Isolation and complete genome sequence of Aeromonas bacteriophage Gekk3-15.

Bacteria of the genus Aeromonas, especially A. hydrophila and A. veronii are recognized as important fish pathogens that cause significant economic losses in aquaculture. Environmentally friendly bacteriophage-based solutions for the treatment of fish and for the reduction of colonization by pathogenic bacteria in production facilities are currently in high demand. The bacteriophage Gekk3-15 was isolated during a search for novel phage strains potentially suitable for Aeromonas biocontrol applications. Genome sequencing revealed that this virus is a relatively small myovirus with a 64847 bp long dsDNA genome, which is consistent with virion electron microscopy data. Bacteriophage Gekk3-15 is distinct in its nucleotide and encoded aa sequences from all other sequenced bacteriophage genomes, and may represent a new viral taxon at the genus or subfamily level.

Genome sequence data of Caudoviricetes bacteriophage MK21 infecting Xanthomonas citri, the causative agent of citrus canker.

This dataset reports the isolation and genomic characterization of the Caudoviricetes bacteriophage MK21, a novel bacteriophage infecting Xanthomonas citri subsp. citri (XCC), collected from soil samples on Jeju Island, South Korea. The phage was isolated and enriched using double agar layer plaque assays on nutrient media. Genomic analysis revealed that the phage MK21 is a double-stranded circular DNA genome of 43,495 bp, comprising 61 genes with high coding density. The dataset includes detailed genomic information, highlighting genes related to structural components, lysis mechanisms, and DNA/RNA metabolism. Phylogenetic analysis shows a close relationship with Xanthomonas phage CP1, supporting its potential use in comparative genomic studies and the development of antibacterial agents against citrus canker. This dataset offers valuable insights for the advancement of phage therapy and sustainable agricultural practices.

Bacteriophage as a potential biotherapeutics to combat present-day crisis of multi-drug resistant pathogens.

The rise of Multi-Drug Resistant (MDR) bacterial pathogens to most, if not all, currently available antibacterial agents has become a global threat. As a consequence of the antibiotic resistance epidemic, phage therapy has emerged as a potential alternative to conventional antibiotics. Despite the high therapeutic advantages of phage therapy, they have not yet been successfully used in the clinic due to various limitations of narrow host specificity compared to antibiotics, poor adhesion on biofilm surface, and susceptibility to both human and bacterial defences. This review focuses on the antibacterial effect of bacteriophage and their recent clinical trials with a special emphasis on the underlying mechanism of lytic phage action with the help of endolysin and holin. Furthermore, recent clinical trials of natural and modified endolysins and some marketed products have also been emphasized with future prospective.

The Biological Characteristics of Mycobacterium Phage Henu3 and the Fitness Cost Associated with Its Resistant Strains.

Tuberculosis (TB), caused by Mycobacterium tuberculosis, is an infectious disease that seriously affects human life and health. Despite centuries of efforts to control it, in recent years, the emergence of multidrug-resistant bacterial pathogens of M. tuberculosis due to various factors has exacerbated the disease, posing a serious threat to global health. Therefore, a new method to control M. tuberculosis is urgently needed. Phages, viruses that specifically infect bacteria, have emerged as potential biocontrol agents for bacterial pathogens due to their host specificity. In this study, a mycobacterium phage, Henu3, was isolated from soil around a hospital. The particle morphology, biological characteristics, genomics and phylogeny of Henu3 were characterized. Additionally, to explore the balance between phage resistance and stress response, phage Henu3-resistant strains 0G10 and 2E1 were screened by sequence passage and bidirectional validation methods, which significantly improved the sensitivity of phage to antibiotics (cefotaxime and kanamycin). By whole-genome re-sequencing of strains 0G10 and 2E1, 12 genes involved in cell-wall synthesis, transporter-encoded genes, two-component regulatory proteins and transcriptional regulatory factor-encoded genes were found to have mutations. These results suggest that phage Henu3 has the potential to control M. tuberculosis pathogens, and phage Henu3 has the potential to be a new potential solution for the treatment of M. tuberculosis infection.

In Vitro and In Vivo Assessments of Newly Isolated N4-like Bacteriophage against ST45 K62 Capsular-Type Carbapenem-Resistant Klebsiella pneumoniae: vB_kpnP_KPYAP-1.

