Generation of a CRISPR database forYersinia pseudotuberculosiscomplex and role of CRISPR-based immunity in conjugation

Harnessing the Native Type I-F CRISPR-Cas System of Acinetobacter baumannii for Genome Editing and Gene Repression

INTRODUCTION

The rapid emergence of infections caused by multidrug-resistant Acinetobacter baumannii (A. baumannii) has posed a serious threat to global public health. It has therefore become important to obtain a deeper understanding of the mechanisms of multidrug resistance and pathogenesis of A. baumannii; however, there are still relatively few genetic engineering tools for this. Although A. baumannii possesses Type I-F CRISPR-Cas systems, they have not yet been used for genetic modifications.

METHODS

A single plasmid-mediated native Type I-F CRISPR-Cas system for gene editing and gene regulation in A. baumannii was developed. The protospacer adjacent motif sequence was identified as 5'-NCC-3' by analysis of the CRISPR array.

RESULTS

Through introduction of the RecAb homologous recombination system, the knockout efficiency of the oxyR gene significantly increased from 12.5% to 75.0% in A. baumannii. To investigate transcriptional inhibition by the Type I-F CRISPR system, the gene encoding its Cas2-3 nuclease was deleted and the native Type I-F Cascade effector was repurposed to regulate transcription of alcohol dehydrogenase gene adh4. The level of adh4 transcription was inhibited by up to 900-fold compared with the control. The Cascade transcriptional module was also successfully applied in a clinical Klebsiella pneumoniae isolate.

CONCLUSION

This study proposed a tool for future exploration of the genetic characteristics of A. baumannii or other clinical strains.

Clustered regularly interspaced short palindromic repeats-Cas system: diversity and regulation in Enterobacteriaceae

Insights into the arms race between bacteria and invading mobile genetic elements have revealed the intricacies of the clustered regularly interspaced short palindromic repeats (CRISPR)-Cas system and the counter-defenses of bacteriophages. Incredible spacer diversity but significant spacer conservation among species/subspecies dictates the specificity of the CRISPR-Cas system. Researchers have exploited this feature to type/subtype the bacterial strains, devise targeted antimicrobials and regulate gene expression. This review focuses on the nuances of the CRISPR-Cas systems in Enterobacteriaceae that predominantly harbor type I-E and I-F CRISPR systems. We discuss the systems' regulation by the global regulators, H-NS, LeuO, LRP, cAMP receptor protein and other regulators in response to environmental stress. We further discuss the regulation of noncanonical functions like DNA repair pathways, biofilm formation, quorum sensing and virulence by the CRISPR-Cas system. The review comprehends multiple facets of the CRISPR-Cas system in Enterobacteriaceae including its diverse attributes, association with genetic features, regulation and gene regulatory mechanisms.

CRISPR: A new paradigm of theranostics

Infectious and hereditary diseases are the primary cause of human mortality globally. Applications of conventional techniques require significant improvement in sensitivity and specificity in therapeutics. However, clustered regularly interspaced short palindromic repeats (CRISPRs) is an innovative genome editing technology which has provided a significant therapeutic tool exhibiting high sensitivity, fast and precise investigation of distinct pathogens in an epidemic. CRISPR technology has also facilitated the understanding of the biology and therapeutic mechanism of cancer and several other hereditary diseases. Researchers have used the CRISPR technology as a theranostic approach for a wide range of diseases causing pathogens including distinct bacteria, viruses, fungi and parasites and genetic mutations as well. In this review article, besides various therapeutic applications of infectious and hereditary diseases we have also explained the structure and mechanism of CRISPR tools and role of CRISPR integrated biosensing technology in provoking diagnostic applications.

Polymorphism of Type I-F CRISPR/Cas system in Escherichia coli of phylogenetic group B2 and its application in genotyping

E. coli of phylogenetic group B2 is responsible for many extraintestinal infections, posing a great threat to health. The relatively polymorphic nature of CRISPR in phylogenetically related E. coli strains makes them potential markers for bacterial typing and evolutionary studies. In the current work, we investigated the occurrence and diversity of CRISPR/Cas system and explored its potential for genotyping. Type I-F CRISPR/Cas systems were found in 413 of 1190 strains of E. coli and exhibited the clustering within certain CCs and STs. And CRISPR spacer contents correlated well with MLST types. The divergence analysis of CRISPR showed stronger discriminatory power than MLST, and CRISPR polymorphism was instrumental for differentiating highly closely related strains. The timeline of spacer acquisition and deletion provided important information for inferring the evolution model between distinct serotypes. Identical spacer sequences were shared by strains with the same H-antigen type but not strains with the same O-antigen type. The homology between spacers and antibiotic-resistant plasmids demonstrated the role of Type I-F system in limiting the acquisition of antimicrobial resistance. Collectively, our data presents the dynamic nature of Type I-F CRISPR in E. coli of phylogenetic group B2 and provides new insights into the application of CRISPR-based typing in the species.

