Thermodynamic and biophysical characterization of cytochrome P450 BioI from Bacillus subtilis

Cytochrome P450 BioI (CYP107H1) from Bacillus subtilis is involved in the early stages of biotin synthesis. Previous studies have indicated that BioI can hydroxylate fatty acids and may also perform an acyl bond cleavage reaction [Green, A. J., Rivers, S. L., Cheesman, M., Reid, G. A., Quaroni, L. G., Macdonald, I. D. G., Chapman, S. K., and Munro, A. W. (2001) J. Biol. Inorg. Chem. 6, 523-533. Stok, J. E., and De Voss, J. J. (2000) Arch. Biochem. Biophys. 384, 351-360]. Here we show novel binding features of P450 BioI--specifically that it binds steroids (including testosterone and progesterone) and polycyclic azole drugs with similar affinity to that for fatty acids (K(d) values in the range 0.1-160 microM). Sigmoidal binding curves for titration of BioI with azole drugs suggests a cooperative process in this case. BioI as isolated from Escherichia coli is in a mixed heme iron spin state. Alteration of the pH of the buffer system affects the heme iron spin-state equilibrium (higher pH increasing the low-spin content). Steroids containing a carbonyl group at the C(3) position induce a shift in heme iron spin-state equilibrium toward the low-spin form, whereas fatty acids produce a shift toward the high-spin form. Electron paramagnetic resonance (EPR) studies confirm the heme iron spin-state perturbation inferred from optical titrations with steroids and fatty acids. Potentiometric studies demonstrate that the heme iron reduction potential becomes progressively more positive as the proportion of high-spin heme iron increases (potential for low-spin BioI = -330 +/- 1 mV; for BioI as purified from E. coli (mixed-spin) = 228 +/- 2 mV; for palmitoleic acid-bound BioI = -199 +/- 2 mV). Extraction of bound substrate-like molecule from purified BioI indicates palmitic acid to be bound. Differential scanning calorimetry studies indicate that the BioI protein structure is stabilized by binding of steroids and bulky azole drugs, a result confirmed by resonance Raman studies and by analysis of disruption of BioI secondary and tertiary structure by the chaotrope guanidinium chloride. Molecular modeling of the BioI structure indicates that a disulfide bond is present between Cys250 and Cys275. Calorimetry shows that structural stability of the protein was altered by addition of the reductant dithiothreitol, suggesting that the disulfide is important to integrity of BioI structure.     

Thermodynamic characterization of the osmolyte- and ligand-folded states of Bacillus subtilis ribonuclease P protein

In Bacillus subtilis, P protein is the noncatalytic component of ribonuclease P (RNase P) that is critical for achieving maximal nuclease activity under physiological conditions. P protein is predominantly unfolded (D) at neutral pH and low ionic strength; however, it folds upon the addition of sulfate anions (ligands) as well as the osmolyte trimethylamine N-oxide (TMAO) [Henkels, C. H., Kurz, J. C., Fierke, C. A., and Oas, T. G. (2001) Biochemistry 40, 2777-2789]. Since the molecular mechanisms that drive protein folding for these two solutes are different, CD thermal denaturation studies were employed to dissect the thermodynamics of protein unfolding from the two folded states. A global fit of the free-energy of TMAO-folded P protein versus [TMAO] and temperature yields T(S), DeltaH(S), and DeltaC(p) of unfolding for the poorly populated, unliganded, folded state (N) in the absence of TMAO. These thermodynamic parameters were used in the fit of the data from the coupled unfolding/ligand dissociation reaction to obtain the sulfate dissociation constant (K(d)) and the DeltaH and DeltaC(p) of dissociation. These fits yielded a DeltaC(p) of protein unfolding of 826 +/- 23 cal mol(-)(1) K(-)(1) and a DeltaC(p) of 1554 +/- 29 cal mol(-)(1) K(-)(1) for the coupled unfolding and dissociation reaction (NL(2) --> D + 2L). The apparent stoichiometry of sulfate binding is two, so the DeltaC(p) increment of ligand dissociation is 363 +/- 9 cal mol(-)(1) K(-)(1) per site. Because N and NL(2) appear to be structurally similar and therefore similarly solvated using standard biophysical analyses, we attribute a substantial portion of this DeltaC(p) increment to an increase in conformational heterogeneity coincident with the NL(2) --> N + 2L transition.     