The rise of carbapenem-resistant Klebsiella pneumoniae (CRKP) presents a significant global challenge in clinical and healthcare settings, severely limiting treatment options. This study aimed to utilize a bacteriophage as an alternative therapy against carbapenem-resistant K. pneumoniae. A novel lytic N4-like Klebsiella phage, vB_kpnP_KPYAP-1 (KPYAP-1), was isolated from sewage. It demonstrated efficacy against the K62 serotype polysaccharide capsule of blaOXA-48-producing K. pneumoniae. KPYAP-1 forms small, clear plaques, has a latent period of 20 min, and reaches a growth plateau at 35 min, with a burst size of 473 plaque-forming units (PFUs) per infected cell. Phylogenetic analysis places KPYAP-1 in the Schitoviridae family, Enquatrovirinae subfamily, and Kaypoctavirus genus. KPYAP-1 employs an N4-like direct terminal repeat mechanism for genome packaging and encodes a large virion-encapsulated RNA polymerase. It lacks integrase or repressor genes, antibiotic resistance genes, bacterial virulence factors, and toxins, ensuring its safety for therapeutic use. Comparative genome analysis revealed that the KPYAP-1 genome is most similar to the KP8 genome, yet differs in tail fiber protein, indicating variations in host recognition. In a zebrafish infection model, KPYAP-1 significantly improved the survival rate of infected fish by 92% at a multiplicity of infection (MOI) of 10, demonstrating its potential for in vivo treatment. These results highlight KPYAP-1 as a promising candidate for developing phage-based therapies targeting carbapenemase-producing K. pneumoniae.

Phage-based biocontrol of Porphyromonas gingivalis through indirect targeting.

Bacteriophages offer an opportunity for chemical-free, precise control of problematic bacteria, but this approach can be limited when lytic phages are difficult to obtain for the target host. In such cases, phage-based targeting of cooperating or cross-feeding bacteria (e.g., Streptococcus gordonii) can be an effective approach to control the problematic bacteria (e.g., Porphyromonas gingivalis). Using a dual-species biofilm system, phage predation of S. gordonii (108 PFU·mL-1) decreased the abundance of pathogenic P. gingivalis by >99% compared with no-treatment controls, while also inhibiting the production of cytotoxic metabolic end products (butyric and propionic acids). Phage treatment upregulated genes associated with interspecies co-adhesion (5- to 8-fold) and quorum sensing (10-fold) in residual P. gingivalis, which is conducive to increased potential to bind to S. gordonii. Counterintuitively, lower-titer phage applications (104 PFU·mL-1) increased the production of extracellular polymeric substance (EPS) by 22% and biofilm biomass by 50%. This overproduction of EPS may contribute to the phenomenon where the biofilm separated into two distinct species layers, as observed by confocal laser scanning microscopy. Although more complex mixed-culture systems should be considered to delineate the merits and limitations of this novel biocontrol approach (which would likely require the use of phage cocktails), our results offer proof of concept that indirect phage-based targeting can expand the applicability of phage-based control of pathogenic bacteria for public health protection. IMPORTANCE: Lytic phages are valuable agents for targeted elimination of bacteria in diverse applications. Nevertheless, lytic phages are difficult to isolate for some target pathogens. We offer proof of concept that this limitation may be overcome via indirect phage targeting, which involves knocking out species that interact closely with and benefit the primary problematic target bacteria. Our target (P. gingivalis) only forms a periodontal pathogenic biofilm if the pioneer colonizer (S. gordonii) offers its surface for P. gingivalis to attach. Phage predation of the co-adhesive S. gordonii significantly reduced abundance of the target pathogen by >99%, decreased the total biofilm biomass by >44%, and suppressed its production of cytotoxic metabolic byproducts. Thus, this research extends the scope of phage-based biocontrol for public health protection.

Elucidating the molecular properties and anti-mycobacterial activity of cysteine peptidase domain of D29 mycobacteriophage endolysin.

