Structure of aspartate ß-semialdehyde dehydrogenase from Francisella tularensis.

Aspartate ß-semialdehyde dehydrogenase (ASADH) is an enzyme involved in the diaminopimelate pathway of lysine biosynthesis. It is essential for the viability of many pathogenic bacteria and therefore has been the subject of considerable research for the generation of novel antibiotic compounds. This manuscript describes the first structure of ASADH from Francisella tularensis, the causative agent of tularemia and a potential bioterrorism agent. The structure was determined at 2.45 Šresolution and has a similar biological assembly to other bacterial homologs. ASADH is known to be dimeric in bacteria and have extensive interchain contacts, which are thought to create a half-sites reactivity enzyme. ASADH from higher organisms shows a tetrameric oligomerization, which also has implications for both reactivity and regulation. This work analyzes the apo form of F. tularensis ASADH, as well as the binding of the enzyme to its cofactor NADP+.

Identification of Maillard reaction products on peanut allergens that influence binding to the receptor for advanced glycation end products.

BACKGROUND: Recent immunological data demonstrated that dendritic cells preferentially recognize advanced glycation end product (AGE)-modified proteins, upregulate expression of the receptor for AGE (RAGE), and consequently bias the immune response toward allergy. METHODS: Peanut extract was characterized by mass spectrometry (MS) to elucidate the specific residues and specific AGE modifications found in raw and roasted peanuts and on rAra h 1 that was artificially glycated by incubation with glucose or xylose. The binding of the RAGE-V1C1 domain to peanut allergens was assessed by PAGE and Western analysis with anti-Ara h 1, 2, and 3 antibodies. IgE binding to rAra h 1 was also assessed using the same methods. RESULTS: AGE modifications were found on Ara h 1 and Ara h 3 in both raw and roasted peanut extract. No AGE modifications were found on Ara h 2. Mass spectrometry and Western blot analysis demonstrated that RAGE binds selectively to Ara h 1 and Ara h 3 derived from peanut extract, whereas the analysis failed to demonstrate Ara h 2 binding to RAGE. rAra h 1 with no AGE modifications did not bind RAGE; however, after AGE modification with xylose, rAra h 1 bound to RAGE. CONCLUSIONS: AGE modifications to Ara h 1 and Ara h 3 can be found in both raw and roasted peanuts. Receptor for AGE was demonstrated to selectively interact with AGE-modified rAra h 1. If sensitization to peanut allergens occurs in dendritic cells via RAGE interactions, these cells are likely interacting with modified Ara h 1 and Ara h 3, but not Ara h 2.

Crystal structures of SarA, a pleiotropic regulator of virulence genes in S. aureus.

Staphylococcus aureus is a major human pathogen, the potency of which can be attributed to the regulated expression of an impressive array of virulence determinants. A key pleiotropic transcriptional regulator of these virulence factors is SarA, which is encoded by the sar (staphylococcal accessory regulator) locus. SarA was characterized initially as an activator of a second virulence regulatory locus, agr, through its interaction with a series of heptad repeats (AGTTAAG) within the agr promoter. Subsequent DNA-binding studies have revealed that SarA binds readily to multiple AT-rich sequences of variable lengths. Here we describe the crystal structure of SarA and a SarA-DNA complex at resolutions of 2.50 A and 2.95 A, respectively. SarA has a fold consisting of a four-helix core region and 'inducible regions' comprising a beta-hairpin and a carboxy-terminal loop. On binding DNA, the inducible regions undergo marked conformational changes, becoming part of extended and distorted alpha-helices, which encase the DNA. SarA recognizes an AT-rich site in which the DNA is highly overwound and adopts a D-DNA-like conformation by indirect readout. These structures thus provide insight into SarA-mediated transcription regulation.

Conservative mutations of glutamine-125 in herpes simplex virus type 1 thymidine kinase result in a ganciclovir kinase with minimal deoxypyrimidine kinase activities.

