Your search keyword '"Gencay, Yilmaz Emre"' showing total 10 results

1. Campycins are novel broad-spectrum antibacterials killing Campylobacter jejuni.

Author

Zampara, Athina, Gencay, Yilmaz Emre, Brøndsted, Lone, and Sørensen, Martine Camilla Holst

Subjects

MEMBRANE proteins, CARRIER proteins, AMINO acid sequence, BINDING sites, SEQUENCE alignment, CAMPYLOBACTER jejuni

Abstract

Pyocins are high molecular weight bacteriocins produced by Pseudomonas aeruginosa that can be retargeted to new bacterial species by exchanging the pyocin tail fibers with bacteriophage receptor binding proteins (RBPs). Here, we develop retargeted pyocins called campycins as new antibacterials to precisely and effectively kill the major foodborne pathogen Campylobacter jejuni. We used two diverse RBPs (H-fibers) encoded by CJIE1 prophages found in the genomes of C. jejuni strains CAMSA2147 and RM1221 to construct campycin 1 and campycin 2, respectively. Campycins 1 and 2 could target all C. jejuni strains tested due to complementary antibacterial spectra. In addition, both campycins led to more than 3 log reductions in C. jejuni counts under microaerobic conditions at 42 °C, whereas the killing efficiency was less efficient under anaerobic conditions at 5 °C. Furthermore, we discovered that both H-fibers used to construct the campycins bind to the essential major outer membrane protein (MOMP) present in all C. jejuni in a strain-specific manner. Protein sequence alignment and structural modeling suggest that the highly variable extracellular loops of MOMP form the binding sites of the diverse H-fibers. Further in silico analyses of 5000 MOMP sequences indicated that the protein falls into three major clades predicted to be targeted by either campycin 1 or campycin 2. Thus, campycins are promising antibacterials against C. jejuni and are expected to broadly target numerous strains of this human pathogen in nature and agriculture. Key points: • Campycins are engineered R-type pyocins containing H-fibers from C. jejuni prophages • Campycins reduce C. jejuni counts by >3 logs at conditions promoting growth • Campycins bind to the essential outer membrane protein MOMP in a strain-dependent way [ABSTRACT FROM AUTHOR]

Published

2024

2. Engineered phage with antibacterial CRISPR–Cas selectively reduce E. coli burden in mice.

Author

Gencay, Yilmaz Emre, Jasinskytė, Džiuginta, Robert, Camille, Semsey, Szabolcs, Martínez, Virginia, Petersen, Anders Østergaard, Brunner, Katja, de Santiago Torio, Ana, Salazar, Alex, Turcu, Iszabela Cristiana, Eriksen, Melissa Kviesgaard, Koval, Lev, Takos, Adam, Pascal, Ricardo, Schou, Thea Staffeldt, Bayer, Lone, Bryde, Tina, Johansen, Katja Chandelle, Bak, Emilie Glad, and Smrekar, Frenk

Abstract

Antibiotic treatments have detrimental effects on the microbiome and lead to antibiotic resistance. To develop a phage therapy against a diverse range of clinically relevant Escherichia coli, we screened a library of 162 wild-type (WT) phages, identifying eight phages with broad coverage of E. coli, complementary binding to bacterial surface receptors, and the capability to stably carry inserted cargo. Selected phages were engineered with tail fibers and CRISPR–Cas machinery to specifically target E. coli. We show that engineered phages target bacteria in biofilms, reduce the emergence of phage-tolerant E. coli and out-compete their ancestral WT phages in coculture experiments. A combination of the four most complementary bacteriophages, called SNIPR001, is well tolerated in both mouse models and minipigs and reduces E. coli load in the mouse gut better than its constituent components separately. SNIPR001 is in clinical development to selectively kill E. coli, which may cause fatal infections in hematological cancer patients. Phage engineered with tail fibers and CRISPR–Cas reduce Escherichia coli load in animals. [ABSTRACT FROM AUTHOR]

