- Research article
- Open Access
Genetic and phenotypic diversity in Burkholderia: contributions by prophage and phage-like elements
- Catherine M Ronning†1, 4,
- Liliana Losada†1,
- Lauren Brinkac1,
- Jason Inman1,
- Ricky L Ulrich2,
- Mark Schell3,
- William C Nierman1 and
- David DeShazer2Email author
© Ronning et al; licensee BioMed Central Ltd. 2010
Received: 15 April 2010
Accepted: 28 July 2010
Published: 28 July 2010
Burkholderia species exhibit enormous phenotypic diversity, ranging from the nonpathogenic, soil- and water-inhabiting Burkholderia thailandensis to the virulent, host-adapted mammalian pathogen B. mallei. Genomic diversity is evident within Burkholderia species as well. Individual isolates of Burkholderia pseudomallei and B. thailandensis, for example, carry a variety of strain-specific genomic islands (GIs), including putative pathogenicity and metabolic islands, prophage-like islands, and prophages. These GIs may provide some strains with a competitive advantage in the environment and/or in the host relative to other strains.
Here we present the results of analysis of 37 prophages, putative prophages, and prophage-like elements from six different Burkholderia species. Five of these were spontaneously induced to form bacteriophage particles from B. pseudomallei and B. thailandensis strains and were isolated and fully sequenced; 24 were computationally predicted in sequenced Burkholderia genomes; and eight are previously characterized prophages or prophage-like elements. The results reveal numerous differences in both genome structure and gene content among elements derived from different species as well as from strains within species, due in part to the incorporation of additional DNA, or 'morons' into the prophage genomes. Implications for pathogenicity are also discussed. Lastly, RNAseq analysis of gene expression showed that many of the genes in ϕ1026b that appear to contribute to phage and lysogen fitness were expressed independently of the phage structural and replication genes.
This study provides the first estimate of the relative contribution of prophages to the vast phenotypic diversity found among the Burkholderiae.
Burkholderia pseudomallei, causal agent of the potentially fatal disease melioidosis, is a metabolically versatile soil organism that has been classified as a Category B biological threat by the CDC [1, 2]. Relatively little is known about its pathogenesis, virulence factors, the extent of diversity in natural populations, and host response. B. pseudomallei genome plasticity has been associated with genomic island variation. The genome of B. pseudomallei K96243 (7.3 Mb), for example, features 16 genomic islands, at least three of which appear to be prophages . It is unclear whether all of these putative prophages are active, although one (ΦK96243) was shown to be a productive bacteriophage. B. pseudomallei isolates are genetically quite diverse [4, 5], and this heterogeneity may be due at least in part to the highly variable distribution of bacteriophages among strains . Such differences may provide certain strains survival advantages in the environment and the host, as well as explain the variable clinical presentation of melioidosis.
Also raising concern as a potential biological weapon is the very closely related B. mallei, causal agent of the primarily equine disease known as glanders . In contrast to B. pseudomallei, B. mallei is a highly specialized pathogen, not found outside of a mammalian host in nature. B. mallei is a host-adapted clone of B. pseudomallei, and all of the B. mallei genome is nearly identical to a set of genes within B. pseudomallei core genome. However, in addition to its core genome B. pseudomallei contains numerous contiguous gene clusters that were deleted from B. mallei during its evolution [8, 9].
B. thailandensis is another closely related organism often found in the same environmental samples (soil and water of endemic melioidosis regions) as B. pseudomallei. Unlike B. pseudomallei and B. mallei, B. thailandensis has very low virulence in most animal hosts, including humans. The ability to metabolize arabinose, and the corresponding loss of the arabinose assimilation operon from B. pseudomallei, phenotypically distinguishes B. thailandensis from B. pseudomallei. The genes encoding arabinose assimilation may be considered as antivirulent, and their absence from B. pseudomallei (and B. mallei) may have allowed the development of the latter as pathogens . Burkholderia multivorans, a member of the Burkholderia cepacia complex, is an opportunistic pathogen associated with infection in cystic fibrosis patients that is also found in soil environments .
The presence of prophages among bacterial isolates and their possible contribution to bacterial diversity is widespread. By carrying various elements contributing to virulence, prophages can contribute to the genetic individuality of a bacterial strain. This phenomenon has been reported in Salmonella spp  and Lactobacillus spp [15, 16], among others. Prophage-associated chromosomal rearrangements and deletions have been found to be largely responsible for strain-specific differences in Streptococcus pyogenes and Xylella fastidiosa. Thus, temperate phages carrying foreign DNA can play a role in the emergence of pathogenic variants. Lateral gene transfer between phage and host genomes, and phage lysogenic conversion genes, can alter host phenotype through production of phage-encoded toxins and disease-modifying factors that affect virulence of the bacterial strain. Examples of such phage-encoded virulence factors abound in the literature, and include proteins associated with toxicity, antigenicity, invasion, intracellular survival, serum resistance, and adhesion . Many of these factors are encoded by morons that are present variably across phage genomes and are thought to be regulated independently of the phage genes .
To estimate the contribution of prophages to genetic and phenotypic diversity of the species, we have isolated and sequenced five temperate bacgteriophages from Burkholderia, three from B. pseudomallei and two from B. thailandensis, and used bioinformatics techniques to search for putative prophage regions in the genomes of nine sequenced B. pseudomallei strains, six B. mallei strains, one B. thailandensis strain, three B. multivorans strains, and one Burkholderia xenovorans strain. While no prophages were detected in any of the B. mallei strains, a total of 24 putative prophages or prophage-like islands (PI) were identified in the other species. Sequences from the isolated phages and inferred prophages were compared with each other and with the 8 published phage sequences from B. pseudomallei, B. thailandensis, B. cenocepacia, and B. cepacia. As seen in other genera, the prophages among the Burkholderiae contribute to the genomic variability of the species and carry genes that could provide advantages in the environment and host adaptation.
Spontaneous bacteriophage production by lysogenic B. pseudomallei and B. thailandensis strains, host range studies, and UV induction experiments
Sources and descriptions of bacteriophage and putative prophage islands (PI) used in this study.
A. Isolated bacteriophages
Phage (Acc #)
Head diameter (nm)
Tail (length × diameter) (nm)
Plaque diameter (mm)
Bp Pasteur 52237
155 × 23
1.5 - 2.0
3 × 106
Australia; disease (ulcer)
190 × 9
3 × 103
NE Thailand; soil
152 × 21
1.5 - 2.0
1 × 101
NE Thailand; soil
140 × 21
1.5 - 2.0
2 × 105
central Thailand; soil
143 × 21
2 × 103
B. Inferred prophages
Bp Pasteur 6068
Bp Pasteur 6068
PI E264-1 (GI1)
PI E264-2 (GI13)
PI E264-3 (GI12)
Bmul ATCC 17616
Bmul ATCC 17616
Bmul ATCC 17616
putative prophage 
C. Published bacteriophages
Phage (Acc #)
GI2; ΦK96243 (N/A)
B. cenocepacia J2315
Myoviridae (Mu-like) 
B. pseudomallei strains Pasteur 52237, E12, and 644 and B. thailandensis strains E202 and E255 were grown in LB broth for 18 h at 37°C with shaking (250 rpm). Overnight cultures were briefly centrifuged to pellet the cells, and the supernatants were filter-sterilized (0.45 mm). The samples were serially diluted in suspension medium (SM) , and the number of plaque forming units (pfu) was assessed using B. mallei ATCC 23344 as the host strain. Briefly, one hundred microliters of filter-sterilized culture supernatant was added to a saturated B. mallei ATCC 23344 culture, incubated at 25°C for 20 min, and 4.8 ml of molten LB top agar (0.7%) containing 4% glycerol was added. The mixture was immediately poured onto a LB plate containing 4% glycerol and incubated overnight at 25°C or 37°C. For ϕE202 host range studies, this procedure was followed using the bacteria listed in Additional file 1, Table S1. Bacteria were considered to be sensitive to ϕE202 if they formed plaques under these conditions and resistant if they did not. No bacterial species tested formed plaques in the absence of ϕE202.
