Role of ner protein in bacteriophage Mu transposition

Genomic characterization of prophage elements in Clostridium clostridioforme: an understudied component of the intestinal microbiome

Genome sequencing of Clostridium clostridioforme strain LM41 revealed the presence of an atypically high proportion of mobile genetic elements for this species, with a particularly high abundance of prophages. Bioinformatic analysis of prophage sequences sought to characterize these elements and identify prophage-linked genes contributing to enhanced fitness of the host bacteria in the dysbiotic gut. Using PHASTER, PhageScope and manual curation, this work has identified 15 prophages: 4 predicted to be intact, 2 predicted to be defective and 9 which are unclassified. Quantitative PCR (qPCR) analysis revealed spontaneous release of four of the LM41 prophages (φ1, φ2, φ4 and φ10) into the culture supernatant, with virion-like particles visualized using transmission electron microscopy. The majority (12/14) of these particles had morphology akin to podoviruses, which is consistent with morphology predictions for φ1 and φ4. We observed diversity in the lysogeny mechanisms utilized by the prophages, with examples of the classical λ-like CI/Cro system, the ICEBs1 ImmR/ImmA-like system and the Mu-like C/Ner system. Classical morons, such as toxins or immune evasion factors, were not observed. We did, however, identify a variety of genes with roles in mediating restriction modification and genetic diversity, as well as some candidate genes with potential roles in host adaptation. Despite being the most abundant entities in the intestine, there is a dearth of information about phages associated with members of the microbiome. This work begins to shed light on the contribution of these elements to the lifestyle of C. clostridioforme LM41.

Nlp enhances biofilm formation by Yersinia pestis biovar microtus

Biofilms formed by Yersinia pestis are able to attach to and block flea's proventriculus, which stimulates the transmission of this pathogen from fleas to mammals. In this study, we found that Nlp (YP1143) enhanced biofilm formation by Y. pestis and had regulatory effects on biofilm-associated genes at the transcriptional level. Phenotypic assays, including colony morphology assay, crystal violet staining, and Caenorhabditis elegans biofilm assay, disclosed that Nlp strongly promoted biofilm formation by Y. pestis. Further gene regulation assays showed that Nlp stimulated the expression of hmsHFRS, hmsCDE and hmsB, while had no regulatory effect on the expression of hmsT and hmsP at the transcriptional level. These findings promoted us to gain more understanding of the complex regulatory circuits controlling biofilm formation by Y. pestis.

Controlling DNA degradation from a distance: a new role for the Mu transposition enhancer

Phage Mu is unique among transposable elements in employing a transposition enhancer. The enhancer DNA segment is the site where the transposase MuA binds and makes bridging interactions with the two Mu ends, interwrapping the ends with the enhancer in a complex topology essential for assembling a catalytically active transpososome. The enhancer is also the site at which regulatory proteins control divergent transcription of genes that determine the phage lysis-lysogeny decision. Here we report a third function for the enhancer - that of regulating degradation of extraneous DNA attached to both ends of infecting Mu. This DNA is protected from nucleases by a phage protein until Mu integrates into the host chromosome, after which it is rapidly degraded. We find that leftward transcription at the enhancer, expected to disrupt its topology within the transpososome, blocks degradation of this DNA. Disruption of the enhancer would lead to the loss or dislocation of two non-catalytic MuA subunits positioned in the transpososome by the enhancer. We provide several lines of support for this inference, and conclude that these subunits are important for activating degradation of the flanking DNA. This work also reveals a role for enhancer topology in phage development.

Regulation of transposition in bacteria

Mobile genetic elements (MGEs) play a central role in the evolution of bacterial genomes. Transposable elements (TE: transposons and insertion sequences) represent an important group of these elements. Comprehension of the dynamics of genome evolution requires an understanding of how the activity of TEs is regulated and how their activity responds to the physiology of the host cell. This article presents an overview of the large range of, often astute, regulatory mechanisms, which have been adopted by TEs. These include mechanisms intrinsic to the element at the level of gene expression, the presence of key checkpoints in the recombination pathway and the intervention of host proteins which provide a TE/host interface. The multiplicity and interaction of these mechanisms clearly illustrates the importance of limiting transposition activity and underlines the compromise that has been reached between TE activity and the host genome. Finally, we consider how TE activity can shape the host genome.

