A third DNA-dependent ATPase from Bacillus cereus free of ATP-dependent DNase activity

The purification of ATP-dependent DNase from Bacillus cereus led to the isolation and characterization of a third DNA-dependent ATPase. The enzyme called ATPase III has been purified free of nuclease activity. None of the expected ATPases proved to be identical with ATP-dependent DNase-DNA-dependent ATPase. Separation of ATPase I, II and III and a DNase specific for single-stranded DNA from the same source excludes the possibility of ATP-dependent DNase being the action of a single enzyme molecule.     

Purification and characterization of a DNA-dependent ATPase from Bacillus cereus

A DNA-dependent ATPase (molecular weight 71 000) free of nuclease activity has been purified from Bacillus cereus. The enzyme shows similar characteristics as the enzyme isolated from Escherichia coli and Bacillus subtilis. Heat denatured DNA stimulates the rate of ATP hydrolysis to ADP and Pi to an extent about tenfold higher than the native DNA. Double stranded DNA without single stranded regions is not a suitable cofactor for the enzyme. The ATPase is inhibited by adenosine 5'-(beta, gamma-imino)-diphosphate, while another ATP analogue, adenosine 5'-(beta, gamma-methylene)-diphosphate has no effect on ATPase activity. KM for ATP is 0.38 mM, the apparent KM for nucleotide equivalent DNA is 1.2 microM. Evidence of the unwinding function of the enzyme is presented.     

A DNA-dependent ATPase of calf-thymus.

A DNA-dependent ATPase has been purified from calf thymus. The enzyme hydrolyses ATP and dATP in the presence of heat-denatured DNA. It does not hydrolyse the corresponding nucleoside triphosphates of guanine, uridine and cytosine. The Km values for ATP and dATP are both 0.62 mM. The enzyme requires magnesium or manganese ions. Its sedimentation coefficient is about 4.4 S. The catalytic activity is inhibited by N-ethylmaleimide but is not sensitive to novobiocin and nalidixic acid which are potent inhibitors of bacterial DNA gyrase. In some cases, during purification, chromatographically distinct additional DNA-dependent ATPase activities were detected. Limited proteolysis or covalent modification of the enzyme in the tissues, or during the first steps of its extraction, are probably responsible for the appearance of these chromatographically distinct forms.     

Enzyme-catalyzed DNA unwinding. A DNA-dependent ATPase from E. coli.

We have isolated a new DNA-dependent ATPase from E. coli. The enzyme has been purified to greater than 90% purity. It appears to be composed of two identical polypeptide chains of molecular weight 20,000. The enzyme catalyzed the hydrolysis of ATP in the presence, but not in the absence, of single-stranded DNA. Double-stranded DNA is not a cofactor. The products of hydrolysis are ADP and Pi. The enzyme also catalyzed strand separation of duplex DNA in the presence of ATP and E. coli DNA binding protein. Two E. coli proteins capable of promoting strand separation have been reported previously and have been termed helicase I and II (Abdel-Monem, M., and Hoffmann-Berling, H. (1977) Eur. J. Biochem. 79, 33-38). Accordingly, this protein is named helicase III.     

Superhelical DNA-dependent ATPase from calf thymus

Two physically and catalytically distinct DNA-dependent ATPases were isolated from a purified preparation of calf thymus poly(ADP-ribose) polymerase. A unique feature of these two ATPases was the high stimulation by supercoiled DNA. Other nucleic acids (including denatured DNA and ribosomal RNA) and certain polynucleotides differentially stimulated the two enzymes. We have not detected any other DNA-related activity associated with these ATPases.     

Properties of a DNA-dependent ATPase from rat mitochondria.

A DNA-dependent ATPase has been highly purified from rat liver mitochondria and characterized. The enzyme catalyzes the hydrolysis of ATP or dATP in the presence of single-stranded DNA cofactor and a divalent cation. The Km values for ATP and dATP are 0.15 mM and 0.35 mM, respectively. The enzyme activity is highly sensitive to N-ethylmaleimide. The sedimentation coefficient of the enzyme is 8.3 S in a glycerol gradient. From this and data on Sephadex G-200 gel filtration, the molecular weight of the native enzyme was calculated to be about 190,000. All the natural single-stranded DNAs tested were equally effective for the ATPase activity, but synthetic deoxyhomopolymer poly(dC) was found to be more effective than natural single-stranded DNAs. Synthetic and natural RNAs had no effect on the activity.     