For ϕE202 UV induction studies, one hundred microliters of saturated B. thailandensis E202 culture was used to inoculate two LB broth (3 ml) subcultures. One set of subcultures was incubated for 5 h without interruption. The other set of subcultures was incubated for 3 h, poured into sterile petri dishes in a class II biological safety cabinet, subjected to a hand-held UV light source (254 nm) for 20 sec (25 cm above the sample), pipetted back into culture tubes, and incubated for an additional 2 h. The titer of the filter-sterilized supernatants were determined by performing quantitative plaque assays on serially diluted samples.
To determine morphotypes, bacteriophages were prepared from 20 ml of a plate culture lysate, incubated at 37°C for 15 min with Nuclease Mixture (Promega), precipitated with Phage Precipitant (Promega), and resuspended in 1 ml of Phage Buffer (Promega). The bacteriophage solution (~100 μl) was added to a strip of parafilm M (Sigma), and a formvar-coated nickel grid (400 mesh) was floated on the bacteriophage solution for 30 min at 25°C. Excess fluid was removed, and the grid was placed on a drop of 1% phosphotungstic acid, pH 6.6 (PTA) for 2 min at 25°C. Excess fluid was removed, and the specimen was examined on a Philips CM100 transmission electron microscope. Nickel grids were glow discharged on the day of use.
Bacteriophage sequencing and annotation
Libraries were constructed from the genomic DNA from the bacteriophage isolates. Since the phage genomes were estimated to be 50 kb in size, sequencing, closure, and annotation was performed similar to that of a BAC sequence . Each of the five isolated bacteriophages were completely sequenced to 10× coverage, closed, and annotated, and the sequences deposited in GenBank (Table 1A).
Identification of putative prophages and prophage-like elements within strains
Presence of prophage sequence within sequenced genomes of nine B. pseudomallei strains, six B. mallei strains , three B. multivorans strains, B. thailandensis E264 , and B. xenovorans LB400  (Additional file 1, Table S2) was inferred using a number of similarity measures previously described [26, 27]. First, the protein set of each genome was searched against a non-redundant database of viral proteins using BLASTP  with a cutoff of e-10. Secondly, the annotation of each strain was searched for several virus-related keywords such as integrase, tail, capsid, portal, terminase, etc. Clustering of such proteins with proteins containing similarity to known phage proteins as identified by BLASTP, as well as the orientation of proteins within clusters was considered strong evidence for prophage presence. Finally, tRNA genes and attachment sites were examined. A tRNA sequence immediately flanking an integrase was considered to be a potential att site, particularly if an exact repeat of least a 10 bp of the tRNA was present within several thousand bp. Regions containing all of these factors (i.e., viral-like proteins clustered and in a specific orientation, and flanked by a tRNA/integrase on one end and an exact repeat of at least 10 bp of the tRNA on the other end) were considered putative prophage. Regions containing many of these characteristics but lacking one or more, usually an integrase or repeat sequence, were considered prophage-like. Some att sites are less than 10 bp and are difficult to spot so it is possible that some of the prophage-like elements may actually be true prophages. Prophage and prophage-like regions so inferred have been designated "PI-strain-1", "PI-strain-2", etc. (PI for Prophage Island), and are listed in Table 1B. Four of the B. pseudomallei strains represent two paired isolates from two separate patients, one strain isolated from an initial infection and the paired isolate from a re-emergent infection in the same patient.
Three of the 16 genomic islands previously identified in B. pseudomallei K96243 were included in the analysis, including ϕK96243 (GI2) and the putative prophages GI3 and GI15 . Three prophage-like islands identified in B. thailandensis E264, GI1, GI12, and GI13, were also included in the analysis (Table 1B) . Additionally, the published genome sequences of ϕ1026b from B. pseudomallei 1026b , ϕE125 from B. thailandensis E125 , BcepMu from B. cenocepacia J2315 , Bcep22 from B. cepacia, and Bcep781 from B. cepacia, all of which are classified as dsDNA phages, were included for comparison (Table 1C).
Comparative genome sequence analysis and phylogenetic tree construction
The program Dotter  was used to align nucleotide sequences of all isolated and putative prophage and prophage-like sequences and to identify initial groupings. To refine clusters, distance measures were calculated between all pairs of each of the 30 prophage and PI sequences. Reciprocal BLASTP comparisons of the translated protein sets were performed for each prophage/PI against all others. BLASTP distances between each pair were calculated according to the formula: 1-(number of significant hits between both genomes/total number of genes in both genomes) . Distances were calculated using E value cutoffs of 1 × E-01, 1 × E-05, and 1 × E-10. FITCH with the global and jumble options was used to generate a phylogenetic tree from each of the three distance matrices derived from the BLASTP distances .
Calculation of local collinear blocks (LCB or synteny blocks) was done using progressive Mauve alignment  with default settings. Initial identification of morons was conducted in the Mauve alignments by searching for ORFs that disrupted the collinearity in LCBs. Confirmation of morons was done by (i) comparing % GC content of each ORF against the mean % GC of phage-specific genes (i.e., involved in structure, replication, and host lysis); (ii) promoter and terminator prediction analysis with BPROM http://www.softberry.com, PPP http://bioinformatics.biol.rug.nl/websoftware, PROMSCAN  or Promoter Prediction by Neural Network ; (iii) prediction of terminators with TransTermHP ; and (iv) search for homologs across different phage types within our data set and in the non-redundant database at NCBI.
Phage gene expression analysis using RNAseq
RNA from three biological replicates of B. pseudomallei DD503 (a derivative of 1026b) grown in LB was extracted from cells in early logarithmic growth using RNAeasy (QIAgen, Valencia CA). Ribosomal RNAs were removed by 2 rounds of MicrobExpress (Ambion, Foster City CA). Each RNA preparation was used in individual cDNA synthesis reactions using SuperScript II (Invitrogen, Carlsbad CA) and sequenced individually in the Illumina Genome Analyzer (Illumina Technologies, San Diego CA) or SOLiD instruments with 100 or 50 bp reads, respectively. Data was analyzed using CLC Genomics Workbench allowing for 2 mismatches in each read and only one map location per read. Total gene expression was normalized according to the total number of reads in the library and the gene size, resulting in reads per kilobase per million reads (RPKM). Only genes that had more than 10 hits were considered to be expressed above the noise level.