Emergence of antibiotic resistance in pathogenic Mycobacterium tuberculosis (Mtb) has elevated tuberculosis to a serious global threat, necessitating alternate solutions for its eradication. D29 mycobacteriophage can infect and kill several mycobacterial species including Mtb. It encodes an endolysin LysA to hydrolyze host bacteria peptidoglycan for progeny release. We previously showed that out of the two catalytically active domains of LysA [N-terminal domain (NTD) and lysozyme-like domain], NTD, when ectopically expressed in Mycobacterium smegmatis (Msm), is able to kill the bacterium nearly as efficiently as full-length LysA. Here, we dissected the functioning of NTD to develop it as a phage-derived small molecule anti-mycobacterial therapeutic. We performed a large-scale site-directed mutagenesis of the conserved residues in NTD and examined its structure, stability, and function using molecular dynamic simulations coupled with biophysical and biochemical experiments. Our data show that NTD functions as a putative cysteine peptidase with a catalytic triad composed of Cys41, His112, and Glu137, acting as nucleophile, base, and acid, respectively, and showing characteristics similar to the NlpC/P60 family of cysteine peptidases. Additionally, our peptidoglycan hydrolysis assays suggested that NTD hydrolyzes only mycobacterial peptidoglycan and does not act on Gram-positive and Gram-negative bacterial peptidoglycans. More importantly, the combined activity of exogenously added NTD and sub-lethal doses of anti-mycobacterial drugs kills Msm in vitro and exhibits disruption of pre-formed mycobacterial biofilm. We additionally show that NTD treatment increases the permeability of antibiotics in Msm, which reduces the minimum inhibitory concentration of the antibiotics. Collectively, we present NTD as a promising phage-derived therapeutic against mycobacteria.IMPORTANCEMycobacteriophages are the viruses that use mycobacteria as host for their progeny production and, in the process, kill them. Mycobacteriophages are, therefore, considered as promising alternatives to antibiotics for killing pathogenic Mycobacterium tuberculosis. The endolysin LysA produced by mycobacteriophage D29 plays an important role in host cell lysis and virion release. Our work presented here highlights the functioning of LysA's N-terminal catalytic domain (NTD) in order to develop it as phage-derived small molecule therapeutics. We show that combined treatment of exogenously added NTD and sub-lethal doses of anti-mycobacterial drugs kills M. smegmatis, shows synergism by reducing the minimum inhibitory concentration of these antibiotics, and exhibits disruption of pre-formed mature biofilm. These outcomes and our detailed biochemical and biophysical dissection of the protein further pave the way toward engineering and development of NTD as a promising therapeutic against mycobacterial infections such as tuberculosis.

Engineered Bacteriophage-Polymer Nanoassemblies for Treatment of Wound Biofilm Infections.

The antibacterial efficacy and specificity of lytic bacteriophages (phages) make them promising therapeutics for treatment of multidrug-resistant bacterial infections. Restricted penetration of phages through the protective matrix of biofilms, however, may limit their efficacy against biofilm infections. Here, engineered polymers were used to generate noncovalent phage-polymer nanoassemblies (PPNs) that penetrate bacterial biofilms and kill resident bacteria. Phage K, active against multiple strains of Staphylococcus aureus, including methicillin-resistant S. aureus (MRSA), was assembled with cationic poly(oxanorbornene) polymers into PPNs. The PPNs retained phage infectivity, while demonstrating enhanced biofilm penetration and killing relative to free phages. PPNs achieved 3-log10 bacterial reduction (∼99.9%) against MRSA biofilms in vitro. PPNs were then incorporated into Poloxamer 407 (P407) hydrogels and applied onto in vivo wound biofilms, demonstrating controlled and sustained release. Hydrogel-incorporated PPNs were effective in a murine MRSA wound biofilm model, showing a 1.5-log10 reduction in bacterial load compared to a 0.5 log reduction with phage K in P407 hydrogel. Overall, this work showcases the therapeutic potential of phage K engineered with cationic polymers for treating wound biofilm infections.

A nanoluciferase-encoded bacteriophage illuminates viral infection dynamics of Pseudomonas aeruginosa cells.

Bacteriophages (phages) are increasingly considered for both treatment and early detection of bacterial pathogens given their specificity and rapid infection kinetics. Here, we exploit an engineered phage expressing nanoluciferase to detect signals associated with Pseudomonas aeruginosa lysis spanning single cells to populations. Using several P. aeruginosa strains we found that the latent period, burst size, fraction of infected cells, and efficiency of plating inferred from fluorescent light intensity signals were consistent with inferences from conventional population assays. Notably, imaging-based traits were obtained in minutes to hours in contrast to the use of overnight plaques, which opens the possibility to study infection dynamics in spatial and/or temporal contexts where plaque development is infeasible. These findings support the use of engineered phages to study infection kinetics of virus-cell interactions in complex environments and potentially accelerate the determination of viral host range in therapeutically relevant contexts.

Isolation of the novel phage SAP71 and its potential use against Staphylococcus aureus in an atopic dermatitis mouse model.

