Cloning, sequencing, and species relatedness of the Escherichia coli cca gene encoding the enzyme tRNA nucleotidyltransferase

The Escherichia coli cca gene which encodes the enzyme tRNA nucleotidyltransferase has been cloned by taking advantage of its proximity to the previously cloned dnaG locus. A series of recombinant bacteriophages, spanning the chromosomal region between the dnaG and cca genes at 66 min on the E. coli linkage map, were isolated from a lambda Charon 28 partial Sau3A E. coli DNA library using recombinant plasmids containing regions between dnaG and cca as probes. Two of the recombinant phage isolates, lambda c1 and lambda c4, contained the cca gene. A BamHI fragment from lambda c1 was subcloned into pBR328, and cells containing this recombinant plasmid, pRH9, expressed tRNA nucleotidyltransferase activity at about 10-fold higher level than the wild type control. The cca gene was further localized to a 1.4-kilobase stretch of DNA by Bal31 deletion analysis. The nucleotide sequence of the cca gene was determined by the dideoxy method, and revealed an open reading frame extending for a total of 412 codons from an initiator GTG codon that would encode a protein of about 47,000 daltons. Southern analysis using genomic blots demonstrated that the cca gene is present as a single copy on the E. coli chromosome and that there is no homology on the DNA level between the E. coli cca gene, and the corresponding gene in the Bacillus subtilis, Saccharomyces cerevisiae, Petunia hybrida, or Homo sapiens genomes. Homology was found only with DNA from the closely related species, Salmonella typhimurium. These studies have also allowed exact placement of the cca gene on the E. coli genetic map, and have shown that it is transcribed in a clockwise direction.     

A mutation in Escherichia coli tRNA nucleotidyltransferase that affects only AMP incorporation is in a sequence often associated with nucleotide-binding proteins

Escherichia coli strain 5C15 contains a mutation in the cca gene that decreases AMP incorporation by tRNA nucleotidyltransferase while leaving CMP incorporation unaffected. Earlier studies of the purified mutant enzyme suggested that the mutation was localized to the AMP-incorporating site. In order to analyze this mutation in more detail, the cca gene from strain 5C15 was cloned into plasmid pUC8. Analysis of tRNA nucleotidyltransferase activity in extracts of a strain transformed with this plasmid demonstrated an elevated level of CMP incorporation, but low AMP incorporation, as expected from the properties of the original mutant. Sequence analysis of the mutant cca gene revealed only a single G to A point mutation leading to a glycine to aspartic acid substitution at position 70 of the peptide chain. The amino acid change was localized to one of two Gly-X-Gly-X-X-Gly sequences present in the protein. This sequence has been identified previously near the nucleotide-binding domain of various proteins, but it has not been noted in enzymes that incorporate nucleotide residues. However, other sequences often associated with ATP-binding domains are not found in tRNA nucleotidyltransferase. The implications of these findings for our understanding of nucleotide-binding domains are discussed.     

tRNA nucleotidyltransferase is not essential for Escherichia coli viability.

The role of tRNA nucleotidyltransferase in Escherichia coli has been uncertain because all tRNA genes studied in this organism already encode the -C-C-A sequence. Examination of a cca mutant, originally thought to contain 1-2% enzyme activity, indicated that it actually produces an inactive fragment of 40 kd compared to 47 kd for the wild-type enzyme due to a nonsense mutation in its cca gene. To confirm that the residual activity in extracts of this strain is due to another enzyme, and that tRNA nucleotidyltransferase is non-essential, we have interrupted the cca gene in vitro, and transferred this mutant gene to a variety of strains. In all cases mutant strains are viable, although as much as 15% of the tRNA population contains defective 3' termini, and no tRNA nucleotidyltransferase is detectable. Mutant strains grow slowly, but can be restored to more normal growth by a relA mutation or by a decrease in RNase T activity. In the latter case the amount of defective tRNA decreases dramatically. These findings indicate that tRNA nucleotidyltransferase is not essential for E. coli viability, and therefore, that all essential tRNA genes in this organism encode the -C-C-A sequence.     

Overproduction and crystallization of FokI restriction endonuclease.

To overproduce FokI endonuclease (R.FokI) in an Escherichia coli system, the coding region of R.FokI predicted from the nucleotide sequence was generated from the FokI operon and joined to the tac promoter of an expression vector, pKK223-3. By introduction of the plasmid into E. coli UT481 cells expressing the FokI methylase gene, the R.FokI activity was overproduced about 30-fold, from which R.FokI was purified in amounts sufficient for crystallization. The removal of a stem-loop structure immediately upstream of the R.FokI coding region was essential for overproduction.     