The herpes simplex virus type 1 thymidine kinase (HSV-1 TK) is the major anti-herpes virus pharmacological target, and it is being utilized in combination with the prodrug ganciclovir as a toxin gene therapeutic for cancer. One active-site amino acid, glutamine-125 (Gln-125), has been shown to form hydrogen bonds with bound thymidine, thymidylate, and ganciclovir in multiple X-ray crystal structures. To examine the role of Gln-125 in HSV-1 TK activity, three site-specific mutations of this residue to an aspartic acid, an asparagine, or a glutamic acid were introduced. These three mutants and wild-type HSV-1 TK were expressed in E. coli and partially purified and their enzymatic properties compared. In comparison to the Gln-125 HSV-1 TK, thymidylate kinase activity of all three mutants was decreased by over 90%. For thymidine kinase activity relative to Gln-125 enzyme, the K(m) of thymidine increased from 0.9 microM for the parent Gln-125 enzyme to 3 microM for the Glu-125 mutant, to 6000 microM for the Asp-125 mutant, and to 20 microM for the Asn-125 mutant. In contrast, the K(m) of ganciclovir decreased from 69 microM for the parent Gln-125 enzyme to 50 microM for the Asn-125 mutant and increased to 473 microM for the Glu-125 mutant. The Asp-125 enzyme was able to poorly phosphorylate ganciclovir, but with nonlinear kinetics. Molecular simulations of the wild-type and mutant HSV-1 TK active sites predict that the observed activities are due to loss of hydrogen bonding between thymidine and the mutant amino acids, while the potential for hydrogen bonding remains intact for ganciclovir binding. When expressed in two mammalian cell lines, the Glu-125 mutant led to GCV-mediated killing of one cell line, while the Asn-125 mutant was equally as effective as wild-type HSV-1 TK in metabolizing GCV and causing cell death in both cell lines.

Characterization of the SarA virulence gene regulator of Staphylococcus aureus.

Staphylococcus aureus is a potent human pathogen that expresses a large number of virulence factors in a temporally regulated fashion. Two pleiotropically acting regulatory loci were identified in previous mutational studies. The agr locus comprises two operons that express a quorum-sensing system from the P2 promoter and a regulatory RNA molecule from the P3 promoter. The sar locus encodes a DNA-binding protein that activates the expression of both agr operons. We have cloned the sarA gene, expressed SarA in Escherichia coli and purified the recombinant protein to apparent homogeneity. The purified protein was found to be dimeric in the presence and absence of DNA and to consist mostly of alpha-helices. DNase I footprinting of SarA on the putative regulatory region cis to the agr promoters revealed three high-affinity binding sites composed of two half-sites each. Quantitative electrophoretic mobility shift assays (EMSAs) were used to derive equilibrium binding constants (KD) for the interaction of SarA with these binding sites. An unusual ladder banding pattern was observed in EMSA with a large DNA fragment including all three binding sites. Our data indicate that SarA regulation of the agr operons involves binding to multiple half-sites and may involve other sites located downstream of the promoters.

The Staphylococcal accessory regulator (sar) represses transcription of the Staphylococcus aureus collagen adhesin gene (cna) in an agr-independent manner.

Comparison of Staphylococcus aureus strains carrying mutations inactivating the staphylococcal accessory regulator (sar ) and/or the accessory gene regulator (agr ) suggests that sar is the primary regulatory element controlling transcription of the collagen adhesin gene (cna ) and that the regulatory effect of sar is independent of the interaction between SarA and agr. To test this hypothesis, we cloned the regions encoding each of the overlapping sar transcripts, all of which include the sarA open reading frame (ORF), and introduced each clone into cna-positive sar and agr mutants. The introduction of each clone restored the expected sar transcripts and the temporal pattern of sar transcription. The introduction of each clone also complemented the defect in cna transcription and restored collagen binding to wild-type levels. This was true even when the clones were introduced into a sar/agr double mutant. These results confirm the hypothesis that the sar-mediated regulation of cna transcription occurs via an agr-independent pathway. Direct evidence supporting this hypothesis comes from electrophoretic mobility shift assays demonstrating that SarA exhibits high-affinity binding to cis elements upstream of the cna structural gene. We also examined the correlation between sar transcription and the production of SarA. Western blot analysis of two wild-type strains indicated that SarA was produced in indistinguishable amounts during both the exponential and the post-exponential growth phases.

Mutational analysis of the NH2-terminal arms of the trp repressor indicates a multifunctional domain.

