YmcA do not show direct membrane attachment. Taken together, our experiments reveal membrane-associated and membrane-independent activities of Y-complex proteins and a dynamic interplay between them with indirect membrane association of YmcA and YlbF via YaaT.

PARN Knockdown in Cell Lines Results in Differential and Cell-Specific Alterations in the Expression of Cancer-Associated mRNAs.

Ribonucleases (RNases) is the collective term used for the group of enzymes that are involved in mRNA degradation. The shortening of the poly (A) tail through deadenylation is the preferred mechanism of degradation of most eukaryotic mRNAs and poly (A)-specific ribonuclease (PARN) is the most important player in deadenylation. Besides its primarily role in mRNA stability, PARN is also involved in several non-conventional functions. It is conceivable that a decreased RNase activity can alter the stability of cancer-associated mRNAs and this alteration may be differential in cells of different origin. Methods:The effects of siRNA-mediated knockdown of PARN on the post-transcriptional expression of 16 oncogenes and 18 tumor suppressor genes in cells derived from different lineages (NCI-H460 and NCI-H522; lung cancer) and (HEK-293; kidney) were investigated. Further, the effects of PARN depletion on proliferation and death of the lung cancer cells were investigated. Results: Quantitative real time PCR analysis revealed an cell-specific alteration in the expression of the target onco and tumor suppressor genes upon PARN depletion, differently, for cells derived from different lineages. The tumor suppressor genes showed a consistent pattern of down regulation upon PARN depletion in all the three cell types tested. In contrast, the expression of oncogenes was not consistent; while some oncogenes showed overexpression in HEK 293 cells, the majority of them were downregulated in the lung cancer cells. Further, PARN depletion did not alter the proliferation of lung cancer cells, which was in contrast to previous reports. Conclusion:The results of this study reveal that PARN deficiency leads to an altered stability of cancer-associated mRNA, distinctly, in cells of different lineages. Despite previous reports suggesting a potential therapeutic role of PARN in cancer, our results suggest that PARN may not be an important biomarker, particularly in lung cancer.

Mass spectrometric analysis of mRNA 5' terminal modifications.

The 7-methylguanosine (m7G) cap structure, an essential epitranscriptomic mark at the 5' terminus of eukaryotic mRNAs, plays critical roles in mRNA stability, export, and translation. Following the cap structure, the first and second nucleotides at the 5' ends of mRNAs are frequently methylated to give more diverse modifications, especially in vertebrates. To understand the biological roles of the cap structures, precise analyses of the 5' terminal modifications are necessary. Here, we describe a detailed protocol for mass spectrometric analysis of 5' terminal fragments of mRNAs.

Analysis of compensatory mechanisms involved in response to genetic perturbation of drug transporters

A diverse repertoire of xenobiotic transporters from the ABC and SLC families are expressed in clinically relevant cell types. Structural and functional similarity of these transporters’ specificities is known to complicate efforts to perturb them. Given the therapeutic importance of these transporters, it is important to uncover the pathways that could lead to compensation for transporter loss‐of‐function. CRISPR/Cas9 based gene editing is extensively utilized for creating genetic lesions to analyze loss‐of‐function mutations. When applied in embryos a commonly observed outcome is genetic compensation. In the present study we take advantage of CRISPR/Cas9 based knockout of xenobiotic transporters in sea urchin embryos. Sea urchins express orthologs of several ABC transporters including P‐glycoprotein (ABCB1) and MRP1 (ABCC1). The fluorescent substrates and inhibitors of these transporters are also well‐defined providing simple system for analyzing changes in transporter activity in response to mutations. We have designed CRISPR single guide RNAs (sgRNAs) targeting orthologs of P‐glycoprotein (ABCB1, ABCB4), multidrug resistance proteins (ABCC1, ABCC4, ABCC5) and breast cancer resistance protein (ABCG2). Using a known CRISPR target in sea urchins, Nodal, we have successfully created small indels resulting in robust phenotypes. Using a bioinformatics tool called Inference of CRISPR Edits (ICE), we measured a cutting efficiency of 77.16% ±26.5 across four biological replicates. Knockdown of ABCB1a expression by antisense morpholino and inhibition of ABCB1a transporter activity with Valspodar (PSC833) was used to standardize the ABCB1a transporter activity in controls. We observed 2.5‐fold and 10‐fold increase in ABCB‐specific substrate, bodipy‐verapamil (b‐ver), in ABCB1a morphants and PSC inhibited embryos, respectively, while ABCC‐specific substrate, fluorescein diacetate (FDA) showed no change. Using microinjection of single as well as multiplex sgRNA, we now have successfully created cuts in ABCB1a loci resulting in small indels and large deletions, respectively. Currently, ABCB1a crispants are being analyzed for phenotypes using efflux assays. These crispants sometimes show increased accumulation of b‐ver, and strong efflux of FDA indicating compensation by ABCC1. We are also currently working to understand how variation in Cas9 cutting efficiency could relate to phenotypic variability. Recent studies have identified the role of Nonsense Mediated Decay (NMD) of mutant transcripts as one of the triggers for compensation which can be reversed by inhibiting the NMD pathway. As such, future work will focus on the role of mRNA stability and NMD on sensing of lesions in transporter loci. Results from this study could have impact on understanding the emergence of drug resistance and help design more effective ways to overcome it.Support or Funding InformationSupported by R01ES027921 and R01ES030318 to Amro Hamdoun

