Lesa M.S. Worsham scite author profile

Hemolysin toxin produced and secreted by pathogenic Escherichia coli is one of a family of cytolytic, structurally homologous protein toxins known as RTX (repeats in toxin) toxins. RTX toxins are products of a gene cluster, CABD. The A gene product, nontoxic hemolysin (proHlyA), is made toxic by posttranslational fatty acylation of two internal lysine residues. HlyC, the C gene product, is essential for acylation, and acyl-acyl carrier protein (ACP) is the acyl donor. HlyB and HlyD are involved in secretion of the toxin. ProHlyA and HlyC were separately subcloned, expressed, and purified, and acyl-ACPs with diverse radioactive acyl groups were synthesized. With these proteins, the conversion of proHlyA to HlyA by acyl transfer was assayed. Acyl-ACP was the obligate acyl donor. Acyl transfer was catalyzed by HlyC monomer, and an acyl-enzyme intermediate was shown. Reaction was inhibited by ACPSH but not by fatty acid or fatty-acyl CoA. Km and Vmax for HlyA were 0.94 microM and 7.5 pmol of acyl group transferred/min, respectively; Km and Vmax for myristoyl-ACP were 0.48 microM and 6.9 pmol/min. The kinetic parameters of different acyl-ACPs resembled a competitive inhibition as acyl group carbon chain length increased; Km's increased while Vmax's remained unchanged. The different kinetic efficacies in the acyltransferase reaction of the ACPs with different acyl groups contrasted notably with the lytic powers of the corresponding acyl-toxins that they generated.

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HlyC, the Internal Protein Acyltransferase That Activates Hemolysin Toxin: Role of Conserved Histidine, Serine, and Cysteine Residues in Enzymatic Activity As Probed by Chemical Modification and Site-Directed Mutagenesis

Trent

Worsham

Ernst-Fonberg

1999

Biochemistry

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HlyC is an internal protein acyltransferase that activates hemolysin, a toxic protein produced by pathogenic Escherichia coli. Acyl-acyl carrier protein (ACP) is the essential acyl donor. Separately subcloned, expressed, and purified prohemolysin A (proHlyA), HlyC, and [1-14C]myristoyl-ACP have been used to study the conversion of proHlyA to HlyA [Trent, M. S., Worsham, L. M., and Ernst-Fonberg, M. L. (1998) Biochemistry 37, 4644-4655]. HlyC and hemolysin belong to a family of at least 13 toxins produced by Gram-negative bacteria. The homologous acyltransferases of the family show a number of conserved residues that are possible candidates for participation in acyl transfer. Specific chemical reagents and site-directed mutagenesis showed that neither the single conserved cysteine nor the three conserved serine residues were required for enzyme activity. Treatment with the reversible histidine-modifying diethyl pyrocarbonate (DEPC) inhibited acyltransferase activity, and acyltransferase activity was restored following hydroxylamine treatment. The substrate myristoyl-ACP protected HlyC from DEPC inhibition. These findings and spectral absorbance changes suggested that histidine, particularly a histidine proximal to the substrate binding site, was essential for enzyme activity. Site-directed mutageneses of the single conserved histidine residue, His23, to alanine, cysteine, or serine resulted in each instance in complete inactivation of the enzyme.

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Amino Acid Residues of Escherichia coli Acyl Carrier Protein Involved in Heterologous Protein Interactions

et al. 2002

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Acyl carrier protein (ACP) is a small, highly conserved protein with an essential role in a myriad of reactions throughout lipid metabolism in plants and bacteria where it interacts with a remarkable diversity of proteins. The nature of the proper recognition and precise alignment between the protein moieties of ACP and its many interactive proteins is not understood. Residues conserved among ACPs from numerous plants and bacteria were considered as possibly being crucial to ACP's function, including protein-protein interaction, and a method of identifying amino acid residue clusters of high hydrophobicity on ACP's surface was used to estimate residues possibly involved in specific ACP-protein interactions. On the basis of this information, single-site mutation analysis of multiple residues, one at a time, of ACP was used to probe the identities of potential contact residues of ACPSH or acyl-ACP involved in specific interactions with selected enzymes. The roles of particular ACP residues were more precisely defined by site-directed fluorescence analyses of various myristoyl-mutant-ACPs upon specific interaction with the Escherichia coli hemolysin-activating acyltransferase, HlyC. This was done by selectively labeling each mutated site, one at a time, with an environmentally sensitive fluoroprobe and observing its fluorescence behavior in the absence and presence of HlyC. Consequently, a picture of the portion of ACP involved in selected macromolecular interaction has emerged.

