cis-acting proteins

Distribution of IS91 family insertion sequences in bacterial genomes: evolutionary implications

IS91 is the prototype element of a family of bacterial insertion sequences that transpose by a rolling-circle mechanism. Although previously considered a rarity among IS elements, many new examples have been identified by sequence analysis of bacterial genomes. In this work we provide a summary of occurrences of IS91-like sequences in the GenBank database, characterise the genetic organisation of adjacent sequences, and analyse IS91 ecological significance under the light of current transposition mechanisms. Interestingly, IS91 family elements were usually found adjacent to pathogenicity- and virulence-related genes. Thus, this might constitute the niche for IS91 and IS91 family elements to play an important role in the dissemination and evolution of virulence and pathogenicity types of genes.

RepC protein of the octopine-type Ti plasmid binds to the probable origin of replication within repC and functions only in cis

Vegetative replication and partitioning of many plasmids and some chromosomes of alphaproteobacteria are directed by their repABC operons. RepA and RepB proteins direct the partitioning of replicons to daughter cells, while RepC proteins are replication initiators, although they do not resemble any characterized replication initiation protein. Here we show that the replication origin of an Agrobacterium tumefaciens Ti plasmid resides fully within its repC gene. Purified RepC bound to a site within repC with moderate affinity, high specificity and with twofold cooperativity. The binding site was localized to an AT-rich region that contains a large number of GANTC sites, which have been implicated in replication regulation in related organisms. A fragment of RepC containing residues 26-158 was sufficient to bind DNA, although with limited sequence specificity. This portion of RepC is predicted to have structural homology to members of the MarR family of transcription factors. Overexpression of RepC in A. tumefaciens caused large increases in copy number in cis but did not change the copy number of plasmids containing the same oriV sequence in trans, confirming other observations that RepC functions only in cis.

Operons

Operons (clusters of co-regulated genes with related functions) are common features of bacterial genomes. More recently, functional gene clustering has been reported in eukaryotes, from yeasts to filamentous fungi, plants, and animals. Gene clusters can consist of paralogous genes that have most likely arisen by gene duplication. However, there are now many examples of eukaryotic gene clusters that contain functionally related but non-homologous genes and that represent functional gene organizations with operon-like features (physical clustering and co-regulation). These include gene clusters for use of different carbon and nitrogen sources in yeasts, for production of antibiotics, toxins, and virulence determinants in filamentous fungi, for production of defense compounds in plants, and for innate and adaptive immunity in animals (the major histocompatibility locus). The aim of this article is to review features of functional gene clusters in prokaryotes and eukaryotes and the significance of clustering for effective function.

Phase-locked mutants of Mycoplasma agalactiae: defining the molecular switch of high-frequency Vpma antigenic variation

Mycoplasma agalactiae, an important pathogen of small ruminants, exhibits antigenic diversity by switching the expression of multiple surface lipoproteins called Vpmas (Variable proteins of M. agalactiae). Although phase variation has been shown to play important roles in many host–pathogen interactions, the biological significance and the mechanism of Vpma oscillations remain largely unclear. Here, we demonstrate that all six Vpma proteins are expressed in the type strain PG2 and all undergo phase variation at an unusually high frequency. Furthermore, targeted gene disruption of the xer1 gene encoding a putative site-specific recombinase adjacent to the vpma locus was accomplished via homologous recombination using a replicon-based vector. Inactivation of xer1 abolished further Vpma switching and the ‘phase-locked’ mutants (PLMs) continued to steadily express only a single Vpma product. Complementation of the wild-type xer1 gene in PLMs restored Vpma phase variation thereby proving that Xer1 is essential for vpma inversions. The study is not only instrumental in enhancing our ability to understand the role of Vpmas in M. agalactiae infections but also provides useful molecular approaches to study potential disease factors in other ‘difficult-to-manipulate’ mycoplasmas.