Results and Discussion
Isolated and sequenced bacteriophages
B. pseudomallei Pasteur 52237 spontaneously produced a bacteriophage, designated ϕ52237 that formed uniform, slightly turbid plaques on B. mallei ATCC 23344, suggesting that this strain produces only one bacteriophage under the growth conditions used. While it is plausible that different bacteriophages might form plaques with the same morphology, here we assumed that similar plaques were formed by only one bacteriophage. Based on its morphotype, ϕ52237 can be classified as a member of the order Caudovirales and the family Myoviridae .
B. pseudomallei E12 spontaneously produced two bacteriophages, ϕE12-1 and ϕE12-2, that formed plaques on B. mallei ATCC 23344. ϕE12-1 produced turbid plaques of 0.5 to 1 mm in diameter and ϕE12-2 produced turbid plaques with a diameter of 1.5 to 2.0 mm. The purified plaques maintained their morphology following a further round of infection in the host suggesting that they were formed by two distinct bacteriophages. Approximately 10 pfu/ml of ϕE12-1 and ϕE12-2 were present in B. pseudomallei E12 culture supernatants. We were unable to isolate nucleic acid from ϕE12-1 and no further work was carried out on this bacteriophage. ϕE12-2 possessed an isometric head that was ~ 62 nm in diameter and a contractile tail that was ~ 152 nm long and ~ 21 nm in diameter (Fig. 1A). Similar to ϕ52237, ϕE12-2 can be classified as a member of the order Caudovirales and the family Myoviridae .
B. pseudomallei 644 spontaneously produced 2 bacteriophages, ϕ644-1 and ϕ644-2, that formed plaques on B. mallei ATCC 23344. ϕ644-1 and ϕ644-2 produced plaques of different size and turbidity. ϕ644-2 was ten times more abundant in B. pseudomallei 644 culture supernatants. Based on its morphology, ϕ644-2 can be classified as a member of the order Caudovirales and the family Siphoviridae . The genome of ϕ644-1, a member of the Myoviridae family, could not be determined in this study.
B. thailandensis E255 spontaneously produced a bacteriophage, designated ϕE255, which formed turbid plaques with a diameter of ~ 0.5 mm on B. mallei ATCC 23344. No other plaque types were identified. Based on its morphotype, ϕE255 can be classified as a member of the order Caudovirales and the family Myoviridae .
B. thailandensis E202 spontaneously produced a bacteriophage, designated ϕE202, which formed turbid plaques on B. mallei ATCC 23344. No other plaque types were identified. ϕE202 production was increased 55-fold by brief exposure to UV light (data not shown). Based on its morphotype (Fig. 1A), ϕE202 can be classified as a member of the order Caudovirales and the family Myoviridae . We examined the host range of ϕE202 using 17 Burkholderia species (Additional file 1, Table S1). Bacteriophage ϕE202 formed plaques on 9 of 10 natural B. mallei strains. It also formed plaques on a capsule-deficient mutant derived from ATCC 23344, DD3008 , suggesting that the capsular polysaccharide is not required for ϕE202 attachment. In contrast, two B. mallei strains that do not produce lipopolysaccharide (LPS) were resistant to plaque formation by ϕE202; NCTC 120 and DD110795 (a laboratory-passaged derivative of ATCC 15310), which suggests that LPS is a receptor, or co-receptor, for ϕE202. Given the >90% nucleotide identity of the tail assembly genes of the Burkholderia Myoviridae, it is likely that they all share the same receptor(s). Unlike other characterized Burkholderia Myoviridae (ϕE125, ϕ1026b), ϕE202 forms plaques on a species other than B. mallei (Additional file 1, Table S1), namely 3 strains of B. pseudomallei; NCTC 4845, STW 199-2, and STW 115-2. It is currently unknown why these B. pseudomallei strains exhibit plaque formation with ϕE202 while others do not. No other Burkholderia species examined formed plaques with ϕE202 (Additional file 1, Table S1).
Genomic analysis of the Burkholderia phages
I. Myoviridae subgroup A and B
The modules for tail assembly, lysis, and head assembly of all Myoviridiae phages were highly conserved (Fig. 1B). However, the region encoding for lysogeny and DNA replication contained abundant genetic variability. Some of the genes within this region were present exclusively in either of the subgroups (Fig. 1B). This suggests that the mechanism of integration, regulation of excision, and/or replication of episomal bacteriophage DNA could be distinct for subgroup A and B Myoviridae. For example, subgroup A bacteriophage genomes encode DNA primase proteins which catalyze the synthesis of short RNA primers required for DNA replication by DNA polymerases (Fig. 1 B). Subgroup B bacteriophages, on the other hand, encode for ParA-like partitioning proteins which are ATPases involved in chromosome partitioning. In addition, subgroup B genomes encode replication gene A protein-like sequences. Members of this family of proteins are endonucleases which introduce single-strand nicks at or near the origin of replication (Fig. 1B).
Among the conserved regions, some segments are variably present in the bacteriophages and PIs (Fig. 1B). It is likely that these regions were acquired by recombination with unrelated bacteriophages (or prophages), and that these segments might be considered 'morons' . This is supported by the fact that these regions exhibit a lower % GC content relative to the rest of the bacteriophage genomes (Fig. 1B), which suggests horizontal transfer of genetic information. Most of these novel genes encode conserved hypothetical proteins which have no defined functional activities, but share similarity with proteins in other bacteriophages. No obvious virulence factor genes are encoded by these bacteriophage genomes, which is consistent with a previous report on this topic . Interestingly, ϕE12-2 gp6 and gp7 appear to encode a type II toxin-antitoxin (TA) addiction module (Fig. 1B - see below) . Other novel proteins are encoded by the ϕ52237, ϕE202, and ϕE12-2 genomes (Fig. 1B), but no functions can be assigned to these gene products at this time.
The phage attachment sites (attP) of ϕ52237 and ϕE202 are found at the 3' ends of putative site-specific integrase genes (Fig. 1B) and are identical to each other. The nucleotide sequence of attP contained a 45-bp sequence that was identical to the 3' end of the phenylalanine tRNA (GAA) gene on chromosome 1 of B. pseudomallei K96243 (positions 145,379-145,454). This attP site is also utilized by ϕK96243 . The integrase genes of these three subgroup A Myoviridae terminate with the tRNA (Phe) gene when integrated as prophages, but not when the bacteriophage genomes are episomal. Thus, following integration the integrase gene is partitioned into two fragments.
The ϕE12-2 attP site is located between gp24 and gp25 (5'-AATTTGACATAAGGTAAA-3') (Fig. 1B) and is identical to the sequence at both ends of GI15 in B. pseudomallei K96243 . This integration site is present in an intergenic region on the B. pseudomallei genome and does not disrupt any obvious ORFs. This attP site does not have any homology to tRNAs. PI-E264-2 is also flanked by a similar sequence (5'-ATTTGACATAACGTAAA-3') in B. thailandensis E264, suggesting that it also uses this attP. No obvious integrase genes are encoded by ϕE12-2, GI15, or PI-E264-2, which suggests these subgroup B Myoviridae use a different mechanism of integration.
