Metabolism of pyrimidine bases and nucleosides in Bacillus subtilis.

In Bacillus subtilis, uracil (Ura), uridine (Urd), and deoxyuridine (dUrd) are metabolized through pathways similar to those of enteric bacteria. Ura is probably converted to uridine 5'-monophosphate by uridine 5'-monophosphate pyrophosphorylase. More than 95% of dUrd added to cultures is converted to Ura and deoxyribose-1-phosphate. Although dUrd kinase activity is detectable in vitro, this enzyme does not seem to play an important role in the metabolism of dUrd. The metabolism of cytosine (Cyt), cytidine (Cyd), and deoxycytidine (dCyd) in B. subtilis appears to be different from that in enteric bacteria. Cytosine cannot be used by Ura-requiring mutants as pyrimidine source. dCyd is deaminated by dCyd-Cyd deaminase or phosphorylated to dCyd nucleotides by dCyd kinase. Cyd is deaminated by dCyd-Cyd deaminase of phosphorylated by Cyd kinase. This Cyd kinase activity has never been reported for B. subtilis.     

Artificial and solar UV radiation induces strand breaks and cyclobutane pyrimidine dimers in Bacillus subtilis spore DNA

The loss of stratospheric ozone and the accompanying increase in solar UV flux have led to concerns regarding decreases in global microbial productivity. Central to understanding this process is determining the types and amounts of DNA damage in microbes caused by solar UV irradiation. While UV irradiation of dormant Bacillus subtilis endospores results mainly in formation of the "spore photoproduct" 5-thyminyl-5,6-dihydrothymine, genetic evidence indicates that an additional DNA photoproduct(s) may be formed in spores exposed to solar UV-B and UV-A radiation (Y. Xue and W. L. Nicholson, Appl. Environ. Microbiol. 62:2221-2227, 1996). We examined the occurrence of double-strand breaks, single-strand breaks, cyclobutane pyrimidine dimers, and apurinic-apyrimidinic sites in spore DNA under several UV irradiation conditions by using enzymatic probes and neutral or alkaline agarose gel electrophoresis. DNA from spores irradiated with artificial 254-nm UV-C radiation accumulated single-strand breaks, double-strand breaks, and cyclobutane pyrimidine dimers, while DNA from spores exposed to artificial UV-B radiation (wavelengths, 290 to 310 nm) accumulated only cyclobutane pyrimidine dimers. DNA from spores exposed to full-spectrum sunlight (UV-B and UV-A radiation) accumulated single-strand breaks, double-strand breaks, and cyclobutane pyrimidine dimers, whereas DNA from spores exposed to sunlight from which the UV-B component had been removed with a filter ("UV-A sunlight") accumulated only single-strand breaks and double-strand breaks. Apurinic-apyrimidinic sites were not detected in spore DNA under any of the irradiation conditions used. Our data indicate that there is a complex spectrum of UV photoproducts in DNA of bacterial spores exposed to solar UV irradiation in the environment.     

Coordinate synthesis of the enzymes of pyrimidine biosynthesis in Bacillus subtilis.

Strains of Bacillus subtilis that were resistant to repression of pyrimidine nucleotide biosynthetic enzymes were selected by isolating spontaneous uracil-tolerant derivatives of a uracil-sensitive strain, which lacks arginine-repressible carbamyl phosphate synthetase. The relative content of all six enzymes of uridylic acid biosynthesis de novo in these strains was in a constant ratio over a 10-fold range of derepression, which indicates that synthesis of these enzymes is coordinately regulated.     

Effect of a new pyrimidine analog on Bacillus subtilis growth.

2-Amino-5-ethoxycarbonylpyrimidine-4(3H)-one, a pyrimidine analog, inhibited growth of Bacillus subtilis. Data were obtained which suggested that the analog interfered with the methylation process. A mutant resistant to the inhibitor was isolated, and the mutation was mapped.     

