The genome and proteome of the Kluyvera bacteriophage Kvp1 – another member of the T7-like Autographivirinae

The T7-like bacterial viruses are members of the Podoviridae – phages with short tails – and are characterized by a simple but elegant temporal transcriptional control system [1]. The early genes are transcribed by the host RNA polymerase while the middle and late regions are transcribed by a single subunit phage-encoded RNA polymerase which recognizes unique 23 bp promoters sequences [2]. These viruses are one of the most common types of bacteriophages with 26–29 defined or tentative species according to the VIII report of the International Committee on the Taxonomy of Viruses [3, 4]. Most of the host species are members of the γ-Proteobacteria (Erwinia, Escherichia, Klebsiella, Morganella, Pseudomonas, Salmonella, Vibrio, and Yersinia) but viral isolates also infecting α-Proteobacteria (Caulobacter, and Rhizobium) have been isolated. Fifteen T7-like phages have been sequenced and deposited with GenBank. As a result of a reanalysis, at the protein level, of relationships within the "T7-like viruses" this group of bacteriophages have been classified into the subfamily Autographivirinae which currently possesses three genera: T7-like, Sp6-like and φKMV-like viruses [5]. Kvp1, the first Kluyvera cryocrescens-specific bacteriophage, was isolated from the Matanza River in Buenos Aires (Argentina) by Gadaleta and Zorzopulos [6]. Morphologically this phage is a member of the Podoviridae. Eleven clones derived from AluI or HaeIII digestion of the viral DNA were sequenced, by these authors, revealing strong sequence similarity to coliphage T7. To further analyze the correct taxonomic position of this virus we have completed the sequence of its genome noting its very close similarity to Yersinia phage Berlin and coliphage T3.

Pyrosequencing (454 technology) has been used to determine the sequence of the genomes of Bacillus thuringiensis phage 0305φ8-36 [7] and coliphage JK98 [8], and, in this incidence, the genome of Kvp1. Sequencing resulted in 2 contigs with 53-fold coverage. While this type of sequencing can result in potential errors at oligonucleotide runs, none were observed in the data on Kvp1. The gap, representing 0 bp, was closed by PCR amplification and ABI sequencing; while the nature of the termini were verified by primer walking off phage DNA template. The total genome is 39,472 bp with 194 bp terminal direct repeats, and a base composition of 48.6 mol%G+C – characteristics remarkably consistent with other T7-like phages. By comparison, the genomes of T7-like phages range from 37.4 kb (Pseudomonas phage gh-1) to 45.4 kb (Erwinia phage Era103) while the reported terminal repeats range from Yersinia phage φA1122 at 148 bp to Pseudomonas aeruginosa phage LKD16 at 428 bp.

Several regions of dissimilarity (indicates by areas of white in Figure 1) centred at genes 1.05, 4.7–2.8, 5.3–5.5, 17–17.2, 18.2 and at the left end of the genome are noted. Several of these genes are not found in phage Berlin. The most interesting difference is in gene 17 which encodes the tail fibre. As with other Gp17 homologs sequence similarity is only found at the N-terminus, the part of the protein which is associated with the tail structure. The C-terminus is involved in ligand interactions and exhibits considerable differences.

Using CoreGenes Kvp1 shares 37 (61.7%), 12 (23.1%) and 9 (18.4%) homologs with the type phages of the three Autographivirinae genera – T7, Sp6 and φKMV-like viruses. The results indicate that Kvp1 is a member of the T7-like virus genus. A comparison with the proteome of phage Berlin indicates 37 homologs – 82.2% common proteins. While the percentage of common proteins is less when compared with coliphage T3 (70.9% similarity) the early regions of T3 and Kvp1 are very similar in that Kvp1 encodes T3-like Gp0.3, 0.6 and 0.7 homologs. The product of early gene 0.3 (Ocr) is a small protein which mimics B-form DNA and binds to, and inhibits, type I restriction endonucleases [9, 10]; and, possesses S-adenosyl-L-methionine hydrolase activity [11]. Gp0.7 produces functions in host gene shutoff [12] and as a protein kinase which phosphorylates host elongation factors G and P and ribosomal protein S6 [13]. A major dissimilarity between Kvp1 and T3/T7 is that while the latter phages possess multiple strong promoters recognized by the host RNA polymerase, only a single promoter showing homology to the consensus was found in the Kvp1 genome. In keeping with the protein similarity to Yersinia phage Berlin, the phage specific promoters are also most closely related in sequence to those of this bacterial virus (Fig. 2).

Typical of this type of bacteriophage, Kvp1 displays a simple protein profile (Fig. 3) in which most of the protein bands can be assigned based upon the extensive knowledge of these phages, and the mass of the protein bands compared with the in silico analysis of the proteins based upon genomic analysis.

One band of interest, with a mass of 43.6 kDa, was noted migrating just above that of the major capsid protein (Gp10) which was not immediately linked, on the basis of its mass, to a product of one of the morphogenesis genes. One of the characteristics of some T7-like phages is that they display, on SDS-PAGE, two "versions" of the major capsid protein which are designated as 10A and 10B [14]. The sequences of the amino termini of these proteins are identical, but during translation a rare ribosomal slippage occurs permitting the elongation of the protein product. The features of this system are a protein slightly larger than the capsid, a slippery site in the DNA/RNA and a downstream stem-loop structure capable of forming a pseudoknot [15, 16]. We obtained evidence for a potential pseudoknot using pknotsRG at http://​bibiserv.​techfak.​uni-bielefeld.​de/​pknotsrg/​submission.​html[17] located 144 bp downstream from the end of the capsid gene, but no typical slippage site was observed. The nature of this protein was investigated by in-gel enzymatic digestion and high-resolution mass spectrometry. MALDI QqTOF MS analysis on a tryptic digest has yielded 70% sequence coverage of the protein Gp10 (Figure 4), and three unique peptides were present at m/z 2244.123, m/z 2372.219 and m/z 2692.310 which revealed the distinct C-terminal amino acid residues 327–372 from the protein sequences of Gp10. This indicates that Kvp1 produces a major capsid protein (10A) and a minor protein (10B) through programmed -1 frameshifting at TTTTCA. The Gp10B protein is predicted to have a calculated mass of 42.1 kDa, consistent with the estimated value of 43.6 kDa by SDS-PAGE gel.

Our data conclusively demonstrate that Kluyvera virus Kvp1 is a member of T7-like virus genus of the Podoviridae subfamily Autographivirinae. It differs from phages such as T3 and φYeO3-12 which exhibit capsid frameshifting at lysyl residues, by ribosomal slippage at polyU residues (phenylalanine) – a property it shares with Yersinia phage φA1122.