The ϕE255 genome shares ~ 90% nucleotide sequence identity with the genome of BcepMu, a Mu-like bacteriophage spontaneously produced by Burkholderia cenocepacia strain J2315 . Similar to BcepMu, the ϕE255 genome can be divided into functional clusters from the left end to the right end of the linear phage genome: replication and regulation, host lysis, head assembly, and tail assembly (Fig. 1D). ϕE255 encodes a transposase with a Rve integrase domain (gp40, PFAM PF00665) that allows transposition as a mechanism of replication. Following replicative transposition, DNA is packaged into the bacteriophage heads using a pac site at the left end of the bacteriophage genome which allows 200-2,000 bp of flanking host DNA to also be packaged . The genomic sequence of ϕE255 (accession number NC_009237) contains 467 bp of host DNA sequence (Bm ATCC23344). The left and right ends of the linear ϕE255 genome contain 23-bp imperfect direct repeats that could be recognized by gp40 during replicative transposition (Fig. 1D). These repeats are similar to those found at the ends of the BcepMu genome  and the nucleotide differences are underlined in Fig. 1D.
Three regions of the ϕE255 genome are not present in the BcepMu genome and appear to be ϕE255-specific (gray shading in Fig. 1D). The unique regions are found at the left and right ends of the ϕE255 genome, which is consistent with the location of unique sequences in BcepMu and other BcepMu-like prophages . The two unique genes on the left side of the bacteriophage genome, gene41 and gene46, encode a conserved hypothetical protein and a lambda C1 repressor-like transcriptional regulator, respectively (Fig. 1D). These proteins are presumably involved in ϕE255 activation and/or replication. Five unique genes are encoded on the extreme right end of the ϕE255 genome, including genes 26-30 (Fig. 1D). Gp26 encodes a putative tail fiber protein which presumably is required for attachment and probably provides host receptor specificity to this bacteriophage. It is interesting that this gene, and the downstream tail assembly chaperone protein (gp27), are the only tail assembly genes that are not conserved in BcepMu. This suggests that the BcepMu receptor(s) on B. cenocepacia is distinct from the ϕE255 receptor(s) on B. thailandensis and B. mallei. Furthermore, it suggests that the unique tail fiber protein and a tail assembly chaperone protein (gp27) were either acquired by ϕE255 via horizontal transfer or lost by BcepMu. Gp28 is a hypothetical protein with no functional prediction, but gp29 is a putative ABC (ATP-binding cassette) transporter protein (Fig. 1D). It is possible that ϕE255 gp29 is involved in the import of a nutrient or export of toxic metabolites that confers a selective advantage on the lysogen harboring it. On the other hand, Lactococcus lactis bacteriophage P335  and Streptococcus pyogenes bacteriophage ϕNIH1.1  also encode ABC transporters and these molecules may play an undefined role in the bacteriophage lifecycle. Finally, gp30 is a putative formyl transferase domain protein (Fig. 1D), a family of proteins involved in a variety of biochemical pathways, including de novo purine biosynthesis, methionyl-tRNA biosynthesis, and formate biosynthesis. None of these ϕE255 genes have homologs in any of the other phage/PI or Burkholderia genomes reported here or elsewhere.
The gene order and modular organization of the ϕ644-2 genome is reminiscent of lambdoid bacteriophages, including ϕ1026b and ϕE125 [6, 21, 46, 47]. The ϕ644-2 genome harbors five regions that are specific to ϕ644-2 and contain a lower GC content than the rest of the ϕ644-2 genome, suggesting they may have been acquired horizontally from a novel source (gray shading in Fig. 1C). The thirteen novel genes present in these regions encode hypothetical proteins with no known function (gp22, gp23, gp24, gp33, gp34, gp35, gp46, gp47, gp48, gp49, gp55, gp66, and gp67). The genome also contains several interesting features, including a putative phosphoadenosine phosphosulphate (PAPS) reductase (gp56), a putative type II toxin-antitoxin module (gp69 and gp70), and a putative HNH endonuclease (gp71) that might be advantageous to the phage or its lysogen (Fig. 1C; discussed further below).
The ϕ644-2 genome contains ten base 3' single-stranded extensions on the left (3'-GCGGGCGAAG-5') and right (5'-CGCCCGCTTC-3') (Fig. 1C). In ϕE125, this sequence serves as a cohesive (cos) site , suggesting that ϕ644-2 uses the same cos site as ϕE125. The nucleotide sequence immediately downstream of gene36, which encodes a putative site-specific integrase, contained the candidate attP site of ϕ644-2. It is characterized by a 30-bp sequence that was identical to the 3' end of a 90-bp serine tRNA (GGA) gene on the B. pseudomallei K96243 small chromosome [3, 4] (Fig. 1C). Interestingly, a 19-kb prophage-like island (GI13) is also integrated at this location in the B. pseudomallei K96243 genome [3, 4], although there is no sequence similarity between the two elements.
Inferred prophage islands
Twenty-four putative prophage or prophage-like regions were identified in 11 of the 20 Burkholderia strains (Table 1B). In addition, two GIs from K96243 (GI3 and GI15) were included in subsequent analysis since these also classify as putative prophage by our definition . We call these regions prophage islands (PI) defined as regions of the genome that were found to contain most if not all of the elements characteristic of prophages (see Materials and Methods), but have not been isolated and experimentally characterized. Most B. pseudomallei and all B. multivorans strains were found to contain PIs; three were identified in B. thailandensis E264, one in B. xenovorans LB400, and none in any of the B. mallei strains. The three B. thailandensis E264 PIs, PI-E264-1, -2, and -3, correspond to B. thailandensis GI1, Bt GI13, and Bt GI12, respectively, as described by Yu et al , although the range of genes in the PIs described here differ slightly due to our criteria for inclusion. Similarly, PI-668-1 corresponds to GI15c from B. pseudomallei MSHR668 in Tuanyok et al . As mentioned above, no PIs were detected in B. pseudomallei 1106a/b, although phage-like remnants were found in these strains. Overall, seventeen of the 24 identified regions were located on chromosome I of the respective bacterial strain, and all but five were putative prophages (i.e., most likely to be active prophages containing all of the prophage-like elements described in the Materials and Methods). Of the seven regions located on chromosome II, one (PI-E264-3) was classified as a putative prophage, while the remaining six were designated prophage-like.
Paired strains B. pseudomallei 1710a/b and B. pseudomallei 1106a/b
The two pairs B. pseudomallei 1710a/b and B. pseudomallei 1106a/b represent two bacterial strains isolated at different time points from the same two infected patients, isolated from the primary infection (a) and the relapse (b). We hypothesized that difference/s in sequence relating to the relapse or host selection would be detected, either in the form of SNPs/indels or as variation in the phage harbored within each strain. Three PIs were identified in each of the B. pseudomallei 1710 strains. PI-1710a/b-1 is immediately followed by PI-1710a/b-2 on chromosome I, separated by a tRNA pseudogene in each strain. This region is described as GI6b in Tuanyok et al. . PI-1710a/b-3 is located further downstream on chromosome I. All three regions are nearly identical, averaging 98.4, 97.7, and 96.6% identity over 98.2, 97.1, and 96.2% of length (for -1, -2, and -3, respectively). PI-1710a-1 and PI-1710b-1 are 41.3 and 41.4 kb in length, respectively, and both are bounded by tRNA-Pseudo-2 and a 23 bp exact repeat of the 3' end of this tRNA. Both PI-1710a-2 and PI-1710b-2 are 60.6 kb in size and are bounded by tRNA-Pro-2 and a 49 bp exact repeat. The prophage-like regions in both strains (PI-1710a-3, PI-1710b-3) are defined by the presence of a phage integrase at the 3' end by tRNA-Thr-3, with several viral-like proteins immediately upstream, but no repeat region could be identified to define the 5' end. Both are 62.8 kb. Since the three prophage islands are nearly identical between B. pseudomallei 1710a and B. pseudomallei 1710b, from here on we will only refer to B. pseudomallei 1710b and associated prophage islands. These results indicate that the prophage in Bp 1710a/b were not excised and did not experience any significant changes even after passage through a host.