Genetic interaction observed in Bacillus subtilis

Summary Some evidence was obtained that genetic interaction occurs inBacillus subtilis K. A mixed inoculation of two doubly auxotrophic mutants onto approriate media yielded tiny colonies which seemed to be initiated by heterocaryons or heterozygotes. The tiny colonies contained not only a recombinant type which acquired two characters from one or another parent, but also some abnormal types having new characters which were not recognized in either parent. The phenomenon is similar to the genetic interaction found inStreptomyces.With 5 Figures in the Text     

Bacillus subtilis transcriptional regulators interaction

Bacillus subtilis aprE gene codes for the extracellular protease subtilisin. Its expression is controlled by AbrB, DegU, Hpr, SinI, SinR and Spo0A transition state protein regulators. To determine in vivo the protein-protein interactions among these regulators, we used the LexA-based bacterial genetic two-hybrid system. Our results show homo-dimerization to all the analyzed proteins and hetero-dimerization between SinR-SinI and SinR-Hpr.     

Glutamate synthase from Bacillus subtilis PCI 219

Reduced pyridine nucleotide dependent glutamate synthase [L-glutamate: NADP+ oxidoreductase (transaminating); EC 1.4.1.13] was purified to homogeneity from Bacillus subtilis PCI 219. The molecular weight of the enzyme was 210,000, and the enzyme was composed of two nonidentical subunits with molecular weights of 160,000 and 56,000. The absorption and CD spectra of the enzyme indicated that the enzyme is an iron-sulfur flavoprotein. The enzyme was found to contain 1:1:7.4:8.7 mol of FMN, FAD, iron atoms, and acid-labile sulfur atoms per mol (MW 210,000). EPR measurements of the NADPH-reduced enzyme at 77K revealed the formation of a stable flavin semiquinone intermediate; however, none of the signals originating from the iron-sulfur cluster was observed. Still at 4.2K the EPR signals in the region of g = 2, which may originate from the paramagnetic iron-sulfur cluster, were clearly observed for both the isolated and dithionite-reduced states of the enzyme. The enzyme exhibited a wide coenzyme specificity, and either NADPH or NADH could be used as electron donor, although the latter was less effective. The enzyme activity was also expressed when ammonium chloride was substituted for L-glutamine. The optimum pHs for NADPH-Gln-, NADH-Gln-, and NADPH-NH3-dependent reactions were 7.8, 6.9, and 9.4, respectively. The apoenzyme exhibited substantial inactivation of the Gln-dependent activities but still retained the NH3-dependent activities. Enzyme reduction-oxidation experiments, initial velocity experiments, and product inhibition patterns revealed that both the NADPH-Gln- and NADH-Gln-dependent reactions coincided with the two-site ping-pong uni-uni bi-bi kinetic mechanism, while the NADPH-NH3-dependent reaction deviated from Michaelis-Menten kinetics. The Gln-dependent activities were inhibited by several TCA cycle members, especially L-malate and fumarate, as well as L-methionine-SR-sulfoximine, pyridoxal-5'-phosphate, and pCMB. The regulation of the glutamate synthase, glutamine synthetase [EC 6.3.1.2], and glutamate dehydrogenase [EC 1.4.1.3] activities was examined with cultures of cells grown with various nitrogen and carbon sources.     

