The nicking homing endonuclease I-BasI is encoded by a group I intron in the DNA polymerase gene of the Bacillus thuringiensis phage Bastille

Here we describe the discovery of a group I intron in the DNA polymerase gene of Bacillus thuringiensis phage Bastille. Although the intron insertion site is identical to that of the Bacillus subtilis phages SPO1 and SP82 introns, the Bastille intron differs from them substantially in primary and secondary structure. Like the SPO1 and SP82 introns, the Bastille intron encodes a nicking DNA endonuclease of the H-N-H family, I-BasI, with a cleavage site identical to that of the SPO1-encoded enzyme I-HmuI. Unlike I-HmuI, which nicks both intron-minus and intron-plus DNA, I-BasI cleaves only intron-minus alleles, which is a characteristic of typical homing endonucleases. Interestingly, the C-terminal portions of these H-N-H phage endonucleases contain a conserved sequence motif, the intron-encoded endonuclease repeat motif (IENR1) that also has been found in endonucleases of the GIY-YIG family, and which likely comprises a small DNA-binding module with a globular ββααβ fold, suggestive of module shuffling between different homing endonuclease families.     

Identification of a genetic determinant responsible for host specificity in Streptococcus thermophilus bacteriophages

Phage-host interactions remain poorly understood in lactic acid bacteria and essentially in all Gram-positive bacteria. The aim of this study was to identify the phage genetic determinant (anti-receptor) involved in the recognition of Streptococcus thermophilus hosts. The complete genomic sequence of the lytic S. thermophilus phage DT1 was determined previously, and bioinformatic analysis indicated that orf18 might be the anti-receptor gene. The orf18 of six additional S. thermophilus phages was determined (DT2, DT4, MD1, MD2, MD4 and Q5) and compared with the orf18 of DT1. The deduced ORF18 was divided into three domains. The first domain, which contains the N-terminal part of the protein, was conserved in all seven phages. The second domain was detected in only two phages and flanked by a motif called collagen-like repeats. The second domain also contained a variable region (VR1). All seven phages had a third domain that consisted of the C-terminal section of the protein as well as another variable region (VR2). Chimeric DT1 phages were constructed by recombination; a portion of its orf18 was replaced by the corresponding section in orf18 of the phage MD4. All DT1 chimeric phages acquired the host range of phage MD4. Analysis of the orf18 in the chimeric phages revealed that host specificity in phages DT1 and MD4 resulted from VR2. This is the first report on the identification and characterization of a phage gene involved in the host recognition process of Gram-positive bacteria.     

Group I intron homing in Bacillus phages SPO1 and SP82: a gene conversion event initiated by a nicking homing endonuclease

Many group I introns encode endonucleases that promote intron homing by initiating a double-stranded break-mediated homologous recombination event. In this work we describe intron homing in Bacillus subtilis phages SPO1 and SP82. The introns encode the DNA endonucleases I-HmuI and I-HmuII, respectively, which belong to the H-N-H endonuclease family and possess nicking activity in vitro. Coinfections of B. subtilis with intron-minus and intron-plus phages indicate that I-HmuI and I-HmuII are required for homing of the SPO1 and SP82 introns, respectively. The homing process is a gene conversion event that does not require the major B. subtilis recombination pathways, suggesting that the necessary functions are provided by phage-encoded factors. Our results provide the first examples of H-N-H endonuclease-mediated intron homing and the first demonstration of intron homing initiated by a nicking endonuclease.     

A self-splicing group I intron in the DNA polymerase gene of Bacillus subtilis bacteriophage SPO1

We report a self-splicing intron in bacteriophage SPO1, whose host is the gram-positive Bacillus subtilis. The intron contains all the conserved features of primary sequence and secondary structure previously described for the group IA introns of eukaryotic organelles and the gram-negative bacteriophage T4. The SPO1 intron contains an open reading frame of 522 nucleotides. As in the T4 introns, this open reading frame begins in a region that is looped out of the secondary structure, but ends in a highly conserved region of the intron core. The exons encode SPO1 DNA polymerase, which is highly similar to E. coli DNA polymerase I. The demonstration of self-splicing introns in viruses of both gram-positive and gram-negative eubacteria lends further evidence for their early origin in evolution.     

