Complete genome sequence of the giant Pseudomonas phage Lu11

The complete genome sequence of the giant Pseudomonas phage Lu11 was determined, comparing 454 and Sanger sequencing. The double-stranded DNA (dsDNA) genome is 280,538 bp long and encodes 391 open reading frames (ORFs) and no tRNAs. The closest relative is Ralstonia phage φRSL1, encoding 40 similar proteins. As such, Lu11 can be considered phylogenetically unique within the Myoviridae and indicates the diversity of the giant phages within this family.     

Complete Genomic Sequence of Bacteriophage φEcoM-GJ1, a Novel Phage That Has Myovirus Morphology and a Podovirus-Like RNA Polymerase

The complete genome of EcoM-GJ1, a lytic phage that attacks porcine enterotoxigenic Escherichia coli of serotype O149:H10:F4, was sequenced and analyzed. The morphology of the phage and the identity of the structural proteins were also determined. The genome consisted of 52,975 bp with a G+C content of 44% and was terminally redundant and circularly permuted. Seventy-five potential open reading frames (ORFs) were identified and annotated, but only 29 possessed homologs. The proteins of five ORFs showed homology with proteins of phages of the family Myoviridae, nine with proteins of phages of the family Podoviridae, and six with proteins of phages of the family Siphoviridae. ORF 1 encoded a T7-like single-subunit RNA polymerase and was preceded by a putative E. coli σ⁷⁰-like promoter. Nine putative phage promoters were detected throughout the genome. The genome included a tRNA gene of 95 bp that had a putative 18-bp intron. The phage morphology was typical of phages of the family Myoviridae, with an icosahedral head, a neck, and a long contractile tail with tail fibers. The analysis shows that EcoM-GJ1 is unique, having the morphology of the Myoviridae, a gene for RNA polymerase, which is characteristic of phages of the T7 group of the Podoviridae, and several genes that encode proteins with homology to proteins of phages of the family Siphoviridae.     

Campylobacter group II phage CP21 is the prototype of a new subgroup revealing a distinct modular genome organization and host specificity

Background

The application of phages is a promising tool to reduce the number of Campylobacter along the food chain. Besides the efficacy against a broad range of strains, phages have to be safe in terms of their genomes. Thus far, no genes with pathogenic potential (e.g., genes encoding virulence factors) have been detected in Campylobacter phages. However, preliminary studies suggested that the genomes of group II phages may be diverse and prone to genomic rearrangements.

Results

We determined and analysed the genomic sequence (182,761 bp) of group II phage CP21 that is closely related to the already characterized group II phages CP220 and CPt10. The genomes of these phages are comprised of four modules separated by very similar repeat regions, some of which harbouring open reading frames (ORFs). Though, the arrangement of the modules and the location of some ORFs on the genomes are different in CP21 and in CP220/CPt10. In this work, a PCR system was established to study the modular genome organization of other group II phages demonstrating that they belong to different subgroups of the CP220-like virus genus, the prototypes of which are CP21 and CP220. The subgroups revealed different restriction patterns and, interestingly enough, also distinct host specificities, tail fiber proteins and tRNA genes. We additionally analysed the genome of group II phage vB_CcoM-IBB_35 (IBB_35) for which to date only five individual contigs could be determined. We show that the contigs represent modules linked by long repeat regions enclosing some yet not identified ORFs (e.g., for a head completion protein). The data suggest that IBB_35 is a member of the CP220 subgroup.

Conclusion

Campylobacter group II phages are diverse regarding their genome organization. Since all hitherto characterized group II phages contain numerous genes for transposases and homing endonucleases as well as similar repeat regions, it cannot be excluded that these phages are genetically unstable. To answer this question, further experiments and sequencing of more group II phages should be performed.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1837-1) contains supplementary material, which is available to authorized users.     

Core and accessory genome architecture in a group of Pseudomonas aeruginosa Mu-like phages

Background

Bacteriophages that infect the opportunistic pathogen Pseudomonas aeruginosa have been classified into several groups. One of them, which includes temperate phage particles with icosahedral heads and long flexible tails, bears genomes whose architecture and replication mechanism, but not their nucleotide sequences, are like those of coliphage Mu. By comparing the genomic sequences of this group of P. aeruginosa phages one could draw conclusions about their ontogeny and evolution.

