Circular Permutation of the Genome of a Temperate Bacteriophage from Streptococcus cremoris BK5

Characterization of a novel and active temperate phage vB_AbaM_ABMM1 with antibacterial activity against Acinetobacter baumannii infection

Acinetobacter baumannii is an opportunistic pathogen that significantly causes hospital-acquired infections. Due to its multidrug resistance, treating infections caused by this pathogen is challenging. Recently, phages have gained attention as a potential alternative to antibiotics in treating bacterial infections. While lytic phages are preferred in therapy, the use of temperate phages for this purpose has received less attention. This study characterized a novel temperate phage vB_AbaM_ABMM1 (ABMM1) with antibacterial activity toward A. baumannii. ABMM1 adsorbs quickly, has short latent periods, and is relatively stable at various temperatures and neutral pH. ABMM1 has an icosahedral head and a contractile tail. It has a 75,731 kb circular permuted dsDNA genome containing 86 gene products with 37.3% G + C content and a mosaic arrangement typical of temperate phages. Genomic analysis confirmed that ABMM1 does not have antibiotic-resistance genes or virulence-related factors. The packaging strategy was predicted in silico, suggesting that ABMM1 represents a headful phage. Only truncated ABMM1 prophage was detected and has similarity in the genome of several A. baumannii strains. Despite its ability to integrate into the host chromosome, the high MOI of ABMM1 (MOI 10) effectively killed the host bacterial cells and reduced the fatality rate of bacterial infection in the zebrafish model. These findings indicate that ABMM1 can be an alternative treatment for A. baumannii infection.

Whey powders are a rich source and excellent storage matrix for dairy bacteriophages

Thirteen whey powders and 5 whey powder formulations were screened for the presence of dairy bacteriophages using a representative set of 8 acid-producing Lactococcus lactis and 5 Streptococcus thermophilus, and 8 flavour-producing Leuconostoc pseudomesenteroides and Leuconostoc mesenteroides strains. Lytic L. lactis phages were detected in all samples, while S. thermophilus and Leuconostoc phages were present in 50% or 40% of the samples, respectively. Maximal phage titers were 6×10⁷ plaque-forming units (pfu)/g of whey powder for L. lactis phages, 1×10⁷pfu/g for Leuconostoc phages and 1×10⁵pfu/g for S. thermophilus phages. In total, 55 phages were isolated and characterized. Thirty one of the 33 lactococcal phages tested belonged to the wide-spread 936 phage group. In the course of this study, a PCR detection method for Leuconostoc phages (Ali et al., 2013) was adapted to new phage isolates. Furthermore, a remarkably high stability of phages in whey powder samples was documented during a long-term storage period of 4 years.

Isolation and characterization of a Lactobacillus fermentum temperate bacteriophage from Chinese yogurt

AIMS

The aim of this study was to investigate the properties of temperate bacteriophage of Lactobacillus fermentum, based on its morphology, restriction patterns, protein profile and the impact on the growth of host strain.

METHODS AND RESULTS

With Mitomycin C, seven temperate phages were induced from Lactobacilli derived from Chinese yogurt. The temperate phages induced belong to the most common Bradley's group B, having hexagonal head and long, noncontractile tail. They were furthermore confirmed to be the same bacteriophage by identical restriction patterns. SDS-PAGE profile showed that the phage studied had one major structure protein about 31.9 kDa. The presence of the prophage influenced the cell shape and colony size of its lysogenic strain.

CONCLUSIONS

The phage obtained had similar, but not complete identical properties with other L. fermentum phages reported. It influenced the growth behaviour of its lysogenic strain.

SIGNIFICANCE AND IMPACT OF THE STUDY

This study provides some information about bacteriophages occurring in the Chinese yoghurt manufacture and contributes to our knowledge on the bacteriophage diversity in the dairy industry.

Sequence analysis and molecular characterization of the Lactococcus lactis temperate bacteriophage BK5-T

The Lactococcus lactis temperate bacteriophage BK5-T is one of twelve type phages that define L. lactis phage species. This paper describes the nucleotide sequence and analysis of a 21-kbp region of the BK5-T genome and completes the nucleotide sequence of the genome of this phage. The 40,003-nucleotide linear genome encodes 63 open reading frames. Sequence runoff experiments showed that the cohesive ends of the BK5-T genome contained a 12-bp 3' single-stranded overhang with the sequence 5'-CACACACATAGG-3'. Two major BK5-T structural proteins, of approximately 30 and 20 kDa, were identified, and N-terminal sequence analysis determined that they were encoded by orf7 and orf12, respectively. A 169-bp fragment containing a 37-bp direct repeat and several smaller repeat sequences conferred resistance to BK5-T infection when introduced in trans to the host cell and is likely a part of the BK5-T origin of replication (ori).