Distribution, sequence homology, and homing of group I introns among T-even-like bacteriophages: evidence for recent transfer of old introns

Self-splicing group I introns are being found in an increasing number of bacteriophages. Most introns contain an open reading frame coding for a homing endo-nuclease that confers mobility to both the intron and the homing endonuclease gene (HEG). The frequent occurrence of intron/HEG has raised questions whether group I introns are spread via horizontal transfer between phage populations. We have determined complete sequences for the known group I introns among T-even-like bacteriophages together with sequences of the intron-containing genes td, nrdB, and nrdD from phages with and without introns. A previously uncharacterized phage isolate, U5, is shown to contain all three introns, the only phage besides T4 found with a "full set" of these introns. Sequence analysis of td and nrdB genes from intron-containing and intronless phages provides evidence that recent horizontal transmission of introns has occurred among the phages. The fact that several of the HEGs have suffered deletions rendering them non-functional implies that the homing endonucleases are of no selective advantage to the phage and are rapidly degenerating and probably dependent upon frequent horizontal transmissions for maintenance within the phage populations. Several of the introns can home to closely related intronless phages during mixed infections. However, the efficiency of homing varies and is dependent on homology in regions flanking the intron insertion site. The occurrence of optional genes flanking the respective intron-containing gene can strongly affect the efficiency of homing. These findings give further insight into the mechanisms of propagation and evolution of group I introns among the T-even-like bacteriophages.     

The DNA polymerase genes of several HMU-bacteriophages have similar group I introns with highly divergent open reading frames.

A previous report described the discovery of a group I, self-splicing intron in the DNA polymerase gene of the Bacillus subtilis bacteriophage SPO1 (1). In this study, the DNA polymerase genes of three close relatives of SPO1: SP82, 2C and phi e, were also found to be interrupted by an intron. All of these introns have group I secondary structures that are extremely similar to one another in primary sequence. Each is interrupted by an open reading frame (ORF) that, unlike the intron core or exon sequences, are highly diverged. Unlike the relatives of Escherichia coli bacteriophage T4, most of which do not have introns (2), this intron seems to be common among the relatives of SPO1.     

Genomic organization and molecular analysis of virulent bacteriophage 2972 infecting an exopolysaccharide-producing Streptococcus thermophilus strain

The Streptococcus thermophilus virulent pac-type phage 2972 was isolated from a yogurt made in France in 1999. It is a representative of several phages that have emerged with the industrial use of the exopolysaccharide-producing S. thermophilus strain RD534. The genome of phage 2972 has 34,704 bp with an overall G+C content of 40.15%, making it the shortest S. thermophilus phage genome analyzed so far. Forty-four open reading frames (ORFs) encoding putative proteins of 40 or more amino acids were identified, and bioinformatic analyses led to the assignment of putative functions to 23 ORFs. Comparative genomic analysis of phage 2972 with the six other sequenced S. thermophilus phage genomes confirmed that the replication module is conserved and that cos- and pac-type phages have distinct structural and packaging genes. Two group I introns were identified in the genome of 2972. They interrupted the genes coding for the putative endolysin and the terminase large subunit. Phage mRNA splicing was demonstrated for both introns, and the secondary structures were predicted. Eight structural proteins were also identified by N-terminal sequencing and/or matrix-assisted laser desorption ionization-time-of-flight mass spectrometry. Detailed analysis of the putative minor tail proteins ORF19 and ORF21 as well as the putative receptor-binding protein ORF20 showed the following interesting features: (i) ORF19 is a hybrid protein, because it displays significant identity with both pac- and cos-type phages; (ii) ORF20 is unique; and (iii) a protein similar to ORF21 of 2972 was also found in the structure of the cos-type phage DT1, indicating that this structural protein is present in both S. thermophilus phage groups. The implications of these findings for phage classification are discussed.     