The NH2-terminal arms of the Escherichia coli trp repressor have been implicated in three functions: formation of repressor-operator complexes via association with non-operator DNA; stabilization of repressor oligomers bound to DNA; and oligomerization of the aporepressor in the absence of DNA. To begin to examine the structural aspects of the arms that are responsible for these varied activities, we generated an extensive set of deletion and substitution mutants and measured the activities of these mutants in vivo using reporter gene fusions. Deletion of any part of the arms resulted in a significant decrease in repressor activity at both the trp and the trpR operons. Positions 4, 5 and 6 were the most sensitive to missense changes. Most substitutions at these positions resulted in repressors with less than 5% of the activity of the wild-type trp repressor. A large percentage of the missense mutants were more active than the wild-type repressor in medium containing tryptophan and less active in medium without tryptophan. This phenotype can be explained in terms of altered oligomerization of both the repressor and the aporepressor. Also, nine super-repressor mutants, resulting from substitutions clustered at both ends of the arms, were found. Our results support the hypothesis that the NH2-terminal arm of the trp repressor is a multifunctional domain and reveal structural components likely to be involved in the various functions.

MyoD-E12 heterodimers and MyoD-MyoD homodimers are equally stable.

Muscle development is controlled by the MyoD family of basic helix-loop-helix (bHLH) DNA-binding proteins. These proteins dimerize with ubiquitous products of the E2A gene (E12 and E47) and bind in a sequence-specific manner to enhancer regions of muscle-specific genes activating their expression. In this study, fluorescence anisotropy has been utilized to characterize the interactions of recombinant MyoD and E12 in solution in the absence of DNA. The Gibb's free energies of dissociation (deltaG) and the equilibrium dissociation constants (K(D)) for the protein-protein interactions are reported. The deltaG for the MyoD homodimers in 100 mM KCl was 8.7 kcal/mol (K(D) = 340 nM), and increasing the salt concentration resulted in destabilization of the dimer. From titrations of MyoD-dansyl with E12 at 100 mM KCl, a free energy of heterodimerization of 8.7 (+0.4/-2.4) kcal/mol was recovered using rigorous confidence limit testing. The titrations of E12-dansyl with MyoD yielded a free energy of 8.3 kcal/mol with tighter confidence limits, +0.5/-0.8 kcal/mol. Thus, in the absence of DNA, both MyoD homodimers and MyoD-E12 heterodimers are relatively weak complexes of approximately the same stability. E12 does not form stable homo-oligomeric complexes; remaining monomeric at concentrations as high as 20 microM. Based on these results and the apparent binding constants reported previously for DNA binding, DNA is likely to facilitate the dimerization of MyoD and E12. Furthermore, higher affinity interactions of MyoD-E12 heterodimers versus MyoD homodimers with DNA binding sites is not due to preferential heterodimerization.

High-level expression and purification of MyoD, myogenin, and E12.

The myogenic regulatory factors (MRFs), MyoD, myogenin, Myf-5, and MRF4, function as transcriptional activators of muscle-specific gene expression by forming heterodimers with the ubiquitously expressed products of the E2A gene, E12 and E47. To enable quantitative biochemical and biophysical analyses of the wild-type proteins, as well as mutants designed to reveal structure-function relationships, we developed protocols for the high-level expression and rapid purification of milligram quantities of MyoD, myogenin, and E12 using conventional biochemical techniques. T7 expression systems were used to direct expression of cDNA encoded proteins in Escherichia coli. Whereas MyoD and E12 were expressed well without alteration, high-level expression of myogenin required changing several rare arginine codons by in vitro mutagenesis to a commonly used E. coli arginine codon. Presumably, inefficient translation of the rare arginine codons inhibited high-level expression of myogenin in the original expression plasmid. Purification protocols are described which involve a simple strategy of cell lysis, ammonium sulfate precipitation, and ion-exchange chromatography. Using this approach, 20 to 50 mg of MyoD, myogenin, or E12 can be purified to 90-95% homogeneity from induced cell pellets in 1 day's time.

Design and optimization of a capillary electrophoretic mobility shift assay involving trp repressor-DNA complexes.

An investigation of DNA-protein interactions by capillary electrophoresis (CE) with laser fluorometric detection is performed that combines the rapid and minimal sample consumption methods of CE with the selective separation influence of mobility shift assays. An inspection of the well characterized interaction between the trp repressor of Escherichia coli and the trp operator (DNA) is the basis of the assay. The use of fluorescently tagged operator not only lends itself to laser-induced fluorescence detection but also precludes the use of radiolabeled detection. It is demonstrated that composition and pH of the running buffer are critical for maximized efficiency and resolution of operator from the repressor-operator complex. Quantitative studies showed reaction of repressor with operator resulted in the diminishing of free operator signal and the simultaneous creation of the repressor-operator peak that is well resolved from the free operator. Also examined was the ability to perform qualitative studies involving non-specific interactions between the operator and a complex protein sample. It is shown that the specificity of operator for repressor can be used to selectively separate the repressor from a complex sample that includes non-specific proteins.

