Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Despite decades of research, predicting where a transcription factor (TF) binds using its sequences alone continues to be an outstanding problem. Here, our thermodynamic model of Gal4p-DNA binding revealed a new mechanism of binding site selection in which Gal4p can bind to promoters that lacks it consensus site. Further investigation revealed that these sequences that Gal4p unexpectedly binds to have a high density of its half site, CGG. Analyses showed the ability of CGG half sites to predict zinc cluster TF in vivo binding and exposed a clear relationship between CGG half sites and zinc cluster binding in multiple binding datasets. To dissect the molecular logic of this half site mode of binding we designed a Sort-seq library containing 6,798 yeast promoter sequences and measured their expression. We learned that there is a linear relationship between CGG half site density and zinc cluster driven expression in vivo. Additionally, we found that promoters encoding 10 half sites have the same transcriptional output as a single consensus site and found no clear effects of half site orientation and spacing on strength of activation. Our experiments demonstrate that this novel mode of half site binding is widespread across the yeast genome and expands our knowledge about TF binding specificity that can be applied to higher eukaryotes.

Project description:Despite decades of research, predicting where a transcription factor (TF) binds using its sequences alone continues to be an outstanding problem. Here, our thermodynamic model of Gal4p-DNA binding revealed a new mechanism of binding site selection in which Gal4p can bind to promoters that lacks it consensus site. Further investigation revealed that these sequences that Gal4p unexpectedly binds to have a high density of its half site, CGG. Analyses showed the ability of CGG half sites to predict zinc cluster TF in vivo binding and exposed a clear relationship between CGG half sites and zinc cluster binding in multiple binding datasets. To dissect the molecular logic of this half site mode of binding we designed a Sort-seq library containing 6,798 yeast promoter sequences and measured their expression. We learned that there is a linear relationship between CGG half site density and zinc cluster driven expression in vivo. Additionally, we found that promoters encoding 10 half sites have the same transcriptional output as a single consensus site and found no clear effects of half site orientation and spacing on strength of activation. Our experiments demonstrate that this novel mode of half site binding is widespread across the yeast genome and expands our knowledge about TF binding specificity that can be applied to higher eukaryotes.

Project description:Plant microRNAs (miRNAs) typically form near-perfect duplexes with their targets and mediate mRNA cleavage. Here, we describe an unconventional miRNA target of miR398 in Arabidopsis, an mRNA encoding the blue copper-binding protein (BCBP). BCBP mRNA carries an miR398 complementary site in its 5'-untranslated region (UTR) with a bulge of six nucleotides opposite to the 5' region of the miRNA. Despite the disruption of a target site region thought to be especially critical for function, BCBP mRNAs are cleaved by ARGONAUTE1 between nucleotides 10th and 11th, opposite to the miRNA, like conventional plant target sites. Levels of BCBP mRNAs are inversely correlated to levels of miR398 in mutants lacking the miRNA, or transgenic plants overexpressing it. Introducing two mutations that disrupt the miRNA complementarity around the cleavage site renders the target cleavage-resistant. The BCBP site functions outside of the context of the BCBP mRNA and does not depend on 5'-UTR location. Reducing the bulge does not interfere with miR398-mediated regulation and completely removing it increases the efficiency of the slicing. Analysis of degradome data and target predictions revealed that the miR398-BCBP interaction seems to be rather unique. Nevertheless, our results imply that functional target sites with non-perfect pairings in the 5' region of an ancient conserved miRNA exist in plants.

Project description:Almost all humans are colonized with Candida albicans However, in immunocompromised individuals, this benign commensal organism becomes a serious, life-threatening pathogen. Here, we describe and analyze the regulatory networks that modulate innate responses in the host niches. We identified Zcf15 and Zcf29, two Zinc Cluster transcription Factors (ZCF) that are required for C. albicans virulence. Previous sequence analysis of clinical C. albicans isolates from immunocompromised patients indicates that both ZCF genes diverged during clonal evolution. Using in vivo animal models, ex vivo cell culture methods, and in vitro sensitivity assays, we demonstrate that knockout mutants of both ZCF15 and ZCF29 are hypersensitive to reactive oxygen species (ROS), suggesting they help neutralize the host-derived ROS produced by phagocytes, as well as establish a sustained infection in vivo Transcriptomic analysis of mutants under resting conditions where cells were not experiencing oxidative stress revealed a large network that control macro and micronutrient homeostasis, which likely contributes to overall pathogen fitness in host niches. Under oxidative stress, both transcription factors regulate a separate set of genes involved in detoxification of ROS and down-regulating ribosome biogenesis. ChIP-seq analysis, which reveals vastly different binding partners for each transcription factor (TF) before and after oxidative stress, further confirms these results. Furthermore, the absence of a dominant binding motif likely facilitates their mobility, and supports the notion that they represent a recent expansion of the ZCF family in the pathogenic Candida species. Our analyses provide a framework for understanding new aspects of the interface between C. albicans and host defense response, and extends our understanding of how complex cell behaviors are linked to the evolution of TFs.

Project description:A Novel mode of half site binding in budding yeast

Project description:BackgroundZinc Finger Nucleases (ZFNs) are man-made restriction enzymes useful for manipulating genomes by cleaving target DNA sequences. ZFNs allow therapeutic gene correction or creation of genetically modified model organisms. ZFN specificity is not absolute; therefore, it is essential to select ZFN target sites without similar genomic off-target sites. It is important to assay for off-target cleavage events at sites similar to the target sequence.ResultsZFN-Site is a web interface that searches multiple genomes for ZFN off-target sites. Queries can be based on the target sequence or can be expanded using degenerate specificity to account for known ZFN binding preferences. ZFN off-target sites are outputted with links to genome browsers, facilitating off-target cleavage site screening. We verified ZFN-Site using previously published ZFN half-sites and located their target sites and their previously described off-target sites. While we have tailored this tool to ZFNs, ZFN-Site can also be used to find potential off-target sites for other nucleases, such as TALE nucleases.ConclusionsZFN-Site facilitates genome searches for possible ZFN cleavage sites based on user-defined stringency limits. ZFN-Site is an improvement over other methods because the FetchGWI search engine uses an indexed search of genome sequences for all ZFN target sites and possible off-target sites matching the half-sites and stringency limits. Therefore, ZFN-Site does not miss potential off-target sites.

Project description:A Novel mode of half site binding in budding yeast II

Project description:A Novel mode of half site binding in budding yeast I

Project description:Transcription of rRNA genes (rDNAs) in the nucleolus is regulated by epigenetic chromatin modifications including histone H3 lysine (de)methylation. Here we show that LegAS4, a Legionella pneumophila type IV secretion system (TFSS) effector, is targeted to specific rDNA chromatin regions in the host nucleolus. LegAS4 promotes rDNA transcription, through its SET-domain (named after Drosophila Su(var)3-9, enhancer of zeste [E(z)], and trithorax [trx]) histone lysine methyltransferase (HKMTase) activity. LegAS4's association with rDNA chromatin is mediated by interaction with host HP1α/γ. L. pneumophila infection potently activates rDNA transcription in a TFSS-dependent manner. Other bacteria, including Bordetella bronchiseptica and Burkholderia thailandensis, also harbour nucleolus-localized LegAS4-like HKMTase effectors. The B. thailandensis type III effector BtSET promotes H3K4 methylation of rDNA chromatin, contributing to infection-induced rDNA transcription and bacterial intracellular replication. Thus, activation of host rDNA transcription might be a general bacterial virulence strategy.