Functional assays of non-canonical splice-site variants in inherited retinal dystrophies genes

Inherited retinal dystrophies are a group of disorders characterized by the progressive degeneration of photoreceptors leading to loss of the visual function and eventually to legal blindness. Although next generation sequencing (NGS) has revolutionized the molecular diagnosis of these diseases, the pathogenicity of some mutations casts doubts. After the screening of 208 patients with a panel of 117 genes, we obtained 383 variants that were analysed in silico with bioinformatic prediction programs. Based on the results of these tools, we selected 15 variants for their functional assessment. Therefore, we carried out minigene assays to unveil whether they could affect the splicing of the corresponding gene. As a whole, seven variants were found to induce aberrant splicing in the following genes: BEST1, CACNA2D4, PRCD, RIMS1, FSCN2, MERTK and MAK. This study shows the efficacy of a workflow, based on the association of the Minimum Allele Frequency, family co-segregation, in silico predictions and in vitro assays to determine the effect of potential splice site variants identified by DNA-based NGS. These findings improve the molecular diagnosis of inherited retinal dystrophies and will allow some patients to benefit from the upcoming gene-based therapeutic strategies.

Impact of Alternative Splicing Variants on Liver Cancer Biology

The two most frequent primary cancers affecting the liver, whose incidence is growing worldwide, are hepatocellular carcinoma (HCC) and intrahepatic cholangiocarcinoma (iCCA), which are among the five most lethal solid tumors with meager 5-year survival rates. The common difficulty in most cases to reach an early diagnosis, the aggressive invasiveness of both tumors, and the lack of favorable response to pharmacotherapy, either classical chemotherapy or modern targeted therapy, account for the poor outcome of these patients. Alternative splicing (AS) during pre-mRNA maturation results in changes that might affect proteins involved in different aspects of cancer biology, such as cell cycle dysregulation, cytoskeleton disorganization, migration, and adhesion, which favors carcinogenesis, tumor promotion, and progression, allowing cancer cells to escape from pharmacological treatments. Reasons accounting for cancer-associated aberrant splicing include mutations that create or disrupt splicing sites or splicing enhancers or silencers, abnormal expression of splicing factors, and impaired signaling pathways affecting the activity of the splicing machinery. Here we have reviewed the available information regarding the impact of AS on liver carcinogenesis and the development of malignant characteristics of HCC and iCCA, whose understanding is required to develop novel therapeutical approaches aimed at manipulating the phenotype of cancer cells.

TRAWLING: a Transcriptome Reference Aware of spLIciNG events

Alternative splicing is critical for human gene expression regulation and plays an important role in multiple human diseases. In this context, RNA sequencing has emerged as powerful approach to detect alternative splicing events.In parallel, fast alignment-free methods have emerged as a viable alternative to quantify gene and transcript level abundance from RNAseq data. However, the ability to detect differential splicing events is dependent on the annotation of the transcript reference provided by the user.Here, we introduce a new reference transcriptome aware of splicing events, TRAWLING, which simplifies the detection of aberrant splicing events in a fast and simple way. In addition, we evaluate the performances and the benefits of aligning transcriptome data to TRAWLING using three different RNA sequencing datasets: whole transcriptome sequencing, single cell RNA sequencing and Digital RNA with pertUrbation of Genes.Collectively, our comprehensive evaluation underlines the value of using TRAWLING in transcriptomic data analysis.Availability and implementationOur code is available at https://github.com/Novartis/TRAWLING

MicroRNA and Alternative mRNA Splicing Events in Cancer Drug Response/Resistance: Potent Therapeutic Targets

Cancer is a multifaceted disease that involves several molecular mechanisms including changes in gene expression. Two important processes altered in cancer that lead to changes in gene expression include altered microRNA (miRNA) expression and aberrant splicing events. MiRNAs are short non-coding RNAs that play a central role in regulating RNA silencing and gene expression. Alternative splicing increases the diversity of the proteome by producing several different spliced mRNAs from a single gene for translation. MiRNA expression and alternative splicing events are rigorously regulated processes. Dysregulation of miRNA and splicing events promote carcinogenesis and drug resistance in cancers including breast, cervical, prostate, colorectal, ovarian and leukemia. Alternative splicing may change the target mRNA 3′UTR binding site. This alteration can affect the produced protein and may ultimately affect the drug affinity of target proteins, eventually leading to drug resistance. Drug resistance can be caused by intrinsic and extrinsic factors. The interplay between miRNA and alternative splicing is largely due to splicing resulting in altered 3′UTR targeted binding of miRNAs. This can result in the altered targeting of these isoforms and altered drug targets and drug resistance. Furthermore, the increasing prevalence of cancer drug resistance poses a substantial challenge in the management of the disease. Henceforth, molecular alterations have become highly attractive drug targets to reverse the aberrant effects of miRNAs and splicing events that promote malignancy and drug resistance. While the miRNA–mRNA splicing interplay in cancer drug resistance remains largely to be elucidated, this review focuses on miRNA and alternative mRNA splicing (AS) events in breast, cervical, prostate, colorectal and ovarian cancer, as well as leukemia, and the role these events play in drug resistance. MiRNA induced cancer drug resistance; alternative mRNA splicing (AS) in cancer drug resistance; the interplay between AS and miRNA in chemoresistance will be discussed. Despite this great potential, the interplay between aberrant splicing events and miRNA is understudied but holds great potential in deciphering miRNA-mediated drug resistance.