Sequence analysis of the Lactococcus lactis temperate bacteriophage BK5-T and demonstration that the phage DNA has cohesive ends

The Lactococcus lactis temperate bacteriophage BK5-T is a type phage in the lactococcal phage classification (A. W. Jarvis, G. F. Fitzgerald, M. Mata, A. Mercenier, H. Neve, I. B. Powell, C. Ronda, M. Saxelin, and M. Teuber, Intervirology 32:2-9, 1991). The nucleotide sequence of 18,935 bp of the genome of BK5-T was determined and analyzed for the presence of open reading frames and other structural features. Thirty-two open reading frames longer than 60 codons were identified, and these appeared to be grouped into at least seven transcriptional units. A search of the nucleotide sequence for restriction sites identified a small number of discrepancies with the previously published physical map of the BK5-T genome (G. Lakshmidevi, B. E. Davidson, and A. J. Hillier, Appl. Environ. Microbiol. 54:1039-1045, 1988). Subsequent analysis of restriction digests of BK5-T DNA which were heated prior to electrophoresis indicated that BK5-T DNA was not terminally redundant as previously reported but contained cohesive ends.

Spontaneous deletion mutants of the Lactococcus lactis temperate bacteriophage BK5-T and localization of the BK5-T attP site

Spontaneous deletion mutants of the temperate lactococcal bacteriophage BK5-T were obtained when the phage was grown vegetatively on the indicator strain Lactococcus lactis subsp. cremoris H2. One deletion mutant was unable to form stable lysogens, and analysis of this mutant led to the identification of the BK5-T attP site and the integrase gene (int). The core sequences of the BK5-T attP and host attB regions are conserved in a number of lactococcal phages and L. lactis strains.

Identification of prophage genes expressed in lysogens of the Lactococcus lactis bacteriophage BK5-T

Bacteriophage BK5-T is a small isometric-headed temperate phage that infects Lactococcus lactis subsp. cremoris. Northern (RNA) analysis of mRNA produced by lysogenic strains containing BK5-T prophage revealed four major BK5-T transcripts that are 0.8, 1.3, 1.8, and 1.8 kb in size and enabled a transcription map of the prophage genome to be prepared. The position and size of each transcript corresponded closely to the position and size of open reading frames predicted from the nucleotide sequence of BK5-T. Analysis of the transcripts suggested that one of them was derived from the gene encoding the BK5-T integrase and another was from the gene encoding the BK5-T homolog of the lambda cI repressor. Computer analysis of the nucleotide sequence upstream of the BK5-T cI homolog predicted the presence of a pair of divergent promoters and three inverted repeat sequences, features characteristic of temperature-phage immunity regions. By analogy with lambda, the three inverted repeat sequences could be binding sites for cI or Cro homologs and the two divergent promoters could initiate transcription through the BK5-T equivalents of cI and cro.

Molecular characterization of lactococcal bacteriophage Tuc2009 and identification and analysis of genes encoding lysin, a putative holin, and two structural proteins

Bacteriophage Tuc2009 is a temperate bacteriophage with a small isometric head and is isolated from Lactococcus lactis subsp. cremoris UC509. The phage genome is packaged by a headful mechanism, giving rise to circularly permuted molecules with terminal redundancy. The unit genome size is approximately 39 kb. A map of the phage genome on which several determinants could be localized was constructed: pac, the site of initiation of DNA packaging; lys (1,287 bp), specifying the phage lysin; S (267 bp), specifying a putative holin; and mp1 (522 bp) and mp2 (498 bp), each specifying one of the phage's structural proteins. lys, S, mp1, and mp2 were further characterized. lys and S are partially overlapping and appear to be part of one operon. The lysin shows homology to the lysins of the Streptococcus pneumoniae phages Cp-9, Cp-1, and Cp-7. The putative holin, which is thought to be involved in the release of lysin from the cytoplasm, contains two strongly hydrophobic presumptive transmembrane domains and a highly charged C-terminal domain.

