A DNA repair process in Escherichia coli corrects U:G and T:G mismatches to C:G at sites of cytosine methylation

Escherichia coli contains a base mismatch correction system called VSP repair that is known to correct T:G mismatches to C:G when they occur in certain sequence contexts. The preferred sequence context for this process is the site for methylation by the E. coli DNA cytosine methylase (Dcm). For this reason, VSP repair is thought to counteract potential mutagenic effects of deamination of 5-methylcytosine to thymine. We have developed a genetic reversion assay that quantitates the frequency of C to T mutations at Dcm sites and the removal of such mutations by DNA repair processes. Using this assay, we have studied the repair of U: G mismatches in DNA to C: G and have found that VSP repair is capable of correcting these mismatches. Although VSP repair substantially affects the reversion frequency, it may not be as efficient at correcting U: G mismatches as the uracil DNA glycosylase-mediated repair process.     

The excision of 3′ penultimate errors by DNA polymerase I and its role in endonuclease V-mediated DNA repair

Deamination of adenine can occur spontaneously under physiological conditions, and is enhanced by exposure of DNA to ionizing radiation, UV light, nitrous acid, or heat, generating the highly mutagenic lesion of deoxyinosine in DNA. Such DNA lesions tends to generate A:T to G:C transition mutations if unrepaired. In Escherichia coli, deoxyinosine is primarily removed through a repair pathway initiated by endonuclease V (endo V). In this study, we compared the repair of three mutagenic deoxyinosine lesions of A-I, G-I, and T-I using E. coli cell-free extracts as well as reconstituted protein system. We found that 3′-5′ exonuclease activity of DNA polymerase I (pol I) was very important for processing all deoxyinosine lesions. To understand the nature of pol I in removing damaged nucleotides, we systemically analyzed its proofreading to 12 possible mismatches 3′-penultimate of a nick, a configuration that represents a repair intermediate generated by endo V. The results showed all mismatches as well as deoxyinosine at the 3′ penultimate site were corrected with similar efficiency. This study strongly supports for the idea that the 3′-5′ exonuclease activity of E. coli pol I is the primary exonuclease activity for removing 3′-penultimate deoxyinosines derived from endo V nicking reaction.     

Molecular cloning and expression characterization of translationally controlled tumor protein in silkworm pupae

A Bombyx mori (B. mori) cDNA was isolated from silkworm pupae cDNA library encoding a homologue of translationally controlled tumor protein (BmTCTPk). BmTCTPk was expressed in E. coli; SDS–PAGE and Western blot showed the molecular weight of recombinant and native BmTCTPk is approximately 28 and 25 kDa, respectively; they are larger than the theoretical molecular weight. Immunohistochemical studies showed that BmTCTPk is uniformly distributed throughout the cytoplasm of BmN cells. In silkworm pupae, BmTCTPk is expressed in the midgut wall, the midgut cavity, and some fat body tissues lying between the midgut wall and body wall. Western blot and ELISAs performed on total protein extracts isolated from silkworm pupae at different development stages showed that, although BmTCTPk is expressed during all pupae stages, its expression level increases dramatically during late pupae stages, suggesting that BmTCTPk may play an important role during the developmental transition from pupa to imago.     

Switching base preferences of mismatch cleavage in endonuclease V: an improved method for scanning point mutations

Endonuclease V (endo V) recognizes a broad range of aberrations in DNA such as deaminated bases or mismatches. It nicks DNA at the second phosphodiester bond 3′ to a deaminated base or a mismatch. Endonuclease V obtained from Thermotoga maritima preferentially cleaves purine mismatches in certain sequence context. Endonuclease V has been combined with a high-fidelity DNA ligase to develop an enzymatic method for mutation scanning. A biochemical screening of site-directed mutants identified mutants in motifs III and IV that altered the base preferences in mismatch cleavage. Most profoundly, a single alanine substitution at Y80 position switched the enzyme to essentially a C-specific mismatch endonuclease, which recognized and cleaved A/C, C/A, T/C, C/T and even the previously refractory C/C mismatches. Y80A can also detect the G13D mutation in K-ras oncogene, an A/C mismatch embedded in a G/C rich sequence context that was previously inaccessible using the wild-type endo V. This investigation offers insights on base recognition and active site organization. Protein engineering in endo V may translate into better tools in mutation recognition and cancer mutation scanning.     