Effect of purine and pyrimidine limitations on RNA synthesis in Bacillus subtilis.

The effects of varying the intracellular levels of GTP or UTP on the rate of RNA synthesis in Bacillus subtilis were studied. The levels of these nucleotides were manipulated by pyrimidine limitation in a pyr auxotroph, by purine limitation in a pur auxotroph, or by the addition of decoyinine , which specifically inhibits GMP synthesis. Decreased levels of UTP and GTP were accompanied by dramatically decreased synthesis and accumulation of stable RNAs (tRNA and rRNA), but mRNA synthesis was less affected. However, sporulation was initiated only when the intracellular level of GTP decreased.     

Structure of the Bacillus subtilis pyrimidine biosynthetic (pyr) gene cluster.

A 10.5-kilobase PstI endonuclease fragment encoding the entire Bacillus subtilis pyrimidine biosynthetic (pyr) gene cluster was cloned in Escherichia coli by transformation of a carB strain to uracil-independent growth. The cloned fragment also complemented E. coli pyrB, pyrC, pyrD, pyrE, and pyrF mutants. From the ability of subclones to complement E. coli pyr mutants, the gene order was deduced to be pyrBCADFE. The B. subtilis pyrB gene was shown to be expressed in E. coli, but synthesis of the enzyme was not repressible by the addition of uracil to the growth medium. The approximate molecular weights of the polypeptides encoded by B. subtilis pyrA, pyrB, pyrC, pyrD, pyrE, and pyrF were found to be 110,000, 36,000, 46,000, 34,000, 25,000, and 27,000, respectively.     

Excision of pyrimidine dimers in toluene-treated Escherichia coli.

Toluene-treated cells were used for examining excision of pyrimidine dimers in Escherichia coli strains W3110, DM845 (uvrA-), P3478 (polA-), and KS5064 (polAex1). Excision occurring in toluene-treated cells is rapid, adenosine 5'-triphosphate dependent, and requires the uvrA gene function. In strains lacking either the polymerizing or 5' leads to 3' exonucleolytic activity of deoxyribonucleic acid polymerase I, excision does occur. However, both in vivo and in vitro, the excision in such strains is initially slower than wild type.     

Repair of DNA-containing pyrimidine dimers

Ultraviolet light-induced pyrimidine dimers in DNA are recognized and repaired by a number of unique cellular surveillance systems. The most direct biochemical mechanism responding to this kind of genotoxicity involves direct photoreversal by flavin enzymes that specifically monomerize pyrimidine:pyrimidine dimers monophotonically in the presence of visible light. Incision reactions are catalyzed by a combined pyrimidine dimer DNA-glycosylase:apyrimidinic endonuclease found in some highly UV-resistant organisms. At a higher level of complexity, Escherichia coli has a uvr DNA repair system comprising the UvrA, UvrB, and UvrC proteins responsible for incision. There are several preincision steps governed by this pathway, which includes an ATP-dependent UvrA dimerization reaction required for UvrAB nucleoprotein formation. This complex formation driven by ATP binding is associated with localized topological unwinding of DNA. This same protein complex can catalyze an ATPase-dependent 5'----3'-directed strand displacement of D-loop DNA or short single strands annealed to a single-stranded circular or linear DNA. This putative translocational process is arrested when damaged sites are encountered. The complex is now primed for dual incision catalyzed by UvrC. The remainder of the repair process involves UvrD (helicase II) and DNA polymerase I for a coordinately controlled excision-resynthesis step accompanied by UvrABC turnover. Furthermore, it is proposed that levels of repair proteins can be regulated by proteolysis. UvrB is converted to truncated UvrB* by a stress-induced protease that also acts at similar sites on the E. coli Ada protein. Although UvrB* can bind with UvrA to DNA, it cannot participate in helicase or incision reactions. It is also a DNA-dependent ATPase.     

Photomonomerization of pyrimidine dimers by indoles and proteins.