Characterization of Streptococcus thermophilus host range phage mutants

To investigate phage-host interactions in Streptococcus thermophilus, a phage-resistant derivative (SMQ-301R) was obtained by challenging a Tn917 library of phage-sensitive strain S. thermophilus SMQ-301 with virulent phage DT1. Mutants of phages DT1 and MD2 capable of infecting SMQ-301 and SMQ-301R were isolated at a frequency of 10(-6). Four host range phage mutants were analyzed further and compared to the two wild-type phages. Altogether, three genes (orf15, orf17, and orf18) contained point mutations leading to amino acid substitutions and were responsible for the expanded host range. These three proteins were also identified in both phages by N-terminal sequencing and/or matrix-assisted laser desorption ionization-time-of-flight mass spectrometry. The results suggest that at least three phage structural proteins may be involved in phage-host interactions in S. thermophilus.     

Lack of Nucleotide Sequence Relationship Among the Temperate Bacteriophage SPO2, Bacillus subtilis, and Virulent Bacteriophages β3 and β22

Radiolabeled phage SPO2 fragments were tested for the abiity to form interspecies deoxyribonucleic acid (DNA) duplexes with DNA from Bacillus subtilis and from phages beta3 and beta22. No reassociation, above control values, occurred between the DNA of phage SPO2 and that of its host or either of the virulent B. subtilis phages. It appears that extensive nucleotide sequence similarities between portions of host and phage DNA species are not necessary for the formation of the lysogenic state. The thermal elution profile of reassociated SPO2 DNA exhibited a normal distribution, indicating no heterogeneity in base composition. This differs from temperate enterophages whose DNA molecules contain regions of differing base composition.     

Molecular analysis of the region encoding the lytic system from Oenococcus oeni temperate bacteriophage phi 10MC

Malolactic fermentation by Oenococcus oeni is a crucial step in wine-making. Oe. oeni phages are thought to be responsible for fermentation failures, yet they have received little attention. After a molecular analysis concerning the phage phi 10MC integration system, this paper focuses on the lytic system. The attP (phage attachment site)-flanking region has been cloned and sequenced. The 1296-bp lysin gene (Lys) was identified in this region. The deduced amino acid sequence showed classical structural features of phage lysins, and this gene product expressed in Escherichia coli had a lytic activity against Oe. oeni. Downstream of Lys, a second ORF was present (P163). According to its amino acid sequence and the location of its gene, the product could be the phi 10MC holin. This study shows that the genomic organization of phage phi 10MC attP-flanking regions is very similar to that of other lactic acid bacteriophages.     

Multiplex PCR for detection and identification of lactococcal bacteriophages

Three genetically distinct groups of Lactococcus lactis phages are encountered in dairy plants worldwide, namely, the 936, c2, and P335 species. The multiplex PCR method was adapted to detect, in a single reaction, the presence of these species in whey samples or in phage lysates. Three sets of primers, one for each species, were designed based on conserved regions of their genomes. The c2-specific primers were constructed using the major capsid protein gene (mcp) as the target. The mcp sequences for three phages (eb1, Q38, and Q44) were determined and compared with the two available in the databases, those for phages c2 and bIL67. An 86.4% identity was found over the five mcp genes. The gene of the only major structural protein (msp) was selected as a target for the detection of 936-related phages. The msp sequences for three phages (p2, Q7, and Q11) were also established and matched with the available data on phages sk1, bIL170, and F4-1. The comparison of the six msp genes revealed an 82. 2% identity. A high genomic diversity was observed among structural proteins of the P335-like phages suggesting that the classification of lactococcal phages within this species should be revised. Nevertheless, we have identified a common genomic region in 10 P335-like phages isolated from six countries. This region corresponded to orfF17-orf18 of phage r1t and orf20-orf21 of Tuc2009 and was sequenced for three additional P335 phages (Q30, P270, and ul40). An identity of 93.4% within a 739-bp region of the five phages was found. The detection limit of the multiplex PCR method in whey was 10(4) to 10(7) PFU/ml and was 10(3) to 10(5) PFU/ml with an additional phage concentration step. The method can also be used to detect phage DNA in whey powders and may also detect prophage or defective phage in the bacterial genome.     

