Mapping of the locus for Escherichia coli transfer ribonucleic acid nucleotidyltransferase

Substitution of the 3' terminal adenosine residue of transfer RNA in vivo

We have altered by site-directed mutagenesis the 3' terminal adenosine residue of a tRNA(Tyrsu3+) gene encoded on a single-copy plasmid and examined the consequences of these substitutions on suppressor activity in vivo. Our data show that mutant su3 genes containing 3'-CCC, -CCG, or -CCU termini instead of -CCA can be efficiently transcribed and processed in Escherichia coli to generate functional suppressor tRNAs. However, in contrast to normal tRNA genes, both tRNA nucleotidyltransferase and exoribonuclease activities are required to obtain suppression by the mutant tRNAs, indicating that removal of the incorrect 3' terminal residue and resynthesis of the normal -CCA terminus are occurring in this situation. In addition, a low level of suppressor activity and tRNA repair was found in cells devoid of tRNA nucleotidyltransferase, suggesting that an additional activity able to partially repair the 3' end of tRNA is present in E. coli. The use of mutant strains lacking one or several exoribonucleases revealed that the various RNAses have very different specificities for removal of incorrect 3' residues and that these differ greatly from their action on CCA-ending tRNA. These data show that the 3' terminal adenosine residue is necessary for tRNA function in vivo and that cells can compensate for its alteration by changes in the normal pathway of tRNA metabolism.

A possible role for the pcnB gene product of Escherichia coli in modulating RNA: RNA interactions

The sequence of the PcnB protein of Escherichia coli, a protein required for copy number maintenance of ColE1-related plasmids, was compared with the PIR sequence database. Strong local similarities to the sequence of the E. coli protein tRNA nucleotidyltransferase were found. Since a substrate of the latter protein, tRNA, structurally resembles the RNAs that control ColE1 copy number we believe that we may have identified a region in PcnB that interacts with these RNAs. Consistent with this idea is our observation that PcnB is required for the replication of R1, a plasmid whose replication is also regulated by a small RNA.

Inactivation of yeast nucleotidyl transferase and its effect on the integrity of the aminoacid acceptor end of transfer RNA

Yeast tRNA nucleotidyl transferase rapidly inactivates (half life c. 2 hr) upon nitrogen starvation of exponentially growing cells. The inactivation does not occur when glucose together with the nitrogen source is removed or when glucose is replaced by ethanol. The transferase activity reappears shortly after replenishment of the nitrogen source and this appearance of the enzymatic activity is blocked by cycloheximide, indicating the need for protein biosynthesis during the process. The nucleotidyl transferase activity is also very low in stationary phase yeast cells. A ten fold decrease in the transferase activity is not paralleled by loss of the integrity of the 3' end of the tRNA chains. It seems that there is a large excess of enzymatic activity over that needed to keep the tRNA chains complete. The observed lack of the 3' end of tRNAs from late stationary phase yeast cannot be accounted for by the observed drop in transferase activity in these cells.

RNase T is responsible for the end-turnover of tRNA in Escherichia coli

A mutant strain deficient in RNase T was isolated and used to study the role of this enzyme in Escherichia coli. Strains lacking as much as 70% of RNase T activity, alone or in combination with the absence of other RNases, display normal growth properties. However, in cca strains, which lack tRNA nucleotidyltransferase, RNase T-deficient derivatives accumulate lower levels of defective tRNA and grow at increased rates compared to their RNase T+ parents. Slow-growing cca strains revert to a faster-growing form that contains less defective tRNA but which is still cca. All of these strains have decreased levels of RNase T. These data indicate that RNase T is responsible for nucleotide removal during the tRNA end-turnover process and that the amount of defective tRNA in cells is determined by the relative levels of RNase T and tRNA nucleotidyltransferase.

Ribonuclease T: new exoribonuclease possibly involved in end-turnover of tRNA

Examination of double mutants lacking one of the exoribonucleases, RNase II, RNase D, RNase BN, or RNase R, and also devoid of tRNA nucleotidyltransferase has suggested that none of these RNases participates in the end-turnover of tRNA. This prompted a search for and identification of a new exoribonuclease, termed RNase T. RNase T could be detected in mutant Escherichia coli strains lacking as many as three of the known exoribonucleases, and it could be separated from each of the four previously described RNases. RNase T is optimally active at pH 8-9 and requires a divalent cation for activity. The enzyme is sensitive to ionic strengths greater than 50 mM and is rapidly inactivated by heating at 45 degrees C. Its preferred substrate is tRNA-C-C-[14C]A, with much less activity shown against tRNA-C-C. RNase T is an exoribonuclease that initiates attack at the 3' hydroxyl terminus of tRNA and releases AMP in a random mode of hydrolysis. The possible involvement of RNase T in end-turnover of tRNA and in RNA metabolism in general are discussed.

AppppA and related adenylylated nucleotides are synthesized as a consequence of oxidation stress

AppppA , ApppGpp , AppppG , ApppG , and ApppA rapidly accumulate to high levels in Salmonella typhimurium following exposure to a variety of oxidizing agents, but not to a variety of other stresses. Among the agents inducing these adenylylated nucleotides are 1-chloro-2,4-dinitrobenzene, diamide, hydrogen peroxide, t-butyl hydroperoxide, N-ethyl maleimide, iodoacetamide, cadmium chloride, and a variety of quinones. Some of these oxidizing agents cause preferential synthesis of specific adenylylated nucleotides, e.g., N-ethyl maleimide induces ApppA and menadione induces ApppGpp . Our data, as well as other evidence in the literature, strongly suggest that oxidation stress is coupled to adenylylated nucleotide synthesis by aminoacyl-tRNA synthetases. Although adenylylated nucleotides are made by tRNA synthetases in vitro, their synthesis in vivo is not a simple consequence of inhibition of synthetase activity. Compounds that inhibit normal charging by aminoacyl-tRNA synthetases do not result in the synthesis of adenylylated nucleotides, nor do mutations in tRNA synthetase structural genes or tRNA structural, modifying, or processing genes. We propose that the family of adenylylated nucleotides are alarmones signaling the onset of oxidation stress, and that particular ones may be alarmones for specific oxidative stresses, e.g., ApppGpp for oxidative damage to amino acid biosynthesis.

