Splicing In Development Research Articles

Isoform characterisation & splicing signatures of AD‐risk genes using long‐read sequencing

AbstractBackgroundAn increasing number of studies implicate a role for alternative splicing in development and neuropathology of Alzheimer’s disease (AD). However, it has been historically challenging to characterise splicing events, due to the inherent limitations of traditional RNA‐sequencing (RNA‐Seq) to capture full‐length transcripts critical for transcriptome assembly. In this study, we use two complementary targeted long‐read sequencing approaches, Pacific Biosciences (PacBio) isoform sequencing (Iso‐Seq) and Oxford Nanopore Technologies (ONT) nanopore cDNA sequencing, to profile the cortex of a mouse model of tau pathology (rTg4510) with ultra‐deep sequencing of a panel of 20 genes robustly implicated in AD.MethodTargeted PacBio Iso‐Seq and targeted ONT profiling were performed on RNA isolated from 24 female rTg4510 transgenic and wild‐type mice, aged 2, 4, 6 and 8 months. Following successful enrichment for target genes using custom‐designed probes (IDT), library preparation were performed for subsequent sequencing on Sequel and MinION. The panel of genes selected for enrichment included genes (i.e. App, Mapt, Snca) and dementia risk genes identified from GWAS analyses. Raw sequence data was processed using a customised bioinformatics, and full‐length reads were merged and annotated with our developed custom scripts (FICLE).ResultWe identify thousands of novel transcripts across the panel of 20 AD‐ and dementia‐associated genes. We reveal unprecedented diversity of alternatively‐spliced isoforms with widespread usage of alternative novel 5’ and 3’ splice sites. We further robust transcriptional and splicing differences in these AD‐risk genes associated with the development of tau pathology. Among these changes, we observed global up‐regulation of Trem2‐associated isoforms and isoform switches in Bin1, further supporting a role for the dysregulation of the immune response in the development of AD pathology.ConclusionThis represents the first study to comprehensively assess variable AS associated with the development of tau pathology using both PacBio Iso‐Seq and ONT nanopore sequencing. Our analyses confirm the importance of alternative RNA splicing in AD and identify evidence of differential transcript usage, even in the absence of gene‐level expression alterations. Further work will be undertaken to validate and functionally characterise these novel isoforms, and to extend these analyses to human post‐mortem AD brain samples.

Splicing factor TRA2A contributes to esophageal cancer progression via a noncanonical role in lncRNA m6 A methylation.

Transformer 2 alpha homolog (TRA2A), a member of the serine/arginine-rich splicing factor family, has been shown to control mRNA splicing in development and cancers. However, it remains unclear whether TRA2A is involved in lncRNA regulation. In the present study, we found that TRA2A was upregulated and correlated with poor prognosis in esophageal cancer. Downregulation of TRA2A suppressed the tumor growth in xenograft nude mice. Epitranscriptomic microarray showed that depletion of TRA2A affected global lncRNA methylation similarly to the key m6 A methyltransferase, METTL3, by silencing. MeRIP-qPCR, RNA pull-down, CLIP analyses, and stability assays indicated that ablation of TRA2A reduced m6 A-modification of the oncogenic lncRNA MALAT1, thus inducing structural alterations and reduced stability. Furthermore, Co-IP experiments showed TRA2A directly interacted with METTL3 and RBMX, which also affected the writer KIAA1429 expression. Knockdown of TRA2A inhibited cell proliferation in a manner restored by RBMX/KIAA1429 overexpression. Clinically, MALAT1, RBMX, and KIAA1429 were prognostic factors of worse survival in ESCA patients. Structural similarity-based virtual screening in FDA-approved drugs repurposed nebivolol, a β1 -adrenergic receptor antagonist, as a potent compound to suppress the proliferation of esophageal cancer cells. Cellular thermal shift and RIP assay indicated that nebivolol may compete with MALAT1 to bind TRA2A. In conclusion, our study revealed the noncanonical function of TRA2A, which coordinates with multiple methylation proteins to promote oncogenic MALAT1 during ESCA carcinogenesis.

Exploring the Diverse Functional and Regulatory Consequences of Alternative Splicing in Development and Disease.

