Your search keyword '"BACTERIOPHAGE genetics"' showing total 8 results

1. Cleavage and Structural Transitions during Maturation of Staphylococcus aureus Bacteriophage 80α and SaPI1 Capsids.

Author

Kizziah, James L., Manning, Keith A., Dearborn, Altaira D., Wall, Erin A., Klenow, Laura, Hill, Rosanne L. L., Spilman, Michael S., Stagg, Scott M., Christie, Gail E., and Dokland, Terje

Subjects

*MOLECULAR structure of viral capsids, *STAPHYLOCOCCUS aureus, *BACTERIOPHAGE genetics, *DEVELOPMENTAL biology, *ELECTRON cryomicroscopy

Abstract

In the tailed bacteriophages, DNA is packaged into spherical procapsids, leading to expansion into angular, thin-walled mature capsids. In many cases, this maturation is accompanied by cleavage of the major capsid protein (CP) and other capsid-associated proteins, including the scaffolding protein (SP) that serves as a chaperone for the assembly process. Staphylococcus aureus bacteriophage 80α is capable of high frequency mobilization of mobile genetic elements called S. aureus pathogenicity islands (SaPIs), such as SaPI1. SaPI1 redirects the assembly pathway of 80α to form capsids that are smaller than those normally made by the phage alone. Both CP and SP of 80α are N-terminally processed by a host-encoded protease, Prp. We have analyzed phage mutants that express pre-cleaved or uncleavable versions of CP or SP, and show that the N-terminal sequence in SP is absolutely required for assembly, but does not need to be cleaved in order to produce viable capsids. Mutants with pre-cleaved or uncleavable CP display normal viability. We have used cryo-EM to solve the structures of mature capsids from an 80α mutant expressing uncleavable CP, and from wildtype SaPI1. Comparisons with structures of 80α and SaPI1 procapsids show that capsid maturation involves major conformational changes in CP, consistent with a release of the CP N-arm by SP. The hexamers reorganize during maturation to accommodate the different environments in the 80α and SaPI1 capsids. [ABSTRACT FROM AUTHOR]

Published

2017

2. Branched Lateral Tail Fiber Organization in T5-Like Bacteriophages DT57C and DT571/2 is Revealed by Genetic and Functional Analysis.

Author

Golomidova, Alla K., Kulikov, Eugene E., Prokhorov, Nikolai S., Guerrero-Ferreira, Ricardo C., Knirel, Yuriy A., Kostryukova, Elena S., Tarasyan, Karina K., and Letarov, Andrey V.

Subjects

*BACTERIOPHAGE genetics, *BACTERIAL genetics, *ESCHERICHIA coli, *PHYSIOLOGICAL effects of lipopolysaccharides, *CELL receptors, *ANTIGEN analysis, *CELL physiology

Abstract

The T5-like siphoviruses DT57C and DT571/2, isolated from horse feces, are very closely related to each other, and most of their structural proteins are also nearly identical to T5 phage. Their LTFs (L-shaped tail fibers), however, are composed of two proteins, LtfA and LtfB, instead of the single Ltf of bacteriophage T5. In silico and mutant analysis suggests a possible branched structure of DT57C and DT571/2 LTFs, where the LtfB protein is connected to the phage tail via the LtfA protein and with both proteins carrying receptor recognition domains. Such adhesin arrangement has not been previously recognized in siphoviruses. The LtfA proteins of our phages are found to recognize different host O-antigen types: E. coli O22-like for DT57C phage and E. coli O87 for DT571/2. LtfB proteins are identical in both phages and recognize another host receptor, most probably lipopolysaccharide (LPS) of E. coli O81 type. In these two bacteriophages, LTF function is essential to penetrate the shield of the host's O-antigens. We also demonstrate that LTF-mediated adsorption becomes superfluous when the non-specific cell protection by O-antigen is missing, allowing the phages to bind directly to their common secondary receptor, the outer membrane protein BtuB. The LTF independent adsorption was also demonstrated on an O22-like host mutant missing O-antigen O-acetylation, thus showing the biological value of this O-antigen modification for cell protection against phages. [ABSTRACT FROM AUTHOR]

Published

2016

3. The A, B, Cs of Herpesvirus Capsids.

Author

Tandon, Ritesh, Mocarski, Edward S., and Conway, James F.

