The corrected nucleotide sequences of the TaqI restriction and modification enzymes reveal a thirteen-codon overlap.

The nucleotide sequence of the genes encoding methyltransferase TaqI (M.TaqI) and restriction endonuclease TaqI (R.TaqI) with the recognition sequence, TCGA, were analyzed in clones isolated from independent libraries. The genes, originally reported as 363 and 236 codons long [Slatko et al., Nucleic Acids Res. 15 (1987) 9781-9796] were redetermined as 421 and 263 codons long, respectively. The C terminus of the taqIM gene overlaps the N terminus of the taqIR gene by 13 codons, as observed with the isoschizomeric TthHB8I restriction-modification system [Barany et al., Gene 112 (1992) 13-20]. Removal of the overlapping codons did not interfere with in vivo M.TaqI activity. We postulate the overlap plays a role in regulating taqIR expression.     

The TaqI 'star' reaction: strand preferences reveal hydrogen-bond donor and acceptor sites in canonical sequence recognition

TaqI endonuclease recognizes and cleaves its canonical sequence, TCGA, with complete fidelity under standard conditions. In the presence of some organic solvents, TaqI endonuclease introduced additional single-strand and double-strand cuts at sequences termed TaqI 'star' sites. Using 'middle-labeled' DNA, the relative rates of cleavage of each strand were simultaneously determined for several star sites. These star recognition sequences differed from the canonical sequence by a single base, and all potential star sites were either nicked or cleaved. Star sites within the middle labeled substrate represented ten of the twelve possible star sequences for each strand. For each group of identical star sites, one strand was consistently preferred for cleavage. Based on these preferences, a model for TaqI recognition of the TCGA sequence is proposed. According to this model, sequence discrimination is mediated by eight hydrogen bonds formed between TaqI and the cognate nucleotides within the major groove.     

Correlation between insertion mutant activities and amino acid sequence identities of the TaqI and TthHB8 restriction endonucleases.

A two-codon insertion mutagenesis method has been generalized. Over two dozen insertion mutants throughout the gene encoding TaqI restriction endonuclease were constructed and activity was characterized. All mutants with activity either cleaved or nicked the canonical T decreases CGA recognition sequence. Some insertion mutants created duplication of gene regions, termed Gemini proteins, which still retained activity. The correlation between mutants with poor activity and the regions of shared amino acid identity between the isoschizomeric TaqI and TthHB8I suggests these regions are involved in DNA recognition and/or catalysis.     

High-level production of TaqI restriction endonuclease by three different expression systems in Escherichia coli cells using the T7 phage promoter

Three different expression systems were constructed for the high-level production of TaqI restriction endonuclease in recombinant Escherichia colicells. In system [R], the TaqI endonuclease gene was cloned and expressed under the control of the strong T7 RNA polymerase promoter. To protect cellular DNA, methylase protection was provided by constitutive co-expression of TaqI methylase activity either by cloning the TaqI methylase gene on a second plasmid (system [R,M]) or by constructing a recombinant plasmid harboring both the endonuclease and methylase genes (system [R+M]). In batch shake flasks containing complex media, co-expression of the methylase gene in systems [R,M] and [R+M] resulted in a 2- and 3-fold increase in volumetric productivity over system [R], yielding activities of 250x10(6) U l(-1) and 350x10(6) U l(-1), which were 28 and 39 times higher than the data in the literature, respectively. Under controlled bioreactor conditions in chemically defined medium, co-expression of methylase activity greatly improved the yield and specific TaqI endonuclease productivity of the recombinant cells, and reduced acetic acid excretion levels. System [R,M] is preferable for high expression levels at longer operation periods, while system [R+M] is well-suited for high expression levels in short-term bioreactor operation.     

Nucleotide sequence and characteristics of the gene for L-lactate dehydrogenase of Thermus caldophilus GK24 and the deduced amino-acid sequence of the enzyme

