DNA modification of bacteriophage Mu-1 requires both host and bacteriophage functions

Transposable phages, DNA reorganization and transfer

Transposable bacteriophages have long been known to necessarily and randomly integrate their DNA in their host genome, where they amplify by successive rounds of replicative transposition, profoundly reorganizing that genome. As a result of such transposition, a conjugative element (plasmid or genomic island), can either become integrated in the chromosome or receive chromosome segments, which can then be transferred to new hosts by conjugation. In recent years, more and more transposable phages have been isolated or detected by sequence similarity searches in a wide range of bacteria, supporting the idea that this mode of HGT may be pervasive in natural bacterial populations.

Noncanonical SMC protein in Mycobacterium smegmatis restricts maintenance of Mycobacterium fortuitum plasmids

Research on tuberculosis and leprosy was revolutionized by the development of a plasmid transformation system in the fast-growing surrogate, Mycobacterium smegmatis. This transformation system was made possible by the successful isolation of a M. smegmatis mutant strain mc(2)155, whose efficient plasmid transformation (ept) phenotype supported the replication of Mycobacterium fortuitum pAL5000 plasmids. In this report, we identified the EptC gene, the loss of which confers the ept phenotype. EptC shares significant amino acid sequence homology and domain structure with the MukB protein of Escherichia coli, a structural maintenance of chromosomes (SMC) protein. Surprisingly, M. smegmatis has three paralogs of SMC proteins: EptC and MSMEG_0370 both share homology with Gram-negative bacterial MukB; and MSMEG_2423 shares homology with Gram-positive bacterial SMCs, including the single SMC protein predicted for Mycobacterium tuberculosis and Mycobacterium leprae. Purified EptC was shown to bind ssDNA and stabilize negative supercoils in plasmid DNA. Moreover, an EptC-mCherry fusion protein was constructed and shown to bind to DNA in live mycobacteria, and to prevent segregation of plasmid DNA to daughter cells. To our knowledge, this is the first report of impaired plasmid maintenance caused by a SMC homolog, which has been canonically known to assist the segregation of genetic materials.

Epigenetic gene regulation in the bacterial world

Like many eukaryotes, bacteria make widespread use of postreplicative DNA methylation for the epigenetic control of DNA-protein interactions. Unlike eukaryotes, however, bacteria use DNA adenine methylation (rather than DNA cytosine methylation) as an epigenetic signal. DNA adenine methylation plays roles in the virulence of diverse pathogens of humans and livestock animals, including pathogenic Escherichia coli, Salmonella, Vibrio, Yersinia, Haemophilus, and Brucella. In Alphaproteobacteria, methylation of adenine at GANTC sites by the CcrM methylase regulates the cell cycle and couples gene transcription to DNA replication. In Gammaproteobacteria, adenine methylation at GATC sites by the Dam methylase provides signals for DNA replication, chromosome segregation, mismatch repair, packaging of bacteriophage genomes, transposase activity, and regulation of gene expression. Transcriptional repression by Dam methylation appears to be more common than transcriptional activation. Certain promoters are active only during the hemimethylation interval that follows DNA replication; repression is restored when the newly synthesized DNA strand is methylated. In the E. coli genome, however, methylation of specific GATC sites can be blocked by cognate DNA binding proteins. Blockage of GATC methylation beyond cell division permits transmission of DNA methylation patterns to daughter cells and can give rise to distinct epigenetic states, each propagated by a positive feedback loop. Switching between alternative DNA methylation patterns can split clonal bacterial populations into epigenetic lineages in a manner reminiscent of eukaryotic cell differentiation. Inheritance of self-propagating DNA methylation patterns governs phase variation in the E. coli pap operon, the agn43 gene, and other loci encoding virulence-related cell surface functions.