Subjects

*NUCLEOCAPSID structure, *HERPESVIRUSES, *BACTERIOPHAGE genetics, *CELL nuclei, *COMMUNICABLE diseases

Abstract

Assembly of herpesvirus nucleocapsids shares significant similarities with the assembly of tailed dsDNA bacteriophages; however, important differences exist. A unique feature of herpesviruses is the presence of different mature capsid forms in the host cell nucleus during infection. These capsid forms, referred to as A-, B-, and C-capsids, represent empty capsids, scaffold containing capsids and viral DNA containing capsids, respectively. The C-capsids are the closest in form to those encapsidated into mature virions and are considered precursors to infectious virus. The evidence supporting A- and B-capsids as either abortive forms or assembly intermediates has been lacking. Interaction of specific capsid forms with viral tegument proteins has been proposed to be a mechanism for quality control at the point of nuclear egress of mature particles. Here, we will review the available literature on these capsid forms and present data to debate whether A- and B-capsids play an important or an extraneous role in the herpesvirus life cycle. [ABSTRACT FROM AUTHOR]

Published

2015

4. Enterococcus faecalis Countermeasures Defeat a Virulent Picovirinae Bacteriophage.

Author

Lossouarn, Julien, Briet, Arnaud, Moncaut, Elisabeth, Furlan, Sylviane, Bouteau, Astrid, Son, Olivier, Leroy, Magali, DuBow, Michael S., Lecointe, François, Serror, Pascale, and Petit, Marie-Agnès

Subjects

*ENTEROCOCCUS faecalis, *BACTERIOPHAGE genetics, *VIRULENCE of bacteria, *LYSIS, *ENTEROCOCCUS

Abstract

Enterococcus faecalis is an opportunistic pathogen that has emerged as a major cause of nosocomial infections worldwide. Many clinical strains are indeed resistant to last resort antibiotics and there is consequently a reawakening of interest in exploiting virulent phages to combat them. However, little is still known about phage receptors and phage resistance mechanisms in enterococci. We made use of a prophageless derivative of the well-known clinical strain E. faecalis V583 to isolate a virulent phage belonging to the Picovirinae subfamily and to the P68 genus that we named Idefix. Interestingly, most isolates of E. faecalis tested—including V583—were resistant to this phage and we investigated more deeply into phage resistance mechanisms. We found that E. faecalis V583 prophage 6 was particularly efficient in resisting Idefix infection thanks to a new abortive infection (Abi) mechanism, which we designated Abiα. It corresponded to the Pfam domain family with unknown function DUF4393 and conferred a typical Abi phenotype by causing a premature lysis of infected E. faecalis. The abiα gene is widespread among prophages of enterococci and other Gram-positive bacteria. Furthermore, we identified two genes involved in the synthesis of the side chains of the surface rhamnopolysaccharide that are important for Idefix adsorption. Interestingly, mutants in these genes arose at a frequency of ~10−4 resistant mutants per generation, conferring a supplemental bacterial line of defense against Idefix. [ABSTRACT FROM AUTHOR]

Published

2019

5. Phage Genetic Engineering Using CRISPR–Cas Systems.

Author

Hatoum-Aslan, Asma

Subjects

*BACTERIOPHAGE genetics, *CRISPRS, *GENOME editing, *VIRAL genes, *PROKARYOTE genetics

Abstract

Since their discovery over a decade ago, the class of prokaryotic immune systems known as CRISPR–Cas have afforded a suite of genetic tools that have revolutionized research in model organisms spanning all domains of life. CRISPR-mediated tools have also emerged for the natural targets of CRISPR–Cas immunity, the viruses that specifically infect bacteria, or phages. Despite their status as the most abundant biological entities on the planet, the majority of phage genes have unassigned functions. This reality underscores the need for robust genetic tools to study them. Recent reports have demonstrated that CRISPR–Cas systems, specifically the three major types (I, II, and III), can be harnessed to genetically engineer phages that infect diverse hosts. Here, the mechanisms of each of these systems, specific strategies used, and phage editing efficacies will be reviewed. Due to the relatively wide distribution of CRISPR–Cas systems across bacteria and archaea, it is anticipated that these immune systems will provide generally applicable tools that will advance the mechanistic understanding of prokaryotic viruses and accelerate the development of novel technologies based on these ubiquitous organisms. [ABSTRACT FROM AUTHOR]

Published

2018

6. Burkholderia cenocepacia Prophages—Prevalence, Chromosome Location and Major Genes Involved.

Author

Roszniowski, Bartosz, McClean, Siobhán, and Drulis-Kawa, Zuzanna

Subjects

*BURKHOLDERIA cenocepacia, *BACTERIOPHAGE genetics, *MICROBIAL virulence, *HORIZONTAL gene transfer, *GRAM-negative bacteria, *CRISPRS, *DRUG resistance in bacteria

