Insights into the catalytic mechanism of HlyC, the internal protein acyltransferase that activates Escherichia coli hemolysin toxin.

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.

HlyC, the internal protein acyltransferase that activates hemolysin toxin: roles of various conserved residues in enzymatic activity as probed by site-directed mutagenesis.

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.

HlyC, the internal protein acyltransferase that activates hemolysin toxin: the role of conserved tyrosine and arginine residues in enzymatic activity as probed by chemical modification and site-directed mutagenesis.

Internal fatty acylation of proteins is a recognized means of modifying biological behavior. Escherichia coli hemolysin A (HlyA), a toxic protein, is transcribed as a nontoxic protein and made toxic by internal acylation of two lysine residue epsilon-amino groups; HlyC catalyzes the acyl transfer from acyl-acyl carrier protein (ACP), the obligate acyl donor. Conserved residues among the respective homologous C proteins that activate 13 different RTX (repeats in toxin) toxins of which HlyA is the prototype likely include some residues that are important in catalysis. Possible roles of two conserved tyrosines and two conserved arginines were investigated by noting the effects of chemical modifiers and site-directed mutagenesis. TNM modification of HlyC at pH 8.0 led to extensive inhibition that was prevented by the presence of the substrate myristoyl-ACP but not by the product, ACPSH. NAI had no effect. Y70G and Y150G greatly diminished enzyme activity, whereas mutations Y70F and Y150F exhibited wild-type activity. Modification of arginine residues with PG markedly lowered acyltransferase activity with moderate protection by both myristoyl-ACP and ACPSH. Under optimum conditions, four separate mutations of the two conserved arginine residues (R24A, R24K, R87A, and R87K) had little effect on acyltransferase activity.

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.

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.

The biochemistry of hemolysin toxin activation: characterization of HlyC, an internal protein acyltransferase.

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.

Early catalytic steps of Euglena gracilis chloroplast type II fatty acid synthase.

Euglena gracilis is a very ancient eukaryote whose chloroplast acquisition and evolution has been independent of higher plants. The organism in unique in possessing two de novo fatty acid synthases, a true multienzyme complex of great size in the cytosol and a plastid-localized type II fatty acid synthase composed of discrete enzymes and acyl carrier protein (ACP). The enzymology of the early steps of fatty acid biosynthesis differed in the Euglena type II fatty acid synthase compared to those of Escherichia coli and plants. The enzymes of Euglena participating in both priming and elongation reactions to form a new carbon-carbon bond were acetyl-CoA-ACP transacylase, malonyl-CoA-ACP transacylase, and beta-ketoacyl-ACP synthase I. The effects of inhibitors on the three different enzymes were noted. All carbon-carbon bond formation was inhibited by cerulenin. Although neither fatty acid biosynthesis nor any of the isolated enzymes were sensitive to diisopropylphosphofluoridate, the three Euglena enzymes studied were sensitive to different sulfhydryl-alkylating agents. Acetyl-ACP supported fatty acid biosynthesis as effectively as did comparable amounts of ACPSH and acetyl-CoA. There was no evidence for a beta-ketoacyl-ACP synthase III for priming such as has been reported in type II fatty acid synthase of higher plants and bacteria. The roles of the acetyl-CoA-ACP transacylase and beta-ketoacyl-ACP synthase I appear to be unique in the type II fatty acid synthase of Euglena. Acetyl-CoA-ACP transacylase, malonyl-CoA-ACP transacylase, and beta-ketoacyl-ACP synthase I were separated from one another and shown to have different molecular weights.

Comparison of acyl-carrier protein and other protein structures in aqueous solutions by Fourier-transform infrared spectroscopy.

Protein solution structures were analyzed by horizontal attenuated total reflectance (ATR) FTIR spectroscopy. Secondary structure compositions determined from analyses of amide-I and II region and amide-III region difference spectra were compared. Data for proteins of known solution structure, cytochrome c, concanavalin A and lysozyme, were compared with those reported in the literature. Melittin, a peptide from bee venom whose secondary structural configuration varies depending upon solution conditions was also examined. Acyl-carrier protein (ACP) is a small protein of recognized dynamic structure that in its diverse physiologic roles interacts specifically with numerous different proteins. Horizontal ATR FTIR analysis of ACP's secondary structure indicated a predominantly helical structure best defined as a combination of ordered and disordered helices. The FTIR-derived structural composition agreed with those determined for ACP by other techniques. Comparison of independent analyses of the amide-I and III regions to determine protein configuration compositions was a useful method of verifying the internal consistency of the calculated structural compositions of dynamically-structured proteins.

Nucleotide cofactor-binding-domain-specific antibodies show immunologic relatedness among unrelated proteins that bind phosphoryl compounds.