Unusual transcriptional and translational regulation of the bacteriophage Mu mom operon

The bacteriophage Mu mom gene encodes a novel DNA modification that protects the viral genome against a wide variety of restriction endonucleases. Expression of mom is subject to a series of unusual regulatory controls. Transcription requires the action of a phage-encoded protein, C, which binds (probably as a dimer) the mom promoter from -33 to -52 (with respect to the transcription start site) in two adjacent DNA major grooves on one face of the helix. No apparent direct interaction between C and the host RNA polymerase (RNAP) is evident; however, C binding alters mom DNA conformation. In the absence of C, RNAP binds the mom promoter at a site that results in transcription in a direction away from the mom gene. The function of this transcription is unknown. An additional layer of transcriptional regulation complexity is due to the fact that the host Dam DNA-(N6-adenine)methyltransferase is required. Dam methylation of three closely spaced upstream GATC sequences is necessary to prevent binding by the host protein, OxyR, which acts as a repressor. Repression is not mediated by inhibition of C binding, but rather through interference with C-mediated recruitment of RNAP to the correct site. Translation of mom is regulated by the phage Com protein. Com is only 62 amino acids long and contains a zinc finger-like structure (coordinated by four cysteine residues) in the amino terminal domain. Com binds mom mRNA 5' to the mom open reading frame, whose translation start signals are contained in a stem-loop translation-inhibition-structure. Com binding to its target site (5' to and adjacent to the translation-inhibition-structure) results in a stable change in RNA secondary structure that exposes the translation start signals.

Escherichia coli OxyR modulation of bacteriophage Mu mom expression in dam+ cells can be attributed to its ability to bind hemimethylated Pmom promoter DNA

Transcription of the bacteriophage Mu mom operon is strongly repressed by the host OxyR protein in dam - but not dam + cells. In this work we show that the extent of mom modification is sensitive to the relative levels of the Dam and OxyR proteins and OxyR appears to modulate the level of mom expression even in dam + cells. In vitro studies demonstrated that OxyR is capable of binding hemimethylated P mom , although its affinity is reduced slightly compared with unmethylated DNA. Thus, OxyR modulation of mom expression in dam + cells can be attributed to its ability to bind hemimethylated P mom DNA, the product of DNA replication.

In vitro transcriptional activation of the phage Mu mom promoter by C protein

The phage Mu gene C encodes a 16.5-kDa site-specific DNA-binding protein that functions as a trans-activator of the four phage "late" operons, including mom. We have overexpressed and purified C and used it for DNase I footprinting and transcription analyses in vitro. The footprinting results are summarized as follows. (i) As shown previously (V. Balke, V. Nagaraja, T. Gindlesperger, and S. Hattman, Nucleic Acids Res. 12:2777-2784, 1992) in vivo, Escherichia coli RNA polymerase (RNAP) bound the wild-type (wt) mom promoter at a site slightly upstream from the functionally active site bound on the C-independent tin7 mutant promoter. (ii) In the presence of C, however, RNAP bound the wt promoter at the same site as tin7. (iii) C and RNAP were both bound by the mom promoter at overlapping sites, indicating that they were probably on different faces of the DNA helix. The minicircle system of Choy and Adhya (H. E. Choy and S. Adhya, Proc. Natl. Acad. Sci. USA 90:472-476, 1993) was used to compare transcription in vitro from the wt and tin7 promoters. This analysis showed the following. (i) Few full-length transcripts were observed from the wt promoter in the absence of C, but addition of increasing amounts of C greatly stimulated transcription. (ii) RNA was transcribed from the tin7 promoter in the absence of C, but addition of C had a small stimulatory effect. (iii) Transcription from linearized minicircles or restriction fragment templates was greatly reduced (although still stimulated by C) with both the wt and tin7 promoters. These results show that C alone is capable of activating rightward transcription in vitro by promoting RNAP binding at a functionally active site. Additionally, DNA topology plays an important role in transcriptional activation in vitro.

Influence of DNA adenine methylase on the sensitivity of Escherichia coli to near-ultraviolet radiation and hydrogen peroxide

Near-ultraviolet (NUV) radiation and hydrogen peroxide (H2O2) inactivation studies were performed on Escherichia coli K-12 DNA adenine methylation (dam) mutants and on cells that carry plasmids which overexpress Dam methylase. Lack of methylation resulted in increased sensitivity to NUV and H2O2 (a photoproduct of NUV). In a dam mutant carrying a dam plasmid, the levels of Dam enzyme and resistance to NUV and H2O2 were restored. However, using a multicopy dam+ plasmid strain, increasing the methylase above wildtype levels resulted in an increase in sensitivity of the cells rather than resistance.