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HlyC, the Internal Protein Acyltransferase That Activates Hemolysin Toxin: Roles of Various Conserved Residues in Enzymatic Activity As Probed by Site-Directed Mutagenesis

1999

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Hemolysin, a toxic protein produced by pathogenic Escherichia coli, is one of a family of homologous toxins and toxin-processing proteins produced by Gram-negative bacteria. HlyC, an internal protein acyltransferase, converts it from nontoxic prohemolysin to toxic hemolysin. Acyl-acyl carrier protein is the essential acyl donor. The acyltransferase reaction progresses through formation of a binary complex between acyl-ACP and HlyC to a reactive acyl-HlyC intermediate [Trent, M. S., Worsham, L. M., and Ernst-Fonberg, M. L. (1998) Biochemistry 37, 4644-4655]. The homologous acyltransferases of the family have a number of conserved amino acid residues that may be catalytically important. Experiments to illuminate the reaction mechanism were done. The formation of an acyl-enzyme intermediate suggested that the reaction likely proceeded through two partial reactions. The reversibility of the first partial reaction was shown by using separately subcloned, purified, and expressed substrates and enzyme. The effects of single site-directed mutations of conserved residues of HlyC on different portions of reaction progress (binary complex formation, acyl-enzyme formation, and enzyme activity, including kinetic parameters) were determined. Mutations of His23, the only residue essential for activity, formed normal binary complexes but were unable to form acyl-HlyC. The same was seen with S20A, a mutant with greatly impaired activity. Mutation of two conserved tyrosines separately to glycines results in greatly impaired binary complex and acyl-HlyC formation, but mutation of those residues to phenylalanines restored behavior to wild-type.

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Insights into the Catalytic Mechanism of HlyC, the Internal Protein Acyltransferase That Activates Escherichia coli Hemolysin Toxin

et al. 2001

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Hemolysin, a toxic protein secreted by pathogenic Escherichia coli, is converted from nontoxic prohemolysin, proHlyA, to toxic hemolysin, HlyA, by an internal protein acyltransferase, HlyC. Acyl-acyl carrier protein (ACP) is the essential acyl donor. The acyltransferase reaction proceeds through two partial reactions and entails formation of a reactive acyl-HlyC intermediate [Trent, M. S., Worsham, L. M., and Ernst-Fonberg, M. L. (1999) Biochemistry 38, 9541-9548]. The ping pong kinetic mechanism implied by these findings was validated using two different acyl-ACP substrates, thus verifying the independence of the previously demonstrated two partial reactions. Assessments of the stability of the acyl-HlyC intermediate revealed an increased stability at pH 8.6 compared to more acidic pHs. Mutations of a single conserved histidine residue essential for catalysis gave minimal activity when substituted with a tyrosine residue and no activity with a lysine residue. Unlike numerous other His23 mutants, however, the H23K enzyme showed significant acyl-HlyC formation although it was unable to transfer the acyl group from the proposed amide bond intermediate to proHlyA. These findings are compatible with transient formation of acyl-His23 during the course of HlyC catalysis. The effects of several other single site-directed mutations of conserved residues of HlyC on different portions of the reaction progress were examined using a 39 500 kDa fragment of proHlyA which was a more effective substrate than intact proHlyA.

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Lesa M.S. Worsham

The Biochemistry of Hemolysin Toxin Activation: Characterization of HlyC, an Internal Protein Acyltransferase

HlyC, the Internal Protein Acyltransferase That Activates Hemolysin Toxin: Role of Conserved Histidine, Serine, and Cysteine Residues in Enzymatic Activity As Probed by Chemical Modification and Site-Directed Mutagenesis

Amino Acid Residues of Escherichia coli Acyl Carrier Protein Involved in Heterologous Protein Interactions

HlyC, the Internal Protein Acyltransferase That Activates Hemolysin Toxin: Roles of Various Conserved Residues in Enzymatic Activity As Probed by Site-Directed Mutagenesis

Insights into the Catalytic Mechanism of HlyC, the Internal Protein Acyltransferase That Activates Escherichia coli Hemolysin Toxin

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