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1. Mathematical modeling of the Candida albicans yeast to hyphal transition reveals novel control strategies

   https://doi.org/10.1371/journal.pcbi.1008690  

   Wooten, David J.; Zañudo, Jorge Gómez; Murrugarra, David; Perry, Austin M.; Dongari-Bagtzoglou, Anna; Laubenbacher, Reinhard; Nobile, Clarissa J.; Albert, Réka (March 2021, PLOS Computational Biology)

   Thieffry, Denis (Ed.)

   Candida albicans , an opportunistic fungal pathogen, is a significant cause of human infections, particularly in immunocompromised individuals. Phenotypic plasticity between two morphological phenotypes, yeast and hyphae, is a key mechanism by which C . albicans can thrive in many microenvironments and cause disease in the host. Understanding the decision points and key driver genes controlling this important transition and how these genes respond to different environmental signals is critical to understanding how C . albicans causes infections in the host. Here we build and analyze a Boolean dynamical model of the C . albicans yeast to hyphal transition, integrating multiple environmental factors and regulatory mechanisms. We validate the model by a systematic comparison to prior experiments, which led to agreement in 17 out of 22 cases. The discrepancies motivate alternative hypotheses that are testable by follow-up experiments. Analysis of this model revealed two time-constrained windows of opportunity that must be met for the complete transition from the yeast to hyphal phenotype, as well as control strategies that can robustly prevent this transition. We experimentally validate two of these control predictions in C . albicans strains lacking the transcription factor UME6 and the histone deacetylase HDA1 , respectively. This model will serve as a strong base from which to develop a systems biology understanding of C . albicans morphogenesis. 

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2. Proteome effects of genome-wide single gene perturbations

   https://doi.org/10.1038/s41467-022-33814-8  

   Öztürk, Merve; Freiwald, Anja; Cartano, Jasmin; Schmitt, Ramona; Dejung, Mario; Luck, Katja; Al-Sady, Bassem; Braun, Sigurd; Levin, Michal; Butter, Falk (December 2022, Nature Communications)

   Abstract Protein abundance is controlled at the transcriptional, translational and post-translational levels, and its regulatory principles are starting to emerge. Investigating these principles requires large-scale proteomics data and cannot just be done with transcriptional outcomes that are commonly used as a proxy for protein abundance. Here, we determine proteome changes resulting from the individual knockout of 3308 nonessential genes in the yeast Schizosaccharomyces pombe . We use similarity clustering of global proteome changes to infer gene functionality that can be extended to other species, such as humans or baker’s yeast. Furthermore, we analyze a selected set of deletion mutants by paired transcriptome and proteome measurements and show that upregulation of proteins under stable transcript expression utilizes optimal codons. 

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3. ReporterSeq reveals genome-wide dynamic modulators of the heat shock response across diverse stressors

   https://doi.org/10.7554/eLife.57376  

   Alford, Brian D; Tassoni-Tsuchida, Eduardo; Khan, Danish; Work, Jeremy J; Valiant, Gregory; Brandman, Onn (July 2021, eLife)

   null (Ed.)

   Understanding cellular stress response pathways is challenging because of the complexity of regulatory mechanisms and response dynamics, which can vary with both time and the type of stress. We developed a reverse genetic method called ReporterSeq to comprehensively identify genes regulating a stress-induced transcription factor under multiple conditions in a time-resolved manner. ReporterSeq links RNA-encoded barcode levels to pathway-specific output under genetic perturbations, allowing pooled pathway activity measurements via DNA sequencing alone and without cell enrichment or single-cell isolation. We used ReporterSeq to identify regulators of the heat shock response (HSR), a conserved, poorly understood transcriptional program that protects cells from proteotoxicity and is misregulated in disease. Genome-wide HSR regulation in budding yeast was assessed across 15 stress conditions, uncovering novel stress-specific, time-specific, and constitutive regulators. ReporterSeq can assess the genetic regulators of any transcriptional pathway with the scale of pooled genetic screens and the precision of pathway-specific readouts. 