By the definitions set forth for prophage islands given in this work, no PIs were identified in either of the B. pseudomallei 1106 strains. Tuanyok et al.  described 16 genomic islands in 1106a, one of which was identified as a putative prophage (GI10.2; BURPS1106A_3666 - 3701). However, this region also contains three transposases, and so was not considered in the analysis reported here.
Results from the Dotter analysis allowed a preliminary clustering of prophages and prophage-like regions. These groups were further refined by examination of BLASTP protein distance data, resulting in the clustering of 32 of the 37 PIs and prophages into each of four groups (data not shown). Cluster composition was very similar between the three BLASTP-distance FITCH trees and agreed with DOTTER results, although branch positions varied slightly (Fig. 2). Seven prophages/PIs clustered into the Siphoviridae-like group, so named because of the inclusion of the previously published bacteriophages ϕ1026b  and ϕE125 . Bacteriophage ϕ644-2, described in this study, is also a member of this group (Fig. 2). Prophages in this group have long non-contractile tails and termini with cohesive ends. The cos site, present in ϕ1026b and ϕE125, was identified in all other members of this group.
The Myoviridae-like group consists of 15 prophages/PIs (Fig. 2). Phages in this group, identified by the inclusion of ϕK96243 (GI2)  and ϕ52237, typically have contractile tails and terminal repeats . Three subgroups were identified within the Myoviridae-like class (Fig. 2). Subgroup A contains ϕK96243, ϕ52237, ϕE202, and four other prophages/PIs. Bacteriophage ϕE12-2 and five prophages/PIs clustered to form subgroup B, including two (PI-406E-2 and PI-S13-2) which appear to be more distantly related. The Mu-like Myoviridae group contains only two prophages: BcepMu  and ϕE255. Both left and right phage ends at the host/phage junction in BcepMu  were located at the ends of ϕE255, with 95% and 91% identity, respectively. No significant identity was found between either of the two Mu-like prophages and any of the other prophages or prophage-like sequences.
Two undefined groups were also identified: undefined-1 contains four PIs, and undefined-2 has five (Fig.2). Interestingly, undefined-2 contains five of the eight PIs identified in the three B. multivorans strains. Finally, six sequences had no significant similarity to any other sequence and were thus considered unclustered, including PI-668-1, PI-406E-1, PI-LB400-1, GI3, Bcep22 and Bcep781.
Burkholderia bacteriophages are populated by morons
Morons identified among phages and PI in Burkholderia species.
Predicted Moron Function*
Species with closest BLAST hit
Abortive infection resistance
Addiction module (killer - antidote)
Aromatic compound degradation (2 genes)
CW surface anchor 1
CW surface anchor 2 proteophosphoglycan 5
HNH motif (DNA endonuclease)
ImpA family protein
Patatin-like phospholipase (1)
Patatin-like phospholipase (2)
Phage growth limitation system (pglY, pglZ)
Pyocin repressor protein (PrtR)
Pyocin-related (R2_PP-tail formation)(1)
Pyocin-related (R2_PP-tail formation)(2)
Azotobacter vinelandii Phage
Pyocin-related (TraC domain)
Reverse transcriptase (UG1)
Reverse transcriptase (UG3 & 8)
Soluble lytic murein trans glycolase
TA system (relE)
Beggiatoa sp. PS
TI secretion (tolC)
TII secretion (eha)
TIII restriction-modification system (2 genes)
Type I restriction-modification system (4 genes)
Analysis of predicted functions of the Burkholderia morons shows that several of these proteins may enhance bacteriophage fitness, and thus replication, as proposed for other morons . For example, two different morons containing toxin-antitoxin modules were found among the Myoviridae and Siphoviridae groups (Table 2). Interestingly, the T-A module in the Myoviridae phages is similar to two modules present in other B. pseudomallei and even B. mallei strains in regions containing phage remnants (data not shown), suggesting that this moron can persist even after the phage has been excised from the genome.
Several of the morons appeared to enhance the metabolic versatility of the host: aromatic compound degradation, iron transport and acquisition, and sulfate assimilation (Table 2). For example, it has been suggested that the PAPS reductase gene, which functions in the assimilatory sulfate reduction pathway, could serve as a fitness factor under conditions of iron limitation for the lysogens that harbor prophages encoding this enzyme . PAPS reductase genes were identified in three members of the Siphoviridae-like group, ϕE125, ϕ644-2 and PI-E264-3 (Fig. 4), and in the Myoviridae-like B subgroup member PI-E264-2. The PAPS reductase moron incorporated between two highly conserved phage genes (Fig. 4) at a location that appears to be an insertion hotspot, since the other members of this group contain different morons (Fig. 4 and rectangles in Fig. 3).
Other morons appear to be associated with enhanced host or bacteriophage competitiveness. For example, morons within the Myoviridae, Undefined-1, Undefined-2, and Siphoviridae encode for the production of toxins that inhibit the growth of competing bacterial strains (bacteriocins) and/or their associated translocation mechanisms (Table 2). Other morons could prevent infection of their host by other phage, these include morons that encode for site-specific endonucleases, DNA methylases, restriction-modification systems, phage abortive infection resistance, and phage-growth limiting genes. Although we could not confirm that GI3 from K96243 contains morons (since LCB analysis was limited to those PIs that formed clusters), two separate reverse-transcriptase (RT) modules are encoded in this PI. Many phage-encoded RT described to date also function in phage resistance by directly targeting other phage DNA.
Lastly, some of the morons encode for proteins associated with bacterial virulence (Table 2). Two different morons encode patatin-like phospholipases (PTP), which in P. aeruginosa can act as cytotoxins necessary for virulence in amoeba and contribute to lung injury in a mouse model [18, 49, 50]. Moreover, a prophage-encoded phosholipase in group A Streptococcus also appears to enhance virulence and its expression results in more severe disease . Two other morons encode for a proteophosphoglycan and a lytic transglycosylase, both of which have been associated with virulence in other pathogens . Thus, some phages in Burkholderia spp. might also be implicated in enhanced virulence.
Moron and phage genes are differentially expressed in Bp DD503
RNASeq analysis of gene expression of phage genes in Bp DD503.
