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The gene encoding for bacterial cytochrome c-551 from Pseudomonas stutzeri substrain ZoBell has been mutated to convert the invariant sixth ligand methionine residue into histidine, creating the site-specific mutant M61H. Proton NMR resonance assignments were made for all main-chain and most-side chain protons in the diamagnetic, reduced form at pH 9.2 and 333 K by two-dimensional NMR techniques. Distance constraints (1074) were determined from nuclear Overhauser enhancements and main-chain torsion-angle constraints (72) from scalar coupling estimates. Solution conformations for the protein were computed by the simulated annealing approach. For 28 computed structures, the root mean squared displacement from the average structure excluding the terminal residues 1, 2, 81, and 82 was 0.52 A (sigma = 0.096) for backbone atoms and 0.90 A (sigma = 0.122) for all heavy atoms. The global folding of the mutant protein is the same as for wild type. The biggest changes are localized in a peptide span over residues 60-65. The most striking behavior of the mutant protein is that at room temperature and neutral pH it exists in a state similar to the molten globular state that has been described for several proteins under mild denaturing conditions, but the mutant converts to a more ordered state at high pH and temperature.

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The gene nirM, coding for cytochrome c-551 in Pseudomonas stutzeri substrain ZoBell, was engineered to mutate Met61, the sixth ligand to the heme c, into His61, thereby converting the typical Met-His coordination of a c-type cytochrome into His-His, typical of b-type cytochromes. The mutant protein was expressed heterologously in Escherichia coli at levels 3-fold higher than in Pseudomonas and purified to homogeneity. The mutant retained low-spin visible spectral characteristics, indicating that the strong field ligand His 61 was coordinated to the iron. The physiochemical properties of the mutant were measured and compared to the wild-type properties. These included visible spectra, ligand binding reactions, stability to temperature and chemical denaturant, oxidation-reduction potentials, and electron-transfer kinetics to the physiological nitrite reductase of Pseudomonas. Despite a change in potential from the normal 260 mV to 55 mV, the mutant retained many of the properties of the c-551 family.

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The polymorphic ciliated protozoan Tetrahymena vorax can undergo differentiation from the microstomal form, which normally feeds on bacteria and other particulate matter, into the macrostomal cell type, which is capable of ingesting prey ciliates. The process is triggered by exposure of the microstome to an inducer contained in stomatin, an exudate of the prey. To establish the identity of the signal, stomatin was fractionated by combinations of cation exchange, HPLC, and TLC, and the fractions were assayed for biological activity. Although no single active fraction of purified inducer was obtained, all fractions with activity contained ferrous iron and the nucleic acid catabolites hypoxanthine (6-oxypurine) and uracil (2, 4-dioxopyrimidine), probably in a chelated form. The activity of synthetic complexes containing these three components is equivalent to stomatin. These results indicate a role for ferrous iron and its potential in chelated form to signal differentiation in certain protozoa and, perhaps, in other organisms as well.

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The urea-induced unfolding of the Escherichia coli tryptophan synthase alpha-subunit is examined via fluorescence measurements with tryptophan-containing alpha-subunit mutants, constructed by in vitro mutagenesis. Early unfolding studies with urea and guanidine suggested that the wild type protein unfolded in a two-step process with a stable intermediate composed of a native alpha-1 folding unit (residues 1-188) and a completely unfolded alpha-2 folding unit (residues 189-268). Recently, more detailed spectroscopic and calorimetric data from the Matthews and Yutani groups indicate that such a structure for the intermediates seems unlikely. Previously, we described the introduction of Trp residues as unfolding reporter groups separately into each of the folding domains and showed that these proteins are wild type enzymatically and in their stability to urea. The unfolding behavior of these alpha-subunits, monitored by fluorescence intensity changes at the discrete emission lambda max for each, in both equilibrium and kinetic experiments, suggest that: (a) both folding units commence unfolding simultaneously (near 2 M urea); (b) the larger alpha-1 unit unfolds in a multistep process, initially yielding a partially unfolded intermediate form which subsequently appears to unfold progressively to completion; and (c) the smaller alpha-2 unit unfolds in a single step event. These results are also clearly incompatible with the early proposals on the structure of the intermediate. It is suggested here that the intermediate is heterogeneous, consisting of a stable, partially unfolded form of alpha-1 attached to either a completely folded or completely unfolded form of alpha-2. These results are consistent with and provide an added dimension to the recent description of the proposed structure of the intermediate.

