Properties of a Bacillus subtilis polynucleotide phosphorylase deletion strain.

The pnpA gene of Bacillus subtilis, which codes for polynucleotide phosphorylase (PNPase), has been cloned and employed in the construction of pnpA deletion mutants. Growth defects of both B. subtilis and Escherichia coli PNPase-deficient strains were complemented with the cloned pnpA gene. RNA decay characteristics of the B. subtilis pnpA mutant were studied, including the in vivo decay of bulk mRNA and the in vitro decay of either poly(A) or total cellular RNA. The results showed that mRNA decay in the pnpA mutant is accomplished despite the absence of the major, Pi-dependent RNA decay activity of PNPase. In vitro experiments suggested that a previously identified, Mn2+ -dependent hydrolytic activity was important for decay in the pnpA mutant. In addition to a cold-sensitive-growth phenotype, the pnpA deletion mutant was found to be sensitive to growth in the presence of tetracycline, and this was due to an increased intracellular accumulation of the drug. The pnpA deletion strain also exhibited multiseptate, filamentous growth. It is hypothesized that defective processing of specific RNAs in the pnpA mutant results in these phenotypes.     

Bacillus subtilis polynucleotide phosphorylase 3′-to-5′ DNase activity is involved in DNA repair

In the presence of Mn²⁺, an activity in a preparation of purified Bacillus subtilis RecN degrades single-stranded (ss) DNA with a 3′ → 5′ polarity. This activity is not associated with RecN itself, because RecN purified from cells lacking polynucleotide phosphorylase (PNPase) does not show the exonuclease activity. We show here that, in the presence of Mn²⁺ and low-level inorganic phosphate (P_i), PNPase degrades ssDNA. The limited end-processing of DNA is regulated by ATP and is inactive in the presence of Mg²⁺ or high-level P_i. In contrast, the RNase activity of PNPase requires Mg²⁺ and P_i, suggesting that PNPase degradation of RNA and ssDNA occur by mutually exclusive mechanisms. A null pnpA mutation (ΔpnpA) is not epistatic with ΔrecA, but is epistatic with ΔrecN and Δku, which by themselves are non-epistatic. The addA5, ΔrecO, ΔrecQ (ΔrecJ), ΔrecU and ΔrecG mutations (representative of different epistatic groups), in the context of ΔpnpA, demonstrate gain- or loss-of-function by inactivation of repair-by-recombination, depending on acute or chronic exposure to the damaging agent and the nature of the DNA lesion. Our data suggest that PNPase is involved in various nucleic acid metabolic pathways, and its limited ssDNA exonuclease activity plays an important role in RecA-dependent and RecA-independent repair pathways.     

Cyclic di-GMP activation of polynucleotide phosphorylase signal-dependent RNA processing

The second messenger cyclic diguanylic acid (c-di-GMP) is implicated in key lifestyle decisions of bacteria, including biofilm formation and changes in motility and virulence. Some challenges in deciphering the physiological roles of c-di-GMP are the limited knowledge about the cellular targets of c-di-GMP, the signals that control its levels, and the proportion of free cellular c-di-GMP, if any. Here, we identify the target and the regulatory signal for a c-di-GMP-responsive Escherichia coli ribonucleoprotein complex. We show that a direct c-di-GMP target in E. coli is polynucleotide phosphorylase (PNPase), an important enzyme in RNA metabolism that serves as a 3′ polyribonucleotide polymerase or a 3′-to-5′ exoribonuclease. We further show that a complex of polynucleotide phosphorylase with the direct oxygen sensors DosC and DosP can perform oxygen-dependent RNA processing. We conclude that c-di-GMP can mediate signal-dependent RNA processing and that macromolecular complexes can compartmentalize c-di-GMP signaling.     