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.     

Purification and properties of yeast ATP (CTP):tRNA nucleotidyltransferase from wild type and overproducing cells

ATP (CTP):tRNA nucleotidyltransferase (EC 2.7.7.25) has been purified from wild type cells of the yeast Saccharomyces cerevisiae, as well as from a strain that overproduces the activity. Purification from the wild type strain was accomplished with a multistep protocol including ammonium sulfate fractionation, anion exchange chromatography, gel filtration, and affinity chromatography. The purified enzyme is near homogeneity as evidenced by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and at 59,000 Da is smaller than reported previously. A similar molecular mass is obtained by gel filtration demonstrating that the enzyme is active as a monomer. The pH optimum for the enzyme is around 9.5. The apparent KM values for ATP and CTP were determined to be 5.6 x 10(-4) M and 1.8 x 10(-4) M, respectively. Purification of the enzyme from the overproducing cells was accomplished by a three step protocol with high yield. The nucleotidyltransferase activity from the overproducing cells had a KM for CTP indistinguishable from that of the wild type enzyme, and the mobility of the protein on sodium dodecyl sulfate gels was the same regardless of the source. Thus, the overproducing strain appears to be a good source for large amounts of yeast nucleotidyltransferase for further biochemical and structural studies.     

Sequence of the cloned Escherichia coli K1 CMP-N-acetylneuraminic acid synthetase gene

The Escherichia coli CMP-N-acetylneuraminic acid (CMP-NeuAc) synthetase gene is located on a 3.3-kilobase (kb) HindIII fragment of the plasmid pSR23 which contains the genes for K1 capsule production (Vann, W. F., Silver, R. P., Abeijon, C., Chang, K., Aaronson, W., Sutton, A., Finn, C. W., Lindner, W., and Kotsatos, M. (1987) J. Biol. Chem. 262, 17556-17562). The CMP-NeuAc synthetase gene expression was increased 10-30-fold by cloning of a 2.7-kb EcoRI-HindIII fragment onto the vector pKK223-3 containing the tac promoter. The complete nucleotide sequence of the gene encoding CMP-NeuAc synthetase was determined from progressive deletions generated by selective digestion of M13 clones containing the 2.7-kb fragment. CMP-NeuAc synthetase is located near the EcoRI site on this fragment as indicated by the detection of an open reading frame encoding a 49,000-dalton polypeptide. The amino- and carboxyl-terminal sequences of the encoded protein were confirmed by sequencing of peptides cleaved from both ends of the purified enzyme. The nucleotide deduced amino acid sequence was confirmed by sequencing several tryptic peptides of purified enzyme. The molecular weight is consistent with that determined from sodium dodecyl sulfate-gel electrophoresis. Gel filtration and ultracentrifugation experiments under nondenaturing conditions suggest that the enzyme is active as a 49,000-dalton monomer but may form aggregates.     

Purification, structure, and properties of Escherichia coli tRNA pseudouridine synthase I

The RNA modification enzyme, tRNA pseudouridine synthase I has been isolated in 95% purity from an Escherichia coli strain harboring a multicopy plasmid with a 2.3-kilobase pair insert from the hisT operon. Its molecular size, amino acid composition, and amino-terminal sequence correspond to those predicted by the structure and expression of the hisT gene. Enzyme activity, as measured by a 3H release assay, is unaffected by pretreatment of tRNA pseudouridine synthase I with micrococcal nuclease and is optimized by the addition of a monovalent cation and thiol reductant. The activity is inhibited by all tRNA species tested, including substrates, modified tRNAs, nonsubstrates, or tRNAs containing 5-fluorouridine. Binding of tRNA pseudouridine synthase I occurs with both substrate and nonsubstrate tRNAs and does not require a monovalent cation. Our findings are consistent with a multistep mechanism whereby tRNA pseudouridine synthase I first binds nonspecifically and then forms transient covalent adducts with tRNA substrates. In the absence of other proteins, purified tRNA pseudouridine synthase I forms psi at all three modification sites known to be affected in hisT mutants. The 36.4-kDa polypeptide product of the gene adjacent to hisT, whose translation is linked to that of tRNA pseudouridine synthase I, is not a functional subunit for tRNA pseudouridine synthase I activity, nor is it a separate synthase acting at one of the three loci.     

