An ordered reaction mechanism for bacterial toxin acylation by the specialized acyltransferase HlyC: formation of a ternary complex with acylACP and protoxin substrates

The 110 kDa haemolysin protoxin (proHlyA) is activated in the Escherichia coli cytosol by acyl carrier protein-dependent fatty acylation of two internal lysine residues, directed by the co-synthesized protein HlyC. Using an in vitro maturation reaction containing purified protoxin peptides and acylACP, we show unambiguously that HlyC possesses an apparently unique acyltransferase activity fully described by Michaelis-Menten analysis. The Vmax of HlyC at saturating levels of both substrates was approximately 115 nmol acyl group min-1 mg-1 with KMacylACP of 260 nM and KMproHlyA of 27 nM, kinetic parameters sufficient to explain why in vivo HlyC is required at a concentration equimolar to proHlyA. HlyC bound the fatty acyl group from acylACP to generate an acylated HlyC intermediate that was depleted in the presence of proHlyA, but enriched in the presence of proHlyA derivatives lacking acylation target sites. HlyC was also able to bind in vivo 4'-phosphopantetheine. Substitution of conserved amino acids that could act as putative covalent attachment sites did not prevent binding of the fatty acyl or 4'-phosphopantetheine groups. These data and substrate variation analyses suggest that the unique acylation reaction does not involve covalent attachment of fatty acid to the acyltransferase, but rather that it proceeds via a sequential ordered Bi-Bi reaction mechanism, requiring the formation of a non-covalent ternary acylACP-HlyC-proHlyA complex.     

E. coli hemolysin interactions with prokaryotic and eukaryotic cell membranes.

The hemolysin toxin (HlyA) is secreted across both the cytoplasmic and outer membranes of pathogenic Escherichia coli and forms membrane pores in cells of the host immune system, causing cell dysfunction and death. The processes underlying the interaction of HlyA with the bacterial and mammalian cell membranes are remarkable. Secretion of HlyA occurs without a periplasmic intermediate and is directed by an uncleaved C-terminal targetting signal and the HlyB and HlyD translocator proteins, the former being a member of a transporter superfamily central to import and export of a wide range of substrates by prokaryotic and eukaryotic cells. The separate process by which HlyA is targetted to mammalian cell membranes is dependent upon fatty acylation of a non-toxic precursor, proHlyA. This is achieved by a novel mechanism directed by the activator protein HlyC, which binds to an internal proHlyA recognition sequence and provides specificity for the transfer of fatty acid from cellular acyl carrier protein.     

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.     

Thermodynamics of a protein acylation: activation of Escherichia coli hemolysin toxin

HlyC, hemolysin-activating lysine-acyltransferase, catalyses the acylation (from acyl-acyl carrier protein [ACP]) of Escherichia coli prohemolysin (proHlyA) on the epsilon-amino groups of specific lysine residues, 564 and 690 of the 1024 amino acid primary structure, to form hemolysin (HlyA). Isothermal titration calorimetry was used to measure the thermodynamic properties of the protein acylation of proHlyA-derived structures, altered by substantial deletions and separation of the acylation sites into two different peptides and site directed mutation analyses of acylation sites. Acylation of proHlyA-derived proteins catalyzed by HlyC was overall an exothermic reaction driven by a negative enthalpy. The reaction, whose kinetics are compatible to a ping-pong mechanism, is composed of two partial reactions. The first, the formation of an acyl-HlyC intermediate, was entropically driven, most likely by noncovalent complex formation between acyl-ACP and HlyC; enthalpy-driven acyl transfer followed, resulting in acyl-HlyC and ACPSH product formation. The second partial reaction was an energetically unfavorable acyl transfer from acyl-enzyme intermediate to the final acyl acceptor, a proHlyA derivative. Overall the acylation of proHlyA-derived proteins catalyzed by HlyC was driven by the energetics of the acyl enzyme intermediate reaction. Of the two acylation sites, intactness of the site equivalent to proHlyA K564 was more important for acylation reaction thermodynamic stability.     