A DNA repair process in Escherichia coli corrects U:G and T:G mismatches to C:G at sites of cytosine methylation

Escherichia coli contains a base mismatch correction system called VSP repair that is known to correct T:G mismatches to C:G when they occur in certain sequence contexts. The preferred sequence context for this process is the site for methylation by the E. coli DNA cytosine methylase (Dcm). For this reason, VSP repair is thought to counteract potential mutagenic effects of deamination of 5-methylcytosine to thymine. We have developed a genetic reversion assay that quantitates the frequency of C to T mutations at Dcm sites and the removal of such mutations by DNA repair processes. Using this assay, we have studied the repair of U: G mismatches in DNA to C: G and have found that VSP repair is capable of correcting these mismatches. Although VSP repair substantially affects the reversion frequency, it may not be as efficient at correcting U: G mismatches as the uracil DNA glycosylase-mediated repair process.     

Biochemical analysis of the substrate specificity and sequence preference of endonuclease IV from bacteriophage T4, a dC-specific endonuclease implicated in restriction of dC-substituted T4 DNA synthesis

Endonuclease IV encoded by denB of bacteriophage T4 is implicated in restriction of deoxycytidine (dC)-containing DNA in the host Escherichia coli. The enzyme was synthesized with the use of a wheat germ cell-free protein synthesis system, given a lethal effect of its expression in E.coli cells, and was purified to homogeneity. The purified enzyme showed high activity with single-stranded (ss) DNA and denatured dC-substituted T4 genomic double-stranded (ds) DNA but exhibited no activity with dsDNA, ssRNA or denatured T4 genomic dsDNA containing glucosylated deoxyhydroxymethylcytidine. Characterization of Endo IV activity revealed that the enzyme catalyzed specific endonucleolytic cleavage of the 5′ phosphodiester bond of dC in ssDNA with an efficiency markedly dependent on the surrounding nucleotide sequence. The enzyme preferentially targeted 5′-dTdCdA-3′ but tolerated various combinations of individual nucleotides flanking this trinucleotide sequence. These results suggest that Endo IV preferentially recognizes short nucleotide sequences containing 5′-dTdCdA-3′, which likely accounts for the limited digestion of ssDNA by the enzyme and may be responsible in part for the indispensability of a deficiency in denB for stable synthesis of dC-substituted T4 genomic DNA.     

Identification of a mismatch-specific endonuclease in hyperthermophilic Archaea

The common mismatch repair system processed by MutS and MutL and their homologs was identified in Bacteria and Eukarya. However, no evidence of a functional MutS/L homolog has been reported for archaeal organisms, and it is not known whether the mismatch repair system is conserved in Archaea. Here, we describe an endonuclease that cleaves double-stranded DNA containing a mismatched base pair, from the hyperthermophilic archaeon Pyrococcus furiosus. The corresponding gene revealed that the activity originates from PF0012, and we named this enzyme Endonuclease MS (EndoMS) as the mismatch-specific Endonuclease. The sequence similarity suggested that EndoMS is the ortholog of NucS isolated from Pyrococcus abyssi, published previously. Biochemical characterizations of the EndoMS homolog from Thermococcus kodakarensis clearly showed that EndoMS specifically cleaves both strands of double-stranded DNA into 5′-protruding forms, with the mismatched base pair in the central position. EndoMS cleaves G/T, G/G, T/T, T/C and A/G mismatches, with a more preference for G/T, G/G and T/T, but has very little or no effect on C/C, A/C and A/A mismatches. The discovery of this endonuclease suggests the existence of a novel mismatch repair process, initiated by the double-strand break generated by the EndoMS endonuclease, in Archaea and some Bacteria.     

