Structural organization of a complex family of palindromic repeats in Enterococci.

Enterococcus faecalis/faecium repeats (EFARs) are miniature insertion sequences spread in the genome of Enterococcus faecalis and Enterococcus faecium. Unit-length repeats measure 165-170 bp and contain two modules (B and T) capable of folding independently into stem-loop sequences, connected by a short, unstructured module J. The E. faecalis elements feature only one type of B, J and T modules. In contrast, the E. faecium elements result from the assembly of different types of B, J and T modules, and may vary in length because they carry multiple B modules. Most EFARs are located close (0-20 bp) to ORF stop codons, and are thus cotranscribed with upstream flanking genes. In both E. faecalis and E. faecium cells, EFAR transcripts accumulate in a strand-dependent fashion. Data suggest that T modules function as bidirectional transcriptional terminators, which provide a 3'-end to gene transcripts spanning B modules, while blocking antisense transcripts coming in from the opposite direction.

PCR-based rapid genotyping of Stenotrophomonas maltophilia isolates.

BACKGROUND: All bacterial genomes contain repetitive sequences which are members of specific DNA families. Such repeats may occur as single units, or found clustered in multiple copies in a head-to-tail configuration at specific loci. The number of clustered units per locus is a strain-defining parameter. Assessing the length variability of clusters of repeats is a versatile typing methodology known as multilocus variable number of tandem repeat analysis (MLVA). RESULTS: Stenotrophomonas maltophilia is an environmental bacterium increasingly involved in nosocomial infections and resistant to most antibiotics. The availability of the whole DNA sequence of the S. maltophilia strain K279a allowed us to set up fast and accurate PCR-based diagnostic protocols based on the measurement of length variations of loci carrying a variable number of short palindromic repeats marking the S. maltophilia genome. On the basis of the amplimers size, it was possible to deduce the number of repeats present at 12 different loci in a collection of S. maltophilia isolates, and therefore label each of them with a digit. PCR-negative regions were labelled 0. Co-amplification of two pairs of loci provided a 4-digit code sufficient for immediate subtyping. By increasing the number of loci analyzed, it should be possible to assign a more specific digit profile to isolates. In general, MLVA data match genotyping data obtained by PFGE (pulsed-field gel electrophoresis). However, some isolates exhibiting the same PCR profiles at all loci display distinct PFGE patterns. CONCLUSION: The utilization of the present protocol allows to type several S. maltophilia isolates in hours. The results are immediately interpretable without the need for sophisticated softwares. The data can be easily reproducible, and compared among different laboratories.

The platelet-derived growth factor controls c-myc expression through a JNK- and AP-1-dependent signaling pathway.

Pro-inflammatory cytokines, environmental stresses, as well as receptor tyrosine kinases regulate the activity of JNK. In turn, JNK phosphorylates Jun members of the AP-1 family of transcription factors, thereby controlling processes as different as cell growth, differentiation, and apoptosis. Still, very few targets of the JNK-Jun pathway have been identified. Here we show that JNK is required for the induction of c-myc expression by PDGF. Furthermore, we identify a phylogenetically conserved AP-1-responsive element in the promoter of the c-myc proto-oncogene that recruits in vivo the c-Jun and JunD AP-1 family members and controls the PDGF-dependent transactivation of the c-myc promoter. These findings suggest the existence of a novel biochemical route linking tyrosine kinase receptors, such as those for PDGF, and c-myc expression through JNK activation of AP-1 transcription factors. They also provide a novel potential mechanism by which both JNK and Jun proteins may exert either their proliferative or apoptotic potential by stimulating the expression of the c-myc proto-oncogene.

Asymmetrical distribution of Neisseria miniature insertion sequence DNA repeats among pathogenic and nonpathogenic Neisseria strains.

Neisseria miniature insertion sequences (nemis) are miniature DNA insertion sequences found in Neisseria species. Out of 57 elements closely flanking cellular genes analyzed by PCR, most were conserved in Neisseria meningitidis but not in N. lactamica strains. Since mRNAs spanning nemis are processed by RNase III at hairpins formed by element termini, gene sets could selectively be regulated in meningococci at the posttranscriptional level.

Ribonuclease III-mediated processing of specific Neisseria meningitidis mRNAs.

Approx. 2% of the Neisseria meningitidis genome consists of small DNA insertion sequences known as Correia or nemis elements, which feature TIRs (terminal inverted repeats) of 26-27 bp in length. Elements interspersed with coding regions are co-transcribed with flanking genes into mRNAs, processed at double-stranded RNA structures formed by TIRs. N. meningitidis RNase III (endoribonuclease III) is sufficient to process nemis+ RNAs. RNA hairpins formed by nemis with the same termini (26/26 and 27/27 repeats) are cleaved. By contrast, bulged hairpins formed by 26/27 repeats inhibit cleavage, both in vitro and in vivo. In electrophoretic mobility shift assays, all hairpin types formed similar retarded complexes upon incubation with RNase III. The levels of corresponding nemis+ and nemis- mRNAs, and the relative stabilities of RNA segments processed from nemis+ transcripts in vitro, may both vary significantly.

NusA modulates intragenic termination by different pathways.

In bacteria, conditions that uncouple translation from transcription activate intragenic terminators located within cistrons. We analyzed the function of NusA in intragenic termination, making use of two tandem terminators located within the hisG cistron, GTTE1 and GTTE2. GTTE2 is a canonical Rho site, capable to terminate with Rho alone in vitro. By contrast, GTTE1 is a suboptimal terminator, featuring a boxA element and requiring a functional NusB to terminate efficiently in vivo. We found that a functional NusA is necessary for efficient termination events to occur at both GTTE1 and 2. To enhance termination at GTTE1 in conditions in which the transcript is free of ribosomes, NusA acts at the same step as NusB and NusE/S10. In the presence of concomitant translation, termination at GTTE1 is dependent on the relative position of the translation stop codon and boxA. If translation stops upstream of boxA, NusA acts at the same step as NusB enhance termination. Ribosomes terminating translation at boxA influence termination at GTTE1. Interactions of NusA and/or NusB with ribosomal components, including NusE/S10, might facilitate termination. Differently from what observed at GTTE1, the NusA-stimulated pausing seems to be sufficient for the occurrence of complete termination events at GTTE2. A functional NusA is also necessary to prevent premature termination of normally translated transcripts. Our data support the hypothesis that NusA may program a fraction of the RNA polymerase to terminate transcription upon interactions with specific sites on the nascent mRNA and either other Nuses or ribosomes.

The abundant class of nemis repeats provides RNA substrates for ribonuclease III in Neisseriae.

About 2% of the Neisseria meningitidis genome is made up by nemis, short DNA sequences which feature long terminal inverted repeats (TIRs). Most nemis are interspersed with single-copy DNA and are found at close distance from cellular genes. In this work, we demonstrate than RNAs spanning nemis of different length and sequence compositions are specifically cleaved at hairpins formed by nemis termini by total cellular lysates derived from both Escherichia coli and Neisseria lactamica strains. The use of cellular extracts from E. coli strains impaired in the activity of known ribonucleases let to establish that cleavage at nemis TIRs is specifically mediated by the endoribonuclease RNase III. Data set the base for the identification of all of the neisserial genes that are regulated by RNase III because of their physical association with nemis DNA.