Genetic mapping of mutation in Escherichia coli leading to a temperature-sensitive RNase D

In order to determine the metabolic role of RNase D in Escherichia coli, we have attempted to isolate strains deficient in this enzyme. One strain containing a temperature-sensitive RNase D was found among a heavily mutagenized stock of strain temperature-sensitive for growth. Genetic mapping of the mutation responsible for the altered RNAse D enabled us to define the rnd locus, at 39.5-40.0 min on the E. coli map, which apparently specifies the RNase D structural gene. Using a Tn10 insertion near the rnd locus, we constructed isogenic strains containing RNase D and Rnase II mutations, alone or in combination. Although the original mutant isolate displayed temperature-sensitive growth. no growth phenotype was associated with the rnd mutation in wild type background, possibly because a substantial amount of RNase D remained in cells grown at 45 degrees C. However, elucidation of the map position of the rnd locus should prove useful for the isolation of other mutant strains with lower levels of RNase D.

Processing of procaryotic ribonucleic acid

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Purification and characterization of a mutant tRNA nucleotidyltransferase

tRNA nucleotidyltransferase has been extensively purified from a mutant strain of Escherichia coli which displays greatly decreased AMP incorporation, but normal CMP incorporation. The defect in AMP incorporation is retained throughout the purification of the mutant protein. The mutant protein behaves identically to the wild-type protein with regard to elution position on various chromatographic columns, and both have similar molecular weights of about 50000. The defect in the mutant protein is accentuated by the use of yeast tRNA rather than E. coli tRNA-C--C as substrate, by decreased pH, by increased ionic strength and by decreased divalent cation concentration. Substitution of MN2+ for Mg2+ greatly increases the relative activity of the mutant enzyme. In all these cases, CMP incorporation by the mutant enzyme remains the same as the wild-type enzyme. The Km values of the mutant enzyme for its tRNA and triphosphate substrates are unchanged, and the mutant protein is as stable as the wild type with respect to temperature inactivation. These results strongly suggest that the mutation is in the structural gene for tRNA nucleotidyltransferase, and that the mutation probably does not affect the overall structure of the mutant protein, but only a localized region near the AMP-incorporating site.

Temperature-sensitive Escherichia coli mutant producing a temperature-sensitive sigma subunit of DNA-dependent RNA polymerase

A gene affecting the sigma subunit of DNA-dependent RNA polymerase is tightly linked to dnaG at 66 min on the Escherichia coli chromosome. In order to create an easily selectable marker in this region, we inserted transposon-10, which carries a gene determining resistance to tetracycline (tet) near 66 min, and the order tolC-dnaG-sigma-tet was determined. We used frequency of contransduction with tet as a criterion to screen a collection of spontaneous temperature-sensitive Escherichia coli mutants that might affect the sigma subunit. One such mutant was found to map at the sigma locus. The sigma subunit isolated from this mutant is unstable at 46 degrees C in vitro and has an altered electrophoretic mobility. The temperature sensitivity of RNA synthesis in this mutant indicates that most transcription in E. coli is sigma dependent.

A physiological role for tRNA nucleotidyltransferase during bacteriophage infection

Bacteriophage infection of E. coli cells deficient in the enzyme tRNA nucleotidyltransferase (cca mutants) resulted in greatly decreased production of viable progeny phage compared to wild type cells. This decrease amounted to as much as 90% in the case of T-even bacteriophages, and 50-65% for T-odd bacteriophages. However, infection by the RNA phages, Qbeta and f2, was unaffected by the cca mutation. Examination of T4 infection of cca hosts indicated that phage development proceeded normally, that near-normal numbers of progeny particles were formed, but that most of these particles were non-viable. Possible functions for E. coli tRNA nucleotidyltransferase during bacteriophage infection are discussed.

Genetic map location of the Escherichia coli dnaG gene

The dnaG locus of Escherichia coli K-12 has been mapped at about 60 min on the genetic map by three-factor crosses using P1 transduction. In crosses selecting for dnaG+, the cotransduction frequency with the tolC marker is 15% and that with the uxaC marker is 49%. The gene order is tolC dnaG uxaC.

Three steps in conversion of large precursor RNA into serine and proline transfer RNAs

Bacteriophage T4 serine and proline transfer RNAs are derived from a common precursor RNA. This precusor RNA lacks -C-C-A sequences which could provide 3' termini for the mature transfer RNAs. We have deduced part of the pathway leading to the formation of the C-C-A sequences in the transfer RNAs by characterizing incompletely matured precursor molecules which accumulate during infection of mutant hosts that lack specific enzymes associated with transfer RNA metabolism. Maturation is initiated by the addition of -C-C-AOH to the 3' terminus of the precusor RNA through the combined actionof an unidentified nuclease and tRNA nucleotidyltransferase (EC 2.7.7.25). Precursor RNA molecules terminating in -C-C-AOH is serine transfer RNA and the second product is immature proline transfer RNA. The terminal steps leading to proline transfer RNA have not been fully delineated, but are known to involve the replacement of a -C-UOH sequence by -C-C-AOH.