IS6110 functions as a mobile, monocyte-activated promoter in Mycobacterium tuberculosis

The mobile insertion sequence, IS6110, is an important marker in tracking of Mycobacterium tuberculosis strains. Here, we demonstrate that IS6110 can upregulate downstream genes through an outward-directed promoter in its 3' end, thus adding to the significance of this element. Promoter activity was orientation dependent and was localized within a 110 bp fragment adjacent to the right terminal inverted repeat. Transcripts from this promoter, named OP6110, begin approximately 85 bp upstream of the 3' end of IS6110. Use of green fluorescent protein (GFP) expression constructs showed that OP6110 was upregulated in M. tuberculosis during growth in human monocytes and in late growth phases in broth. Analysis of natural insertion sites in M. tuberculosis showed that IS6110 upregulated expression of several downstream genes during growth in human monocytes, including Rv2280 in H37Rv and the PE-PGRS gene, Rv1468c, in the clinical strain 210, which is a member of the Beijing family. Transcription between IS6110 and downstream genes was confirmed by reverse transcription polymerase chain reaction. The ability to activate genes during infection suggests that IS6110 has the potential to influence growth characteristics of different strains, and indicates another mechanism by which IS6110 can impact M. tuberculosis evolution.

Bio-array images processing and genetic networks modelling

The new tools available for gene expression studies are essentially the bio-array methods using a large variety of physical detectors (isotopes, fluorescent markers, ultrasounds...). Here we present first rapidly an image-processing method independent of the detector type, dealing with the noise and with the peaks overlapping, the peaks revealing the detector activity (isotopic in the presented example), correlated with the gene expression. After this primary step of bio-array image processing, we can extract information about causal influence (activation or inhibition) a gene can exert on other genes, leading to clusters of genes co-expression in which we extract an interaction matrix M and an associated interaction graph G explaining the genetic regulatory dynamics correlated to the studied tissue function. We give two examples of such interaction matrices and graphs (the flowering genetic regulatory network of Arabidopsis thaliana and the lytic/lysogenic operon of the phage Mu) and after some theoretical rigorous results recently obtained concerning the asymptotic states generated by the genetic networks having a given interaction matrix and reciprocally concerning the minimal (in the sense of having a minimal number of non-zero coefficients) matrices having given stationary stable states.

Identification of an unknown promoter, OUTIIp, within the IS10R element

A novel promoter in IS10R (OUTIIp) has been found in one of its ends in an inverted position relative to promoter pOUT. OUTIIp shows characteristics similar to those of rpoS-dependent promoters such as a gearbox expression pattern. It is under catabolite repression and positively regulated by ppGpp or conditioned media. This opens new challenges in IS10R transposition.

Insertion sequences

Insertion sequences (ISs) constitute an important component of most bacterial genomes. Over 500 individual ISs have been described in the literature to date, and many more are being discovered in the ongoing prokaryotic and eukaryotic genome-sequencing projects. The last 10 years have also seen some striking advances in our understanding of the transposition process itself. Not least of these has been the development of various in vitro transposition systems for both prokaryotic and eukaryotic elements and, for several of these, a detailed understanding of the transposition process at the chemical level. This review presents a general overview of the organization and function of insertion sequences of eubacterial, archaebacterial, and eukaryotic origins with particular emphasis on bacterial elements and on different aspects of the transposition mechanism. It also attempts to provide a framework for classification of these elements by assigning them to various families or groups. A total of 443 members of the collection have been grouped in 17 families based on combinations of the following criteria: (i) similarities in genetic organization (arrangement of open reading frames); (ii) marked identities or similarities in the enzymes which mediate the transposition reactions, the recombinases/transposases (Tpases); (iii) similar features of their ends (terminal IRs); and (iv) fate of the nucleotide sequence of their target sites (generation of a direct target duplication of determined length). A brief description of the mechanism(s) involved in the mobility of individual ISs in each family and of the structure-function relationships of the individual Tpases is included where available.