Published

2024

3. Identification of Novel Phage Resistance Mechanisms in Campylobacter jejuni by Comparative Genomics.

Author

Sørensen, Martine C. H., Gencay, Yilmaz Emre, Fanger, Florian, Chichkova, Mariana A. T., Mazúrová, Mária, Klumpp, Jochen, Nielsen, Eva M., and Brøndsted, Lone

Subjects

CAMPYLOBACTER jejuni, COMPARATIVE genomics, POULTRY farms, BACTERIOPHAGES, CRISPRS

Abstract

Phages infecting Campylobacter jejuni are considered a promising intervention strategy at broiler farms, yet phage sensitivity of naturally occurring poultry isolates is not well studied. Here, we investigated phage sensitivity and identified resistance mechanisms of C. jejuni strains originating from Danish broilers belonging to the most prevalent MLST (ST) types. Determining plaque formation of 51 phages belonging to Fletchervirus or Firehammervirus showed that 21 out of 31 C. jejuni strains were susceptible to at least one phage. While C. jejuni ST-21 strains encoded the common phase variable O -methyl phosphoramidate (MeO P N) receptor of the Fletchervirus and were only infected by these phages, ST-45 strains did not encode this receptor and were exclusively infected by Firehammervirus phages. To identify internal phage resistance mechanism in ST-21 strains, we performed comparative genomics of two strains, CAMSA2002 sensitive to almost all Fletchervirus phages and CAMSA2038, resistant to all 51 phages. The strains encoded diverse clustered regularly interspaced short palindromic repeats (CRISPR) spacers but none matched the tested phages. Sequence divergence was also observed in a predicted SspE homolog and putative restriction modification systems including a methyl-specific McrBC endonuclease. Furthermore, when mcrB was deleted, CAMSA2038 became sensitive to 17 out of 43 phages, three being Firehammervirus phages that otherwise did not infect any ST-21 strains. Yet, 16 phages demonstrated significantly lower efficiencies of plating on the mcrB mutant suggesting additional resistance mechanism still restricting phage propagation in CAMSA2038. Thus, our work demonstrates that C. jejuni isolates originating from broilers may have acquired several resistance mechanisms to successfully prevent phage infection in their natural habitat. [ABSTRACT FROM AUTHOR]

Published

2021

4. Developing Innolysins Against Campylobacter jejuni Using a Novel Prophage Receptor-Binding Protein.

Author

Zampara, Athina, Sørensen, Martine C. Holst, Gencay, Yilmaz Emre, Grimon, Dennis, Kristiansen, Sebastian Hougaard, Jørgensen, Lallana Skaarup, Kristensen, Josephine Rejgaard, Briers, Yves, Elsser-Gravesen, Anne, and Brøndsted, Lone

Subjects

CAMPYLOBACTER jejuni, CARRIER proteins, CAMPYLOBACTER, BACTERIOPHAGES, PROTEIN receptors, FLAGELLA (Microbiology)

Abstract

Campylobacter contaminated poultry remains the major cause of foodborne gastroenteritis worldwide, calling for novel antibacterials. We previously developed the concept of Innolysin composed of an endolysin fused to a phage receptor binding protein (RBP) and provided the proof-of-concept that Innolysins exert bactericidal activity against Escherichia coli. Here, we have expanded the Innolysin concept to target Campylobacter jejuni. As no C. jejuni phage RBP had been identified so far, we first showed that the H-fiber originating from a CJIE1-like prophage of C. jejuni CAMSA2147 functions as a novel RBP. By fusing this H-fiber to phage T5 endolysin, we constructed Innolysins targeting C. jejuni (Innolysins Cj). Innolysin Cj1 exerts antibacterial activity against diverse C. jejuni strains after in vitro exposure for 45 min at 20°C, reaching up to 1.30 ± 0.21 log reduction in CAMSA2147 cell counts. Screening of a library of Innolysins Cj composed of distinct endolysins for growth inhibition, allowed us to select Innolysin Cj5 as an additional promising antibacterial candidate. Application of either Innolysin Cj1 or Innolysin Cj5 on chicken skin refrigerated to 5°C and contaminated with C. jejuni CAMSA2147 led to 1.63 ± 0.46 and 1.18 ± 0.10 log reduction of cells, respectively, confirming that Innolysins Cj can kill C. jejuni in situ. The receptor of Innolysins Cj remains to be identified, however, the RBP component (H-fiber) recognizes a novel receptor compared to lytic phages binding to capsular polysaccharide or flagella. Identification of other unexplored Campylobacter phage RBPs may further increase the repertoire of new Innolysins Cj targeting distinct receptors and working as antibacterials against Campylobacter. [ABSTRACT FROM AUTHOR]