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Early studies suggested that the Escherichia coli tryptophan synthase alpha-subunit unfolded in a two-step process in which there was a stable intermediate composed of a native alpha-1 folding unit (residues 1-188) and a completely unfolded alpha-2 folding unit (residues 189-268). More recent evidence has indicated that such a structure for the intermediate seems unlikely. In this report, single Trp residues (absent in the wild-type alpha-subunit) are substituted separately for Phe residues at positions 139 (in alpha-1) and 258 (in alpha-2) to produce the F139W, F258W, and F139W/F258W mutant alpha-subunits. The UV absorbance and fluorescence properties of the F139W/F258W double mutant are identical with those of equimolar mixtures of the single mutants, suggesting that the Trp residue at each position can independently report the behavior of its respective folding unit. Each mutant alpha-subunit is wild-type enzymatically, and when UV absorbance is monitored, the urea-induced unfolding of the three tryptophan-containing alpha-subunits is virtually identical to the wild-type protein. These wild-type properties make these proteins attractive candidates for a fluorescence examination of the behavior of the individual folding units and the structure of potential intermediate(s) and as host proteins for the insertion of our existing destabilizing and/or stabilizing mutational alterations.

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The roles of Ser-235 and helix-8' (residues 235-242) in the functional binding and turnover of phosphorylated substrates by the alpha-subunit of the E. coli tryptophan synthase (TSase) alpha 2 beta 2-holoenzyme complex are examined. Previous crystallographic analyses indicated that this region was one of several near the phosphate moiety of the physiological substrate, indole-3-glycerol phosphate (IGP). The peptidyl amido group of Ser-235 was suggested to H-bond to the phosphate group; a helix macrodipole binding role was suggested for helix-8'. The activities and substrate Kms of mutant alpha-subunits altered in this region by site-specific mutagenesis are reported here. Substitutions at Ser-235 by an acidic (glutamic acid, mutant SE235), basic (lysine, mutant SK235), or a non-peptidyl amido-containing residue (proline, mutant SP235) exhibit 40- to 180-fold Km increases for IGP and D-glyceraldehyde-3-phosphate; no Km defects for indole were observed. kcat values for SP235, SE235, and SK235 are 100, 70, and 40%, respectively, of the wild-type value. Steric considerations may explain the results with the SE235 and SK235 mutant alpha-subunits; however, the SP235 results are consistent with the suggested phosphate binding role for the Ser-235 peptidyl amido group during catalysis, A helix-8' dipole role was explored following proline substitutions separately at the first six (of eight) residues. Proline substitutions at positions-1 through -4 in helix-8' have normal indole Kms and catalytic activities in all four TSase reactions, suggesting no major global structural changes in these proteins. By these criteria, substitutions at positions-5 and -6 lead to significant structural alterations. Km increases for phosphorylated substrates are substantial (up to 40-fold) and are dependent upon the presence of L-serine at the beta-subunit active site. In the absence of L-serine, substitution only at the first position results in binding defects; in the presence of L-serine, substitutions at the first, second and third positions, show binding defects of decreasing magnitude, sequentially. Substitutions at the fourth and fifth position have no effect on substrate binding. It is suggested that during catalysis a helix dipole effect on binding may be exerted but only via intersubunit-induced conformational changes due to ligand (L-serine) binding to the beta-subunit.

