Sandy Thao scite author profile

Evidence suggesting that eukaryotes and archaea use reversible N ε-lysine (N ε-Lys) acetylation to modulate gene expression has been reported, but evidence for bacterial use of N ε-Lys acetylation for this purpose is lacking. Here, we report data in support of the notion that bacteria can control gene expression by modulating the acetylation state of transcription factors (TFs). We screened the E. coli proteome for substrates of the bacterial Gcn5-like protein acetyltransferase (Pat). Pat acetylated four TFs, including the RcsB global regulatory protein, which controls cell division, and capsule and flagellum biosynthesis in many bacteria. Pat acetylated residue Lys180 of RcsB, and the NAD+-dependent Sir2 (sirtuin)-like protein deacetylase (CobB) deacetylated acetylated RcsB (RcsBAc), demonstrating that N ε-Lys acetylation of RcsB is reversible. Analysis of RcsBAc and variant RcsB proteins carrying substitutions at Lys180 provided biochemical and physiological evidence implicating Lys180 as a critical residue for RcsB DNA-binding activity. These findings further the likelihood that reversible N ε-Lys acetylation of transcription factors is a mode of regulation of gene expression used by all cells.

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Control of protein function by reversible Nɛ-lysine acetylation in bacteria

Thao

Escalante‐Semerena

2011

Current Opinion in Microbiology

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Recently published work indicates that reversible Nε-lysine (Nε-Lys) acetylation of proteins in bacteria may be as diverse, and as important for cellular function, as it has been reported in eukaryotes for the last five decades. In addition to biochemical and genetic approaches, proteomic studies have identified Nε-Lys acetylation of proteins and enzymes involved in diverse cellular activities such as transcription, translation, stress response, detoxification, and especially carbohydrate and energy metabolism. These findings provide a platform for elucidating the molecular mechanisms behind modulation of enzyme activity by Nε-Lys acetylation, as well as for understanding how the prokaryotic cell maintains homeostasis in a changing environment.

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Results from high-throughput DNA cloning of Arabidopsis thaliana target genes using site-specific recombination

Thao

Zhao

Kimball

et al. 2004

J Struct Funct Genomics

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The Center for Eukaryotic Structural Genomics (CESG) was founded as a collaborative effort to develop technologies for the rapid and economic determination of protein three-dimensional structures. The initial focus was on the genome of the model plant Arabidopsis thaliana. Protocols for high-throughput cloning of Arabidopsis open reading frames into Escherichia coli expression vectors are presented along with an analysis of results from approximately 2000 cloning experiments. Open reading frames were chosen on the likelihood that they would represent important unknown regions of protein conformation and fold space or that they would elucidate novel fold-function relationships. The chosen open reading frames were amplified from a cDNA pool created by reverse transcription of RNA isolated from an Arabidopsis callus culture. A novel Gateway protocol was developed to insert the amplified open reading frames into an entry vector for storage and sequence determination. Sequence verified entry clones were then used to create expression vectors again via the Gateway system.

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Biochemical and Thermodynamic Analyses of Salmonella enterica Pat, a Multidomain, Multimeric N ^ε -Lysine Acetyltransferase Involved in Carbon and Energy Metabolism

Thao

Escalante‐Semerena

2011

mBio

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In the bacterium Salmonella enterica, the CobB sirtuin protein deacetylase and the Gcn5-related Nε-acetyltransferase (GNAT) Pat control carbon utilization and metabolic flux via Nε-lysine acetylation/deacetylation of metabolic enzymes. To date, the S. enterica Pat (SePat) acetyltransferase has not been biochemically characterized. Here we report the kinetic and thermodynamic characterization of the SePat enzyme using two of its substrates, acetyl coenzyme A (Ac-CoA) synthetase (Acs; AMP forming, EC 6.2.1.1) and Ac-CoA. The data showed typical Michaelis-Menten kinetic behavior when Ac-CoA was held at a saturating concentration while Acs was varied, and a sigmoidal kinetic behavior was observed when Acs was saturating and the Ac-CoA concentration was varied. The observation of sigmoidal kinetics and positive cooperativity for Ac-CoA is an unusual feature of GNATs. Results of isothermal titration calorimetry (ITC) experiments showed that binding of Ac-CoA to wild-type SePat produced a biphasic curve having thermodynamic properties consistent with two distinct sites. Biphasicity was not observed in ITC experiments that analyzed the binding of Ac-CoA to a C-terminal construct of SePat encompassing the predicted core acetyltransferase domain. Subsequent analytical gel filtration chromatography studies showed that in the presence of Ac-CoA, SePat oligomerized to a tetrameric form, whereas in the absence of Ac-CoA, SePat behaved as a monomer. The positive modulation of SePat activity by Ac-CoA, a product of the Acs enzyme that also serves as a substrate for SePat-dependent acetylation, is likely a layer of metabolic control.

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Letter to the Editor: Solution Structure of a Homodimeric Hypothetical Protein, At5g22580, a Structural Genomics Target from Arabidopsis Thaliana

Cornilescu

Zhao

et al. 2004

J Biomol NMR

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Sandy Thao

Nε−Lysine Acetylation of a Bacterial Transcription Factor Inhibits Its DNA-Binding Activity

Control of protein function by reversible Nɛ-lysine acetylation in bacteria

Results from high-throughput DNA cloning of Arabidopsis thaliana target genes using site-specific recombination

Biochemical and Thermodynamic Analyses of Salmonella enterica Pat, a Multidomain, Multimeric N ^ε -Lysine Acetyltransferase Involved in Carbon and Energy Metabolism

Letter to the Editor: Solution Structure of a Homodimeric Hypothetical Protein, At5g22580, a Structural Genomics Target from Arabidopsis Thaliana

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Sandy Thao

Nε−Lysine Acetylation of a Bacterial Transcription Factor Inhibits Its DNA-Binding Activity

Control of protein function by reversible Nɛ-lysine acetylation in bacteria

Results from high-throughput DNA cloning of Arabidopsis thaliana target genes using site-specific recombination

Biochemical and Thermodynamic Analyses of Salmonella enterica Pat, a Multidomain, Multimeric N ε -Lysine Acetyltransferase Involved in Carbon and Energy Metabolism

Letter to the Editor: Solution Structure of a Homodimeric Hypothetical Protein, At5g22580, a Structural Genomics Target from Arabidopsis Thaliana

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Product

Resources

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Biochemical and Thermodynamic Analyses of Salmonella enterica Pat, a Multidomain, Multimeric N ^ε -Lysine Acetyltransferase Involved in Carbon and Energy Metabolism