The gene for L-lactate dehydrogenase (LDH) (EC 1.1.1.27) of Thermus caldophilus GK24 was cloned in Escherichia coli using synthetic oligonucleotides as hybridization probes. The nucleotide sequence of the cloned DNA was determined. The primary structure of the LDH was deduced from the nucleotide sequence. The deduced amino acid sequence agreed with the NH2-terminal and COOH-terminal sequences previously reported and the determined amino acid sequences of the peptides obtained from trypsin-digested T. caldophilus LDH. The LDH comprised 310 amino acid residues and its molecular mass was determined to be 32,808. On alignment of the whole amino acid sequences, the T. caldophilus LDH showed about 40% identity with the Bacillus stearothermophilus, Lactobacillus casei and dogfish muscle LDHs. The T. caldophilus LDH gene was expressed with the E. coli lac promoter in E. coli, which resulted in the production of the thermophilic LDH. The gene for the T. caldophilus LDH showed more than 40% identity with those for the human and mouse muscle LDHs on alignment of the whole nucleotide sequences. The G + C content of the coding region for the T. caldophilus LDH was 74.1%, which was higher than that of the chromosomal DNA (67.2%). The G + C contents in the first, second and third positions of the codons used were 77.7%, 48.1% and 95.5% respectively. The high G + C content in the third base caused extremely non-random codon usage in the LDH gene. About half (48.7%) the codons in the LDH gene started with G, and hence there were relatively high contents of Val, Ala, Glu and Gly in the LDH. The contents of Pro, Arg, Ala and Gly, which have high G + C contents in their codons, were also high. Rare codons with U or A as the third base were sometimes used to avoid the TCGA sequence, the recognition site for the restriction endonuclease, TaqI. Two TCGA sequences were found only in the sequence of CTCGAG (XhoI site) in the sequenced region of the T. caldophilus DNA. There were three segments with similar sequences in the two 5' non-coding regions, probably the promoter and ribosome-binding regions, of the genes for the T. caldophilus LDH and the Thermus thermophilus 3-isopropylmalate dehydrogenase.     

High level secretion of TaqI restriction endonuclease by recombinant Escherichia coli

The production and high level secretion of TaqI restriction endonuclease using bacterial secretion signal within the malE gene was achieved by cloning the PCR-amplified gene from Thermus aquaticus into E. coli. The maltose binding protein (MBP) part of the MBP-TaqI fusion protein expressed by this construct did not interfere with the biological activity of the TaqI restriction endonuclease. E. coli XL1 carrying pH185 produced 332 U ml^–1 TaqI endonuclease 81% of which was secreted into the medium without apparent cell lysis. Optimization of culture conditions and selection of the host strain were found to be important for the efficient extracellular production of this protein.     

Binding kinetics and footprinting of TaqI endonuclease: effects of metal cofactors on sequence-specific interactions.

Restriction endonucleases achieve sequence-specific recognition and strand cleavage through the interplay of base, phosphate backbone, and metal cofactor interactions. In this study, we investigate the binding kinetics of TaqI endonuclease using the wild-type enzyme and a binding proficient, catalysis deficient mutant TaqI-D137A both in the absence of a metal cofactor and in the presence of Mg2+ or Ca2+. As demonstrated by gel mobility shift analyses, TaqI endonuclease requires a metal cofactor for achieving high-affinity specific binding to its cognate sequence, TCGA. In the absence of a metal cofactor, the enzyme binds all DNA sequences (TaqI cognate site, star site, and nonspecific site) with essentially equal affinity, thereby exhibiting little discrimination. The dissociation constant of the cognate sequence in the presence of Mg2+ at 60 degrees C is 0. 26 nM, a value comparable to our previously reported Km of 0.5 nM measured under steady-state conditions. The TaqI-TCGA-Mg2+ complex is stable, with a half-life of 21 min at 60 degrees C. The boundary of the protein-DNA interface is approximated to be about 18 bp as determined by DNase I footprinting. Data from this study support the notion that a metal cofactor plays a critical role for achieving sequence-specific discrimination in a subset of nucleases, including TaqI, EcoRV, and others.     

Nucleotide sequences of DNA encoding the 3' ends of SV40 mRNA. I. The sequence of the DNA fragment Hi-DII,III-G.

The 3' ends of the mRNA coding for the early and late proteins of SV40 DNA overlap. We have analyzed the restriction endonuclease fragment of SV40 DNA complementary to the 3' untranslated ends of the mRNA and the codons for the COOH-terminal amino acids of early and late protein. The sequence of this DNA fragment is presented.     

Identification of a plasmid-coded protein required for initiation of ColE2 DNA replication.

The product of the rep gene of ColE2 is required for initiation of ColE2 DNA replication. The rep gene was placed under the control of the promoters, PL and PR, and the heat-labile cl857 repressor of bacteriophage lambda. The Rep protein was identified as a 35 Kd protein by the maxicell method in combination with heat-induced expression. The protein was efficiently expressed from these promoters in unirradiated cells and accumulated up to a few per cent of the total cellular proteins. It was partially purified (about 80% pure) and its properties examined. The amino acid sequence of the amino terminal portion of the partially purified protein agreed well with that predicted from the nucleotide sequence of the rep gene. One of the characteristic features of the rep gene is frequent usage of rare codons, especially those for arginine. The protein specifically stimulated replication of ColE2 DNA but not that of ColE3 DNA in crude cell extracts of Escherichia coli. Specific binding of the protein to plasmid DNA containing the origin region of ColE2 was demonstrated by the filter binding method. Neither endonuclease activity nor topoisomerase activity was detected by using ColE2 DNA.     