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Random chemical mutagenesis, in vitro, of the 5' portion of the Escherichia coli trpA gene has yielded 66 mutant alpha subunits containing single amino acid substitutions at 49 different residue sites within the first 121 residues of the protein; this portion of the alpha subunit contains four of the eight alpha helices and three of the eight beta strands in the protein. Sixty-two of the subunits were examined for their heat stabilities by sensitivity to enzymatic inactivation (52 degrees C for 20 min) in crude extracts and by differential scanning calorimetry (DSC) with 29 purified proteins. The enzymatic activities of mutant alpha subunits that contained amino acid substitutions within the alpha and beta secondary structures were more heat labile than the wild-type alpha subunit. Alterations only in three regions, at or immediately C-terminal to the first three beta strands, were stability neutral or stability enhancing with respect to enzymatic inactivation. Enzymatic thermal inactivation appears to be correlated with the relative accessibility of the substituted residues; stability-neutral mutations are found at accessible residual sites, stability-enhancing mutations at buried sites. DSC analyses showed a similar pattern of stabilization/destabilization as indicated by inactivation studies. Tm differences from the wild-type alpha subunit varied +/- 7.6 degrees C. Eighteen mutant proteins containing alterations in helical and sheet structures had Tm's significantly lower (-1.6 to -7.5 degrees C) than the wild-type Tm (59.5 degrees C). In contrast, 6 mutant alpha subunits with alterations in the regions following beta strands 1 and 3 had increased Tm's (+1.4 to +7.6 degrees C). Because of incomplete thermal reversibilities for many of the mutant alpha subunits, most likely due to identifiable aggregated forms in the unfolded state, reliable differences in thermodynamic stability parameters are not possible. The availability of this group of mutant alpha subunits which clearly contain structural alterations should prove useful in defining the roles of certain residues or sequences in the unfolding/folding pathway for this protein when examined by urea/guaninidine denaturation kinetic analysis.

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Thirty-nine mutant tryptophan synthase alpha subunits have been purified and analyzed (in the presence of the beta 2-subunit) for their enzymatic (kcat, Km) behavior in the reactions catalyzed by the alpha 2.beta 2 complex, the fully constituted form of this enzyme. The mutant alpha subunits, obtained by in vitro random, saturation mutagenesis of the encoding trpA gene, contain single amino acid substitutions at sites within the first 121 residues of the alpha polypeptide. Four categories of altered residues have been tentatively assigned roles in the catalytic functions of this enzyme: 1) catalytic residues (Glu49 and Asp60); 2) residues involved in substrate binding or orientation (Phe22, Thr63, Gln65, Tyr102, and Leu105); 3) residues involved in alpha.beta subunit interactions (Gly51, Pro53, Asp56, Asp60, Pro62, Ala67, Phe72, Thr77, Pro78, Tyr102, Asn104, Leu105, and Asn108); and 4) residues with no apparent catalytic roles. Catalytic residue alterations result in no detectable activity in the alpha-subunit specific reactions. Substrate binding/orientation roles are detected enzymatically primarily as rate defects; alterations only at Tyr102 result in apparent Km effects. alpha.beta interaction roles are detected as rate defects in all tryptophan synthase reactions plus Km increases for the alpha-subunit substrate, indole-3-glycerol phosphate, only when L-serine is present at the beta 2-subunit active site. A substitution at only one site, Asn104, appears to be unique in its potential effect on intersubunit channeling of indole, the product of the alpha-subunit specific reaction, to the beta 2-subunit active site.

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In vitro mutagenesis of the Escherichia coli trpA gene has yielded 66 mutant tryptophan synthase alpha subunits containing single amino acid substitutions at 49 different residue sites and 29 double and triple amino acid substitutions at 16 additional sites, all within the first 121 residues of the protein. The 66 singly altered mutant alpha subunits encoded from overexpression vectors have been examined for their ability to support growth in trpA mutant host strains and for their enzymatic and stability properties in crude extracts. With the exception of mutant alpha subunits altered at catalytic residue sites Glu-49 and Asp-60, all support growth; this includes those (48 of 66) that have no enzymatic defects and those (18 of 66) that do. The majority of the enzymatically defective mutant alpha subunits have decreased capacities for substrate (indole-3-glycerol phosphate) utilization, typical of the early trpA missense mutants isolated by in vivo selection methods. These defects vary in severity from complete loss of activity for mutant alpha subunits altered at residue positions 49 and 60 to those, altered elsewhere, that are partially (up to 40 to 50%) defective. The complete inactivation of the proteins altered at the two catalytic residue sites suggest that, as found via in vitro site-specific mutagenesis of the Salmonella typhimurium tryptophan synthetase alpha subunit, both residues probably also participate in a push-pull general acid-base catalysis of indole-3-glycerol phosphate breakdown for the E. coli enzyme as well. Other classes of mutant alpha subunits include some novel types that are defective in their functional interaction with the other tryptophan synthetase component, the beta 2 subunit. Also among the mutant alpha subunits, 19 were found altered at one or another of the 34 conserved residue sites in this portion of the alpha polypeptide sequence; surprisingly, 10 of these have wild-type enzymatic activity, and 16 of these can satisfy growth requirements of a trpA mutant host. Heat stability and potential folding-rate alterations are found in both enzymatically active and defective mutant alpha subunits. Tyr-4. Pro-28, Ser-33, Gly-44, Asp-46, Arg-89, Pro-96, and Cys-118 may be important for these properties, especially for folding. Two regions, one near Thr-24 and another near Met-101, have been also tentatively identified as important for increasing stability.

