Peptide permeases modulate transformation in Streptococcus pneumoniae

To Identify elements participating In the process of transformation, a bank of genetically altered mutants of Streptococcus pneumoniae with defects in exported proteins was assessed for a decrease in transformation efficiency. One mutant consistentiy transformed 10-foid less than the parent strain. Sequence analysis and reconstitution of the altered locus revealed a gene, plpA (permease-like protein), which encodes a putative substrate-binding protein belonging to the family of bacterial permeases responsible for peptide transport. The derived amino acid sequence for this gene was 80% similar to AmiA, a peptide-binding protein homologue from pneumococcus, and 50% similar over 230 amino acids to SpooKA which is a regulatory element in the process of transformation and sporulation in Bacillus subtilis. PIpA fusions to alkaline phosphatase (PhoA) were shown to be membrane associated and labelled with [³H]-palmitic acid, which probably serves as a membrane anchor. Experiments designed to define the roles of the pIpA and ami determinants in the process of transformation showed that: (i) mutants with defects in plpA were >90% transformation deficient while ami mutants exhibited up to a fourfold increase in transformation efficiency; (ii) compared to the parental strain, the onset of competence in an ami mutant occurred earlier in logarithmic growth, whereas the onset was delayed in a plpA mutant; and (ill) the plpA mutation decreases the expression of a competence-regulated locus. Since the permease mutants would fail to bind specific ligands, it seems likely that the substrate-permease interaction modulates the process of transformation.     

A colony‐to‐lawn method for efficient transformation of Escherichia coli

Aims: To develop a fast, convenient, inexpensive and efficient Escherichia coli transformation method for changing hosts of plasmids, which can also facilitate the selection of positive clones after DNA ligation and transformation. Methods and Results: A single fresh colony from plasmid‐containing donor strain is picked up and suspended in 75% ethanol. Cells are pelleted and resuspended in CaCl₂ solution and lysed by repetitive freeze–thaw cycles to obtain plasmid‐containing cell lysate. The E. coli recipient cells are scraped from the lawn of LB plate and directly suspended in the plasmid‐containing cell lysate for transformation. Additionally, a process based on colony‐to‐lawn transformation and protein expression was designed and conveniently used to screen positive clones after DNA ligation and transformation. Conclusions: With this method, a single colony from plasmid‐containing donor strain can be directly used to transform recipient cells scraped from lawn of LB plate. Additionally, in combination with this method, screening of positive clones after DNA ligation and transformation can be convenient and time‐saving. Significance and Impact of the Study: Compared with current methods, this procedure saves the steps of plasmid extraction and competent cell preparation. Therefore, the method should be highly valuable especially for high‐throughput changing hosts of plasmids during mutant library creation.     

Molecular heterozygotes in Bacillus subtilis and their correction

Summary Data are presented on the probability of correction of molecular heterozygotes during the transformation of Bacillus subtilis. This value varies between 0 and 1 for different mutants in the same genetic locus. The correction of closely linked markers is simultaneous but it is independent for distant loci. The efficiency of integration of different genetic markers during transformation depends on their ability to be corrected towards the structure of the recipient strain.The linked correction of neighboring markers explains quantitatively the asymmetric phenomena in reciprocal crosses.UV-irradiation of transforming DNA inhibits strongly the correction of molecular heterozygotes and eliminates the asymmetry in reciprocal crosses. The same effect is found after chemical damage of DNA by nitrous acid.     

Identification and characterization of a cell envelope protein of Haemophilus influenzae contributing to phase variation in colony opacity and nasopharyngeal colonization

Haemophilus influenzae undergoes spontaneous phase variation in colony morphology. Organisms from transparent colonies efficiently colonize the nasopharynx in an infant rat model of H. influenzae carriage, whereas organisms from more opaque colonies are deficient at colonization. A genetic approach relying on the transformability of H. influenzae was used to identify a locus contributing to opacity variation. By screening a library of chomosomal DNA from an opaque variant of strain Rd, it was possible to isolate a single clone capable of transforming a transparent Rd host to a more opaque phenotype. A region containing two genes, designated oapA and oapB , was identified. The deduced amino acid sequence of oapB has similarity to a consensus sequence for bacterial lipoproteins. Genetically defined mutations in oapA were transformed into the transparent Rd to confirm that this gene is required for expression of the transparent colony phenotype. Although oapA lacks a signal sequence, gene fusions to phoA show that OapA is secreted in H. influenzae and undergoes phase variation in expression. Mutagenesis of oapA in strain Rd, and type b strain Eagan, resulted in loss of the ability to colonize the nasopharynx of infant rats. The type b mutant, however, was as virulent as its parent strain when inoculated intraperitoneally. This suggests that the contribution of OapA to pathogenesis is limited to events associated with colonization of the mucosal surface.     