How gene order is influenced by the biophysics of transcription regulation

What are the forces that shape the structure of prokaryotic genomes: the order of genes, their proximity, and their orientation? Coregulation and coordinated horizontal gene transfer are believed to promote the proximity of functionally related genes and the formation of operons. However, forces that influence the structure of the genome beyond the level of a single operon remain unknown. Here, we show that the biophysical mechanism by which regulatory proteins search for their sites on DNA can impose constraints on genome structure. Using simulations, we demonstrate that rapid and reliable gene regulation requires that the transcription factor (TF) gene be close to the site on DNA the TF has to bind, thus promoting the colocalization of TF genes and their targets on the genome. We use parameters that have been measured in recent experiments to estimate the relevant length and times scales of this process and demonstrate that the search for a cognate site may be prohibitively slow if a TF has a low copy number and is not colocalized. We also analyze TFs and their sites in a number of bacterial genomes, confirm that they are colocalized significantly more often than expected, and show that this observation cannot be attributed to the pressure for coregulation or formation of selfish gene clusters, thus supporting the role of the biophysical constraint in shaping the structure of prokaryotic genomes. Our results demonstrate how spatial organization can influence timing and noise in gene expression.

TraA, TraC and TraD autorepress two divergent quorum-regulated promoters near the transfer origin of the Ti plasmid of Agrobacterium tumefaciens

Whole-genome transcriptional profiling experiments were performed to identify the complete set of TraR-regulated genes in isogenic A. tumefaciens strains containing an octopine-type or nopaline-type Ti plasmid. Most of the known TraR-regulated genes as well as a number of new inducible genes were identified. Surprisingly, some known members of this regulon showed both weaker induction and weak levels of expression than we had predicted based upon earlier studies. In particular, traA was expressed at surprisingly weak levels. Genetic analysis showed that the traAFBH operon is repressed by formation of a putative relaxosome at oriT consisting the TraA, TraC and TraD. These proteins also repressed the divergent traCDGyci operon. TraA was essential for oriT processing, and both TraC and TraD were necessary for the efficient processing, although some processing occurred in their absence. Likewise, Ti plasmid conjugation required TraA, TraF and TraG, and occurred at reduced levels in the absence of TraC or TraD. TraA preferentially acted in cis in repressing the traA and traC promoters and in the processing of oriT, which explains the very high activity of plasmid-borne traA-lacZ fusions reported in previous studies.

The relaxase of the Rhizobium etli symbiotic plasmid shows nic site cis-acting preference

Genetic and biochemical characterization of TraA, the relaxase of symbiotic plasmid pRetCFN42d from Rhizobium etli, is described. After purifying the relaxase domain (N265TraA), we demonstrated nic binding and cleavage activity in vitro and thus characterized for the first time the nick site (nic) of a plasmid in the family Rhizobiaceae. We studied the range of N265TraA relaxase specificity in vitro by testing different oligonucleotides in binding and nicking assays. In addition, the ability of pRetCFN42d to mobilize different Rhizobiaceae plasmid origins of transfer (oriT) was examined. Data obtained with these approaches allowed us to establish functional and phylogenetic relationships between different plasmids of this family. Our results suggest novel characteristics of the R. etli pSym relaxase for previously described conjugative systems, with emphasis on the oriT cis-acting preference of this enzyme and its possible biological relevance.

The repA gene of the linear Yersinia enterocolitica prophage PY54 functions as a circular minimal replicon in Escherichia coli

The Yersinia enterocolitica prophage PY54 replicates as a linear DNA molecule with covalently closed ends. For replication of a circular PY54 minimal replicon that has been derived from a linear minireplicon, two phage-encoded loci are essential in Escherichia coli: (i) the reading frame of the replication initiation gene repA and (ii) its 212-bp origin located within the 3' portion of repA. The RepA protein acts in trans on the origin since we have physically separated the PY54 origin and repA onto a two-plasmid origin test system. For this trans action, the repA 3' end carrying the origin is dispensable. Mutagenesis by alanine scan demonstrated that the motifs for primase and for nucleotide binding present in the protein are essential for RepA activity. The replication initiation functions of RepA are replicon specific. The replication initiation proteins DnaA, DnaG, and DnaB of the host are unable to promote origin replication in the presence of mutant RepA proteins that carry single residue exchanges in these motifs. The proposed origins of the known related hairpin prophages PY54, N15, and PKO2 are all located toward the 3' end of the corresponding repA genes, where several structure elements are conserved. Origin function depends on the integrity of these elements.