Regulation of synthesis of glutamine synthase in Bacillus subtilis

A study of the regulation of the synthesis of the enzyme glutamine synthase in Bacillus subtilis was initiated. An assay, based on the measurement of glutamo-hydroxamate, was used to characterize the enzyme in crude preparations and in toluene-treated cells. Determinations were made of the Michaelis constants for adenosine triphosphate, hydroxylamine, and glutamate (9 x 10(-3), 4 x 10(-3), and 2.2 x 10(-2)m, respectively), the pH optimum (7.6 to 7.7), and the stability. The differential rate of synthesis was determined under various growth conditions. The enzyme was found to be relatively insensitive to regulation. Partial repression was caused by glutamine, arginine, asparagine, and glutamate, or by carbon limitation in a chemostat. Derepression was caused by exhaustion of externally added amino acids or by nitrogen limitation in a chemostat.     

Characterization of the major citrate synthase of Bacillus subtilis.

The major citrate synthase of Bacillus subtilis (CS-II) was purified to near homogeneity and shown to correspond to the product of the citZ gene. Accumulation of CS-II during exponential growth and stationary phases paralleled expression of the citZ gene. The physical and kinetic properties of CS-II were similar to those of citrate synthase enzymes from Bacillus megaterium and from eukaryotic cells but differed from those of citrate synthases from many gram-negative bacteria.     

Detecting protein-protein interactions in the intact cell of Bacillus subtilis (ATCC 6633)

The salt bridge, paired group-specific reagent cyanogen (ethanedinitrile; C(2)N(2)) converts naturally occurring pairs of functional groups into covalently linked products. Cyanogen readily permeates cell walls and membranes. When the paired groups are shared between associated proteins, isolation of the covalently linked proteins allows their identity to be assigned. Examination of organisms of known genome sequence permits identification of the linked proteins by mass spectrometric techniques applied to peptides derived from them. The cyanogen-linked proteins were isolated by polyacrylamide gel electrophoresis. Digestion of the isolated proteins with proteases of known specificity afforded sets of peptides that could be analyzed by mass spectrometry. These data were compared with those derived theoretically from the Swiss Protein Database by computer-based comparisons (Protein Prospector; http://prospector.ucsf.edu). Identification of associated proteins in the ribosome of Bacillus subtilis strain ATCC 6633 showed that there is an association homology with the association patterns of the ribosomal proteins of Haloarcula marismortui and Thermus thermophilus. In addition, other proteins involved in protein biosynthesis were shown to be associated with ribosomal proteins.     

Crystal structure of thymidylate synthase A from Bacillus subtilis

Thymidylate synthase (TS) converts dUMP to dTMP by reductive methylation, where 5,10-methylenetetrahydrofolate is the source of both the methylene group and reducing equivalents. The mechanism of this reaction has been extensively studied, mainly using the enzyme from Escherichia coli. Bacillus subtilis contains two genes for TSs, ThyA and ThyB. The ThyB enzyme is very similar to other bacterial TSs, but the ThyA enzyme is quite different, both in sequence and activity. In ThyA TS, the active site histidine is replaced by valine. In addition, the B. subtilis enzyme has a 2.4-fold greater k(cat) than the E. coli enzyme. The structure of B. subtilis thymidylate synthase in a ternary complex with 5-fluoro-dUMP and 5,10-methylenetetrahydrofolate has been determined to 2.5 A resolution. Overall, the structure of B. subtilis TS (ThyA) is similar to that of the E. coli enzyme. However, there are significant differences in the structures of two loops, the dimer interface and the details of the active site. The effects of the replacement of histidine by valine and a serine to glutamine substitution in the active site area, and the addition of a loop over the carboxy terminus may account for the differences in k(cat) found between the two enzymes.     