Activation of hemolysin toxin: relationship between two internal protein sites of acylation

HlyC, hemolysin-activating lysine acyltransferase, catalyzes the acylation (from acyl-ACP) of Escherichia coli prohemolysin (proHlyA) on the epsilon-amino groups of specific lysine residues, Lys564 and Lys690 of the 1024-amino acid primary structure, to form hemolysin (HlyA). The amino acid sequences flanking the two acylation sites are not homologous except that each has a glycine residue immediately preceding the lysine which is acylated; there are, however, numerous GK sequences throughout proHlyA that are not acylation sites. The substrate specificity of acylation was examined. ProHlyA-derived structures, altered by substantial deletions and separation of the acylation sites into two different peptides and site-directed mutation analyses of acylation sites, often served as internal protein acylation substrates, and the kinetics of the acylations were measured. The two sites of acylation of proHlyA functioned independently of one another with HlyC; there did not appear to be a common HlyC binding site or processivity of the enzyme between the sites. Acyl-HlyC was likely the enzyme form that interacted with the final acylation substrate. In a variety of constructs, the two acylation sites had similar K(m) values, but their V(max) values and catalytic efficiencies as substrates differed. Internal protein acylation was inhibited by specific small peptides mimicking the primary structure of each acylation site except that the crucial lysines were replaced with arginines; similar small peptides containing the crucial lysine, however, were not acylated.     

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 endocytic protein intersectin is a major binding partner for the Ras exchange factor mSos1 in rat brain

We recently identified intersectin, a protein containing two EH and five SH3 domains, as a component of the endocytic machinery. The N-terminal SH3 domain (SH3A), unlike other SH3 domains from intersectin or various endocytic proteins, specifically inhibits intermediate events leading to the formation of clathrin-coated pits. We have now identified a brain-enriched, 170 kDa protein (p170) that interacts specifically with SH3A. Screening of combinatorial peptides reveals the optimal ligand for SH3A as Pp(V/I)PPR, and the 170 kDa mammalian son-of-sevenless (mSos1) protein, a guanine-nucleotide exchange factor for Ras, con- tains two copies of the matching sequence, PPVPPR. Immunodepletion studies confirm that p170 is mSos1. Intersectin and mSos1 are co-enriched in nerve terminals and are co-immunoprecipitated from brain extracts. SH3A competes with the SH3 domains of Grb2 in binding to mSos1, and the intersectin-mSos1 complex can be separated from Grb2 by sucrose gradient centrifugation. Overexpression of the SH3 domains of intersectin blocks epidermal growth factor-mediated Ras activation. These results suggest that intersectin functions in cell signaling in addition to its role in endocytosis and may link these cellular processes.     

A protease-like permeability factor in the guinea pig skin. 2. In vitro activation of the latent form permeability factor by weakly acidic phosphate buffer.

Conditions for the in vitro activation of the latent form of a protease-like permeability factor in the pseudoglobulin fraction from guinea pig skin were examined. (1) The factor was activated by dialysis against 67 mM phosphate buffer at pH 5.8--6.4, not at pH 7.0--8.0. (2) High salt concentration (200 mM or greater phosphate buffer or 67 mM phosphate buffer containing 200 mM or greater KCl or NaCl) prevented the activation at pH 6.2. (3) High osmotic pressure (sucrose at 1 M) did not affect activation at pH 6.2. (4) Reconversion of the activated permeability factor into an inactive form was not observed under high salt conditions, under which the latent permeability factor was stable in its own form. (5) The molecular size of the latent permeability factor was estimated as approx. 80 000 by Sephadex G-100 gel filtration at high salt concentration.     

Signaling pathways of transforming growth factor beta family members

Transforming growth factor beta (TGF-beta) signaling controls varies of cellular processes, including cell proliferation, differentiation, fibrosis, apoptosis and specification of developmental fate during embryogenesis as well as in mature tissues. The members of TGF-betas family are secreted as inactive (latent) precursors, what prevents uncontrolled activation of the cognate receptors. After activation TGF-beta ligand initiates signaling by binding to and bringing together type I and type II receptor serine/threronine kinases on the cell surface. Recent cellular, biochemical and structural studies have revealed significant insight into the mechanisms of the activation of TGF-beta receptors through ligand binding, the activation of Smad proteins through phosphorylation as well as Smad independent pathways.     

An alteration in molecular form associated with activation of human heat shock factor

In higher eucaryotes, heat shock factor (HSF) exists in a cryptic form in unstressed cells. We investigated molecular forms of human HSF before and after activation by sucrose density gradient centrifugation and by gel mobility shift assay using a 32P-labeled heat shock element (HSE). We found that the in vivo or in vitro activated HSF, which is capable of binding to HSE, and its inactive form present in unstressed cells have different sedimentation coefficient; the former is 8 S whereas the latter is 4-5 S. Both the 8 S and 4-5 S forms contain the HSF polypeptide which has the ability to bind to HSE upon activation. The inactive 4-5 S form acquires HSE-binding ability when activated by heat shock or other stimuli. This HSF activity was greatly reduced, however, during recentrifugation in sucrose density gradient and, in addition, the residual activity was not recovered in 8 S fractions. Transformation of the inactive 4-5 S form of HSF to the stable, active 8 S form was achieved when the inactive form was activated and mixed with cytosols of unstressed cells.     