A new approach to quantify the adaptive potential of gene expression variation in gymnosperms

Variation in patterns of gene expression contributes to phenotypic diversity and can ultimately predict adaptive responses. However, in many cases, the consequences of regulatory mutations on patterns of gene expression and ultimately phenotypic differences remain elusive. A standard way to study the genetic architecture of expression variation in model systems has been to map gene expression variation to genetic loci (Fig. 1a). At the same time, in many nonmodel species, especially for long‐lived organisms, controlled crosses are not feasible. If we are to expand our understanding of the role of regulatory mutations on phenotypes, we need to develop new methodologies to study species under ecologically relevant conditions. In this issue of Molecular Ecology, Verta et al. ( 2013 ) present a new approach to analyse gene expression variation and regulatory networks in gymnosperms (Fig. 1b). They capitalized on the fact that gymnosperm seeds contain an energy storage tissue (the megagametophyte) that is directly derived from a single haploid cell (the megaspore). The authors identified over 800 genes for which expression segregated in this maternally inherited haploid tissue. Based on the observed segregation patterns, these genes (Mendelian Expression Traits) are most probably controlled by biallelic variants at a single locus. Most of these genes also belonged to different regulatory networks, except for one large group of 180 genes under the control of a putative trans‐acting factor. In addition, the approach developed here may also help to uncover the effect of rare recessive mutations, which usually remain hidden in a heterozygous state in diploid individuals. The appeal of the work by Verta et al. ( 2013 ) to study gene expression variation is in its simplicity, which circumvents several of the hurdles behind traditional expression quantitative trait locus (eQTL) studies, and could potentially be applied to a large number of species.     

Transcriptional analysis of the titin cap gene

Mutations in titin cap (Tcap), also known as telethonin, cause limb-girdle muscular dystrophy type 2G (LGMD2G). Tcap is one of the titin interacting Z-disc proteins involved in the regulation and development of normal sarcomeric structure. Given the essential role of Tcap in establishing and maintaining normal skeletal muscle architecture, we were interested in determining the regulatory elements required for expression of this gene in myoblasts. We have defined a highly conserved 421 bp promoter proximal promoter fragment that contains two E boxes and multiple putative Mef2 binding sequences. This promoter can be activated by MyoD and myogenin in NIH3T3 fibroblast cells, and maintains the differentiated cell-specific expression pattern of the endogenous Tcap in C2C12 cells. We find that while both E boxes are required for full activation by MyoD or myogenin in NIH3T3 cells, the promoter proximal E box has a greater contribution to activation of this promoter in C2C12 cells and to activation by MyoD in NIH3T3 cells. Together, the data suggest an important role for MyoD in activating Tcap expression through the promoter proximal E box. We also show that myogenin is required for normal expression in vivo and physically binds to the Tcap promoter during embryogenesis.     

Influence of gene position on the expression divergence of oxidative response genes in intraspecific yeast

Phenotypic variation can arise from differences in the protein coding sequence and in the regulatory elements. However, little is known about the contribution of regulatory difference to the expression divergence, especially the cis and trans regulatory variation to the expression divergence in intraspecific populations. In this study, we used two different yeast strains, BY4743 and RM11‐1a/α, to study the regulatory variation to the expression divergence between BY and RM under oxidative stress condition. Our results indicated that the expression divergence of BY and RM is mainly due to trans regulatory variations under both normal and oxidative stress conditions. However, cis regulatory variation seems to play a very important role in oxidative stress response in yeast because 36% of genes showed an increase in cis regulatory variation effect compared with 13% of genes that showed an increase in trans regulatory variation effect after oxidative stress. Our data also indicated that genes located on the longer arm of the chromosomes are more susceptible to cis variation effect under oxidative stress than genes on the shorter arm of the chromosomes.     

A convenient colony-based transformation method for high-throughput changing of plasmid hosts

We have developed a convenient Escherichia coli transformation method, termed colony-based transformation, in which a single fresh colony of plasmid-containing donor strain is used instead of extracted plasmid to transform E. coli recipient cell. Thus the need for plasmid extraction and competent cell preparation is avoided. Additionally, a high-throughput transformation process based on this method was designed in which samples are prepared in a 96-well PCR plate and hundreds of transformations can be performed simultaneously in a thermocycler. We therefore suggest that this method may serve as a substitute of current transformation methods based on plasmid extraction.     

