Protospacer-Adjacent Motif Specificity during Clostridioides difficile Type I-B CRISPR-Cas Interference and Adaptation.

CRISPR (clustered regularly interspaced short palindromic repeats)-Cas (CRISPR-associated) systems provide prokaryotes with efficient protection against foreign nucleic acid invaders. We have recently demonstrated the defensive interference function of a CRISPR-Cas system from Clostridioides (Clostridium) difficile, a major human enteropathogen, and showed that it could be harnessed for efficient genome editing in this bacterium. However, molecular details are still missing on CRISPR-Cas function for adaptation and sequence requirements for both interference and new spacer acquisition in this pathogen. Despite accumulating knowledge on the individual CRISPR-Cas systems in various prokaryotes, no data are available on the adaptation process in bacterial type I-B CRISPR-Cas systems. Here, we report the first experimental evidence that the C. difficile type I-B CRISPR-Cas system acquires new spacers upon overexpression of its adaptation module. The majority of new spacers are derived from a plasmid expressing Cas proteins required for adaptation or from regions of the C. difficile genome where generation of free DNA termini is expected. Results from protospacer-adjacent motif (PAM) library experiments and plasmid conjugation efficiency assays indicate that C. difficile CRISPR-Cas requires the YCN consensus PAM for efficient interference. We revealed a functional link between the adaptation and interference machineries, since newly adapted spacers are derived from sequences associated with a CCN PAM, which fits the interference consensus. The definition of functional PAMs and establishment of relative activity levels of each of the multiple C. difficile CRISPR arrays in present study are necessary for further CRISPR-based biotechnological and medical applications involving this organism. IMPORTANCE CRISPR-Cas systems provide prokaryotes with adaptive immunity for defense against foreign nucleic acid invaders, such as viruses or phages and plasmids. The CRISPR-Cas systems are highly diverse, and detailed studies of individual CRISPR-Cas subtypes are important for our understanding of various aspects of microbial adaptation strategies and for the potential applications. The significance of our work is in providing the first experimental evidence for type I-B CRISPR-Cas system adaptation in the emerging human enteropathogen Clostridioides difficile. This bacterium needs to survive in phage-rich gut communities, and its active CRISPR-Cas system might provide efficient antiphage defense by acquiring new spacers that constitute memory for further invader elimination. Our study also reveals a functional link between the adaptation and interference CRISPR machineries. The definition of all possible functional trinucleotide motifs upstream protospacers within foreign nucleic acid sequences is important for CRISPR-based genome editing in this pathogen and for developing new drugs against C. difficile infections.

PpCas9 from Pasteurella pneumotropica - a compact Type II-C Cas9 ortholog active in human cells.

CRISPR-Cas defense systems opened up the field of genome editing due to the ease with which effector Cas nucleases can be programmed with guide RNAs to access desirable genomic sites. Type II-A SpCas9 from Streptococcus pyogenes was the first Cas9 nuclease used for genome editing and it remains the most popular enzyme of its class. Nevertheless, SpCas9 has some drawbacks including a relatively large size and restriction to targets flanked by an 'NGG' PAM sequence. The more compact Type II-C Cas9 orthologs can help to overcome the size limitation of SpCas9. Yet, only a few Type II-C nucleases were fully characterized to date. Here, we characterized two Cas9 II-C orthologs, DfCas9 from Defluviimonas sp.20V17 and PpCas9 from Pasteurella pneumotropica. Both DfCas9 and PpCas9 cleave DNA in vitro and have novel PAM requirements. Unlike DfCas9, the PpCas9 nuclease is active in human cells. This small nuclease requires an 'NNNNRTT' PAM orthogonal to that of SpCas9 and thus potentially can broaden the range of Cas9 applications in biomedicine and biotechnology.

Position of Deltaproteobacteria Cas12e nuclease cleavage sites depends on spacer length of guide RNA.

Cas12e proteins (formerly CasX) form a distinct subtype of Class II type V CRISPR-Cas effectors. Recently, it was shown that DpbCas12e from Deltaproteobacteria and PlmCas12e from Planctomycetes can introduce programmable double-stranded breaks in mammalian genomes. Thus, along with Cas9 and Cas12a Class II effectors, Cas12e could be harnessed for genome editing and engineering. The location of cleavage points in DNA targets is important for application of Cas nucleases in biotechnology. DpbCas12e was reported to produce extensive 5'-overhangs at cleaved targets, which can make it superior for some applications. Here, we used high throughput sequencing to precisely map the DNA cut site positions of DpbCas12e on several DNA targets. In contrast to previous observations, our results demonstrate that DNA cleavage pattern of Cas12e is very similar to that of Cas12a: DpbCas12e predominantly cleaves DNA after nucleotide position 17-19 downstream of PAM in the non-target DNA strand, and after the 22nd position of target strand, producing 3-5 nucleotide-long 5'-overhangs. We also show that reduction of spacer sgRNA sequence from 20nt to 16nt shifts Cas12e cleavage positions on the non-target DNA strand closer to the PAM, producing longer 6-8nt 5'-overhangs. Overall, these findings advance the understanding of Cas12e endonucleases and may be useful for developing of DpbCas12e-based biotechnology instruments.