Reconstitution of lipid vesicles associated with HVJ (Sendai virus) sikes. Purification and some properties of vesicles containing nontoxic fragment A of diphtheria toxin

A mixture of HVJ (Sendai virus) spike proteins, the nontoxic fragment A of diphtheria toxin, lecithin, and cholesterol was solubilized in sucrose solution containing a nonionic neutral detergent. The liposomal vesicles which formed on removal of the detergent by dialysis were purified by gel filtration and centrifugation on a sucrose gradient. The resulting purified vesicles had hemagglutinating activity, hemolytic activity and, after solubilization, the enzymic activity of fragment A. The vesicles had no cell fusion activity. Electron microscopy showed that both the outside and inside of membranes of the vesicles were associated with the spikes. When the vesicles were freeze-fractured, no large aggregates of particles were seen on either face. Such fragment A-containing lipid vesicles (liposomes) with HVJ spikes bound to mamalian cell membrane and released their fragment A into the cytoplasm causing cell death. Neither fragment A-containing liposomes without spikes nor empty liposomes with spikes were toxic.     

Characterization and reassembly of a regular array in the cell wall of Clostridium difficile GAI 4131

The cell wall of Clostridium difficile GAI 4131 was revealed by electron microscopy to have an outer layer composed of a nearly square array and contained the two major proteins with molecular weights of 38 kDa and 42 kDa. The properties and reassembly of the two major proteins into the regular array were investigated. When the isolated cell walls were treated with hydrophobic bond-disrupting agents or a chelating agent specific for Ca2+, the two major proteins were effectively removed and the regularly arranged outer layer disappeared. The amino acid composition of the two major proteins differed from each other. The two major proteins also gave different peptide maps from each other upon proteolysis with Staphylococcus aureus V8 protease. The major proteins solubilized from the isolated cell walls with 8 M urea or 4 M guanidine hydrochloride could be reassembled into open-ended cylinders possessing the native regular pattern by dialysis against neutral buffer containing 5 mM CaCl2. The reassembled cylinders purified by centrifugation on a Percoll density gradient were composed of almost equal amounts of the 38 kDa and 42 kDa proteins and freed from the other proteins. These results suggest that the regular array in the outer cell wall layer is constructed from the two major cell wall proteins and requires Ca2+ for its assembly.     

Salmonella typhimurium secreted invasion determinants are homologous to Shigella lpa proteins

Salmonella typhimurium secreted proteins (Ssp) were previously implicated in epithelial cell invasion. Here we describe four genes ( sspB , sspC , sspD , and sspA ), located between spaT and prgH , which encode proteins of 63, 42, 36, and 87 kDa, respectively. These Ssp are homologous to Shigella flexneri secreted proteins lpaB, lpaC, lpaD and lpaA. A non-invasive mutant with a transposon insertion in sspC lacks Ssp of 87,42 and 36 kDa. Complementation analyses show that sspC and sspD encode the 42 and the 36 kDa Ssp, while the 87 kDa Ssp is encoded by sspA . sspC and sspD , but not sspA are required for invasion. Amino-terminal sequencing shows that SspC and SspA are secreted without amino-terminal processing. We further demonstrate that Ssp secretion requires proteins encoded by prgHIJK , homologous to the Shigella lpa secretion system, since SspA is abundantly secreted by wild-type bacteria but is completely retained within the cellular fraction of a prgHIJK mutant. A precipitate containing abundant SspC and three other major Ssp of 63,59 and 22 kDa was isolated from culture supernatants of wild-type bacteria. These data indicate that major secreted invasion determinants of S. typhimurium are structurally and functionally homolgous to S. flexneri lpa proteins.     

Fertilization triggers unmasking of maternal mRNAs in sea urchin eggs.