DNA-dependent ATPases in Bacillus subtilis mutants and in competent cells

Three DNA-dependent ATPases (gamma phosphohydrolases) can be isolated from Bacillus subtilis cells. We studied these enzymes in a number of mutants deficient in recombination or repair functions (rec, uvr) and in competent cells. The recA mutant studied had lower ATPase II activity, while competent cells had higher ATPase I activity, in comparison with the parental strain not brought to competence.     

Membrane ATPase of Bacillus subtilis. I. Purification and properties.

The membrane ATPase (EC 3.6.1.3) of Bacillus subtilis can be solubilized by a shock-wash process. Two procedures for purifying the solubilized enzyme are reported. A protease inhibitor, phenylmethane sulfonylfluoride, was introduced in the solubilization and purification step. The resultant ATPase purified by density gradient centrifugation has a molecular weight of 315 000, an s20,w of 13,4 and an amino acid composition very similar to bacterial ATPases already studied. After exposure to polyacrylamide gel electrophoresis in presence of sodium dodecyl sulphate (SDS), or 8 M urea or SDS-urea, the purified ATPase can be dissociated in two non-identical subunits of molecular weights 59 000 (alpha) and 57 000 (beta) with different charges. Kinetic studies showed that Ca2+ or Zn2+ are required for ATPase activity, although Mg2+ was uneffective. At optimal Ca2+ concentration, the Mg2+ has an inhibitory effect. The Km for ATP is 1.3 mM. Inhibitors of the oxydative phosphorylation, of the mitochondrial ATPase and of the (Na+ + K+)-ATPase are studied.     

A Multitask ATPase Serving Different ABC-Type Sugar Importers in Bacillus subtilis

