Mechanisms of Transcriptional Regulation of Cat-1 Gene Expression by Endoplasmic Reticulum (ER) Stress

Li, Yi

21 July 2009

No description available.

Nutrition

cat-1 gene

transcriptional regulation

ER stress

Sodium ion transporters in sperm: Epigenetic regulation of the sperm-specific alpha4 Na,K-ATPase and role of the epithelial sodium channel alpha in sperm physiology

Kumar, Deepti Lava

06 May 2014

No description available.

Physiology

Molecular Biology

Transcriptional regulation of LAMB3 by p53

Jani, Meghna

January 2008

No description available.

Molecular Biology

p53

LAMB3

Hdm2

HdmX

transcriptional

Laminin-5

Combinatorial transcriptional regulation of the maize flavonoid pathway: understanding the old players and discovering new ones

Hernandez, Julia Marcela

14 July 2006

No description available.

Maize flavonoid pathway

transcriptional regulation

MYB

bHLH

ENT

Agenet

Functional Dissection of the Aristaless-related Homeobox Proteins, Arx and Rx

Fullenkamp, Amy N.

14 November 2008

No description available.

Molecular Biology

Aristaless

homeobox

Arx

Rx

transcriptional repression

Analysis of the Regulons Controlled by Transcriptional Regulators LuxR and LitR in Vibrio fischeri

Qin, Nan

18 August 2008

Quorum sensing is a bacterial signaling system that controls gene expression in a population density-dependent manner. In Gram-negative proteobacteria, the cell density control of luminescence was first observed in the symbiotic marine bacterium Vibrio fischeri and this system is one of the best studied quorum sensing systems. Two-dimensional sodium dodecyl sulfate-polyacrylamide (2D-SDS) gel electrophoresis analysis previously identified several non-Lux proteins in V. fischeri MJ-100 whose expression was dependent on LuxR and 3-oxo-hexanoyl-L-homoserine lactone (3-oxo-C6-HSL). A lacZ reporter was used to show that the promoters for qsrP, acfA, and ribB were directly activated via LuxR-3-oxo-C6-HSL in recombinant Escherichia coli. The sites of transcription initiation were established via primer extension analysis. Based on the position of the lux box-binding site near position â 40, all three promoters appear to have a class II-type promoter structure. Real-time reverse transcription-PCR was used to study the temporal expression of qsrP, acfA, and ribB during the exponential and stationary phases of growth, and electrophoretic mobility shift assays were used to compare the binding affinities of LuxR to the promoters under investigation. In order to fully characterize the LuxR regulon in V. fischeri ES114, microarray analysis was performed in the Greenberg lab (University of Washington) and 18 LuxR-3-oxo-C6-HSL regulated promoters were found including 2 genes (qsrP and acfA) identified previously in MJ-100 in addition to the well-studied lux operon. In collaboration with them, full-length purified LuxR protein was used to show direct interaction between the LuxR protein and 7 genes/operons newly identified out of 13 genes/operons examined. The binding affinity between LuxR proteins and those genes was also measured. Based on the sequence of the lux boxes of the known genes regulated by LuxR and LitR, a position specific weight matrix (PSWM) was created and used to search through the intergenic regions of the V. fischeri ES114 genome. Some potential LuxR and LitR-regulated genes with high score were tested experimently to confirm direct activation. For the LuxR regulon, these possible LuxR-regulated promoters were cloned into a lacZ reporter and tested for their LuxR dependence. Beyond the genes found in microarray, the promoter of the intergenic region VFA0658-0659 was found to be activated by LuxR and 3-oxo-C6-HSL. For the LitR regulon, two LitR-regulated genes found in the microarray were also identified using PSWM and confirmed by real-time PCR to be dependent on LitR for expression. EMSA experiments showed that LitR can specifically bind to the litR boxes of LitR-regulated genes, litR and VF0170 which confirmed that the regulation is direct. / Ph. D.