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.

MDS-Associated Splicing Factor Mutations Promote Alternative Splicing of a Differentiation-Impaired CSF3R Isoform

Background. Myelodysplastic syndromes (MDS) constitute the most common group of bone marrow failure disorders, characterized by ineffective hematopoiesis and a significant risk of transformation to AML. Efforts to understand the molecular basis of MDS led to the identification of acquired somatic mutations in the RNA splicing factors SF3B1, U2AF1, SRSF2, ZRSR2, and LUC7L2 in 45-85% of adult MDS patients. How they perturb hematopoiesis and promote expansion of abnormal clones remain unknown. Elevated levels of alternate isoforms of granulocyte colony stimulating factor receptor (CSF3R) patients with MDS and other myeloid neoplasias have been reported with a strong correlation reported with loss of chromosome 7. Constitutive splicing produces the canonical Class I CSF3R isoform that supports proliferation and differentiation. Alternative splicing promoting intron excision in CSF3R exon 17 results in a differentiation-defective Class IV CSF3R isoform. We hypothesized that aberrant splicing activity of MDS-associated splicing factor mutations promote Class IV CSF3R expression, resulting in dysgranulopoiesis. Methods. We constructed a CSF3R minigene that was transiently expressed in K562 cells along with eukaryotic expression vectors containing cDNAs for wild-type or mutant forms of SF3B1, U2AF1, or SRSF2. To determine role of LUC7L2, a splicing factor residing on chromosome 7, the CSF3R minigene was transiently expressed in K562 cells with knockout LUC7L2. Class IV or Class I was measure by qPCR using specific primers. Putative exonic splicing enhancer motifs (ESEs) within exon 17 were deleted in the minigene and transfected into K562 cells expressing either wildtype or mutant SRSF2. To determine impact of mutant SRSF2 on granulopoiesis, wildtype or mutant SRSF2 were overexpressed in GCSF-treated CD34+ cells and morphology was assessed on day 14. To determine impact of Class IV isoform on granulopoiesis, Lin-, Sca-1+, and c-Kit+ (LSK) cells from Csf3r null mice were transduced with Class I or Class IV and colony forming unit (CFU) assay for granulopoiesis was performed with Methocult 3534. Colony scores and cell morphology were assessed on day 8. Results. K562 cells with transient expression of mutant SRSF2 P95H and LUC7L2 knockout resulted in statistically significant increase in Class IV:I CSF3R mRNA ratios normalized to a minigene-only control. Interestingly, expression of mutant U2AF1 S34F significantly decreased Class IV:I while U2AF1 Q157P increased Class IV:I ratios. K562 cells expressing mutant SF3B1 K700E did not show significant differences in Class IV splicing. To further investigate how SRSF2 regulates CSF3R splicing, we deleted two putative SRSF2-binding ESE motifs (ESE1 and ESE2) within exon 17 of the CSF3R minigene and transfected them into K562 cells stably expressing either wildtype SRSF2 or mutant P95H, P95L, or P95R. Deletion of either ESE1 or ESE2 resulted in decreased Class IV:I in all SRSF2 P95 mutant cells compared to minigene-only and wildtype controls. Next, we assessed the effect of SRSF2 P95 mutations on neutrophil differentiation in CD34+ cells. Overexpression of SRSF2 P95H, P95L, or P95R led to increased neutrophilic precursors compared to untransduced CD34+ cells. To determine the effect of a single CSF3R isoform on granulopoiesis, we cultured LSK cells from Csf3r null mice transduced with either Class I or Class IV on MethoCult 3534 with addition of GCSF. On day 8, cells expressing Class I had more total colony numbers with significantly higher CFU-GM colonies than cells expressing Class IV compared to empty vector control. Conclusions. We demonstrated that mutated SRSF2, U2AF1, and LUC7L2 deficiency alters CSF3R splicing in its terminal exon. Interestingly, mutations on different residues of the same gene (U2AF1) had opposing effects on CSF3R splicing. Mutant SRSF2 resulted in increased intron excision to promote increased levels of Class IV isoform. Mutation of two putative SRSF2 binding sites within CSF3R exon 17 reversed the increased splicing promoted by mutant SRSF2, further support our observation that CSF3R is a target for mutant SRSF2. Our observation with overexpression of mutant SRSF2 P95 in CD34+ cells suggests that defective neutrophil differentiation is related to increased Class IV. Our findings shed insights into how aberrant splicing of CSF3R drives MDS progression and provides a new model of dysgranulopoiesis. Disclosures No relevant conflicts of interest to declare.