Saturation mutagenesis and self-inducible expression of trehalose synthase in Bacillus subtilis

Trehalose is a nonreducing disaccharide synthesized by trehalose synthase (TreS), which catalyzes the reversible interconversion of maltose and trehalose. We aimed to enhance the catalytic conversion of maltose to trehalose by saturation mutagenesis, and constructed a self-inducible TreS expression system by generating a robust Bacillus subtilis recombinant. We found that the conversion yield and enzymatic activity of TreS was enhanced by saturation mutations, especially by the combination of V407M and K490L mutations. At the same time, these saturation mutations were contributing to reducing by-products in the reaction. Compared to WT TreS, the conversion yield of maltose to trehalose was increased by 11.9%, and the k_cat/K_m toward trehalose was 1.33 times higher in the reaction catalyzed by treS^V407M-K490L. treS^V407M-K490L expression was further observed in the recombinant B. subtilis W800N(Δσ^F) under the influence of P_srfA, P_cry3Aa, and P_srfA-cry3Aa promoters without an inducer. It was shown that P_srfA-cry3Aa was evidently a stronger promoter for treS^V407M-K490L expression, with the intracellular enzymatic activity of recombinant treS^V407M-K490L being over 5,800 U/g at 35 hr in TB medium. These results suggested the combination of two mutations, V407M and K490L, was conducive for the production of trehalose. In addition, the self-inducible TreS^V407M/K490L mutant in the B. subtilis host provides a low-cost choice for the industrial production of endotoxin-free trehalose with high yields.     

Regulation of dihydrodipicolinate synthase and aspartate kinase in Bacillus subtilis.

The regulation of dihydrodipicolinate synthase (EC 4.2.1.52) and aspartate kinase (EC 2.7.2.4) was studied in Bacillus subtilis 168. Starvation for lysine gave depression of one aspartate kinase isoenzyme but not of dihydrodipicolinate synthase. Strains resistant to growth inhibition by the lysine analogue thiosine exhibited constitutively derepressed synthesis of one aspartate kinase isoenzyme but had normal levels of dihydrodipicolinate synthase. The data provide strong evidence that lysine is not the signal for derepression of dihydrodipicolinate synthase. Nevertheless, dihydrodipicolinate synthase specific activity increased during sporulation, and it is suggested that this increase may result, in part, from resistance to proteolysis of that enzyme.     

Cloning and characterization of two plasmids from Bacillus thuringiensis in Bacillus subtilis

Bacillus thuringiensis subspecies israliensis plasmids pTX14-1 and pTX14-3 were cloned and analyzed by Southern blot hybridization for their replication mechanism in Bacillus subtilis. The cloning of pTX14-1 into the replicon deficient vector pBOE335 showed the usual characteristics of single-stranded DNA plasmids, i.e., it generated circular single-stranded DNA and high molecular weight (HMW) multimers. The other plasmid, pTX14-3, behaved differently; it generated neither single-stranded DNA nor HMW multimers. Treatment with rifampicin did not result in the accumulation of single-stranded DNA. However, deletion of an EcoRI-PstI fragment resulted in the accumulation of both single-stranded DNA and HMW multimers. From various deletion derivatives, we have mapped the minus origin and the locus responsible for suppression of HMW multimer formation. Full activity of the minus origin and of the locus suppressing HMW formation was only observed on the native replicon, indicating a coupling to the plus strand synthesis.     

The Bacillus subtilis spore coat protein interaction network

Bacterial spores are surrounded by a morphologically complex, mechanically flexible protein coat, which protects the spore from toxic molecules. The interactions among the over 50 proteins that make up the coat remain poorly understood. We have used cell biological and protein biochemical approaches to identify novel coat proteins in Bacillus subtilis and describe the network of their interactions, in order to understand coat assembly and the molecular basis of its protective functions and mechanical properties. Our analysis characterizes the interactions between 32 coat proteins. This detailed view reveals a complex interaction network. A key feature of the network is the importance of a small subset of proteins that direct the assembly of most of the coat. From an analysis of the network topology, we propose a model in which low-affinity interactions are abundant in the coat and account, to a significant degree, for the coat's mechanical properties as well as structural variation between spores.