The integration host factor-DNA complex upstream of the early promoter of bacteriophage Mu is functionally symmetric

Inversion of the ihf site in the promoter region of the early promoter of bacteriophage Mu did not influence the integration host factor (IHF)-mediated functions. IHF bound to this inverted site could counteract H-NS-mediated repression, directly activate transcription, and support lytic growth of bacteriophage Mu. This implies that the IHF heterodimer and its asymmetrical binding site form a functionally symmetrical complex.

Purification and self-association equilibria of the lysis-lysogeny switch proteins of coliphage 186

The CI repressor protein, responsible for maintenance of the lysogenic state, and the Apl protein, required for efficient prophage induction, are the two control proteins of the lysis-lysogeny transcriptional switch of coliphage 186. These proteins have been overexpressed, purified, and their self-association behavior examined by sedimentation equilibrium. Phage 186 CI dimers self-associate in solution through tetramers to octamers in a concerted process. The Apl protein of 186 is an unusual example of a helix-turn-helix protein which is monomeric in solution.

Characterization of the lysogenic repressor (c) from transposable Mu-like bacteriophage D108

The c gene products from related, transposable phages Mu and D108 encode lysogenic repressors which negatively regulate transcription and transposition. Using the gel shift assay to monitor c-operator specific DNA-binding activity, the 19.5 kDa D108 c repressor was purified to homogeneity. Sequence analysis of the N-terminus confirmed the identity of the purified protein as the repressor and ascribed its ATG initiation codon to base pair 864 from the D108 left end. Analytical gel filtration and dimethyl suberimidate cross-linking of repressor at 0.1-0.5 microM concentrations revealed that the repressor protein could form oligomers in the absence of its DNA substrate. From DNase I footprinting and gel mobility shift analyses, the D108 repressor only bound to two operators (O1 and O2) which, as in Mu, flank an Integration Host Factor (IHF) binding site. In contrast to Mu, an O3 site in D108 was not found. Moreover, D108 repressor first bound operator O2, while occupancy of O1 required higher protein concentrations. The implications of these results on the D108 regulatory system are discussed.

Genetic analysis of the DNA recognition sequence of the P2 Cox protein

The Cox protein of temperate Escherichia coli phage P2 is involved in three important biological processes: (i) excision of the integrated prophage genome (G. Lindahl and M. Sunshine, Virology 49:180-187, 1972), (ii) transcriptional repression of the P2 Pc promoter, which controls the expression of the immunity repressor C and the integrase (S. Saha, E. Haggård-Ljungquist, and K. Nordström, EMBO J. 6:3191-3199, 1987), and (iii) transcriptional activation of the late PII promoter of the unrelated satellite phage P4 (S. Saha, E. Haggård-Ljungquist, and K. Nordström, Proc. Natl. Acad. Sci. USA 86:3973-3977, 1989). A comparison of the DNA regions protected by Cox from DNaseI degradation has revealed a presumptive Cox recognition sequence (Saha et al., Proc. Natl. Acad. Sci. USA). The binding region of Cox in the P2 Pc promoter contains three presumptive recognition sequences, "Cox boxes," located in tandem. P2 vir3 and P2 vir24 are virulent deletion mutants unable to plate on Cox-producing strains, most likely because the deletions locate the new early promoters too close to the Cox-binding region (Saha et al., EMBO J.). In this report, spontaneous P2 vir3 and vir24 mutants, no longer sensitive to repression by the Cox protein, have been isolated. These mutants plate with equal efficiency on strains with or without a Cox-producing plasmid, and they have been named cor for cox resistance. Three types are recognized; the four P2 vir3 cor mutants have a 1-base deletion in the first Cox box, while the P2 vir24 cor mutants were of two types; four have a base substitution in the first Cox box, and one has a base substitution in the second Cox box. The effect of the Cox protein on the mutated P2 vir3 and vir24 promoters was analyzed in vivo by using fusions to a promoterless cat (chloramphenicol acetyltransferase) gene. The activities of the P2 vir3 and vir24 early promoters, as opposed to the wild-type early Pe promoter, are drastically reduced by the Cox protein, and the cor mutation renders them as resistant to Cox as the wild-type Pe promoter. Thus, at least the first two Cox boxes are essential for binding of the Cox protein.

