ヴィーラナラヤナン スリワニ

Abstract Phage therapy has emerged as a promising alternative to conventional antimicrobial therapy for antimicrobial-resistant bacterial infections, but concerns about uncontrolled phage proliferation have limited its use. To address this issue, we established a nonproliferative phage-based DNA delivery system, called bacteria-targeting capsid particle (B-CAP), for the development of antimicrobial agents which effectively prevented phage spread while maintaining bactericidal activity. B-CAP is principally a T7 phage capsids packaged with a partial T7 phage genome, giving it the allowance to accommodate large foreign DNA up to 18 kb in length. We confirmed the efficacy of B-CAP in targeting and injecting its genome into bacteria, analogous to the wild-type phage. To demonstrate proof-of-concept and potential for developing an antimicrobial agent, we loaded colicin E1 operon onto the B-CAP system, resulting in the construction of B-CAP_ColE1, an antimicrobial agent capable of boosting colicin E1-based bacterial killing against Escherichia coli. Although no therapeutic effect was observed for B-CAP, B-CAP_ColE1 exhibited strong bactericidal activity against carbapenem-resistant E. coli both in vitro and in vivo, and significantly improved the survival of mice in an infection mouse model experiment. Finally, B-CAP_ColE1 is biologically contained or inert, reducing potential biological hazards during therapeutic use. Our results demonstrate that the B-CAP system offers a new strategy for developing nonreplicative phage-based antimicrobial agents against bacterial infections.

In response to the escalating antibiotic resistance in multidrug-resistant pathogens, we propose an innovative phagemid-based capsid system to generate CRISPR-Cas13a-loaded antibacterial capsids (AB-capsids) for targeted therapy against multidrug-resistant Staphylococcus aureus. Our optimized phagemid system maximizes AB-capsid yield and purity, showing a positive correlation with phagemid copy number. Notably, an 8.65-fold increase in copy number results in a 2.54-fold rise in AB-capsid generation. Phagemids carrying terL-terS-rinA-rinB (prophage-encoded packaging site genes) consistently exhibit high packaging efficiency, and the generation of AB-capsids using lysogenized hosts with terL-terS deletion resulted in comparatively lower level of wild-type phage contamination, with minimal compromise on AB-capsid yield. These generated AB-capsids selectively eliminate S. aureus strains carrying the target gene while sparing non-target strains. In conclusion, our phagemid-based capsid system stands as a promising avenue for developing sequence-specific bactericidal agents, offering a streamlined approach to combat antibiotic-resistant pathogens within the constraints of efficient production and targeted efficacy.

Phage therapy, the use of bacteriophages (phages) to treat bacterial infections, is regaining momentum as a promising weapon against the rising threat of multidrug-resistant (MDR) bacteria. This comprehensive review explores the historical context, the modern resurgence of phage therapy, and phage-facilitated advancements in medical and technological fields. It details the mechanisms of action and applications of phages in treating MDR bacterial infections, particularly those associated with biofilms and intracellular pathogens. The review further highlights innovative uses of phages in vaccine development, cancer therapy, and as gene delivery vectors. Despite its targeted and efficient approach, phage therapy faces challenges related to phage stability, immune response, and regulatory approval. By examining these areas in detail, this review underscores the immense potential and remaining hurdles in integrating phage-based therapies into modern medical practices.

In response to the escalating global threat of antimicrobial resistance, our laboratory has established a phagemid packaging system for the generation of CRISPR-Cas13a-antimicrobial capsids targeting methicillin-resistant Staphylococcus aureus (MRSA). However, a significant challenge arose during the packaging process: the unintentional production of wild-type phages alongside the antimicrobial capsids. To address this issue, the phagemid packaging system was optimized by strategically incorporated silent mutations. This approach effectively minimized contamination risks without compromising packaging efficiency. The study identified the indispensable role of phage packaging genes, particularly terL-terS, in efficient phagemid packaging. Additionally, the elimination of homologous sequences between the phagemid and wild-type phage genome was crucial in preventing wild-type phage contamination. The optimized phagemid-LSAB(mosaic) demonstrated sequence-specific killing, efficiently eliminating MRSA strains carrying target antibiotic-resistant genes. While acknowledging the need for further exploration across bacterial species and in vivo validation, this refined phagemid packaging system offers a valuable advancement in the development of CRISPR-Cas13a-based antimicrobials, shedding light on potential solutions in the ongoing battle against bacterial infections.