TaqI digestion reveals fractions of satellite DNAs on human chromosomes

Restriction endonuclease TaqI has been known as a nonbanding restriction endonuclease when it is used on fixed human chromosomes. However, a specific TaqI digestion can be obtained after varying experimental conditions such as concentration of enzyme, time of incubation, and volume of the final reaction mixture. This digestion consists of an extensive DNA loss in heterochromatin subregions of chromosomes 1, 9, 15, 16, and Y. These regions essentially coincide with those corresponding to the main chromosome locations of satellite II DNA, whose tandem repeated units contain many TaqI target sequences, and some satellite III DNA domains enriched in TaqI sites.     

A genetic system for isolation and characterization of TaqI restriction endonuclease mutants

The gene encoding TaqI restriction endonuclease has been subcloned downstream from an inducible phoA promoter. Certain strains of Escherichia coli remain viable when endonuclease is expressed, even in the absence of (protective) methylation. Infecting lambda phage DNA is not restricted in vivo. One E. coli strain, MM294, exhibited a temperature-sensitive phenotype when TaqI endonuclease was induced. This allowed for design of an in vivo plate assay for identification of specially constructed two-codon insertion mutants in the endonuclease gene. These mutants exhibited a wide range of in vitro activities, including wild-type activity, greater activity in low-salt buffer, and sequence-specific nicking activity.     

Investigation of sequence homology in a group of type-II restriction/modification isoschizomers

We have dissected the cloned PstI M and R genes to make DNA hybridization probes spanning most of the sequence. These subclones, and also the intact sequence, were used to search for nucleic acid homology by Southern blot in the DNA from twelve organisms which produce PstI isoschizomers. One of these probes, a 206-bp fragment from the N-terminal domain of the endonuclease, showed significant hybridisation in four strains (Escherichia coli strains RFL48, RFL49 and RFL83, and Streptomyces albus P). No significant hybridisation was detected with other parts of the PstI sequences. We have used computer similarity searches to look for homology between the PstI proteins and the known sequences of other type-II systems that recognise different sites. We postulate a possible recognition domain within the M.PstI methyltransferase based on similarity to the M.PaeR7 and M.TaqI methyltransferases.     

Sequence homologies of diverse length tandem repetitions near ends of vaccinia virus genome suggest unequal crossing over.

The 180,000 base pair (bp), covalently closed, linear duplex DNA genome of vaccinia virus contains a 10,000 bp inverted terminal repetition within which are one set of 13 and one set of 18 tandem 70 bp repeating units. A 967 bp segment containing the innermost 70 bp repeat and an adjacent region notable for a scarcity of restriction endonuclease sites has been sequenced. This was facilitated by the cloning of TaqI and partial TaqI fragments in pBR322. We found that the innermost 70 bp repeat overlaps one of two adjacent 125 bp repeats, following which are eight repeats of 54 bp, parts of 54 bp and 70 bp repeats, and four consecutive 6 to 7 bp repeats. The 70, 125, and 54 bp repeating units have extensive sequence homologies and redundancies that suggest evolution by unequal crossing over. Schemes whereby unequal crossovers of 54 bp repeats lead to a recombinant segment 86% homologous to the 125 bp repeat and unequal crossovers of 125 bp repeats lead to a recombinant segment 94% homologous to the 70 bp repeat were considered. This propensity for sequence divergence should provide a useful marker for comparing the relatedness of poxviruses.     

Partial characterization of a DNA restriction endonuclease from Ruminococcus flavefaciens FD-1 and its inhibition by site-specific adenine methylation.

The principal DNA restriction-modification system of the cellulolytic ruminal bacterium Ruminococcus flavefaciens FD-1 is described. The restriction endonuclease RflFI could be separated from cell extracts by phosphocellulose and heparin-sepharose chromatography. Restriction enzyme digests utilizing RflFI alone or in combination with SalI, a restriction enzyme isolated from Streptomyces albus G, showed that the DNA sequence recognized by RflFI either overlapped or was the same as that recognized by SalI. DNA sequence analysis confirmed that RflFI was identical in activity to SalI, with the recognition sequence being 5'-GTCGAC-3' and cleavage occurring between G and T. Adenine methylation within this sequence can be catalyzed in vitro by TaqI methylase, and this inhibited the cleavage of plasmid DNA molecules by RflFI and SalI. Chromosomal DNA from R. flavefaciens FD-1 is also methylated within this DNA sequence because neither restriction endonuclease could degrade this DNA substrate. These findings provide a means to protect plasmid molecules from degradation prior to gene transfer experiments with R. flavefaciens FD-1.     

mRNA sequence predictions from homologous protein sequences

A model has been developed that permits the prediction of mRNA nucleic acid sequence from the sequences of the translated proteins. The model relies on the information obtained from the comparison of protein sequences in related species to reduce the number of possible codons for those amino acids where mutations are observed. The predictions so obtained have been tested by applying the model to proteins whose mRNA sequences are known. The model's predictions have been found to be 100% accurate if three or more different amino acids are known at a given position and if the protein sequences are restricted to relatively closely related species (within the same class). The use of this model may permit a reduction of the mRNA sequence degeneracy and therefore be helpful in the synthesis of cDNA probes or for the prediction of restriction endonuclease sites. Computer programs have been developed to ease the use of the model.     