Abstract

Burkholderia cenocepacia, is a Gram-negative opportunistic pathogen that belongs to Burkholderia cepacia complex (BCC) group. BCC representatives carry various pathogenicity factors and can infect humans and plants. Phages as bacterial viruses play a significant role in biodiversity and ecological balance in the environment. Specifically, horizontal gene transfer (HGT) and lysogenic conversion (temperate phages) influence microbial diversification and fitness. In this study, we describe the prevalence and gene content of prophages in 16 fully sequenced B. cenocepacia genomes stored in NCBI database. The analysis was conducted in silico by manual and automatic approaches. Sixty-three potential prophage regions were found and classified as intact, incomplete, questionable, and artifacts. The regions were investigated for the presence of known virulence factors, resulting in the location of sixteen potential pathogenicity mechanisms, including toxin–antitoxin systems (TA), Major Facilitator Superfamily (MFS) transporters and responsible for drug resistance. Investigation of the region’s closest neighborhood highlighted three groups of genes with the highest occurrence—tRNA-Arg, dehydrogenase family proteins, and ABC transporter substrate-binding proteins. Searches for antiphage systems such as BacteRiophage EXclusion (BREX) and Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) in the analyzed strains suggested 10 sequence sets of CRISPR elements. Our results suggest that intact B. cenocepacia prophages may provide an evolutionary advantage to the bacterium, while domesticated prophages may help to maintain important genes. [ABSTRACT FROM AUTHOR]

Published

2018

7. In Vitro Studies of Lipopolysaccharide-Mediated DNA Release of Podovirus HK620.

Author

Broeker, Nina K., Kiele, Franziska, Casjens, Sherwood R., Gilcrease, Eddie B., Thalhammer, Anja, Koetz, Joachim, and Barbirz, Stefanie

Subjects

*LIPOPOLYSACCHARIDES, *IN vitro studies, *PODOVIRIDAE, *DNA, *BACTERIOPHAGE genetics, *POLYSACCHARIDES, *VIRULENCE of Escherichia coli, *GRAM-negative bacteria

Abstract

Gram-negative bacteria protect themselves with an outermost layer containing lipopolysaccharide (LPS). O-antigen-specific bacteriophages use tailspike proteins (TSP) to recognize and cleave the O-polysaccharide part of LPS. However, O-antigen composition and structure can be highly variable depending on the environmental conditions. It is important to understand how these changes may influence the early steps of the bacteriophage infection cycle because they can be linked to changes in host range or the occurrence of phage resistance. In this work, we have analyzed how LPS preparations in vitro trigger particle opening and DNA ejection from the E. coli podovirus HK620. Fluorescence-based monitoring of DNA release showed that HK620 phage particles in vitro ejected their genome at velocities comparable to those found for other podoviruses. Moreover, we found that HK620 irreversibly adsorbed to the LPS receptor via its TSP at restrictive low temperatures, without opening the particle but could eject its DNA at permissive temperatures. DNA ejection was solely stimulated by LPS, however, the composition of the O-antigen dictated whether the LPS receptor could start the DNA release from E. coli phage HK620 in vitro. This finding can be significant when optimizing bacteriophage mixtures for therapy, where in natural environments O-antigen structures may rapidly change. [ABSTRACT FROM AUTHOR]

Published

2018

8. The Auxiliary Role of the Amidase Domain in Cell Wall Binding and Exolytic Activity of Staphylococcal Phage Endolysins.

Author

Son, Bokyung, Kong, Minsuk, and Ryu, Sangryeol

Subjects

*AMIDASES, *BACTERIAL cell walls, *BINDING sites, *STAPHYLOCOCCUS aureus, *BACTERIOPHAGE genetics, *CHIMERIC proteins, *CLONING, *GENE expression

Abstract

In response to increasing concern over antibiotic-resistant Staphylococcus aureus, the development of novel antimicrobials has been called for, with bacteriophage endolysins having received considerable attention as alternatives to antibiotics. Most staphylococcal phage endolysins have a modular structure consisting of an N-terminal cysteine, histidine-dependent amidohydrolases/peptidase domain (CHAP), a central amidase domain, and a C-terminal cell wall binding domain (CBD). Despite extensive studies using truncated staphylococcal endolysins, the precise function of the amidase domain has not been determined. Here, a functional analysis of each domain of two S. aureus phage endolysins (LysSA12 and LysSA97) revealed that the CHAP domain conferred the main catalytic activity, while the central amidase domain showed no enzymatic activity in degrading the intact S. aureus cell wall. However, the amidase-lacking endolysins had reduced hydrolytic activity compared to the full-length endolysins. Comparison of the binding affinities of fusion proteins consisting of the green fluorescent protein (GFP) with CBD and GFP with the amidase domain and CBD revealed that the major function of the amidase domain was to enhance the binding affinity of CBD, resulting in higher lytic activity of endolysin. These results suggest an auxiliary binding role of the amidase domain of staphylococcal endolysins, which can be useful information for designing effective antimicrobial and diagnostic agents against S. aureus. [ABSTRACT FROM AUTHOR]

Published

2018