Abstract:The transcriptional activator AphB has been implicated in acid resistance and pathogenesis in the food borne pathogens Vibrio vulnificus and Vibrio cholerae. To date, the full-length AphB crystal structure of V. cholerae has been determined and characterized by a tetrameric assembly of AphB consisting of a DNA binding domain and a regulatory domain (RD). Although acidic pH and low oxygen tension might be involved in the activation of AphB, it remains unknown which ligand or stimulus activates AphB at the molec… Show more
“…Applying PGSEA on miRNA target genes highlights miRNA-30a (Additional file 3: Figure S20), whose target genes are specifically activated by IR in wild-type B cells. miRNA-30a was shown to be involved in response to IR [77] and mutually regulate p53 [78]. Thus, the complex p53 signaling pathways are unveiled with remarkable accuracy.Fig.…”
BackgroundRNA-seq is widely used for transcriptomic profiling, but the bioinformatics analysis of resultant data can be time-consuming and challenging, especially for biologists. We aim to streamline the bioinformatic analyses of gene-level data by developing a user-friendly, interactive web application for exploratory data analysis, differential expression, and pathway analysis.ResultsiDEP (integrated Differential Expression and Pathway analysis) seamlessly connects 63 R/Bioconductor packages, 2 web services, and comprehensive annotation and pathway databases for 220 plant and animal species. The workflow can be reproduced by downloading customized R code and related pathway files. As an example, we analyzed an RNA-Seq dataset of lung fibroblasts with Hoxa1 knockdown and revealed the possible roles of SP1 and E2F1 and their target genes, including microRNAs, in blocking G1/S transition. In another example, our analysis shows that in mouse B cells without functional p53, ionizing radiation activates the MYC pathway and its downstream genes involved in cell proliferation, ribosome biogenesis, and non-coding RNA metabolism. In wildtype B cells, radiation induces p53-mediated apoptosis and DNA repair while suppressing the target genes of MYC and E2F1, and leads to growth and cell cycle arrest. iDEP helps unveil the multifaceted functions of p53 and the possible involvement of several microRNAs such as miR-92a, miR-504, and miR-30a. In both examples, we validated known molecular pathways and generated novel, testable hypotheses.ConclusionsCombining comprehensive analytic functionalities with massive annotation databases, iDEP (http://ge-lab.org/idep/) enables biologists to easily translate transcriptomic and proteomic data into actionable insights.Electronic supplementary materialThe online version of this article (10.1186/s12859-018-2486-6) contains supplementary material, which is available to authorized users.
“…Applying PGSEA on miRNA target genes highlights miRNA-30a (Additional file 3: Figure S20), whose target genes are specifically activated by IR in wild-type B cells. miRNA-30a was shown to be involved in response to IR [77] and mutually regulate p53 [78]. Thus, the complex p53 signaling pathways are unveiled with remarkable accuracy.Fig.…”
BackgroundRNA-seq is widely used for transcriptomic profiling, but the bioinformatics analysis of resultant data can be time-consuming and challenging, especially for biologists. We aim to streamline the bioinformatic analyses of gene-level data by developing a user-friendly, interactive web application for exploratory data analysis, differential expression, and pathway analysis.ResultsiDEP (integrated Differential Expression and Pathway analysis) seamlessly connects 63 R/Bioconductor packages, 2 web services, and comprehensive annotation and pathway databases for 220 plant and animal species. The workflow can be reproduced by downloading customized R code and related pathway files. As an example, we analyzed an RNA-Seq dataset of lung fibroblasts with Hoxa1 knockdown and revealed the possible roles of SP1 and E2F1 and their target genes, including microRNAs, in blocking G1/S transition. In another example, our analysis shows that in mouse B cells without functional p53, ionizing radiation activates the MYC pathway and its downstream genes involved in cell proliferation, ribosome biogenesis, and non-coding RNA metabolism. In wildtype B cells, radiation induces p53-mediated apoptosis and DNA repair while suppressing the target genes of MYC and E2F1, and leads to growth and cell cycle arrest. iDEP helps unveil the multifaceted functions of p53 and the possible involvement of several microRNAs such as miR-92a, miR-504, and miR-30a. In both examples, we validated known molecular pathways and generated novel, testable hypotheses.ConclusionsCombining comprehensive analytic functionalities with massive annotation databases, iDEP (http://ge-lab.org/idep/) enables biologists to easily translate transcriptomic and proteomic data into actionable insights.Electronic supplementary materialThe online version of this article (10.1186/s12859-018-2486-6) contains supplementary material, which is available to authorized users.