Atopic dermatitis (AD) is accompanied by changes in skin microbiota, in which abnormal colonization of Staphylococcus aureus is particularly common. The antibiotic treatment is prone to destroy the commensal bacterial community, further exacerbating the microbiome dysbiosis. Elimination of S. aureus through phage-targeted therapies presents a promising method in the treatment strategy of AD. In this study, we isolated a novel phage SAP71, which specifically lysed S. aureus. Genome sequencing showed that SAP71 contained no virulence, lysogenic, or antimicrobial resistance genes, making this lytic phage a potential agent for phage therapy. Moreover, we demonstrated that phage SAP71 was able to significantly improve the skin lesions, reduce the bacterial loads in the skin, and prevent the development of AD-like skin pathological changes in an AD model. In short, phage SAP71 was demonstrated to effectively treat S. aureus infection in AD, which provided a theoretical basis for the clinical phage therapy of AD.

Formulation of Dual-Functional Nonionic Cetomacrogol Creams Incorporated with Bacteriophage and Human Platelet Lysate for Effective Targeting of MDR P. aeruginosa and Enhanced Wound Healing.

Successful development of phage-based therapeutics and their utility predominantly depend on the mode and route of phage administration. Topical and site-directed phage application evokes minimal immune clearance and allows more phage-host adsorption, thereby ensuring higher phage efficacy. However, a notable drawback of conventional topical phage applications is the absence of sustained release. Occlusive emollients guarantee the controlled release of active pharmaceutical ingredients (APIs), thereby facilitating administration, preventing moisture loss, and acting as a skin barrier. In this study, we developed phage and human platelet lysate (h-PL) incorporated cetomacrogol-based creams for combined phage therapy and wound healing. The base material for phage immobilization was formulated by emulsifying paraffin and sterile water with cetomacrogol (emulsifying agent). Specifically, we incorporated a Pseudomonas aeruginosa-infecting lytic phage vB_PaeM_M12PA in the formulation and characterized its genome in this study. Cetomacrogol, a nonionic PEG (polyethylene glycol) based ether, rendered phage stability and allowed initial burst release followed by continuous controlled release of phages from the embedding matrix in the initial 6-8 h. Rheological studies showed that the material has elastic properties with storage moduli (G') values ranging from 109.51 ± 2.10 to 126.02 ± 3.13 kPa, indicating frequency-independent deformation. Platelet lysates in the cream acted as wound healing agents, and in vitro evaluation of cell migration and wound healing capacity of h-PL showed a significant enhancement by the sixth hour compared to untreated groups. The phage-incorporated cream showed sustained phage release in solid media and a significant reduction in bacterial growth in liquid cultures. In vivo wound healing studies in 6-week-old Wistar rats with full-thickness excision wounds and subsequent histopathological studies showed that the formulation enhanced wound healing and tissue restoration efficiency. In conclusion, the study unveils a promising approach for integrated phage therapy and wound healing strategies.

Isolation and characterization of two novel bacteriophages against carbapenem-resistant Klebsiella pneumoniae.

The increase of antibiotic-resistant bacteria has become a global health emergency and the need to explore alternative therapeutic options arises. Phage therapy uses bacteriophages to target specific bacterial strains. Phages are highly specific and can target resistant bacteria. Currently, research in this regard is focused on ensuring reliability and safety to bring this tool into clinical practice. The first step is to conduct comprehensive preclinical research. In this work, we present two novel bacteriophages vB_Kpn_F13 and vB_Kpn_F14 isolated against clinical carbapenem-resistant Klebsiella pneumoniae strains obtained from hospital sewage. Multiple studies in vitro were conducted, such as sequencing, electron microscopy, stability, host range infectivity, planktonic effect and biofilm inhibition in order to discover their ability to be used against carbapenem-resistant K. pneumoniae pathogens causing difficult-to-treat infections.

Antibacterial efficacy of mycobacteriophages against virulent Mycobacterium tuberculosis.

