Identification of Brevibacterium flavum genes related to receptors involved in bacteriophage BFK20 adsorption.

Phage infection of bacterial cells is a process requiring the interaction between phage receptor binding proteins and receptors on the bacterial cell surface. We prepared a Brevibacterium flavum CCM 251 EZ-Tn5 transposon insertional library and isolated phage-resistant mutants. Analysis of the DNA fragments produced by single-primer PCR was used to determine the EZ-Tn5 transposon insertion sites in the genomes of phage-resistant B. flavum mutants. Seven disrupted genes were identified in forty B. flavum mutants. The phage resistance of these mutants was demonstrated by cultivation analysis in the presence of BFK20, and the adsorption rate of BFK20 to these mutants was tested. B. flavum mutants displayed significantly reduced adsorption rates; the lowest rate was observed for mutants containing interrupted major facilitator superfamily (MFS) protein and glycosyltransferase genes. Uninterrupted forms of these genes were cloned into corynebacterial vector pJUP06 and used for in trans complementation of the corresponding B. flavum mutants. The growth of these complemented mutants when infected with BFK20 closely resembled that of wild-type B. flavum. These complemented mutants also exhibited similar BFK20 adsorption as the wild-type control. We infer that the disrupted MFS protein and glycosyltransferase genes are responsible for the phage-resistant phenotype of these B. flavum transposition mutants.

The BFK20 phage replication origin confers a phage-encoded resistance phenotype to the industrial strain Brevibacterium flavum.

The phage BFK20 replication origin was identified using bioinformatics tools and a fragment with the origin nucleotide sequence was cloned into the tetracycline resistance gene of Escherichia coli vector pBR328, to make the plasmid pBOS. After transformation into the host strain Brevibacterium flavum CCM 251, pBOS was able to replicate, showing that the cloned region may function as a replication origin. The presence of the BFK20 origin sequence in a pBOS plasmid isolated from B. flavum CCM 251 was confirmed by Southern hybridisation. Monitoring pBOS stability in corynebacterial hosts showed that pBOS was stable in Corynebacterium glutamicum RM3 for 20 generations and in B. flavum CCM 251 for 10 generations. The effect of the cloned BFK20 replication origin on host resistance to BFK20 infection was tested. Growth of a B. flavum CCM 251 strain harbouring pBOS stopped after phage infection, but without complete lysis. Five hours after infection, the viability of the modified strain was about five times higher than the viability of wild-type B. flavum CCM 251. Thus, the ability of the BFK20 replication origin to confer the origin-derived phage-encoded resistance phenotype to B. flavum CCM 251 was confirmed.

Gp41, a superfamily SF2 helicase from bacteriophage BFK20.

Gp41 is one of two helicases encoded by the genome of bacteriophage BFK20. The gp41 sequence contains conserved motifs from the SF2 family of helicases. We prepared and studied three recombinant proteins: gp41HN, a wild type-like protein with an N-terminal His-Tag; gp41HC, with an S2A mutation and a C-terminal His-Tag; and gp41dC, a mutant protein with a deleted C-terminal region and His-Tags on both N- and C-termini. We tested the enzymatic activities and DNA binding abilities of these isolated proteins. We found that both gp41HN and gp41HC had strong DNA-dependent ATPase activities, but that the ATPase activity of gp41dC was significantly lower regardless of the presence of DNA. The preferred substrates for the NTP hydrolysis reactions were ATP and dATP. gp41HC and gp41HN exhibited a low helicase activity in a fluorescence-based assay using dsDNA substrates with a 3' overhang and with a forked end in the presence of ATP. We infer that the C-terminal region of gp41 may be involved in DNA binding, since removing this region in gp41dC reduced the protein's DNA binding ability.

A RepA-like protein from bacteriophage BFK20 is a multifunctional protein with primase, polymerase, NTPase and helicase activities.

Phage BFK20 replication protein gp43 comprises an N-terminal prim-pol domain and a C-terminal domain similar to replicative helicases. We prepared and studied two recombinant proteins: gp43-1 containing both prim-pol and helicase domains, and gp43C with the helicase domain only. A SEC-MALS analysis indicated that gp43-1 forms a hexameric homooligomer. NTPase activity testing revealed that gp43-1 was able to hydrolyze a wide spectrum of NTPs, ATP the most efficiently. The ATPase activity of gp43-1 was strongly dependent on the presence of ssDNA in the reaction, but was low in the presence of dsDNA and in the absence of DNA. On the other hand, the ATPase activity of gp43C was very low regardless of the presence of DNA. The helicase activity of gp43-1 was detected using a fluorescence-based assay with a forked DNA substrate in the presence of ATP. However, no helicase activity could be detected for gp43C. We therefore conclude that the prim-pol domain is essential for the helicase and ssDNA-dependent ATPase activity of gp43-1.

Interaction between phage BFK20 helicase gp41 and its host Brevibacterium flavum primase DnaG.