Genetic studies of lactococcal bacteriophages--taxonomic differentiations and DNA analysis: evidence for 3' cohesive ends

Twenty-four bacteriophages of Lactococcus lactis subsp. lactis and L. lactis subsp. cremoris were classified. Two groups of bacteriophages morphologically defined as prolate or isometric types by electron microscopy were examined for their genome sizes, protein patterns and DNA homologies. These criteria showed that prolate phages are quite homogeneous. In contrast, isometric phages exhibit more differences, particularly in particle sizes and protein compositions. Analysis of DNA hybridizations confirmed that prolate phages can be grouped together as can be isometric phages but for one exception, phage I52. These two families were clearly defined. The unique phage which does not fit in either group probably belongs to a third one which is much less represented. No obvious relationships between these criteria and the lytic spectra were detected. Evidence of the presence of cohesive ends in phage genomes is also presented in this study. A more detailed analysis performed on one member of the prolate group revealed 3' protruding ends made up of around 13 nucleotides on complementary single strands.

Characterization of the lactococcal temperate phage TP901-1 and its site-specific integration

The temperate lactococcal phage TP901-1, induced by UV light from Lactococcus lactis subsp. cremoris 901-1, was characterized. The restriction map was found to be circular, and the packaging of TP901-1 DNA was concluded to occur by a headful mechanism. The pac region was localized on the 38.4-kb phage genome. TP901-1 belongs to the class of P335 phages (V. Braun, S. Hertwig, H. Neve, A. Geis, and M. Teuber, J. Gen. Microbiol. 135:2551-2560, 1989). Evidence is presented that the phages TP936-1 (V. Braun, S. Hertwig, H. Neve, A. Geis, and M. Teuber, J. Gen. Microbiol. 135:2551-2560, 1989) and C3-T1 (A. W. Jarvis, V. R. Parker, and M. B. Bianchin, Can. J. Microbiol. 38:398-404, 1992) are very closely related to or are identical to TP901-1. The lytically propagated TP901-1 phages were able to lysogenize both indicator strains Lactococcus cremoris 3107 and Wg2. Lysogenization resulted in site-specific integration of the phage genome into the bacterial chromosome. Only one chromosomal attB site was found in 20 independent lysogens. The attP region of TP901-1 and the attL and attR regions were cloned and sequenced. The results showed a core region of only 5 bp, in which the recombination occurs, followed after a 1-bp mismatch by a 7-bp identical region, TCAAT(T/C)AAGGTAA. This result was further verified by sequencing of the attB region obtained by PCR. An integration vector was constructed with the 6.5-kb EcoRI fragment from TP901-1 containing attP. This vector also functions in the plasmid-free strains, MG1363 and LM0230 with only one specific attB site, strongly indicating a more general use of the TP901-1-based integration vector in lactococci.

Antisense RNA directed against the major capsid protein of Lactococcus lactis subsp. cremoris bacteriophage 4-1 confers partial resistance to the host

Antisense RNA targeted against the major capsid protein (MCP) of Lactococcus lactis subsp. cremoris bacteriophage F4-1 reduced bacteriophage replication by up to 50%. The region containing the mcp gene was oriented to transcribe the antisense strand using a L. lactis subsp. cremoris Wg2 promoter. The size of the mcp insert transcribed affected the level of bacteriophage inhibition and the greatest level of inhibition was achieved using a 301-bp fragment from the 5' end of the mcp. Antisense mcp RNA constructs were stable and did not alter the endogenous plasmid profile in the host, L. lactis subsp. cremoris F4-1. There were, however, some adverse effects on the host during the stationary phase as exhibited by a decline in cell density.

Use of antisense RNA to confer bacteriophage resistance in dairy starter cultures

The strategy and implementation of a unique system for engineering bacteriophage resistant starter cultures of Lactococcus lactis employing antisense RNA is reviewed. As a necessary prerequisite for developing this system, we have cloned and sequenced a number of bacteriophage genes coding for minor and major structural proteins. In addition, we have also identified a series of genes whose function(s) is not known but their sequences appear to be conserved in a vast number of isolates. One of these latter sequences, designated gp51C, codes for a 51-kDa protein which is extremely charged and shares some homology with yeast translation initiation factor. Resistance to a broad class of isometric bacteriophages has been achieved by expression of an antisense RNA targeted against, for example, gp51C. In the best case, expression of the antisense gp51C RNA results is a greater than 99% reduction in the total number of plaque forming units. Additional antisense RNA constructs directed against other bacteriophage genes, including the major capsid protein, also appear effective at inhibiting infection from 40-55% suggesting that this approach may prove useful for engineering a set of truly isogenic strains to be used in a starter culture rotation plan.