COMPARATIVE ANALYSIS OF CRISPR-CAS SYSTEM STRUCTURES OF YERSINIA PSEUDOTUBERCULOSIS IP32953 AND IP31758

Background. Pseudotuberculosis is still relevant problem in medical science and public health of Russia and other countries. Typing of Y. рseudotuberculosis strains by their CRISPR systems is a perspective tool for monitoring of Yersinia populations as was shown in Y. pestis.

Aims. Here we describe and compare CRISPR-Cas systems of Yersinia pseudotuberculosis strains IP32953 and IP31758 causing classic pseudotuberculosis and Far-East scarlet-like fever (FESLF) respectively.

Materials and methods. Complete genomes of Y. pseudotuberculosis IP329353 and IP31758 (NC_006155 and NC_009708 respectively) were obtained from NCBI Nucleotide Database. Search; identification; and analysis of CRISPR systems were carried out by online-tools CRISPROne; CRISPRDetect; and CRISPRTarget.

Results and discussion. Analyzed strains have CRISPR-Cas systems that include one set of cas-genes and arrays situated at the long distances from each other. We defined three CRISPR arrays in Y. pseudotuberculosis IP32953 by the combination of program methods. CRISPR-Cas system of this strain consist of array YP1 located near cas-genes; arrays YP2 and YP3. CRISPR-Cas system of Y. pseudotuberculosis IP31758 includes two arrays – YP1 and YP3. CRISPR systems do not share similar spacers. CRISPR systems of the analyzed strains differ in CRISPR loci and cas-protein structures that can be used as specific marks of analyzed strains.

Conclusions. We suggest that acquisition of certain spacers may play a role in evolution and divergence of Y. pseudotuberculosis strains.

The CRISPR-Cas system in Enterobacteriaceae

In nature, microorganisms are constantly exposed to multiple viral infections and thus have developed many strategies to survive phage attack and invasion by foreign DNA. One of such strategies is the clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated proteins (Cas) bacterial immunological system. This defense mechanism is widespread in prokaryotes including several families such as Enterobacteriaceae. Much knowledge about the CRISPR-Cas system has been generated, including its biological functions, transcriptional regulation, distribution, utility as a molecular marker and as a tool for specific genome editing. This review focuses on these aspects and describes the state of the art of the CRISPR-Cas system in the Enterobacteriaceae bacterial family.

Characterization and Exploitation of CRISPR Loci in Bifidobacterium longum

Diverse CRISPR-Cas systems provide adaptive immunity in many bacteria and most archaea, via a DNA-encoded, RNA-mediated, nucleic-acid targeting mechanism. Over time, CRISPR loci expand via iterative uptake of invasive DNA sequences into the CRISPR array during the adaptation process. These genetic vaccination cards thus provide insights into the exposure of strains to phages and plasmids in space and time, revealing the historical predatory exposure of a strain. These genetic loci thus constitute a unique basis for genotyping of strains, with potential of resolution at the strain-level. Here, we investigate the occurrence and diversity of CRISPR-Cas systems in the genomes of various Bifidobacterium longum strains across three sub-species. Specifically, we analyzed the genomic content of 66 genomes belonging to B. longum subsp. longum, B. longum subsp. infantis and B. longum subsp. suis, and identified 25 strains that carry 29 total CRISPR-Cas systems. We identify various Type I and Type II CRISPR-Cas systems that are widespread in this species, notably I-C, I-E, and II-C. Noteworthy, Type I-C systems showed extended CRISPR arrays, with extensive spacer diversity. We show how these hypervariable loci can be used to gain insights into strain origin, evolution and phylogeny, and can provide discriminatory sequences to distinguish even clonal isolates. By investigating CRISPR spacer sequences, we reveal their origin and implicate phages and prophages as drivers of CRISPR immunity expansion in this species, with redundant targeting of select prophages. Analysis of CRISPR spacer origin also revealed novel PAM sequences. Our results suggest that CRISPR-Cas immune systems are instrumental in mounting diversified viral resistance in B. longum, and show that these sequences are useful for typing across three subspecies.

Phylogeographic separation and formation of sexually discrete lineages in a global population of Yersinia pseudotuberculosis

Yersinia pseudotuberculosis is a Gram-negative intestinal pathogen of humans and has been responsible for several nationwide gastrointestinal outbreaks. Large-scale population genomic studies have been performed on the other human pathogenic species of the genus Yersinia, Yersinia pestis and Yersinia enterocolitica allowing a high-resolution understanding of the ecology, evolution and dissemination of these pathogens. However, to date no purpose-designed large-scale global population genomic analysis of Y. pseudotuberculosis has been performed. Here we present analyses of the genomes of 134 strains of Y. pseudotuberculosis isolated from around the world, from multiple ecosystems since the 1960s. Our data display a phylogeographic split within the population, with an Asian ancestry and subsequent dispersal of successful clonal lineages into Europe and the rest of the world. These lineages can be differentiated by CRISPR cluster arrays, and we show that the lineages are limited with respect to inter-lineage genetic exchange. This restriction of genetic exchange maintains the discrete lineage structure in the population despite co-existence of lineages for thousands of years in multiple countries. Our data highlights how CRISPR can be informative of the evolutionary trajectory of bacterial lineages, and merits further study across bacteria.