Intramolecular transposition of insertion sequence IS91 results in second-site simple insertions

A series of plasmids carrying an IRL-kan-IRR transposable cassette, in which IRL and IRR are the left- and right-terminal sequences of IS91, have been constructed. These cassettes could be complemented for transposition with similar efficiency when IS91 transposase was provided either in cis or in trans. A total of 87% of IS91 transposition products were simple insertions of the element, while the remaining 13% were plasmid fusions and co-integrates. When transposase expression was induced from an upstream lac promoter, transposition frequency increased approximately 100-fold. An open reading frame (ORF) present upstream of the transposase gene, ORF121, could be involved in target selection, as mutations affecting this ORF were altered in their insertion specificity. Intramolecular rearrangements were analysed by looking at transposition events disrupting a chloramphenicol resistance gene (cat ) located outside the transposable cassette. Plasmid instability resulting from insertion of an extra copy of IRL-kan-IRR within the cat gene was observed; transposition products contained a second copy of the cassette inserted either as a direct or as an inverted repeat. No deletion or inversion of the intervening DNA was observed. These results could be explained as a consequence of intramolecular transposition of IS91 according to a model of rolling-circle transposition.

Genetic analyses of the interactions of the IS1-encoded proteins with the left end of IS1 and its insertion hotspot

Insertion sequence IS1 specifies the InsA, delta InsA-B'-InsB and InsA-B'-InsB protein species. These three proteins have the identical alpha-helix-turn-alpha-helix motif that is likely to be responsible for DNA binding. In fact, InsA binds to the ends of IS1, and regulates gene expression and transposition of IS1. delta InsA-B'-InsB and/or InsA-B'-InsB has been thought to possess a transposase-like activity. Here, I examined the actions of these proteins in vivo on the promoter (pinsL) in the left end of IS1. InsA repressed pinsL-driven gene expression, both in cis and in trans. delta InsA-B'-InsB inhibited it efficiently only when pinsL was located near the construct where delta InsA-B'-InsB is expressed. Furthermore, it has been shown that the possible -10 sequence of pinsL is required for delta InsA-B'-InsB to act on, but the -35 sequence where InsA binds specifically, is not. InsA-B'-InsB appeared not to work on a nearby pinsL. The cis-action of delta InsA-B'-InsB is consistent with the previous observation that the IS1 transposase acts preferentially in cis. Interestingly, delta InsA-B'-InsB acted on a nearby P3 promoter in the IS1 insertion hotspot, and on another promoter outside the hotspot. delta InsA-B'-InsB may generally interact with the regions in or around promoters owing to their low DNA helix stability. Note that IS1 transposes preferentially into A + T-rich DNA segments, and that DNA is unwound from the -10 region of a promoter in transcription. The cis-preference of delta InsA-B'-InsB would result in an overall reduction of transposition of IS1 and its defective copy in a cell, allowing stable existence of the element in its bacterial host.

