Application of CRISPR/Cas9 System for Plasmid Elimination and Bacterial Killing of Bacillus cereus Group Strains

The CRISPR-Cas system has been widely applied in prokaryotic genome editing with its high efficiency and easy operation. We constructed some “scissors plasmids” via using the temperature-sensitive pJOE8999 shuttle plasmid, which carry the different 20nt (N20) guiding the Cas9 nuclease as a scissors to break the target DNA. We successfully used scissors plasmids to eliminate native plasmids from Bacillus anthracis and Bacillus cereus, and specifically killed B. anthracis. When curing pXO1 and pXO2 virulence plasmids from B. anthracis A16PI2 and A16Q1, respectively, we found that the plasmid elimination percentage was slightly higher when the sgRNA targeted the replication initiation region (96–100%), rather than the non-replication initiation region (88–92%). We also tried using a mixture of two scissors plasmids to simultaneously eliminate pXO1 and pXO2 plasmids from B. anthracis, and the single and double plasmid-cured rates were 29 and 14%, respectively. To our surprise, when we used the scissor plasmid containing two tandem sgRNAs to cure the target plasmids pXO1 and pXO2 from wild strain B. anthracis A16 simultaneously, only the second sgRNA could guide Cas9 to cleave the target plasmid with high efficiency, while the first sgRNA didn't work in all the experiments we designed. When we used the CRISPR/cas9 system to eliminate the pCE1 mega-virulence plasmid from B. cereus BC307 by simply changing the sgRNA, we also obtained a plasmid-cured isogenic strain at a very high elimination rate (69%). The sterilization efficiency of B. anthracis was about 93%, which is similar to the efficiency of plasmid curing, and there was no significant difference in the efficiency of among the scissors plasmids containing single sgRNA, targeting multi-sites, or single-site targeting and the two tandem sgRNA. This simple and effective curing method, which is applicable to B. cereus group strains, provides a new way to study these bacteria and their virulence profiles.

Population genomics of Salmonella enterica serovar Weltevreden ST365, an emerging predominant causative agent of diarrheal disease

Salmonella enterica serovar Weltevreden is a recently emerged pathogen, and as such we lack a comprehensive knowledge of its microbiology, genomics, epidemiology and biogeography. In this study, we analyzed 174 novel S. Weltevreden isolates including 111 isolates recovered from diarrheal patients in China between 2006 and 2017. Our results demonstrate that the ST365 clone was the predominant causative agent of the diarrhea-outbreak during this period, as vast majority of the isolates recovered from diarrheal patients belonged to this sequence type (97.37%, 74/76). We also determined the ST365 clone as the predominant sequence type of S. Weltevreden from diarrheal patients globally from previously published sequences (97.51%, 196/201). In order to determine the possible antimicrobial genes and virulence factors associated with S. Weltevreden, we performed whole genome sequencing on our novel isolates. We were able to identify a range of key virulence factors associated with S. Weltevreden that are likely to be beneficial to their fitness and pathogenesis. Furthermore, we were able to isolate a novel 100.03-kb IncFII(S) type virulence plasmid that used the same replicon as pSPCV virulence plasmid. Importantly, we demonstrated through plasmid elimination a functional role for this plasmid in bacterial virulence. These findings are critical to further our knowledge of this high consequence pathogen.

A modified pCas/pTargetF system for CRISPR-Cas9-assisted genome editing in Escherichia coli