[An history of the CRISPR-Cas systems discovery]

From 1987 and during the following 20 years, a few research teams exploring bacteria and archea genome sequences uncover the prokaryotic adaptative immune system made of the CRISPR sequence and associated cas genes. First believed to be similar to the eukaryote RNA interference system, CRISPR-Cas turned out to be unique and of an amazing genetic complexity. The comparative studies of CRISPR arrays and of cas, and later of microbiotes metagenomes allowed to propose an evolution scenario for these systems. The results demonstrate the importance of a naturalistic approach, without a priori, for the understanding of living organisms.

Whole genome analysis of Yersinia ruckeri isolated over 27 years in Australia and New Zealand reveals geographical endemism over multiple lineages and recent evolution under host selection

Yersinia ruckeri is a salmonid pathogen with widespread distribution in cool-temperate waters including Australia and New Zealand, two isolated environments with recently developed salmonid farming industries. Phylogenetic comparison of 58 isolates from Australia, New Zealand, USA, Chile, Finland and China based on non-recombinant core genome SNPs revealed multiple deep-branching lineages, with a most recent common ancestor estimated at 18 500 years BP (12 355–24 757 95% HPD) and evidence of Australasian endemism. Evolution within the Tasmanian Atlantic salmon serotype O1b lineage has been slow, with 63 SNPs describing the variance over 27 years. Isolates from the prevailing lineage are poorly/non-motile compared to a lineage pre-vaccination, introduced in 1997, which is highly motile but has not been isolated since from epizootics. A non-motile phenotype has arisen independently in Tasmania compared to Europe and USA through a frameshift in fliI, encoding the ATPase of the flagella cluster. We report for the first time lipopolysaccharide O-antigen serotype O2 isolates in Tasmania. This phenotype results from deletion of the O-antigen cluster and consequent loss of high-molecular-weight O-antigen. This phenomenon has occurred independently on three occasions on three continents (Australasia, North America and Asia) as O2 isolates from the USA, China and Tasmania share the O-antigen deletion but occupy distant lineages. Despite the European and North American origins of the Australasian salmonid stocks, the lineages of Y. ruckeri in Australia and New Zealand are distinct from those of the northern hemisphere, suggesting they are pre-existing ancient strains that have emerged and evolved with the introduction of susceptible hosts following European colonization.

Bacteriophages of Yersinia pestis

Bacteriophage play many varied roles in microbial ecology and evolution. This chapter collates a vast body of knowledge and expertise on Yersinia pestis phages, including the history of their isolation and classical methods for their isolation and identification. The genomic diversity of Y. pestis phage and bacteriophage islands in the Y. pestis genome are also discussed because all phage research represents a branch of genetics. In addition, our knowledge of the receptors that are recognized by Y. pestis phage, advances in phage therapy for Y. pestis infections, the application of phage in the detection of Y. pestis, and clustered regularly interspaced short palindromic repeats (CRISPRs) sequences of Y. pestis from prophage DNA are all reviewed here.

Diverse Genotypes of Yersinia pestis Caused Plague in Madagascar in 2007

BACKGROUND

Yersinia pestis is the causative agent of human plague and is endemic in various African, Asian and American countries. In Madagascar, the disease represents a significant public health problem with hundreds of human cases a year. Unfortunately, poor infrastructure makes outbreak investigations challenging.

METHODOLOGY/PRINCIPAL FINDINGS

DNA was extracted directly from 93 clinical samples from patients with a clinical diagnosis of plague in Madagascar in 2007. The extracted DNAs were then genotyped using three molecular genotyping methods, including, single nucleotide polymorphism (SNP) typing, multi-locus variable-number tandem repeat analysis (MLVA), and Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) analysis. These methods provided increasing resolution, respectively. The results of these analyses revealed that, in 2007, ten molecular groups, two newly described here and eight previously identified, were responsible for causing human plague in geographically distinct areas of Madagascar.

CONCLUSIONS/SIGNIFICANCE

Plague in Madagascar is caused by numerous distinct types of Y. pestis. Genotyping method choice should be based upon the discriminatory power needed, expense, and available data for any desired comparisons. We conclude that genotyping should be a standard tool used in epidemiological investigations of plague outbreaks.