Two DNA antirestriction systems of bacteriophage P1, darA, and darB: characterization of darA- phages

Bacteriophage P1 is only weakly restricted when it infects cells carrying type I restriction and modification systems even though DNA purified from P1 phage particles is a good substrate for type I restriction enzymes in vitro. Here we show that this protection against restriction is due to the products of two phage genes which we call darA and darB (dar for defense against restriction). Each of the dar gene products provides protection against a different subset of type I restriction systems. The darA and darB gene products are found in the phage head and protect any DNA packaged into a phage head, including transduced chromosomal markers, from restriction. The proteins must, therefore, be injected into recipient cells along with the DNA. The proteins act strictly in cis. For example, upon double infection of restricting cells with dar+ and dar- P1 phages, the dar+ genomes are protected from restriction while the dar- genomes are efficiently restricted.

Transactivation of several genes of two native Serratia prophages after superinfection by phage kappa

Serratia marcescens HY bacteria must be lysogenic with either prophage y or psi to make it possible for phage kappa to form plaques unless they carry a so-called ink mutation. Genes in y and psi termed any and anp were identified that after infection of ink+ cells are necessary for an effective propagation of these phages as well as of coinfecting kappa phage. When kappa infects y and/or psi-lysogenic cells it transactivates the respective prophage genes by means of two early genes termed tay and tap. It appears that on infection of nonlysogenic ink+ cells kappa damps its own development, provided the regulatory region of the responsible gene is undermethylated. After kappa infection duly to achieve the special methylation of this region seems to be the function of any and anp. There are some more genes in y and psi prophage under the control of tay and tap, concerning in both cases a Dam methylation (recognition sequence GATC) of kappa DNA, a recombination proneness under restricting conditions of kappa DNA not modified by the modification enzyme of HY, and the kappa plaque size. By hybridization studies a region of homology common to y and psi was demonstrated which from its size might comprise all the transactivated genes. The view is supported by genetic data indicating an affinity among the any and anp genes. Investigation of various any mutants were indicative of DNA inversions in this region of the y genome. Surprisingly some of the any mutants had become sensitive in their plaque forming ability to an inhibitory activity exerted by prophage psi. Mutants of psi unable to interfere but still able to lysogenize were isolated. A model is presented accounting for the formation of pleiotropic and nonpleiotropic mutations with Any phenotype and their reversion types. Possible functions of the y genes and their counterparts in psi are discussed.

Post-transcriptional regulation of the bacteriophage Mu mom gene by the com gene product

The mom gene of bacteriophage Mu encodes a DNA modification function, the expression of which is detrimental to the host cell. This may be reflected by the tight regulation of the mom gene at the level of transcription initiation by the Mu C gene product and the host Dam function. In addition, mom expression requires the positive regulatory function Com. The com and mom genes comprise the mom operon with the com coding region partially overlapping that of mom. The degree of overlap is defined by experiments reported here. We have tested Com for activity as an antiterminator of mom transcription. We show that in the absence of Com, premature termination affects at most 33% of the transcription across the mom operon. Although no premature termination is observed in the presence of Com, these results are inconsistent with a role for Com as an antiterminator. Northern blot analysis of Com+ and Com- Mu phage mRNA confirms this conclusion. Two models for the post-transcriptional regulation of mom gene expression by Com are presented.

The sequence and mom-transactivation function of the C gene of bacteriophage Mu

The mom gene of bacteriophage Mu encodes a DNA modification function. The gene is regulated on the transcriptional level by Dam-specific methylation and a trans-acting Mu function, and on a post-transcriptional level by the product of gene com. The gene encoding the transactivator has been cloned and mapped. By complementation analysis the activation function (also designated Dad) was shown to be the product of gene C. Transactivation of the mom promoter was shown in the following assay: the mom promoter and N-terminal part of com were fused in frame to lacZ. Cells containing such fusion plasmids were infected with M13 clones expressing C in the presence of IPTG and XGal. Successful transactivation results in the formation of blue plaques. Moreover, we have determined the sequence of gene C and found that it has a coding capacity of 140 amino acids. The promoter for C (pc) is likely to be located at least 0.5 kb upstream from the gene. A transcription terminator is found directly downstream from the C-coding region.