Alternative splicing is a fundamental mechanism of eukaryotic RNA regulation that increases the transcriptomic and proteomic complexity within an organism. Moreover, alternative splicing provides a framework for generating unique yet complex tissue- and cell type-specific gene expression profiles, despite using a limited number of genes. Recent efforts to understand the negative consequences of aberrant splicing have increased our understanding of developmental and neurodegenerative diseases such as spinal muscular atrophy, frontotemporal dementia and Parkinsonism linked to chromosome 17, myotonic dystrophy, and amyotrophic lateral sclerosis. Moreover, these studies have led to the development of innovative therapeutic treatments for diseases caused by aberrant splicing, also known as spliceopathies. Despite this, a paucity of information exists on the physiological roles and specific functions of distinct transcript spliceforms for a given gene. Here, we will highlight work that has specifically explored the distinct functions of protein-coding spliceforms during development. Moreover, we will discuss the use of alternative splicing of noncoding exons to regulate the stability and localization of RNA transcripts.

TMOD-30. NTRK2 SPLICE VARIANT, TRKB.T1, LINKS NEUROBIOLOGY, EMBRYONIC DEVELOPMENT, AND ONCOGENESIS

Abstract Temporally regulated alternative splicing choices are vital for proper development yet the wrong splice choice may be detrimental. Here we highlight a novel role for the neurotrophin receptor splice variant TrkB.T1 in neurodevelopment, embryogenesis, transformation, and oncogenesis across multiple tumor types in both humans and mice. TrkB.T1 is the predominant NTRK2 isoform across embryonic organogenesis and is highly expressed in a wide range of adult and pediatric tumors. Further, forced expression of TrkB.T1 causes multiple solid and non-solid tumors in mice in the context of tumor suppressor loss. These results highlight a unique role for the neurotrophin receptor splicing in development and oncogenesis and underscore the need for considering alternative splicing and transcript level data in neuroscience, developmental biology, and oncology research.

Alternative Splicing in Cardiovascular Disease-A Survey of Recent Findings.

Alternative splicing, a driver of posttranscriptional variance, differs from canonical splicing by arranging the introns and exons of an immature pre-mRNA transcript in a multitude of different ways. Although alternative splicing was discovered almost half a century ago, estimates of the proportion of genes that undergo alternative splicing have risen drastically over the last two decades. Deep sequencing methods and novel bioinformatic algorithms have led to new insights into the prevalence of spliced variants, tissue-specific splicing patterns and the significance of alternative splicing in development and disease. Thus far, the role of alternative splicing has been uncovered in areas ranging from heart development, the response to myocardial infarction to cardiac structural disease. Circular RNAs, a product of alternative back-splicing, were initially discovered in 1976, but landmark publications have only recently identified their regulatory role, tissue-specific expression, and transcriptomic abundance, spurring a renewed interest in the topic. The aim of this review is to provide a brief insight into some of the available findings on the role of alternative splicing in cardiovascular disease, with a focus on atherosclerosis, myocardial infarction, heart failure, dilated cardiomyopathy and circular RNAs in myocardial infarction.

OPTC-4. Bioinformatic analysis of COLXIα1 gene expression and its alternative splicing regulation in Paediatric Diffuse Intrinsic Pontine Gliomas (DIPGs)