Insect immunity: Early fate of bacteria injected in saturniid pupae

Saturniid pupae have previously been shown to synthesize a set of antibacterial proteins in response to an injection of viable nonpathogenic bacteria (Boman, H. G., Nilsson-Faye, I., Paul, K., and Rasmuson, T., Jr. 1974. Insect immunity. I. Characteristics of an inducible cell-free antibacterial reaction hemolymph of Samia cynthia pupae; Infec. Immun., 10, 136–145; Faye, I., Pye, A., Rasmuson, T., Boman, H. G., and Boman, I. A. 1975. Insect immunity. II. Simultaneous induction of antibacterial activity and selective synthesis of some hemolymph proteins in diapausing pupae of Hyalophora cecropia and Samia cynthia). Infec. Immun., 12, 1426–1438). It show here that two such injected bacteria, Enterobacter cloacae and Escherichia coli, were rapidly eliminated from the hemolymph. The distribution of the injected bacteria was studied by the use of radioactively labeled E. coli, which were traced by combustion of tissue samples and by radioautography. Both methods showed that the bacteria appeared most frequently in the upper distal ends of the pupae. In the radioautographic study this was expressed as a high number of silver grain-containing cells. These cells appeared singly or as two to five cells clumped together, preferentially attached to the fat body. No decisive effect was shown on either the elimination of bacteria from hemolymph or the appearance in the tissue when pupae were treated with actinomycin D or cycloheximide. Phagocytosis by adhesive hemocytes is discussed as an explanation of bacterial elimination from the hemolymph.     

Detection of 81 of 81 Known Mouse β-Globin Promoter Mutations with T4 Endonuclease VII—The EMC Method

The enzyme mismatch cleavage (EMC) method relies on the use of the resolvase T4 Endonuclease VII to cleave and thus detect mismatches in heteroduplex DNA formed by annealing normal DNA with mutant DNA. Detection is based on cleavage 3′ to the mismatch within a few nucleotides. We report the detection of all 81 different homozygous single-basepair changes tested and present in the mouse β-globin promoter by using the EMC method with a single set of conditions. Efficiency of cleavage was rated as strong, medium, or weak based on the intensity of the cleavage product(s) compared with background bands on autoradiography. We expect this method to detect near 100% of mutations.     

Lack of correlation between binding of Eco RII methyltransferase to DNA duplexes containing mismatches and the promotion of C to T mutations

The cytosine methyltransferases (MTases) M. HhaIand M. HpaII bind substrates in which the target cytosine is replaced by uracil or thymine, i.e. DNA containing a U:G or a T:G mismatch. We have extended this observation to the EcoRII MTase (M. EcoRII) and determined the apparent K_d for binding. Using a genetic assay we have also tested the possibility that MTase binding to U:G mismatches may interfere with repair of the mismatches and promote C:G to T:A mutations. We have compared two mutants of M. EcoRII that are defective for catalysis by the wild-type enzyme for their ability to bind DNA containing U:G or T:G mismatches and for their ability to promote C to T mutations. We find that although all three proteins are able to bind DNAs with mismatches, only the wild-type enzyme promotes C:G to T:A mutations in vivo. Therefore, the ability of M. EcoRII to bind U:G mismatched duplexes is not sufficient for their mutagenic action in cells.     

Bacteriophage T7 DNA Synthesis in Isolated DNA-Membrane Complexes

A DNA-membrane complex isolated from Escherichia coli infected with bacteriophage T7 contains newly synthesized T7 DNA and the T7 DNA polymerase (gene 5 product). The DNA present in the complex appears to exist as a concatemer which contains single-strand breaks and possibly internal single-stranded regions (gaps). The complex is capable of synthesizing T7 DNA by using endogenous template, and part of the DNA is made by a semiconservative mechanism. A portion of the in vitro synthesized DNA sediments in alkaline sucrose as 10-11S material. This DNA is converted to a larger-molecular-weight material after treatment with T4 polynucleotide ligase and E. coli DNA polymerase I.     