Tuberculosis (TB) remains a major global health concern, with drug-resistant strains posing a significant challenge to effective treatment. Bacteriophage (phage) therapy has emerged as a potential alternative to combat antibiotic resistance. In this study, we investigated the efficacy of widely used mycobacteriophages (D29, TM4, DS6A) against Mycobacterium tuberculosis (M. tuberculosis) under pathophysiological conditions associated with TB, such as low pH and hypoxia. We found that even at low multiplicity of infection (MOI), mycobacteriophages effectively infected M. tuberculosis, got rapidly amplified, and lysed M. tuberculosis, demonstrating their potential as therapeutic agents. Furthermore, we observed a novel phage tolerance mechanism with bacteria forming aggregates after several days of phage treatment. These aggregates were enriched with biofilm components and metabolically active bacteria. However, no phage tolerance was observed upon treatment with the three-phage mixture, highlighting the dynamic interplay between phages and bacteria and emphasizing the importance of phage cocktails. We also observed that phages were effective in lysing bacteria even under low pH and low oxygen concentrations as well as antibiotic-resistant bacteria. Our results provide key insights into phage infection of slow-growing bacteria and suggest that mycobacteriophages can effectively eliminate M. tuberculosis in complex pathophysiological environments like hypoxia and acidic pH. These results can aid in developing targeted phage-based therapies to combat antibiotic-resistant mycobacterial infections.

Isolation and characterization of a novel bacteriophage against Vibrio alginolyticus from coastal waters and its environmental tolerance.

In response to the problems associated with drug resistance resulting from the use of antibiotics, phages have become desirable options for the treatment of Vibrio alginolyticus disease in aquaculture. In this study, we isolated a novel double-stranded DNA (dsDNA) phage named vB_ValC_WD615 infecting V. alginolyticus; this phage belongs to the family Podoviridae and has a short noncontractile tail (13 ± 1.5 nm) and an icosahedral head (60.2 ± 2 nm); its genome is 50,522 bp and encodes 69 open reading frames (ORFs) and no lysogenic genes were annotated in the genome. Physiological results indicate that vB_ValC_WD615 infects V. alginolyticus SC1 with a burst size of 335 PFU/cell and can maintain stable infectivity within temperature and pH conditions ranging from 4 to 45 °C and 3 to 11, respectively. The results suggest that the vB_ValC_WD615 isolated from coastal waters could be a potential candidate for phage therapy targeting V. alginolyticus.

Zebrafish as an effective model for evaluating phage therapy in bacterial infections: a promising strategy against human pathogens.

The escalating prevalence of antibiotic-resistant bacterial infections necessitates urgent alternative therapeutic strategies. Phage therapy, which employs bacteriophages to specifically target pathogenic bacteria, emerges as a promising solution. This review examines the efficacy of phage therapy in zebrafish models, both embryos and adults, which are proven and reliable for simulating human infectious diseases. We synthesize findings from recent studies that utilized these models to assess phage treatments against various bacterial pathogens, including Enterococcus faecalis, Pseudomonas aeruginosa, Mycobacterium abscessus, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, and Escherichia coli. Methods of phage administration, such as circulation injection and bath immersion, are detailed alongside evaluations of survival rates and bacterial load reductions. Notably, combination therapies of phages with antibiotics show enhanced efficacy, as evidenced by improved survival rates and synergistic effects in reducing bacterial loads. We also discuss the transition from zebrafish embryos to adult models, emphasizing the increased complexity of immune responses. This review highlights the valuable contribution of the zebrafish model to advancing phage therapy research, particularly in the face of rising antibiotic resistance and the urgent need for alternative treatments.

Complete genome sequence of E. coli lytic bacteriophage BAU.Micro_ELP-22, isolated from sewage water, Bangladesh.

Escherichia coli lytic bacteriophage BAU.Micro_ELP-22 was isolated from sewage wastewater as a therapeutic agent alternative to antibiotics. The phage genome is 373,488 bp in length, encoding 744 protein-coding sequences and 7 tRNAs, and contains no antibiotic resistance, virulence, or temperate marker genes, which specifies its potentiality as a compatible phage therapy candidate.

Complete genome sequences of four lytic bacteriophages against multidrug-resistant Enterococcus faecium.

We report the genome sequences of four Enterococcus faecium phages isolated from environmental wastewater in Kenya. They are double-stranded DNA phages with genomes varying in length from 42,231 to 43,348 bp, with G+C contents ranging from 34.96% to 35.2%. The genomes contain 78-82 coding sequences.

Phage-specific antibodies: are they a hurdle for the success of phage therapy?

