Host range expansion of Acinetobacter phage vB_Ab4_Hep4 driven by a spontaneous tail tubular mutation

He, Penggang; Cao, Feng; Qu, Qianyu; Geng, Huaixin; Yang, Xin; Xu, Tong; Wang, Rui; Jia, Xu; Lu, Mao; Zeng, Peibin; Luan, Guangxin

doi:10.3389/fcimb.2024.1301089

Cited by 2 publications

(1 citation statement)

References 55 publications

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“…An arbitrary 20% intergenomic similarity threshold was applied to all Acinetobacter phages except representatives of the family Schitoviridae, resulting in 27 clusters numbered conditionally according to phage morphology (first podovirus, then myovirus and siphovirus morphology), phage lifestyle (first lytic, then temperate phages), and alphabetical order of the names of taxonomic groups (Table 1). [53], Ab124 [54], AB_SZ6 [55], Abgy2021-6-2, AbKT21phiIII [56] ***, Abp1 [57], ABp57, AbpL, AbTP3phi1 [32], Acba_6 [58], AIIMS-AbE5-RC ***, APK09 [34], APK15, APK16 [34], APK20, APK37.1 [34], APK77, APK86 [34], APK127v [34], Aristophanes [30], BM12, F70-K44, fBenAci001 [59], fBenAci002 [59], fBenAci003 [59], Fri1 [25], IME-200 [60], MRABP9, Paty, pB3074 [61], Petty [62,63], phiAB1 [57], phiAB6 [27], Pipo, SH-Ab 15519 [64], SWH-Ab-1, SWH-Ab-3, vB_Ab4_Hep4 [65], vB_Ab4_Hep4-M [65], vB_AbaP_46-62_Aci07 [66], vB_AbaP_100, vB_AbaP_ABWU2101 [67], vB_AbaP_Acibel007 [68], vB_AbaP_AGC01 [69], vB_AbaP_APK2 [26], vB_AbaP_APK2-2, vB_AbaP_APK14 [34], vB_AbaP_APK26 [70], vB_AbaP_APK32 [31], vB_AbaP_APK37 [31], vB_AbaP_APK44 [31], vB_AbaP_APK48 [31], vB_AbaP_APK48-3, vB_AbaP_APK81, vB_AbaP_APK87 [31], vB_AbaP_APK89…”

Section: Cluster and Phylogenetic Analyses Of Acinetobacter Phagesmentioning

confidence: 99%

Lytic Capsule-Specific Acinetobacter Bacteriophages Encoding Polysaccharide-Degrading Enzymes

Evseev,

Sukhova,

Tkachenko

et al. 2024

Viruses

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The genus Acinetobacter comprises both environmental and clinically relevant species associated with hospital-acquired infections. Among them, Acinetobacter baumannii is a critical priority bacterial pathogen, for which the research and development of new strategies for antimicrobial treatment are urgently needed. Acinetobacter spp. produce a variety of structurally diverse capsular polysaccharides (CPSs), which surround the bacterial cells with a thick protective layer. These surface structures are primary receptors for capsule-specific bacteriophages, that is, phages carrying tailspikes with CPS-depolymerizing/modifying activities. Phage tailspike proteins (TSPs) exhibit hydrolase, lyase, or esterase activities toward the corresponding CPSs of a certain structure. In this study, the data on all lytic capsule-specific phages infecting Acinetobacter spp. with genomes deposited in the NCBI GenBank database by January 2024 were summarized. Among the 149 identified TSPs encoded in the genomes of 143 phages, the capsular specificity (K specificity) of 46 proteins has been experimentally determined or predicted previously. The specificity of 63 TSPs toward CPSs, produced by various Acinetobacter K types, was predicted in this study using a bioinformatic analysis. A comprehensive phylogenetic analysis confirmed the prediction and revealed the possibility of the genetic exchange of gene regions corresponding to the CPS-recognizing/degrading parts of different TSPs between morphologically and taxonomically distant groups of capsule-specific Acinetobacter phages.

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Section: Cluster and Phylogenetic Analyses Of Acinetobacter Phagesmentioning

confidence: 99%

Lytic Capsule-Specific Acinetobacter Bacteriophages Encoding Polysaccharide-Degrading Enzymes

Evseev,

Sukhova,

Tkachenko

et al. 2024

Viruses

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Synergistic Antimicrobial Effects of Phage vB_AbaSi_W9 and Antibiotics against Acinetobacter baumannii Infection

Choi,

Kim,

Shin

et al. 2024

Antibiotics

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Acinetobacter baumannii is a challenging multidrug-resistant pathogen in healthcare. Phage vB_AbaSi_W9 (GenBank: PP146379.1), identified in our previous study, shows lytic activity against 26 (89.66%) of 29 carbapenem-resistant Acinetobacter baumannii (CRAB) strains with various sequence types (STs). It is a promising candidate for CRAB treatment; however, its lytic efficiency is insufficient for complete bacterial lysis. Therefore, this study aimed to investigate the clinical utility of the phage vB_AbaSi_W9 by identifying antimicrobial agents that show synergistic effects when combined with it. The A. baumannii ATCC17978 strain was used as the host for the phage vB_AbaSi_W9. Adsorption and one-step growth assays of the phage vB_AbaSi_W9 were performed at MOIs of 0.001 and 0.01, respectively. Four clinical strains of CRAB belonging to different sequence types, KBN10P04948 (ST191), LIS2013230 (ST208), KBN10P05982 (ST369), and KBN10P05231 (ST451), were used to investigate phage–antibiotic synergy. Five antibiotics were tested at the following concentration: meropenem (0.25–512 µg/mL); colistin, tigecycline, and rifampicin (0.25–256 µg/mL); and ampicillin/sulbactam (0.25/0.125–512/256 µg/mL). The in vitro synergistic effect of the phage and rifampicin was verified through an in vivo mouse infection model. Phage vB_AbaSi_W9 demonstrated 90% adsorption to host cells in 1 min, a 20 min latent period, and a burst size of 114 PFU/cell. Experiments combining phage vB_AbaSi_W9 with antibiotics demonstrated a pronounced synergistic effect against clinical strains when used with tigecycline and rifampicin. In a mouse model infected with CRAB KBN10P04948 (ST191), the group treated with rifampicin (100 μg/mL) and phage vB_AbaSi_W9 (MOI 1) achieved a 100% survival rate—a significant improvement over the phage-only treatment (8.3% survival rate) or antibiotic-only treatment (25% survival rate) groups. The bacteriophage vB_AbaSi_W9 demonstrated excellent synergy against CRAB strains when combined with tigecycline and rifampicin, suggesting potential candidates for phage–antibiotic combination therapy in treating CRAB infections.

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Host range expansion of Acinetobacter phage vB_Ab4_Hep4 driven by a spontaneous tail tubular mutation

Cited by 2 publications

References 55 publications

Lytic Capsule-Specific Acinetobacter Bacteriophages Encoding Polysaccharide-Degrading Enzymes

Lytic Capsule-Specific Acinetobacter Bacteriophages Encoding Polysaccharide-Degrading Enzymes

Synergistic Antimicrobial Effects of Phage vB_AbaSi_W9 and Antibiotics against Acinetobacter baumannii Infection

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