CRISPR/Cpf1-Mediated Multiplex and Large-Fragment Gene Editing in Staphylococcus aureus

Bioactive Specialized Metabolites from Staphylococcus: Diversity, Biosynthesis, and Biotechnological Potential

Staphylococci are a heterogeneous group of bacteria capable of colonizing diverse ecological niches and adopting a wide variety of lifestyles. While several strains are known as notorious, multidrug-resistant human pathogens, others are harmless inhabitants of soil, water, and food products, or beneficial members of the skin microbiota. To survive and remain competitive under challenging environmental conditions, staphylococci have evolved the ability to assemble and secrete a diverse range of ribosomally synthesized and posttranslationally modified peptides, nonribosomal peptides, terpenes, siderophores, and other specialized metabolites with antibiotic, immunomodulating and metal chelating activities. In this review, an overview of the bioactive metabolite arsenal of staphylococci is provided with a focus on their biosynthetic pathway, mode of action, and industrial application potential. Also, unexplored natural product biosynthetic pathways in staphylococci, along with strategies to access this hidden potential, are highlighted.

Implementation of RAGATH RNA-associated DNA Endonucleases as Genome Editing Tool in Escherichia coli

The preferred method for Escherichia coli genome editing relies on Cas9 from Streptococcus pyogenes (SpCas9) and λ-Red recombinase. Although SpCas9 is currently the most active RNA-guided DNA endonuclease, a significant number of escapers are often observed, making it inefficient across different sites, particularly when inserting large fragments. In this study, we identified two RAGATH RNA-associated DNA endonucleases (RADs) derived from IS607 transposons. Both of them exhibited high cleavage activity in E. coli. When combined with λ-Red recombinase, they achieved editing efficiencies approaching 100%. Even at target sites where SpCas9 exhibited low editing efficiency, RADs maintained efficiencies ranging from 57% to 94%. Moreover, RADs exhibited higher efficiencies in inserting large fragments in certain cases compared to SpCas9. Taken together, these RAD-based genome editing tools provide viable alternatives to SpCas9, particularly for challenging targets and/or large fragment insertions.

Multi-gene precision editing tool using CRISPR-Cas12a/Cpf1 system in Ogataea polymorpha

BACKGROUND

Ogataea polymorpha, a non-conventional methylotrophic yeast, has demonstrated significant potential for heterologous protein expression and the production of high-value chemicals and biopharmaceuticals. However, the lack of precise and efficient genome editing tools severely hinders the construction of cell factories. Although the CARISP-Cas9 system has been established in Ogataea polymorpha, the gene editing efficiency, especially for multiple genes edition, needs to be further improved.

RESULTS

In this study, we developed an efficient CRISPR-Cpf1-mediated genome editing system in O. polymorpha that exhibited high editing efficiency for single gene (98.1 ± 1.7%), duplex genes (93.9 ± 2.4%), and triplex genes (94.0 ± 6.0%). Additionally, by knocking out non-homologous end joining (NHEJ) related genes, homologous recombination (HR) efficiency was increased from less than 30% to 90 ~ 100%, significantly enhancing precise genome editing capabilities. The increased HR rates enabled over 90% integration efficiency of triplex genes, as well as over 90% deletion rates of large DNA fragments up to 20 kb. Furthermore, using this developed CRISPR-Cpf1 system, triple genes were precisely integrated into the genome by one-step, enabling lycopene production in O. polymorpha.

CONCLUSIONS

This novel multiplexed genome-editing tool mediated by CRISPR-Cpf1 can realize the deletion and integration of multiple genes, which holds great promise for accelerating engineering efforts on this non-conventional methylotrophic yeast for metabolic engineering and genomic evolution towards its application as an industrial cell factory.

CRISPR-Cas9-Mediated Targeting of Multidrug Resistance Genes in Methicillin-Resistant Staphylococcus aureus

Antibiotic resistance poses a global health crisis limiting the efficacy of available therapeutic agents. We explored CRISPR-Cas-based antimicrobials to combat multidrug resistance in methicillin-resistant Staphylococcus aureus (MRSA), targeting methicillin (mecA), gentamicin (aacA), and ciprofloxacin (grlA, grlB) resistance genes. Engineered CRISPR plasmids with specific single-guide RNAs were electroporated into MRSA strains. Real-time polymerase chain reaction assessed gene expression changes, while antibiotic susceptibility tests (ASTs) evaluated resistance status. Results showed a 1.5-fold decrease in mecA, a 5.5-fold decrease in grlA, a 6-fold decrease in grlB, and a 4-fold decrease in aacA expression. ASTs demonstrated the reversal of resistance to beta-lactam, quinolone, and aminoglycoside antibiotics. Western blot analysis revealed a 70% decrease in penicillin-binding protein 2a expression. Sanger sequencing confirmed point mutations in the grlB and aacA genes. Our findings highlight the potential of CRISPR-Cas9 technology to restore antibiotic efficacy against multidrug-resistant pathogens.

Development of the CRISPR-Cas12a system for editing of Pseudomonas aeruginosa phages

Pseudomonas aeruginosa is a common opportunistic pathogen. The potential efficacy of phage therapy has attracted the attention of researchers, but efficient gene-editing tools are lacking, limiting the study of their biological properties. Here, we designed a type V CRISPR-Cas12a system for the gene editing of P. aeruginosa phages. We first evaluated the active cutting function of the CRISPR-Cas12a system in vitro and discovered that it had a higher gene-cutting efficiency than the type II CRISPR-Cas9 system in three different P. aeruginosa phages. We also demonstrated the system's ability to precisely edit genes in Escherichia coli phages, Salmonella phages, and P. aeruginosa phages. Using the aforementioned strategies, non-essential P. aeruginosa phage genes can be efficiently deleted, resulting in a reduction of up to 5,215 bp (7.05%). Our study has provided a rapid, efficient, and time-saving tool that accelerates progress in phage engineering.

