Klebsiella Phage Research Articles

Characterization of Two Lytic Bacteriophages Infecting Carbapenem-Resistant Clinical Klebsiella pneumoniae in Dhaka, Bangladesh

Bacteriophages or bacteria infecting viruses are genetically diverse. Due to the emergence of antimicrobial-resistant bacteria, lytic bacteriophages are gaining enormous attention for treating superbug infections. Klebsiella pneumoniae is one of the eight most significant nosocomial pathogens and is addressed as a critical priority pathogen by WHO, requiring alternative treatment options. We reported two highly lytic bacteriophages, Klebsiella phage Kpn BM7 and the novel Klebsiella phage Kpn BU9, isolated from hospital wastewater and exhibiting lytic activity against different clinical isolates. Whole-genome analysis revealed that phages BM7 and BU9 belong to class Caudoviricetes. Phage BM7, with a genome length of 170,558 bp, is a member of the genus Marfavirus and the species Marfavirus F48, while phage BU9, with a genome length of 60,450 bp, remains unclassified. Neither phage harbors any lysogenic, toxin, or antimicrobial resistance genes. Both phages can steadily survive up to 40°C and at pH 5-7. The optimal MOI was 0.1 for BM7 and 1 for BU9, with short latent periods of 10 and 25 min and burst sizes of 85 PFU/cell and 12 PFU/cell, respectively. This is the first carbapenem-resistant K. pneumoniae (CRKP) targeting lytic phages to be reported from Bangladesh. This study suggests that BM7 and BU9 are potential candidates for targeting carbapenem-resistant K. pneumoniae.

Characterization and genomic analysis phage PmP19, a novel Proteus mirabilis phage with a broad host range.

A lytic Proteus mirabilis phage, PmP19, was isolated from sewage on a farm. PmP19 has an icosahedral head (60 ± 3 nm in diameter) and a short tail (15 ± 2 nm long). Its genome, a linear, double-stranded DNA molecule 44,305 bp in length with an average GC content of 51.93%, has 52 putative open reading frames (ORFs). BLASTn comparisons and phylogenetic analysis revealed a close relationship between Pmp19 and Klebsiella phage vB_KpnP_ZK1. Bioinformatic analysis revealed that PmP19 belongs to the phage subfamily Molineuxvirinae.

Isolation and preliminary characterization of a novel bacteriophage vB_KquU_φKuK6 that infects the multidrug-resistant pathogen Klebsiella quasipneumoniae.

Klebsiella quasipneumoniae (previously known as K. pneumoniae K6) strains are among the multidrug-resistant hypervirulent bacterial pathogens. Phage therapy can help treat infections caused by such pathogens. Here we report some aspects of virology and therapeutic potentials of vB_KquU_φKuK6, a bacteriophage that infects Klebsiella quasipneumoniae. K. quasipneumoniae (ATCC 700603) was used to screen wastewater lytic phages. The isolate vB_KquU_φKuK6 that consistently created large clear plaques was characterized using standard virological and molecular methods. vB_KquU_φKuK6 has a complex capsid with an icosahedral head (~60 nm) and a slender tail (~140 nm × 10 nm). The phage has a 51% AT-rich linear dsDNA genome (51,251 bp) containing 121 open reading frames. The genome contains genes encoding spanin, endolysin, and holin proteins necessary for lytic infection and a recombinase gene possibly involved in lysogenic infection. vB_KquU_φKuK6 is stable at -80 to +67°C, pH 4-9, and brief exposure to one volume percent of chloroform. vB_KquU_φKuK6 has a narrow host range. Its lytic infection cycle involves a latency of 20 min and a burst size of 435 plaque-forming units. The phage can cause lysogenic infection, and the resulting lysogens are resistant to lytic infection by vB_KquU_φKuK6. vB_KquU_φKuK6 reduces the host cells' ability to form biofilm but fails to eliminate that ability. vB_KquU_φKuK6 demonstrates phage-antibiotic synergy and reduces the minimum inhibitory concentration of chloramphenicol and neomycin sulfate by about 8 folds. vB_KquU_φKuK6 cannot be directly used for phage therapy because it is a temperate bacteriophage. However, genetically modified strains of vB_KquU_φKuK6 alone or combined with antibiotics or other lytic Klebsiella phages can have therapeutic utilities in treating K. quasipneumoniae infections.