Replication fidelity in E. coli: Differential leading and lagging strand effects for dnaE antimutator alleles

DNA Pol III holoenzyme (HE) is the major DNA replicase of Escherichia coli. It is a highly accurate enzyme responsible for simultaneously replicating the leading- and lagging DNA strands. Interestingly, the fidelity of replication for the two DNA strands is unequal, with a higher accuracy for lagging-strand replication. We have previously proposed this higher lagging-strand fidelity results from the more dissociative character of the lagging-strand polymerase. In support of this hypothesis, an E. coli mutant carrying a catalytic DNA polymerase subunit (DnaE915) characterized by decreased processivity yielded an antimutator phenotype (higher fidelity). The present work was undertaken to gain deeper insight into the factors that influence the fidelity of chromosomal DNA replication in E. coli. We used three different dnaE alleles (dnaE915, dnaE911, and dnaE941) that had previously been isolated as antimutators. We confirmed that each of the three dnaE alleles produced significant antimutator effects, but in addition showed that these antimutator effects proved largest for the normally less accurate leading strand. Additionally, in the presence of error-prone DNA polymerases, each of the three dnaE antimutator strains turned into mutators. The combined observations are fully supportive of our model in which the dissociative character of the DNA polymerase is an important determinant of in vivo replication fidelity. In this model, increased dissociation from terminal mismatches (i.e., potential mutations) leads to removal of the mismatches (antimutator effect), but in the presence of error-prone (or translesion) DNA polymerases the abandoned terminal mismatches become targets for error-prone extension (mutator effect). We also propose that these dnaE alleles are promising tools for studying polymerase exchanges at the replication fork.     

Functional expression of cloned yeast DNA in Escherichia coli: specific complementation of argininosuccinate lyase (argH) mutations.

Segments of yeast (Saccharomyces cerevisiae) DNA cloned on various plasmid vectors in Escherichia coli can be functionally expressed to produce active enzymes. We have identified several ColE1-DNA(yeast) plasmids capable of complementing argH mutations, including deletions, in E. coli. Variants of the original transformants that grow faster on selective media and contain higher levels of the complementing enzyme activity (argininosuccinate lyase) can be readily isolated. The genetic alterations leading to increased expression of the yeast gene are associated with the cloned yeast DNA segment, rather than the host genome. The yeast DNA segment cloned in these plasmids also specifies a suppressor of the leuB6 mutation in E. coli. The argH and leuB6 complementing activities are expressed from discrete regions of the cloned yeast DNA segment, since the two genetic functions can be separated on individual recloned restriction fragments. The ease with which the bacterial cell can achieve functional high-level gene expression from cloned yeast DNA indicates that there are no significant barriers preventing expression of many yeast genes in E. coli.     

In Vitro Processing of Heteroduplex Loops and Mismatches by Endonuclease VII

Endonuclease VII is a Holliday-structure resolving enzyme ofphage T4 which cleaves at junctions of branched DNAs and atmispairings. In extension of these findings we report the following:i) Endonuclease VII can discriminate between a large heteroduplexloop and a TT mismatch arranged in tandem, 6 nt distant fromeach other, in the same heteroduplex molecule. The enzyme cleavestwo nucleotides 3' from the base of the loop or the TT mismatch.ii) Similar to its reactions with mismatches cleavage of heteroduplexloops by endonucleave VII can also initiate correction of perfectdouble-strandedness by T4 DNA polymerase and T4 DNA-ligase invitro. Loops of 8 nt and 20 nt were repaired efficiently. iii)For the first time endonuclease VII cleavage sites were alsomapped in single-stranded DNA if it was part of the 20-nt loop.This suggests that looping of single-stranded DNA can induceformation of secondary structures, which are recognizable byendonuclease VII.     

Identification of proteins of Escherichia coli and Saccharomyces cerevisiae that specifically bind to C/C mismatches in DNA

The pathways leading to G:C→C:G transversions and their repair mechanisms remain uncertain. C/C and G/G mismatches arising during DNA replication are a potential source of G:C→C:G transversions. The Escherichia coli mutHLS mismatch repair pathway efficiently corrects G/G mismatches, whereas C/C mismatches are a poor substrate. Escherichia coli must have a more specific repair pathway to correct C/C mismatches. In this study, we performed gel-shift assays to identify C/C mismatch-binding proteins in cell extracts of E.coli. By testing heteroduplex DNA (34mers) containing C/C mismatches, two specific band shifts were generated in the gels. The band shifts were due to mismatch-specific binding of proteins present in the extracts. Cell extracts of a mutant strain defective in MutM protein did not produce a low-mobility complex. Purified MutM protein bound efficiently to the C/C mismatch-containing heteroduplex to produce the low-mobility complex. The second protein, which produced a high-mobility complex with the C/C mismatches, was purified to homogeneity, and the amino acid sequence revealed that this protein was the FabA protein of E.coli. The high-mobility complex was not formed in cell extracts of a fabA mutant. From these results it is possible that MutM and FabA proteins are components of repair pathways for C/C mismatches in E.coli. Furthermore, we found that Saccharomyces cerevisiae OGG1 protein, a functional homolog of E.coli MutM protein, could specifically bind to the C/C mismatches in DNA.     