Expression value (RPKM)*
putative portal protein
putative major capsid protein
putative tail length tape measure protein
putative DNA adenine methylase
PAAR repeat-containing protein
VRR-NUC domain protein
putative site-specific integrase
putative LysR family transcriptional regulator
putative major facilitator family permease
putative transcriptional regulator
XRE familiy putative transcriptional regulator
addiction module toxin, RelE/StbE family
In addition to the highly expressed repressor, several of the morons in ϕ1026b were also expressed, consistent with the notion that morons are differentially regulated from the rest of the prophage genes as proposed by Hendrix et al. The toxin-antidote morons were highly expressed, with the toxin gene (phi1026bp82) 1.5-fold higher than the antidote gene (phi1026bp81; Table 3). The DNA methylase and restriction modification moron (phi1026bp28-30), major facilitator permease, LysR transcriptional regulator and other morons with hypothetical proteins present among the genome were also highly expressed (Table 3) independently of the phage genes in their vicinity, further suggesting that phages represent a rich source of fitness factors that benefit the host even while the phage genes are repressed.
The vast diversity in pathogenicity, clinical presentation, and living environments that exists within and between the Burkholderiae can be attributed at least in part to the presence of prophages and prophage-like elements within the genomes of these microbes. In this report we have characterized and classified 37 prophages, putative prophages, and prophage-like elements identified from several Burkholderia species and strains within species. Five spontaneously produced bacteriophages of lysogenic B. pseudomallei and B. thailandensis were isolated and characterized, including their host range, genome structure, and gene content. Using bioinformatic techniques, 24 putative prophages and prophage-like elements were identified within whole genome sequences of various Burkholderia species. Interestingly, while putative prophages were found in all but one of the B. pseudomallei strains none were detected in any of the B. mallei strains searched. The B. mallei genome is nearly identical to that of B. pseudomallei, differing by several contiguous gene clusters in B. pseudomallei that appear to have been deleted from B. mallei, and it is hypothesized that B. mallei evolved from a single B. pseudomallei strain [8, 9]. If true, it is likely that this B. pseudomallei strain had at least one prophage within its genome that was excised from B. mallei leaving behind a toxin-antitoxin module. The prophage excision was part of a major host adaptation in B. mallei that also removed ~1200 other genes . In addition, B. mallei is largely confined to a mammalian host in nature and is less likely to be exposed to new bacteriophages in this niche relative to other Burkholderia species that are commonly found in the soil/plant rhizosphere. Taken together, prophage elimination and limited prophage acquisition probably account for the lack of functional prophages in the B. mallei genome.
Sequences of the five isolated and sequenced bacteriophages, the 24 inferred prophages, and eight previously published Burkholderia prophages or putative prophages were classified based on nucleotide and protein sequence similarity, and an unrooted radial tree was constructed to estimate genetic relatedness between them. Several sequences could be classified as Siphoviridae-like, Myoviridae-like, or Mu-like Myoviridae based on similarity to phages known to be members of these groups. Additionally, two novel groups were detected, and five prophages/PIs could not be grouped with other phages. For the most part the phage groups were represented across all species and strains, with the notable exception of the undefined-2 group, which is composed primarily of B. multivorans-derived PIs (five from B. multivorans, one from B. pseudomallei), albeit loosely related. Further work that includes prophages derived from environmental and clinical isolates from other Burkholderia species as well as from other microbes is needed to refine these relationships.
Burkholderia spp. are responsible for a number of potentially devastating infectious diseases for which no vaccines currently exist. The presence of a wide variety of bacteriophages within these bacteria opens the possibility that phage therapy may be developed to augment present antibiotic treatments. We present here a detailed comparative analysis of gene content within and between groups of bacteriophages, putative prophages, and prophage-like regions in various Burkholderia species and strains. Several interesting genes and gene groups associated with pathogenicity and various metabolic functions were identified within specific groups. This study provides the first estimate of the relative contribution of prophages to the vast phenotypic diversity found among the Burkholderiae.
This research was sponsored by the Medical Biological Defense Research Program, U.S. Army Medical Research and Materiel Command (project 02-4-5X-026). This project was also funded with federal funds from the National Institute of Allergy and Infectious Diseases, National Institutes of Health, Department of Health and Human Services under contract number N01-AI-30071.
We thank Kathy Kuehl for assistance with electron microscopy.
The opinions, interpretations, conclusions, and recommendations expressed here are those of the author and are not necessarily endorsed by the U.S. Army in accordance with AR 70-31.
- Rotz LD, Khan AS, Lillibridge SR, Ostroff SM, Hughes JM: Public health assessment of potential biological terrorism agents. Emerg Infect Dis. 2002, 8 (2): 225-230. 10.3201/eid0802.010164.PubMed CentralView ArticlePubMedGoogle Scholar
- Vietri N, DeShazer D: Melioidosis. Medical Aspects of Biological Warfare. Edited by: Dembek Z. 2007, Washington, DC: Dept of the Army, Office of the Surgeon General, Borden Institute, 225-230.Google Scholar
- Holden MT, Titball RW, Peacock SJ, Cerdeno-Tarraga AM, Atkins T, Crossman LC, Pitt T, Churcher C, Mungall K, Bentley SD: Genomic plasticity of the causative agent of melioidosis, Burkholderia pseudomallei. Proc Natl Acad Sci USA. 2004, 101 (39): 14240-14245. 10.1073/pnas.0403302101.PubMed CentralView ArticlePubMedGoogle Scholar