LuxR

transcriptional regulation

regulon

LitR

quorum sensing

luminescence

Vibrio fischeri

Characterization of AgaR and YihW, Members of the DeoR Family of Transcriptional Regulators, and GlpE, a Rhodanese Belonging to the GlpR Regulon, Also a Member of the DeoR Family

Ray, William Keith

24 August 1999

AgaR, a protein in <i>Escherichia coli</i> thought to control the metabolism of N-acetylgalactosamine, is a member of the DeoR family of transcriptional regulators. Three transcriptional promoters within a cluster of genes containing the gene for AgaR were identified, specific for <i>agaR, agaZ</i> and <i>agaS</i>, and the transcription start sites mapped. Transcription from these promoters was specifically induced by N-acetylgalactosamine or galactosamine, though K-12 strains lacked the ability to utilize these as sole sources of carbon. The activity of these promoters was constitutively elevated in a strain in which <i>agaR</i> had been disrupted confirming that the promoters are subject to negative regulation by AgaR. AgaR-His6, purified using immobilized metal affinity chromatography, was used for DNase I footprint analysis of the promoter regions. Four operator sites bound by AgaR were identified. A putative consensus binding sequence for AgaR was proposed based on these four sites. <i>In vivo</i> and <i>in vitro</i> analysis of the <i>agaZ</i> promoter indicated that this promoter was activated by the cAMP-cAMP receptor protein (CRP). Expression from the <i>aga</i> promoters was less sensitive to catabolite repression in revertants capable of <i>N</i>-acetylgalactosamine utilization, suggesting that these revertants have mutation(s) that result in an elevated level of inducer for AgaR. A cluster of genes at minute 87.7 of the <i>E. coli</i> genome contains a gene that encodes another member of the DeoR family of transcriptional regulators. This protein, YihW, is more similar to GlpR, transcriptional regulator of <i>sn</i>-glycerol 3-phosphate metabolism in <i>E. coli</i>, than other members of the DeoR family. Despite the high degree of similarity, YihW lacked the ability to repress P_glpK, a promoter known to be controlled by GlpR. A variant of YihW containing substitutions in the putative recognition helix to more closely match the recognition helix of GlpR was also unable to repress P_glpK. Transcriptional promoters identified in this cluster of genes were negatively regulated by YihW. Regulation of genes involved in the metabolism of <i>sn</i>-glycerol 3-phosphate in <i>E. coli</i> by GlpR has been well characterized. However, the function of a protein (GlpE) encoded by a gene cotranscribed with that for GlpR was unknown prior to this work. GlpE was identified as a single-domain, 12-kDa rhodanese (thiosulfate:cyanide sulfurtransferase). The enzyme was purified to near homogeneity and characterized. As shown for other characterized rhodaneses, kinetic analysis revealed that catalysis occurs via an enzyme-sulfur intermediate utilizing a double-displacement mechanism requiring an active-site cysteine. K_m (SSO₃²⁻) and K_m (CN⁻) were determined to be 78 mM and 17 mM, respectively. The native molecular mass of GlpE was 22.5 kDa indicating that GlpE functions as a dimer. GlpE exhibited a kcat of 230 s-1. Thioredoxin, a small multifunctional dithiol protein, served as sulfur-acceptor substrate for GlpE with an apparent K_m of 34 mM when thiosulfate was near its K_m, suggesting thioredoxin may be a physiological substrate. / Ph. D.

sulfurtransferase

iron-sulfur cluster biosynthesis

repressors

carbon metabolism

transcriptional control

Structure-Function Analysis of the EsaR N-terminal Domain

Geissinger, Jared Scott

24 January 2012

The LuxR protein family is a class of quorum-sensing regulated bacterial transcription factors that alter gene expression as a function of ligand detection. This coincides with a high population density and/or a low rate of signal ligand diffusion. The majority of LuxR proteins are activated only in the presence of the signal ligand, an acyl-homoserine lactone (AHL). EsaR, from the corn pathogen Pantoea stewartii, represents a subset of LuxR homologues that are active in the absence of AHL and deactivated by its presence. The mechanism by which EsaR responds to AHL in a manner opposite to that of the majority of LuxR homologues remains elusive. Unlike the majority of LuxR homologues, which require AHL for purification, EsaR can be purified and biochemically investigated in the absence and presence of AHL. This work sought to answer questions regarding the structure-function relationship of the LuxR homologue, EsaR. Fluorescence anisotropy was used to determine the relative DNA-binding affinity of wild type EsaR and three AHL-independent EsaR variants in the presence and absence of AHL. This enabled for quantitative analysis of the relative binding affinities of these AHL-independent variants for the EsaR binding site, the esa box. The results demonstrate that one AHL-independent EsaR variant has a slightly higher affinity for the esa box in the presence, rather than the absence of AHL. The affinity of the other two for the DNA is not impacted by AHL, potentially due to an inability to transduce the signal of ligand detection to the DNA binding domain. Constructs containing only the EsaR N-terminal domain (NTD) were also developed. These constructs circumvented solubility issues associated with the full-length protein, allowing for additional biochemical analysis. It was determined that the EsaR NTD alone is sufficient for multimerization and ligand binding. Additionally, preliminary X-ray crystallography efforts have established some of the early parameters required to solve the crystal structure of the EsaR ligand binding domain in both the presence and absence of AHL. If pursued, these structures would be the first solved of a LuxR homologue ligand binding domain in both the presence and absence of the native AHL, potentially demonstrating the conformational change that occurs as a result of ligand binding. Collectively, these findings have established some of the groundwork required to resolve the question of what sort of conformational changes occur in EsaR as a result of ligand binding. / Master of Science