Fertilization of sea urchin eggs results in a large increase in the rate of protein synthesis which is mediated by the translation of stored maternal mRNA. The masked message hypothesis suggests that messenger ribonucleoprotein particles (mRNPs) from unfertilized eggs are translationally inactive and that fertilization results in alterations of the mRNPs such that they become translationally active. Previous workers have isolated egg mRNPs by sucrose gradient centrifugation and have assayed their translational activity in heterologous cell-free systems. The conflicting results they obtained are probably due to the sensitivity of mRNPs to artifactual activation and inactivation. Previously, we demonstrated that unfractionated mRNPs in a sea urchin cell-free translation system were translationally inactive. Now, using large-pore gel filtration chromatography, we partially purified egg mRNPs while retaining their translationally repressed state. Polysomal mRNPs from fertilized eggs isolated under the same conditions were translationally active. The changes in the pattern of proteins synthesized by fractionated unfertilized and fertilized mRNPs in vitro were similar to those changes observed in vivo. Treatment of egg mRNPs with buffers containing high salt and EDTA, followed by rechromatography, resulted in the activation of the mRNPs and the release of an inhibitor of translation from the mRNPs. Analysis of the inhibitory fraction on one-dimensional sodium dodecyl sulfate gels indicated that this fraction contains a complex set of proteins, several of which were released from high-salt-EDTA-activated mRNPs and not from inactive low-salt control mRNPs. One of the released proteins may be responsible for the repression of egg mRNPs in vitro and be involved in the unmasking of mRNPs at fertilization.     

Pro-apoptotic proteins released from the mitochondria regulate the protein composition and caspase-processing activity of the native Apaf-1/caspase-9 apoptosome complex

The apoptosome is a large caspase-activating ( approximately 700-1400 kDa) complex, which is assembled from Apaf-1 and caspase-9 when cytochrome c is released during mitochondrial-dependent apoptotic cell death. Apaf-1 the core scaffold protein is approximately 135 kDa and contains CARD (caspase recruitment domain), CED-4, and multiple (13) WD40 repeat domains, which can potentially interact with a variety of unknown regulatory proteins. To identify such proteins we activated THP.1 lysates with dATP/cytochrome c and used sucrose density centrifugation and affinity-based methods to purify the apoptosome for analysis by MALDI-TOF mass spectrometry. First, we used a glutathione S-transferase (GST) fusion protein (GST-casp9(1-130)) containing the CARD domain of caspase-9-(1-130), which binds to the CARD domain of Apaf-1 when it is in the apoptosome and blocks recruitment/activation of caspase-9. This affinity-purified apoptosome complex contained only Apaf-1XL and GST-casp9(1-130), demonstrating that the WD40 and CED-4 domains of Apaf-1 do not stably bind other cytosolic proteins. Next we used a monoclonal antibody to caspase-9 to immunopurify the native active apoptosome complex from cell lysates, containing negligible levels of cytochrome c, second mitochondria-derived activator of caspase (Smac), or Omi/HtrA2. This apoptosome complex exhibited low caspase-processing activity and contained four stably associated proteins, namely Apaf-1, pro-p35/34 forms of caspase-9, pro-p20 forms of caspase-3, X-linked inhibitor of apoptosis (XIAP), and cytochrome c, which was only bound transiently to the complex. However, in lysates containing Smac and Omi/HtrA2, the caspase-processing activity of the purified apoptosome complex increased 6-8-fold and contained only Apaf-1 and the p35/p34-processed subunits of caspase-9. During apoptosis, Smac, Omi/HtrA2, and cytochrome c are released simultaneously from mitochondria, and thus it is likely that the functional apoptosome complex in apoptotic cells consists primarily of Apaf-1 and processed caspase-9.     

A comparative study of the extracellular glucosyl- and fructosyltransferases from cariogenic and non-cariogenic Streptococcus mutans strains of two different serotypes

Extracellular proteins from continuous cultures of serotype c and g Streptococcus mutans strains were separated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. Gels stained with raffinose after electrophoresis revealed that although serotype c strains secrete two fructosyltransferases of molecular mass 68 kDa and 79 kDa, no fructosyltransferase was secreted by the serotype g strain K1. A sucrose activity stain was used to detect two glucosyltransferases (GTF) of molecular mass 162 kDa (bifunctional 1,6-alpha-D-glucan 3-alpha- and 6-alpha GTF or 'dextransucrase') and 153 kDa (a 1,3-alpha-D-glucan 3-alpha-GTF) in samples from cariogenic serotype c strains. Neither the 153 kDa protein nor the corresponding GTF activity was secreted by the non-cariogenic mutant C 67-25. The molecular masses of the corresponding 1,3-alpha and 1,6-alpha-GTF proteins from the serotype g strain K1 were 164 kDa and 158 kDa, respectively. All of the GTF proteins were degraded to discrete bands of lower molecular mass on storage at 4 degrees C even after extensive purification. The results provide an explanation for several outstanding controversies in the GTF literature.     

