Spatial and temporal requirement of Mlp60A isoforms during muscle development and function in Drosophila melanogaster

Many myofibrillar proteins undergo isoform switching in a spatio-temporal manner during muscle development. The biological significance of the variants of several of these myofibrillar proteins remains elusive. One such myofibrillar protein, the Muscle LIM Protein (MLP), is a vital component of the Z-discs. In this paper, we show that one of the Drosophila MLP encoding genes, Mlp60A, gives rise to two isoforms: a short (279 bp, 10 kDa) and a long (1461 bp, 54 kDa) one. The short isoform is expressed throughout development, but the long isoform is adult-specific, being the dominant of the two isoforms in the indirect flight muscles (IFMs). A concomitant, muscle-specific knockdown of both isoforms leads to late pupal lethality, with the surviving flies being majorly flight defective. Mlp60A null flies show developmental lethality, and muscle defects in the individuals surviving till the third instar larval stage. This lethality could be rescued partially by muscle-specific overexpression of the short isoform. Almost 90% of the long isoform-specific P-element insertion mutant flies show a compromised flight ability and have reduced sarcomere length. Hence, our data shows that the two Mlp60A isoforms are functionally specialized, to ensuring normal embryonic muscle development and adult flight muscle function.

Probing Isoform Switching Events in Various Cancer Types: Lessons From Pan-Cancer Studies

Alternative splicing is an essential regulatory mechanism for gene expression in mammalian cells contributing to protein, cellular, and species diversity. In cancer, alternative splicing is frequently disturbed, leading to changes in the expression of alternatively spliced protein isoforms. Advances in sequencing technologies and analysis methods led to new insights into the extent and functional impact of disturbed alternative splicing events. In this review, we give a brief overview of the molecular mechanisms driving alternative splicing, highlight the function of alternative splicing in healthy tissues and describe how alternative splicing is disrupted in cancer. We summarize current available computational tools for analyzing differential transcript usage, isoform switching events, and the pathogenic impact of cancer-specific splicing events. Finally, the strategies of three recent pan-cancer studies on isoform switching events are compared. Their methodological similarities and discrepancies are highlighted and lessons learned from the comparison are listed. We hope that our assessment will lead to new and more robust methods for cancer-specific transcript detection and help to produce more accurate functional impact predictions of isoform switching events.

ADAR1 Splicing Modulation As a Mechanism to Eradicate Immunologically Silent Leukemia Stem Cells