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.

Physiochemical characterization of a potential Klebsiella phage MKP-1 and analysis of its application in reducing biofilm formation.

The common intestinal pathogen Klebsiella pneumoniae (K. pneumoniae) is one of the leading causes of fatal superbug infections that can resist the effects of commonly prescribed medicines. The uncontrolled use or misuse of antibiotics has increased the prevalence of drug-resistant K. pneumoniae strains in the environment. In the quest to search for alternative therapeutics for treating these drug-resistant infections, bacteriophages (bacterial viruses) emerged as potential candidates for in phage therapy against Klebsiella. The effective formulation of phage therapy against drug-resistant Klebsiella infections demands thorough characterization and screening of many bacteriophages. To contribute effectively to the formulation of successful phage therapy against superbug infections by K. pneumoniae, this study includes the isolation and characterization of a novel lytic bacteriophage MKP-1 to consider its potential to be used as therapeutics in treating drug-resistant Klebsiella infections. Morphologically, having a capsid attached to a long non-contractile tail, it was found to be a siphovirus that belongs to the class Caudoviricetes and showed infectivity against different strains of the target host bacterium. Comparatively, this double-stranded DNA phage has a large burst size and is quite stable in various physiological conditions. More interestingly, it has the potential to degrade the tough biofilms formed by K. pneumoniae (Klebsiella pneumoniae subsp. pneumoniae (Schroeter) Trevisan [ATCC 15380]) significantly. Thus, the following study would contribute effectively to considering phage MKP-1 as a potential candidate for phage therapy against Klebsiella infection.

Isolation, Identification, and Biological Characterization of Phage vB_KpnM_KpVB3 Targeting Carbapenem-Resistant Klebsiella pneumoniae ST11

This study aimed to isolate a phage capable of lysing carbapenem-resistant Klebsiella pneumoniae (CRKP) and to analyse its biological characteristics and whole-genome sequence. The phage was isolated and purified from the sewage. Transmission electron microscopy (TEM) was employed to observe the bacteriophage's morphology. Phenotypic characterization of the bacteriophages was determined. The genomic information was analysed. Evolutionary relationships were established through comparative genomics, proteomics, and phylogenetic analysis. The isolation of a virulent phage, named Klebsiella phage vB_KpnM_KpVB3, was notable for forming 6-7 mm transparent circular zones, each surrounded by a distinct halo. The phage had a head diameter of ca. 30 nm and a tail length of ca. 20 nm, being identified as a member of the Myoviridae family and the Caudovirales order. The optimal multiplicity of infection (MOI) was 0.00001, with an incubation period of 20 minutes and a lysis period of 60 minutes, and the number of released phages after lysis was 133±35 PFU/cell. The phage was relatively stable at temperatures ranging from 10°C to 40°C and at pH values ranging from 3 to 11. Its lytic efficiency against CRKP was 30.30%. It has been shown to be able to destroy the biofilm of host bacteria. The bacteriophage genome consists of double-stranded DNA (dsDNA) with a total length of 48,394 base pairs, a GC content of 48.99%, and 78 open reading frames (ORFs). The study resulted in the isolation vB_KpnM_KpVB3, a phage demonstrating potential therapeutic efficacy against infections caused by CRKP.