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4. Epigenetic Regulation of ABA-Induced Transcriptional Responses in Maize

   https://doi.org/10.1534/g3.119.400993  

   Vendramin, Stefania; Huang, Ji; Crisp, Peter A.; Madzima, Thelma F.; McGinnis, Karen M. (May 2020, G3: Genes|Genomes|Genetics)

   Plants are subjected to extreme environmental conditions and must adapt rapidly. The phytohormone abscisic acid (ABA) accumulates during abiotic stress, signaling transcriptional changes that trigger physiological responses. Epigenetic modifications often facilitate transcription, particularly at genes exhibiting temporal, tissue-specific and environmentally-induced expression. In maize ( Zea mays ), MEDIATOR OF PARAMUTATION 1 (MOP1) is required for progression of an RNA-dependent epigenetic pathway that regulates transcriptional silencing of loci genomewide. MOP1 function has been previously correlated with genomic regions adjoining particular types of transposable elements and genic regions, suggesting that this regulatory pathway functions to maintain distinct transcriptional activities within genomic spaces, and that loss of MOP1 may modify the responsiveness of some loci to other regulatory pathways. As critical regulators of gene expression, MOP1 and ABA pathways each regulate specific genes. To determine whether loss of MOP1 impacts ABA-responsive gene expression in maize, mop1-1 and Mop1 homozygous seedlings were subjected to exogenous ABA and RNA-sequencing. A total of 3,242 differentially expressed genes (DEGs) were identified in four pairwise comparisons. Overall, ABA-induced changes in gene expression were enhanced in mop1-1 homozygous plants. The highest number of DEGs were identified in ABA-induced mop1-1 mutants, including many transcription factors; this suggests combinatorial regulatory scenarios including direct and indirect transcriptional responses to genetic disruption ( mop1-1 ) and/or stimulus-induction of a hierarchical, cascading network of responsive genes. Additionally, a modest increase in CHH methylation at putative MOP1-RdDM loci in response to ABA was observed in some genotypes, suggesting that epigenetic variation might influence environmentally-induced transcriptional responses in maize. 

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5. Tup1 Paralog CgTUP11 Is a Stronger Repressor of Transcription than CgTUP1 in Candida glabrata

   https://doi.org/10.1128/msphere.00765-21  

   Bui, Lilian N.; Iosue, Christine L.; Wykoff, Dennis D. (April 2022, mSphere)

   Mitchell, Aaron P. (Ed.)

   ABSTRACT TUP1 is a well-characterized repressor of transcription in Saccharomyces cerevisiae and Candida albicans and is observed as a single-copy gene. We observe that most species that experienced a whole-genome duplication outside of the Saccharomyces genus have two copies of TUP1 in the Saccharomycotina yeast clade. We focused on Candida glabrata and demonstrated that the uncharacterized TUP1 homolog, C. glabrata TUP11 ( CgTUP11 ), is most like the S. cerevisiae TUP1 ( ScTUP1 ) gene through phenotypic assays and transcriptome sequencing (RNA-seq). Whereas CgTUP1 plays a role in gene repression, it is much less repressive in standard growth media. Through RNA-seq and reverse transcription-quantitative PCR (RT-qPCR), we observed that genes associated with pathogenicity ( YPS2 , YPS4 , and HBN1 ) are upregulated upon deletion of either paralog, and loss of both paralogs is synergistic. Loss of the corepressor CgCYC8 mimics the loss of both paralogs, but not to the same extent as the Cgtup1 Δ Cgtup11 Δ mutant for these pathogenesis-related genes. In contrast, genes involved in energy metabolism ( CgHXT2 , CgADY2 , and CgFBP1 ) exhibit similar behavior (dependence on both paralogs), but deletion of CgCYC8 is very similar to the Cgtup1 Δ Cgtup11 Δ mutant. Finally, some genes ( CgMFG1 and CgRIE1 ) appear to only be dependent on CgTUP11 and CgCYC8 and not CgTUP1 . These data indicate separable and overlapping roles for the two TUP1 paralogs and that other genes may function as the Cg Cyc8 corepressor. Through a comparison by RNA-seq of Sctup1 Δ, it was found that TUP1 homologs regulate similar genes in the two species. This work highlights that studies focused only on Saccharomyces may miss important biological processes because of paralog loss after genome duplication. IMPORTANCE Due to a whole-genome duplication, many yeast species related to C. glabrata have two copies of the well-characterized TUP1 gene, unlike most Saccharomyces species. This work identifies roles for the paralogs in C. glabrata , highlights the importance of the uncharacterized paralog, called TUP11 , and suggests that the two paralogs have both overlapping and unique functions. The TUP1 paralogs likely influence pathogenicity based on tup mutants upregulating genes that are associated with pathogenicity. 

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