Mode of action and substrate specificities of cellulases from cloned bacterial genes

Three recombinant plasmids, pEC1, pEC2, and pEC3, each containing a unique Cellulomonas fimi chromosomal DNA insert, expressed Cm-cellulase activities in Escherichia coli C600 (Whittle, D. J., Kilburn, D. H., Warren, R. A. J., and Miller, R. C., Jr. (1982) Gene (Amst.) 17, 139-145; Gilkes, N. R., Kilburn, D. G., Langsford, M. L., Miller, R. C., Jr., Wakarchuk, W. W., Warren, R. A. J., Whittle, D. J., and Wong, W. K. R. (1984) J. Gen. Microbiol. 130, 1377-1384). Viscometric and chemical analyses showed that the enzymes encoded by pEC2 and pEC3 behaved as endoglucanases, whereas that encoded by pEC1 behaved as an exoglucanase. The activities of the exoglucanase and the pEC2-encoded endodglucanase were additive on Cm-cellulose as substrate. The pEC1-encoded enzyme also hydrolyzed xylan and p-nitrophenyl cellobioside. Two substrate-bound Cm-cellulases were isolated from the residual cellulose in a C. fimi culture by guanidine hydrochloride elution, affinity chromatography, and polyacrylamide gel electrophoresis. Both were glycoproteins of apparent Mr = 58,000 and 56,000, respectively. The 56-kDa enzyme appeared to be identical with the pEC1-encoded product, suggesting that they arise from the same gene.     

Large-scale preparation of T4 endonuclease VII from over-expressing bacteria

Endonuclease VII is the product of gene 49 of phage T4 and was the first enzyme shown to resolve Holliday structures in vitro [Mizuuchi, K. et al. (1982) Cell 29, 357-365]. Low amounts of the enzyme were originally purified from phage-infected cells [Kemper, B. & Garabett, M. (1981) Eur. J. Biochem. 115, 123-131]. We now report a purification procedure for milligram amounts of cloned endonuclease VII expressed in Escherichia coli with gene 49 under the control of a temperature-inducible promoter on a plasmid system [Tomaschewski, J. (1988) PhD Thesis, University of Bochum, FRG]. The protein was purified 500-fold from crude extracts in five steps with a recovery of 15%. The steps include (a) poly(ethyleneglycol)/dextran two-phase separation; (b) DEAE-cellulose; (c) single-stranded DNA-agarose; (d) Mono-Q and (e) Mono-S chromatography. The final protein was more than 98% pure as estimated from SDS/PAGE analysis. The protein has an apparent molecular mass of 17.8 kDa on SDS-containing polyacrylamide gels and 36 kDa when determined by gel filtration or sedimentation through sucrose gradients in the presence of high salt (600 mM NaCl). In the absence of additional salt, the enzyme has a tendency to aggregate and products of molecular masses differing in steps of about 18 kDa appear on SDS-containing polyacrylamide gels.     

hisT is part of a multigene operon in Escherichia coli K-12.

The Escherichia coli K-12 hisT gene has been cloned, and its organization and expression have been analyzed on multicopy plasmids. The hisT gene, which encodes tRNA pseudouridine synthase I (PSUI), was isolated on a Clarke-Carbon plasmid known to contain the purF gene. The presence of the hisT gene on this plasmid was suggested by its ability to restore both production of PSUI enzymatic activity and suppression of amber mutations in a hisT mutant strain. A 2.3-kilobase HindIII-ClaI restriction fragment containing the hisT gene was subcloned into plasmid pBR322, and the resulting plasmid (designated psi 300) was mapped with restriction enzymes. Complementation analysis with different kinds of hisT mutations and tRNA structural analysis confirmed that plasmid psi 300 contained the hisT structural gene. Enzyme assays showed that plasmid psi 300 overproduced PSUI activity by ca. 20-fold compared with the wild-type level. Subclones containing restriction fragments from plasmid psi 300 inserted downstream from the lac promoter established that the hisT gene is oriented from the HindIII site toward the ClaI site. Other subclones and derivatives of plasmid psi 300 containing insertion or deletion mutations were constructed and assayed for production of PSUI activity and production of proteins in minicells. These experiments showed that: (i) the proximal 1.3-kilobase HindIII-BssHII restriction fragment contains a promoter for the hisT gene and encodes a 45,000-dalton polypeptide that is not PSUI; (ii) the distal 1.0-kilobase BssHII-ClaI restriction fragment encodes the 31,000-dalton PSUI polypeptide; (iii) the 45,000-dalton polypeptide is synthesized in an approximately eightfold excess compared with PSUI; and (iv) synthesis of the two polypeptides is coupled, suggesting that the two genes are part of an operon. Insertion of mini-Mu d1 (lac Km) phage into plasmid psi 300 confirmed that the hisT gene is the downstream gene in the operon.     