“…Both residues are found far from the DNA binding site, but while K271 is located on the back relative to the dimerization interface, the K103 was in a position to potentially affect dimerization (Figure 7A ). In the Vibrio vulnificus AphB homolog, K103 was shown to interact with an as yet unknown ligand (Park et al, 2017 ). Acetylation of vibriobactin transporter VctP (KNH52012) K110 was identified in both growth conditions.…”
Protein lysine acetylation is recognized as an important reversible post translational modification in all domains of life. While its primary roles appear to reside in metabolic processes, lysine acetylation has also been implicated in regulating pathogenesis in bacteria. Several global lysine acetylome analyses have been carried out in various bacteria, but thus far there have been no reports of lysine acetylation taking place in the important human pathogen Vibrio cholerae. In this study, we analyzed the lysine acetylproteome of the human pathogen V. cholerae V52. By applying a combination of immuno-enrichment of acetylated peptides and high resolution mass spectrometry, we identified 3,402 acetylation sites on 1,240 proteins. Of the acetylated proteins, more than half were acetylated on two or more sites. As reported for other bacteria, we observed that many of the acetylated proteins were involved in metabolic and cellular processes and there was an over-representation of acetylated proteins involved in protein synthesis. Of interest, we demonstrated that many global transcription factors such as CRP, H-NS, IHF, Lrp and RpoN as well as transcription factors AphB, TcpP, and PhoB involved in direct regulation of virulence in V. cholerae were acetylated. In conclusion, this is the first global protein lysine acetylome analysis of V. cholerae and should constitute a valuable resource for in-depth studies of the impact of lysine acetylation in pathogenesis and other cellular processes.
“…The RD of LTTRs has an inducer binding cavity (IBC) and is presumed to play a critical role in the conformational change of the LTTR tetramer upon inducer binding (Choi et al, 2001;Maddocks and Oyston, 2008;Quade et al, 2011;Park et al, 2017). The RD from CysB was the first crystal structure solved of a RD (Tyrell et al, 1997).…”
Section: Regulatory Domain (Rd)mentioning
confidence: 99%
“…RD-II contains a five-stranded -sheet that is strongly twisted and four -helices ( Fig. 4) (Tyrell et al, 1997;Muraoka et al, 2003;Monferrer et al, 2010;Quade et al, 2011;Park et al, 2017). Structural studies of BenM, OxyR, PcaQ, RovM, AphB and DntR have led us to hypothesize that inducer binding (or environmental change) to the RD of LTTR causes a conformational change in the RD that is propagated throughout the tetrameric LTTR and changes the bend angle of the promoter DNA (Kovacikova and Skorupski, 2001;Bundy et al, 2002;Smirnova et al, 2004;Quade et al, 2011;Wei et al, 2012;Jo et al, 2015) However, while crystal structures of OxyR (Choi et al, 2001;Jo et al, 2015), BenM (Ezezika et al, 2007a) and DntR (Devesse et al, 2011) have revealed conformational changes of the RD upon inducer binding, conformational changes of tetrameric full-length LTTR upon inducer binding have not been observed in the crystal.…”
Section: Regulatory Domain (Rd)mentioning
confidence: 99%
“…In the closed form, there are interactions between two helices from two RD-II subdomains (two V helices from two distinct RD-II) that are related by a two-fold axis. Upon inducer binding, local conformational changes in the RD (Ezezika et al, 2007a;Devesse et al, 2011;Park et al, 2017) seem to disrupt helix-helix interactions leading to a structural change to the open form ( Fig. 3(C)) (Choi et al, 2001;Monferrer et al, 2010;Devesse et al, 2011).…”
Section: Transition From Closed To Open Form Of Tetrameric Lttrsmentioning
LysR-type transcriptional regulators (LTTRs) comprise one of the largest families of transcriptional regulators in bacteria andcontrol gene expression of various types of metabolic, virulence and physiological functions. LTTRs typically form homotetramers and require an inducer molecule(s) to activate the transcription of target genes. The N-terminal region of LTTRs contains a DNAbinding domain (DBD) with the winged helix-turn-helix motif that specifically binds the promoter region of target genes. The C-terminal region of LTTRs is connected to the DBD by a linker helix and forms the regulatory domain (RD) that contains a binding pocket for inducer molecules. Crystal structures of several LTTR family members together with their biochemical analyses have provided a potential mechanism for the initial process of transcriptional activation by LTTRs. First, helix 3 of the winged helix-turn-helix motif in DBD is supposed to distinguish the recognition binding site (RBS) in the promoter region, resulting in complex formation through interactions between two DBDs in the tetrameric LTTR and RBS. Formation of this complex seems to enable interactions between the other two DBDs in the LTTR tetramer and the activation binding site (ABS) in the promoter region.The binding of the tetrameric LTTR to both the RBS and ABS causes the promoter DNA to adopt a bent structure because the four DBDs in the tetrameric LTTR are arranged in a V-shaped manner at the bottom of the LTTR. Interaction of an inducer molecule(s) with the RD seems to cause a quaternary structural change of the LTTR that relaxes the bending angle of the promoter DNA with a concomitant shift of the bound DBDs at the ABS. These events facilitate recruitment of RNA polymerase to its binding site in the promoter region, which overlaps with the ABS for LTTR.
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