Nucleotide sequence of the Thiobacillus ferrooxidans chromosomal gene encoding mercuric reductase

The nucleotide sequence of the Thiobacillus ferrooxidans chromosomal mercuric-reductase-encoding gene (merA) has been determined. The merA gene contains 1635 bp, and shares 78.2% and 76.6% sequence homology with the transposon, Tn501, and plasmid R100 merA genes, respectively. From the sequence, a 545-amino acid (aa) polypeptide was deduced, and comparison with those of Tn501 and R100 revealed 80.6% and 80.0% homology, respectively, at the aa sequence level. Divergence among the three merA aa sequences was clustered within a specific region (aa positions 41-87). By analysis of codon usage frequency, it is speculated that the T. ferrooxidans merA gene originated from Tn501, R100, or a common ancestral gene, but not from T. ferrooxidans itself.     

Nucleotide sequence of a gene from the Pseudomonas transposon Tn501 encoding mercuric reductase

We have determined the nucleotide sequence of the merA gene from the mercury-resistance transposon Tn501 and have predicted the structure of the gene product, mercuric reductase. The DNA sequence predicts a polypeptide of Mr 58 660, the primary structure of which shows strong homologies to glutathione reductase and lipoamide dehydrogenase, but mercuric reductase contains as additional N-terminal region that may form a separate domain. The implications of these comparisons for the tertiary structure and mechanism of mercuric reductase are discussed. The DNA sequence presented here has an overall G+C content of 65.1 mol%, typical of the bulk DNA of Pseudomonas aeruginosa from which Tn501 was originally isolated. Analysis of the codon usage in the merA gene shows that codons with C or G at the third position are preferentially utilized.     

The merR regulatory gene in Thiobacillus ferrooxidans is spaced apart from the mer structural genes

Two distinct merR genes, which regulate expression of the mercuric ion resistance gene (mer), of Thiobacillus ferrooxidans strain E-15 have been cloned, sequenced and termed merR1 and merR2. As a result of gene walking around two merR genes, it was found that these two genes were quite close in distance. The nucleotide sequence of the region (5,001 base pairs; PstI-EcoRI fragment) containing the merR genes was determined. Between the two merR genes, there were five potential open reading frames (ORFs). Two of these were identified as merC genes, and the other three as ORFs 1 to 3. ORFs 1 to 3 show significant homology to merA, tnsA from transposon Tn7, and merA, respectively. Both merR genes consist of a 408 bp ORF coding for 135 amino acids. Their gene products, MerR1 and MerR2, differed at three amino acid positions, and shared 56-57% and 32-38% identity with the MerRs from other Gram-negative and Gram-positive bacteria, respectively. Competitive primer extension analysis revealed that both regulatory genes were expressed in the host cells. These merR genes were located more than 6 kb from either end of the mer structural genes (merC-merA). This is the first example of merR being separated from the mer structural genes. The two merC genes, each of which coded for a 140-amino-acid protein, appeared to be functionally active because Escherichia coli cells carrying these merC genes on plasmid vectors showed hypersensitivity to HgCl2. However, ORFs 1 and 3, which were homologous to merA, seemed to be inactive both structurally and enzymatically. The gene arrangement in this region took on a mirror image, with the truncated tnsA as the symmetrical centre. It is suggested that the Tn7-like factor may have participated in gene duplication events of the mer region, and in its chromosomal integration.     

Restriction pattern and polypeptide homology among plasmid-borne mercury resistance determinants

The structural and functional properties of mercury resistance determinants cloned from a series of independently isolated conjugative plasmids were compared with those of the prototype HgR determinants from Tn501 and plasmid R100 (containing Tn21). Restriction endonuclease mapping classified the HgR determinants into at least three different but related structural groups which are distantly related to those from Tn501 and R100. These relationships were confirmed by the functional analysis of sub-clones and gamma delta insertion mutations and from the polypeptides specified by the cloned HgR determinants. Each mercury resistance clone synthesized polypeptides equivalent in size to the merA, merT, and merP gene products. However, those for merA and merT showed considerable size variation. No polypeptide equivalent to merD or merC of R100 was detected.     