Evaluation of suspected autosomal Alport Syndrome synonymous variants

【Background】 Alport syndrome is an inherited disorder characterized by progressive renal disease, variable sensorineural hearing loss, and ocular abnormalities. Although many pathogenic variants in COL4A3 and COL4A4 have been identified in autosomal Alport syndrome cases, synonymous mutations in these genes have rarely been identified. 【Methods】 We conducted in silico splicing analysis using the Human Splicing Finder (HSF) and Alamut to predict splicing domain strength and disruption of the sites. Furthermore, we performed in vitro splicing assays using minigene constructs and mRNA analysis of patient samples to determine the pathogenicity of 4 synonymous variants detected in 4 patients with suspected autosomal dominant Alport syndrome (COL4A3 (c.693G>A (p.Val231=) and COL4A4 (c.1353C>T (p.Gly451=), c.735G>A (p.Pro245=), and c.870G>A (p.Lys290=))). 【Results】 Both in vivo and in vitro splicing assays showed exon skipping in 2 out of the 4 synonymous variants identified (c.735G>A and c.870G>A in COL4A4). Prediction analysis of wild-type and mutated COL4A4 sequences using the HSF and Alamut suggested that these 2 variants may lead to the loss of binding sites for several splicing factors, e.g., in acceptor sites and exonic splicing enhancers. The other 2 variants did not induce aberrant splicing. 【Conclusions】 This study highlights the pitfalls of classifying the functional consequences of variants by a simple approach. Certain synonymous variants, although they do not alter the amino acid sequence of the encoded protein, can dramatically affect pre-mRNA splicing as shown in 2 of our cases. Our findings indicate that transcript analysis should be carried out to evaluate synonymous variants detected in autosomal dominant Alport syndrome cases.

Insights of Non-canonical Splice-site Variants on RNA Splicing in Patients with Congenital Hypothyroidism

Context Congenital hypothyroidism (CH) is caused by mutations in the genes for thyroid hormone synthesis. In our previous investigation of CH patients, ~53% of patients had mutations in either coding exons or canonical splice-sites of causative genes. Non-canonical splice-sites variants in the intron were detected but their pathogenic significance was not known. Objective To evaluate non-canonical splice-site variants on pre-mRNA splicing of CH-causing genes. Methods Next-generation sequencing data of 55 CH cases in 47 families were analyzed to identify rare intron variants. The effects of variants on pre-mRNA splicing were investigated by minigene RNA-splicing assays. Results Four intron variants were found in 3 patients: SLC26A4 c.1544 + 9C>T and c.1707 + 94C>T in one patient, and SLC5A5 c.970-48G>C and c.1652-97A>C in two other patients. The c.1707 + 94C>T and c.970-48G>C caused exons 15 and 16 skipping, and exon 8 skipping, respectively. The remaining variants had no effect on RNA splicing. Furthermore, we analyzed 28 previously reported non-canonical splice-site variants (4 in TG and 24 in SLC26A4). Among them, 15 variants (~54%) resulted in aberrant splicing and 13 variants had no effect on RNA splicing. These data were compared with three variant-prediction programs (FATHMM-XF, FATHMM-MKL, and CADD). Among 32 variants, FATHMM-XF, FATHMM-MKL, and CADD correctly predicted 20 (63%), 17 (53%), and 26 (81%) variants, respectively. Conclusions Two novel deep intron mutations have been identified in SLC26A4 and SLC5A5, bringing the total number of solved families with disease-causing mutations to ~45% in our cohort. Approximately 46% (13/28) reported non-canonical splice-site mutations do not disrupt pre-mRNA splicing. CADD provides highest prediction accuracy of non-canonical splice-site variants.

The identification of a novel splicing mutation in the DMD gene of a Chinese family

The Duchenne Muscular Dystrophy (DMD) gene variants are associated with the disease phenotypes. The pathogenic mutation, c.2293-1G>C, was detected in DMD gene in the proband and the fetus, which has not been reported in the literature.The minigene expression in vitro confirmed that c.2293-1G>C is responsible of aberrant splicing.