The immunologic relatedness of various cofactor-binding sites of enzymes requiring different nucleotide cofactors was examined. Chicken antibodies specific for NADPH- or CoA-binding domains were raised using an NADPH- or CoA-requiring enzyme as an immunogen. Antibodies specific for either NADPH- or CoA-binding domains were isolated by immunoaffinity chromatography of the respective antisera using unrelated NADPH- or CoA-requiring enzymes as affinity ligands. The reactivities of the NADPH- and CoA-binding-site-specific antibodies with a variety of enzymes that required different cofactors was shown on Western blots of SDS-PAGE of the enzymes. Variable cross-reactivities were observed among all nucleotide-cofactor requiring enzymes with each specific cofactor-domain-antibody population. Numerous proteins not physiologically associated with nucleotide cofactors, including acyl carrier protein, were completely unreactive. Proteins that bound phosphoryl compounds either as substrates or cofactors showed varying degrees of reactivity with each population of specific antibodies. These included aldolase, ribulose-1,5-bisphosphate carboxylase/oxygenase, ribonuclease A, carbonic anhydrase and triosephosphate isomerase. The immunologic cross-reactivity suggested that these proteins share a common structural feature, probably a primary structure epitope, since the proteins had been subjected to denaturing polyacrylamide gel electrophoresis. A candidate for this common structural feature is a glycine-rich sequence comprising a phosphate binding loop.

Purification and partial characterization of acyl carrier protein from Euglena gracilis variety bacillaris.

Acyl carrier protein (ACP) was purified from Euglena gracilis variety bacillaris in yields of about 1 mg/100 g (wet wt) of cells. Antibodies against the purified protein were raised in hens and isolated from eggs. Antibodies raised against Euglena ACP inhibited the Euglena chloroplast nonaggregated fatty acid synthetase using either Euglena or Escherichia coli ACP as a substrate. Comparisons with other ACPs included the following items: biologic activity, acidic pI, size, behavior in size exclusion media, and amino acid sequence of the N-terminal portion of the molecule.

Acyl carrier protein interacts with melittin.

Acyl carrier protein (ACP) from Escherichia coli has been shown to form complexes with melittin, a cationic peptide from bee venom. ACP is a small (Mr 8847), acidic, Ca2(+)-binding protein, which possesses some characteristics resembling those of regulatory Ca2(+)-binding proteins including interaction with melittin. Complexing between melittin and ACP which occurred both in the presence and absence of Ca2+ was evident by chemical cross-linking the two peptides, fluorescence changes (including anisotropy measurements), and inhibition by melittin of the activity of a nonaggregated fatty acid synthetase from Euglena. Also, anti-Apis mellifera antibodies which contained antibodies against melittin specifically inhibited the same enzyme system activity relative to non-immune IgG.

Behavior of acyl carrier proteins on western blots.

Acyl carrier proteins (ACPs) from Escherichia coli and Euglena were analyzed on Western blots using rabbit antibodies raised against E. coli ACP. Euglena ACP, unlike that from E. coli, behaves upon electrophoresis under denaturing conditions as its size would predict. Oligomeric forms of both ACPs were evident on Western blots, but the bacterial ACP had more tendency to aggregate. That the oligomeric forms were not due to impurities was shown by their regeneration from low-Mr protein, reaction with antibodies isolated from low-Mr protein, and by molecular weight determination of the ACP by low-angle laser light scattering.

Chemical cross-linking and its effect on fatty acid synthetase activity in intact chloroplasts from Euglena gracilis.

Intact chloroplasts were isolated from Euglena gracilis variety bacillaris, aliquots were exposed to several different chemical cross-linking reagents. The reagents penetrated the triple membrane of Euglena chloroplasts. This was shown by gradient acrylamide gel electrophoresis under denaturing conditions. The activity of the nonaggregated fatty acid synthetase of Euglena was located within the chloroplast stroma, and the effects of dimethylsuberimidate cross-linking on the activity of the enzyme system were examined. The acyl-carrier protein concentration in the chloroplast was measured at about 0.24 mM.

Kinetic studies of the fatty acid synthetase multienzyme complex from Euglena gracilis variety bacillaris.

A fatty acid synthetase multienzyme complex was purified from Euglena gracilis variety bacillaris. The fatty acid synthetase activity is specifically inhibited by antibodies against Escherichia coli acyl-carrier protein. The Euglena enzyme system requires both NADPH and NADH for maximal activity. An analysis was done of the steady-state kinetics of the reaction catalysed by the fatty acid synthetase multienzyme complex. Initial-velocity studies were done in which the concentrations of the following pairs of substrates were varied: malonyl-CoA and acetyl-CoA, NADPH and acetyl-CoA, malonyl-CoA and NADPH. In all three cases patterns of the Ping Pong type were obtained. Product-inhibition studies were done with NADP+ and CoA. NADP+ is a competitive inhibitor with respect to NADPH, and uncompetitive with respect to malonyl-CoA and acetyl-CoA. CoA is uncompetitive with respect to NADPH and competitive with respect to malonyl-CoA and acetyl-CoA. When the concentrations of acetyl-CoA and malonyl-CoA were varied over a wide range, mutual competitive substrate inhibition was observed. When the fatty acid synthetase was incubated with radiolabelled acetyl-CoA or malonyl-CoA, labelled acyl-enzyme was isolated. The results are consistent with the idea that fatty acid synthesis proceeds by a multisite substituted-enzyme mechanism involving Ping Pong reactions at the following enzyme sites: acetyl transacylase, malonyl transacylase, beta-oxo acyl-enzyme synthetase and fatty acyl transacylase.