Project description:Mammalian SR proteins are a family of reversibly phosphorylated RNA binding proteins primarily studied for their roles in alternative splicing. While budding yeast lack alternative splicing, they do have three SR-like proteins: Npl3, Gbp2, and Hrb1. However, these have been primarily studied for their roles in mRNA export, leaving their potential roles in splicing largely unexplored. Here we combined high-density genetic interaction profiling and genome-wide splicing-sensitive microarray analysis to demonstrate that a single SR-like protein, Npl3, is required for efficient splicing of a large set of pre-mRNAs in Saccharomyces cerevisiae. We tested the hypothesis that Npl3 promotes splicing by facilitating co-transcriptional recruitment of splicing factors. Using chromatin immunoprecipitation, we showed that mutation of NPL3 reduces the occupancy of U1 and U2 snRNPs at Npl3-stimulated genes. This provides the first evidence that an SR protein can promote recruitment of splicing factors to chromatin. Splicing-specific microarrays were used to assay changes to splicing in single and double deletion mutants of non-essential SR proteins, in a deletion mutant of a non-essential component of the nonsense-mediated decay pathway, and in a double deletion mutant of in an SR protein plus a non-sense mediated decay factor in Saccharomyces cerevisiae. The data includes both samples obtained at the permissive temperature and also shifts to the non-permissive temperature for some mutants, as well as dye-flipped technical replicates.

Project description:Alternative splicing coupled mRNA decay shapes the temperature-dependent transcriptome

Project description:Anti-viral innate immunity represents the first line of defense against invading viruses and is key to control viral infections, including the pandemic SARS-CoV-2. Body temperature is an omnipresent variable but was so far neglected when addressing host defense mechanisms and susceptibility to SARS-CoV-2 infection. Here we show that increasing temperature in a 1.5°C window, between 36.5°C and 38°C, strongly increases anti-viral immunity. We show that alternative splicing coupled to nonsense-mediated decay decreases STAT2 expression in colder conditions and suggest that increased STAT2 expression at elevated temperature induces the expression of diverse anti-viral genes. This cascade is activated in a remarkably narrow temperature range below febrile temperature, which reflects individual, circadian and age-dependent body temperature variation. Accordingly, decreased body temperature with ageing correlates with reduced expression of anti-viral genes in older individuals. Using cell culture and in vivo models, we show that higher body temperature indeed reduces SARS-CoV-2 replication, which likely impacts on the different vulnerability of children versus seniors towards severe SARS-CoV-2 infection. Altogether, our data reveal a molecular mechanism, from temperature sensing and pre-mRNA processing to an in vivo phenotype connecting body temperature variation with SARS-CoV-2 replication, thus providing a new paradigm for the regulation of anti-viral innate immunity.

Project description:Homoeothermic organisms maintain their core body temperature in a narrow, tightly controlled range. Whether and how subtle circadian oscillations or disease-associated changes in core body temperature are sensed and integrated in gene expression programs remains elusive. Furthermore, a thermo-sensor capable of sensing the small temperature differentials leading to temperature-dependent sex determination (TSD) in poikilothermic reptiles has not been identified. Here we show that the activity of CDC-like kinases (CLKs) is highly responsive to physiological temperature changes, which is conferred by structural rearrangements within the kinase activation segment. Lower body temperature activates CLKs resulting in strongly increased phosphorylation of SR-proteins in vitro and in vivo. This globally controls temperature-dependent alternative splicing and gene expression, with wide implications in circadian, tissue-specific and disease-associated settings. This temperature sensor is conserved across evolution and adapted to growth temperatures of diverse poikilotherms. The dynamic temperature range of reptilian CLK homologs suggests a role in TSD.

Project description:The goal of this study is to measure Arabidopsis mRNA transcription and mRNA decay rates genome wide at two temperatures, and thus to calculate the temperature coefficient of both processes. Sensing and response to ambient temperature is important for controlling growth and development of many organisms, in part by regulating mRNA levels. mRNA abundance can change with temperature, but it is unclear whether this results from changes to transcription or decay rates and whether passive or active temperature regulation is involved. Results Using a base analogue labelling method we directly measured the temperature coefficient (Q10) of mRNA synthesis and degradation rates of the Arabidopsis transcriptome. We show that for most genes transcript levels are buffered against passive increases in transcription rates by balancing passive increases in the rate of decay. Strikingly, for temperature-responsive transcripts, increasing temperature raises transcript abundance primarily by promoting faster transcription relative to decay and not vice versa, suggesting a global transcriptional mechanism process exists for the activethat controls of mRNA abundance by temperature/

Project description:We used GFP-tagged SR proteins expressed at endogenous levels and iCLIP to identify and compare endogenous RNA targets of individual SR proteins, map the preferential sites of binding, compare binding pattern and binding motifs between family members and to NXF1 and quantify binding of SR proteins and NXF1 to spliced versus unspliced RNAs to study the role of SR proteins in mRNA export via NXF1.

Project description:Members of the SR protein family of RNA binding proteins play numerous roles in gene expression, including the regulation of pre-mRNA splicing, mRNA export, and translation. How SR proteins coordinate gene expression programs is unknown, and comprehensive knowledge of endogenous mRNA targets is lacking. We established physiological expression of GFP-tagged SR protein, allowing the immunopurification and systematic identification of mRNAs associated with SRp20 and SRp75. This genome-wide analysis showed that SRp20 and SRp75 are components of distinct, mostly non-overlapping mRNPs in undifferentiated and neural cells.

Project description:Members of the SR protein family of RNA binding proteins play numerous roles in gene expression, including the regulation of pre-mRNA splicing, mRNA export, and translation. How SR proteins coordinate gene expression programs has been largely unexplored, and comprehensive knowledge of endogenous mRNA targets is lacking. Gene expression changes upon SRp20 or SRp75 RNAi in P19 parental, SRp75-BAC, and SRp20-BAC cells were measured with mouse whole genome microarrays. The knockdown of either SRp20 or SRp75 led to up- or downregulation of specific transcripts. Phenotypic rescue in the SRp75-BAC, and SRp20-BAC cells demonstrated functionality of the GFP-tagged SR proteins, and showed the specificity of the knockdowns.

Project description:Our data suggest that all SR proteins contribute to mRNA export via NXF1. To identify endogenous export targets we depleted all seven SR proteins individually from P19 WT cells prepared cytoplasmic fractions. We sequenced the cytoplasmic fraction and as a control whole celll RNA from the identical sample. Knockdown of seven SR Proteins plus control, total RNA and cytoplasmic RNA, polyA+ enriched, 2 biological replicates per condition, 2 technical replicates per condition

Project description:Proteins regulate gene expression by controlling mRNA biogenesis, localization, translation and decay. Identifying the composition, diversity and function of mRNPs (mRNA protein complexes) is essential to understanding these processes. In a global survey of S. cerevisiae mRNA binding proteins we identified 120 proteins that cross-link to mRNA, including 66 new mRNA binding proteins. These include kinases, RNA modification enzymes, metabolic enzymes, and tRNA and rRNA metabolism factors. These proteins show dynamic subcellular localization during stress, including assembly into stress granules and P-bodies (Processing-bodies). CLIP (cross-linking and immunoprecipitation) analyses of the P-body components Pat1, Lsm1, Dhh1 and Sbp1 identified sites of interaction on specific mRNAs revealing positional binding preferences and co-assembly preferences. Taken together, this work defines the major yeast mRNP proteins, reveals widespread changes in their subcellular location during stress, and begins to define assembly rules for P-body mRNPs. CLIP-seq analysis of Dhh1, Lsm1, Pat1 and Sbp1