Paediatric Diffuse Intrinsic Pontine Glioma (DIPGs), is a rare aggressive childhood malignancy that arise in a region and age specific manner, with no cure and children seldom survive 2 years after diagnosis. There has been significant advances in genomic and molecular identification of driver genes as well as signature mutations that help with diagnosis. A multi-methodological approach to begin to profile the DIPG/host landscape in the context of developing brainstem was conducted. Bioinformatic analyses of a DIPG dataset and normal developing brain dataset to help separate expression associated with development from tumour was conducted. In parallel; fixed-formalin paraffin embedded DIPG tissue was obtained from post-mortem brain for focused RNA arrays and RNAseq. Two of several overlapping genes that were overexpressed in DIPG was tenascin C and the collagen XI (α1) gene (COL11A1). A common feature of these genes is that they are alternatively spliced. Therefore, the aim of this study was to focus on COL11A1, further explore its expression in diffuse midline gliomas (DMGs), to determine association with H3K27M alterations and to explore the use of bioinformatic programmes that could potentially predict the specific Col11α1 isoform expression in DIPG. The following programs were used to determine if a bioinformation approach could aid in our understanding of alternative splicing in development and DIPG: R2: Genomics Analysis and Visualization Platform, SnapGene program, Basic Local Alignment Search Tools (BLAST), RNA Interactome Database (RNAInter). In silico analysis highlited an RNA-binding protein eIF4A3 as a candidate of alternative splicing regulator of COL11A1 gene. EIF4A3 gene was shown to be upreguated in DIPG using publicly available datasets. Results shows that isoform A is the most likely isoform present in DIPG. The data obtained will help inform future in vitro and in vivo investigations into the potential role of COL11A1 and its isoforms in DIPG.

Modulation of alternative splicing of trafficking genes by genome editing reveals functional consequences in muscle biology

Alternative splicing is a regulatory mechanism by which multiple mRNA isoforms are generated from single genes. Numerous genes that encode membrane trafficking proteins are alternatively spliced. However, there is limited information about the functional consequences that result from these splicing transitions. Here, we developed appropriate tools to study the functional impact of alternative splicing in development within the most in vivo context. Secondly, we provided evidence of the physiological implications of splicing regulation during muscle development. Our previous work in mouse heart development identified three trafficking genes that are regulated by alternative splicing between birth and adulthood: the clathrin heavy chain, the clathrin light chain-a, and the trafficking kinesin binding protein-1. Here, we demonstrated that alternative splicing regulation of these three genes is tissue- and developmental stage-specific. To identify the functional consequences of splicing regulation in vivo, we used genome editing to block the neonatal-to-adult splicing transitions. We characterized the phenotype of one of these mouse lines and demonstrated that when splicing regulation of the clathrin heavy chain gene is prevented mice exhibit an increase in body and muscle weights which is due to an enlargement in myofiber size. The significance of this work has two components. First, we revealed novel roles of the clathrin heavy chain in muscle growth and showed that its regulation by alternative splicing contributes to muscle development. Second, the new mouse lines will provide a useful tool to study how splicing regulation of three trafficking genes affects tissue identity acquisition and maturation in vivo.

High-resolution temporal and regional mapping of MAPT expression and splicing in human brain development.

The microtubule associated protein tau plays a critical role in the pathogenesis of neurodegenerative disease. Recent studies suggest that tau also plays a role in disorders of neuronal connectivity, including epilepsy and post-traumatic stress disorder. Animal studies have shown that the MAPT gene, which codes for the tau protein, undergoes complex pre-mRNA alternative splicing to produce multiple isoforms during brain development. Human data, particularly on temporal and regional variation in tau splicing during development are however lacking. In this study, we present the first detailed examination of the temporal and regional sequence of MAPT alternative splicing in the developing human brain. We used a novel computational analysis of large transcriptomic datasets (total n = 502 patients), quantitative polymerase chain reaction (qPCR) and western blotting to examine tau expression and splicing in post-mortem human fetal, pediatric and adult brains. We found that MAPT exons 2 and 10 undergo abrupt shifts in expression during the perinatal period that are unique in the canonical human microtubule-associated protein family, while exon 3 showed small but significant temporal variation. Tau isoform expression may be a marker of neuronal maturation, temporally correlated with the onset of axonal growth. Immature brain regions such as the ganglionic eminence and rhombic lip had very low tau expression, but within more mature regions, there was little variation in tau expression or splicing. We thus demonstrate an abrupt, evolutionarily conserved shift in tau isoform expression during the human perinatal period that may be due to tau expression in maturing neurons. Alternative splicing of the MAPT pre-mRNA may play a vital role in normal brain development across multiple species and provides a basis for future investigations into the developmental and pathological functions of the tau protein.