EsaR

LuxR homologue

Pantoea stewartii

quorum sensing

transcriptional repressor

Molecular Interactions of Type III Secretion System Transcriptional Regulators in Pseudomonas aeruginosa: ExsA and ExsD

Bernhards, Robert Cory

03 June 2013

The opportunistic pathogen Pseudomonas aeruginosa ranks among the leading causes of nosocomial infections.  The type III secretion system (T3SS) aids acute P. aeruginosa infections by injecting potent cytotoxins (effectors) into host cells to suppress the host's innate immune response.  Expression of all T3SS-related genes is strictly dependent upon the transcription factor ExsA.  Consequently, ExsA and the biological processes that regulate ExsA function are of great biomedical interest.  The ExsA-ExsC-ExsD-ExsE signaling cascade ties host cell contact to the up-regulation of T3SS gene expression.  Prior to T3SS induction, the antiactivator protein ExsD binds to ExsA and blocks ExsA-dependent transcription by interfering with ExsA dimerization and promoter interactions.  Upon host cell contact, ExsD is sequestered by the T3SS chaperone ExsC, resulting in the release of ExsA and an up-regulation of the T3SS. ExsA is an AraC/XylS-type transcriptional regulator and belongs to a subfamily of activators that regulate the T3SS in a variety of Gram-negative pathogens.  These regulators are characteristically difficult to purify due to the low solubility of their C-terminal DNA binding domains.  A new method for purifying ExsA was developed and produced ExsA with improved solubility.  The interaction of ExsA and its PexsD promoter was examined using fluorescence anisotropy.  An in vitro transcription assay was developed and it was determined that ExsA is sufficient to activate T3SS transcription. Next, the ExsD--ExsA inhibitory mechanism was examined.  It was demonstrated for the first time that ExsD alone is sufficient to inhibit ExsA-dependent transcription in  vitro without the aid of any other cellular factors.  More significantly and contrary to previously published results, it was discovered that independently folded ExsD and ExsA are capable of interacting, but only at 37 degrees C and not at 30 degrees C.  Guided by the crystal structure of ExsD, a monomeric variant of the protein was designed to demonstrate that ExsD trimerization prevents ExsD from inhibiting ExsA-dependent transcription at 30 degrees C. To further elucidate the ExsD-ExsA inhibitory mechanism, the ExsD-ExsA interface was examined.  ExsD variants were generated and used to determine which region of ExsD interacts with ExsA.  Interestingly, ExsD was also found to bind DNA, although it is unclear whether or not this plays a role in ExsA inhibition.  Fully understanding the mechanism by which ExsD inhibits ExsA may enable the development of drugs that target ExsA in order to shut down the T3SS, thereby eliminating P. aeruginosa infection. / Ph. D.

Pseudomonas aeruginosa

ExsA

ExsD

type III secretion system

transcriptional regulation

Characterization of the VtlR regulons in Brucella abortus and Agrobacterium tumefaciens