Partial characterization of a DNA restriction endonuclease from Ruminococcus flavefaciens FD-1 and its inhibition by site-specific adenine methylation.

The principal DNA restriction-modification system of the cellulolytic ruminal bacterium Ruminococcus flavefaciens FD-1 is described. The restriction endonuclease RflFI could be separated from cell extracts by phosphocellulose and heparin-sepharose chromatography. Restriction enzyme digests utilizing RflFI alone or in combination with SalI, a restriction enzyme isolated from Streptomyces albus G, showed that the DNA sequence recognized by RflFI either overlapped or was the same as that recognized by SalI. DNA sequence analysis confirmed that RflFI was identical in activity to SalI, with the recognition sequence being 5'-GTCGAC-3' and cleavage occurring between G and T. Adenine methylation within this sequence can be catalyzed in vitro by TaqI methylase, and this inhibited the cleavage of plasmid DNA molecules by RflFI and SalI. Chromosomal DNA from R. flavefaciens FD-1 is also methylated within this DNA sequence because neither restriction endonuclease could degrade this DNA substrate. These findings provide a means to protect plasmid molecules from degradation prior to gene transfer experiments with R. flavefaciens FD-1.     

Nucleotide sequence and functional map of pE194, a plasmid that specifies inducible resistance to macrolide, lincosamide, and streptogramin type B antibodies.

pE194 is a small plasmid (isolated originally in Staphylococcus aureus) which confers erythromycin-inducible resistance to macrolide, lincosamide, and streptogramin type B (MLS) antibiotics. The nucleotide sequence of pE194 contains 3,728 base pairs (bp), corresponding to a molecular mass of 2.4 million daltons. By means of site-specific cleavage with restriction endonucleases and cloning resultant fragments, determinants of the two major biological functions of p E194, i.e., inducible MLS resistance and replication, could be localized and assigned to specific sequences in the plasmid. Restriction endonuclease TaqI cut pE194 at three sites. TaqI fragment A (1,443 bp) contained the determinant for inducible MLS resistance, whereas TaqI fragment B (1,354 bp) contained a determinant necessary for plasmid replication. Regulatory mutations resulting in constitutive expression of MLS resistance mapped in TaqI fragment A, whereas a mutation associated with elevated plasmid copy number was mapped in TaqI fragment B. Also mapping in TaqI fragment B was a plasmid replication determinant comprising two sets of inverted complementary repeat sequences, one of which spanned 124 bp and was adjacent to a second smaller set which was rich in guanine and cytosine residues. pE194 contained six open reading frames which were theoretically capable of coding for proteins with maximum molecular masses as follows (in daltons): A, 48,300; B, 29,200; C, 14,000; D, 13,900; E, 12,600; and F, 2,700. Insertion of plasmid pBR322 into the single PstI site located in frame A of pE194 resulted in a composite plasmid which could replicate in both Bacillus subtilis and Escherichia coli, suggesting that an intact polypeptide A is dispensable for both replication of pE194 and for MLS resistance. Frame B specified inducible MLS resistance, whereas frame F specified the putative peptide associated with the proposed B determinant translational attenuator. The extent to which frames C, D, and E, all contained in TaqI fragment B, were translated into polypeptide products is not known; however, a base change in frame E was found in a comparison between the high-copy-number mutant, cop-6, and the wild-type strains.     

Structure and evolution of the XcyI restriction-modification system.

The XcyI restriction-modification system from Xanthomonas cyanopsidis recognizes the sequence, CCCGGG. The XcyI endonuclease and methylase genes have been cloned and sequenced and were found to be aligned in a head to tail orientation with the methylase preceding and overlapping the endonuclease by one base pair. The nucleotide sequence codes for an N4 cytosine methyltransferase with a predicted molecular weight of 33,500 and an endonuclease comprised of 333 codons and a molecular weight of 36,600. Sequence comparisons revealed significant similarity between the XcyI, CfrI and SmaI methylisomers. In contrast, no similarity was detected between the primary structures of the XcyI and SmaI endonucleases. The XcyI restriction-modification system is highly homologous to the XmaI genes, although the DNA sequences flanking the genes rapidly diverge. The sequence of the XcyI endonuclease contains two motifs which have recently been identified as essential to the activity of the EcoRV endonuclease.