Complete genome sequence analysis of bacterial-flagellum-targeting bacteriophage chi

Bacteriophage chi is a well-known phage that infects pathogens such as E. coli, Salmonella, and Serratia via bacterial flagella. To further understand its host-phage interaction and infection mechanism via host flagella, the genome was completely sequenced and analyzed. The phage genome contains 59,407-bp-length DNA with a GC content of 56.51 %, containing 75 open reading frames (ORFs) with no tRNA genes. Its annotation and functional analysis revealed that chi is evolutionarily very closely related to Enterobacter phage Enc34 and Providencia phage Redjac. However, most of the annotated genes encode hypothetical proteins, indicating that further genomic study of phage chi is required to elucidate the bacterial-flagellum-targeting infection mechanism of phage chi.     

Complete genome sequence of the Pectobacterium carotovorum subsp. carotovorum virulent bacteriophage PM1

PM1, a novel virulent bacteriophage that infects Pectobacterium carotovorum subsp. carotovorum, was isolated. Its morphological features were examined by electron microscopy, which indicated that this phage belongs to the family Myoviridae. It has a 55,098-bp genome, including a 2,665-bp terminal repeat. A total of 63 open reading frames (ORFs) were predicted, but only 20 ORFs possessed homology with functional proteins. There is one tRNA coding region, and the GC-content of the genome is 44.9 %. Most ORFs in bacteriophage PM1 showed high homology to enterobacteria phage ΦEcoM-GJ1 and Erwinia phage νB EamM-Y2. Like these bacteriophages, PM1 encodes an RNA polymerase, which is a hallmark of T7-like phages. There is no integrase or repressor, suggesting that PM1 is a virulent bacteriophage.     

Coping with cold: the genome of the versatile marine Antarctica bacterium Pseudoalteromonas haloplanktis TAC125

A considerable fraction of life develops in the sea at temperatures lower than 15 degrees C. Little is known about the adaptive features selected under those conditions. We present the analysis of the genome sequence of the fast growing Antarctica bacterium Pseudoalteromonas haloplanktis TAC125. We find that it copes with the increased solubility of oxygen at low temperature by multiplying dioxygen scavenging while deleting whole pathways producing reactive oxygen species. Dioxygen-consuming lipid desaturases achieve both protection against oxygen and synthesis of lipids making the membrane fluid. A remarkable strategy for avoidance of reactive oxygen species generation is developed by P. haloplanktis, with elimination of the ubiquitous molybdopterin-dependent metabolism. The P. haloplanktis proteome reveals a concerted amino acid usage bias specific to psychrophiles, consistently appearing apt to accommodate asparagine, a residue prone to make proteins age. Adding to its originality, P. haloplanktis further differs from its marine counterparts with recruitment of a plasmid origin of replication for its second chromosome.     

Anti-biofilm activity of the Antarctic marine bacterium Pseudoalteromonas haloplanktis TAC125

Considering the increasing impact of bacterial biofilms on human health, industrial and food-processing activities, the interest in the development of new approaches for the prevention and treatment of adhesion and biofilm formation capabilities has increased. A viable approach should target adhesive properties without affecting bacterial vitality in order to avoid the rapid appearance of escape mutants.It is known that marine bacteria belonging to the genus Pseudoalteromonas produce compounds of biotechnological interest, including anti-biofilm molecules. Pseudoalteromonas haloplanktis TAC125 is the first Antarctic Gram-negative strain whose genome was sequenced. In this work the anti-biofilm activity of P. haloplanktis supernatant was examined on different staphylococci. Results obtained demonstrated that supernatant of P. haloplanktis, grown in static condition, inhibits biofilm of Staphylococcus epidermidis. In order to define the chemical nature of the biofilm-inhibiting compound, the supernatant was subject to various treatments. Data reported demonstrated that the biologically active component is sensible to treatment with sodium periodate suggesting its saccharidic nature.     

Complete genome sequence of virulent bacteriophage SHOU24, which infects foodborne pathogenic Vibrio parahaemolyticus

A novel lytic Vibrio parahaemolyticus phage (SHOU24) belonging to the family Siphoviridae was isolated from aquatic market sewage. The phage is only able to infect V. parahaemolyticus containing a tdh gene. SHOU24 has a linear genome of 77,837 bp with a G+C content of 46.0 %. In total, 88 predicted proteins have homologues in databases, and the majority of the core genes share high sequence similarity with genes from unrelated viruses and bacteria. Genes related to lysogeny and host lysis were not detected. However, the detection method, the results of a one-step growth experiment and analysis using the Phage Classification Tool Set (PHACTS) indicate that SHOU24 is lytic. A bioinformatics analysis showed that SHOU24 is not closely related to other Vibrio phages.     

Complete nucleotide sequence of the genome of coxsackievirus B1

The complete nucleotide sequence of the genome of the coxsackievirus B1, a human enterovirus that belongs to the Picornaviridae, was determined by using molecular cloning and rapid sequence analysis techniques. Sequence analysis of the cloned cDNAs revealed that the virion RNA was 7389 nucleotides long and polyadenylylated at the 3' terminus. Similar to other picornavirus genomes, a single large open reading frame was identified. The translated sequence starts at nucleotide position 742 and ends at 7287 of the genome. Thus, the viral polyprotein should consist of 2182 amino acids. When the predicted amino acid sequence of the viral polyprotein was compared with those of other human enteroviruses such as polioviruses, a striking sequence homology was observed, especially in viral proteins 1B, 2C, and 3D. This allowed us to predict precise map locations of the viral structural and nonstructural proteins on the genome, although two proteolytic processing sites, between 1D and 2A and between 2B and 2C, were obscure. The result presented here implied important information with respect to the genetical variation of human enteroviruses.     

