CRISPR (clustered regularly interspaced short palindromic repeats) arrays and their associated (Cas) proteins confer bacteria and archaea adaptive immunity against exogenous mobile genetic elements, such as phages or plasmids. CRISPRCasFinder allows the identification of both CRISPR arrays and Cas proteins. The program includes: (i) an improved CRISPR array detection tool facilitating expert validation based on a rating system, (ii) prediction of CRISPR orientation and (iii) a Cas protein detection and typing tool updated to match the latest classification scheme of these systems. CRISPRCasFinder can either be used online or as a standalone tool compatible with Linux operating system. All third-party software packages employed by the program are freely available. CRISPRCasFinder is available at https://crisprcas.i2bc.paris-saclay.fr.
Recent progress in the field of human genome analysis has led to the development of new concepts in the definition of subtelomeric domains. Analysis of DNA sequences from human and yeast chromosome ends have shown that short stretches of degenerate TTAGGG are found at a distance from the telomeric repeats. These stretches define a boundary between two structurally different regions. The distal domain is characterised by numerous, short segments of interrupted homology to many other human telomeric regions and to a number of ESTs. The proximal domain shows much longer uninterrupted homology to a few chromosome ends. This domain evolved quickly within primates at least, as demonstrated by the detailed study of locus DNF92 which spread very recently in humans from 17 qter to at least ten other chromosome ends. At the different sites, presence-absence polymorphisms are observed within humans. The region remained single locus at the paralogous site in higher primates. Conversely, a human and orangutan single locus telomeric domain occupies multiple chromosome ends in chimpanzee. Balanced translocation is the likely mechanism through which the spreading occurred. Some members of the olfactory receptor gene family show a similar behaviour: multiple telomeric locations, and presence-absence polymorphism. Strikingly, the set of chromosome ends occupied by the two regions is identical, except for the two ancestral sites. Moreover, the relative frequency of detection of the region at the different sites indicates some kind of competition between the two regions. Consequently, these two regions represent major new tools to investigate recent human genome evolution and human genome diversity in different populations.
We report a deletion of 1p36.3 in a child with microcephaly, mental retardation, broad forehead, deep set eyes, depressed nasal bridge, flat midface, relative prognathism, and abnormal ears. The phenotype is consistent with that described for partial monosomy for 1p36.3. Reverse chromosome painting and microsatellite and Southern blot analyses were used to map the extent of the deletion. Fluorescence in situ hybridisation (FISH) analysis using probes from every telomere indicates that the rearrangement is likely to be a chromosomal truncation or rearrangement involving subtelomeric repetitive DNA. The deletion was identified by screening a sample of children and adults with idiopathic mental retardation. In conjunction with previous work on this sample, we estimate that 7.4% of the group have subtelomeric rearrangements.
A synthetic probe, STR 14C13, detects a new polymorphic locus on chromosome arm 7q (D7S450) Get access Valérie Lauthier, Valérie Lauthier Centre d'Etudes du Bouchet, Laboratoire de Génétique Moléculaire, BP no. 3, 91710 Vert le PetitFrance Search for other works by this author on: Oxford Academic PubMed Google Scholar Denis Mariat, Denis Mariat Centre d'Etudes du Bouchet, Laboratoire de Génétique Moléculaire, BP no. 3, 91710 Vert le PetitFrance Search for other works by this author on: Oxford Academic PubMed Google Scholar Monique Zoroastro, Monique Zoroastro Centre d'Etudes du Bouchet, Laboratoire de Génétique Moléculaire, BP no. 3, 91710 Vert le PetitFrance Search for other works by this author on: Oxford Academic PubMed Google Scholar Gilles Vergnaud Gilles Vergnaud * Centre d'Etudes du Bouchet, Laboratoire de Génétique Moléculaire, BP no. 3, 91710 Vert le PetitFrance *To whom correspondence should be addressed Search for other works by this author on: Oxford Academic PubMed Google Scholar Nucleic Acids Research, Volume 19, Issue 14, 25 July 1991, Page 4014, https://doi.org/10.1093/nar/19.14.4014-a Published: 25 July 1991