ScDAPA: detection and visualization of dynamic alternative polyadenylation from single cell RNA-seq data

Alternative polyadenylation (APA) plays a key post-transcriptional regulatory role in mRNA stability and functions in eukaryotes. Single cell RNA-seq (scRNA-seq) is a powerful tool to discover cellular heterogeneity at gene expression level. Given 3' enriched strategy in library construction, the most commonly used scRNA-seq protocol-10× Genomics enables us to improve the study resolution of APA to the single cell level. However, currently there is no computational tool available for investigating APA profiles from scRNA-seq data. Here, we present a package scDAPA for detecting and visualizing dynamic APA from scRNA-seq data. Taking bam/sam files and cell cluster labels as inputs, scDAPA detects APA dynamics using a histogram-based method and the Wilcoxon rank-sum test, and visualizes candidate genes with dynamic APA. Benchmarking results demonstrated that scDAPA can effectively identify genes with dynamic APA among different cell groups from scRNA-seq data. The scDAPA package is implemented in Shell and R, and is freely available at https://scdapa.sourceforge.io. Supplementary data are available at Bioinformatics online.

Abstract 3323: Role of RNA methyltransferase METTL3 in melanoma

Abstract Melanoma is the sixth most common cancer in the USA. Introduction of BRAF inhibitors and advances in cancer immunotherapy has greatly improved treatment of melanoma, however, the problem of tumour relapse and therapy resistance persists. Better understanding of the mechanism of development of the diseases is urgently needed to improve therapeutic intervention. Role of DNA and histone modifications have been well established in several diseases, however, RNA modifications, specifically, N6 methyl adenosine (m6A), has only recently begun to be shown to play critical role in cancer. m6A plays crucial roles in mRNA stability, splicing, export, translation and decay and is regulated by: methyltransferase complex proteins METTL3, METTL14, and WTAP; the demethylases FTO and ALKBH5, and the m6A reader proteins. In the present study, we uncover the role of RNA methyltransferase METTL3 in human melanoma cells. METTL3 expression was assessed in 8 melanoma cell lines (A375, A375MA2, A2058, WM164, 451Lu, WM793, SKMEL2, WM3918). Western blotting data revealed METTL3 to be upregulated in seven melanoma cell lines (except A2058) relative to normal melanocytes. To uncover the role of METTL3 in melanoma, we knockdown METTL3 with lentiviral shRNA and studied the effect on melanoma cells tumorigenesis. The colony formation assay revealed reduced colony number in the METTL3 knockdown A375, A375MA2 and WM793 cells relative to the scrambled control cells. The main cause of melanoma associated fatality is its metastatic dissemination we therefore, next sought to investigate whether METTL3 could affect melanoma cells migration and invasiveness. We performed migration and invasion assays to detect the migratory potential of control or METTL3 knockdown A375, A375MA2 and WM793 cells. Interestingly, both migration and invasion was found to be reduced in METTL3 knockdown cells in all the three cell lines examined. RNA dot blot assay demonstrated a decreased m6A level in total RNA of the METTL3 knockdown cells relative to control cells. p16 and p53 mRNA were found to be enriched in m6A immunoprecipitated samples as compared to IgG control, pointing towards a potential role of m6A in regulating expression of melanoma associated genes. Ongoing effort is aimed at identifying what known or novel regulators of the migratory/invasive cascade is regulated by METTL3 and whether it is through m6A mediated or independent mechanisms. In summary, we have shown that METTL3 is overexpressed in human melanoma and play an important role in metastasis. Citation Format: Ujwal Dahal, Kang Le, Mamta Gupta. Role of RNA methyltransferase METTL3 in melanoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 3323.