THE USE OF A POLYVALENT KLEBSIELLA BACTERIOPHAGE IN INFECTION AFTER RECONSTRUCTIVE PLASTIC SURGERY ON THE SPINE IN A CHILD (A CLINICAL CASE)

The incidence of infection after reconstructive plastic surgery on the spine (in particular, spondylodesis) in children remains at a fairly high level and ranges from 0.4% to 8.7%. These complications are often caused by polyresistant bacterial pathogens; this accentuates the need for new effective therapeutic approaches. Bacteriophage preparations in combination with antibiotics can optimize existing strategies for the treatment of infectious diseases, since they are able to selectively destroy bacteria, including biofilm-forming ones. The aim of the study was to draw the attention of practitioners to modern problems of treating polyresistant infections on the example of a case of purulent complication after spinal surgery in a child. Materials and methods. On the basis of the FSBI "Federal Center for Traumatology, Orthopedics and Endoprosthetics" under the Health Ministry of the Russian Federation (the town of Cheboksary) a retrospective analysis of a clinical case of treating early infection after reconstructive plastic surgery on the spine caused by a polyresistant strain of Klebsiella pneumoniae was conducted. Research results. Patient P., 2.2 years old, with congenital pathology of the musculoskeletal system, who repeatedly received medical care in various medical organizations, underwent surgical spine stabilization. In the early postoperative period, an infectious complication developed caused by a polyresistant strain of Klebsiella pneumoniae (a producer of extended-spectrum beta-lactamases and carbapenemases). Along with surgical debridement of the postoperative wound, a combined etiotropic antibacterial therapy was performed (12 weeks). However, complete healing of the postoperative wound was achieved in combination with the administration of a polyvalent klebsiella bacteriophage (10 weeks). Conclusions. This clinical case demonstrates that the use of a polyvalent klebsiella bacteriophage can increase the effectiveness of antibacterial pharmacotherapy in surgical treatment with preservation of metal structures.

Biological and genomic characteristics of three novel bacteriophages and a phage-plasmid of Klebsiella pneumoniae.

Bacteriophages have emerged as promising candidates for the treatment of difficult-to-treat bacterial infections. The aim of this study is to isolate and characterize phages infecting carbapenem-resistant and extended-spectrum beta-lactamase producer Klebsiella pneumoniae isolates. Water samples were taken for the isolation of bacteriophages. One-step growth curve, the optimal multiplicity of infection (MOI), thermal and pH stabilities, transmission electron microscopy and whole-genome sequencing of phages were studied. Four phages were isolated and named Klebsiella phage Kpn02, Kpn17, Kpn74, and Kpn13. The optimal MOI and latent periods of phage Kpn02, Kpn17, Kpn74, and Kpn13 were 10, 1, 0.001, and 100 PFU/CFU and 20, 10, 20, and 30min, respectively. Burst sizes ranged from 811 to 2363. No known antibiotic resistance and virulence genes were identified. No tRNAs were detected except Klebsiella phage Kpn02 which encodes 24 tRNAs. Interestingly, Klebsiella phage Kpn74 was predicted to be a lysogenic phage whose prophage is a linear plasmid molecule with covalently closed ends. Of the Klebsiella-infecting phages presented in current study, virulent phages suggest that they may represent candidate therapeutic agents against MDR K. pneumoniae, based on short latent period, high burst sizes and no known antibiotic resistance and virulence genes in their genomes.

Bacterial isolation and genome analysis of a novel Klebsiella quasipneumoniae phage in southwest China’s karst area

BackgroundSouthwest China is one of the largest karst regions in the world. Karst environment is relatively fragile and vulnerable to human activities. Due to the discharge of sewage and domestic garbage, the karst system may be polluted by pathogenic bacteria. The detection of bacterial distribution and identification of phage capable of infecting them is an important approach for environmental assessment and resource acquisition.MethodsBacteria and phages were isolated from karst water in southwest China using the plate scribing and double plate method, respectively. Isolated phage was defined by transmission electron microscopy, one-step growth curve and optimal multiplicity of infection (MOI). Genomic sequencing, phylogenetic analysis, comparative genomic and proteomic analysis were performed.ResultsA Klebsiella quasipneumoniae phage was isolated from 32 isolates and named KL01. KL01 is morphologically identified as Caudoviricetes with an optimal MOI of 0.1, an incubation period of 10 min, and a lysis period of 60 min. The genome length of KL01 is about 45 kb, the GC content is 42.5%, and it contains 59 open reading frames. The highest average nucleotide similarity between KL01 and a known Klebsiella phage 6939 was 83.04%.ConclusionsKL01 is a novel phage, belonging to the Autophagoviridae, which has strong lytic ability. This study indicates that there were not only some potential potentially pathogenic bacteria in the karst environment, but also phage resources for exploration and application.

