Redundant exonuclease involvement in Escherichia coli methyl-directed mismatch repair.

Previous biochemical analysis of Escherichia coli methyl-directed mismatch repair implicates three redundant single-strand DNA-specific exonucleases (RecJ, ExoI, and ExoVII) and at least one additional unknown exonuclease in the excision reaction (Cooper, D. L., Lahue, R. S., and Modrich, P. (1993) J. Biol. Chem. 268, 11823-11829). We show here that ExoX also participates in methyl-directed mismatch repair. Analysis of the reaction with crude extracts and purified components demonstrated that ExoX can mediate repair directed from a strand signal 3' of a mismatch. Whereas extracts of all possible single, double, and triple exonuclease mutants displayed significant residual mismatch repair, extracts deficient in RecJ, ExoI, ExoVII, and ExoX exonucleases were devoid of normal repair activity. The RecJ(-) ExoVII(-) ExoI(-) ExoX(-) strain displayed a 7-fold increase in mutation rate, a significant increase, but less than that observed for other blocks of the mismatch repair pathway. This elevation is epistatic to deficiency for MutS, suggesting an effect via the mismatch repair pathway. Our other work (Burdett, V., Baitinger, C., Viswanathan, M., Lovett, S. T., and Modrich, P. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 6765-6770) suggests that mutants are under-recovered in the exonuclease-deficient strain due to loss of viability that is triggered by mismatched base pairs in this genetic background. The availability of any one exonuclease is enough to support full mismatch correction, as evident from the normal mutation rates of all triple mutants. Because three of these exonucleases possess a strict polarity of digestion, this suggests that mismatch repair can occur exclusively from a 3' or a 5' direction to the mismatch, if necessary.

In vivo requirement for RecJ, ExoVII, ExoI, and ExoX in methyl-directed mismatch repair.

Biochemical studies with model DNA heteroduplexes have implicated RecJ exonuclease, exonuclease VII, exonuclease I, and exonuclease X in Escherichia coli methyl-directed mismatch correction. However, strains deficient in the four exonucleases display only a modest increase in mutation rate, raising questions concerning involvement of these activities in mismatch repair in vivo. The quadruple mutant deficient in the four exonucleases, as well as the triple mutant deficient in RecJ exonuclease, exonuclease VII, and exonuclease I, grow poorly in the presence of the base analogue 2-aminopurine, and exposure to the base analogue results in filament formation, indicative of induction of SOS DNA damage response. The growth defect and filamentation phenotypes associated with 2-aminopurine exposure are effectively suppressed by null mutations in mutH, mutL, mutS, or uvrD/mutU, which encode activities that act upstream of the four exonucleases in the mechanism for the methyl-directed reaction that has been proposed based on in vitro studies. The quadruple exonuclease mutant is also cold-sensitive, having a severe growth defect at 30 degrees C. This phenotype is suppressed by a uvrD/mutU defect, and partially suppressed by mutH, mutL, or mutS mutations. These observations confirm involvement of the four exonucleases in methyl-directed mismatch repair in vivo and suggest that the low mutability of exonuclease-deficient strains is a consequence of under recovery of mutants due to a reduction in viability and/or chromosome loss associated with activation of the mismatch repair system in the absence of RecJ exonuclease, exonuclease VII, exonuclease I, and exonuclease X.

Nomenclature for new tetracycline resistance determinants.

Letters of the English alphabet have heretofore been used to name tetracycline resistance determinants. Since all 26 letters have now been used, a nomenclature employing numerals is recommended for future determinants, and one laboratory has offered to coordinate the assignment of numerals.

Binding interaction between Tet(M) and the ribosome: requirements for binding.

Tet(M) protein interacts with the protein biosynthesis machinery to render this process resistant to tetracycline by a mechanism which involves release of the antibiotic from the ribosome in a reaction dependent on GTP hydrolysis. To clarify this resistance mechanism further, the interaction of Tet(M) with the ribosome has been examined by using a gel filtration assay with radioactively labelled Tet(M) protein. The presence of GTP and 5'-guanylyl imido diphosphate, but not GDP, promoted Tet(M)-ribosome complex formation. Furthermore, thiostrepton, which inhibits the activities of elongation factor G (EF-G) and EF-Tu by binding to the ribosome, blocks stable Tet(M)-ribosome complex formation. Direct competition experiments show that Tet(M) and EF-G bind to overlapping sites on the ribosome.

Tet(M)-promoted release of tetracycline from ribosomes is GTP dependent.