Molecular studies on thiaminase I

The thiaminase I gene of Bacillus thiaminolyticus was cloned on a 1.6 kb DNA fragment (enzyme molecular weight 42 000), and was expressed in both Escherichia coli and Bacillus subtilis. When a selection drug was absent, the plasmid was maintained stably for approx. 100 generations in wild-type E. coli. Instability of the thiaminase gene was demonstrated in the thiamin pyrophosphate-requiring mutant of E. coli from which the plasmid was deleted rapidly. Wild-type E. coli accumulated the enzyme in its periplasm. A method for the detection of thiaminase I enzyme in SDS-polyacrylamide gel was developed. Thiaminase I of B. thiaminolyticus was found to exist in two sizes, 44 and 42 kDa, among different strains. Moreover, thiaminase of 42 kDa became approximately 41 kDa after a long-term culture, most likely because of the action of proteinases. Thiaminase expressed in E. coli from a thiaminase-positive recombinant plasmid was 42 kDa, and showed the same mobility on SDS-polyacrylamide gele electrophoresis as the enzyme isolated from the young culture of the parent strain of B. thiaminolyticus used for cloning. This value was, therefore, considered to represent intact thiaminase that had escaped from the attack of bacilli proteinases.     

Effect of Deoxyribonucleic Acid Ligands on Deoxyribonucleases and Deoxyribonucleic Acid Polymerase I of Escherichia coli K-12

Endonuclease I, exonuclease I, and exonuclease II-deoxyribonucleic acid (DNA) polymerase I activities are not vital functions in Escherichia coli, although the latter two enzymes have been indirectly shown to be involved in DNA repair processes. Acridines such as acridine orange and proflavine interfere with repair in vivo, and we find that such compounds inhibit the in vitro activity of exonuclease I and DNA polymerase I but stimulate endonuclease I activity and hydrolysis of p-nitrophenyl thymidine-5′-phosphate by exonuclease II. Another acridine, 10-methylacridinium chloride, binds strongly to DNA but is relatively inert both in vivo and in vitro. These experiments suggest that acridines affect enzyme activity by interacting with the enzyme directly as well as with DNA. Resulting conformational changes in the DNA-dependent enzymes might explain why similar acridines which form similar DNA complexes have such a wide range of physiological effects. Differential sensitivity of exonuclease I and DNA polymerase I to acridine inhibition relative to other DNA-dependent enzymes may contribute to the acridine sensitivity of DNA repair.     

CRISPR RNA binding and DNA target recognition by purified Cascade complexes from Escherichia coli

Clustered regularly interspaced short palindromic repeats (CRISPRs) and their associated Cas proteins comprise a prokaryotic RNA-guided adaptive immune system that interferes with mobile genetic elements, such as plasmids and phages. The type I-E CRISPR interference complex Cascade from Escherichia coli is composed of five different Cas proteins and a 61-nt-long guide RNA (crRNA). crRNAs contain a unique 32-nt spacer flanked by a repeat-derived 5′ handle (8 nt) and a 3′ handle (21 nt). The spacer part of crRNA directs Cascade to DNA targets. Here, we show that the E. coli Cascade can be expressed and purified from cells lacking crRNAs and loaded in vitro with synthetic crRNAs, which direct it to targets complementary to crRNA spacer. The deletion of even one nucleotide from the crRNA 5′ handle disrupted its binding to Cascade and target DNA recognition. In contrast, crRNA variants with just a single nucleotide downstream of the spacer part bound Cascade and the resulting ribonucleotide complex containing a 41-nt-long crRNA specifically recognized DNA targets. Thus, the E. coli Cascade-crRNA system exhibits significant flexibility suggesting that this complex can be engineered for applications in genome editing and opening the way for incorporation of site-specific labels in crRNA.