The nadI region of Salmonella typhimurium encodes a bifunctional regulatory protein

Mutants of the nadI and pnuA genes were independently isolated on the basis of defects in repression of NAD biosynthetic genes and defects in transport nicotinamide mononucleotide (NMN). The mutations map at min 99 on the Salmonella chromosome, and the affected regions appear to be cotranscribed. Some pairs of nadI and pnuA mutations complement, suggesting the existence of independent functions. However, cis/trans tests with particular mutations provide evidence that both repressor and transport functions are actually performed by a single bifunctional protein. (This result confirms sequencing data of Foster and coworkers [J. W. Foster, Y. K. Park, T. Fenger, and M. P. Spector, J. Bacteriol. 172:4187-4196, 1990]). We have designated the gene for this bifunctional protein nadI and distinguish the regulatory and transport defects with phenotypic designations (R and T). When a nadI(R- T+) mutation (eliminating only repression function) is placed cis to a superrepressor mutation, nadI(Rs T-), the superrepression phenotype is lost. In contrast, placement of R- and Rs T- mutations in trans allows full superrepression. This result suggests that the transport function (eliminated by the Rs T- mutation) and the repression function are provided by the same protein. Insertion mutations in the promoter-proximal repressor region of the nadI gene eliminate transport function unless the inserted element can provide both for both transcription and translation start signals; this finding suggests that there is no transcriptional or translational start between the regions encoding repression and transport functions.

Bacteriophage Mu sites and functions involved in the inhibition of lambda::mini-Mu growth

To better understand the nature of the mini-Mu-directed process which results in inhibition of lambda::mini-Mu growth we characterized spontaneous deletion mutants of the lambda::mini-Mu phage. On the basis of analysis of the deletion endpoints, mini-Mu replication functions, and integration and inhibition properties, the lambda::mini-Mu deletion mutants were divided into five classes which define the Mu sites and functions involved in lambda::mini-Mu growth inhibition. Class 1 mutants, which still exhibit lambda::mini-Mu growth inhibition, collectively delete all the Mu late functions encoded by the mini-Mu. Class 2 and 5 mutants, which show cis-dominant defects in inhibition and integration, delete the right and left mini-Mu attachment sites, respectively. Phages of Classes 3 and 4, which delete the Mu B or A and B genes, respectively, show recessive defects in growth inhibition. The properties of these mutants define the Mu replication functions, A and B, and the Mu attachment sites as essential for the inhibition of lambda::mini-Mu growth. The observation that the sites and functions essential for Mu replication also have requisite roles in the inhibition of lambda::mini-Mu growth suggests that inhibition results from mini-Mu-promoted replicative interference of lambda::mini-Mu development.

Characterization of the C operon transcript of bacteriophage Mu

Mu transcription occurs in three phases: early, middle, and late. Middle transcription occurs in the region of the C gene, which encodes the transactivator for late transcription. A middle promoter, Pm, was previously localized between 0.28 and 1.2 kilobase pairs upstream of C. We used S1 nuclease mapping with both unlabeled and radiolabeled capped RNAs from induced lysogens to characterize C transcription and identify its promoter. The C transcription initiation site was localized to a 4-base-pair region, approximately 740 base pairs upstream of C within the region containing Pm. Transcription of C was activated between 4 and 8 min after induction of cts and Cam lysogens and increased throughout the lytic cycle. Significant C transcription did not occur in replication-defective Aam lysogens. These kinetic and regulatory characteristics identify the C transcript as a middle RNA species and demonstrate that Pm is the C promoter. DNA sequence analysis of the Pm region showed a good -10, but poor -35, site homology to the Escherichia coli RNA polymerase consensus sequence. In addition, the sequence demonstrated that C is the distal gene in a middle operon containing several open reading frames. S1 mapping also showed an upstream transcript with a 3' end in the Pm region at a sequence strongly resembling a Rho-independent terminator. The regulatory characteristics of this RNA are consistent with this terminator, t9.2, being the early operon terminator.