Tet(M) protein, which displays homology to elongation factor G (EF-G), interacts with the protein biosynthetic machinery to render this process resistant to tetracycline in vivo and in vitro. To clarify the basis of the resistance mechanism, the effects of Tet(M) on several reactions which occur during protein synthesis were examined. The mechanism of action of Tet(M) has been clarified by two observations. The protein relieves tetracycline inhibition of factor-dependent tRNA binding and dramatically reduces the affinity of ribosomes for tetracycline when GTP is present. This reduction in drug affinity appears to be due to a large increase in the rate of tetracycline dissociation. Addition of Tet(M) to ribosome-tetracycline complexes results in displacement of bound drug. And, while Tet(M) and EF-G GTPase activities are tetracycline resistant, the two proteins differ in their sensitivities to fusidic acid, with the latter activity inhibited by the drug. Furthermore, while Tet(M) protects translation from tetracycline inhibition in a defined system, it is unable to substitute for either EF-G or elongation factor Tu.

tRNA modification activity is necessary for Tet(M)-mediated tetracycline resistance.

Tet(M) protein interacts with the protein biosynthetic machinery to render this process resistant to the tetracycline in vivo and in vitro (V. Burdett, J. Biol. Chem. 266:2872-2877, 1991). To understand this process more completely, a mutant of Escherichia coli which is altered in the ability of Tet(M) to confer resistance has been identified. This mutation maps to miaA and displays phenotypes characteristic of previously isolated miaA mutations. The miaA gene product modifies A37 adjacent to the anticodon of several tRNA species. Both the mutant isolated in this work and previously isolated miaA mutants confer tetracycline sensitivity in the presence of functional Tet(M), both share a slow growth phenotype, and in neither case is a wild-type phenotype restored in trans by F'112 carrying the 89- to 98-min region of the chromosome. These similar phenotypes further substantiate the assignment of the mutation described here to the miaA locus.

Purification and characterization of Tet(M), a protein that renders ribosomes resistant to tetracycline.

The tet(M) tetracycline resistance gene has been found in a wide variety of clinically important bacteria. It has been shown previously (Burdett, V. (1986) J. Bacteriol. 165, 564-569) that the tet(M) gene product mediates resistance at the level of protein synthesis as judged by in vitro assay. Using this assay, large amounts of protein were purified from an Escherichia coli overproducer expressing the gene under control of a T7 promoter. The purified activity consists of a single polypeptide of molecular weight 68,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and was confirmed to be the tet(M) gene product by amino-terminal sequence analysis. Purified Tet(M) has an associated ribosome-dependent GTPase with the specific activity being similar to that of the corresponding activity associated with elongation factor G. Since Tet(M) also displays substantial homology to elongation factor G throughout its length, Tet(M) may function as an analog of this elongation factor.

Nomenclature for tetracycline resistance determinants.

Tetracycline resistance determinants are widespread and distinguishable genetically and biochemically. The nomenclature for this increasing number of determinants has been varied and inconsistent. This communication suggests ways of naming these determinants and their genes and gene products consistent with current genetic terminology.

Conservation of protective and nonprotective epitopes in M proteins of group A streptococci.

Carefully controlled hybridization experiments with probes from a cloned serotype 5 M protein (M5) gene (smp5) were performed with DNA isolated from heterologous M types of group A streptococci, and the homologies detected by hybridization were compared with the ability of anti-pepM5 serum to cross-opsonize heterologous M types. As previously reported (J.R. Scott, S.K. Hollingshead, and V.A. Fischetti, Infect. Immun. 52:609-612, 1986), extensive structural homologies exist among the 3' ends of heterologous M protein genes, but there appears to be an increase in sequence variation as one moves towards the 5' ends. However, a clear, predictive correlation between the hybridization patterns and cross-opsonization was not observed. Antibodies raised to a synthetic peptide corresponding to central, conserved sequences adjacent to the C-terminal sides of the pepsin cleavage sites in M5, serotype 6 M protein, and serotype 24 M protein cross-reacted with heterologous acid-extracted M antigens but were not protective and did not bind to intact streptococcal cells, indicating that these epitopes are inaccessible on the intact cell surface. Removal of the N-terminal half of M5, serotype 6 M protein, or serotype 24 M protein by pepsin exposed the conserved epitope on the cell surface. These results suggest that immunoaccessible protective epitopes are confined to the highly variable N-terminal halves of M proteins and that a single, broadly conserved protective M protein epitope does not exist.

Comparison of the leader sequences of four group A streptococcal M protein genes.

The 5' portions and flanking sequences of genes encoding types 1, 12, 24, and 6 M proteins were compared. Although the DNA sequences encoding the amino-termini of the mature M proteins had no obvious similarity, upstream sequences, and those encoding the signal peptides (leader sequences) of the four M protein genes had considerable similarity. In general, the 5' ends of all the leader sequences were more conserved than the 3' ends, although the M6 and M24 leader sequences had identical 3' ends. Sequence similarity among the deduced amino acid sequences of the four signal peptides was more extensive than the corresponding DNA sequences. We found that strict DNA similarity among all four sequences extended only to the ends of the hydrophilic amino-terminal regions of the signal peptides, but that amino acid sequence conservation continued to the ends of the respective hydrophobic cores. With the exception of the M6 and M24 sequences, the regions adjacent to the signal peptidase cleavage sites were highly variable.