Characterization of sucrose-hydrolyzing enzymes of Zymomonas mobilis

Extracellular proteins of Zymomonas mobilis were analyzed by two-dimensional gel electrophoresis and protein maps drawn up. One of these proteins showed sucrose-hydrolyzing activity, as indicated by activity staining after polyacrylamide gel electrophoresis. It was purified from the extracellular extract of a glucose fermentation by polyacrylamide gel electrophoresis, using a two-step procedure. The molecular mass of the protein was 46 kDa and its isoelectric point 5.0. A rabbit antiserum was raised against this protein. As shown by immunoblotting, the same protein was present in extracellular extracts obtained from glucose, fructose and sucrose fermentations. A cross-reaction was also detected by immunoblotting, with a cellular protein of molecular mass 46 kDa present on the three carbon sources studied. However, activity staining was unsuccessful on gels after electrophoresis of these cellular extracts. The extracellular protein extract obtained from a fermentation run on glucose contained another sucrose-hydrolyzing protein of molecular mass 51 kDa and with an isoelectric point of 4.8. This protein was absent in fructose and sucrose fermentations but showed a positive reaction with the antiserum raised against the 46 kDa extracellular protein. Partially purified sucrose-hydrolyzing proteins also catalyzed transfructosylation reactions, suggesting that they could be of the levansucrase type.     

Rainbow trout (Oncorhynchus mykiss) sIgM- leucocytes secrete an interleukin-2 like growth factor after mitogenic stimulation in vitro

Two secreted proteins were detected in culture supernatants of PHA or PMA stimulated, immunomagnetically separated, sIgM(-) leucocytes of rainbow trout (Oncorhynchus mykiss) with 60kDa and with 12-15kDa (multiple bands). So called conditioned media (CM), containing these proteins, induced significant activation of blood and head kidney leucocytes. Immunomagnetically separated, naive as well as PHA activated sIgM(-) T lymphocytes and LPS prestimulated sIgM(+) B lymphocytes could be identified to be responding to these secreted proteins. Using a monoclonal antibody specific for mouse IL-2 (clone JES6-1A12), one of the multiple 12-15kDa proteins could be stained in Western blots. It was also shown that the induced proliferation was due to this protein in the CM, as the same anti-IL-2 mab was able to block the CM induced proliferation. Furthermore, survival of the IL-2 dependent mouse cell line HT-2 was enhanced after addition of various concentrations of CM. The data presented show, for the first time, that mitogen stimulated trout sIgM(-) leucocytes secrete a cytokine like growth factor sharing functional and structural similarities with mammalian IL-2.     

Identification and partial purification of a chromatin bound calmodulin activated histone 3 kinase from calf thymus

A calcium-calmodulin (Ca2(+)-CaM) stimulated histone H3 phosphorylating activity was identified as a component of a nuclear protein complex purified from a 150 mM NaCl extract of calf thymus chromatin. This activity bound to a CaM-Sepharose affinity column in a Ca2+ dependent manner and was eluted off the column in the presence of EGTA. Equilibrium centrifugation of the EGTA eluate on a sucrose density gradient revealed that the activity is a component of a larger complex identified at 25% sucrose. This complex consisted of two major proteins, having Mr of 65 and 75 kDa. Using [125I] CaM and the gel overlay technique it was shown that the 75 kDa protein is the major CaM binding protein in the complex.     

In vitro activation of [FeFe] hydrogenase: new insights into hydrogenase maturation

The in vitro activation of the [FeFe] hydrogenase is accomplished by combining Escherichia coli cell extracts containing the heterologously expressed inactive HydA with extracts in which hydrogenase-specific maturation proteins HydE, HydF, and HydG are expressed in concert. Interestingly, the process of HydA activation occurs rapidly and in the absence of potential substrates, which suggests that the hydrogenase accessory proteins synthesize an H-cluster precursor that can be quickly transferred to the hydrogenase enzyme to affect activation. HydA activity is observed to be dependent on the protein fraction containing all three accessory proteins expressed in concert and cannot be accomplished with addition of heat-treated extract or extract filtrate, suggesting that the activation of the hydrogenase structural protein is mediated by interaction with the accessory assembly protein(s). These results represent the first important step in understanding the process of H-cluster assembly and provide significant insights into hydrogenase maturation. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.