The distribution and divergence of DNA sequences related to the Tn21 and Tn501 mer operons

The mercury resistance (mer) operons of the Gram-negative bacterial transposons, Tn21 and Tn501, are phenotypically indistinguishable and have extensive DNA identity. However, Tn21 mer has an additional coding region (merC) in the middle of the operon which is lacking in Tn501 and there is also a discrete region of the mercuric ion reductase gene (merA) which differs markedly between the two operons. DNA fragment probes were used to determine the distribution of specific mer coding regions in two distinct collections of mercury-resistant (Hgr) Gram-negative bacteria. Colony blot hybridization analysis showed that merC-positive operons occur almost exclusively in Escherichia, although merC-negative operons can also be found in this genus. The merC-negative operons were found in Citrobacter, Klebsiella, and Enterobacter and in some Pseudomonas. Most of the Pseudomonas did not hybridize detectably with either of the two operons studied, indicating that they harbor an unrelated or more distantly related class of mercury resistance locus. Southern hybridization patterns demonstrated that the merC-positive mer operon is well conserved at the DNA level, whereas the merC-negative operons are much less conserved. The presence of merC also correlated with conservation of a specific variant region of the merA gene and with an antibiotic resistance pattern similar to that of Tn21. Tn501 appears to be an atypical example of the merC-negative subgroup of Hgr loci.     

The region of the IncN plasmid R46 coding for resistance to beta-lactam antibiotics, streptomycin/spectinomycin and sulphonamides is closely related to antibiotic resistance segments found in IncW plasmids and in Tn21-like transposons.

The nucleotide sequence of a 2.5 kb segment of the pKM101 (R46) genome has been determined. The 1.3 kb from a BamHI site at 153 to base 1440 differs by only 2 bases from a part of the published sequence of the aadB (gentamicin resistance) gene region including the coding region for the N-terminal 70 amino acids of the predicted aadB product. The same sequence has been found 5'-to the dhfrII gene of R388 and to the aadA gene of Tn21 (R538-1). Three open reading frames are located in this region, two on the same strand as the resistance genes and one on the complementary strand. The latter predicts a polypeptide of 337 amino acids, whose N-terminal segment is 40% homologous to the predicted product of an open reading frame of 179 amino acids located next to the dhfrI gene of Tn7. The oxa2 (oxacillin resistance) gene predicts a long polypeptide commencing with (the N-terminal) 70 amino acids of the aadB product. A similar arrangement is found in the aadA gene of R538-1. The N-terminal segment of an aadA gene is located 3'- to oxa2, separated by 36 bases. Sequences surrounding the BamHI site are identical to sequences 5'- to the tnpM gene of Tn21 and homology ceases where homology between Tn21 and Tn501 commences. The possibility that this antibiotic resistance segment is a discrete mobile DNA element is discussed.     

The nucleotide sequence of the mercuric resistance operons of plasmid R100 and transposon Tn501: further evidence for mer genes which enhance the activity of the mercuric ion detoxification system

Summary The DNA sequences of the mercuric resistance determinants of plasmid R100 and transposon Tn501 distal to the gene (merA) coding for mercuric reductase have been determined. These 1.4 kilobase (kb) regions show 79% identity in their nucleotide sequence and in both sequences two common potential coding sequences have been identified. In R100, the end of the homologous sequence is disrupted by an 11.2 kb segment of DNA which encodes the sulfonamide and streptomycin resistance determinants of Tn21. This insert contains terminal inverted repeat sequences and is flanked by a 5 base pair (bp) direct repeat. The first of the common potential coding sequences is likely to be that of the merD gene. Induction experiments and mercury volatilization studies demonstrate an enhancing but non-essential role for these merA-distal coding sequences in mercury resistance and volatilization. The potential coding sequences have predicted codon usages similar to those found in other Tn501 and R100 mer genes.     