Regulation and expression of the bacteriophage mu mom gene: mapping of the transactivation (dad) function to the C region

Expression of the bacteriophage Mu mom gene is under tight regulatory control. One of the factors required for mom gene expression is the trans-acting function (designated Dad) provided by another Mu gene. To facilitate studies on the signals mediating mom regulation, we have constructed a mom-lacZ fusion plasmid which synthesizes beta-galactosidase only when the Mu Dad transactivating function is provided. lambda pMu phages carrying different segments of the Mu genome have been assayed for their ability to transactivate beta-galactosidase expression by the fusion plasmid. The results of these analyses indicated that the Dad transactivation function is encoded between the leftmost EcoRI site and the lys gene of Mu; this region includes the C gene, which is required for expression of all Mu late genes. Cloning of an approx. 800-bp fragment containing the C gene produced a plasmid which could complement MuC- phages for growth and could transactivate the mom-lacZ fusion plasmid to produce beta-galactosidase. These results suggest that the C gene product mediates the Dad transactivation function.

S1 nuclease mapping of the phage Mu mom gene promoter: a model for the regulation of mom expression

The mom gene of bacteriophage Mu encodes a DNA modification function. Expression of this modification requires the host Escherichia coli Dam (DNA-adenine methylase) function and the transacting phage Mu Dad function. The mom gene was subcloned into a variety of sites on plasmid pBR322. Insertions were made into the HincII and PvuI sites within the amp gene and into the ClaI site of the tet gene promoter. The only clones found were those in which the orientation of the mom gene prevents its transcription from the vector promoter(s), suggesting that constitutive expression of mom from a foreign promoter can occur independently of Dad function but is lethal for the cell. Employing S1 nuclease mapping, we have identified two Mu mRNA transcripts: (1) the gin transcript extends into the gin-mon intercistronic divide and terminates downstream from the BclI site; and (2) the mom transcript appears to initiate about 74 bp upstream from the BclI site, 12 bp downstream from a promoter-like sequence. Production of the mom transcript is dependent on the host Dam activity and on Dad transactivation. In contrast, the gin transcript is produced independently of Dam and Dad functions; the gin transcript may extend into the mom gene, but it appears to be either degraded at the 3' end or differentially terminated. We propose that regulation of mom gene transcription involves both positive and negative regulatory proteins, and that binding of the Dad protein (a "late" Mu protein) is required for transcription initiation by the host RNA polymerase. However, Dad protein action may be inhibited by prior binding of a repressor to the mom operator, located farther upstream. We propose that this repressor (encoded by a phage or host gene) binds to the operator only when there is no active Dam enzyme present, i.e., when there is no methylation of (or methylase binding to) the G-A-T-C sites within the mom operator.

Methylation dependent expression of the mom gene of bacteriophage Mu: deletions downstream from the methylation sites affect expression

The expression of the DNA modification gene (mom) of bacteriophage Mu requires the cellular deoxyadenosine methylase (dam) and a transactivation factor from the phage. By hypothesis, the transcription of mom is activated by methylation of three GATC sequences upstream from the mom gene. We have introduced small deletions at a fourth GATC site located about 140 base pairs downstream from the primary methylation region. Some of the deletions severely affect the mom gene expression. We propose from this analysis that (1) some important elements, possibly the promoter, concerned with the expression of mom are located between nucleotides 840 and 880 from the right end of Mu and (2) the mom protein starts with the codon GTG located at position 810. We favor the hypothesis that methylation turns off transcription upstream, thereby allowing the main mom promoter to function.

Expression of the gin and mom genes of bacteriophage Mu

The gin and mom genes are located in the rightmost 1.6-kb segment, designated the beta segment, of bacteriophage Mu DNA. The gin gene is responsible for the inversion of the G segment of Mu, whereas the mom gene is involved in an unusual modification of the DNA. We have analyzed recombinant plasmids carrying one or both ends of Mu DNA for the expression of the Gin and Mom functions. The Gin protein and the presumptive Mom protein are not always detected in minicells, even though the plasmids being tested have the gin- and mom-containing segment of Mu DNA. However, some plasmids, in which the right end segment of Mu DNA is confined to the 1.6-kb beta segment, do give rise to these gene products in minicells. It seems that synthesis of the Gin and Mom proteins is inhibited in minicells, but this inhibition is lifted if most of the DNA to the left of the beta segment is eliminated from the plasmids. The most prominent Mu product detected in minicells is a 23-25-kDal polypeptide, termed here the zeta (zeta) protein. The function of the zeta protein remains unknown. In vitro transcription of Mu DNA with purified Escherichia coli RNA polymerase is limited to only two regions of the genome. The early region of Mu DNA is transcribed at a relatively high efficiency, whereas the beta region is transcribed at a low efficiency. This low-efficiency transcription appears to be specific for the gin gene; the mom gene transcript cannot be detected.