Bacillus subtilis is able to utilize arabinopolysaccharides derived from plant biomass. Here, by combining genetic and physiological analyses we characterize the AraNPQ importer and identify primary and secondary transporters of B. subtilis involved in the uptake of arabinosaccharides. We show that the ABC-type importer AraNPQ is involved in the uptake of α-1,5-arabinooligosaccharides, at least up to four l-arabinosyl units. Although this system is the key transporter for α-1,5-arabinotriose and α-1,5-arabinotetraose, the results indicate that α-1,5-arabinobiose also is translocated by the secondary transporter AraE. This broad-specificity proton symporter is the major transporter for arabinose and also is accountable for the uptake of xylose and galactose. In addition, MsmX is shown to be the ATPase that energizes the incomplete AraNPQ importer. Furthermore, the results suggest the existence of at least one more unidentified MsmX-dependent ABC importer responsible for the uptake of nonlinear α-1,2- and α-1,3-arabinooligosaccharides. This study assigns MsmX as a multipurpose B. subtilis ATPase required to energize different saccharide transporters, the arabinooligosaccharide-specific AraNPQ-MsmX system, a putative MsmX-dependent ABC transporter specific for nonlinear arabinooligosaccharides, and the previously characterized maltodextrin-specific MdxEFG-MsmX system.Transport across biological membranes is a fundamental process for life and is accomplished by channels, primary and secondary transporters, and group translocators (19). ATP-binding cassette (ABC) transporters constitute one of the largest families of translocation facilitators and are distributed across all domains of life. Although they are involved in a variety of distinct processes, such as nutrient uptake, resistance to antibiotics and other drugs, lipid trafficking, cell division, sporulation, immune response, and pathogenesis, all ABC transporters, regardless of the polarity of transport (exporters and importers), share a structure and a general mechanism (reviewed in references 3 and 8). Their organization comprises two transmembrane domains (TMDs) coupled to two cytosolic nucleotide-binding domains (NBDs), or ATP-binding cassettes, responsible for ATP binding and hydrolysis-driven conformational changes.The majority of the eukaryotic ABC transporters are exporters facilitating translocation from the cytoplasm. In contrast, prokaryotic ABC permeases are involved mainly in the import of nutrients, vitamins, and trace elements (3, 6, 8). Canonical bacterial ABC importers are dependent predominantly on high-affinity substrate-binding proteins (BPDs) that capture the substrate and deliver it to the transporter. The canonical maltose/maltodextrin importer MalEFGK₂ of Escherichia coli/Salmonella enterica serovar Typhimurium (5) is one of the most-characterized members of this superfamily of translocation facilitators, serving as model for ABC importers in general (14, 15). In Gram-negative bacteria, BPDs are proteins located in the periplasmic space between the inner and outer membranes. In Gram-positive organisms, which are devoid of this type of cellular compartment, BPDs often are lipoproteins that are anchored to the extracellular side of the cytoplasmic membrane via its N-terminal domain (3 and 8 and references therein).In nature, the major source of carbohydrates for microorganisms to utilize is plant biomass. Thus, in their natural habitat, such as soil, aquatic environments, or animal digestive tracts, bacteria secrete a vast number of polysaccharolytic enzymes for the degradation of plant-derived polysaccharides. The resulting mono-, di-, and oligosaccharides enter the cell mainly through specific ABC transporters. The number of well-characterized ABC transporters devoted to the uptake of products resulting from the degradation of hemicellulose is very scarce (6), and in Gram-positive organisms only two systems, BxlEFG of Streptomyces thermoviolaceus (31) and XynEFG (29) of Geobacillus staerothermophilus, both dedicated to the transport of xylodextrins, have been characterized in detail.An in silico analysis of the Bacillus subtilis genome estimated the existence of at least 78 ABC transporters based on the identification of 86 NBDs in 78 proteins, 103 MSD proteins, and 37 BPD proteins, which account for about 5% of the protein-coding genes of this model organism (17). At least 10 ABC systems are predicted to be involved in the uptake of sugars (20). One of these ABC importers, AraNPQ, is clustered together with genes encoding enzymes involved in arabinose catabolism and the degradation of arabinooligosaccharides in a large operon, araABDLMNPQ-abfA (23). AraN is the BPD, and AraP and AraQ are the TMDs. This transporter, which lacks the NBD protein partner, was proposed to be involved in the uptake of arabinose oligomers mainly by genomic context and in silico analysis (10, 11, 23).Here, by combining genetic and physiological analyses, we characterize the AraNPQ importer and identify primary and secondary transporters of B. subtilis involved in the uptake of arabinosaccharides. Furthermore, this study assigns the role of MsmX as a multipurpose B. subtilis ATPase required to energize different saccharide transporters.     

Teichoicase from Bacillus subtilis Marburg.

The properties of a teichoic acid degrading enzyme (teichoicase) isolated from Bacillus subtilis Marburg are described. The purified enzyme showed phosphodiesterase activity but not phosphomonoesterase activity, and it had an absolute substrate specificity for alpha-glucosylated glycerol teichoic acid, the endogenous cell wall teichoic acid of the enzyme-producing cell. The substrate was degraded by an exo-mechanism yielding the monomer alpha-D-glucose 1 leads to 2 (sn)glycero-3-phosphate. When B. subtilis Marburg was grown in a rich medium, enzyme activity was detected in extracts from sporulating cells. Teichoicase activity was present in a mutant blocked in stage II of the sporulation process but was absent in a mutant blocked in stage O. It was concluded that teichoicase is active on enzyme-producing cells since the reaction product could be detected in their culture supernatant. Attempts to demonstrate analogous enzyme activity in other Bacillus strains failed. The enzyme could be used for the rapid detection of alpha-glucosylated glycerol teichoic acid and for the controlled alteration of native bacterial cell surfaces exhibiting the appropriate structure.     

A manganese-stimulated endonuclease from Bacillus subtilis

An endonuclease activity has been identified in extracts of $\text{Bacillus subtilis}$. This activity is stimulated by Mn⁺⁺ or Ca⁺⁺ ions but not by Mg⁺⁺ ions. The enzyme catalyzes the breakdown of native DNA of high molecular weight to fragments of molecular weights ranging from 3 × 10⁶ to 20 × 10⁶. A variety of DNA's from sources such as $\text{B. subtilis, Salmonella}$ and T7 phage are attacked. About 61% of the activity of the cells is released into the medium during protoplast formation under conditions where 98% of the glucose 6-P dehydrogenase activity is retained by the cells.     