Nucleotide sequences at the ends of the mercury resistance transposon, Tn501.

The nucleotide sequences at the ends of the mercury-resistance transposon, Tn501, have been determined. The terminal sequences are inverted repeated sequences 38 nucleotide pairs in length, which differ in 3 nucleotide pairs. The transposon is flanked by directly repeated sequences of 5 nucleotide pairs, originating from a single pentanucleotide sequence in the recipient replicon. There is no obvious homology between recipient replicons at the site of insertion of the transposon. The structures of the ends of Tn501 are compared with those of other transposons and insertion sequences. The use of Tn501 to locate an EcoRI site within a genetically defined sequence of interest is discussed.     

DNA sequence analysis of the transposon Tn3: three genes and three sites involved in transposition of Tn3.

The complete nucleotide sequence of the transposon Tn3 and of 20 mutations which affect its transposition are reported. The mutations, generated in vitro by random insertion of synthetic restriction sites, proved to contain small duplications or deletions immediately adjacent to the new restriction site. By determining the phenotype and DNA sequence of these mutations we were able to generate an overlapping phenotypic and nucleotide map. This 4957 bp transposon encodes three polypeptides which account for all but 350 bp of its total coding capacity. These proteins are the transposase, a high molecular weight polypeptide (1015 amino acids) encoded by the tnpA gene; the Tn3-specific repressor, a low molecular weight polypeptide (185 amino acids) encoded by the tnpR gene; and the 286 amino acid beta-lactamase. The 38 bp inverted repeats flanking Tn3 appear to be absolutely required in cis for Tn3 to transpose. Genetic data suggest that Tn3 contains a third site (Gill et al., 1978), designated IRS (internal resolution site), whose absence results in the insertion of two complete copies of Tn3 as direct repeats into the recipient DNA. We suggest that these direct repeats of complete copies of Tn3 are intermediates in transposition, and that the IRS site is required for recombination and subsequent segregation of the direct repeats to leave a single copy of Tn3 (Gill et al., 1978). A 23 nucleotide sequence within the amino terminus of the transposase which shares strong sequence homology with the inverted repeat may be the internal resolution site.     

Sequence analysis of the large and small subunits of human ribonucleotide reductase.

We have isolated and sequenced overlapping cDNA clones from a breast carcinoma cDNA library containing the entire coding region of both the R1 and R2 subunits of the human ribonucleotide reductase gene. The coding region of the human R1 subunit comprises 2376 nucleotides and predicts a polypeptide of 792 amino acids (calculated molecular mass 90,081). The sequence of this subunit is almost identical to the equivalent mouse ribonucleotide reductase subunit with 97.7% homology between the mouse and human R1 subunit amino acid sequences. The coding region of the human R2 subunit of ribonucleotide reductase comprises 1170 nucleotides and predicts a polypeptide of 389 amino acids (calculated molecular mass 44,883), which is one amino acid shorter than the equivalent mouse subunit. The human and mouse R2 subunits display considerable homology in their carboxy-terminal amino acid sequences, with 96.3% homology downstream of amino acid 68 of the human and mouse R2 proteins. However, the amino-terminal portions of these two proteins are more divergent in sequence, with only 69.2% homology in the first 68 amino acids.     

The nucleotide sequence of the tnpA gene completes the sequence of the Pseudomonas transposon Tn501.

The nucleotide sequence of the gene (tnpA) which codes for the transposase of transposon Tn501 has been determined. It contains an open reading frame for a polypeptide of Mr = 111,500, which terminates within the inverted repeat sequence of the transposon. The reading frame would be transcribed in the same direction as the mercury-resistance genes and the tnpR gene. The amino acid sequence predicted from this reading frame shows 32% identity with that of the transposase of the related transposon Tn3. The C-terminal regions of these two polypeptides show slightly greater homology than the N-terminal regions when conservative amino acid substitutions are considered. With this sequence determination, the nucleotide sequence of Tn501 is fully defined. The main features of the sequence are briefly presented.     

