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Query: UNIPROT:P06889 (Mol)
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The Escherichia coli ada-alkB operon encodes a 39-kDa protein (Ada) that is a DNA-repair methyltransferase and a 27-kDa protein (AlkB) of unknown function. By DNA blot hybridization analysis we show that the alkylation-sensitive E. coli mutant BS23 [Sedgwick, B. & Lindahl, T. (1982) J. Mol. Biol. 154, 169-175] is a deletion mutant lacking the entire ada-alkB operon. Despite the absence of the ada gene and its product, the cells contain detectable levels of a DNA-repair methyltransferase activity. We conclude that the methyltransferase in BS23 cells is the product of a gene other than ada. A similar activity was detected in extracts of an ada-10::Tn10 insertion mutant of E. coli AB1157. This DNA methyltransferase has a molecular mass of about 19 kDa and transfers the methyl groups from O6-methylguanine and O4-methylthymine in DNA, but not those from methyl phosphotriester lesions. This enzyme was not induced by low doses of alkylating agent and is expressed at low levels in ada+ and a number of ada- E. coli strains.
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PMID:A second DNA methyltransferase repair enzyme in Escherichia coli. 328 37

The 3' ends of most Saccharomyces cerevisiae mitochondrial mRNAs terminate at a conserved dodecamer sequence, 5'-AAUAAUAUUCUU-3', of unknown function. We have studied the consequences of mutations within a dodecamer found in an 1,143-base-pair optional intron of the mitochondrial large (21S) rRNA gene on RNA processing. The dodecamer is situated at the 3' end of an expressed open reading frame (ORF) within that intron, and the mutations are two adjacent transversions that extend the intron ORF by 51 nucleotides. The strain harboring these mutations, L5-10-1, is defective in biased intron transmission in crosses to strains that lack the intron, as are other mutants which contain nucleotide changes within the ORF (I. G. Macreadie, R. M. Scott, A. R. Zinn, and R. A. Butow, Cell 41:395-402, 1985). However, unlike these other mutants, wild-type strains, or petites which retain the intron allele, L5-10-1 is defective in processing at the intron dodecamer. In addition, L5-10-1 lacks a prominent 2.7-kilobase RNA containing both intron and exon sequences and at least two of four RNAs that correspond to various forms of the excised intron. We propose that these RNAs, missing in L5-10-1 but present in all other strains examined, arise in part by processing at the intron dodecamer. In addition, in all strains examined, we have detected a novel processing activity in which precursor 21S rRNA transcripts are cleaved in the upstream exon, about 1,500 nucleotides from the 5' end of the RNA. This activity, together with 3' intron dodecamer cleavage, probably accounts for the 2.7-kilobase RNA species, a candidate for the mRNA for the intron-encoded protein.
Mol Cell Biol 1987 Jul
PMID:RNA processing and expression of an intron-encoded protein in yeast mitochondria: role of a conserved dodecamer sequence. 330 79

In a previous study of three independent families of mutants selected for overproduction of adenylate deaminase (AMPD), we were not able to isolate a cDNA probe for the gene and so could not demonstrate its amplification directly. In addition to overproduction of AMPD, four proteins of unknown function, designated W, X, Y1, and Y2, accumulated, and by using the corresponding cDNA probes, we demonstrated amplification of all four genes. In independent mutant clones, sometimes all and sometimes only a subset of these genes were amplified. Assuming that all five genes are linked, the pattern of their coamplification suggested a genetic map in which AMPD lies between W and Y1. We show here that a two-step chromosome walk joins the W and Y1 genes, that the AMPD gene is the only expressed sequence between them, and that its amplification is indeed responsible for overproduction of the AMPD protein. In the course of this work, we cloned and studied two novel joints which mark rearrangements on either side of the AMPD gene. Each joint was generated independently in a single first-step mutant at single or low copy number. Remarkably, each joint was amplified preferentially in every second- and third-step mutant derived from the first-step line in which it was originally present, suggesting that the two independent rearrangements each generated amplification-prone structures.
Mol Cell Biol 1988 Jan
PMID:Preferential amplification of rearranged sequences near amplified adenylate deaminase genes. 333 58