Purification and characterization of a DNA-dependent ATPase from Escherichia coli.

A DNA-dependent ATPase has been isolated and purified from an Escherichia coli cell-free extract. The ATPase has the following characteristics: preferential dependence on single-stranded DNA, specificity for ATP hydrolysis, Km value of 1.4 X 10-4 M for ATP, and molecular weight of approximately 69,000. The ATPase can be shown to bind to single stranded DNA. The resemblance between this ATPase and that isolated from vaccinia cores is discussed.     

Purification and characterization of DNA-dependent ATPase II from Escherichia coli.

A new DNA-dependent ATPase was isolated and purified from soluble extracts of Escherichia coli. This enzyme, called ATPase II, has a molecular weight of 86,000 and exists in a monomeric state. It degrades ATP (or dATP) to ADP (or dADP) and Pi in the presence of magnesium and requires a double-stranded polynucleotide as cofactor. A correlation between the efficiency as cofactor and the melting point of the polynucleotide has been found; the lower the melting temperature, the higher the stimulation of ATPase II. The enzyme binds to single-stranded DNA and poly[d(A-T)] copolymer, but not to the double-stranded circular DNA (Form I) of simian virus 40.     

Zinc is associated with the beta subunit of DNA-dependent RNA polymerase of Bacillus subtilis.

The Bacillus subtilis DNA-dependent RNA polymerase holoenzyme and core enzyme each contain approximately two atoms of zinc per molecule. When the dissociated subunits of the enzyme are passed through a blue dextran-Sepharose affinity column, only the beta subunit binds to the column. The total zinc content of the enzyme is tightly bound to the beta subunit. Dialysis studies suggest that the two zinc ions differ in the strength of their association with the beta subunit. The presence of zinc in beta is consistent with several other lines of evidence which indicate that this subunit is dirrectly involved in phosphodiester bond formation. The blue dextran-Sepharose column procedure should be useful in future studies of the dissociation and reassociation of the enzyme since the method is rapid and provides excellent recovery of the beta subunit as well as the alpha and beta' subunits of the RNA polymerase.     

A periplasm in Bacillus subtilis.

The possibility of there being a periplasm in Bacillus subtilis, in the distinct cell compartment bounded by the cytoplasmic membrane and the thick cell wall, has been investigated quantitatively and qualitatively. Cytoplasmic, membrane, and protoplast supernatant fractions were obtained from protoplasts which were prepared isotonically from cells grown under phosphate limitation. The contents of the protoplast supernatant fraction represent an operational definition of the periplasm. In addition, this cell fraction includes cell wall-bound proteins, exoproteins in transit, and contaminating cytoplasmic proteins arising through leakage from, or lysis of a fraction of, protoplasts. The latter, measured by assay of enzyme markers and by radiolabeled RNA and protein, was found to represent 7.6% of total cell protein, yielding a mean of 9.8% +/- 4.8% for B. subtilis 168 protein considered periplasmic. Qualitatively, after subjection of all cell fractions to polyacrylamide gel electrophoresis, RNase and DNase, zymographs revealed that (i) each cell fraction had a unique profile of nucleases and (ii) multiple species and a major fraction of both nucleases were concentrated in the periplasm. We conclude that the operationally defined periplasmic fraction corresponds closely, both quantitatively and qualitatively, to the contents of the periplasm of Escherichia coli. We discuss evidence that the maintenance of the components of this surface compartment in B. subtilis is compatible with the thick negatively charged cell wall acting as an external permeability barrier.     

Secretion of streptavidin from Bacillus subtilis.

Streptavidin is an extracellular tetrameric protein produced by Streptomyces avidinii. A series of hybrid gene fusions consisting of Bacillus signal peptide coding regions fused to the mature streptavidin sequence were constructed. B. subtilis strains harboring these plasmids accumulate a tetrameric streptavidin in the growth medium. The properties of the streptavidin produced by B. subtilis are similar to those of the streptavidin produced by S. avidinii. B. subtilis strains carrying the various fusions can be grown to a high cell density in a biotin-free medium. Thus, B. subtilis represents an alternate host system for the production of streptavidin.