Cis preference of the IS903 transposase is mediated by a combination of transposase instability and inefficient translation

The transposase protein encoded by the insertion element IS903 belongs to an unusual class of DNA-binding proteins, termed cis-acting proteins, that act preferentially at their site of synthesis. Previous work had led us to propose that instability of the IS903 transposase was a major determinant of its cis preference. Here we describe the isolation of two classes of mutations within the transposase gene that increased action in trans. One class specifically increased trans action without increasing the level of transposition when the mutant gene was located in cis to the transposon. In particular, a threonine-to-proline substitution at amino acid 25 (T25P) reduced cis preference about 60-fold. The half-life of this mutant transposase was significantly longer than that of the wild-type transposase, confirming the critical role of protein instability. The second, larger, class of mutations increased the level of transposition both in trans and in cis. The behaviour and location of these mutations were consistent with an increase in gene expression by improving translational initiation. Several of these mutations exerted a disproportionate effect on the action of transposase in trans, implying that translation efficiency may affect more than just the amount of transposase made. Our results indicate that cis preference of the IS903 transposase is mediated by a combination of transposase instability and inefficient translation initiation.

Organization and transcriptional regulation of the Escherichia coli K-12 D-serine tolerance locus

We have reinvestigated the genetic organization and the transcription regulation of the dsd operon of Escherichia coli. By combining genetic and biochemical studies, it is demonstrated that the regulatory region of the operon and the gene encoding the specific regulator of D-serine tolerance (dsdC) had been misplaced in previous work on the dsd system. Also, the previous erroneous DNA sequence of the dsdC gene has been corrected. It turned out that an additional gene (dsdX) is present immediately upstream of dsdA (encoding D-serine deaminase) and that dsdC is located adjacent to dsdX. The dsdXA genes are cotranscribed from a common promoter region present in the dsdX-dsdC intercistronic region. The DsdC activator belongs to the LysR-type of transcriptional regulators and is absolutely required for dsdA expression. Additionally, the activity of the dsdXA promoter depends on the cyclic AMP receptor protein, and the two activators act in concert to synergistically activate transcription.

Construction of Zn2+/Cd(2+)-tolerant cyanobacteria with a modified metallothionein divergon: further analysis of the function and regulation of smt

This paper reports the (de novo) construction of mutants of Synechococcus PCC 7942 lacking the repressor (SmtB) of the metallothionein gene, smtA. These smtA+/B- cells are more tolerant to elevated [Zn2+] and [Cd2+] than cells containing an intact metallothionein divergon (smt). Previously selected (by step-wise adaptation) Cd(2+)-tolerant mutants contain additional copies of smtA and possibly other undetected mutations. It is now confirmed that these cells also contain a deletion within 'all' copies of smtB and hence fail to revert to wild type following subculture in medium which has not been supplemented with Cd2+ or Zn2+. Northern analysis showed enhanced accumulation of smtA transcripts, even in the absence of added metal ions in these mutants. An increase in the accumulation of Zn2+ is reported in cells containing an intact metallothionein divergon compared to cells deficient in both smtA and smtB. This supports the assumption that SmtA binds Zn2+ within cyanobacterial cells. We also describe the use of the above mentioned mutants to identify additional factors involved in the regulation of transcription from the smtA operator-promoter.

Evidence that the cis preference of the Tn5 transposase is caused by nonproductive multimerization

The transposase (Tnp) of the bacterial transposon Tn5 acts 50- to 100-fold more efficiently on elements located cis to the site of its synthesis compared with those located in trans. In an effort to understand the basis for this cis preference, we have screened for Tnp mutants that exhibit increased transposition activity in a trans assay. Two mutations in the carboxyl terminus were isolated repeatedly. The EK345 mutation characterized previously increases Tnp activity eightfold both in cis and in trans. The novel LP372 mutation, however, increases Tnp activity 10-fold specifically in trans. Combining both mutations increases Tnp activity 80-fold. Interestingly, the LP372 mutation maps to a region shown previously to be critical for interaction with Inh, an inhibitor of Tn5 transposition, and results in reduced inhibition activity by both Tnp and Inh. Tnp also inhibits Tn5 transposition in trans, and this has been suggested to occur by the formation of inactive Tnp multimers. Because Inh and (presumably) Tnp inhibit Tn5 transposition by forming defective multimers with Tnp, the inhibition defect of the trans-active LP372 mutant suggests that the cis preference of Tnp may also be attributable to nonproductive Tnp-Tnp multimerization. In addition, we show that increasing the synthesis of EK345/LP372 Tnp, but not wild-type Tnp, leads to very high levels of transposition, presumably because this altered Tnp is defective in the inhibitory activity of the wild type protein.