Reactions at the 3' terminus of transfer ribonucleic acid. IX. tRNA nucleotidyltransferase activity in bacteriophage T4-infected Escherichia coli

There was no detectable increase in tRNA nucleotidyltransferase activity upon infection of $\text{Escherichia coli}$ A19 with bacteriophage T4. Three mutant strains which contained low levels of tRNA nucleotidyltransferase activity also showed no increase in activity after infection. tRNA nucleotidyltransferase was purified from both uninfected and T4-infected cells and examined for possible modification. It was found that enzyme purified from both types of cells eluted from DEAE cellulose at the same specific conductivity. In addition, the molecular weight of tRNA nucleotidyltransferase purified from both uninfected and T4-infected cells was approximately 45,000 daltons as determined by chromatography on Sephadex G-100. These results suggest that T4-infection does not lead to synthesis of a new virus-specific tRNA nucleotidyltransferase nor does it cause modification of the host enzyme.     

A mutation in the tRNA nucleotidyltransferase gene promotes stabilization of mRNAs in Saccharomyces cerevisiae.

To identify trans-acting factors involved in mRNA decay in the yeast Saccharomyces cerevisiae, we have begun to characterize conditional lethal mutants that affect mRNA steady-state levels. A screen of a collection of temperature-sensitive mutants identified ts352, a mutant that accumulated moderately stable and unstable mRNAs after a shift from 23 to 37 degrees C (M. Aebi, G. Kirchner, J.-Y. Chen, U. Vijayraghavan, A. Jacobson, N.C. Martin, and J. Abelson, J. Biol. Chem. 265:16216-16220, 1990). ts352 has a defect in the CCA1 gene, which codes for tRNA nucleotidyltransferase, the enzyme that adds 3' CCA termini to tRNAs (Aebi et al., J. Biol. Chem., 1990). In a shift to the nonpermissive temperature, ts352 (cca1-1) cells rapidly cease protein synthesis, reduce the rates of degradation of the CDC4, TCM1, and PAB1 mRNAs three- to fivefold, and increase the relative number of ribosomes associated with mRNAs and the overall size of polysomes. These results were analogous to those observed for cycloheximide-treated cells and are generally consistent with models that invoke a role for translational elongation in the process of mRNA turnover.     

Possible regulation by nucleosidediphosphate kinase involvement of the synthesis of tRNA 3'-terminal -pCpCpA in mammalian cells

When the cytosol of Ehrlich ascites tumor cells was fractionated by chromatofocusing in the pH range of 9 to 6, two active peaks (I and II) of tRNA nucleotidyltransferase were obtained. Fraction I was a multiple complex with a high molecular weight (M.W. greater than 300K) and fraction II comprised components derived from fraction I. Fraction II was separated into tRNA nucleotidyltransferase (M.W., ca. 46,000) and nucleosidediphosphate kinase (M.W., ca. 74,000) by subsequent Sephacryl S-200 chromatography. The two enzymes appeared to be associated loosely with each other. Using the above fraction II or a mixture of the purified tRNA nucleotidyltransferase and nucleosidediphosphate kinase, it was possible to effectively synthesize the 3'-terminal -pCpCpA of tRNA in a reaction mixture containing [3H]-CDP plus XTP or [3H]ADP plus XTP as substrate. Among the XTPs investigated, dTTP was most effective. In addition, it was found that [3H]AMP + XTP also serves as a substrate. [14C]CMP plus XTP, however, was not utilized. From the antagonism of cold CDP against [3H]CTP, and that of cold ADP and AMP against [3H]ATP with the purified tRNA nucleotidyltransferase, the affinity of CDP to the enzyme was estimated to be 1/100 of that of CTP, while the affinities of ADP and AMP to the enzyme were 3 and 30 times higher, respectively, than that of ATP, suggesting that the subsite which binds ATP also binds ADP or AMP. The tRNA nucleotidyltransferase, which had bound ADP or AMP, could not completely synthesize the 3'-terminus of tRNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of a tRNA nucleotidyltransferase from Lupinus albus and functional complementation of a yeast mutation by the corresponding cDNA