In vitro transactivation of Bacillus subtilis RNase P RNA

We have partially characterised an alpha4-fucosyltransferase (alpha4-FucT) from Vaccinium myrtillus, which catalysed the biosynthesis of the Lewis(a) adhesion determinant. The enzyme was stable up to 50 degrees C. The optimum pH was 7.0, both in the presence and in the absence of Mn(2+). The enzyme was inhibited by Mn(2+) and Co(2+), and showed resistance towards inhibition with N-ethylmaleimide. It transferred fucose to N-acetylglucosamine in the type I Galbeta3GlcNAc motif from oligosaccharides linked to a hydrophobic tail and glycoproteins (containing the type I motif). Sialylated oligosaccharides containing the type II Galbeta4GlcNAc motif were not acceptors. The catalytic mechanism of the plant alpha4-FucT possibly involves a His residue, and it must have arisen by convergent evolution relative to its mammalian counterparts.     

Isolation and characterization of a polynucleotide phosphorylase from Bacillus amyloliquefaciens.

Bacillus amyloliquefaciens BaM-2 produces large amounts of extracellular enzymes, and the synthesis of these proteins appears to be dependent upon abnormal ribonucleic acid metabolism. A polynucleotide phosphorylase (nucleoside diphosphate:polynucleotide nucleotidyl transferase) was identified, purified, and characterized from this strain. The purification scheme involved cell disruption, phase partitioning, differential (NH4)2SO4 solubilities, agarose gel filtration, and diethylaminoethyl-Sephadex chromatography. The purified enzyme demonstrated the reactions characteristic of polynucleotide phosphorylase: polymerization, phosphorolysis, and inorganic phosphate exchange with the beta-phosphate of a nucleotide diphosphate. The enzyme was apparently primer independent and required a divalent cation. The reactions for the synthesis of the homopolyribonucleotides, (A)n and (G)n, were optimized with respect to pH and divalent cation concentration. The enzyme is sensitive to inhibition by phosphate ion and heparin and is partially inhibited by rifamycin SV and synthetic polynucleotides.     

Mechanism of polynucleotide phosphorylase

The de novo polymerization of RNA initiated by polynucleotide phosphorylase from nucleoside diphosphates was examined. End group analysis performed under conditions designed to specifically end label the polymer revealed no evidence for a 5'-pyrophosphate-terminated polymer. However, we observed preferential incorporation of the ADP alpha S(RP) diastereomer into the 5' end (Marlier & Benkovic, 1982) in chain initiation, suggesting that the enzyme incorporates a nucleoside diphosphate specifically into the 5' end of the product, with subsequent enzymatic removal of the polyphosphate linkage. No evidence could be obtained for a covalent adduct between the enzyme and the 5' end of the polymer chain, despite the high processivity of the polymerization reaction. Gel electrophoretic analysis showed the polymer to be highly disperse, varying from 1 to 30 kb. Scanning transmission electron microscopy supported this product analysis and further suggested that (i) each subunit can produce an RNA polymer and (ii) both 5' and 3' ends of the RNA can be bound simultaneously to the same or differing enzyme molecules.     

In vivo and in vitro chemotactic methylation in Bacillus subtilis

Two doublets of Bacillus subtilis membrane proteins with molecular weights of 69,000 and 71,000 and of 30,000 and 30,800, were labeled by C3H3 transfer in the absence of protein synthesis. In addition, there was intense methylation of several low-molecular-weight substances. Both doublets were missing in a chemotaxis mutant. The equivalent proteins in Escherichia coli and Salmonella typhimurium are believed to be the methyl-accepting chemotaxis proteins. The higher-molecular-weight doublet bands were increased in degree of methylation upon addition of attractant to the bacteria. A methyltransferase from B. subtilis that methylates the wild-type membrane significantly better than the mutant membrane, using S-adenosylmethionine, has been partly purified. The methylated product was alkali labile and is probably a gamma-glutamyl methyl ester, as in E. coli and S. typhimurium. Ca2+ ion inhibited the methyltransferase, with a Ki of about 80 nM. Analysis of the in vitro methylation product showed labeling of the 69,000-dalton methyl-accepting chemotaxis protein and a low-molecular-weight protein, using wild-type membrane. Labeling of the low-molecular-weight protein but not of the 69,000 dalton protein was observed when the mutant membrane was used. The chemotaxis mutant tumbled much longer than the wild type when diluted away from attractant.     