Phage therapy has attracted attention again owing to the increasing number of drug-resistant bacteria. Although the efficacy of phage therapy has been reported, numerous studies have indicated that the generation of phage-specific antibodies resulting from phage administration might have an impact on clinical outcomes. Phage-specific antibodies promote phage uptake by macrophages and contribute to their rapid clearance from the body. In addition, phage-specific neutralizing antibodies bind to the phages and diminish their antibacterial activity. Thus, phage-specific antibody production and its role in phage therapy have been analyzed both in vitro and in vivo. Strategies for prolonging the blood circulation time of phages have also been investigated. However, despite these efforts, the results of clinical trials are still inconsistent, and a consensus on whether phage-specific antibodies influence clinical outcomes has not yet been reached. In this review, we summarize the phage-specific antibody production during phage therapy. In addition, we introduce recently performed clinical trials and discuss whether phage-specific antibodies affect clinical outcomes and what we can do to further improve phage therapy regimens.

Proportion of patients with prosthetic joint infection eligible for adjuvant phage therapy: a French single-centre retrospective study.

BACKGROUND: Bone and joint infections represent a major public health issue due to their increasing prevalence, their functional prognosis and their cost to society. Phage therapy has valuable anti-biofilm properties against prosthetic joint infections (PJI). The aim of this study was to establish the proportion of patients eligible for phage therapy and to assess their clinical outcome judged against all patients presenting with PJI. METHOD: . Patients admitted for periprosthetic joint infection (PJI) at a French general hospital between 2015 and 2019 were retrospectively included. Eligibility for phage therapy was determined based on French recommendations, with polymicrobial infections serving as exclusion criteria. Patients were categorized into two groups: those eligible and those ineligible for phage therapy. We analyzed their characteristics and outcomes, including severe adverse events, duration of intravenous antibiotic therapy, length of hospitalization, and relapse rates. RESULTS: . In this study, 96 patients with PJI were considered in multidisciplinary medical meetings. Of these, 44% patients (42/96) were eligible for additional phage therapy. This group of patients had a longer duration of intravenous therapy (17 days vs. 10 days, p = 0.02), more severe adverse events (11 vs. 3, p = 0.08) and had a longer hospital stay (43 days vs. 18 days, p < 0.01). CONCLUSION: . A large number of patients met eligibility criteria for phage therapy and treatment and follow-up is more complex. A larger epidemiological study would more accurately describe the prognosis of eligible patients.

Antibacterial effect of phage cocktails and phage-antibiotic synergy against pathogenic Klebsiella pneumoniae.

The global rise of antibiotic resistance has renewed interest in phage therapy, as an alternative to antibiotics to eliminate multidrug-resistant (MDR) bacterial pathogens. However, optimizing the broad-spectrum efficacy of phage therapy remains a challenge. In this study, we addressed this issue by employing strategies to improve antimicrobial efficacy of phage therapy against MDR Klebsiella pneumoniae strains, which are notorious for their resistance to conventional antibiotics. This includes the selection of broad host range phages, optimization of phage formulation, and combinations with last-resort antibiotics. Our findings unveil that having a broad host range was a dominant trait of isolated phages, and increasing phage numbers in combination with antibiotics significantly enhanced the suppression of bacterial growth. The decreased incidence of bacterial infection was explained by a reduction in pathogen density and emergence of bacterial resistance. Furthermore, phage-antibiotic synergy (PAS) demonstrated considerable broad-spectrum antibacterial potential against different clades of clinical MDR K. pneumoniae pathogens. The improved treatment outcomes of optimized PAS were also evident in a murine model, where mice receiving optimized PAS therapy demonstrated a reduced bacterial burden in mouse tissues. Taken together, these findings offer an important development in optimizing PAS therapy and its efficacy in the elimination of MDR K. pneumoniae pathogens. IMPORTANCE: The worldwide spread of antimicrobial resistance (AMR) has posed a great challenge to global public health. Phage therapy has become a promising alternative against difficult-to-treat pathogens. One important goal of this study was to optimize the therapeutic efficiency of phage-antibiotic combinations, known as phage-antibiotic synergy (PAS). Through comprehensive analysis of the phenotypic and genotypic characteristics of a large number of CRKp-specific phages, we developed a systematic model for phage cocktail combinations. Crucially, our finding demonstrated that PAS treatments not only enhance the bactericidal effects of colistin and tigecycline against multidrug-resistant (MDR) K. pneumoniae strains in in vitro and in vivo context but also provide a robust response when antibiotics fail. Overall, the optimized PAS therapy demonstrates considerable potential in combating diverse K. pneumoniae pathogens, highlighting its relevance as a strategy to mitigate antibiotic resistance threats effectively.