Maturation of bacteriophage SPPI DNA: limited precision in the sizing of mature bacteriophage genomes

DNA Packaging and Genomics of the Salmonella 9NA-Like Phages

We present the genome sequences of Salmonella enterica tailed phages Sasha, Sergei, and Solent. These phages, along with Salmonella phages 9NA, FSL_SP-062, and FSL_SP-069 and the more distantly related Proteus phage PmiS-Isfahan, have similarly sized genomes of between 52 and 57 kbp in length that are largely syntenic. Their genomes also show substantial genome mosaicism relative to one another, which is common within tailed phage clusters. Their gene content ranges from 80 to 99 predicted genes, of which 40 are common to all seven and form the core genome, which includes all identifiable virion assembly and DNA replication genes. The total number of gene types (pangenome) in the seven phages is 176, and 59 of these are unique to individual phages. Their core genomes are much more closely related to one another than to the genome of any other known phage, and they comprise a well-defined cluster within the family Siphoviridae To begin to characterize this group of phages in more experimental detail, we identified the genes that encode the major virion proteins and examined the DNA packaging of the prototypic member, phage 9NA. We show that it uses a pac site-directed headful packaging mechanism that results in virion chromosomes that are circularly permuted and about 13% terminally redundant. We also show that its packaging series initiates with double-stranded DNA cleavages that are scattered across a 170-bp region and that its headful measuring device has a precision of ±1.8%.IMPORTANCE The 9NA-like phages are clearly highly related to each other but are not closely related to any other known phage type. This work describes the genomes of three new 9NA-like phages and the results of experimental analysis of the proteome of the 9NA virion and DNA packaging into the 9NA phage head. There is increasing interest in the biology of phages because of their potential for use as antibacterial agents and for their ecological roles in bacterial communities. 9NA-like phages that infect two bacterial genera have been identified to date, and related phages infecting additional Gram-negative bacterial hosts are likely to be found in the future. This work provides a foundation for the study of these phages, which will facilitate their study and potential use.

The Revisited Genome of Bacillus subtilis Bacteriophage SPP1

Bacillus subtilis bacteriophage SPP1 is a lytic siphovirus first described 50 years ago [1]. Its complete DNA sequence was reported in 1997 [2]. Here we present an updated annotation of the 44,016 bp SPP1 genome and its correlation to different steps of the viral multiplication process. Five early polycistronic transcriptional units encode phage DNA replication proteins and lysis functions together with less characterized, mostly non-^{essential, functions. Late transcription drives synthesis of proteins necessary for SPP1 viral particles assembly and for cell lysis, together with a short set of proteins of unknown function. The extensive genetic, biochemical and structural biology studies on the molecular mechanisms of SPP1 DNA replication and phage particle assembly rendered it a model system for tailed phages research. We propose SPP1} as the reference species for a new SPP1-like viruses genus of the Siphoviridae family.

A non-invasive method for studying viral DNA delivery to bacteria reveals key requirements for phage SPP1 DNA entry in Bacillus subtilis cells

Bacteriophages use most frequently a tail apparatus to create a channel across the entire bacterial cell envelope to transfer the viral genome to the host cell cytoplasm, initiating infection. Characterization of this critical step remains a major challenge due to the difficulty to monitor DNA entry in the bacterium and its requirements. In this work we developed a new method to study phage DNA entry that has the potential to be extended to many tailed phages. Its application to study genome delivery of bacteriophage SPP1 into Bacillus subtilis disclosed a key role of the host cell membrane potential in the DNA entry process. An energized B. subtilis membrane and a millimolar concentration of calcium ions are shown to be major requirements for SPP1 DNA entry following the irreversible binding of phage particles to the receptor YueB.

Genome of Bacillus subtilis Bacteriophage SPP1: Structure and Nucleotide Sequence of pac, the Origin of DNA Packaging

The DNA of Bacillus subtilis bacteriophage SPP1 is terminally redundant and partially circularly permuted. To explain these parameters, we followed the Streisinger-Botstein models of phage maturation and assumed that packaging of SPP1 DNA begins at a unique genomic site ("pac") and proceeds sequentially from there. We describe the sequence of about 1,000 nucleotides surrounding pac. This together with size determinations of small, pac-terminated restriction fragments has revealed heterogeneity of the natural pac ends of SPP1 DNA. Such ends fell in each DNA strand into a region of five to seven nucleotides. However, within this range more than 50% of all molecules terminated with defined cytosines on both strands, generating a 3' protruding terminus. The nucleotide sequence of the DNA segment surrounding pac did not reveal any features which would distinguish this region.