Disruption of the Fatty Acid Δ<Superscript>6</Superscript>-Desaturase Gene in the Oil-Producing Fungus <Emphasis Type="Italic">Mortierella isabellina</Emphasis> by Homologous Recombination

The γ-linolenic acid-producing fungus Mortierella isabellina 6-22 is an important industrial strain. To clarify the biosynthetic pathways for polyunsaturated fatty acids in this strain, a disruption vector pD4MI6, including 5′ and 3′ regions of the fatty acid Δ⁶-desaturase open reading frame as homologous recombination elements and the Escherichia coli hygromycin B (HmB) phosphotransferase gene (hph) as selectable marker, was successfully constructed. Following transformation of pD4MI6 into the hygromycin B-sensitive recipient strain M. isabellina 6-22-4, a Δ⁶-desaturase gene-defective mutant strain was selected that was unable to produce γ-linolenic acid as determined by gas chromatography and molecular analysis. The morphology and physiology of the mutant, such as colony shape, color, and growth rate, were changed dramatically compared with that of strain M. isabellina 6-22-4.     

Novel determinant (comA) essential for natural transformation competence in Neisseria gonorrhoeae and the effect of a comA defect on pilin variation

A novel genetic determinant (comA) has been identified and found to be required for the transformation of piliated Neisseria gonorrhoeae. Mutants in comA of strain MS11 grow normally and are DNA-uptake proficient but blocked in the translocation of DNA into the cytoplasm. Here we show by site-specific mutagenesis and genetic complementation that only one of two open reading frames identified in comA is essential for competence: it encodes a protein (ComA) with a predicted size of 74kDa. The comAgene maps upstream of the iga locus and is transcribed in the opposite orientation, probably under the control of a putative σ;⁵⁴ type promoter. While DNA probes specific for the N. gonorrhoeae iga locus reveal only a little cross-reactivity with commensal Neisseria species, the neighbouring comA gene appears to be present in most of them. ComA fusion proteins were obtained by in vitro translation. The synthesized gene products migrated atypically in SDS gels indicating its strong hydrophobicity. Several transmembrane α-helices were predicted from the amino acid sequence of ComA which, in the context of an observed sequence similarity with other inner membrane proteins, suggests a location for the protein in the inner membrane. Using piliated and non-piliated comA mutants the consequences of transformation deficiency on pilin phase variation were assessed. We show that the comA defect affects some but not all types of DNA rearrangements associated with pilE variation. The results are in agreement with previous observations supporting the notion that multiple recombination pathways contribute to the variability of pilE.     

Correlated evolution of the cis-acting regulatory elements and developmental expression of the Drosophila Gld gene in seven species from the subgroup melanogaster

The tissue-specific expression patterns of glucose dehydrogenase (GLD) exhibit a high degree of inter specific variation in the adult reproductive tract among the species in the genus Drosophila. We chose to focus on the evolution of GLD expression and the evolution of the Gld promoter in seven closely related species in the mela-nogaster subgroup as a means of elucidating the relationship of changes in cis-acting regulatory elements in the Gld promoter region with changes in tissue-specific expression. Although little variation in tissue-specific patterns of GLD was found in nonreproductive tissues during development, a surprisingly high level of variation was observed in the expression of GLD in both developing and ma-ture reproductive organs. In some cases this variation is correlated with changes in sequence elements in the Gld promoter which were previously shown to direct tissue-specific expression in the reproductive tract. In particular D. teissieri adult males do not express GLD in their ejaculatory ducts, atypical of the melanogaster subgroup species. The Gld promoter region of D. teissieri specifically lacks all three of the TTAGA regulatory elements present in D. melanogaster. The TTAGA elements were previously shown to direct reporter gene expression to the ejaculatory duct. Together these data suggest the absence or presence of the TTAGA elements may be responsible for variation in the absence or presence of GLD in the ejaculatory duct among species. © 1994 Wiley-Liss, Inc.     

Transduction versus transformation of methicillin resistance inStaphylococcus aureus

Requirements for the transformation of methicillin resistance (Mec^r) inStaphylococcus aureus were found to differ from those of transduction in three significant respects. Production of -lactamase by the recipient strain is not a stringent requirement for Mec^r transformation as it is for transduction althoughbla ⁺ recipients exhibited a higher transformation frequency in the absence of added NaCl. Incorporation of NaCl into the methicillin-selective media markedly inhibited Mec^r transduction but increased the transformation frequency of plasmid-free recipients to the level obtained withbla ⁺ recipients. Four separately maintained clones of strain 8325-4 exhibited marked variation in recipient effectiveness for Mec^r transduction but were equally effective as recipients in transformation.     