The dilemma of phage taxonomy illustrated by comparative genomics of Sfi21-like Siphoviridae in lactic acid bacteria

The complete genome sequences of two dairy phages, Streptococcus thermophilus phage 7201 and Lactobacillus casei phage A2, are reported. Comparative genomics reveals that both phages are members of the recently proposed Sfi21-like genus of Siphoviridae, a widely distributed phage type in low-GC-content gram-positive bacteria. Graded relatedness, the hallmark of evolving biological systems, was observed when different Sfi21-like phages were compared. Across the structural module, the graded relatedness was represented by a high level of DNA sequence similarity or protein sequence similarity, or a shared gene map in the absence of sequence relatedness. This varying range of relatedness was found within Sfi21-like phages from a single species as demonstrated by the different prophages harbored by Lactococcus lactis strain IL1403. A systematic dot plot analysis with 11 complete L. lactis phage genome sequences revealed a clear separation of all temperate phages from two classes of virulent phages. The temperate lactococcal phages share DNA sequence homology in a patchwise fashion over the nonstructural gene cluster. With respect to structural genes, four DNA homology groups could be defined within temperate L. lactis phages. Closely related structural modules for all four DNA homology groups were detected in phages from Streptococcus or Listeria, suggesting that they represent distinct evolutionary lineages that have not uniquely evolved in L. lactis. It seems reasonable to base phage taxonomy on data from comparative genomics. However, the peculiar modular nature of phage evolution creates ambiguities in the definition of phage taxa by comparative genomics. For example, depending on the module on which the classification is based, temperate lactococcal phages can be classified as a single phage species, as four distinct phage species, or as two if not three different phage genera. We propose to base phage taxonomy on comparative genomics of a single structural gene module (head or tail genes). This partially phylogeny-based taxonomical system still mirrors some aspects of the current International Committee on Taxonomy in Virology classification system. In this system the currently sequenced lactococcal phages would be grouped into five genera: c2-, sk1, Sfi11-, r1t-, and Sfi21-like phages.     

RNA splicing in the T-even bacteriophage

Group 1 introns, first demonstrated in the nuclear large rRNA of Tetrahymena thermophila and subsequently in many yeast, fungal mitochondrial, and chloroplast precursor RNAs, are capable of intron excision and exon ligation in vitro, although this process occurs much more rapidly in vivo. The discovery and characterization of a similar intron in the T4 phage thymidylate synthase gene (td) led to the finding of additional group 1 introns in other T4 genes and in genes of the related T2 and T6 phages. Because protein factors are not required in the splicing of group 1 introns in vitro, it has been postulated that the precursor RNA can assume a critical conformation enabling it to undergo site-specific autocatalytic cleavage and ligation (self-splicing). By means of site-directed mutation, it has been shown unequivocally that several sequence elements in the Tetrahymena rRNA intron are involved in the formation of base-paired stem structures that are essential for the self-splicing process. These sequence elements have been demonstrated in other eukaryotic group 1 introns, as well as in the td intron. In this brief review we shall describe the biochemical and structural properties of the td intron in relation to other newly found phage introns. The interesting implications arising from these revelations will also be discussed.     

Genomic sequence of C1, the first streptococcal phage

C(1), a lytic bacteriophage infecting group C streptococci, is one of the earliest-isolated phages, and the method of bacterial classification known as phage typing was defined by using this bacteriophage. We present for the first time a detailed analysis of this phage by use of electron microscopy, protein profiling, and complete nucleotide sequencing. This virus belongs to the Podoviridae family of phages, all of which are characterized by short, noncontractile tails. The C(1) genome consists of a linear double-stranded DNA molecule of 16,687 nucleotides with 143-bp inverted terminal repeats. We have assigned functions to 9 of 20 putative open reading frames based on experimental substantiation or bioinformatic analysis. Their products include DNA polymerase, holin, lysin, major capsid, head-tail connector, neck appendage, and major tail proteins. Additionally, we found one intron belonging to the HNH endonuclease family interrupting the apparent lysin gene, suggesting a potential splicing event yielding a functional lytic enzyme. Examination of the C(1) DNA polymerase suggests that this phage utilizes a protein-primed mechanism of replication, which is prominent in the phi29-like members of Podoviridae. Consistent with this evidence, we experimentally determined that terminal proteins are covalently attached to both 5' termini, despite the fact that no homology to known terminal proteins could be elucidated in any of our open reading frames. Likewise, comparative genomics revealed no close evolutionary matches, suggesting that the C(1) bacteriophage is a unique member of the Podoviridae.