- Tuanyok A, Leadem BR, Auerbach RK, Beckstrom-Sternberg SM, Beckstrom-Sternberg JS, Mayo M, Wuthiekanun V, Brettin TS, Nierman WC, Peacock SJ: Genomic islands from five strains of Burkholderia pseudomallei. BMC Genomics. 2008, 9: 566-10.1186/1471-2164-9-566.PubMed CentralView ArticlePubMedGoogle Scholar
- Tumapa S, Holden MT, Vesaratchavest M, Wuthiekanun V, Limmathurotsakul D, Chierakul W, Feil EJ, Currie BJ, Day NP, Nierman WC: Burkholderia pseudomallei genome plasticity associated with genomic island variation. BMC Genomics. 2008, 9: 190-10.1186/1471-2164-9-190.PubMed CentralView ArticlePubMedGoogle Scholar
- DeShazer D: Genomic diversity of Burkholderia pseudomallei clinical isolates: subtractive hybridization reveals a Burkholderia mallei-specific prophage in B. pseudomallei 1026b. J Bacteriol. 2004, 186 (12): 3938-3950. 10.1128/JB.186.12.3938-3950.2004.PubMed CentralView ArticlePubMedGoogle Scholar
- Waag DM, DeShazer D: Glanders: New Insights into an Old Disease. Biological Weapons Defense: Infectious Diseases and Counterbioterrorism. Edited by: Lindler LE, Lebeda FJ, Korch GW. 2004, Totowa, NJ: Humana Press, IncGoogle Scholar
- Losada L, Ronning CM, DeShazer D, Woods D, Kim HS, Fedorova N, Shabalina SA, Tan P, Nandi T, Pearson T: Continuing evolution of Burkholderia mallei through genome reduction and large scale rearrangements. Genome Biol Evol. 2010, 2010: 102-116. 10.1093/gbe/evq003.View ArticleGoogle Scholar
- Nierman WC, DeShazer D, Kim HS, Tettelin H, Nelson KE, Feldblyum T, Ulrich RL, Ronning CM, Brinkac LM, Daugherty SC: Structural flexibility in the Burkholderia mallei genome. Proc Natl Acad Sci USA. 2004, 101 (39): 14246-14251. 10.1073/pnas.0403306101.PubMed CentralView ArticlePubMedGoogle Scholar
- Brett PJ, DeShazer D, Woods DE: Burkholderia thailandensis sp. nov., a Burkholderia pseudomallei-like species. Int J Syst Bacteriol. 1998, 48 (Pt 1): 317-320. 10.1099/00207713-48-1-317.View ArticlePubMedGoogle Scholar
- Smith MD, Angus BJ, Wuthiekanun V, White NJ: Arabinose assimilation defines a nonvirulent biotype of Burkholderia pseudomallei. Infect Immun. 1997, 65 (10): 4319-4321.PubMed CentralPubMedGoogle Scholar
- Moore RA, Reckseidler-Zenteno S, Kim H, Nierman W, Yu Y, Tuanyok A, Warawa J, DeShazer D, Woods DE: Contribution of gene loss to the pathogenic evolution of Burkholderia pseudomallei and Burkholderia mallei. Infect Immun. 2004, 72 (7): 4172-4187. 10.1128/IAI.72.7.4172-4187.2004.PubMed CentralView ArticlePubMedGoogle Scholar
- Mahenthiralingam E, Baldwin A, Dowson CG: Burkholderia cepacia complex bacteria: opportunistic pathogens with important natural biology. J Appl Microbiol. 2008, 104 (6): 1539-1551. 10.1111/j.1365-2672.2007.03706.x.View ArticlePubMedGoogle Scholar
- Figueroa-Bossi N, Uzzau S, Maloriol D, Bossi L: Variable assortment of prophages provides a transferable repertoire of pathogenic determinants in Salmonella. Mol Microbiol. 2001, 39 (2): 260-271. 10.1046/j.1365-2958.2001.02234.x.View ArticlePubMedGoogle Scholar
- Ventura M, Canchaya C, Pridmore D, Berger B, Brussow H: Integration and distribution of Lactobacillus johnsonii prophages. J Bacteriol. 2003, 185 (15): 4603-4608. 10.1128/JB.185.15.4603-4608.2003.PubMed CentralView ArticlePubMedGoogle Scholar
- Ventura M, Canchaya C, Bernini V, Altermann E, Barrangou R, McGrath S, Claesson MJ, Li Y, Leahy S, Walker CD: Comparative genomics and transcriptional analysis of prophages identified in the genomes of Lactobacillus gasseri, Lactobacillus salivarius, and Lactobacillus casei. Appl Environ Microbiol. 2006, 72 (5): 3130-3146. 10.1128/AEM.72.5.3130-3146.2006.PubMed CentralView ArticlePubMedGoogle Scholar
- Nakagawa I, Kurokawa K, Yamashita A, Nakata M, Tomiyasu Y, Okahashi N, Kawabata S, Yamazaki K, Shiba T, Yasunaga T: Genome sequence of an M3 strain of Streptococcus pyogenes reveals a large-scale genomic rearrangement in invasive strains and new insights into phage evolution. Genome Res. 2003, 13 (6A): 1042-1055. 10.1101/gr.1096703.PubMed CentralView ArticlePubMedGoogle Scholar
- Van Sluys MA, de Oliveira MC, Monteiro-Vitorello CB, Miyaki CY, Furlan LR, Camargo LE, da Silva AC, Moon DH, Takita MA, Lemos EG: Comparative analyses of the complete genome sequences of Pierce's disease and citrus variegated chlorosis strains of Xylella fastidiosa. J Bacteriol. 2003, 185 (3): 1018-1026. 10.1128/JB.185.3.1018-1026.2003.PubMed CentralView ArticlePubMedGoogle Scholar
- Boyd EF, Brussow H: Common themes among bacteriophage-encoded virulence factors and diversity among the bacteriophages involved. Trends Microbiol. 2002, 10 (11): 521-529. 10.1016/S0966-842X(02)02459-9.View ArticlePubMedGoogle Scholar
- Hendrix RW, Lawrence JG, Hatfull GF, Casjens S: The origins and ongoing evolution of viruses. Trends Microbiol. 2000, 8 (11): 504-508. 10.1016/S0966-842X(00)01863-1.View ArticlePubMedGoogle Scholar
- Woods DE, Jeddeloh JA, Fritz DL, DeShazer D: Burkholderia thailandensis E125 harbors a temperate bacteriophage specific for Burkholderia mallei. J Bacteriol. 2002, 184 (14): 4003-4017. 10.1128/JB.184.14.4003-4017.2002.PubMed CentralView ArticlePubMedGoogle Scholar
- Lech K, Brent R: Plating lambda phage to generate plaques. Current Protocols in Molecular Biology. Edited by: Ausubel FM, Brent R, Kingston RE, Moore DD, Seidman JG, Smith JA, Struhl K. 1987, New York: John Wiley & Sons, 1.11.11-11.11.14.Google Scholar
- Lin X, Kaul S, Rounsley S, Shea TP, Benito MI, Town CD, Fujii CY, Mason T, Bowman CL, Barnstead M: Sequence and analysis of chromosome 2 of the plant Arabidopsis thaliana. Nature. 1999, 402 (6763): 761-768. 10.1038/45471.View ArticlePubMedGoogle Scholar
- Yu Y, Kim HS, Chua HH, Lin CH, Sim SH, Lin D, Derr A, Engels R, DeShazer D, Birren B: Genomic patterns of pathogen evolution revealed by comparison of Burkholderia pseudomallei, the causative agent of melioidosis, to avirulent Burkholderia thailandensis. BMC Microbiol. 2006, 6: 46-10.1186/1471-2180-6-46.PubMed CentralView ArticlePubMedGoogle Scholar
- Chain PS, Denef VJ, Konstantinidis KT, Vergez LM, Agullo L, Reyes VL, Hauser L, Cordova M, Gomez L, Gonzalez M: Burkholderia xenovorans LB400 harbors a multi-replicon, 9.73-Mbp genome shaped for versatility. Proc Natl Acad Sci USA. 2006, 103 (42): 15280-15287. 10.1073/pnas.0606924103.PubMed CentralView ArticlePubMedGoogle Scholar