Budnick, James Andrew

25 April 2019

Brucella abortus and Agrobacterium tumefaciens are pathogenic bacteria that infect animals and plants, respectively. These bacteria are genetically similar and are found within the same Class, Alphaproteobacteria, and Order, Rhizobiales, of the domain Eubacteria; however, they survive and replicate in vastly different environmental niches. In Order to adapt to different environments, bacteria utilize several mechanisms of gene regulation to tightly control gene expression. Two of these mechanisms include transcriptional regulators and small regulatory RNAs (sRNAs), which can activate and repress gene expression through various interactions with DNA, mRNA, and proteins. A well-conserved transcriptional regulator among the Rhizobiales is VtlR, a virulence-associated transcriptional LysR regulator. The objectives of this dissertation were three fold: 1) characterize the known regulon of VtlR in B. abortus with regards to gene regulatory function and virulence, 2) determine the regulon of VtlR in A. tumefaciens and define the mechanism by which this regulation occurs, and 3) define the role of an ABC-type transport system indirectly regulated by VtlR in B. abortus that putatively imports the non-proteinogenic amino acid gamma-aminobutyric acid (GABA). VtlR was characterized in B. abortus as a virulence-associated transcriptional regulator that directly activates four genes: the sRNA AbcR2, and the three small hypothetical proteins BAB1_0914, BAB2_0512, and BAB2_0574; and deletion of vtlR led to a significant defect in the ability of B. abortus to cause infection in vitro and in vivo. Since dysregulation of abcR2 alone could not account for the defect in virulence, it was hypothesized that one or all three hypothetical proteins could be responsible for a virulence phenotype observed in ΔvtlR. This turned out to not be the case, as a deletion of the entire VtlR regulon displayed no difference in virulence compared to the parental strain. Further characterization of the small hypothetical proteins is outlined in Chapter 2 and the data revealed bona fide translation of each small protein, and the deletion strain of the VtlR regulon displayed a growth defect when grown in the presence of the sugar fucose. This phenotype was subsequently observed in ΔvtlR as well. This led to the identification of a putative fucose transport and metabolism locus in B. abortus that has yet to be studied. In A. tumefaciens, VtlR is necessary for proper attachment to plant cells and biofilm formation and regulates over 200 genes, significantly more than the four genes VtlR regulates in B. abortus. The mechanism by which this occurs was unknown, and the relationship between VtlR and AbcR1 or AbcR2 was uncharacterized. The data in Chapter 3 outline the VtlR network by showing that VtlR regulation of myriad genes in A. tumefaciens is primarily indirect via the direct regulation of a few sRNAs. This direct interaction was shown experimentally and a VtlR binding box was identified in the A. tumefaciens genome. This project outlines the divergence of a regulatory element between phylogenetically related organisms that occupy different environmental niches. The AbcR sRNAs are conserved throughout the Rhizobiales and regulate numerous ABC-type transport systems within these bacteria. In A. tumefaciens, one of these transport systems specifically transports the amino acds proline and GABA. B. abortus contains homologs of this system, which led to the hypothesis that the brucellae may also transport GABA but for a yet unknown purpose. The data in Chapter 4 revealed that B. abortus also transports GABA in vitro and this transport is under the regulation of AbcR1 and AbcR2. This transport was increased under extreme nutrient limitations and was uninhibited by the presence of other amino acids. Metabolic studies showed GABA is not utilized by B. abortus under aerobic conditions, and transcriptomic data revealed increased expression of several loci in the presence of GABA. Altogether, this study uncovers a putative signaling role for the amino acid GABA that has been understudied in bacterial pathogens that infect animal hosts. Overall, the work presented in this dissertation is focused on further elucidating the biological role of downstream regulatory targets of both VtlR and the sRNAs AbcR1 and AbcR2 in the related organisms Brucella abortus and Agrobacterium tumefaciens. Findings show that while there are similarities between the two systems, there are also many differences that may be attributed to the vastly different lifestyles of each organism. / Doctor of Philosophy / Brucella abortus and Agrobacterium tumefaciens are two highly related bacterial pathogens that infect mammals and plants, respectively. Although genetically related, both organisms survive and replicate in vastly different environmental niches with one living in the soil (i.e., A. tumefaciens) and the other living within immune cells of the infected host (i.e., B. abortus). In Order to quickly adapt to changing environmental conditions, the bacteria must rapidly control gene expression through multiple regulatory mechanisms. The works presented in this dissertation will focus on further characterizing one of these regulatory systems and comparing the homologous systems shared by B. abortus and A. tumefaciens. This includes uncovering a putative sugar transport and metabolism system, as well as discovering the potential for host-pathogen signaling via the well-studied neurotransmitter GABA.

Brucella abortus

Agrobacterium tumefaciens

transcriptional regulon

small protein

GABA