Transposition of IS117, the 2.5 kb Streptomyces coelicolor A3(2) 'minicircle': roles of open reading frames and origin of tandem insertions

IS117 is a 2527 bp transposable element from Streptomyces coelicolor A3(2) with a circular transposition intermediate. Disruption of ORF1 of IS117, presumed to encode a transposase, abolished transposition. Deletion or mutation of ORF2 and ORF3, which overlap each other on opposite strands of IS117, caused a c. 20-fold reduction in integration frequency of the circular form of IS117 into the Streptomyces lividans chromosome or into the preferred chromosomal target site cloned on a plasmid in transformation experiments. In contrast, inactivation of ORF2/3 did not significantly influence transposition of IS117 derivatives from an already integrated state in the chromosome to the preferred target site cloned on a plasmid. ORF2 mutants apparently excised readily from the S. lividans chromosome, whereas excision of integrated wild-type IS117 derivatives to yield the unoccupied site was not detected; presumably, therefore, the circular transposition intermediate normally arises replicatively. Attempts to promote integration of a plasmid carrying the attachment site of IS117 by providing the ORF1 product in trans were unsuccessful. Most transformation of S. lividans with circular IS117 derivatives yielded tandem chromosomal insertions, which arose by co-transformation rather than dimerization of a monomeric insert. Typically, two to three transforming elements gave a transformed strain, suggesting a local concentration of transposase as a limit on integration.

Heterogeneous functional Ty1 elements are abundant in the Saccharomyces cerevisiae genome

Despite the abundance of Ty1 RNA in Saccharomyces cerevisiae, Ty1 retrotransposition is a rare event. To determine whether transpositional dormancy is the result of defective Ty1 elements, functional and defective alleles of the retrotransposon in the yeast genome were quantitated. Genomic Ty1 elements were isolated by gap repair-mediated recombination of pGTy1-H3(delta 475-3944) HIS3, a multicopy plasmid containing a GAL1/Ty1-H3 fusion element lacking most of the gag domain (TYA) and the protease (PR) and integrase (IN) domains. Of 39 independent gap repaired pGTyHIS3 elements isolated, 29 (74%) transposed at high levels following galactose induction. The presence of restriction site polymorphisms within the gap repaired region of the 29 functional pGTyHIS3 elements indicated that they were derived from at least eight different genomic Ty1 elements and one Ty2 element. Of the 10 defective pGTyHIS3 elements, one was a partial gap repair event while the other nine were derived from at least six different genomic Ty1 elements. These results suggest that most genomic Ty1 elements encode functional TYA, PR and IN proteins. To understand how functional Ty1 elements are regulated, we tested the hypothesis that a TYB protein associates preferentially in cis with the RNA template that encodes it, thereby promoting transposition of its own element. A genomic Ty1 mhis3AI element containing either an in-frame insertion in PR or a deletion in TYB transposed at the same rate as a wild-type Ty1mhis3AI allele, indicating that TYB proteins act efficiently in trans. This result suggests in principle that defective genomic Ty1 elements could encode trans-acting repressors of transposition; however, expression of only one of the nine defective pGTy1 isolates had a negative effect on genomic Ty1 mhis3AI element transposition in trans, and this effect was modest. Therefore, the few defective Ty1 elements in the genome are not responsible for transpositional dormancy.