Integration host factor is necessary for lysogenization of Escherichia coli by bacteriophage P2

Whether infection by bacteriophage P2 results in lysogenization of the host or vegetative growth of the phage depends upon a race between transcription from the repressor promoter Pc and the early promoter Pe; transcription from these promoters is mutually exclusive, since the Pc repressor Cox is formed from the Pe transcript and the Pe repressor C from the Pc transcript. The involvement of integration host factor (IHF) in the lysogenization of Escherichia coli K12 by P2 was tested by comparing wild-type and IHF-deficient (himA and himD) mutants. No lysogenic clones were formed following infection of the mutant bacteria. A switch plasmid that contains Pc-C-cat and Pe-cox-kan was used to test the choice for expression of Pc versus Pe. In the wild-type K12 bacteria, 20% of the clones expressed Pe transcription and 80% Pc transcription, whereas all transformed IHF-defective clones expressed transcription from Pe only. The effects of IHF on the in vivo expression of the Pe and Pc promoters were only marginal. The IHF protein was found to bind upstream of the Pe promoter, where a potential ihf sequence is located.

Cloning and sequencing of an Escherichia coli gene, nlp, highly homologous to the ner genes of bacteriophages Mu and D108

An nlp (Ner-like protein) gene was isolated from Escherichia coli. The nucleotide sequence of a 1,342-base-pair chromosomal DNA fragment containing the nlp gene was analyzed. It contained two open reading frames; one encoded 91 amino acid residues with an Mr of 10,361, and the other (ORFX) encoded 131 amino acid residues of the carboxyl-terminal region of a truncated polypeptide. The amino acid sequence deduced from the DNA sequence of nlp was highly homologous (62 to 63%) to the Ner proteins of bacteriophages Mu and D108. The amino-terminal region of Nlp deduced from the complete open reading frame contained a presumed DNA-binding region. The nlp gene was located at 69.3 min on the E. coli genetic map.

Efficient Mu transposition requires interaction of transposase with a DNA sequence at the Mu operator: implications for regulation

Phage Mu transposition is initiated by the Mu DNA strand-transfer reaction, which generates a branched DNA structure that acts as a transposition intermediate. A critical step in this reaction is formation of a special synaptic DNA-protein complex called a plectosome. We find that formation of this complex involves, in addition to a pair of Mu end sequences, a third cis-acting sequence element, the internal activation sequence (IAS). The IAS is specifically recognized by the N-terminal domain of Mu transposase (MuA protein). Neither the N-terminal domain of MuA protein nor the IAS is required for later reaction steps. The IAS overlaps with the sequences to which Mu repressor protein binds in the Mu operator region; the Mu repressor directly inhibits the Mu DNA strand-transfer reaction by interfering with the interaction between MuA protein and the IAS, providing an additional mode of regulation by the repressor.

Activation of prophage P4 by the P2 Cox protein and the sites of action of the Cox protein on the two phage genomes

Phage P2 induces the unrelated prophage P4. In this paper we show that this is due to the activation of the P4 late promoter PII by the P2 Cox protein. This is in contrast to the effects of Cox on P2, for which it is known from previous work that it acts as a repressor of the promoter Pc, which is responsible for expression of the immunity repressor C. The activator role of Cox was revealed by its effect on replication of P4 DNA and on the formation of chloramphenicol acetyltransferase when a promoterless cat gene was inserted downstream of the P4 PII promoter. DNase I protection studies revealed that the Cox protein binds to the repressor promoter Pc of phage P2 and to the promoter PII of phage P4. In the latter case the Cox protein binds upstream of the -35 region, in analogy to several other activators of promoters. A weak binding was found in the promoters Pe of phage P2 and Ple of phage P4. The Cox protein is a case of viral transactivation of the replication genes of one phage by a control protein of the other. However, the effects of the Cox protein are totally different in the two phages, repressive in one case and activating in the other.