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Certain Escherichia coli tryptophan synthase mutant alpha-subunits encoded from mutagenized trpA-containing plasmids were overexpressed as insoluble aggregates which were seen as large, intracellular inclusion bodies. The insoluble aggregates were solubilized to various degrees by several neutral, chaotropic salts. The order of effectiveness of these salts (KSCN, NaI greater than NaNO3, LiBr greater than CaCl2) followed that for the Hofmeister series. Optimum conditions for the use of KSCN resulted in a maximum 70 to 75% solubilization of the aggregate forms for all mutant alpha-subunits examined. Removal of KSCN by dialysis resulted in the recovery of biological activity and of certain characteristic structural properties. Such salts may be a useful alternative for other recombinant protein aggregates which resist complete renaturation by commonly used treatments with guanidine or urea.

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A mutagenesis approach was initiated in order to examine further the folding behavior of the alpha-subunit of the Escherichia coli tryptophan synthase. A random single base pair saturation mutagenesis procedure (Myers, R.M., Lerman, L.S., and Maniatis, T. (1985) Science 229, 242-247) was applied in vitro to subcloned fragments of the trpA gene, which codes for this polypeptide. Mutagenesis plasmid vectors were constructed containing three fragments of the trpA gene which together code for about half of the total amino acid residues of the alpha-subunit. The vectors were constructed such that each strand of each trpA fragment could be altered. These trpA fragments were mutagenized in vitro (using nitrous acid, formic acid, hydrazine, and potassium permanganate), and several thousands of mutants have been isolated. Thirty-two mutants, contained within the first two trpA fragments (which encompass the first 206 base pairs of the trpA gene and encode the first 63 residues of the alpha-subunit) have been sequenced. Of these, 20 (63%) contained single base pair alterations, 12 (37%) contained multiple alterations, and 17 (53%) of these base pair alterations resulted in single amino acid substitutions. Selected mutant trpA fragments were subcloned into an overexpression vector in which the trpA gene is controlled by the tac promoter and is inducible by lactose. The kinetics and extent of induction show that after 22 h of induction, the wild-type alpha-subunit constituted about 30% of the total protein. A simple one-step purification procedure for the alpha-subunit is described in which 15 mg of alpha-subunit can be obtained from 200 ml of fully induced cultures. The mutant trpA genes were induced for mutant alpha-subunit expression, and an initial examination of their properties in crude extracts was performed. Of the 17 mutant proteins examined, most were overproduced to levels comparable to that for the wild-type alpha-subunit. An analysis of the apparent stability, beta 2-subunit-activating activity, and intrinsic activity of this group of mutant alpha-subunits suggests that many amino acid alterations have no apparent effect; there is a variety of novel functional defects; and a sequence located near residues 28 through 54 may be particularly critical for the normal folding of the polypeptide.

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The tryptophan synthase alpha 2 beta 2 complex catalyzes tryptophan (Trp) biosynthesis from serine plus either indole (IN) or indole-3-glycerol phosphate (InGP). The photoreactive 5-azido analog in IN (AzIN), itself a substrate in the dark, was utilized to examine the substrate binding sites on this enzyme. When irradiated with AzIN at concentrations approaching IN saturation for the IN----Trp activity (0.1 mM), in the absence of serine, the enzyme was increasingly inactivated (up to 70-80%) concomitant with the progressive binding of a net of 2 mol AzIN per alpha beta equivalent. Little or no cooperativity in the binding of the 2 mol AzIN was observed. In contrast, there was minimal effect on the IN----InGP activity. Under these conditions AzIN appeared to be incorporated equally into each subunit. No significant inactivation nor binding occurred in the presence of serine. A quantitatively similar inactivation of InGP----Trp activity was observed over the same AzIN concentration range, suggesting common IN sites for Trp biosynthesis from either indole substrate. At higher concentrations (0.1-0.7 mM), no further inactivation occurred, although there was extensive additional binding (up to 10 mol/alpha beta equivalent). These data are consistent, although more clear-cut quantitatively, with the high- and low-affinity sites proposed from equilibrium dialysis studies. AzIN binding studies utilizing the isolated beta 2 subunit confirmed earlier reports suggesting the existence of many nonspecific IN binding sites on this subunit.