Preferential cis action of IS10 transposase depends upon its mode of synthesis

A number of bacterial DNA-binding proteins, including IS element transposases, act preferentially in cis. We show below that the degree of preferential cis action by IS10 transposase depends upon its mode of synthesis at steps subsequent to transcription initiation. Cis preference is increased several fold by mutations that decrease translation initiation, by the presence of IS10-specific antisense RNA and by plasmids that increase the level of cellular RNases. Conversely, cis preference is decreased by mutations that increase translation initiation; in some cases, cis preference is nearly abolished. Mutations that alter the rate of transcription initiation have no effect. In light of other observations, we suggest that cis preference is strongly dependent upon the rate at which transcripts are released from their templates and/or the half-life of the transposase message. These observations provide further evidence that inefficient translation plays multiple roles in the biology of IS10.

csgA expression entrains Myxococcus xanthus development

The development cycle of the myxobacterium Myxococcus xanthus consists of three partially overlapping morphological stages referred to as rippling, fruiting body formation, and sporulation, all of which are absent in csgA null mutants. The CsgA gene product is an extracellular protein, referred to as the C signal, which is essential for developmental cell-cell interactions. csgA expression increases throughout development, reaching its peak during sporulation. CsgA was made limiting for development by constructing nested deletions upstream from the csgA gene, which resulted in reduced csgA expression. Successively larger deletions resulted in termination of development at earlier and earlier stages, with rippling requiring approximately 20% maximum csgA expression, fruiting body formation requiring approximately 30% expression, and sporulation requiring 82% expression. Conversely, artificial induction of csgA also induced development provided nutrients were limiting. These results suggest that steady increases in CsgA over the course of development entrain the natural sequence of morphological events. The csgA upstream region appears to process information concerning the levels of nutrients, peptidoglycan components, and the B signal. In the absence of nutrients, a region extending 400 bp upstream from the start site of transcription was necessary for development and maximal csgA expression. In the presence of low levels of nutrients, a region extending approximately 930 bp upstream was essential for the same tasks. It appears that the upstream region extending from -400 to -930 stimulates csgA expression in the presence of excess carbon, nitrogen, and phosphate, thereby allowing development to go to completion.

Multiple mechanisms contribute to osmotic inducibility of proU operon expression in Escherichia coli: demonstration of two osmoresponsive promoters and of a negative regulatory element within the first structural gene

Transcription of the proU operon in Escherichia coli is induced several hundredfold upon growth of cells in media of elevated osmolarity. A low-copy-number promoter-cloning plasmid vector, with lacZ as the reporter gene, was used for assaying the osmoresponsive promoter activity of each of various lengths of proU DNA, generated by cloning of discrete restriction fragments and by an exonuclease III-mediated deletion approach. The results indicate that expression of proU in E. coli is directed from two promoters, one (P2) characterized earlier by other workers with the start site of transcription 60 nucleotides upstream of the initiation codon of the first structural gene (proV), and the other (P1) situated 250 nucleotides upstream of proV. Furthermore, a region of DNA within proV was shown to be involved in negative regulation of proU transcription; phage Mu dII1681-generated lac fusions in the early region of proV also exhibited partial derepression of proU regulation, in comparison with fusions further downstream in the operon. Sequences around promoter P1, sequences around P2, and the promoter-downstream negative regulatory element, respectively, conferred approximately 5-, 8-, and 25-fold osmoresponsivity on proU expression. Within the region genetically defined to encode the negative regulatory element, there is a 116-nucleotide stretch that is absolutely conserved between the proU operons of E. coli and Salmonella typhimurium and has the capability of exhibiting alternative secondary structure. Insertion of this region of DNA into each of two different plasmid vectors was associated with a marked reduction in the mean topological linking number in plasmid molecules isolated from cultures grown in high-osmolarity medium. We propose that this region of DNA undergoes reversible transition to an underwound DNA conformation under high-osmolarity growth conditions and that this transition mediates its regulatory effect on proU expression.