We have constructed and characterized two Dictyostelium transformation vectors (pB10TP1 and pB10TP2) designed for the facile sequence determination, mutagenesis and functional analysis of Dictyostelium genes. The vectors incorporate the B10 neomycin-resistance (neo) gene [Nellen et al., Mol. Cell. Biol. 4 (1984) 2890-2898] and sequences derived pEMBL18+ [Dente et al., Nucl. Acids Res. 11 (1983) 1645-1655], enabling the production of single-stranded template and increasing the yield of double-stranded DNA. A new multiple cloning site (MCS) has been inserted adjacent to the M13 sequence primer binding site so that single-stranded template DNA isolated from recombinants prepared using these vectors is suitable for sequence analysis and site-directed mutagenesis. The linker incorporates restriction sites suitable for the preparation of a directed deletion series and useful in cloning, including some sites with recognition sequences frequent in the extremely A + T-rich Dictyostelium genome. A Dictyostelium genomic fragment has been included to provide transcription termination signals for the neo gene. One of the two vectors (pB10TP1) contains the 3'-proximal portion of a constitutively expressed mRNA of unknown function. It is located downstream from the MCS so that 5'-proximal fragments of genes, cloned into the MCS, generate fusion transcripts which are distinguishable from transcripts of the corresponding endogenous genes. The complete nucleotide sequence of the two vectors has been established and a comprehensive restriction map deduced. We also describe a modification of the published transformation system, which allows it to be applied to the commonly used strain Ax-2, and another generally applicable modification which greatly reduces the time required to obtain stable transformants.
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PMID:Two vectors which facilitate gene manipulation and a simplified transformation procedure for Dictyostelium discoideum. 343 28

FAS1, the structural gene of the pentafunctional fatty acid synthetase subunit beta in Saccharomyces cerevisiae has been sequenced. Its reading frame represents an intron-free nucleotide sequence of 5,535 base pairs, corresponding to a protein of 1,845 amino acids with a molecular weight of 205,130 daltons. In addition to the coding sequence, 1,468 base pairs of its 5'-flanking region were determined. S1 nuclease mapping revealed two transcriptional initiation sites; 5 and 36 base pairs upstream of the translational start codon. Within the flanking sequences two TATATAAA boxes, several A-rich and T-rich blocks and a TAG...TATGTT...TATGTT...TTT sequence were found and are discussed as transcriptional initiation and termination signals, respectively. The order of catalytic domains in the cluster gene was established by complementation of defined fas1 mutants with overlapping FAS1 subclones. Acetyl transferase (amino acids 1-468) is located proximal to the N-terminus of subunit beta, followed by the enoyl reductase (amino acids 480-858), the dehydratase (amino acids 1,134-1,615) and the malonyl/palmityl transferase (amino acids 1,616-1,845) domains. One major inter-domain region of about 276 amino acids with so far unknown function was found between the enoyl reductase and dehydratase domains. The substrate-binding serine residues of acetyl, malonyl and palmityl transferases were identified within the corresponding domains. Significant sequence homologies exist between the acyl transferase active sites of yeast and animal fatty acid synthetases. Similarly, a putative sequence of the enoyl reductase active site was identified.
Mol Gen Genet 1986 Jun
PMID:The pentafunctional FAS1 gene of yeast: its nucleotide sequence and order of the catalytic domains. 352 50

The isolation and characterization of a new mutation conferring radiation sensitivity in Escherichia coli is described. This mutation is located close to the gene coding for deoxycytidine deaminase, in the chromosomal region of the gat operon. It is very sensitive to gamma rays and exhibits a decrease in recombination ability. The expression of radiation sensitivity seems to result from the additive effect of the dcd mutation and another mutation of unknown function.
Mol Gen Genet 1985
PMID:Characterization of a mutation conferring radiation sensitivity, ior, located close to the gene coding for deoxycytidine deaminase in Escherichia coli. 389 90