Determining DNA packaging strategy by analysis of the termini of the chromosomes in tailed-bacteriophage virions

Tailed-bacteriophage virions contain a single linear dsDNA chromosome which can range in size from about 18 to 500 kbp across the known tailed-phage types. These linear chromosomes can have one of several known types of termini as follows: cohesive ends (5'- or 3'-single-strand extensions), circularly permuted direct terminal repeats, short or long exact direct terminal repeats, terminal host DNA sequences, or covalently bound terminal proteins. These different types of ends reflect differing DNA replication strategies and especially differing terminase actions during DNA packaging. In general, complete genome sequence determination does not by itself elucidate the nature of these ends, so directed experimental analysis is usually required to understand the nature of the virion chromosome ends. This chapter discusses these methods.

Sequential headful packaging and fate of the cleaved DNA ends in bacteriophage SPP1

The virulent Bacillus subtilis bacteriophage SPP1 packages its DNA from a precursor concatemer by a headful mechanism. Following disruption of mature virions with chelating agents the chromosome end produced by the headful cut remains stably bound to the phage tail. Cleavage of this tail-chromosome complex with restriction endonucleases that recognize single asymmetric positions within the SPP1 genome yields several distinct classes of DNA molecules whose size reflects the packaging cycle they were generated from. A continuous decrease in the number of molecules within each class derived from successive encapsidation rounds indicates that there are several packaging series which end after each headful packaging cycle. The frequency of molecules in each packaging class follows the distribution expected for a sequential mechanism initiated unidirectionally at a defined position in the genome (pac). The heterogeneity of the DNA fragment sizes within each class reveals an imprecision in headful cleavage of approximately 2.5 kb (5.6% of the genome size). The number of encapsidation events in a packaging series (processivity) was observed to increase with time during the infection process. DNA ejection through the tail can be induced in vitro by a variety of mild denaturing conditions. The first DNA extremity to exit the virion is invariably the same that was observed to be bound to the tail, implying that the viral chromosome is ejected with a specific polarity to penetrate the host. In mature virions a short segment of this chromosome end (55 to 67 bp equivalent to 187 to 288 A) is fixed to the tail area proximal to the head (connector). Upon ejection this extremity is the first to move along the tail tube to exit from the virion through the region where the tail spike was attached.

Identification of a gene in Bacillus subtilis bacteriophage SPP1 determining the amount of packaged DNA

The virulent Bacillus subtilis bacteriophage SPP1 encapsidates its DNA by a headful mechanism. Analyzing phage missense mutants, which package less DNA than SPP1 wild-type but show no other affected properties, we have identified a gene whose product is involved in the sizing of phage DNA during maturation. Characterization of this gene and its product provides an experimental access to the poorly understood mechanism of DNA sizing in packaging. The gene (gene 6 or siz) was cloned and sequenced. An open reading frame (ORF) coding for a 57.3 kDa polypeptide was identified. All the single nucleotide substitutions present in different siz mutants affect the net charge of that protein. The gene was further characterized by assignment of several nonsense mutations (sus) to the ORF. Phages carrying the latter type of mutations could be complemented in trans when gene 6 is provided by a plasmid.

Molecular analysis of the Bacillus subtilis bacteriophage SPP1 region encompassing genes 1 to 6. The products of gene 1 and gene 2 are required for pac cleavage

Packaging of Bacillus subtilis phage SPP1 DNA into viral capsids is initiated at a specific DNA site termed pac. Using an in vivo assay for pac cleavage, we show that initiation of DNA synthesis and DNA packaging are uncoupled. When the DNA products of pac cleavage were analyzed, we could detect the pac end that was destined to be packaged, but we failed to detect the other end of the cleavage reaction. SPP1 conditional lethal mutants, which map adjacent to pac, were analyzed with our assay. This revealed that the products of gene 1 and gene 2 are essential for pac cleavage. SPP1 mutants that are affected in the genes necessary for viral capsid formation (gene 41) or involved in headful cleavage (gene 6) remain proficient in pac site cleavage. Analysis of the nucleotide sequence (2.769 x 10(3) base-pairs) of the region of the genes required for pac cleavage revealed five presumptive genes. We have assigned gene 1 and gene 2 to two of these open reading frames (orf), giving the gene order gene 1-gene 2-orf 3-orf 4-orf 5. The direction of transcription of the gene 1 to orf 5 operon and the length of the mRNAs was determined. We have identified, upstream from gene 1, the major transcriptional start point (P1). Transcription originating from P1 requires a phage-encoded factor for activity. The organization of gene 1 and gene 2 of SPP1 resembles the organization of genes in the pac/cos region of different Escherichia coli double-stranded DNA phages. We propose that the conserved gene organization is representative of the packaging machinery of a primordial packaging system.