Results

Two newly isolated Mu-like phages of P. aeruginosa are described and their genomes sequenced and compared with those available in the public data banks. The genome sequences of the two phages are similar to each other and to those of a group of P. aeruginosa transposable phages. Comparing twelve of these genomes revealed a common genomic architecture in the group. Each phage genome had numerous genes with homologues in all the other genomes and a set of variable genes specific for each genome. The first group, which comprised most of the genes with assigned functions, was named “core genome”, and the second group, containing mostly short ORFs without assigned functions was called “accessory genome”. Like in other phage groups, variable genes are confined to specific regions in the genome.

Conclusion

Based on the known and inferred functions for some of the variable genes of the phages analyzed here, they appear to confer selective advantages for the phage survival under particular host conditions. We speculate that phages have developed a mechanism for horizontally acquiring genes to incorporate them at specific loci in the genome that help phage adaptation to the selective pressures imposed by the host.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-1146) contains supplementary material, which is available to authorized users.     

DNA relatedness among bacteriophages of the morphological group C3

Six bacteriophages with an elongated head and a short, noncontractile tail were compared by DNA-DNA hybridization, seroneutralization kinetics, mol% G+C and molecular weight of DNA, and host range. Three phage species could be identified. Phage species 1 containedEnterobacter sakazakii phage C2,Erwinia herbicola phages E3 and E16P, andSalmonella newport phage 7–11. These phages had a rather wide host range (4 to 13 bacterial species). DNA relatedness among species 1 phages was above 75% relative binding ratio (S1 nuclease method, 60°C) when labeled DNA from phage C2 was used, and above 41% when labeled DNA from phage E3 was used. Molecular weight of DNA was about 58×10⁶ (C2) to 67 ×10⁶ (E3). The mol% G+C of DNA was 43–45. Anti-C2 serum that neutralizes all phages of species 1 does not neutralize phages of the other two species. Species 2 contains only coliphage Esc-7-11, whose host range was only oneEscherichia coli strain out of 188 strains of Enterobacteriaceae studied; it was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage Esc-7-11 had a base composition of 43 mol% G+C and a molecular weight of about 45×10⁶. Species 3 contains onlyProteus mirabilis phage 13/3a. Its host range was limited to swarmingProteus species. Species 3 was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage 13/3a had a base composition of 35 mol% G+C and molecular weight of about 53×10⁶. It is proposed that phage species be defined as phage nucleic acid hybridization groups.     

A Virulent Phage Infecting Lactococcus garvieae,with Homology to Lactococcus lactis Phages

A new virulent phage belonging to the Siphoviridae family and able to infect Lactococcus garvieae strains was isolated from compost soil. Phage GE1 has a prolate capsid (56 by 38 nm) and a long noncontractile tail (123 nm). It had a burst size of 139 and a latent period of 31 min. Its host range was limited to only two L. garvieae strains out of 73 tested. Phage GE1 has a double-stranded DNA genome of 24,847 bp containing 48 predicted open reading frames (ORFs). Putative functions could be assigned to only 14 ORFs, and significant matches in public databases were found for only 17 ORFs, indicating that GE1 is a novel phage and its genome contains several new viral genes and encodes several new viral proteins. Of these 17 ORFs, 16 were homologous to deduced proteins of virulent phages infecting the dairy bacterium Lactococcus lactis, including previously characterized prolate-headed phages. Comparative genome analysis confirmed the relatedness of L. garvieae phage GE1 to L. lactis phages c2 (22,172 bp) and Q54 (26,537 bp), although its genome organization was closer to that of phage c2. Phage GE1 did not infect any of the 58 L. lactis strains tested. This study suggests that phages infecting different lactococcal species may have a common ancestor.     