In Archeae and Bacteria, the repeated elements called CRISPRs for "clustered regularly interspaced short palindromic repeats" are believed to participate in the defence against viruses. Short sequences called spacers are stored in-between repeated elements. In the current model, motifs comprising spacers and repeats may target an invading DNA and lead to its degradation through a proposed mechanism similar to RNA interference. Analysis of intra-species polymorphism shows that new motifs (one spacer and one repeated element) are added in a polarised fashion. Although their principal characteristics have been described, a lot remains to be discovered on the way CRISPRs are created and evolve. As new genome sequences become available it appears necessary to develop automated scanning tools to make available CRISPRs related information and to facilitate additional investigations.We have produced a program, CRISPRFinder, which identifies CRISPRs and extracts the repeated and unique sequences. Using this software, a database is constructed which is automatically updated monthly from newly released genome sequences. Additional tools were created to allow the alignment of flanking sequences in search for similarities between different loci and to build dictionaries of unique sequences. To date, almost six hundred CRISPRs have been identified in 475 published genomes. Two Archeae out of thirty-seven and about half of Bacteria do not possess a CRISPR. Fine analysis of repeated sequences strongly supports the current view that new motifs are added at one end of the CRISPR adjacent to the putative promoter.It is hoped that availability of a public database, regularly updated and which can be queried on the web will help in further dissecting and understanding CRISPR structure and flanking sequences evolution. Subsequent analyses of the intra-species CRISPR polymorphism will be facilitated by CRISPRFinder and the dictionary creator. CRISPRdb is accessible at http://crispr.u-psud.fr/crispr.
Q (query) fever is an infectious zoonotic disease caused by the Gram-negative bacterium Coxiella burnetii. Although the disease has been studied for decades, it still represents a threat due to sporadic outbreaks across farms in Europe. The absence of a central platform for Coxiella typing data management is an important epidemiological gap that is relevant in the case of an outbreak. To fill this gap, we have designed and implemented an online, open-source, web-based platform called CoxBase (https://coxbase.q-gaps.de). This platform includes a database that holds genotyping information on more than 400 Coxiella isolates alongside metadata that annotate them. We have also implemented features for in silico genotyping of completely or minimally assembled Coxiella sequences using five different typing methods, querying of existing isolates, visualization of isolate geodata via aggregation on a world map, and submission of new isolates. We tested our in silico typing method on 50 Coxiella genomes downloaded from the RefSeq database, and we successfully genotyped all genomes except for cases where the sequence quality was poor. We identified new spacer sequences using our implementation of the multispacer sequence typing (MST) in silico typing method and established adaA gene phenotypes for all 50 genomes as well as their plasmid types. IMPORTANCE Q fever is a zoonotic disease that is a source of active epidemiological concern due to its persistent threat to public health. In this project, we have identified areas in the field of Coxiella research, especially regarding public health and genomic analysis, where there is an inadequacy of resources to monitor, organize, and analyze genomic data from C. burnetii. Subsequently, we have created an open, web-based platform that contains epidemiological information, genome typing functions comprising all the available Coxiella typing methods, and tools for isolate data discovery and visualization that could help address the above-mentioned challenges. This is the first platform to combine all disparate genotyping systems for Coxiella burnetii as well as metadata assets with tools for genomic comparison and analyses. This platform is a valuable resource for laboratory researchers as well as research epidemiologists interested in investigating the relatedness or dissimilarity among C. burnetii strains.
The present study was aimed at simplifying procedures to delineate species and identify isolates based on DNA–DNA reassociation. DNA macro-arrays harbouring genomic DNA of reference strains of several Burkholderia species were produced. Labelled genomic DNA, hybridized to such an array, allowed multiple relative pairwise comparisons. Based on the relative DNA–DNA relatedness values, a complete data matrix was constructed and the ability of the method to discriminate strains belonging to different species was assessed. This simple approach led successfully to the discrimination of Burkholderia mallei from Burkholderia pseudomallei, but also discriminated Burkholderia cepacia genomovars I and III, Burkholderia multivorans, Burkholderia pyrrocinia, Burkholderia stabilis and Burkholderia vietnamiensis. Present data showed a sufficient degree of congruence with previous DNA–DNA reassociation techniques. As part of a polyphasic taxonomic scheme, this straightforward approach is proposed to improve species definition, especially for application in the rapid screening necessary for large numbers of clinical or environmental isolates.