The clustered regularly interspaced short palindromic repeats (CRISPR)-associated nuclease 9 (Cas9)-based genome editing tool pCas/pTargetF system that we established previously has been widely used in Escherichia coli MG1655. However, this system failed to manipulate the genome of E. coli BL21(DE3), owing to the potential higher leaky transcription of the gRNA-pMB1 specific to pTargetF in this strain. In this study, we modified the pCas/pTargetF system by replacing the promoter of gRNA-pMB1 with a tightly regulated promoter PrhaB, changing the replicon of pCas to a nontemperature-sensitive replicon, adding the sacB gene into pCas, and replacing the original N20-specific sequence of pTargetF with ccdB gene. We call this updated system as pEcCas/pEcgRNA. We found that gRNA-pMB1 indeed showed a slightly higher leaky expression in the pCas/pTargetF system compared with pEcCas/pEcgRNA. We also confirmed that genome editing can successfully be performed in BL21(DE3) by pEcCas/pEcgRNA with high efficiency. The application of pEcCas/pEcgRNA was then expanded to the E. coli B strain BL21 StarTM (DE3), K-12 strains MG1655, DH5α, CGMCC3705, Nissle1917, W strain ATCC9637, and also another species of Enterobacteriaceae, Tatumella citrea DSM13699, without any specific modifications. Finally, the plasmid curing process was optimized to shorten the time from $\sim$60 h to $\sim$32 h. The entire protocol (including plasmid construction, editing, electroporation and mutant verification, and plasmid elimination) took only $\sim$5.5 days per round in the pEcCas/pEcgRNA system, whereas it took $\sim$7.5 days in the pCas/pTargetF system. This study established a faster-acting genome editing tool that can be used in a wider range of E. coli strains and will also be useful for other Enterobacteriaceae species.

Exploring the pathogenic function of an endogenous plasmid of Pantoea ananatis by a simple and efficient plasmid elimination strategy

Background: The bacterium Pantoea ananatis is associated with devastating diseases in many crops that cause serious economic losses. We previously isolated strain DZ-12 from maize brown rot leaves and, genome sequencing revealed that it belongs to P. ananatis and contains a large, endogenous plasmid, pDZ-12. Virulence plasmids are essential for pathogenesis in many bacterial pathogens. However, nothing was known regarding the role of this plasmid in P. ananatis pathogenicity in maize. Results: Here, we eliminated the endogenous plasmid from P. ananatis by substituting its native replicon with a temperature-sensitive replicon. The resulting temperature-sensitive plasmid could be cured by growing cells at high temperature (37 °C). Loss of pDZ-12 from P. ananatis DZ-12 led to decreased disease severity in maize plants, suggesting the endogenous plasmid was important for pathogenesis. Meanwhile, loss of pDZ-12 also affected the ability of the bacterium to form biofilms. The method described here, which is efficient and needs only two steps to cure the endogenous plasmid without antibiotic resistance, was also shown to work in Bacillus subtilis, and may be generally applicable in bacteria. Conclusions: This study provides the first evidence that the endogenous plasmid of P. ananatis DZ-12 is important for pathogenesis in maize plants and in the ability of this species to form biofilms. It also presents the first report on curing plasmid DNA from P. ananatis.

Loss of mcr Genes Mediated by Plasmid Elimination and ISApl1

ABSTRACT We characterized the stability of a plasmid pCP53-mcr1_3 encoding mcr-1 and mcr-3.19 with and without colistin exposure during cultural passages via S1-pulsed-field gel electrophoresis (PFGE) and nanopore MinION sequencing. Both mcr-1 and mcr-3.19 were missing in certain subclones, mediated by genetic excision (ISApl1-mcr-1-pap2), and deletions of large multidrug resistance (MDR) regions confirmed by ISApl1 and plasmid elimination. Without colistin exposure, the eradication of mcr genes is feasible, while the factors influencing the elimination processes warrant further study.

A genetic study of a Staphylococus aureus plasmid involving cure and transference

High frequency transfer and elimination of drug resistance may indicate an extrachromosomal inheritance of genetic determinants. This study shows the cure and transfer of a small plasmid and tetracycline resistance in Staphylococcus aureus 1030 (55)TetR strains. Several methods are available for plasmid elimination. We used ethidium bromide, an agent that binds to DNA, and thus inhibits DNA polymerase. This caused a high frequency of loss of the small plasmid and resistance to tetracycline. Transfer of tetracycline resistance was done in a mixed culture at a frequency of 10-6. This type of study is very important to physicians and epidemiology investigators and provides better knowledge on antibiotic-resistance mechanisms that may occur in vivo in a hospital environment.