Genome Organization and Characterization of the Virulent Lactococcal Phage 1358 and Its Similarities to Listeria Phages

Virulent phage 1358 is the reference member of a rare group of phages infecting Lactococcus lactis. Electron microscopy revealed a typical icosahedral capsid connected to one of the smallest noncontractile tails found in a lactococcal phage of the Siphoviridae family. Microbiological characterization identified a burst size of 72 virions released per infected host cell and a latent period of 90 min. The host range of phage 1358 was limited to 3 out of the 60 lactococcal strains tested. Moreover, this phage was insensitive to four Abi systems (AbiK, AbiQ, AbiT, and AbiV). The genome of phage 1358 consisted of a linear, double-stranded, 36,892-bp DNA molecule containing 43 open reading frames (ORFs). At least 14 ORFs coded for structural proteins, as identified by SDS-PAGE coupled to liquid chromatography-tandem mass spectrometry (LC-MS/MS) analyses. The genomic organization was similar to those of other siphophages. All genes were on the same coding strand and in the same orientation. This lactococcal phage was unique, however, in its 51.4% GC content, much higher than those of other phages infecting this low-GC Gram-positive host. A bias for GC-rich codons was also observed. Comparative analyses showed that several phage 1358 structural proteins shared similarity with two Listeria monocytogenes phages, P35 and P40. The possible origin and evolution of lactococcal phage 1358 is discussed.The first sequenced genome of a phage infecting Lactococcus lactis (bIL67) was reported in 1994 (57). Its genomic characterization was performed with the prospect of a better understanding of lactococcal phage biology. L. lactis is a Gram-positive bacterium added to milk to produce an array of fermented dairy products. In this human-made environment, substantial amounts of lactococcal cells are cultivated on a daily basis in large fermentation vats, and these added cells randomly encounter virulent phages present in heat-treated but nonsterile milk. Moreover, it is widely acknowledged that the increased use of the same bacterial strains within existing dairy facilities inevitably leads to milk fermentation failures due to the multiplication of virulent phages. This biotechnological problem reduces yields and lowers the quality of fermented products (51).Over 700 lactococcal phage isolates have been reported in the literature (3). To date, more than 25 complete genome sequences of lactococcal phages are publicly available in the NCBI database, and the sequencing of others is under way. These numbers indicate that Lactococcus phages are among the most studied of the bacterial viruses. All lactococcal phages belong to the order Caudovirales and are included within two families according to their tail morphology: the Siphoviridae (long noncontractile tail [most lactococcal phages]) and the Podoviridae (short noncontractile tail [few lactococcal phages]) (14). Currently, phages infecting L. lactis strains have been divided into 10 genetically distinct groups (14). The complete genomic sequence is available for at least one representative of 8 of the groups.Early sequencing efforts concentrated on the genomes of lactococcal phages belonging to the 936, c2, and P335 groups (Siphoviridae), because members of these groups were regularly isolated in dairy plants (8, 36, 50). PCR-based methods were also devised to rapidly classify these phages (41). These Siphoviridae phages pose a significant risk to the dairy industry, and their characterization is important for developing adapted antiphage strategies to limit their propagation and evolution.In recent years, representatives of the less recognized lactococcal phage groups have been characterized, including phages Q54 (22), KSY1 (13), 1706 (23), asccφ28 of the P034 group (39), and P087 (63). Their molecular characterizations were aimed at understanding why some phage groups (936, c2, and P335) predominate while the others have remained marginal, at best. However, it was recently reported that P034-like phages may be emerging in certain regions (52). Genomic and microbiological analyses indicated that members of these rare phage groups were likely the result of recombination between different lactococcal phages and phages infecting other Gram-positive bacteria, and they may not be fit to multiply rapidly in milk. For example, lactococcal phage 1706 shares similarities with Ruminococcus and Clostridium prophages (23). Similarly, L. lactis phage P087 structural proteins share identity with gene products found in a prophage in the Enterococcus faecalis genome (63). It was also shown previously that lactococcal phage asccφ28 was related to Streptococcus pneumoniae phage Cp-1 and Bacillus subtilis φ29-like phages (39). It was suggested that phages 1706, asccφ28, and P087 acquired a receptor-binding protein complex from another lactococcal phage that enabled them to infect a L. lactis host.Here, we report the complete genome sequence and analysis of phage 1358, a virulent representative of the 9th lactococcal phage group.     

Whole-genome synthesis and characterization of viable S13-like bacteriophages

Background

Unprecedented progresses in high-throughput DNA sequencing and de novo gene synthesis technologies have allowed us to create living organisms in the absence of natural template.