Published

2021

5. The genera of bacteriophages and their receptors are the major determinants of host range.

Author

Gencay, Yilmaz Emre, Gambino, Michela, Prüssing, Tessa From, and Brøndsted, Lone

Subjects

BACTERIOPHAGES, BACTERIAL ecology, BACTERIAL evolution, CARRIER proteins, ENVIRONMENTAL sampling

Abstract

Summary: The host range of phages is a key to understand their impact on bacterial ecology and evolution. Because of the complexity of phage–host interactions, the variables that determine the breadth of a phage host range remain poorly understood. Here, we propose a novel holistic approach to identify the host range determinants of a new collection of phages infecting Salmonella, isolated from animal, environmental and wastewater samples that were able to infect 58 of the 71 Salmonella strains in our collection. By using a set of statistic approaches (non‐metric dimensional scaling, Bray–Curtis distance, PERMANOVA), we analysed phenotypic (host range on wild‐type and receptor mutants) and genetic data (taxonomic assignment and receptor binding proteins) to evaluate the impact of isolation strain and niche, phage receptor and genus on the host range. Statistical analysis revealed that two phage characteristics influence the host range by explaining the most variance: the receptor by 45% and the genus by 51%. Interestingly, phage genus and receptor in combination explained 79% of the variance, establishing these characteristics as the major determinants of the host range. This study demonstrates the power and the novelty of applying statistical approaches to phenotypic and genetic data to investigate the ecology of phage–host interactions. [ABSTRACT FROM AUTHOR]

Published

2019

6. Phase Variable Expression of a Single Phage Receptor in Campylobacter jejuni NCTC12662 Influences Sensitivity Toward Several Diverse CPS-Dependent Phages.

Author

Gencay, Yilmaz Emre, Sørensen, Martine C. H., Wenzel, Cory Q., Szymanski, Christine M., and Brøndsted, Lone

Subjects

CAMPYLOBACTER jejuni, PATHOGENIC microorganisms

Abstract

Campylobacter jejuni NCTC12662 is sensitive to infection by many Campylobacter bacteriophages. Here we used this strain to investigate the molecular mechanism behind phage resistance development when exposed to a single phage and demonstrate how phase variable expression of one surface component influences phage sensitivity against many diverse C. jejuni phages. When C. jejuni NCTC12662 was exposed to phage F207 overnight, 25% of the bacterial cells were able to grow on a lawn of phage F207, suggesting that resistance develops at a high frequency. One resistant variant, 12662R, was further characterized and shown to be an adsorption mutant. Plaque assays using our large phage collection showed that seven out of 36 diverse capsular polysaccharide (CPS)-dependent phages could not infect 12662R, whereas the remaining phages formed plaques on 12662R with reduced efficiencies. Analysis of the CPS composition of 12662R by high-resolution magic angle spinning nuclear magnetic resonance (HR-MAS NMR) showed a diminished signal for O-methyl phosphoramidate (MeOPN), a phase variable modification of the CPS. This suggested that the majority of the 12662R population did not express this phase variable modification in the CPS, indicating that MeOPN serves as a phage receptor in NCTC12662. Whole genome analysis of 12662R showed a switch in the length of the phase variable homopolymeric G tract of gene 06810, encoding a putative MeOPN-transferase located in the CPS locus, resulting in a non-functional protein. To confirm the role of 06810 in phage resistance development of NCTC12662, a 06810 knockoutmutant in NCTC12662 was constructed and analyzed by HR-MAS NMR demonstrating the absence of MeOPN in the CPS of the mutant. Plaque assays using NCTC12662106810 demonstrated that seven of our CPS-dependent Campylobacter phages are dependent on the presence of MeOPN for successful infection of C. jejuni, whereas the remaining 29 phages infect independently of MeOPN, although with reduced efficiencies. Our data indicate that CPS-dependent phages uses diverse mechanisms for their initial interaction with their C. jejuni host. [ABSTRACT FROM AUTHOR]