Abstract 693: RNA Stability Protein ILF3 Mediates IL-19 Induced Angiogenesis

Angiogenesis is a physiological process vital for growth, development and wound healing but is also a promising therapeutic target for the treatment of ischemic cardiovascular disease. Presently, there is nothing known regarding the role of, the RNA binding protein, Interleukin Enhancer-binding Factor 3 (ILF3) in angiogenesis. RNA binding proteins play crucial roles in cellular processes, specifically, post-transcriptional control of RNAs through mRNA stabilization. We hypothesized that ILF3 plays an essential role in angiogenesis through the stabilization of pro-angiogenic mRNA transcripts. Using immunohistochemistry we identified abundant ILF3 expression in CD31 + vessels of hypoxic porcine cardiac tissue exposed to ischemic myocardial infarction. Using both western blotting and qRT-PCR, we found that pro-angiogenic stimuli, IL-19 and VEGF, induce ILF3 expression in cultured human coronary artery endothelial cells (hEC). Angiogenic proliferation, migration and tube formation are all significantly reduced in hEC when ILF3 is knocked down using siRNA. Importantly, these angiogenic assays are significantly increased when ILF3 is overexpressed in hEC using adenovirus. Using ILF3 siRNA in addition to VEGF stimulation in hEC, several angiogenic factors including CXCL1, IL-8, and HGF are decreased at the transcript and protein level. However, these angiogenic factors are increased when hEC are infected with AdILF3 and stimulated with VEGF. Through immunohistochemistry we found that ILF3 translocates from the nucleus to the cytoplasm of hEC stimulated with VEGF or IL-19 at various time points, suggesting a role in mRNA stability. Using the transcription inhibitor actinomycin D, we found that ILF3 stabilizes pro-angiogenic transcripts including VEGF, CXCL1, and IL-8 in hEC. Together these data suggest that in endothelial cells, the RNA stability protein, ILF3, plays a novel and central role in angiogenesis. We believe that ILF3 is impacting functional angiogenesis through cytokine-inducible mRNA stabilization of pro-angiogenic transcripts.

Genome-wide analysis shows that RNase G plays a global role in the stability of mRNAs in Stenotrophomonas maltophilia

Gene expression is determined by critical processes such as RNA synthesis and degradation. Ribonucleases participate in the coordinated and differential decay of messenger RNAs. We describe a suitable method of normalization and calculation of mRNAs half-life values quantified by RNA-Seq. We determined the mRNA half-lives of more than 2000 genes in Stenotrophomonas maltophilia D457 and in an isogenic RNase G deficient mutant. Median half-lives were 2,74 and 3 min in the wild-type and the rng-deficient strain, respectively. The absence of RNase G resulted in an overall enhancement of mRNA half-life times, showing that many RNAs are targets of RNase G in S. maltophilia. Around 40 genes are likely to be regulated directly by RNase G since their half-lives were more than two-fold higher in the rng-deficient mutant. Gene length, GC content or expression levels did not correlate with mRNAs lifetimes, although groups of genes with different functions showed different RNA half-lives. Further, we predicted 1542 gene pairs to be part of the same operons in S. maltophilia. In contrast to what was described for other bacteria, our data indicate that RNase G has a global role in mRNA stability and consequently in the regulation of S. maltophilia gene expression.