Methodology/Principal Findings

The sequence of wild-type S13 phage genome was downloaded from GenBank. Two synonymous mutations were introduced into wt-S13 genome to generate m1-S13 genome. Another mutant, m2-S13 genome, was obtained by engineering two nonsynonymous mutations in the capsid protein coding region of wt-S13 genome. A chimeric phage genome was designed by replacing the F capsid protein open reading frame (ORF) from phage S13 with the F capsid protein ORF from phage G4. The whole genomes of all four phages were assembled from a series of chemically synthesized short overlapping oligonucleotides. The linear synthesized genomes were circularized and electroporated into E.coli C, the standard laboratory host of S13 phage. All four phages were recovered and plaques were visualized. The results of sequencing showed the accuracy of these synthetic genomes. The synthetic phages were capable of lysing their bacterial host and tolerating general environmental conditions. While no phenotypic differences among the variant strains were observed when grown in LB medium with CaCl₂, the S13/G4 chimera was found to be much more sensitive to the absence of calcium and to have a lower adsorption rate under calcium free condition.

Conclusions/Significance

The bacteriophage S13 and its variants can be chemically synthesized. The major capsid gene of phage G4 is functional in the phage S13 life cycle. These results support an evolutional hypothesis which has been proposed that a homologous recombination event involving gene F of quite divergent ancestral lineages should be included in the history of the microvirid family.     

一株枯草芽孢杆菌原噬菌体Bsu-yong1的基因组分析

【目的】枯草芽孢杆菌（Bacillus subtilis）是在自然界中广泛存在的革兰氏阳性菌，其抗逆性极强，能抑制大多数有害菌的繁殖，是常用的产酶菌，用其生产的蛋白酶、淀粉酶占全球工业酶产量的50%。原噬菌体（prophage）整合在宿主基因组中，可为宿主提供基因和生物学功能，非常具有研究价值。以往，有关B. subtilis原噬菌体的报道主要集中于缺陷型原噬菌体（defective prophage），本研究对一株非缺陷型活性原噬菌体（active prophage）的基因组进行解析，以扩充对非缺陷型原噬菌体的认知。【方法】使用丝裂霉素C从枯草芽孢杆菌中诱导一株噬菌体，命名为Bacillus phage Bsu-yong1（简称Bsu-yong1）。对Bsu-yong1进行负染、透射电镜（transmission electron microscopy，TEM）观察，用Illumina MiSeq测定其基因组序列、综合运用生物信息学工具对其进行基因功能注释和系统进化分析。【结果】Bsu-yong1与PBSX类缺陷型原噬菌体在形态上相似，但Bsu-yong1具有完整的噬菌体基因组，这与缺陷型原噬菌体不同，后者在包装过程中不能正确包裹自身的基因组，而是随机包裹一段宿主染色体。Bsu-yong1基因组全长为43 590 bp，G+C含量为41%，含有62个开放阅读框（open reading frame，ORF），呈模块化分布。Bsu-yong1拥有基因编码T7SS效应器LXG多态性毒素（T7SS effector LXG polymorphic toxin）、ImmA/IrrE蛋白和SMI1/KNR4蛋白。前二者为细菌毒素（toxin），后者为抗毒素（antitoxin），toxin-antitoxin是细菌免疫系统重要成员，参与菌间竞争与环境适应。此前，尚未有编码LXG polymorphic toxin的基因在噬菌体中被发现和报道。在基于全基因组比对构建的蛋白谱进化树（proteomic tree）中，Bsu-yong1与噬菌体sv105、rho14、vB_BteM-A9Y聚集形成一个独立的进化支（clade），基因组比对显示它们基因组的复制与调控模块具有高度保守性，它们共享29个核心基因（core gene），均具有PBSX样形态特征。Bsu-yong1与其他噬菌体的进化距离较远。将Bsu-yong1与所有噬菌体进行比对，得到的成对序列比较（pairwise sequence comparison，PASC）最大值为46.72%，小于属边界值（70%）。【结论】vB_Bsu-yong1在有尾纲中代表一个新的未知的属；建议构建一个新的科（family），该科由Bsu-yong1与噬菌体sv105、rho14、vB_BteM-A9Y组成。vB_Bsu-yong携带免疫相关基因，它可能有利于宿主在菌间竞争中获胜和适应环境。本研究丰富了噬菌体基因数据库，拓展了对芽孢杆菌活性原噬菌体的认知。     