Characterization and complete genome analysis of Klebsiella phage Kp109 with lytic activity against Klebsiella pneumoniae.

Klebsiella pneumonia is a serious pathogen involved in a range of infections. The increasing frequency ofinfection associated with K. pneumoniae and accelerated development of antimicrobial resistance has limited the available options of antibiotics for the treatment of infection. Bacteriophages are an attractive substitute to alleviate the problem of antibiotic resistance. In this study, isolation, microbiological and genomic characterization of bacteriophage Kp109 having the ability to infect K. pneumoniae has been shown. Phage Kp109 showed good killing efficiency and tolerance to a broad range of temperatures (4-60°C) and pH (3-9). Transmission electron microscopy and genomic analysis indicated that phage Kp109 belongs to the genus Webervirus and family Drexlerviridae. Genomic analysis showed that the Kp109 has a 51,630bp long double-stranded DNA genome with a GC content of 51.64%. The absence of known lysogenic, virulence, and antibiotic-resistant genes (ARGs) in its genome makes phage Kp109 safer to be used as a biocontrol agent for different purposes including phage therapy. The computational analysis of the putative endolysin gene revealed a binding energy of -6.23kcal/mol between LysKp109 and ligand NAM-NAG showing its potential to be used as an enzybiotic. However, future research is required for experimental validation of the in silico work to further corroborate the results obtained in the present study. Overall, phenotypic, genomic, and computational characterization performed in the present study showed that phages Kp109 and LysKp109 are promising candidates for future in vivo studies and could potentially be used for controlling K. pneumoniae infection.

Two novel phages, Klebsiella phage GADU21 and Escherichia phage GADU22, from the urine samples of patients with urinary tract infection.

Phages are found in a wide variety of places where bacteria exist including body fluids. The aim of the present study was to isolate phages from the urine samples of patients with urinary tract infection. The 10 urine samples were cultured to isolate bacteria and also used as phage sources against the isolated bacteria. From 10 urine samples with positive cultures, 3 phages were isolated (33%) and two of them were further studied. The Klebsiella phage GADU21 and Escherichia phage GADU22 phages infected Klebsiella pneumonia and Escherichia coli, respectively. Among the tested 14 species for host range analysis, the Klebsiella phage GADU21 was able to infect two species which are Klebsiella pneumonia and Proteus mirabilis, and Escherichia phage GADU22 was able to infect four species which are Shigella flexneri, Shigella sonnei and Escherichia coli. Among different isolates of the indicator bacteria for each phage, GADU21 infected half of the tested 20 Klebsiella pneumonia isolates while GADU22 infected 85% of the tested 20 E. coli isolates. The genome sizes and GC ratios were 75,968bp and 44.4%, and 168,023bp and 35.3% for GADU21 and GADU22, respectively. GADU21 and GADU22 were both lytic and had no antibiotic resistance and virulence genes. GADU21 was homologue with Klebsiella phage vB_KpP_FBKp27 but only 88% of the genome was covered by this phage. The non-covered parts of the GADU21 genome included genes for tail-fiber-proteins and HNH-endonuclease. GADU22 had 94.8% homology with Escherichia phage vB_Eco_OMNI12 and had genes for immunity proteins. Phylogenetic analysis showed GADU21 and GADU22 were members of Schitoviridae family and Efbeekayvirus genus and Straboviridae family and Tevenvirinae genus, respectively. VIRIDIC analysis classified these phages in new species clusters. Our study demonstrated the possibility to use infected body fluids as phage sources to isolate novel phages. GADU21 is the first reported Klebsiella phage isolated from human body fluid. The absence of virulence and antibiotic resistance genes in their genomes makes the phages a potential therapeutic tool against infections.