Secondary acute myeloid leukemia (sAML) is the most therapeutically recalcitrant form of AML with a life expectancy of less than 12 months. Secondary AML evolves from relatively prevalent myeloproliferative neoplasms (MPNs), myelodysplastic syndrome (MDS), or after chemotherapy, radiation therapy, or hematopoietic cell transplantation (HCT) that together confer a 14% risk of sAML at 15 years. Cumulative sequencing studies show that human splicing factor mutations, epigenetic spliceosome deregulation, RNA editing-induced splicing alterations, and pro-survival splice isoform switching drive dormant leukemia stem cell (LSC) generation and sAML resistance to chemotherapy and molecularly targeted agents resulting in high rates of relapse. LSC are immunologically silent in part because they activate adenosine deaminase acting on dsRNA (ADAR1), which attenuates the innate immune response. In addition, therapeutic splicing modulation has the potential to induce neoepitope formation and augment checkpoint inhibitor therapy. Thus, there is a pressing need for clinical development of splicing modulatory agents that eradicate therapy resistant LSC and reduce sAML drug resistance and relapse. Rebecsinib (17 S-FD-895) is a pharmacologically stable, potent, and selective small molecule splicing modulator that targets the SF3B core of the spliceosome at the interface of SF3B1, SF3B3 and PHF5A. We previously showed that Rebecsinib inhibits human LSC maintenance in sAML models at doses that spare normal hematopoietic stem and progenitor cells (HSPCs). In IND-enabling studies, we now demonstrate that splicing modulation with this potent agent is a pre-clinical tox-proven strategy to eradicate LSC with the potential to overcome immune checkpoint resistance via inhibition of ADAR1 splicing and activity. We further describe targeted LSC eradication that correlates with detection of unique intron-retained and exon-skipped transcripts that can be quantified by splice isoform-specific qRT-PCR and RNA-sequencing analyses and can be used as predictive biomarkers to monitor molecular responses to Rebecsinib treatment. Mechanistically, the therapeutic effects were accompanied by on-target splicing modulatory effects, including reductions in pro-survival MCL1L transcripts and splicing factor gene products such as SF3B1 and SF3B3, which form part of the splicing modulator binding pocket as well as alterations in self-renewal promoting ADAR1 and STAT3beta transcripts. In multi-species toxicology and pharmacokinetic/pharmacodynamic studies, Rebecsinib induced splicing modulation and was well-tolerated over a broad range of doses. Because of disrupted spliceosome function, SF3B1 overexpression and increased dependence on pro-survival splice isoform expression, Rebecsinib-mediated induction of pro-survival to pro-apoptotic splice isoform switching inhibits sAML LSC survival and self-renewal at doses that spare normal HSPCs in vitro and in humanized mouse models commensurate with dose-dependent changes in splicing reporter exon skipping and SF3B1, MCL1, BCL2 and CD44 isoform levels. Together, this potent and selective agent along with biomarkers of response to splicing modulation provide a sensitive method of detecting activity and mechanism of action of Rebecsinib, and demonstrate its LSC selectivity in humanized stromal co-cultures and humanized mouse models, which will have utility in future clinical development of this novel therapeutic agent. Disclosures Crews: Ionis Pharmaceuticals: Research Funding. Burkart: Algenesis: Other: Co-founder. Jamieson: Forty Seven Inc.: Patents & Royalties.

CanIsoNet: A Database to Study the Functional Impact of Isoform Switching Events in Cancer

Motivation: Alternative splicing, as an essential regulatory mechanism in normal mammalian cells, is frequently disturbed in cancer. Switches in the expression of alternative isoforms can alter protein interaction networks of associated genes giving rise to cancer progression and metastases. We have recently analysed the pathogenic impact of switching events in 1209 cancer samples covering 24 different cancer types. Here, we are presenting CanIsoNet (Cancer Isoform specific interaction Network), a database to view, browse and search these isoform switching events. CanIsoNet is the first webserver that incorporates isoform expression data with STRING interaction networks and COSMIC annotations to predict the pathogenic impact of isoform switching events in various cancer types. Results: Data in CanIsoNet can be browsed by cancer types or searched by genes or isoforms in annotation rich data tables. Various annotations for 11,041 isoforms and 31,748 unique isoform switching events are provided across 24 cancer types, including proximity information to COSMIC cancer census genes, network density data for each cancer-specific isoform, PFAM domain IDs of disrupted interactions, domain structure visualization of transcripts and expression data of switched isoforms for each sample. Availability: CanIsoNet is freely available at https://caniso.net under a Creative Common License. The source codes can be found at https://github.com/KarakulakTulay/CanIsoNet_Web

Cytoplasmic Switch of ARS2 Isoforms Promotes Nonsense-Mediated mRNA Decay and Arsenic Sensitivity

The life of RNA polymerase II (RNAPII) transcripts is shaped by the dynamic formation of mutually exclusive ribonucleoprotein complexes (RNPs) that direct transcript biogenesis and turnover. A key regulator of RNA metabolism in the nucleus is the scaffold protein ARS2 (arsenic resistance protein 2), bound to the cap binding complex (CBC). We report here that alternative splicing of ARS2 intron 5, generates cytoplasmic isoforms that lack 270 amino acids from the N-terminal of the protein and are functionally distinct from nuclear ARS2. Switching of ARS2 isoforms within the CBC in the cytoplasm has dramatic functional consequences, changing ARS2 from a NMD inhibitor to a NMD promoter that enhances the binding of UPF1 to NCBP1, ERF1 and DHX34, favoring SURF complex formation, SMG7 recruitment and transcript degradation. ARS2 isoform exchange is also relevant during arsenic stress, where cytoplasmic ARS2 promotes a global response to arsenic in a CBC-independent manner. We propose that ARS2 isoform switching promotes the proper recruitment of RNP complexes during NMD and the cellular response to arsenic stress. The existence of non-redundant ARS2 isoforms is relevant for cell homeostasis, stress response, and cancer treatment.