Model systems for the study of photoreactivation have been developed that utilize a variety of indole derivatives. These systems can split uracil cis-syn cyclobutadipyrimidine, either free or in RNA, when irradiated at wave-lengths absorbed only by the indole moiety. The ability of indole compounds to split dimers is closely related to their electronic properties. Those of high electron-donor capacity such as indole, 3-methylindole, indole-3-acetic acid, 5-hydroxytryptophan and tryptophan are good photosensitizers, with efficacy in that order. Indoles with electron-withdrawing substituents such as indole-3-carboxylic acid, indole-3-aldehyde and oxindole are inactive in the monomerization reaction. These findings support the proposed mechanism that the photosensitized monomerization occurs as a result of electron transfer from the excited indole molecules to the pyrimidine bases.Proteins containing fully exposed tryptophan residues (chicken egg white lysozyme and bovine diisopropylphosphoryltrypsin) also cause the splitting of the ¹⁴C-labeled dimers under the same conditions. In the case of lysozyme the quantum yield of monomerization is similar to that of free tryptophan. Much of the monomerization ability of lysozyme was lost after the solvent-available tryptophan had been oxidized by treatment with N-bromosuccinimide. Bovine pancreatic ribonuclease A, a protein devoid of tryptophan, failed to exhibit photosensitized monomerization of uracil dimers. The biological implication of these reactions involving a protein with an exposed tryptophan residue is discussed.Although indoles are able to split the dimers in RNA, they fail to photo-reactivate u.v.-damaged TMV-RNA. Indole-3-acetic acid, 3-methylindole and 5-hydroxytryptophan rapidly inactivate viral RNA when irradiated at 313 nm, possibly because of side reactions.     

Genetic transformation and transfection ofBacillus subtilis spheroplasts

Genetic transformation and transfection of lysozyme-treatedBacillus subtilis spheroplasts 168M ind occurs only if they are stabilized with 0.5m phosphate buffer and not if they are stabilized with 0.5m sucrose. Spheroplasts prepared from maximally competent cells give maximum transformation and transfection results. The results indicate that the DNA receptors must also be intact in the spheroplasts.     

Recognition in action: flipping pyrimidine dimers

DNA bases are normally sheltered within a double helix, but enzymes that modify and repair DNA gain access by flipping individual bases out of the double helix.     

Aminopeptidases of Bacillus subtilis.

Three enzymes with L- and one enzyme with D-aminopeptidase (EC 3.4.11; alpha-aminoacyl peptide hydrolase) activity have been separated from each other and partially purified from Bacillus subtilis 168 W.T., distinguished with respect to their molecular weights and catalytic properties, and studied in relation to the physiology of this bacterium. One L-aminopeptidase, designated aminopeptidase I, has a molecular weight of 210,000 +/- 20,000, is produced early in growth, and hydrolyzes L-alanyl-beta-naphthylamide most rapidly. Another, designated aminopeptidase II, molecular weight 67,000 +/- 10,000, is also produced early in growth and hydrolyzes L-lysyl-beta-naphthylamide most rapidly. A third, aminopeptidase III, molecular weight 228,000 +/- 20,000, is produced predominantly in early stationary phase and most efficiently utilizes L-alpha-aspartyl-beta-naphthylamide as substrate. The synthesis of aminopeptidase III in early stationary phase suggests that selective catabolism of peptides occurs at this time, perhaps related to the cessation of growth or the onset of early sporulation-associated events. A D-aminopeptidase which hydrolyzes the carboxyl-blocked dipeptide D-alanyl-D-alanyl-beta-naphthylamide (as well as D-alanyl-beta-naphthylamide and D-alanyl-D-alanyl-D-alanine) has also been identified, separated from aminopeptidase II, and purified 170-fold. D-Aminopeptidase, molecular weight 220,000 +/- 20,000, is localized predominantly in the cell wall and periplasm of the organism. This evidence and the variation of the activity during the growth cycle suggest an important function in cell wall or peptide antibiotic metabolism.