Molecular evolution of streptococcal M protein: cloning and nucleotide sequence of the type 24 M protein gene and relation to other genes of Streptococcus pyogenes.

The structural gene for the type 24 M protein of group A streptococci has been cloned and expressed in Escherichia coli. The complete nucleotide sequence of the gene and the 3' and 5' flanking regions was determined. The sequence includes an open reading frame of 1,617 base pairs encoding a pre-M24 protein of 539 amino acids and a predicted Mr of 58,738. The structural gene contains two distinct tandemly reiterated elements. The first repeated element consists of 5.3 units, and the second contains 2.7 units. Each element shows little variation of the basic 35-amino-acid unit. Comparison of the sequence of the M24 protein with the sequence of the M6 protein (S. K. Hollingshead, V. A. Fischetti, and J. R. Scott, J. Biol. Chem. 261:1677-1686, 1986) indicates that these molecules have are conserved except in the regions coding for the antigenic (type specific) determinant and they have three regions of homology within the structural genes: 38 of 42 amino acids within the amino terminal signal sequence, the second repeated element of the M24 protein is found in the M6 molecule at the same position in the protein, and the carboxy terminal 164 amino acids, including a membrane anchor sequence, are conserved in both proteins. In addition, the sequences flanking the two genes are strongly conserved.

Energy-dependent efflux mediated by class L (tetL) tetracycline resistance determinant from streptococci.

The class L (TetL) tetracycline resistance determinant from streptococci specified resistance and an energy-dependent decreased accumulation of tetracycline in both Streptococcus faecalis and Escherichia coli. Using E. coli, we showed that the reduced uptake resulted from active efflux. The streptococcal class M determinant, known to render the protein synthesis machinery of S. faecalis resistant to tetracycline inhibition, did not alter tetracycline transport in either host.

Streptococcal tetracycline resistance mediated at the level of protein synthesis.

The mechanism of tetracycline resistance was examined in strains containing each of the three previously identified resistance determinants in Streptococcus spp. Uptake of tetracycline was measured in tetracycline-sensitive cells as well as in cells containing each of the three resistance determinants. In cells containing tetL, uptake was not observed. However, in sensitive cells and cells containing either tetM or tetN, tetracycline was accumulated approximately 25-fold against a concentration gradient. Furthermore, there was no evidence for modification of intracellular tetracycline recovered from sensitive, tetM, or tetN cells. Protein synthesis in extracts derived from organisms containing tetM or tetN was resistant to tetracycline. In contrast, extracts of sensitive and tetL cells were sensitive to tetracycline.

Structural organization of a 67-kilobase streptococcal conjugative element mediating multiple antibiotic resistance.

The molecular organization of the conjugative cat-erm-tet region of Streptococcus agalactiae B109 was examined by cloning large contiguous portions of the strain B109 chromosome, using a cosmid vector system. The organization of this region was compared with pDP5, a plasmid which acquired this resistance element by transposition. Both the chromosomal copy and the transposed copy of the resistance region were found to be 67-kilobases long, although sequences at the boundary of the transposed copy of the element showed some rearrangement. In addition to the stable chromosomal state, we present evidence which suggests the presence of a circular form of the element.

Heterogeneity of tetracycline resistance determinants in Streptococcus.

We found that naturally occurring tetracycline resistance in streptococci is encoded by more than one genetic determinant. Two of these distinct determinants were cloned, and the regions that are necessary and sufficient for expression of tetracycline resistance were defined by deletion analysis. These cloned determinants were further characterized by DNA-DNA hybridization experiments which also identified a third genetically unrelated tetracycline resistance determinant. Some of these genetic differences appear to represent mechanistic differences. The tetL determinant was associated with small nonconjugative plasmids and mediated resistance to tetracycline. The tetM determinant was most often "nonplasmid" associated and mediated resistance to minocycline as well as tetracycline. The tetN determinant was represented on a large conjugative plasmid and was genetically distinct from tetL and tetM, although phenotypically it resembled tetM.

Identification of tetracycline-resistant R-plasmids in Streptococcus agalactiae (group B).

In this report, 30 tetracycline-resistant clinical isolates of group B Streptococcus were examined to assess the extent to which tetracycline resistance is plasmid mediated. Of these, 27 showed no physical or genetic evidence of plasmid-mediated resistance; however, one conjugative and two small (3.5 X 10(6)-dalton) multicopy non-self-transmissible tetracycline resistance plasmids were identified. The conjugative plasmid was transmissible to Streptococcus faecalis as well as to Streptococcus agalactiae (group B). The two nonconjugative plasmids were readily mobilized by a number of sex factors into these same two backgrounds and, in addition, readily transformed Streptococcus sanguis Challis to tetracycline resistance. Due to readily available sites for several site-specific endonuycleases, these small, multicopy plasmids should prove useful as cloning vehicles in this host system.