Molecular Characterization of Pediatric Restrictive Cardiomyopathy from Integrative Genomics

Pediatric restrictive cardiomyopathy (RCM) is a genetically heterogeneous heart disease with limited therapeutic options. RCM cases are largely idiopathic; however, even within families with a known genetic cause for cardiomyopathy, there is striking variability in disease severity. Although accumulating evidence implicates both gene expression and alternative splicing in development of dilated cardiomyopathy (DCM), there have been no detailed molecular characterizations of underlying pathways dysregulated in RCM. RNA-Seq on a cohort of pediatric RCM patients compared to other forms of adult cardiomyopathy and controls identified transcriptional differences highly common to the cardiomyopathies, as well as those unique to RCM. Transcripts selectively induced in RCM include many known and novel G-protein coupled receptors linked to calcium handling and contractile regulation. In-depth comparisons of alternative splicing revealed splicing events shared among cardiomyopathy subtypes, as well as those linked solely to RCM. Genes identified with altered alternative splicing implicate RBM20, a DCM splicing factor, as a potential mediator of alternative splicing in RCM. We present the first comprehensive report on molecular pathways dysregulated in pediatric RCM including unique/shared pathways identified compared to other cardiomyopathy subtypes and demonstrate that disruption of alternative splicing patterns in pediatric RCM occurs in the inverse direction as DCM.

Alternative splicing in development

Alternative splicing is critical for skeletal muscle health and glutamatergic synaptic function.

Non-coding functions of alternative pre-mRNA splicing in development

A majority of messenger RNA precursors (pre-mRNAs) in the higher eukaryotes undergo alternative splicing to generate more than one mature product. By targeting the open reading frame region this process increases diversity of protein isoforms beyond the nominal coding capacity of the genome. However, alternative splicing also frequently controls output levels and spatiotemporal features of cellular and organismal gene expression programs. Here we discuss how these non-coding functions of alternative splicing contribute to development through regulation of mRNA stability, translational efficiency and cellular localization.

The significant other: splicing by the minor spliceosome

The removal of non-coding sequences, introns, from the mRNA precursors is an essential step in eukaryotic gene expression. U12-type introns are a minor subgroup of introns, distinct from the major or U2-type introns. U12-type introns are present in most eukaryotes but only account for less than 0.5% of all introns in any given genome. They are processed by a specific U12-dependent spliceosome, which is similar to, but distinct from, the major spliceosome. U12-type introns are spliced somewhat less efficiently than the major introns, and it is believed that this limits the expression of the genes containing such introns. Recent findings on the role of U12-dependent splicing in development and human disease have shown that it can also affect multiple cellular processes not directly related to the functions of the host genes of U12-type introns. At the same time, advances in understanding the regulation and phylogenetic distribution of the minor spliceosome are starting to shed light on how the U12-type introns and the minor spliceosome may have evolved. © 2012 John Wiley & Sons, Ltd.

Alternative Splicing in Development and Function of Chordate Endocrine Systems: A Focus on Pax Genes

Genome sequencing has facilitated an understanding of gene networks but has also shown that they are only a small part of the answer to the question of how genes translate into a functional organism. Much of the answer lies in epigenetics-heritable traits not directly encoded by the genome. One such phenomenon is alternative splicing, which affects over 75% of protein coding genes and greatly amplifies the number of proteins. Although it was postulated that alternative splicing and gene duplication are inversely proportional and, therefore, have similar effects on the size of the proteome, for ancient duplications such as occurred in the Pax family of transcription factors, that is not necessarily so. The importance of alternative splicing in development and physiology is only just coming to light. However, several techniques for studying isoform functions both in vitro and in vivo have been recently developed. As examples of what is known and what is yet to be discovered, this review focuses on the evolution and roles of the Pax family of transcription factors in development and on alternative splicing of endocrine genes and the factors that regulate them.

Alternative splicing of SMADs in differentiation and tissue homeostasis

Tissue-specific alternate splicing is an important means of regulating gene expression during development. The effector proteins for the transforming growth factor-beta signaling pathway, the SMADs, encode distinct isoforms generated via alternate splicing, which appear to have distinct tissue-specific expression profiles and functions. Here, we discuss the roles of various SMAD isoforms, and the consequences of mis-regulation of SMAD splicing in development and tissue homeostasis.