Purification and characterization of the unusual deoxynucleoside, alpha-N-(9-beta-D-2'-deoxyribofuranosylpurin-6-yl)glycinamide, specified by the phage Mu modification function

Bacteriophage Mu encodes a protein that modifies approximately equal to 15% of DNA adenine residues to a new and unusual form. Modified DNA was enzymatically digested to deoxynucleosides, and the products were fractionated by HPLC. A modified adenine nucleoside, designated dA'x, was purified and its molecular structure was established by mass spectrometry. We show that dA'x is alpha-N-(9-beta-D-2'-deoxyribofuranosylpurin-6-yl)-glycinamide. The dA'x obtained from DNA was indistinguishable from the synthetic product with respect to its chromatographic behavior (HPLC and gas chromatography) and mass spectrum. Acid hydrolysis degrades dA'x to produce N6-carboxymethyladenine; this compound corresponds to the base Ax observed in earlier studies.

AvaII and BglI restriction maps of bacteriophage Mu

The AvaII and BglI restriction maps of bacteriophage Mu were derived by restriction analysis of a series of plasmid clones containing segments of Mu DNA which, in combination, covered the entire Mu genome. The plasmids analyzed included pKN36, pKN54, pKN62, pKN50, pKN35, pKN27, pKN48, pKN82, and pKN56 from the collection of W. Schumann and E. G. Bade, and pCM02, a newly constructed plasmid containing the rightmost internal EcoRI-PstI fragment of Mu DNA. BglI cuts Mu DNA at 23 sites, producing 24 fragments which range in size from 0.05 kb up to the approximately 7-kb fragment derived from the right end. AvaII cuts Mu DNA at 17 sites (including 2 within the G segment), producing fragments which range in size from 0.17 to 8.9 kb. The derived maps were confirmed by results of hybridization of 32P-labeled, nick-translated plasmid DNA to AvaII- and BglI-digested Mu DNAs. Evidence for modification of one of the AvaII sites in E. coli was obtained.

The products of gene A of the related phages Mu and D108 differ in their specificities

By recombination between different mutants of mutator phages Mu and D108, we isolated a set of viable hybrids. The structure of the hybrids was analyzed by digestion with different restriction enzymes. Genetic studies show that hybrids which carry the left end of the Mu genome complement a mini-Mu deleted from within the A gene as well as Mu while hybrids with the left end of the D108 genome or D108 do not. Vice versa, hybrids with the left end of the D108 genome or D108, but not hybrids with the left end of the Mu genome or Mu complement a mini-D108 deleted from within the A gene. The nucleotide sequence of the A gene of Mu and its equivalent on D108 are mainly similar except on their left end. These observations demonstrate that the two pA products, although only partially different, have different specificities.

Production and modification of Mu (G-) phage particles in E. coli K12 and Erwinia

We studied the amount of Mu(G+) and Mu(G−) phages in different Mu lysates prepared either upon induction or upon infection ofE. coliandErwiniastrains. We also looked at the level of expression of the modification function (mom) by Mu(G−) phages, both after induction and after infection ofE. coliandErwinia. The expression ofmomseems to be regulated in the same manner inE. coliand in the strain ofErwinia carotovoratested. The proportion of both types of Mu(G+) and Mu(G−) phages in induced lysates is very variable and we found growth conditions favouring the production of Mu(G−) particles. This should extend the use of Mu as a genetic tool and as a generalized transducing phage to many enterobacteria.

The isolation and characterization of the Escherichia coli DNA adenine methylase (dam) gene

The E. coli dam (DNA adenine methylase) enzyme is known to methylate the sequence GATC. A general method for cloning sequence-specific DNA methylase genes was used to isolate the dam gene on a 1.14 kb fragment, inserted in the plasmid vector pBR322. Subsequent restriction mapping and subcloning experiments established a set of approximate boundaries of the gene. The nucleotide sequence of the dam gene was determined, and analysis of that sequence revealed a unique open reading frame which corresponded in length to that necessary to code for a protein the size of dam. Amino acid composition derived from this sequence corresponds closely to the amino acid composition of the purified dam protein. Enzymatic and DNA:DNA hybridization methods were used to investigate the possible presence of dam genes in a variety of prokaryotic organisms.