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The incorporation and distribution of 14C in 2'-deoxycoformycin, elaborated by Streptomyces antibioticus, were studied with [U-14C]glycine, [U-14C]adenosine and [U-14C]adenine. Similar ratios of 14C in the aglycon and carbohydrate portions of 2'-deoxycoformycin, ara-A, and adenosine isolated from the RNA indicated that [U-14C]adenosine was incorporated into 2'-deoxycoformycin without cleavage of the N-glycosylic bond. Following the addition of [U-14C]adenine, 98% of the 14C isolated from [14C]-2'-deoxycoformycin resided in the aglycon. 2'-Deoxycoformycin biosynthesis may not require the de novo purine biosynthetic pathway as evidenced by the failure to detect incorporation of [U-14C]glycine into 2'-deoxycoformycin. These data suggest that the biosynthesis of 2'-deoxycoformycin involves the incorporation of the carbon-nitrogen skeleton of an intact purine nucleoside or nucleotide, thereby implying that a purine ring is opened enzymatically between C-6 and N-1 and a one-carbon unit is added to form the 1,3-diazepine ring of 2'-deoxycoformycin.

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The alpha subunit of the Escherichia coli tryptophan synthase catalyzes the reversible aldolytic reaction: Indole-3-glycerol phosphate in equilibrium indole + glyceraldehyde 3-phosphate. The use of 5-azidoindole as a photoaffinity label has made the generation of a number of enzyme-substrate complexes possible, each with a given degree of saturation of the two postulated indole sites. When assayed in the reverse reaction (indole-3-glycerol phosphate synthesis), samples of alpha subunit treated at concentrations of 5-azidoindole less than or equal to 2 mM show a progressive 30-40% activation. A gradual inactivation occurs only in samples irradiated at concentrations in excess of 2 mM 5-azidoindole, and this inactivation is complete at 8-10 mM. A quantitatively similar activation occurs in the forward reaction (indole synthesis), however inactivation in this case is incomplete, with complexes treated at 8-12 mM 5-azidoindole retaining 30-40% relative activity in this reaction. When treated alpha subunits were assayed for their abilities to complement the beta 2-subunit in the reactions indole + L-serine leads to L-tryptophan + H2O and indole-3-glycerol phosphate + L-serine leads to L-tryptophan + glyceraldehyde 3-phosphate, quantitatively lesser amounts of activation followed by total inactivation are observed over a similar range of 5-azidoindole concentrations.

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Mutants of Staphylococcus staphylolyticus incapable of producing an extracellular staphylolytic glycylglycine endopeptidase were isolated and found to have cells in the population susceptible to lysis by this enzyme, as did the wild-type organism under conditions in which the endopeptidase was not produced. These results suggest that cultures of this organism normally contain a heterogeneous population of cells with regard to cell wall composition and susceptibility to the enzyme. Production of the endopeptidase appears to act as a selective pressure which removes the susceptible cells in the population as the enzyme appears in the medium. A comparison of the peptidoglycan of the wild-type organism grown under conditions in which the endopeptidase was produced with that of this organism grown under nonproducing conditions and with those of endopeptidase-less mutants showed that in the presence of the endopeptidase the cell population had peptidoglycan with shorter peptide cross bridges and a greater percentage of serine in these cross bridges than was found in cells grown in the absence of the enzyme. The inability of the endopeptidase to hydrolyze glycylserine and serylglycine peptide bonds suggests that at least part of the resistance this organism has to the endopeptidase is due to relative amounts of serine found in the peptide cross bridges of some cells in the population.

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