Depolymerisation of the Klebsiella pneumoniae Capsular Polysaccharide K21 by Klebsiella Phage K5.

Klebsiella pneumoniae is a pathogen associated with various infection types, which often exhibits multiple antibiotic resistance. Phages, or bacterial viruses, have an ability to specifically target and destroy K. pneumoniae, offering a potential means of combatting multidrug-resistant infections. Phage enzymes are another promising therapeutic agent that can break down bacterial capsular polysaccharide, which shields K. pneumoniae from the immune response and external factors. In this study, Klebsiella phage K5 was isolated; this phage is active against Klebsiella pneumoniae with the capsular type K21. It was demonstrated that the phage can effectively lyse the host culture. The adsorption apparatus of the phage has revealed two receptor-binding proteins (RBPs) with predicted polysaccharide depolymerising activity. A recombinant form of both RBPs was obtained and experiments showed that one of them depolymerised the capsular polysaccharide K21. The structure of this polysaccharide and its degradation fragments were analysed. The second receptor-binding protein showed no activity on capsular polysaccharide of any of the 31 capsule types tested, so the substrate for this enzyme remains to be determined in the future. Klebsiella phage K5 may be considered a useful agent against Klebsiella infections.

Genome sequence of the Klebsiella quasipneumoniae bacteriophage EKq1 with activity against Klebsiella pneumoniae.

We describe the genome of a lytic phage EKq1 isolated on Klebsiella quasipneumoniae, with activity against Klebsiella pneumoniae. EKq1 is an unclassified representative of the class Caudoviricetes, similar to Klebsiella phages VLCpiS8c, phiKp_7-2, and vB_KleS-HSE3. The 48,244-bp genome has a GC content of 56.43% and 63 predicted protein-coding genes.

Genomic analysis of K47-type Klebsiella pneumoniae phage IME305, a newly isolated member of the genus Teetrevirus.

We isolated a K47-type Klebsiella pneumoniae phage from untreated hospital sewage: vB_KpnP_IME305 (GenBank no. OK149215). Next-generation sequencing (NGS) demonstrated that IME305 has a double-stranded DNA genome of 38,641 bp with 50.9% GC content. According to BLASTn comparisons, the IME305 genome sequence shares similarity with that of Klebsiella phage 6998 (97.37% identity and 95% coverage). IME305 contains 45 open reading frames (ORFs) and no rRNA, tRNA, or virulence-related gene sequences. Bioinformatic analysis showed that IME305 belongs to the phage subfamily Studiervirinae and genus Teetrevirus.

Broad-range capsule-dependent lytic Sugarlandvirus against Klebsiella sp.

The emergence of antibiotic-resistant bacteria has become a serious global health threat requiring the development of novel treatments. Klebsiella pneumoniae is an encapsulated bacterium considered a major concern due to its high resistance, prevalence, and mortality rates. Phage therapy has been proposed as a very promising alternative to combat infections by Klebsiella sp. infections. However, most of the Klebsiella phages described so far present a high specificity, infecting one or a few capsular types due to the presence of depolymerases in their genomes, which limits their therapeutic potential. Here, we present three new Klebsiella phages isolated from the environment, vB_Kpn_K7PH164C4, vB_Kpn_K30λ2.2, and vB_Kpl_K32PH164C1, belonging to the family Demerecviridae and the genus Sugarlandvirus. The most important feature of these new Klebsiella phages is their broad host range, especially vB_Kpn_K7PH164C4 and vB_Kpn_K30λ2.2, which infects strains of more than 20 different capsular types, representing the broadest infection range observed for Klebsiella phages. Genomic analysis revealed the presence of three receptor-binding proteins lacking depolymerase domains. Nevertheless, capsule expression is suggested to be a determining factor in phage infectivity, despite the absence of depolymerase activity against capsular components. Our findings hold potential for the development of promising phage-based therapeutics directed against K. pneumoniae.IMPORTANCEThe emergence of multi-drug resistant bacteria is a global health problem. Among them, Klebsiella pneumoniae is considered a high-priority pathogen, making it necessary to develop new therapeutic tools to reduce the bacterial burden in an effective and sustainable manner. Phages, bacterial viruses, are very promising tools. However, phages are highy specific, rendering large-scale therapeutics costly to implement. This is especially certain in Klebsiella, a capsular bacterium in which phages have been shown to be capsular type dependent, infecting one or a few capsular types through specific enzymes called depolymerases. In this study, we have isolated and characterized novel phages with lytic ability against bacteria from a wide variety of capsular types, representing the Klebsiella phages with the widest range of infection described. Remarkably, these broad-range phages showed capsule dependency, despite the absence of depolymerases in their genomes, implying that infectivity could be governed by alternative mechanisms yet to be uncovered.