The mitochondrial DNA of <Emphasis Type="Italic">Dictyostelium discoideum</Emphasis>: complete sequence,gene content and genome organization

We present an overview of the gene content and organization of the mitochondrial genome of Dictyostelium discoideum. The mitochondria genome consists of 55,564?bp with an A + T content of 72.6%. The identified genes include those for two ribosomal RNAs (rnl and rns), 18 tRNAs, ten subunits of the NADH dehydrogenase complex (nad1, 2, 3, 4, 4L, 5, 6, 7, 9 and 11), apocytochrome b (cytb), three subunits of the cytochrome oxidase (cox1/2 and 3), four subunits of the ATP synthase complex (atp1, 6, 8 and 9), 15 ribosomal proteins, and five other ORFs, excluding intronic ORFs. Notable features of D. discoideum mtDNA include the following. (1) All genes are encoded on the same strand of the DNA and a universal genetic code is used. (2) The cox1 gene has no termination codon and is fused to the downstream cox2 gene. The 13 genes for ribosomal proteins and four ORF genes form a cluster 15.4?kb long with several gene overlaps. (3) The number of tRNAs encoded in the genome is not sufficient to support the synthesis of mitochondrial protein. (4) In total, five group I introns reside in rnl and cox1/2, and three of those in cox1/2 contain four free-standing ORFs. We compare the genome to other sequenced mitochondrial genomes, particularly that of Acanthamoeba castellanii.     

Characterization of Two Virulent Phages of Lactobacillus plantarum

We characterized two Lactobacillus plantarum virulent siphophages, ATCC 8014-B1 (B1) and ATCC 8014-B2 (B2), previously isolated from corn silage and anaerobic sewage sludge, respectively. Phage B2 infected two of the eight L. plantarum strains tested, while phage B1 infected three. Phage adsorption was highly variable depending on the strain used. Phage defense systems were found in at least two L. plantarum strains, LMG9211 and WCSF1. The linear double-stranded DNA genome of the pac-type phage B1 had 38,002 bp, a G+C content of 47.6%, and 60 open reading frames (ORFs). Surprisingly, the phage B1 genome has 97% identity with that of Pediococcus damnosus phage clP1 and 77% identity with that of L. plantarum phage JL-1; these phages were isolated from sewage and cucumber fermentation, respectively. The double-stranded DNA (dsDNA) genome of the cos-type phage B2 had 80,618 bp, a G+C content of 36.9%, and 127 ORFs with similarities to those of Bacillus and Lactobacillus strains as well as phages. Some phage B2 genes were similar to ORFs from L. plantarum phage LP65 of the Myoviridae family. Additionally, 6 tRNAs were found in the phage B2 genome. Protein analysis revealed 13 (phage B1) and 9 (phage B2) structural proteins. To our knowledge, this is the first report describing such high identity between phage genomes infecting different genera of lactic acid bacteria.     

Complete Genome Sequence of φHSIC, a Pseudotemperate Marine Phage of Listonella pelagia

The genome for the marine pseudotemperate member of the Siphoviridae HSIC has been sequenced using a combination of linker amplification library construction, restriction digest library construction, and primer walking. HSIC enters into a pseudolysogenic relationship with its host, Listonella pelagia, characterized by sigmoidal growth curves producing >10⁹ cells/ml and >10¹¹ phage/ml. The genome (37,966 bp; G+C content, 44%) contained 47 putative open reading frames (ORFs), 17 of which had significant BLASTP hits in GenBank, including a β subunit of DNA polymerase III, a helicase, a helicase-like subunit of a resolvasome complex, a terminase, a tail tape measure protein, several phage-like structural proteins, and 1 ORF that may assist in host pathogenicity (an ADP ribosyltransferase). The genome was circularly permuted, with no physical ends detected by sequencing or restriction enzyme digestion analysis, and lacked a cos site. This evidence is consistent with a headful packaging mechanism similar to that of Salmonella phage P22 and Shigella phage Sf6. Because none of the phage-like ORFs were closely related to any existing phage sequences in GenBank (i.e., none more than 62% identical and most <25% identical at the amino acid level), HSIC is unique among phages that have been sequenced to date. These results further emphasize the need to sequence phages from the marine environment, perhaps the largest reservoir of untapped genetic information.     