- Canchaya C, Proux C, Fournous G, Bruttin A, Brussow H: Prophage genomics. Microbiol Mol Biol Rev. 2003, 67 (2): 238-276. 10.1128/MMBR.67.2.238-276.2003. table of contentsPubMed CentralView ArticlePubMedGoogle Scholar
- Casjens S: Prophages and bacterial genomics: what have we learned so far?. Mol Microbiol. 2003, 49 (2): 277-300. 10.1046/j.1365-2958.2003.03580.x.View ArticlePubMedGoogle Scholar
- Altschul SF, Lipman DJ: Protein database searches for multiple alignments. Proc Natl Acad Sci USA. 1990, 87 (14): 5509-5513. 10.1073/pnas.87.14.5509.PubMed CentralView ArticlePubMedGoogle Scholar
- Summer EJ, Gonzalez CF, Carlisle T, Mebane LM, Cass AM, Savva CG, LiPuma J, Young R: Burkholderia cenocepacia phage BcepMu and a family of Mu-like phages encoding potential pathogenesis factors. J Mol Biol. 2004, 340 (1): 49-65. 10.1016/j.jmb.2004.04.053.View ArticlePubMedGoogle Scholar
- Summer EJ, Gonzalez CF, Bomer M, Carlile T, Embry A, Kucherka AM, Lee J, Mebane L, Morrison WC, Mark L: Divergence and mosaicism among virulent soil phages of the Burkholderia cepacia complex. J Bacteriol. 2006, 188 (1): 255-268. 10.1128/JB.188.1.255-268.2006.PubMed CentralView ArticlePubMedGoogle Scholar
- Sonnhammer EL, Durbin R: A dot-matrix program with dynamic threshold control suited for genomic DNA and protein sequence analysis. Gene. 1995, 167 (1-2): GC1-10. 10.1016/0378-1119(95)00714-8.View ArticlePubMedGoogle Scholar
- Rohwer F, Edwards R: The Phage Proteomic Tree: a genome-based taxonomy for phage. J Bacteriol. 2002, 184 (16): 4529-4535. 10.1128/JB.184.16.4529-4535.2002.PubMed CentralView ArticlePubMedGoogle Scholar
- Felsenstein J: PHYLIP (Phylogeny Inference Package), version 3.6. 2005, Department of Genome Sciences, University of Washington, Seattle, Distributed by the authorGoogle Scholar
- Darling ACE, Mau B, Blattner FR, Perna NT: Mauve: multiple alignment of conserved genomic sequence with rearrangements. Genome Res. 2004, 14 (7): 1394-1403. 10.1101/gr.2289704.PubMed CentralView ArticlePubMedGoogle Scholar
- Studholme DJ, Dixon R: Domain architectures of sigma 54-dependent transcriptional activators. J Bacteriol. 2003, 185 (6): 1757-10.1128/JB.185.6.1757-1767.2003.PubMed CentralView ArticlePubMedGoogle Scholar
- Reese MG: Application of a time-delay neural network to promoter annotation in the Drosophila melanogaster genome. Comput Chem. 2001, 26 (1): 51-56. 10.1016/S0097-8485(01)00099-7.View ArticlePubMedGoogle Scholar
- Kingsford C, Ayanbule K, Salzberg S: Rapid, accurate, computational discovery of Rho-independent transcription terminators illuminates their relationship to DNA uptake. Genome Biol. 2007, 8 (2): R22-10.1186/gb-2007-8-2-r22.PubMed CentralView ArticlePubMedGoogle Scholar
- Ackermann HW: Bacteriophage observations and evolution. Res Microbiol. 2003, 154 (4): 245-251. 10.1016/S0923-2508(03)00067-6.View ArticlePubMedGoogle Scholar
- DeShazer D, Waag DM, Fritz DL, Woods DE: Identification of a Burkholderia mallei polysaccharide gene cluster by subtractive hybridization and demonstration that the encoded capsule is an essential virulence determinant. Microb Pathog. 2001, 30 (5): 253-269. 10.1006/mpat.2000.0430.View ArticlePubMedGoogle Scholar
- Brussow H, Hendrix RW: Phage genomics: small is beautiful. Cell. 2002, 108 (1): 13-16. 10.1016/S0092-8674(01)00637-7.View ArticlePubMedGoogle Scholar
- Hendrix RW, Hatfull GF, Smith MC: Bacteriophages with tails: chasing their origins and evolution. Res Microbiol. 2003, 154 (4): 253-257. 10.1016/S0923-2508(03)00068-8.View ArticlePubMedGoogle Scholar
- Summer EJ, Gill JJ, Upton C, Gonzalez CF, Young R: Role of phages in the pathogenesis of Burkholderia, or 'Where are the toxin genes in Burkholderia phages?'. Curr Opin Microbiol. 2007, 10 (4): 410-417. 10.1016/j.mib.2007.05.016.PubMed CentralView ArticlePubMedGoogle Scholar
- Hayes F: Toxins-antitoxins: plasmid maintenance, programmed cell death, and cell cycle arrest. Science. 2003, 301 (5639): 1496-1499. 10.1126/science.1088157.View ArticlePubMedGoogle Scholar
- Labrie SJ, Josephsen J, Neve H, Vogensen FK, Moineau S: Morphology, genome sequence, and structural proteome of type phage P335 from Lactococcus lactis. Appl Environ Microbiol. 2008, 74 (15): 4636-4644. 10.1128/AEM.00118-08.PubMed CentralView ArticlePubMedGoogle Scholar
- Ikebe T, Wada A, Inagaki Y, Sugama K, Suzuki R, Tanaka D, Tamaru A, Fujinaga Y, Abe Y, Shimizu Y: Dissemination of the phage-associated novel superantigen gene speL in recent invasive and noninvasive Streptococcus pyogenes M3/T3 isolates in Japan. Infect Immun. 2002, 70 (6): 3227-3233. 10.1128/IAI.70.6.3227-3233.2002.PubMed CentralView ArticlePubMedGoogle Scholar
- Brussow H, Desiere F: Comparative phage genomics and the evolution of Siphoviridae: insights from dairy phages. Mol Microbiol. 2001, 39 (2): 213-222. 10.1046/j.1365-2958.2001.02228.x.View ArticlePubMedGoogle Scholar
- Juhala RJ, Ford ME, Duda RL, Youlton A, Hatfull GF, Hendrix RW: Genomic sequences of bacteriophages HK97 and HK022: pervasive genetic mosaicism in the lambdoid bacteriophages. J Mol Biol. 2000, 299 (1): 27-51. 10.1006/jmbi.2000.3729.View ArticlePubMedGoogle Scholar
- Buchen-Osmond C: ICTVdB - The Universal Virus Database, version 3. 2006, Columbia University, New YorkGoogle Scholar
- Sitkiewicz I, Stockbauer KE, Musser JM: Secreted bacterial phospholipase A2 enzymes: better living through phospholipolysis. Trends Microbiol. 2007, 15 (2): 63-69. 10.1016/j.tim.2006.12.003.View ArticlePubMedGoogle Scholar
- Pukatzki S, Kessin RH, Mekalanos JJ: The human pathogen Pseudomonas aeruginosa utilizes conserved virulence pathways to infect the social amoeba Dictyostelium discoideum. Proc Natl Acad Sci USA. 2002, 99 (5): 3159-3164. 10.1073/pnas.052704399.PubMed CentralView ArticlePubMedGoogle Scholar
- Sacks DL, Modi G, Rowton E, Späth G, Epstein L, Turco SJ, Beverley SM: The role of phosphoglycans in Leishmania-sand fly interactions. Proc Natl Acad Sci USA. 2000, 97 (1): 406-411. 10.1073/pnas.97.1.406.PubMed CentralView ArticlePubMedGoogle Scholar
- Woods DE: The use of animal infection models to study the pathogenesis of melioidosis and glanders. Trends Microbiol. 2002, 10 (11): 483-484. 10.1016/S0966-842X(02)02464-2. discussion 484-485View ArticlePubMedGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.