Preferential binding of MyoD-E12 versus myogenin-E12 to the murine sarcoma virus enhancer in vitro.

The MyoD family of transcription factors regulates muscle-specific gene expression in vertebrates. In the adult rat, MyoD mRNA accumulates predominately in fast-twitch muscle, in particular type IIb and/or IIx fibers, whereas Myogenin mRNA is restricted to slow-twitch type I muscle fibers. Transgenic mice expressing the avian v-ski oncogene from the murine sarcoma virus (MSV) promoter-enhancer display preferential hypertrophy of type IIb fast-twitch muscle apparently because of the restricted expression of the transgene. We tested the hypothesis that preferential interactions of MyoD, as a heterodimer with E12, with the MSV enhancer, which has six E-box targets for MyoD family proteins, could contribute to v-ski gene expression in IIb muscle fibers. A series of quantitative binding studies was performed using an electrophoretic mobility shift assay to test MyoD-E12 versus Myogenin-E12 binding to the MSV enhancer. Our results indicate that MyoD-E12 binds the MSV enhancer with higher affinity and higher cooperativity than Myogenin-E12. Interestingly, MyoD-E12 bound all of the individual E-boxes tested with positive cooperativity indicating DNA-mediated dimerization of the protein subunits.

Functional selection and characterization of DNA binding sites for trp repressor of Escherichia coli.

trp repressor of Escherichia coli controls transcription initiation in operons involved in tryptophan biosynthesis by binding to operator sequences within the regulated promoters. Naturally occurring operators are homologous over an 18-base pair region and display dyad symmetry. We have examined the sequence determinants of a repressor binding site using a functional selection/polymerase chain reaction (PCR) amplification strategy. A trp repressor affinity column was generated and used to select binding-competent DNAs from a randomized pool of synthetic double-stranded DNA. DNAs that showed tryptophan-dependent high-affinity binding were eluted by addition of the tryptophan analog beta-indole acrylic acid and amplified by PCR. Following iterative cycles of affinity chromatography and PCR, the selected DNAs were cloned and sequenced. The CTAG tetranucleotide, present in the consensus sequence of all natural operators, was found in all selected DNAs. Mapping experiments utilizing the repressor affinity column showed the CTAG motif to be a critical determinant for repressor binding. Quantitative electrophoretic mobility shift assays with purified trp repressor revealed that although some of the DNAs were bound by one repressor dimer, others were bound by two repressor dimers with cooperativity. Measured binding constants ranged from 0.035 to 0.5 nM for the selected DNAs, compared with 0.1 nM for the trp operator.

Analysis of heterodimer formation by the Escherichia coli trp repressor.

The trp repressor of Escherichia coli is a dimeric DNA-binding protein that regulates transcription of several operons concerned with tryptophan metabolism. Although heterodimer formation between mutant and wild type subunits occurs readily in vivo, comparable heterodimers could be formed in vitro only under extreme conditions. To explain this difference we analyzed trp repressor dimer formation and dissociation using an in vitro transcription/translation system. Nascent wild type or mutant repressor polypeptides, synthesized in the presence of an excess of a second repressor, were invariably incorporated into heterodimers. In contrast, previously synthesized and assembled wild type dimers appeared to be refractory to dissociation, since they did not form heterodimers. However, previously synthesized mutant dimeric repressors that were defective in tryptophan binding readily dissociated and formed heterodimers. We noted that the ability of a dimeric repressor to dissociate under our conditions correlated inversely with its affinity for tryptophan. Consistent with this conclusion, we found that dissociation of the wild type aporepressor (no added tryptophan) was appreciably more rapid than dissociation of the tryptophan-saturated wild type repressor.

trp repressor/trp operator interaction. Equilibrium and kinetic analysis of complex formation and stability.