The nucleotide sequence of the tnpA gene of Tn21.

The nucleotide sequence of the tnpA gene of Tn21 is presented. The transposase encoded by this gene is exactly the same length (988 amino acids) as the Tn501 transposase (4), and shows 72% homology overall with this protein, with greater homology towards the C-terminus. The sequence of the transposase is discussed in the context of the evolution of Class II transposable elements and of the characteristics of the enzyme's action.     

Nucleotide sequence of a chromosomal mercury resistance determinant from a Bacillus sp. with broad-spectrum mercury resistance.

A 13.5-kilobase HindIII fragment, bearing an intact mercury resistance (mer) operon, was isolated from chromosomal DNA of broad-spectrum mercury-resistant Bacillus sp. strain RC607 by using as a probe a clone containing the mercury reductase (merA) gene. The new clone, pYW33, expressed broad-spectrum mercury resistance both in Escherichia coli and in Bacillus subtilis, but only in B. subtilis was the mercuric reductase activity inducible. Sequencing of a 1.8-kilobase mercury hypersensitivity-producing fragment revealed four open reading frames (ORFs). ORF1 may code for a regulatory protein (MerR). ORF2 and ORF4 were associated with cellular transport function and the hypersensitivity phenotype. DNA fragments encompassing the merA and the merB genes were sequenced. The predicted Bacillus sp. strain RC607 MerA (mercuric reductase) and MerB (organomercurial lyase) were similar to those predicted from Staphylococcus aureus plasmid pI258 (67 and 73% amino acid identities, respectively); however, only 40% of the amino acid residues of RC607 MerA were identical to those of the mercuric reductase from gram-negative bacteria. A 69-kilodalton polypeptide was isolated and identified as the merA gene product by examination of its amino-terminal sequence.     

Molecular cloning and determination of the nucleotide sequence of raw starch digesting alpha-amylase from Aspergillus awamori KT-11

Complementary DNAs encoding alpha-amylases (Amyl I, Amyl III) and glucoamylase (GA I) were cloned from Aspergillus awamori KT-11 and their nucleotide sequences were determined. The sequence of Amyl III that was a raw starch digesting alpha-amylase was found to consist of a 1,902 bp open reading frame encoding 634 amino acids. The signal peptide of the enzyme was composed of 21 amino acids. On the other hand, the sequence of Amyl I, which cannot act on raw starch, consisted of a 1,500 bp ORF encoding 499 amino acids. The signal peptide of the enzyme was composed of 21 amino acids. The sequence of GA I consisted of a 1,920 bp ORF that encoded 639 amino acids. The signal peptide was composed of 24 amino acids. The amino acid sequence of Amyl III from the N-terminus to the amino acid number 499 showed 63.3% homology with Amyl I. However, the amino acid sequence from the amino acid number 501 to C-terminus, including the raw-starch-affinity site and the TS region rich in threonine and serine, showed 66.9% homology with GA I.     

Cloning and expression in Escherichia coli of mercuric ion resistance coding genes from Zymomonas mobilis.

From a genomic library of Zymomonas mobilis prepared in Escherichia coli, two clones (carrying pZH4 and pZH5) resistant to the mercuric ion were isolated. On partial restriction analysis these two clones appeared to have the same 2.9 kb insert. Mercuric reductase activity was assayed from the Escherichia coli clone carrying pZH5 and it was Hg(2+)-inducible, NADH dependent and also required 2-mercaptoethanol for its activity. The plasmid pZH5 encoded three polypeptides, mercuric reductase (merA; 65 kDa), a transport protein (merT 18-17 kDa) and merC (15 kDa) as analysed by SDS-PAGE. Southern blot analysis showed the positive signal for the total DNA prepared from Hgr Z. mobilis but not with the Hgs strain which was cured for a plasmid (30 kb). These results were also confirmed by isolating this plasmid from Hgr Z. mobilis and transforming into E. coli. Moreover the plasmid pZH5 also hybridized with the mer probes derived from Tn21.