Developmental Control of CaV1.2 L-Type Calcium Channel Splicing by Fox Proteins

CaV1.2 voltage-gated calcium channels play critical roles in the control of membrane excitability, gene expression, and muscle contraction. These channels show diverse functional properties generated by alternative splicing at multiple sites within the CaV1.2 pre-mRNA. The molecular mechanisms controlling this splicing are not understood. We find that two exons in the CaV1.2 channel are controlled in part by members of the Fox family of splicing regulators. Exons 9* and 33 confer distinct electrophysiological properties on the channel and show opposite patterns of regulation during cortical development, with exon 9* progressively decreasing its inclusion in the CaV1.2 mRNA over time and exon 33 progressively increasing. Both exons contain Fox protein binding elements within their adjacent introns, and Fox protein expression is induced in cortical neurons in parallel with the changes in CaV1.2 splicing. We show that knocking down expression of Fox proteins in tissue culture cells has opposite effects on exons 9* and 33. The loss of Fox protein increases exon 9* splicing and decreases exon 33, as predicted by the positions of the Fox binding elements and by the pattern of splicing in development. Conversely, overexpression of Fox1 and Fox2 proteins represses exon 9* and enhances exon 33 splicing in the endogenous CaV1.2 mRNA. These effects of Fox proteins on exons 9* and 33 can be recapitulated in transfected minigene reporters. Both the repressive and the enhancing effects of Fox proteins are dependent on the Fox binding elements within and adjacent to the target exons, indicating that the Fox proteins are directly regulating both exons. These results demonstrate that the Fox protein family is playing a key role in tuning the properties of CaV1.2 calcium channels during neuronal development.

Conditional knockout mice to study alternative splicing in vivo

Analysis of genomes has revealed that the total number of human genes is comparable to those of simpler organisms, and thus, the number of genes does not correlate with the complexity and functional diversity of different organisms. Multiple mechanisms, including alternative splicing, are believed to contribute to the molecular complexity in higher eukaryotes. Given the fact that more than half of human genes undergo alternative splicing, however, little is known about the biological relevance of most alternative splicing events and their regulatory mechanisms. Recent work has highlighted the power of reverse genetic approaches in addressing regulated splicing in animal models. Here, we focus on the conditional knockout approach adapted for splicing research with the intension to provide a general guide to the generation of mouse models to study regulated splicing in development and disease.

Profiling alternative splicing on fiber-optic arrays.

The human transcriptome is marked by extensive alternative mRNA splicing and the expression of many closely related genes, which may be difficult to distinguish using standard microarray techniques. Here we describe a sensitive and specific assay for parallel analysis of mRNA isoforms on a fiber-optic microarray platform. The method permits analysis of mRNA transcripts without prior RNA purification or cDNA synthesis. Using an endogenously expressed viral transcript as a model, we demonstrated that the assay readily detects mRNA isoforms from as little as 10-100 pg of total cellular RNA or directly from a few cells. Multiplexed analysis of human cancer cell lines revealed differences in mRNA splicing and suggested a potential autocrine mechanism in the development of choriocarcinomas. Our approach may be useful in the large-scale analysis of the role of alternative splicing in development and disease.

Splicing of pre-mRNA: mechanism, regulation and role in development

Over the past year, significant progress has been made in the understanding of how RNA-binding factors may facilitate splice-site selection and spliceosome assembly, and confer fidelity to the pre-mRNA splicing reaction. In addition, a number of studies have revealed a complex network of RNA-RNA interactions in the spliceosome, strengthening the structural and functional parallels between nuclear pre-mRNA splicing and the self-splicing group I and group II introns. These new data further support the idea that pre-mRNA splicing occurs by RNA-mediated catalysis and illustrate quite dramatically the dynamic nature of conformational changes in the spliceosome cycle. With respect to tissue-specific pre-mRNA splicing, a number of studies have begun to illuminate mechanisms underlying control of splice-site selection and how so-called ‘general’ RNA-binding proteins, such as heterogeneous nuclear ribonucleoproteins, may be involved in determining different splicing patterns. Finally, an emerging theme involving the role of splicing in development is that differential transcriptional programs can be triggered in different cell types by alternative splicing patterns that generate transcription factor isoforms with different activities or DNA-binding specificities.