The trp repressor of Escherichia coli regulates transcription initiation in the trp operon by binding at an operator located within the trp promoter region. We have used a filter binding assay to analyze the interaction between purified trp repressor and a synthetic 43-base pair DNA fragment containing the natural trp promoter-operator region. In equilibrium binding experiments, the KD of high affinity binding of trp repressor to this DNA fragment was determined to be 2 x 10(-10) M. Low affinity binding was observed at repressor concentrations above 10 nM. In kinetic experiments with various input ratios of repressor to operator, trp repressor-operator complexes dissociated with equivalent, first-order kinetics. Instantaneous reduction of the tryptophan concentration resulted in increased rates of complex dissociation, indicating that loss of one or both tryptophan molecules from the repressor-operator complex destabilizes the complex. A heterodimeric repressor with a single tryptophan binding site was constructed and its affinity for operator was compared with that of ligand free aporepressor and tryptophan saturated repressor. The heterodimeric repressor had a 20-25-fold higher affinity for operator than did the aporepressor, and it had a 20-25-fold lower affinity for operator than did the tryptophan-saturated repressor.

The NH2-terminal arms of trp repressor participate in repressor/operator association.

The 3-dimensional structure of the trp repressor, aporepressor, and repressor/operator complex have been described. The NH2-terminal arms of the protein, comprising approximately 12-14 residues, were not well resolved in any of these structures. Previous studies by Carey showed that the arms are required for full in vitro repressor activity. To examine the roles of the arms more fully we have removed codons 2-5 and 2-8 of the trpR gene and analyzed the resulting truncated repressors in vivo and in vitro. The delta 2-5 trp repressor was found to be approximately 25% as active as the wild type repressor in vivo. In in vitro equilibrium binding experiments, the delta 2-5 trp repressor was shown to be five-fold less active in operator binding. The rate of dissociation of the complex formed between the delta 2-5 trp repressor and operator was essentially the same as the rate of dissociation of the wild type trp repressor/operator complex. However association of the delta 2-5 trp repressor with operator was clearly defective. Since the NH2-terminal arms of the trp repressor appear to affect association predominantly they may play a role in facilitating non-specific association of repressor with DNA as repressor seeks its cognate operators. The delta 2-8 trp repressor was unstable in vivo and in vitro, suggesting that some portion of the NH2-terminal arm is required for proper folding of the remainder of the molecule.

Enhanced operator binding by trp superrepressors of Escherichia coli.

The trp repressor of Escherichia coli binds to the operators of three operons concerned with tryptophan biosynthesis and regulates their expression. trp superrepressors can repress expression of the trp operon in vivo at lower tryptophan concentrations than those required by the wild-type repressor. The five known superrepressors have been purified and characterized using a modified filter binding assay. In four of the five superrepressors, EK13, EK18, DN46 and EK49, negatively charged wild-type residues located on the surface of the repressor that faces the operator are replaced by positively charged or neutral residues. Each of these proteins has higher affinity for the trp operator than wild-type repressor. Decreased rates of dissociation of the repressor-operator complex were found to be responsible for the higher affinities. The fifth superrepressor, AV77, has an amino acid substitution in the turn of the helix-turn-helix DNA-binding motif. This superrepressor was indistinguishable from wild-type repressor in our filter binding assay. We conclude that rapid dissociation of repressor from operator is important for trp repressor function in vivo. The negatively charged wild-type residues that are replaced in superrepressors are probably responsible for the characteristic rapid dissociation of the trp repressor from the trp operator.

Nitrate assimilation in Neurospora crassa: enzymatic and immunoblot analysis of wild-type and nit mutant protein products in nitrate-induced and glutamine-repressed cultures.

The nitrate assimilatory pathway in Neurospora crassa is composed of two enzymes, nitrate reductase and nitrite reductase. Both are alpha 2 type homodimers. Enzyme-bound prosthetic groups mediate the electron transfer reactions which reduce inorganic nitrate to an organically utilizable form, ammonium. One, a molybdenum-containing cofactor, is required by nitrate reductase for both enzyme activity and holoenzyme assembly. Three modes of regulation are imposed on the expression of nitrate assimilation, namely: nitrogen metabolite repression, nitrate induction and autogenous regulation by nitrate reductase. In this study, nitrocellulose blots of sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) resolved proteins from crude extracts of the wild type and specific nitrate-nonutilizing (nit) mutants were examined for material cross-reactive with antibodies against nitrate reductase and nitrite reductase. The polyclonal antibody preparations used were rendered monospecific by reverse affinity chromatography. Growth conditions which alter the regulatory response of the organism were selected such that new insight could be made into the complex nature of the regulation imposed on this pathway. The results indicate that although nitrate reductase and nitrite reductase are coordinately expressed under specific nutritional conditions, the enzymes are differentially responsive to the regulatory signals.