Sequence Analysis of Leuconostoc mesenteroides Bacteriophage Φ1-A4 Isolated from an Industrial Vegetable Fermentation

Vegetable fermentations rely on the proper succession of a variety of lactic acid bacteria (LAB). Leuconostoc mesenteroides initiates fermentation. As fermentation proceeds, L. mesenteroides dies off and other LAB complete the fermentation. Phages infecting L. mesenteroides may significantly influence the die-off of L. mesenteroides. However, no L. mesenteroides phages have been previously genetically characterized. Knowledge of more phage genome sequences may provide new insights into phage genomics, phage evolution, and phage-host interactions. We have determined the complete genome sequence of L. mesenteroides phage Φ1-A4, isolated from an industrial sauerkraut fermentation. The phage possesses a linear, double-stranded DNA genome consisting of 29,508 bp with a G+C content of 36%. Fifty open reading frames (ORFs) were predicted. Putative functions were assigned to 26 ORFs (52%), including 5 ORFs of structural proteins. The phage genome was modularly organized, containing DNA replication, DNA-packaging, head and tail morphogenesis, cell lysis, and DNA regulation/modification modules. In silico analyses showed that Φ1-A4 is a unique lytic phage with a large-scale genome inversion (∼30% of the genome). The genome inversion encompassed the lysis module, part of the structural protein module, and a cos site. The endolysin gene was flanked by two holin genes. The tail morphogenesis module was interspersed with cell lysis genes and other genes with unknown functions. The predicted amino acid sequences of the phage proteins showed little similarity to other phages, but functional analyses showed that Φ1-A4 clusters with several Lactococcus phages. To our knowledge, Φ1-A4 is the first genetically characterized L. mesenteroides phage.Bacteriophages are the most abundant biological entities (estimated to be on the order of ≥10³¹) on the planet (9, 18). Phages are ubiquitous in nature and can influence the microbial ecology and genetics of bacteria. Because of their small (usually <60 kb) genomes, phages can provide an excellent model system for studying many biological processes, including DNA replication and genetic evolution. Despite this, many phages remain uncharacterized. Very little is known about phage diversity and phage-host interactions owing to the small number of sequenced phages. Furthermore, the existing phage sequence database is highly biased toward a limited spectrum of phage hosts, namely, Enterobacteriaceae, Bacillus, Staphylococcus, Pseudomonas, Vibrio cholerae, Lactococcus, Streptococcus thermophilus, and S. pyogenes. The majority of host species for sequenced phages are either pathogenic or dairy-related bacteria. Most of the newly sequenced phage genes have no assigned functions or matches in the GenBank database (7).Vegetable fermentations rely on a variety of lactic acid bacteria (LAB). The proper succession of LAB directly determines the quality and safety of the final fermentation products. Leuconostoc mesenteroides initiates most vegetable fermentations. It converts the sugars in vegetables (primarily glucose and fructose) to lactic acid, acetic acid, ethanol, CO₂, and other flavor compounds (22, 58, 59, 60, 61). Acid production lowers the pH of fermenting vegetables and inhibits the growth of many microorganisms, including pathogens. CO₂ production promotes the establishment of an anaerobic environment which favors the growth of other LAB. The metabolites produced by L. mesenteroides largely determine the flavor characteristics of the final products. As fermentation proceeds, L. mesenteroides rapidly dies off. Other LAB, including Lactobacillus plantarum, take over and complete the fermentation.It has been a widely held view that the disappearance of L. mesenteroides and the subsequent bacterial succession in sauerkraut fermentations are due to the inhibitory effect of acids that accumulate during fermentation (54, 61). Little is known about other factors that may play a role in bacterial succession. Recent studies have shown that phages are present in the vegetable fermentations (4, 47, 48, 74, 75). Because of the rapid lytic cycle of these phages, they may significantly impact starter cultures and bacterial succession in vegetable fermentations (56). Phages active against L. mesenteroides have been isolated and characterized (48); however, genome sequences have not been reported.L. mesenteroides phage 1-A4 (designated Φ1-A4) is of particular interest. Φ1-A4 is a lytic phage that was repeatedly isolated during the initial stages of a commercial sauerkraut fermentation. As a result, Φ1-A4 may significantly influence the survival of L. mesenteroides and flavor development during sauerkraut fermentation. It was found that Φ1-A4 infects at least three different strains of L. mesenteroides (48), and therefore it may also promote genetic exchange and genetic diversity in microbial communities (34).The objectives of this study were to determine and analyze the complete genome sequence of Φ1-A4, to experimentally identify the structural protein genes, and to compare the genome organization with that of related phages. To our knowledge, this study represents the first complete genomic and molecular characterization of Leuconostoc phage. The results from this study may provide new insights into our understanding of phage genetics. This study may aid the development of phage control technologies in vegetable and other fermentations that are susceptible to phage attack.     