Published

2018

7. Biocontrol of Shiga Toxigenic Escherichia coli O157:H7 in Turkish Raw Meatball by Bacteriophage.

Author

Gencay, Yilmaz Emre, Ayaz, Naim Deniz, Copuroglu, Gizem, and Erol, Irfan

Subjects

VEROCYTOTOXINS, ESCHERICHIA coli, MEATBALLS, MEAT storage, FOOD pathogens, BIOLOGICAL pest control, BACTERIOPHAGES

Abstract

With an E scherichia coli O157:H7 virulent bacteriophage, M8AEC16, biocontrol efficiency of phages on a highly risky, ready-to-eat, traditional delicacy food called 'raw meatball' under different storage conditions was investigated. Phage, belonging to the M yoviridae family, was isolated from the wastewater of a local slaughterhouse and showed a broad lytic activity toward many E . coli O157:H7 strains with high efficiency of plating and O157 specificity. Our experimental study provided favorable results, with 0.69-2.09 log colony-forming unit (cfu)/g E . coli O157:H7 reductions in the first 5 h of the replica trials. Major reductions of viable E . coli O157:H7 counts were observed in the beginning of the storage period, reaching up to 1.85 log cfu/g. Although a significant reduction in E . coli O157:H7 was observed with increased phage concentration, storage conditions had minor effect on efficiency of phage biocontrol. This is the first study in Turkey that investigates applicability of phage biocontrol for a traditional food model. Practical Applications Phage addition in preparation stage of a very complex food model, ready-to-eat Turkish raw meatball, is a promising application in decontamination of E scherichia coli O157:H7. Although investigation of its genomic characteristics along with its stability to different food matrices must be completed for further use of the model phage M8AEC16, findings of this work were encouraging, as phages are valuable in biocontrol of important foodborne in this ready-to-eat Turkish delicacy. [ABSTRACT FROM AUTHOR]

Published

2016

8. Primary Isolation Strain Determines Both Phage Type and Receptors Recognised by Campylobacter jejuni Bacteriophages.

Author

Sørensen, Martine C. Holst, Gencay, Yilmaz Emre, Birk, Tina, Baldvinsson, Signe Berg, Jäckel, Claudia, Hammerl, Jens A., Vegge, Christina S., Neve, Horst, and Brøndsted, Lone

Subjects

CAMPYLOBACTER jejuni, BACTERIOPHAGES, ZOONOSES, BIOINDICATORS, GENETIC mutation, HOSTS (Biology)

Abstract

In this study we isolated novel bacteriophages, infecting the zoonotic bacterium Campylobacter jejuni. These phages may be used in phage therapy of C. jejuni colonized poultry to prevent spreading of the bacteria to meat products causing disease in humans. Many C. jejuni phages have been isolated using NCTC12662 as the indicator strain, which may have biased the selection of phages. A large group of C. jejuni phages rely on the highly diverse capsular polysaccharide (CPS) for infection and recent work identified the O-methyl phosphoramidate modification (MeOPN) of CPS as a phage receptor. We therefore chose seven C. jejuni strains each expressing different CPS structures as indicator strains in a large screening for phages in samples collected from free-range poultry farms. Forty-three phages were isolated using C. jejuni NCTC12658, NCTC12662 and RM1221 as host strains and 20 distinct phages were identified based on host range analysis and genome restriction profiles. Most phages were isolated using C. jejuni strains NCTC12662 and RM1221 and interestingly phage genome size (140 kb vs. 190 kb), host range and morphological appearance correlated with the isolation strain. Thus, according to C. jejuni phage grouping, NCTC12662 and NCTC12658 selected for CP81-type phages, while RM1221 selected for CP220-type phages. Furthermore, using acapsular ∆kpsM mutants we demonstrated that phages isolated on NCTC12658 and NCTC12662 were dependent on the capsule for infection. In contrast, CP220-type phages isolated on RM1221 were unable to infect non-motile ∆motA mutants, hence requiring motility for successful infection. Hence, the primary phage isolation strain determines both phage type (CP81 or CP220) as well as receptors (CPS or flagella) recognised by the isolated phages. [ABSTRACT FROM AUTHOR]