Regulation of the expression of iso 2-cytochrome c gene in S. cerevisiae: cloning of the positive regulatory gene CYP1 and identification of the region of its target sequence on the structural gene CYP3

Summary CYP1 is a trans acting regulatory locus modulating both iso 1- and iso 2-cytochrome c synthesis. Genetical analysis of various mutated alleles has allowed us to identify the gene product as a positive regulatory element.The region of the target sequence of the CYP1 product on the iso 2-cytochrome c structural gene was located by molecular and genetic analysis of two cis acting mutations located at the CYP3 locus: CYP3-36 and CYP3-4, which have been shown to arise from the integration of TY1 elements near the promoter site. Determination of the amount of iso 2-cytochrome c synthesized by strains bearing various genetic constructions, in which the cis acting mutations were associated with different alleles of the CYP1 trans acting locus, showed that TY1 inserted into CYP3-36 extinguishes the activation function due to a mutated overproducer allele CYP1-18, while CYP3-4 amplifies this function. This result identifies at least a part of the target sequence of the CYP1 product within the region separating the two TY1 insertions.To clone the CYP1 gene, we took advantage of the iso 2-cytochrome c overproducer phenotype of the mutated allele CYP1-18, which confers a Lactate⁺ phenotype on an iso 1-cytochrome c-deficient strain. Such a phenotype allowed the isolation of a recombinant plasmid YEpJFM1 carrying the mutated allele, able to complement on lactate medium a lactate ^- recipient strain. The identity of the YEpJFM1 sequence with the chromosomal gene was confirmed by homologous recombination at the CYP1 locus.     

Characterization of a new organization of the plantaricin locus in the inducible bacteriocin-producing<Emphasis Type="Italic"> Lactobacillus plantarum</Emphasis> J23 of grape must origin

Lactobacillus plantarum J23 was previously characterized as a bacteriocin-producer-strain when it was cocultured with other lactic acid bacteria. In this work, the genetic organization of the pln locus in the J23 strain was studied and compared with those of previously described L. plantarum C11, WCFS1 and NC8 strains. A new organization of the plantaricin locus was detected in the J23 strain. The sequenced fragment (20,266 bp) comprised plnJLR, plnMNOP, plnEFI, plnGHSTUVWXY, and plNC8IF-plNC8HK-plnD operons, as well as a new region that includes three new orfs (GenBank accession number DQ323671). When the J23 pln gene sequences were compared with those included in the GenBank database, the identity of the putative encoded proteins was in the range 67.1–100%. The regulatory system and the repertoire of putative bacteriocins of the J23 pln locus presented important differences with respect to the ones of C11, WCFS1 and NC8, such as the absence of plnK and the presence of a larger plnJ gene than the previously described for the other L. plantarum strains. The pln locus in L. plantarum strains seems to be a mosaic-like structure with different modules and reorganizations that presents highly conserved regions related to transport and bacteriocin maturation and variable regions related to regulation and bacteriocin production.     

TfoX-Based Genetic Mapping Identifies Vibrio fischeri Strain-Level Differences and Reveals a Common Lineage of Laboratory Strains

Bacterial strain variation exists in natural populations of bacteria and can be generated experimentally through directed or random mutation. The advent of rapid and cost-efficient whole-genome sequencing has facilitated strain-level genotyping. Even with modern tools, however, it often remains a challenge to map specific traits to individual genetic loci, especially for traits that cannot be selected under culture conditions (e.g., colonization level or pathogenicity). Using a combination of classical and modern approaches, we analyzed strain-level variation in Vibrio fischeri and identified the basis by which some strains lack the ability to utilize glycerol as a carbon source. We proceeded to reconstruct the lineage of the commonly used V. fischeri laboratory strains. Compared to the wild-type ES114 strain, we identify in ES114-L a 9.9-kb deletion with endpoints in tadB2 and glpF; restoration of the missing portion of glpF restores the wild-type phenotype. The widely used strains ESR1, JRM100, and JRM200 contain the same deletion, and ES114-L is likely a previously unrecognized intermediate strain in the construction of many ES114 derivatives. ES114-L does not exhibit a defect in competitive squid colonization but ESR1 does, demonstrating that glycerol utilization is not required for early squid colonization. Our genetic mapping approach capitalizes on the recently discovered chitin-based transformation pathway, which is conserved in the Vibrionaceae; therefore, the specific approach used is likely to be useful for mapping genetic traits in other Vibrio species.