Biological Properties and Antibiotic Resistance of <i>Klebsiella pneumoniae</i> and Its Role in the Etiological Structure of Community-Acquired Pneumonia Pathogens

Background. In a novel coronavirus pandemic, the most common complications of viral pneumonia are secondary infections of bacterial and fungal etiology. At the same time, the spread of multidrug-resistant bacteria remains a global threat to public health. One of such microorganisms of the Enterobacteriaceae family is Klebsiella pneumoniae, which belongs to dangerous resistant pathogens of the ESKAPE group.The aim of the study was the comparative analysis of the biological properties of classical and hypermucoid strains of K.pneumoniae isolated from patients with community-acquired pneumonia (CAP): characterization of their sensitivity to antibacterial drugs, Klebsiella bacteriophage, and a disinfectant (polyhexamethylene guanidine hydrochloride), as well as assessment of the strains’ virulence in the model of experimental infection in white mice.Material and methods. 56 strains of Klebsiella isolated in diagnostic quantities from patients’ sputum samples were studied. Species identification of cultures was carried out using bacteriological and mass spectrometric methods. The sensitivity of bacteria to antibiotics, bacteriophage, and the disinfectant was determined in accordance with regulatory documents.Results. In the course of the study, 243 gram-negative cultures were isolated, of which 30% were bacteria of the genus Klebsiella spp. An analysis of their species composition showed that K.pneumoniae occupied a dominant place in the structure. Based on colony morphology, Burri-Gins smear staining, and a positive string test, 14 strains with a hypermucoid phenotype were identified. These strains differed from the classic K.pneumoniae strain by the presence of a thicker capsule in smears, virulence in white mice (DCL≤103 mc), and increased resistance to commercial Klebsiella bacteriophage. At the same time, they were characterized by a wider spectrum of sensitivity to antibiotics. There were no significant differences in sensitivity to the disinfectant in strains of both morphotypes.Conclusion. The results obtained demonstrated the important role of K.pneumoniae in the etiological structure of CAP pathogens.

Metatranscriptomic sequencing reveals there were abundant and diverse viruses in the midgut of diseased silkworm (Bombyx mori) with soft rot symptoms

To date, six viruses belonging to genera Alphabaculovirus, Cypovirus, Iflavirus, Iteravirus, Bidensovirus and Maculavirus were harbored in the silkworm (Bombyx mori) and in the cultured BmN cells. Diseased silkworms with unknown etiology often create economic losses to the farmers. In the present investigation, the abundance and diversity of viruses in the midgut of diseased silkworms with soft rot symptoms were assessed by metatranscriptomic sequencing in order to screen the potential pathogenic virus of the silkworm, B. mori. After removal of undefined reads, clean reads were assembled, and the obtained 76 viral unigenes were annotated to 43 viruses. Among these viruses, the B. mori cypovirus, Pieris rapae virus, Nodaviridae sp., B. mori bidensovirus, Pseudomonas virus pf16, Pseudomonas phage Skulduggery, Klebsiella phage KPN U2874, Equid gammaherpesvirus 2, fowlpox virus and Xestia c-nigrum granulovirus were dominant virus species. These metatranscriptomic sequencing results provided new clues for screening and identifying novel pathogenic virus of the silkworm.

