Project description:Our study found that insertion of commonly used selection cassettes in yeast can drive aberrant transcription events and disrupt expression of neighboring genes. We performed ribosome profiling and mRNA-seq on yeast strains where ORFs had been replaced with common selection cassettes and observed aberrant transcripts. Aberrant transcripts positioned near adjacent genomic loci repressed protein synthesis of those genes by transcription interference (ablating normal length transcript production) coincident with translation of competitive uORFs on the long transcript which prevented translation of the main ORF seen by ribosome profiling.

Project description:Mammalian genomes are pervasively transcribed to produce thousands of spliced long noncoding RNAs (lncRNAs), whose functions remain poorly understood. Because recent evidence has implicated several specific lncRNA loci in the local regulation of gene expression, we sought to determine whether such local regulation is a property of many lncRNA loci. We used genetic manipulations to dissect 12 genomic loci that produce lncRNAs and found that 5 of these loci influence the expression of a neighboring gene in cis. Surprisingly, however, none of these effects required the specific lncRNA transcripts themselves and instead involved general processes associated with their production, including enhancer-like activity of gene promoters, the process of transcription, and the splicing of the transcript. Interestingly, such effects are not limited to lncRNA loci: we found similar effects on local gene expression at 4 of 6 protein-coding loci. These results demonstrate that ‘crosstalk’ among neighboring genes is a prevalent phenomenon that can involve multiple mechanisms and cis regulatory signals, including a novel role for RNA splice sites. These mechanisms may coordinate the expression of neighboring genes and explain the function and evolution of some genomic loci that produce lncRNAs.

Project description:Dimorphic fungi are temperature-sensitive organisms that couple their cell shape with their environment. One of these fungi, Histoplasma capsulatum, exists as both a soil-dwelling hypha and a host-associated yeast. Here we examine the role of the previously uncharacterized gene MSB2 in filamentous growth. We performed a genetic screen to identify insertion mutants that are unable to transition from the yeast form to the hyphal form. One yeast-locked mutant has an insertion upstream of the MSB2 gene. This mutant strain (SG1) fails to express MSB2, whose ortholog in the model yeast Saccharomyces cerevisiae is a known signaling component in the high osmolarity glycerol (HOG) pathway and filamentous growth (FG) pathway. Here, we profiled gene expression by RNA-seq to characterize transcriptional differences between wild type and msb2 mutant strains during the yeast to hyphal transition.

Project description:Partitioning of active gene loci to the nuclear envelope is a key mechanism by which organisms can increase the speed of adaptation and metabolic robustness to fluctuating resources in the environment. In the budding yeast Saccharomyces cerevisiae, adaptation and transcriptional memory induced by nutrient depletion or other stresses, results from relocalization of active gene loci from nucleoplasm to the nuclear envelope, leading to increased transport of mRNAs to the cytosol and their translation. The mechanism by which this translocation occurs remains a mystery. We show here, that for the inositol depletion-responsive gene locus INO1 in yeast, translocation to the nuclear envelope is caused by a local phase transition of the mechanical stiffness of chromatin surrounding activated INO1 that favors phase separation of the active gene locus into low density regions of chromatin proximal to the nuclear envelope. Gene regulatory elements essential to translocation encode binding sites for histone acetyl transferases, which are necessary for chromatin decompaction. INO1 locus partitioning can be explained by a phenomenological model of chromatin decompaction, which reflects stiffening of chromatin and its partitioning into a dilute chromatin phase adjacent to the nuclear envelope, from the dense chromatin found in the nucleoplasmic phase. Recent evidence suggests that this demixing of chromatin could be due to the dissolution of multivalent chromatin interactions mediated by histone post-translational modifications.

Project description:Integron gene cassette metagenome

Project description:Long Terminal Repeat (LTR) Retrotransposons are an abundant class of genomic parasites that replicate by insertion of new copies into the host genome. LTR retrotransposons prevent mutagenic insertions through diverse targeting mechanisms that avoid coding sequences, but a universal set of principles guiding their target site selection hasn’t been established. Here we show that insertion of the fission yeast LTR retrotransposon Tf1 is guided by the DNA binding protein Sap1, and that the efficiency and location of the targeting depend on the activity of Sap1 as a replication fork barrier. We propose that Sap1 guides insertion of Tf1 by blocking the progression of the replication fork, and that the Tf1 transposon uses features of arrested forks to insert into the host genome. These observations point to a universal mechanism for determination of LTR retrotransposon target site selection.

Project description:The goal of this study was to identify and compare baseline mRNA expression levels for a set of Ixodes scapularis cell lines originally reported in Munderloh et al. 1994 Journal of Parasitology 80(4):533-43. Three unmodified I. scapularis cell lines were included in the study: ISE6, IDE2, and ISE18. In addition, one cell population modified by insertion of a transgenic cassette using Sleeping Beauty transposition was also included: ISE18SB. The ISE18SB cells are a non-clonal cell population fully enriched for expression of a DsRed fluorescent marker gene included within the transposon insertion cassette. For all replicate samples, cells were collected after reaching approximately 60% confluency under standard culture conditions, then processed for RNA-seq analysis.

Project description:Transcriptome analysis of effect of Lockd knockout on cells Many long non-coding (lnc) RNAs are reported to regulate gene expression and protein functions. However, the proportion of lncRNAs with biological activities among the thousands expressed in mammalian cells is controversial. We studied Lockd (Downstream of p27), a 434 bp polyadenylated lncRNA originating 4 kb 3’ to the Cdkn1b gene. Heterozygous and homozygous deletion of the 25 kb Lockd locus reduced Cdkn1b transcription by approximately 35 and 70% respectively in a mouse erythroid cell line. In contrast, homozygous insertion of a polyadenylation cassette 80 bp downstream of the Lockd transcription start site reduced the entire lncRNA transcript level by > 90%, but had no effect on Cdkn1b transcription. The 5’ region of the Lockd gene contains a DNase hypersensitive site, binds numerous transcription factors (TFs), and physically associates with the Cdkn1b promoter in chromosomal conformation capture (NG Capture-C) studies. Thus, the Lockd gene positively regulates Cdkn1b transcription through an enhancer-like cis element and not via the lncRNA transcript. These findings demonstrate that the biological functions of a lncRNA cannot be inferred simply from phenotypes that arise after deleting the corresponding genomic locus.

Project description:To investigate the role of acrA in antibiotic resistance and pathogenicity this gene was inactivated by insertion of a kanamycin cassette in strain SL1344 and the results on the transcriptome determined.

Project description:Transposon screens are powerful in vivo assays used to identify loci driving carcinogenesis. These loci are identified as Common Insertion Sites (CIS), i.e. regions with more transposon insertions than expected by chance. However, the identification of CIS is strongly affected by biases in the insertion behaviour of transposon systems. Here, we introduce Transmicron, a novel method that differs from previous methods by i) modelling neutral insertion rates based on chromatin accessibility, transcriptional activity, and sequence context, and ii) estimating oncogenic selection for each genomic region using Poisson regression to model insertion counts while controlling for neutral insertion rates. To assess the benefits of our approach, we generated a dataset applying two different transposon systems under comparable conditions. Benchmarking for enrichment of known cancer genes showed improved performance of Transmicron against state-of-the-art methods. Modelling neutral insertion rates allowed for better control of false positives and stronger agreement of the results between transposon systems. Moreover, using Poisson regression to consider intra-sample and inter-sample information proved beneficial in small and moderately-sized datasets. Transmicron is open-source and freely available. Overall, this study contributes to the understanding of transposon biology and introduces a novel approach to use this knowledge for discovering cancer driver genes.