Protein-protein interactions have been identified between the replication proteins of corynephage BFK20 and its host Brevibacterium flavum CCM 251. We tested the interactions between phage proteins gp40, gp41, gp42, gp43 and gp44 and between these phage proteins and host replication proteins DnaZX, DnaN, Dnaδ, DnaG, DnaA, RecF, TrxC, TrxB1 and SSB using a bacterial two-hybrid system. Phage proteins gp41, gp42 and gp43 self-associated, demonstrating that these proteins are oligomers in vivo. Interactions were also detected between phage protein gp41 and host proteins DnaZX, DnaN, Dnaδ, DnaG and SSB. ß-galactosidase activity measurements showed that the strongest interaction was between gp41 and DnaG. The interaction was studied further using 2-dimensional blue native SDS-polyacrylamide gel electrophoresis and Western blot analysis.

Immunodetection and N-terminal sequencing of DNA replication proteins of bacteriophage BFK20 - lytic phage of Brevibacterium flavum.

Phages are excellent models for studying the mechanism of DNA replication in prokaryotes. Identification of phage proteins involved in phage DNA replication is the first prerequisite for elucidation of the phage replication module. We focused on replication proteins gp41 (a putative helicase from SF2 superfamily), gp43 (a RepA-like protein), and gp44 (a putative DNA polymerase A) of phage BFK20 grown in Brevibacterium flavum. To identify them in the phage-host system, we prepared antibodies to these proteins which were cloned and expressed in Escherichia coli as his-tagged recombinant proteins. After purification to homogeneity the recombinant proteins served for raising specific polyclonal antibodies in mice. Using these antibodies in Western blot analysis the phage proteins gp41, gp43 and gp44 were detected during the phage growth cycle. The proteins gp41 and gp43, prepared from cell lysate by ammonium sulphate precipitation, were N-terminally sequenced and found to contain the sequences N-SVKPRELR-C and N-MLGSTML-C, respectively. This means that gp41 starts with serine but not with common methionine. We consider these findings an initial but important step towards more thorough characterization of replication proteins of phage BFK20.

Transcriptional profiling of bacteriophage BFK20: coexpression interrogated by "guilt-by-association" algorithm.

Global gene expression profiling of bacteriophage BFK20 infecting the industrial L-lysine producer Brevibacterium flavum CCM 251 was performed using DNA microarray. The relative gene expressions were measured in fourteen time samples collected during phage development. Phage genes were classified as early, middle, late or unassigned based on complex expression patterns during infection. Temporal classification of BFK20 genes was in concordance with previous predictions. However, proposed late regulatory genes were reclassified and new functional assignments for ORF55 were strongly suggested. Furthermore, we consider possible functions of other genes and their products regarding coexpression pattern by using "guilt-by-association" algorithm. Microarray results were validated using real-time RT-PCR. The detailed description of phage BFK20 transcriptional profile can answer the basic questions of its life cycle and it also can help to prevent phage contamination during industrial fermentation. In addition, this work presents the first complete microarray time course study of gene expression utilizing loop design.

Complete nucleotide sequence and genome analysis of bacteriophage BFK20--a lytic phage of the industrial producer Brevibacterium flavum.

The entire double-stranded DNA genome of bacteriophage BFK20, a lytic phage of the Brevibacterium flavum CCM 251--industrial producer of L-lysine--was sequenced and analyzed. It consists of 42,968 base pairs with an overall molar G + C content of 56.2%. Fifty-five potential open reading frames were identified and annotated using various bioinformatics tools. Clusters of functionally related putative genes were defined (structural, lytic, replication and regulatory). To verify the annotation of structural proteins, they were resolved by 2D gel electrophoresis and were submitted to N-terminal amino acid sequencing. Structural proteins identified included the portal and major and minor tail proteins. Based on the overall genome sequence comparison, similarities with other known bacteriophage genomes include primarily bacteriophages from Mycobacterium spp. and some regions of Corynebacterium spp. genomes--possible prophages. Our results support the theory that phage genomes are mosaics with respect to each other.

Resistance of corynebacterial strains to infection and lysis by corynephage BFK 20.

AIMS: Defence mechanisms of the corynebacterial strains against corynephage BFK 20, which causes lysis of Brevibacterium flavum CCM 251. METHODS AND RESULTS: We tested adsorption of the phage BFK 20 to the corynebacterial cell surface. We observed strong adsorption ranging from ca 79 to 93% on the cells of B. flavum ATCC strains, but only ca 76% for B. flavum CCM 251. Minor adsorption for Brevibacterium lactofermentum BLOB (ca 13%) and no adsorption for Corynebacterium glutamicum RM3 were determined. BFK 20 infection had no significant effect on growth and viability of C. glutamicum and B. lactofermentum, but significantly influenced growth and viability of B. flavum ATCC 21127, 21128 and 21474. Cell growth stopped in short time after infection but with no lysis. Brevibacterium flavum CCM 251 cell growth was arrested too and lysis occurred. The Southern hybridization confirmed the presence of significant amount of BFK 20 DNA in samples from B. flavum CCM 251 and B. flavum ATCC strains after BFK 20 infection. Only weak hybridization signal was detected for DNA from infected cells of B. lactofermentum BLOB and no signal for C. glutamicum RM3. CONCLUSIONS: Based on the above results we suggest presence of a mechanism leading to abortive infection in B. flavum ATCC 21127, 21128 and 21474. In B. lactofermentum BLOB and C. glutamicum RM3 the adsorption barrier is more likely. SIGNIFICANCE AND IMPACT OF THE STUDY: This study increases the knowledge on defence mechanisms of corynebacteria against bacteriophages.