From phyllosphere to insect cuticles: silkworms gather antifungal bacteria from mulberry leaves to battle fungal parasite attacks

BACKGROUND

Bacterial transfers from plants to insect herbivore guts have been well investigated. However, bacterial exchanges between plant phyllospheres and insect cuticles remain unclear, as does their related biological function.

RESULTS

Here, we report that the cuticular bacterial loads of silkworm larvae quickly increased after molting and feeding on the white mulberry (Morus alba) leaves. The isolation and examination of silkworm cuticular bacteria identified one bacterium Mammaliicoccus sciuri that could completely inhibit the spore germination of fungal entomopathogens Metarhizium robertsii and Beauveria bassiana. Interestingly, Ma. sciuri was evident originally from mulberry leaves, which could produce a secreted chitinolytic lysozyme (termed Msp1) to damage fungal cell walls. In consistency, the deletion of Msp1 substantially impaired bacterial antifungal activity. Pretreating silkworm larvae with Ma. sciuri cells followed by fungal topical infections revealed that this bacterium could help defend silkworms against fungal infections. Unsurprisingly, the protective efficacy of ΔMsp1 was considerably reduced when compared with that of wild-type bacterium. Administration of bacterium-treated diets had no negative effect on silkworm development; instead, bacterial supplementation could protect the artificial diet from Aspergillus contamination.

CONCLUSIONS

The results of this study evidence that the cross-kingdom transfer of bacteria from plant phyllospheres to insect herbivore cuticles can help protect insects against fungal parasite attacks. Video Abstract.

The Development of a CRISPR-FnCpf1 System for Large-Fragment Deletion and Multiplex Gene Editing in Acinetobacter baumannii

Acinetobacter baumannii is a low-GC-content Gram-negative opportunistic pathogen that poses a serious global public health threat. Convenient and rapid genetic manipulation is beneficial for elucidating its pathogenic mechanisms and developing novel therapeutic methods. In this study, we report a new CRISPR-FnCpf1-based two-plasmid system for versatile and precise genome editing in A. baumannii. After identification, this new system prefers to recognize the 5'-TTN-3' (N = A, T, C or G) and the 5'-CTV-3' (V = A, C or G) protospacer-adjacent motif (PAM) sequence and utilize the spacer with lengths ranging from 19 to 25 nt. In direct comparison with the existing CRISPR-Cas9 system, it exhibits approximately four times the targetable range in A. baumannii. Moreover, by employing a tandem dual crRNA expression cassette, the new system can perform large-fragment deletion and simultaneous multiple gene editing, which is difficult to achieve via CRISPR-Cas9. Therefore, the new system is valuable and can greatly expand the genome editing toolbox of A. baumannii.

CRISPR/Cas12a toolbox for genome editing in Methanosarcina acetivorans

Methanogenic archaea play an important role in the global carbon cycle and may serve as host organisms for the biotechnological production of fuels and chemicals from CO2 and other one-carbon substrates. Methanosarcina acetivorans is extensively studied as a model methanogen due to its large genome, versatile substrate range, and available genetic tools. Genome editing in M. acetivorans via CRISPR/Cas9 has also been demonstrated. Here, we describe a user-friendly CRISPR/Cas12a toolbox that recognizes T-rich (5'-TTTV) PAM sequences. The toolbox can manage deletions of 3,500 bp (i.e., knocking out the entire frhADGB operon) and heterologous gene insertions with positive rates of over 80%. Cas12a-mediated multiplex genome editing was used to edit two separate sites on the chromosome in one round of editing. Double deletions of 100 bp were achieved, with 8/8 of transformants being edited correctly. Simultaneous deletion of 100 bp at one site and replacement of 100 bp with the 2,400 bp uidA expression cassette at a separate site yielded 5/6 correctly edited transformants. Our CRISPR/Cas12a toolbox enables reliable genome editing, and it can be used in parallel with the previously reported Cas9-based system for the genetic engineering of the Methanosarcina species.

Efficient Genome Editing in Most Staphylococcus aureus by Using the Restriction-Modification System Silent CRISPR-Cas9 Toolkit

Staphylococcus aureus is a clinically important pathogen that threatens human health due to its strong pathogenicity and drug resistance, leading to meningitis, endocarditis, and skin and soft tissue infections. Genetic manipulation in S. aureus is a powerful approach for characterizing the molecular mechanisms of bacterial drug resistance, pathogenicity, and virulence. However, a strong restriction barrier presents a major obstacle to the extensive utilization of genetic manipulation tools in clinical isolates of S. aureus. Here, we constructed a restriction-modification (RM) system silent CRISPR-Cas9 toolkit that synonymously eliminated the type I RM targets of S. aureus from plasmids, downsized plasmids using minicircle technology, and combined with a plasmid artificial modification (PAM) method to circumvent the type II RM system. The RM-silent CRISPR-Cas9 toolkit enables a significant improvement in transformation (105-106 transformants per microgram plasmid in strains we tested) and high-success efficiency editing for gene deletion (knockout strain obtained in one-round electroporation) in a wide range of S. aureus species including clinical isolates of unknown genetic background. The RM-silent CRISPR-Cas9 toolkits could expedite the process of mutant construction in most S. aureus strains, and this approach could be applied to the design of other genetic toolkit plasmids for utilization in a wider range of S. aureus strains.