IKKε isoform switching governs the immune response against EV71 infection

The reciprocal interactions between pathogens and hosts are complicated and profound. A comprehensive understanding of these interactions is essential for developing effective therapies against infectious diseases. Interferon responses induced upon virus infection are critical for establishing host antiviral innate immunity. Here, we provide a molecular mechanism wherein isoform switching of the host IKKε gene, an interferon-associated molecule, leads to alterations in IFN production during EV71 infection. We found that IKKε isoform 2 (IKKε v2) is upregulated while IKKε v1 is downregulated in EV71 infection. IKKε v2 interacts with IRF7 and promotes IRF7 activation through phosphorylation and translocation of IRF7 in the presence of ubiquitin, by which the expression of IFNβ and ISGs is elicited and virus propagation is attenuated. We also identified that IKKε v2 is activated via K63-linked ubiquitination. Our results suggest that host cells induce IKKε isoform switching and result in IFN production against EV71 infection. This finding highlights a gene regulatory mechanism in pathogen-host interactions and provides a potential strategy for establishing host first-line defense against pathogens.

Surface Phenotype Changes and Increased Response to Oxidative Stress in CD4+CD25high T Cells

Conversion of CD4+CD25+FOXP3+ T regulatory cells (Tregs) from the immature (CD45RA+) to mature (CD45RO+) phenotype has been shown during development and allergic reactions. The relative frequencies of these Treg phenotypes and their responses to oxidative stress during development and allergic inflammation were analysed in samples from paediatric and adult subjects. The FOXP3lowCD45RA+ population was dominant in early childhood, while the percentage of FOXP3highCD45RO+ cells began increasing in the first year of life. These phenotypic changes were observed in subjects with and without asthma. Further, there was a significant increase in phosphorylated ERK1/2 (pERK1/2) protein in hydrogen peroxide (H2O2)-treated CD4+CD25high cells in adults with asthma compared with those without asthma. Increased pERK1/2 levels corresponded with increased Ca2+ response to T cell receptor stimulation. mRNA expression of peroxiredoxins declined in Tregs from adults with asthma. Finally, CD4+CD25high cells from paediatric subjects were more sensitive to oxidative stress than those from adults in vitro. The differential Treg sensitivity to oxidative stress observed in children and adults was likely dependent on phenotypic CD45 isoform switching. Increased sensitivity of Treg cells from adults with asthma to H2O2 resulted from a reduction of peroxiredoxin-2, -3, -4 and increased pERK1/2 via impaired Ca2+ response in these cells.

Transcriptional Regulation of Postnatal Cardiomyocyte Maturation and Regeneration

During the postnatal period, mammalian cardiomyocytes undergo numerous maturational changes associated with increased cardiac function and output, including hypertrophic growth, cell cycle exit, sarcomeric protein isoform switching, and mitochondrial maturation. These changes come at the expense of loss of regenerative capacity of the heart, contributing to heart failure after cardiac injury in adults. While most studies focus on the transcriptional regulation of embryonic or adult cardiomyocytes, the transcriptional changes that occur during the postnatal period are relatively unknown. In this review, we focus on the transcriptional regulators responsible for these aspects of cardiomyocyte maturation during the postnatal period in mammals. By specifically highlighting this transitional period, we draw attention to critical processes in cardiomyocyte maturation with potential therapeutic implications in cardiovascular disease.