Genomic characterization of the novel bacteriophage IME183, infecting Klebsiella pneumoniae of capsular type K2.

Klebsiella pneumoniae causes a wide range of serious and life-threatening infections. Klebsiella phage IME183, isolated from hospital sewage, exhibited lytic activity against K. pneumoniae of capsular type K2. Transmission electron microscopy revealed that phage IME183 has a head with a diameter of 50 nm and a short tail. Its genome is 41,384 bp in length with a GC content of 52.92%. It is predicted to contain 50 open reading frames (ORFs). The results of evolutionary analysis suggest that phage IME183 should be considered a member of a new species in the genus Przondovirus.

Structural biology and functional features of phage-derived depolymerase Depo32 on Klebsiella pneumoniae with K2 serotype capsular polysaccharides.

Hypervirulent Klebsiella pneumoniae with capsular polysaccharides (CPSs) causes severe nosocomial- and community-acquired infections. Phage-derived depolymerases can degrade CPSs from K. pneumoniae to attenuate bacterial virulence, but their antimicrobial mechanisms and clinical potential are not well understood. In the present study, Klebsiella phage GH-K3-derived depolymerase Depo32 (encoded by gene gp32) was identified to exhibit high efficiency in specifically degrading the CPSs of K2 serotype K. pneumoniae. The cryo-electron microscopy structure of trimeric Depo32 at a resolution up to 2.32 Å revealed potential catalytic centers in the cleft of each of the two adjacent subunits. K. pneumoniae subjected to Depo32 became more sensitive to phagocytosis by RAW264.7 cells and activated the cells by the mitogen-activated protein kinase signaling pathway. In addition, intranasal inoculation with Depo32 (a single dose of 200 µg, 20 µg daily for 3 days, or in combination with gentamicin) rescued all C57BL/6J mice infected with a lethal dose of K. pneumoniae K7 without interference from its neutralizing antibody. In summary, this work elaborates on the mechanism by which Depo32 targets the degradation of K2 serotype CPSs and its potential as an antivirulence agent. IMPORTANCE Depolymerases specific to more than 20 serotypes of Klebsiella spp. have been identified, but most studies only evaluated the single-dose treatment of depolymerases with relatively simple clinical evaluation indices and did not reveal the anti-infection mechanism of these depolymerases in depth. On the basis of determining the biological characteristics, the structure of Depo32 was analyzed by cryo-electron microscopy, and the potential active center was further identified. In addition, the effects of Depo32 on macrophage phagocytosis, signaling pathway activation, and serum killing were revealed, and the efficacy of the depolymerase (single treatment, multiple treatments, or in combination with gentamicin) against acute pneumonia caused by Klebsiella pneumoniae was evaluated. Moreover, the roles of the active sites of Depo32 were also elucidated in the in vitro and in vivo studies. Therefore, through structural biology, cell biology, and in vivo experiments, this study demonstrated the mechanism by which Depo32 targets K2 serotype K. pneumoniae infection.

Klebsiella phage KP34gp57 capsular depolymerase structure and function: from a serendipitous finding to the design of active mini-enzymes against K. pneumoniae.

In this work, we determined the structure of Klebsiella phage KP34p57 capsular depolymerase and dissected the role of individual domains in trimerization and functional activity. The crystal structure serendipitously revealed that the enzyme can exist in a monomeric state once deprived of its C-terminal domain. Based on the crystal structure and site-directed mutagenesis, we localized the key catalytic residues in an intra-subunit deep groove. Consistently, we show that C-terminally trimmed KP34p57 variants are monomeric, stable, and fully active. The elaboration of monomeric, fully active phage depolymerases is innovative in the field, as no previous example exists. Indeed, mini phage depolymerases can be combined in chimeric enzymes to extend their activity ranges, allowing their use against multiple serotypes.