By S1 nuclease protection experiments and primer extension analysis, we determined precisely the cap and polyadenylation sites of transcripts from the four genes of the yeast 2 micron circle plasmid, as well as those of other plasmid transcripts of unknown function. In addition, we used deletion analysis to identify sequences necessary for polyadenylation in plasmid transcripts. Our results indicate that plasmid genes constitute independent transcription units and that plasmid mRNAs are not derived by extensive processing of precursor transcripts. In addition, we found that the D coding region of 2 micron circle is precisely encompassed by a polyadenylated transcript, suggesting that this coding region constitutes a functional plasmid gene. Our identification of the position of plasmid polyadenylation sites and of sequences necessary for polyadenylation provides support for a tripartite signal for polyadenylation as proposed by Zaret and Sherman (K.S. Zaret and F. Sherman, Cell 28:563-573, 1982). Finally, these data highlight salient features of the transcriptional regulatory circuitry that underlies the control of plasmid maintenance in the cell.
Mol Cell Biol 1985 Oct
PMID:Signals for transcription initiation and termination in the Saccharomyces cerevisiae plasmid 2 micron circle. 391 34

Bacteriophage T4 contains genes for eight transfer RNAs and two stable RNAs of unknown function. These are found in two clusters at 70 X 10(3) base-pairs on the T4 genetic map. To understand the control of transcription in this region we have completed the sequencing of 5000 base-pairs in this region. The sequence contains a part of gene 3, gene 1, gene 57, internal protein I, the tRNA genes and five open reading frames which most likely code for heretofore unidentified proteins. We have used subclones of the region to investigate the kinetics of transcription in vivo. The results show that transcription in this region consists of overlapping early, middle and late transcripts. Transcription is directed from two early promoters, one or two middle promoters and perhaps two late promoters. This region contains all of the features that are seen in T4 transcription and as such is a good place to study the phenomenon in more detail.
J Mol Biol 1985 Oct 05
PMID:Sequence organization and control of transcription in the bacteriophage T4 tRNA region. 405 54

Transcription at various points in the trf A region of broad host range plasmid RK2 has been analysed by measuring expression of the galK gene inserted at EcoRI sites introduced previously by TB1723 transposition mutagenesis. Rightward transcription (anti-clockwise on RK2) probably from a single promoter, proceeds across two open reading frames coding for a 13 kD polypeptide of unknown function, and the trf A gene, which provides a protein(s) essential for plasmid replication. This transcription is not auto-regulated by the products of either open reading frame and is also not subject to significant attenuation prior to the end of the trfA open reading frame. Leftward transcription appears to be directed by at least two well separated promoters, the more leftward being three to four times stronger than the more rightward. Rightward, but not leftward, transcription is repressed about 9-fold by the trfB locus of RK2 alone (so far not separable from the loci korA and korD) in trans while the combination of the korB and trfB loci in trans represses both rightward transcription (about 100-fold) and leftward transcription (the stronger activity by 10 to 15-fold). Regulation of these operons is therefore qualitatively different. The kilD locus in the trfA region, which is suppressed by korD (trfB) is thus probably part of the rightward (trfA) operon, while leftward transcription may represent the start of an operon containing kilB. The results suggest that RK2kor loci act by repressing transcription of kil loci and that the kil and kor control circuits may be part of an interlocking system of RK2 genes involved in replication and stable maintenance.
Mol Gen Genet 1984
PMID:Transcription in the trfA region of broad host range plasmid RK2 is regulated by trfB and korB. 608 48

Cell-free DNA synthesis was performed in a lysed cell system from mouse cell cultures. The in vitro reaction was totally inhibited by N-ethylmaleimide but unaffected by hydroxyurea or fluorodeoxyuridine when these compounds were added to the incubation mixture. However, in a preparation obtained from cells which had been blocked by hydroxyurea before lysis, the rate of DNA synthesis was markedly reduced. This effect could not have been caused by the depletion of the precursor pools as all necessary triphosphates were added to the in vitro incubation mixture. Analysis by alkaline density gradients showed that the ligation of primary synthesis products is retarded in hydroxyurea-pretreated lysed cells and that small fragments accumulate. These results suggest that hydroxyurea interferes with the processing of early replication products, preventing the formation of longer intermediates. Its mechanism is either independent from the well-known inhibition of ribonucleoside diphosphate reductase or it may be the result of an as-yet-unknown function of this enzyme in a later step of replication. This observation could help to explain why cells appear to be blocked by hydroxyurea in the early part of the S phase (rather than at the G1/S border proper) and also why DNA repair synthesis is relatively insensitive to the drug.
Mol Cell Biol 1983 Mar
PMID:Does hydroxyurea inhibit DNA replication in mouse cells by more than one mechanism? 622 Nov 89


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