ATP (CTP):tRNA nucleotidyltransferase (EC 2.7.7.25) was purified to apparent homogeneity from a crude extract of Lupinus albus seeds. Purification was accomplised using a multistep protocol including ammonium sulfate fractionation and chromatography on anion-exchange, hydroxylapatite and affinity columns. The lupin enzyme exhibited a pH optimum and salt and ion requirements that were similar to those of tRNA nucleotidyltransferases from other sources. Oligonucleotides, based on partial amino acid sequence of the purified protein, were used to isolate the corresponding cDNA. The cDNA potentially encodes a protein of 560 amino acids with a predicted molecular mass of 64164 Da in good agreement with the apparent molecular mass of the pure protein determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The size and predicted amino acid sequence of the lupin enzyme are more similar to the enzyme from yeast than from Escherichia coli with some blocks of amino acid sequence conserved among all three enzymes. Functionality of the lupin cDNA was shown by complementation of a temperature-sensitive mutation in the yeast tRNA nucleotidyltransferase gene. While the lupin cDNA compensated for the nucleocytoplasmic defect in the yeast mutant it did not enable the mutant strain to grow at the non-permissive temperature on a non-fermentable carbon source.     

Escherichia coli glycerol kinase. Cloning and sequencing of the glpK gene and the primary structure of the enzyme

The glpK gene, which codes for Escherichia coli K-12 glycerol kinase (EC 2.1.7.30, ATP:glycerol 3-phosphotransferase), has been cloned into the HindIII site of pBR322. The gene was contained in a 2.8-kilobase DNA fragment which was obtained from a lambda transducing bacteriophage, lambda dglpK100 (Conrad, C.A., Stearns, G.W., III, Prater, W.E., Rheiner, J.A., and Johnson, J.R. (1984) Mol. Gen. Genet. 195, 376-378). The DNA sequence of 2 kilobases of the cloned HindIII fragment was obtained using the dideoxynucleotide method. The start of the open reading frame for the glpK gene was identified from the N-terminal sequence of the first 22 amino acid residues of the purified enzyme, which was determined by automated Edman degradation. The open reading frame codes for a protein of 502 amino acids and a molecular weight of 56,106 which is in good agreement with the value previously determined by sedimentation equilibrium. The primary structure of the protein as deduced from the gene sequence was corroborated by the isolation and sequencing of four tryptic peptides, which were found to occur at the following amino acid locations: 173-177, 203-211, 279-281, 464-468. The N-terminal sequence of the purified enzyme shows that the enzyme undergoes post-translational processing. Restriction digestion as well as DNA sequencing of the supercoiled plasmid shows that the HindIII fragment is inserted into pBR322 such that the glpK gene is transcribed in a counterclockwise direction. Examination of the upstream DNA sequence reveals two possible promoters of essentially the same efficiency: the P1 promoter of pBR322 and a hybrid promoter which contains both bacterial and pBR322 DNA sequences.     

A trans-acting regulatory mutation that causes overproduction of phosphatidylserine synthase in Escherichia coli

We have isolated three mutants of Escherichia coli which have elevated levels of the phospholipid synthetic enzyme phosphatidylserine synthase. One of these strains carries a mutation, designated pssR1, which maps near minute 84 of the chromosome, distinct from the synthase structural gene (pss) at minute 56. The pssR1 mutation causes selective overproduction of phosphatidylserine synthase, since the levels of six other lipid synthetic enzymes are unaltered. The specific activity of the synthase in crude cell extracts of mutants harboring pssR1 is about five times greater than wild type. The synthase can also be overproduced 10-fold in wild type strains with hybrid ColE1 plasmids carrying the synthase structural gene (pss). A pssR1 mutant harboring such a pss plasmid overproduces the synthase about 50-fold. This multiplicative interaction of pssR1 and cloned pss demonstrates that pssR1 is trans-acting. The synthase has been purified in parallel from pssR1 and pssR+ strains. The pssR1 mutant yields more total synthase protein than pssR+, but the pure enzyme has the same specific activity in both cases. Therefore, pssR1 acts by increasing the amount of the normal protein, not by activating the enzyme. The discovery of pssR shows that there are regulatory loci which control the production of enzymes involved in membrane lipid synthesis.