In vitro characterization of the Bacillus subtilis protein tyrosine phosphatase YwqE

Both gram-negative and gram-positive bacteria possess protein tyrosine phosphatases (PTPs) with a catalytic Cys residue. In addition, many gram-positive bacteria have acquired a new family of PTPs, whose first characterized member was CpsB from Streptococcus pneumoniae. Bacillus subtilis contains one such CpsB-like PTP, YwqE, in addition to two class II Cys-based PTPs, YwlE and YfkJ. The substrates for both YwlE and YfkJ are presently unknown, while YwqE was shown to dephosphorylate two phosphotyrosine-containing proteins implicated in UDP-glucuronate biosynthesis, YwqD and YwqF. In this study, we characterize YwqE, compare the activities of the three B. subtilis PTPs (YwqE, YwlE, and YfkJ), and demonstrate that the two B. subtilis class II PTPs do not dephosphorylate the physiological substrates of YwqE.     

De Novo synthesis of DNA-like molecules by polynucleotide phosphorylase in vitro

In the presence of Mg²⁺ ions, polynucleotide phosphorylase (PNPase, EC 2.7.7.8) is known to synthesize RNA-like polymers using ribonucleoside-5′-diphosphate (NDP) substrates but to be unable to utilize deoxyribonucleoside substrates. Our experiments show that when MgCl₂ is replaced by FeCl₃, PNPase becomes able to synthesize deoxyheteropolymers using deoxyribonucleoside-5′-diphosphates (dNDPs). The deoxyheteropolymer formed from the four dNDPs is degraded by pancreatic DNase, but not by RNase, and is readily used as a template by DNA-dependent DNA polymerase. Synthesis of this DNA-like polymer is accomplished de novo without the help of any primer or preexisting template. What is more, dA/dG and dC/dT ratios of polymers synthesized by different bacterial PNPases closely match ratios found in DNA of the bacterial species the enzyme came from.     

Animal tissue polynucleotide phosphorylase]

Localization, physico-chemical and catalytic properties and possible biological functions of polynucleotide phosphorylase (PNPase) from animal tissues are discussed. In animal tissue cells PNPase has multiple localization; the major amount of the enzyme is localized in the endoplasmic reticulum ribosomes. In the nuclei PNPase, similar to other endo- and exo-RNAses participates in the processing of precursor molecules of mature forms of RNA, whereas in the cytoplasm it is involved in the destruction of polyribosomes in the polyribosomes of rapidly growing tissues the activity of PNPase is extremely decreased. The mechanisms regulating the PNPase activity in rapidly growing tissues are discussed.     

In vitro packaging of DNA of the Bacillus subtilis bacteriophage SPP1

In vitro packaging of bacteriophage SPP1 DNA into procapsids is described and the requirements of this process were determined. Combination of proheads with an extract supplying terminase, DNA and phage tails yielded up to 10(7 )viable phages per milliliter of in vitro reaction under optimized conditions. The presence of neutral polymers and polyamines had a concentration and type dependent effect in the packaging reaction. The terminase donor extract lost rapidly activity at 30 degrees C in contrast to the stability of the prohead donor extract. Maturation to infective virions was observed using both procapsids assembled in SPP1 infected cells and procapsid-like structures assembled in Escherichia coli that overexpressed the SPP1 prohead gene clusters. Neither a majority of aberrant capsid-related structures present in the latter material nor procapsids lacking the portal protein inhibited DNA packaging. Addition of purified portal protein reduced DNA packaging activity in vitro only at concentrations 20-fold higher than those found in the SPP1 infected cell. The SPP1 DNA packaged in vitro originated exclusively from the terminase donor extract. This packaging selectivity was not observed in vivo during mixed infections. The data are compatible with a model for processive headful DNA packaging in which terminase and DNA co-produced in the same cell are tightly associated and can effectively discriminate the portal vertex of DNA packaging-proficient proheads from aberrant structures, from portal-less procapsids, and from isolated portal protein.