Published

2015

9. Serotype identification and antimicrobial resistance profiles of Salmonella spp. isolated from chicken carcasses.

Author

Dogru, Aylin Kasimoglu, Ayaz, Naim Deniz, and Gencay, Yilmaz Emre

Abstract

In this study, 32 Salmonella strains isolated from 400 chicken carcasses were serotyped, and antibiotic resistance profiles were detected against 12 selected antimicrobial agents using disc diffusion method. Thirty-two isolates were identified as follows; 22 (68.7%) Salmonella Enteritidis, five (15.6%) Salmonella Virchow, three (9.3%) Salmonella Typhimurium and two (6.2%) Salmonella Hadar. In all Salmonella isolates, antibiotic resistance were detected. Out of 32 Salmonella strains, 22 (68.75%) displayed multi-drug resistance. Thirty-two (100.0%) of the isolates were found to be resistant to penicillin G, 20 (62.5%) to nalidixic acid, four (12.5%) to cephalothin, two (6.2%) to streptomycin and two (6.2%) to tetracycline. Fifteen (68.1%) Salmonella Enteritidis, one (33.3%) Salmonella Typhimurium, two (100.0%) Salmonella Hadar and two (40.0%) Salmonella Virchow were shown to be resistant to nalidixic acid. Cephalothin resistance was detected in 9.0%, 33.3%, and 20.0% for Salmonella Enteritidis, Salmonella Typhimurium and Salmonella Virchow, respectively. The results indicate that Salmonella recovered from chicken carcasses were resistant to multiple antimicrobials and that resistance among these isolates varies by serotype. Also, this emerged as a significant public health problem. [ABSTRACT FROM AUTHOR]

Published

2010

10. Phage S144, a New Polyvalent Phage Infecting Salmonella spp. and Cronobacter sakazakii.

Author

Gambino, Michela, Nørgaard Sørensen, Anders, Ahern, Stephen, Smyrlis, Georgios, Gencay, Yilmaz Emre, Hendrix, Hanne, Neve, Horst, Noben, Jean-Paul, Lavigne, Rob, and Brøndsted, Lone

Subjects

CRONOBACTER, SALMONELLA, EPINEPHELUS, TRANSMISSION electron microscopy, CYTOSKELETAL proteins, BACTERIOPHAGES

Abstract

Phages are generally considered species- or even strain-specific, yet polyvalent phages are able to infect bacteria from different genera. Here, we characterize the novel polyvalent phage S144, a member of the Loughboroughvirus genus. By screening 211 Enterobacteriaceae strains, we found that phage S144 forms plaques on specific serovars of Salmonellaenterica subsp. enterica and on Cronobacter sakazakii. Analysis of phage resistant mutants suggests that the O-antigen of lipopolysaccharide is the phage receptor in both bacterial genera. The S144 genome consists of 53,628 bp and encodes 80 open reading frames (ORFs), but no tRNA genes. In total, 32 ORFs coding for structural proteins were confirmed by ESI-MS/MS analysis, whereas 45 gene products were functionally annotated within DNA metabolism, packaging, nucleotide biosynthesis and phage morphogenesis. Transmission electron microscopy showed that phage S144 is a myovirus, with a prolate head and short tail fibers. The putative S144 tail fiber structure is, overall, similar to the tail fiber of phage Mu and the C-terminus shows amino acid similarity to tail fibers of otherwise unrelated phages infecting Cronobacter. Since all phages in the Loughboroughvirus genus encode tail fibers similar to S144, we suggest that phages in this genus infect Cronobacter sakazakii and are polyvalent. [ABSTRACT FROM AUTHOR]

Published

2020