Molecular characterization of new group A streptococcal bacteriophages containing the gene for streptococcal erythrogenic toxin A (speA)

Bacteriophage T12 is the prototype phage carrying the streptococcal erythrogenic toxin A (speA) gene. To examine more closely the phages involved in lysogenic conversion, we examined 300 group A streptococcal strains, and identified and isolated two new phages that carry the speA gene. The molecular sizes of these phage genomes were between 32 and 40 kb, similar to that of phage T12 (35 kb). However, as ascertained by restriction analysis, the physical maps of the new phage genomes were different from phage T12 and from each other. Hybridization analysis also showed that all of these phages were only partially related to one another and the speA gene was always located close to the phage attachment site. Additionally, colony hybridization showed that whereas phage T12 or one of its close relatives is the most common phage associated with the group A streptococci, phage 49 has a much stronger association with the speA gene. A defective phage was also found following pulsed field gel electrophoresis of total phage DNA. This phage appears to be a resident of strain T25(3)c and is found only following induction of a T25(3)c lysogen. Restriction enzyme analysis of the isolated defective phage DNA suggests that it is the source of the submolar amounts of DNA previously found in association with phage T12 digestion patterns. Additionally, the defective phage may serve as the site of integration of the speA gene-carrying phages described above.

Characterization of phiLC3, a Lactococcus lactis subsp. cremoris temperature bacteriophage with cohesive single-stranded DNA ends

The temperate bacteriophage phiLC3, isolated from Lactococcus lactis subsp. cremoris, has an isometric head and a flexible tail containing 1 major protein and 8 minor proteins. Infection of a permissive L. lactis host strain yields a burst of about 50 phages per infected cell with a latent period of 60 min. A detailed restriction map of the phage chromosome was constructed by using 12 different restriction enzymes. The phage chromosome is a 33-kb linear double-stranded DNA molecule with unique cohesive ends and with a G + C content of 36.5%. Chemical sequencing of the DNA ends revealed 13-base 3' extended complementary single strands with a relatively high percentage of G + C. Pulsed-field gel electrophoretic analysis of DNA from a strain lysogenized with phiLC3 was used to localize the prophage to a 320-kb BamHI restriction endonuclease fragment from the host chromosomal DNA. This result indicates that lysogeny involves integration of the phage into the host chromosome. A spontaneous phiLC3 clear plaque mutant that was unable to give rise to lysogens was isolated.

Cloning and nucleotide sequence of the major capsid protein from Lactococcus lactis ssp. cremoris bacteriophage F4-1

The gene (mcp) coding for the major capsid protein (MCP) of the Lactococcus lactis ssp. cremoris bacteriophage F4-1 has been cloned and its nucleotide sequence determined. The mcp gene was localized, by Western blotting with rabbit antiserum against intact bacteriophage, within a 3.3-kb HindIII-Spe I fragment and the sequence of the entire region determined. The 35-kDa MCP is coded for by a 905-bp open reading frame preceded by a putative ribosome-binding site. Deletion analysis and N-terminal sequencing of the MCP confirmed the identification of the gene coding for this bacteriophage MCP.

Temperate bacteriophages and lysogeny in lactic acid bacteria

Lysogeny is widespread in the lactic acid bacteria. The majority of lysogens can be induced by UV irradiation or treatment with mitomycin C, but indicator strains which allow lytic growth of the induced phage are often not easy to identify. A few temperate phages have been shown to transduce chromosomal and/or plasmid markers. Information about the molecular biology of the temperate phages from lactic acid bacteria is sparse and needs significant supplementation in order that these potentially valuable phages might be utilized more efficiently as tools for improving existing starter strains in dairy fermentations.

Molecular characterization of promoters of the Lactococcus lactis subsp. cremoris temperate bacteriophage BK5-T and identification of a phage gene implicated in the regulation of promoter activity

DNA fragments from the temperate lactococcal bacteriophage BK5-T were cloned into the promoter-detecting plasmid pMU1328. Five DNA fragments conferring promoter activity were selected by transformation of Streptococcus sanguis and were functional in Escherichia coli, S. sanguis, and Lactococcus lactis subspp. lactis and cremoris. The nucleotide sequences of these fragments were determined, and primer extension analysis was used to locate the site of initiation of transcription from each promoter in both E. coli and S. sanguis. Transcription was initiated from the same nucleotide in these two organisms, and the promoters contained -10 and -35 regions similar to the consensus sequence for E. coli promoters. The activities of three of the five promoters were decreased two- to threefold when a compatible plasmid containing a 3.8-kilobase-pair EcoRI fragment (EcoRI-f) of BK5-T was coresident with the promoter-containing plasmid in either L. lactis subsp. cremoris or E. coli. Data from Tn5 mutagenesis, subcloning experiments, and DNA sequence analysis indicate that this decrease in promoter activity requires a region of EcoRI-f that contains a 621-base-pair open reading frame. This region has been designated bpi (for BK5-T promoter inhibitor).