Effects of structural changes in the dsdA-dsdC intergenic region on D-serine deaminase synthesis

Single-base-pair changes well upstream of its transcription initiation site resulted in partially to fully constitutive expression of the D-serine deaminase structural gene, dsdA, independently of the cyclic AMP-cyclic AMP-binding protein complex and of the specific D-serine deaminase activator protein. These promoter mutations appear to define a consensus sequence that is repeated several times. Basal expression of dsdA+ was also strongly enhanced by subcloning on multicopy plasmids, by the DNA gyrase inhibitor novobiocin, and in dsdC(Con) mutants by increasing growth temperature. These results suggest that activation of dsdA+ expression by the dsdC-encoded protein involves distortion of promoter DNA. A dsdA translation start at bp -731 was verified by subcloning of dsdC+. Plasmid-specified activator at a high concentration interfered with chromosomal dsdC(Con) expression, and the interference was enhanced by deletion of most of the intergenic region from the plasmid. Even at a high concentration, however, plasmid-specified activator did not activate expression of chromosomal dsdA+, and in one case it was actually repressive. These results confirm the strong cis tropism of plasmid-specified dsdC-encoded protein and suggest that it is mediated by multiple sites in the dsdA-dsdC intergenic region.

Role of instability in the cis action of the insertion sequence IS903 transposase

An unusual subset of DNA-binding proteins, termed cis-acting proteins, has been shown to act preferentially at their site of synthesis; the transposases of several bacterial insertion sequences (ISs) fall into this class. The transposase of IS903 exhibits a strong preference for action in cis: complementation of defective transposons in trans occurs at less than 1%. Furthermore, transposition mediated by transposase acting in cis is extremely sensitive to the distance between the 3' end of the transposase gene and the nearest transposon inverted repeat; we find that an insertion of 1 kilobase of DNA reduces transposition to 1-2% of control levels. Here we show that there is a strong correlation between the stability of transposase and its ability to act in trans. We found that the wild-type transposase is a very unstable protein with a physical half-life of about 3 min. However, a transposase-beta-galactosidase fusion protein has a much greater half-life and can act equally well in cis or in trans. In addition, the native transposase is stabilized in lon- strains of Escherichia coli, and, in these protease-deficient strains, trans action of transposase is increased 10- to 100-fold. These results suggest that instability of the IS903 transposase is a major determinant of its cis action and that the La protease, product of the lon gene, is an important determinant of transposase instability.

IS257 from Staphylococcus aureus: member of an insertion sequence superfamily prevalent among gram-positive and gram-negative bacteria

The nucleotide sequences for the IS257 family of insertion sequences from Staphylococcus aureus were compared with those of the ISS1 family from Streptococcus lactis and the IS15 family which is widespread amongst Gram-negative bacteria. These elements have a striking degree of similarity in both their putative transposase polypeptide sequences and their nucleotide sequences (40 to 64% between pairs), including 12 out of 14 bp conservation in their terminal inverted repeats. The evolutionary distance between the IS15 family and the IS257 and ISS1 families of Gram-positive origin is approximately twice that between the IS257 and ISS1 families. Analysis of base substitutions in the three sequences has provided insights into the effect of selection for the G + C content of immigrant genes to conform to that of their hosts, and into the evolution of biases in overall amino acid composition of cellular proteins in prokaryotes and eukaryotes. The IS257, ISS1, IS15 families form a superfamily of insertion sequences that has been involved in the spread of a number of antimicrobial resistance determinants in Gram-positive and Gram-negative pathogens.

The outB gene of Bacillus subtilis regulates its own transcription

The outB gene of Bacillus subtilis is under the control of two promoters (P1 and P2). To study the regulation of expression from the P1 promoter we have constructed a set of multicopy plasmids carrying different portions of the outB region and analyzed the transcripts present in vivo by RNase protection experiments. The data indicate that the product of gene outB regulates its own transcription from the P1 promoter. We also constructed an outB-lacZ fusion in an insertional plasmid. The plasmid was inserted into the chromosome adjacent to or distal from the outB gene. Assays of beta-galactosidase activity and RNase protection experiments are in accordance with a model implying that the product of gene outB regulates the initiation of transcription from the P1 promoter acting in the cis configuration.