Genomic analysis of bacteriophage ϕAB1, a ϕKMV-like virus infecting multidrug-resistant Acinetobacter baumannii

We present the complete genomic sequence of a lytic bacteriophage ?AB1 which can infect many clinical isolates of multidrug-resistant Acinetobacter baumannii. The recently isolated bacteriophage displays morphology resembling Podoviridae family. The ?AB1 genome is a linear double-stranded DNA of 41,526 bp containing 46 possible open reading frames (ORFs). The majority of the predicted structural proteins were identified as part of the phage particle by mass spectrometry analysis. According to the virion morphology, overall genomic structure, and the phylogenetic tree of RNA polymerase, we propose that ?AB1 is a new member of the ?KMV-like phages. Additionally, we identified four ORFs encoding putative HNH endonucleases, one of which is presumed to integrate and create a genes-in-pieces DNA polymerase. Also, a potential lysis cassette was identified in the late genome. The lytic power of this bacteriophage combined with its specificity for A. baumannii makes ?AB1 an attractive agent for therapeutic or disinfection applications.     

Molecular cytogenetic characterization of a new wheat-rye 1BL•1RS translocation line expressing superior stripe rust resistance and enhanced grain yield

Main conclusion

A new wheat-rye 1BL?1RS translocation line, with the characteristics of superior stripe rust resistance and high thousand-kernel weight and grain number per spike, was developed and identified from progenies of wheat-rye- Psathyrostachys huashanica trigeneric hybrids.

Abstract

The wheat-rye 1BL?1RS translocation line from Petkus rye has contributed substantially to the world wheat production. However, due to extensive growing of cultivars with disease resistance genes from short arm of rye chromosome 1R and coevolution of pathogen virulence and host resistance, these cultivars successively lost resistance to pathogens. In this study, a new wheat-rye line K13-868, derived from the progenies of wheat-rye-Psathyrostachys huashanica trigeneric hybrids, was identified and analyzed using fluorescence in situ hybridization (FISH), genomic in situ hybridization (GISH), acid polyacrylamide gel electrophoresis (A-PAGE), and molecular markers. Cytological studies indicated that the mean chromosome configuration of K13-868 at meiosis was 2n = 42 = 0.14 I + 18.78 II (ring) + 2.15 II (rod). Sequential FISH and GISH results demonstrated that K13-868 was a compensating wheat-rye 1BL?1RS Robertsonian translocation line. Acid PAGE analysis revealed that clear specific bands of rye 1RS were expressed in K13-868. Simple sequence repeat (SSR) and rye 1RS-specific markers ω-sec-p1/ω-sec-p2 and O-SEC5′-A/O-SEC3′-R suggested that the 1BS arm of wheat had been substituted by the 1RS arm of rye. At the seedling and adult growth stage, compared with its recurrent wheat parent SM51 and six other wheat cultivars containing the 1RS arm in southwestern China, K13-868 showed high levels of resistance to stripe rust (Puccinia striiformis f. sp. tritici, Pst) pathogens prevalent in China, which are virulent to Yr10 and Yr24/Yr26. In addition, K13-868 expresses higher thousand-kernel weight and more grain number per spike than these controls in two growing seasons, suggesting that this line may carry yield-related genes of rye. This translocation line, with significant characteristics of resistance to stripe rust and high thousand-kernel weight and grain number per spike, could be utilized as a valuable germplasm for wheat improvement.