Analysis in vivo of the bacteriophage P22 headful nuclease

Bacteriophage P22 packages its double-stranded DNA chromosomes from concatemeric replicating DNA in a processive, sequential fashion. According to this model, during the initial packaging event in such a series the packaging apparatus recognizes a nucleotide sequence, called pac, on the DNA, and then condenses DNA within the coat protein shell unidirectionally (rightward) from that point. DNA ends are generated near the pac site before or during the condensation reaction. The right end of the mature chromosome is created by a cut made in the DNA by the "headful nuclease" after a complete chromosome is condensed within the phage head. Subsequent packaging events on that concatemeric DNA begin at the end generated by the headful cut of the previous event and proceed in the same direction as the previous event. We report here accurate measurements of the P22 chromosome length (43,400( +/- 750) base-pairs, where the uncertainty is the range in observed lengths), genome length (41,830( +/- 315) base-pairs, where the uncertainty represents the accuracy with which the length is known), the terminal redundancy (1600( +/- 750) base-pairs or 3.8( +/- 1.8)%, where the uncertainty is the observed range) and the imprecision in the headful measuring device ( +/- 750 base-pairs or +/- 1.7%). In addition, we present evidence for a weak nucleotide sequence specificity in the headful nuclease. These findings lend further support to, and extend our understanding of, the sequential series model of P22 DNA packaging.

Vibrio cholerae bacteriophage CP-T1: characterization of bacteriophage DNA and restriction analysis

Temperature bacteriophage CP-T1 of Vibrio cholerae has a capsid that is 45 nm in diameter, a contractile tail 65 nm long and 9.5 nm wide, and a baseplate with several spikes or short tail fibers. The linear double-stranded DNA is 43.5 +/- 1.4 kilobases long, and the phage genome is both terminally redundant and partially circularly permuted. The extent of terminal redundancy is ca. 4%, and circular permutation is up to ca. 44%. Circular restriction maps have been constructed for the enzymes HindIII, EcoRI, BamHI, and PstI. By restriction endonuclease and heteroduplex analyses of phage DNA, the presence and location of a site (pac) at which packaging of phage DNA is initiated was established.

MP13, a generalized transducing bacteriophage for Bacillus megaterium

The first generalized transducing bacteriophage reported for Bacillus megaterium has been characterized. Optimum conditions for lysate production and transduction procedures were established so that transducing frequencies of 8 x 10(-6) and higher are now possible. The phage, MP13, has a head diameter of 97 nm and a contractile tail (202 by 17 nm) and adsorbs to the periphery of the cell. MP13 was inactivated rapidly at 60 degrees C, but not at 55 degrees C, and was sensitive to toluene, ether, and chloroform. When centrifuged in a neutral CsCl gradient, two bands were observed, a major band of 1.490 g cm-3 and a minor band of 1.482 g cm-3 buoyant density. The major band contained only infective particles, whereas the minor band contained both infective and transducing particles. Phage DNA was resistant to several restriction endonucleases, but yielded 9 fragments with MboI, more than 34 with HindIII, and 7 with BstEII. The molecular weights for the fragments from MboI-BstEII double digests total 97 x 10(9).

Construction and use of SPP1v, a viral cloning vector for Bacillus subtilis

A unique BamHI restriction site has been inserted into a nonessential region of the genome of a deletion mutant of phage SPP1. Construction of this phage, designated SPP1 v, required the in vitro conversion of a BclI site to a BamHI site. SPP1 v has been used as a vector phage to clone BamHI, BglII and BclI-generated restriction fragments of DNA. A direct selection for recombinants has been developed. Transfection with SPP1 v requires intact, genomic-length molecules, and cleavage with BamHI destroys the transfecting ability of this DNA. Recombinants in which the BamHI site has been destroyed by ligation to Bg/II or BclI-generated fragments of DNA become resistant to BamHI digestion after ligation and are active in transfection. Cloning of DNA containing BamHI sites has been accomplished by using the enzyme Bst1503I to methylate BamHI sites before insertion, and so to protect them during the BamHI digestion used to select against vector molecules. The in vitro construction of SPP1 v generated XmaIII sites directly adjacent to, and on both sides of the inserted BamHI site. This permits precise excision of cloned DNA even when cloning destroys the BamHI insertion site. Restriction-enzyme generated fragments of DNA in the size range of 0 to 4 Md have been cloned, including a full-length copy of plasmid pUB110, almost the complete sequence of plasmid pBR322, and a sequence of DNA that carried the lambda cos site.