Transcription initiation of Mu mom depends on methylation of the promoter region and a phage-coded transactivator

The product of the bacteriophage Mu gene mom modifies adenine residues of DNA within the consensus sequence CGAGCNPy, providing protection against various restriction endonucleases (ref. 1 and D. Kamp, personal communication cited in ref. 2). The mom gene is only expressed during lytic development of the phage. It is known that mom is nonfunctional in Escherichia coli host mutants in a gene (dam) which itself encodes an adenine methylation system. We show here that the E. coli dam gene is essential for transcription initiation of the mom gene, and that this dependence on dam seems to lie in a short segment preceding the mom coding region, which also contains the mom promoter. The sequence of this segment reveals the presence of dam methylation sites (GATC), and suggests a model for the regulation of mom gene expression based on DNA secondary structure, which may explain why mom is only expressed during phage lytic development. We also show that expression of phage-coded proteins (A, B and C) is needed for transactivation of mom transcription.

DNA methyltransferase-dependent transcription of the phage Mu mom gene

The phage Mu mom gene controls an unusual DNA modification. Expression of the mom function requires an active host (dam+) DNA adenine methylase [S-adenosyl-L-methionine:DNA (6-aminopurine)-methyltransferase]; in dam- hosts, Mu development is normal except that the viral DNA does not undergo the mom modification. The present communication compares transcription of the mom gene in dam+ versus dam- cells. 32P-labeled probes were prepared by nick-translation of a purified mom gene-containing restriction fragment and of virion DNA, respectively. These probes were hybridized with various RNAs blotted onto nitrocellulose filters (after fractionation by agarose gel electrophoresis). The salient findings are: (i) mom-specific RNA was readily detected in dam+ lysogenic cells, but only after induction of the Mu prophage; (ii) the level of mom RNA was decreased at least to 1/20th in induced dam- Mu lysogens; and (iii) little difference, if any, was observed between dam+ and dam- cells with respect to total Mu transcripts produced after prophage induction. These results are in accord with the known pattern of mom gene expression and Mu development. They show that the host (dam+) DNA adenine methylase activity is required for transcription of the mom gene. This represents a unique example where a DNA methylase exerts a positive regulatory role in mRNA transcription; alternative mechanisms for this process will be discussed.

The plasmid cloning vector pBR325 contains a 482 base-pair-long inverted duplication

The plasmid pBR325 is a cloning vector constructed in vitro by addition of the chloramphenicol resistance (Cmr) gene of an IS1-flanked transposon to pBR322 (Bolivar, 1978). It is a 5 995 bp plasmid carrying no sequence originating from IS1. DNA-sequence data suggest that its Cmr segment was derived from a Cm transposon longer than Tn9. The plasmid pBR325 carries between the Cmr and Tcr genes a 482 bp sequence which duplicates, in the opposite orientation, a section pf pBR322 located at the end of the tcr gene. The same structure was found in pBR328, a deletion derivative of pBR325 (Soberon et al., 1980). The possible implications of this inverted duplication on cloning experiments are discussed.

In vitro and in vivo manipulations of bacteriophage Mu DNA: cloning of Mu ends and construction of mini-Mu's carrying selectable markers

Recombinant plasmids carrying one or both ends of the bacteriophage Mu genome were constructed by molecular cloning. Transposable mini-Mu's with selectable markers (ampicillin resistance, kanamycin resistance or the entire lac operon of Escherichia coli) inserted between the Mu ends were also constructed. As a source of lac operon DNA, a pBR322 derivative with a 27 kb insert containing the lac operon was constructed. The plasmids with both ends of Mu (mini-Mu's) conferred full Mu immunity upon the host cells. However, the same mini-Mu's containing kan or lac inserts were defective in immunity. A summary of the construction and physical characterization, including restriction endonuclease cleavage maps and some of the biological properties of the plasmids, is presented.