Autoregulation of phage mu transposase at the level of translation

The bacteriophage Mu A and B genes, which lie adjacent to each other and are colinear on the phage genome, encode proteins that catalyze efficient transposition of Mu DNA. We show that the molar ratio of A and B proteins is approximately 1:20 in extracts prepared after induction of cells containing a Mu lysogen or a plasmid carrying the Mu fragment that encompasses A and B. In cells harboring the cloned genes, the proteins are synthesized from a single transcript. Pulse-chase experiments demonstrate that the lower amounts of A protein are not from preferential turnover of this protein. This suggests the existence of a post-transcriptional mechanism to down-regulate A protein synthesis. From an analysis of the activity of several beta-galactosidase fusions to A protein, we infer that A protein may repress its own translation. By an agarose gel mobility-shift assay, we demonstrate that purified A protein binds specifically in vitro to its mRNA.

Isolation of mutations of the phage Mu ner gene

A method was devised which allows the easy detection of mutations within the ner gene of Mu DNA. This method is based upon the observation that a transcriptional gene A-galK fusion containing the complete ner gene and the cts62 allele does not express the galK gene in an Escherichia coli strain lacking functional integration host factor under inducing conditions (white colonies on MacConkey galactose plates at 42 degrees) In contrast, a gene ner-galK fusion which lacks part of the ner gene exhibits GalK activity (red colonies) on MacConkey galactose plates at 42 degrees. After mutagenesis of a plasmid carrying a transcriptional gene A-galK fusion, putative ner mutants could be identified on indicator plates. Cloning experiments locate the mutation(s) to the right of the HindIII site which is situated within the early promoter of Mu DNA. One of the mutants was sequenced and revealed two substitutions: one within the-10 region of the early promoter, and another near the end of the ner gene. The former lesion was shown to be pleiotropic.

Lysogenization of Escherichia coli him+, himA, and himD hosts by bacteriophage Mu

The possible outcomes of infection of Escherichia coli by bacteriophage Mu include lytic growth, lysogen formation, nonlysogenic surviving cells, and perhaps simple killing of the host. The influence of various parameters, including host himA and himD mutations, on lysogeny and cell survival is described. Mu does not grow lytically in or kill him bacteria but can lysogenize such hosts. Mu c+ lysogenizes about 8% of him+ bacteria infected at low multiplicity at 37 degrees C. The frequency of lysogens per infected him+ cell diminishes with increasing multiplicity of infection or with increasing temperature over the range from 30 to 42 degrees C. In him bacteria, the Mu lysogenization frequency increases from about 7% at low multiplicity of infection to approach a maximum where most but not all cells are lysogens at high multiplicity of infection. Lysogenization of him hosts by an assay phage marked with antibiotic resistance is enhanced by infection with unmarked auxiliary phage. This helping effect is possible for at least 1 h, suggesting that Mu infection results in formation of a stable intermediate. Mu immunity is not required for lysogenization of him hosts. We argue that in him bacteria, all Mu genomes which integrate into the host chromosome form lysogens.

Mini-Mu transduction: cis-inhibition of the insertion of Mud transposons

Mud (mini-Mu) transposons are defective phage Mu genomes that conserve the Mu ends. The transduction of Mud transposons is strictly dependent on Mu complementation, inefficient, and affected by modifications in the Mud internal sequences. The transduction of Mud transposons depends on transposition, which appears to be low, relative to wild-type Mu. Insertions of Mud into a plasmid can be frequently recovered among transductants; new Mud insertions into plasmids that already have both Mu ends, or just one, are rarely found. This suggests that the presence of Mu ends "immunizes" the plasmid against further insertion. This phenomenon may be similar to the transposition immunity of Tn3.