     

Genome analysis of Heliothis virescens ascovirus 3h isolated from China

No ascovirus isolated from China has been sequenced so far. Therefore, in this study, we aimed to sequence the genome of Heliothis virescens ascovirus 3h (HvAV-3h) using the 454 pyrosequencing technology. The genome was found to be 190,519-bp long with a G+C content of 45.5%. We also found that it encodes 185 hypothetical open reading frames (ORFs) along with at least 50 amino acids, including 181 ORFs found in other ascoviruses and 4 unique ORFs. Gene-parity plots and phylogenetic analysis revealed a close relationship between HvAV-3h and three other HvAV-3a strains and a distant relationship with Spodoptera frugiperda ascovirus 1a (SfAV-1a), Trichoplusia ni ascovirus 6a (TnAV-6a), and Diadromus pulchellus ascovirus 4a (DpAV-4a). Among the 185 potential genes encoded by the genome, 44 core genes were found in all the sequenced ascoviruses. In addition, 25 genes were found to be conserved in all ascoviruses except DpAV-4a. In the HvAV-3h genome, 24 baculovirus repeat ORFs (bros) were present, and the typical homologous repeat regions (hrs) were absent. This study supplies information important for understanding the conservation and functions of ascovirus genes as well as the variety of ascoviral genomes.

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Sequence homology and recombination between the genomes of morphologically dissimilar bacteriophages LP 52 and theta

Summary A restriction fragment map of Bacillus licheniformis temperate phage LP 52 DNA (molecular weight 38.5×10⁶) was established, using restriction endonucleases BamHI (8 target sites), BglI (10 sites), BglII (13 sites) and EcoRI (22 sites). The map is linear, with well-defined ends, without any signs of circular permutation. The DNA of a related phage, LP 51, produced identical restriction fragments. At least 62% DNA of LP 52 has been found homologous to the DNA of the recently discovered, morphologically quite dissimilar, phage , as demonstrated by hybridization of electrophoretically separated restriction fragments of DNA. Under the same conditions, the DNAs of LP 52 and of the morphologically similar Bacillus subtilis phage 105 did not cross-hybridize. The homologous regions in the genomes of phages LP 52 and have been shown to be colinear. Comparison of the cleavage maps of phages LP 52 and has shown that, within the regions of homology, not a single restriction fragment and few restriction sites have been conserved during divergent evolution. Three major regions of heterology were defined; the longest one, covering the right-hand end of the map (73±2.75% up to 100% LP 52 genome length) appeared to contain genes coding for structural proteins of the virions; a shorter region at the left-hand end of the map (coordinates zero to 10.3±3.3% LP 52 genome length) and a very short central region (coordinates 41.8–43.9%) could be identified, the latter apparently containing a regulatory locus responsible for the heteroimmune behavior of the two phages. Recombinants between phages LP 52 and were isolated. Mapping of recombinant genomes has indicated mutual substitution of allelic pieces of LP 52 and DNAs upon strict conservation of overall genome length.     

Phenogenetic Characterization of a Group of Giant φKZ-like Bacteriophages of Pseudomonas aeruginosa

A comparative study was made of a group ofPseudomonas aeruginosa virulent giant DNA bacteriophages similar to phage KZ in several genetic and phenotypic properties (particle size, particle morphology, genome size, appearance of negative colonies, high productivity, broad spectrum of lytic activity, ability to overcome the suppressing effect of plasmids, absence of several DNA restriction sites, capability of general transduction, pseudolysogeny). We have recently sequenced the phage KZ genome (288 334 bp) [J. Mol. Biol., 2002, vol. 317, pp. 1–19]. By DNA homology, the phages were assigned to three species (represented by phages KZ, Lin68, and EL, respectively) and two new genera (KZ and EL). Restriction enzyme analysis revealed the mosaic genome structure in four phages of the KZ species (KZ, Lin21, NN, and PTB80) and two phages of the EL species (EL and RU). Comparisons with respect to phage particle size, number of structural proteins, and the N-terminal sequences of the major capsid protein confirmed the phylogenetic relatedness of the phages belonging to the KZ genus. The origin and evolution of the KZ-like phages are discussed. Analysis of protein sequences encoded by the phage KZ genome made it possible to assume wide migration of the KZ-like phages (wandering phages) among various prokaryotes and possibly eukaryotes. Since the phage KZ genome codes for potentially toxic proteins, caution must be exercised in the employment of large bacteriophages in phage therapy.