Specificity of the bacteriophage Mu mom+ -controlled DNA modification

Bacteriophage Mu DNA was labeled after induction in the presence of [8-3H]adenine. Purified DNA was enzymatically digested, and the 3H-labeled dinucleotides were isolated. Approximately 15 to 20% of the adenine residues were modified to a new form, Ax, as observed previously (S. Hattman, J. Virol. 32:468-475, 1979) in bulk DNA. Paper electrophoretic analysis revealed that only two dinucleotide species contain Ax, namely, (Ax,C) and (Ax,G). The observation that only C and G are the nearest neighbors of Ax is consistent with the proposal of Kahmann and Kamp (R. Kahmann and D. Kamp, J. Mol. Biol., in press) that modification of Mu DNA occurs at the A residue within the pentanucleotide sequence, 5'...(CG)-A-(GC)-N-Py...3'.

Mapping of the modification function of temperate phage Mu-1

Using internal deletions in the Mu genome, we have mapped the gene coding for Mu modification in the beta segment of Mu DNA.

Unusual modification of bacteriophage Mu DNA

Bacteriophage Mu DNA was labeled after induction in the presence of [2-(3)H]adenine or [8-(3)H]adenine. Both Mu mom(+).dam(+) DNA and Mu mom(-).dam(+) DNA have similar N(6)-methyladenine (MeAde) contents, as well as similar frequencies of MeAde nearest neighbors. Both DNAs are sensitive to in vitro cleavage by R.DpnI but resistant to cleavage by R.DpnII. These results indicate that the mom(+) protein does not alter the sequence specificity of the host dam(+) methylase to produce MeAde at new sites. However, we have discovered a new modified base, denoted A(x), in Mu mom(+).dam(+) DNA; approximately 15% of the adenine residues are modified to A(x). Although the precise nature of the modification is not yet defined, analysis by electrophoresis and chromatography indicates that the N(6)-amino group is not the site of modification, and that the added moiety contains a free carboxyl group. A(x) is not present in Mu mom(+).dam(+) or Mu mom(-).dam(+) phage DNA or in cellular DNA from uninduced Mu mom(+).dam(+) lysogens. These results suggest that expression of the dam(+) and mom(+) genes are required for the A(x) modification and that this modification is responsible for protecting Mu DNA against certain restriction nucleases. Mu mom(+).dam(-) DNA and Mu mom(-).dam(-) DNA contain a very low level of MeAde (ca. 1 MeAde per 5,000 adenine residues). Since the only nearest neighbor to MeAde appears to be cytosine, we suggest that the methylated sequence is 5'... C-A(*)-C... 3' and that this methylation is mediated by the EcoK modification enzyme.

Characterization of DNA adenine methylation mutants of Escherichia coli K12

The phenotypic traits of 7 independently isolated dam mutants of Escherichia coli have been examined. The mutant strains differ from the wildtype in the following respects: (1) decreased DNA adenine methylase activity in vivo and in vitro; (2) a 14--85-fold increase in spontaneous mutability; (3) decreased survival after ultraviolet irradiation; (4) a 10--21-fold increase in spontaneous induction of lambda phage from lysogens; (5) a 3--17-fold increase in the level of recombination; and (6) inviability of double mutants containing dam- and recB- or recC-. Unmethylated fd phage chromosomes are able to replicate normally in dam- mutants. A mutant strain in which the dcm gene is deleted is viable, showing that the dcm gene product is dispensible for growth.

Bacteriophage Mu-induced modification of DNA is dependent upon a host function

The DNA of bacteriophage Mu, extracted from induced lysates, is partially resistant to digestion by the endonuclease BalI. This modification of DNA is controlled by the Mu modification function (mom), which acts in conjunction with the dam (DNA-adenine methylation) function of Escherichia coli. Since the BalI recognition site is apparently different from the dam recognition site, these results imply that either the specificity of the dam function is changed by the mom function or the mom function requires the dam function for its activity.

Chromosomal rearrangements by an IS2 insertion in phage Mu-1

We have isolated and characterized a mutant of temperate phage Mu-1 carrying an IS2 insertion in the middle of its beta region. This mutant gives rise spontaneously to secondary mutants which have deletions of different sizes adjacent to IS2. One particular derivative however, was found to have acquired an additional insertion sequence adjacent to IS2. This derivative gave rise to tertiary mutants carrying a deletion next to the tandem insertion. The tandem insertion was located at the same place in the Mu beta region as another 2.6 kb insertion independently isolated by Chow et al. (1977) and was found to be homologous to that insertion. The properties of this particular secondary mutant show that Mu phage particles lacking their S end are defective for growth and lysogenisation.