Complete genomic sequence of the Vibrio alginolyticus lytic bacteriophage PVA1

A novel Vibrio alginolyticus lytic bacteriophage was isolated from sewage samples obtained from a local aquatic market. Morphological analysis revealed that the phage, designated as PVA1, belonged to the family Podoviridae. The complete genomic sequence of phage PVA1 contained 41,529 bp with a G + C content of 43.7 % and 75 putative open reading frames. The genome was grouped into four modules, including phage structure, DNA packaging, DNA replication and regulation, and some additional functions. Further genomic comparison of the phage PVA1 with other known phages showed no significant similarities. Genes related to virulence and lysogeny were not detected in the phage genome. Our results suggest that phage PVA1 may be classified as a new Vibrio phage. We believe that these phage genomic sequence data will provide useful basic information for further molecular research on this Vibrio phage and its host as well for determining its infection/interaction mechanisms.     

Complete genome sequence of the lytic cold-active Pseudomonas fluorescens bacteriophage VSW-3 from Napahai plateau wetland

Virus Genes - The lytic cold-active bacteriophage VSW-3, belonging to the Podoviridae family and infecting the host Pseudomonas fluorescens SW-3, was isolated from the Napahai plateau wetland in...     

Complete genomic sequence of the lytic bacteriophage DT1 of Streptococcus thermophilus

Streptococcus thermophilus lytic bacteriophage DT1, isolated from a mozzarella whey, was characterized at the microbiological and molecular levels. Phage DT1 had an isometric head of 60 nm and a noncontractile tail of 260 x 8 nm, two major structural proteins of 26 and 32 kDa, and a linear double-stranded DNA genome with cohesive ends at its extremities. The host range of phage DT1 was limited to 5 of the 21 S. thermophilus strains tested. Using S. thermophilus SMQ-301 as a host, phage DT1 had a burst size of 276 +/- 36 and a latent period of 25 min. The genome of phage DT1 contained 34,820 bp with a GC content of 39.1%. Forty-six open reading frames (ORFs) of more than 40 codons were found and putative functions were assigned to 20 ORFs, mostly in the late region of phage DT1. Comparative genomic analysis of DT1 with the completely sequenced S. thermophilus temperate phage O1205 revealed two large homologous regions interspersed by two heterologous segments. The homologous regions consisted of the early replication genes, the late morphogenesis genes, and the lysis cassette. The divergent segments contained the DNA packaging machinery, the major structural proteins, and remnants of a lysogeny module.     

Complete genome sequence of arracacha mottle virus

Arracacha mottle virus (AMoV) is the only potyvirus reported to infect arracacha (Arracacia xanthorrhiza) in Brazil. Here, the complete genome sequence of an isolate of AMoV was determined to be 9,630 nucleotides in length, excluding the 3′ poly-A tail, and encoding a polyprotein of 3,135 amino acids and a putative P3N-PIPO protein. Its genomic organization is typical of a member of the genus Potyvirus, containing all conserved motifs. Its full genome sequence shared 56.2 % nucleotide identity with sunflower chlorotic mottle virus and verbena virus Y, the most closely related viruses.     

Complete genome sequence of turnip ringspot virus

Here we present the complete genome sequences of two TuRSV isolates. They are 90–100% identical in distinct genes, but reasonably less identical with RaMV isolates. Regarding the CPs, TuRSV and RaMV have an aa sequence identity of 72–74% among all isolates and the proposed cut-off level is 75%. For the proteinase–polymerase region, the average value between the two isolates of TuRSV and three isolates of RaMV is 79.8% and the cut-off level is 80%. At the moment, TuRSV and RaMV are the two identified species most closely related within the genus Comovirus.     

Complete genome sequence of a polyvalent bacteriophage, phiKP26, active on Salmonella and Escherichia coli

Bacteriophages are viruses that specifically infect and lyse prokaryotic cells and therefore might be used as biocontrol agents. However, it is necessary to acquire genomic information to predict and understand the phage’s characteristics for the efficient and safe use of bacteriophages as biocontrol agents against bacterial pathogens. In this study, the complete genome sequence of a novel enterobacteriophage, phiKP26, was determined by pyrosequencing. Genomic analysis of phiKP26 revealed a genome size of 47,285 bp with an overall G + C content of 44.3 %. Seventy-eight open reading frames (ORFs) in the phiKP26 genome were grouped into the modules of replication, DNA packaging, morphogenesis, cell lysis and absence of genes related to virulence and lysogeny.     

Complete genome sequence of 285P,a novel T7-like polyvalent E. coli bacteriophage

Bacteriophages are considered potential biological agents for the control of infectious diseases and environmental disinfection. Here, we describe a novel T7-like polyvalent Escherichia coli bacteriophage, designated “285P,” which can lyse several strains of E. coli. The genome, which consists of 39,270 base pairs with a G+C content of 48.73 %, was sequenced and annotated. Forty-three potential open reading frames were identified using bioinformatics tools. Based on whole-genome sequence comparison, phage 285P was identified as a novel strain of subgroup T7. It showed strongest sequence similarity to Kluyvera phage Kvp1. The phylogenetic analyses of both non-structural proteins (endonuclease gp3, amidase gp3.5, DNA primase/helicase gp4, DNA polymerase gp5, and exonuclease gp6) and structural protein (tail fiber protein gp17) led to the identification of 285P as T7-like phage. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and matrix-assisted laser desorption/ionization time-of-flight mass spectrometric analyses verified the annotation of the structural proteins (major capsid protein gp10a, tail protein gp12, and tail fiber protein gp17).