DNA targeting by Clostridium cellulolyticum CRISPR-Cas9 Type II-C system.

Type II CRISPR-Cas9 RNA-guided nucleases are widely used for genome engineering. Type II-A SpCas9 protein from Streptococcus pyogenes is the most investigated and highly used enzyme of its class. Nevertheless, it has some drawbacks, including a relatively big size, imperfect specificity and restriction to DNA targets flanked by an NGG PAM sequence. Cas9 orthologs from other bacterial species may provide a rich and largely untapped source of biochemical diversity, which can help to overcome the limitations of SpCas9. Here, we characterize CcCas9, a Type II-C CRISPR nuclease from Clostridium cellulolyticum H10. We show that CcCas9 is an active endonuclease of comparatively small size that recognizes a novel two-nucleotide PAM sequence. The CcCas9 can potentially broaden the existing scope of biotechnological applications of Cas9 nucleases and may be particularly advantageous for genome editing of C. cellulolyticum H10, a bacterium considered to be a promising biofuel producer.

Characterization of the Transmitted Virus in an Ongoing HIV-1 Epidemic Driven by Injecting Drug Use.

Understanding features of the HIV-1 transmission process has the potential to inform biological interventions for prevention. We have examined the transmitted virus in a cohort of people who inject drugs and who are at risk of HIV-1 infection through blood contamination when injecting in a group. This study focused on seven newly infected participants in St. Petersburg, Russia, who were in acute or early infection. We used end-point dilution polymerase chain reaction to amplify single viral genomes to assess the complexity of the transmitted virus. We also used deep sequencing to further assess the complexity of the virus. We interpret the results as indicating that a single viral variant was transmitted in each case, consistent with a model where the exposure to virus during transmission was limited. We also looked at phenotypic properties of the viral Env protein in isolates from acute and chronic infection. Although differences were noted, there was no consistent pattern that distinguished the transmitted variants. Similarly, despite the reduced genetic heterogeneity of the more recent subtype A HIV-1 epidemic in St. Petersburg, we did not see reduced variance in the neutralization properties compared to isolates from the more mature subtype C HIV-1 epidemic. Finally, in looking at members of injecting groups related to the acute HIV-1 infection/early subjects, we found examples of sequence linkage consistent with ongoing and rapid spread of HIV-1 in these groups. These studies emphasize the dynamic nature of this epidemic and reinforce the idea that improved prevention methods are needed.

Multilocus genotyping based species identification of entomopathogenic fungi of the genus Lecanicillium (=Verticillium lecanii s.l.).

Mitochondrial gene NADH dehydrogenase subunit 1 (nad1), ß-tubulin gene, and elongation factor 1-alpha (tef) were used to characterize and to identify 42 Lecanicillum spp. isolates (former complex species Verticillium lecanii Zimm. Viegas) and to study the phylogenetic relationships in this group. Within the isolates under investigation, Lecanicillium muscarium was the most common species (about 70% of all isolates, collected on the different hosts, predominantly on the insects from the order Hemiptera). Based on nad1 sequencing four main molecular haplotypes were revealed. All four haplotypes have Holarctic origin. Most of them were isolated in the Central part of Russia. One haplotype showed a specific association with the certain geographical area, limited to southwest Georgia and the Krasnodar Territory. For most strains their affiliation to species L. muscarium, L. longisporum, L. psalliotae, L. pissodes were confirmed by the phylogenetic tree, based on the combined sequences of nad1, ß-tub, and tef genes. Only five strains of haplotype C and strain F-2643 could not be identified to any present Lecanicillium species and their position remains ambiguous. Thus, the use of multilocus molecular approach based on these genes was useful to identify the Lecanicillium species. Inter-simple sequence repeat (ISSR) study evaluated a high diversity among the L. muscarium strains. The topology of the NJ-tree based on the ISSR-PCR markers has shown the genetic relationships with the support values 62-91% between L. muscarium isolates.