RepA protein- and oriR-dependent initiation of R1 plasmid replication: identification of a rho-dependent transcription terminator required for cis-action of repA protein

Initiation of R1 plasmid replication is dependent on cis-acting repA protein and the 188 base-pair (bp) sequence, oriR. RepA protein synthesized in vitro preferentially activates oriR in cis, regardless of the orientation and location of oriR on the template DNA. RepA protein is not reusable after it activates oriR in the cis-position. Cis-action of repA protein is also dependent on the presence of CIS, a 170 bp sequence, between repA and oriR. CIS contains a rho dependent transcription terminator of the repA transcript, deletion of which results in decrease in transformation efficiency and rapid loss of plasmid in the absence of selection. The significance of transcription termination events in replication was indicated by decreased replication activity in vivo caused by premature termination of the repA transcript between repA and CIS. A model which may account for the role of CIS in mediating the cis-action of the repA protein is presented.

DNA sequence of the D-serine deaminase activator gene dsdC

We have determined the DNA sequence of dsdC, the gene that encodes the D-serine deaminase activator protein of Escherichia coli K-12. The sequence contains a single open reading frame that terminates in a UGA codon. One the basis of the size of the protein, 33 kilodaltons, and the amino acid sequence encoded by the open reading frame, we identified a likely translation initiation codon 731 base pairs upstream of the translation initiation codon for the divergently transcribed D-serine deaminase gene. There is a broad range of codon usage, not surprising in view of the weak expression of the gene. The N-terminal two-thirds of the activator is arginine-lysine rich and quite polar; the remainder is more neutral. The segment of the protein that seems most likely to have potential to form the helix-turn-helix structure characteristic of DNA-regulatory proteins is located near the end of the polar region. The protein contains a region with significant homology to lambda attB.

The puf operon region of Rhodobacter sphaeroides

The puf operon of the purple nonsulfur photosynthetic bacterium, Rhodobacter sphaeroides, contains structural gene information for at least two functionally distinct bacteriochlorophyll-protein complexes (light harvesting and reaction center) which are present in a fixed ratio within the photosynthetic intracytoplasmic membrane. Two proximal genes (pufBA) specify subunits of a long wavelength absorbing (i.e., 875 nm) light harvesting complex which are present in the photosynthetic membrane in ≃15 fold excess relative to the reaction center subunits which are encoded by the pufLM genes. This review summarizes recent studies aimed at determining how expression of the R. sphaeroides puf operon region relates to the ratio of individual bacteriochlorophyll-protein complexes found within the photosynthetic membrane. These experiments indicate that puf operon expression may be regulated at the transcriptional, post-transcriptional, translation and post-translational levels. In addition, this review discusses the possible role(s) of newly identified loci upstream of pufB which may be involved in regulating either synthesis or assembly of individual bacteriochrlorophyll-protein complexes as well as the pufX gene, the most distal genetic element within the puf operon whose function is still unknown.

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.

Bacteriophage P22 gene 23 product acts preferentially in cis

The expression of the P22 late operon was measured while the activator of the late operon, the product of gene 23, was provided in cis or in trans. It was found that expression of the late operon, assayed from a late-gene-lacZ gene fusion, was reduced by more than twofold when the only functional copy of gene 23 was present in trans.

Selection of mutations that alter the osmotic control of transcription of the Salmonella typhimurium proU operon

We isolated 60 independent mutations, designated osmX, in Salmonella typhimurium that result in constitutive expression of the normally osmoregulated proU operon. Each of the osmX mutations is closely linked to the proU locus and cis-dominant over the osmX+ allele in diploid strains. These results suggest that the mutations are probably in the 5' transcriptional control region of the proU operon. Our failure to obtain either recessive or unlinked mutations that altered the osmotic control of transcription of the proU operon suggests that transcriptional regulation of the gene is not under the negative control of a repressor protein that is dispensable for cell viability. We discuss possible models for the mechanism of osmotic regulation of transcription of the proU operon.