Regulation of mRNA turnover in cystic fibrosis lung disease.

Cystic fibrosis (CF) is an autosomal recessive disease due to mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene, F508del-CFTR being the most frequent mutation. The CF lung is characterized by a hyperinflammatory phenotype and is regulated by multiple factors that coordinate its pathophysiology. In CF the expression of CFTR as well as proinflammatory genes are regulated at the level of messenger RNA (mRNA) stability, which subsequently affect translation. These mechanisms are mediated by inflammatory RNA-binding proteins as well as small endogenous noncoding microRNAs, in coordination with cellular signaling pathways. These regulatory factors exhibit altered expression and function in vivo in the CF lung, and play a key role in the pathophysiology of CF lung disease. In this review, we have described the role of mRNA stability and associated regulatory mechanisms in CF lung disease. WIREs RNA 2017, 8:e1408. doi: 10.1002/wrna.1408 For further resources related to this article, please visit the WIREs website.

Neonatal cardiac dysfunction and transcriptome changes caused by the absence of Celf1.

The RNA binding protein Celf1 regulates alternative splicing in the nucleus and mRNA stability and translation in the cytoplasm. Celf1 is strongly down-regulated during mouse postnatal heart development. Its re-induction in adults induced severe heart failure and reversion to fetal splicing and gene expression patterns. However, the impact of Celf1 depletion on cardiac transcriptional and posttranscriptional dynamics in neonates has not been addressed. We found that homozygous Celf1 knock-out neonates exhibited cardiac dysfunction not observed in older homozygous animals, although homozygous mice are smaller than wild type littermates throughout development. RNA-sequencing of mRNA from homozygous neonatal hearts identified a network of cell cycle genes significantly up-regulated and down-regulation of ion transport and circadian genes. Cell cycle genes are enriched for Celf1 binding sites supporting a regulatory role in mRNA stability of these transcripts. We also identified a cardiac splicing network coordinated by Celf1 depletion. Target events contain multiple Celf1 binding sites and enrichment in GU-rich motifs. Identification of direct Celf1 targets will advance our knowledge in the mechanisms behind developmental networks regulated by Celf1 and diseases where Celf1 is mis-regulated.

Stabilization of Oncostatin-M mRNA by Binding of Nucleolin to a GC-Rich Element in Its 3'UTR.

Oncostatin-M (OSM) is a patho-physiologically important pleiotropic, multifunctional cytokine. OSM mRNA sequence analysis revealed that its 3'UTR contains three highly conserved GC-rich cis-elements (GCREs) whose role in mRNA stability is unidentified. In the present study, the functional role of the proximal GC-rich region of osm 3'-UTR (GCRE-1) in post-transcriptional regulation of osm expression in U937 cells was assessed by transfecting construct containing GCRE-1 at 3'-end of a fairly stable reporter gene followed by analysis of the expression of the reporter. GCRE-1 showed mRNA destabilizing activity; however, upon PMA treatment the reporter message containing GCRE-1 was stabilized. This stabilization is owing to a time-dependent progressive binding of trans-factors (at least five proteins) to GCRE-1 post-PMA treatment. Nucleolin was identified as one of the proteins in the RNP complex of GCRE-1 with PMA-treated U937 cytosolic extracts by oligo-dT affinity chromatography of poly-adenylated GCRE-1. Immuno-blot revealed time-dependent enhancement of nucleolin in the cytoplasm which in turn directly binds GCRE-1. RNA co-immunoprecipitation confirmed the GCRE-1-nucleolin interaction in vivo. To elucidate the functional role of nucleolin in stabilization of osm mRNA, nucleolin was overexpressed in U937 cells and found to stabilize the intrinsic osm mRNA, where co-transfection with the reporter containing GCRE-1 confirms the role of GCRE-1 in stabilization of the reporter mRNA. Thus, in conclusion, the results asserted that PMA treatment in U937 cells leads to cytoplasmic translocation of nucleolin that directly binds GCRE-1, one of the major GC-rich instability elements, thereby stabilizing the osm mRNA.