Cnr protein, the negative regulator of bacteriophage P4 replication, stimulates specific DNA binding of its initiator protein alpha

Ziegelin, Günter; Calendar, Richard; Ghisotti, Daniela; Terzano, Susanna; Lanka, Erich

doi:10.1128/jb.179.9.2817-2822.1997

Cited by 9 publications

(20 citation statements)

References 26 publications

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“…The ␣ protein plays four roles: it acts as a replicative helicase, a primase, and an origin recognition protein (37,42) and interacts with the P4 Cnr protein (copy number regulation (34,38). Therefore, the RepA proteins may exert additional activities to the proposed ones that do not become readily obvious by sequence comparisons.…”

Section: Discussionmentioning

confidence: 99%

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The repA Gene of the Linear Yersinia enterocolitica Prophage PY54 Functions as a Circular Minimal Replicon in Escherichia coli

et al. 2005

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The Yersinia enterocolitica prophage PY54 replicates as a linear DNA molecule with covalently closed ends. For replication of a circular PY54 minimal replicon that has been derived from a linear minireplicon, two phage-encoded loci are essential in Escherichia coli: (i) the reading frame of the replication initiation gene repA and (ii) its 212-bp origin located within the 3 portion of repA. The RepA protein acts in trans on the origin since we have physically separated the PY54 origin and repA onto a two-plasmid origin test system. For this trans action, the repA 3 end carrying the origin is dispensable. Mutagenesis by alanine scan demonstrated that the motifs for primase and for nucleotide binding present in the protein are essential for RepA activity. The replication initiation functions of RepA are replicon specific. The replication initiation proteins DnaA, DnaG, and DnaB of the host are unable to promote origin replication in the presence of mutant RepA proteins that carry single residue exchanges in these motifs. The proposed origins of the known related hairpin prophages PY54, N15, and PKO2 are all located toward the 3 end of the corresponding repA genes, where several structure elements are conserved. Origin function depends on the integrity of these elements.Three temperate bacterial viruses of different organisms generating linear prophages are known, PY54, N15, and PKO2. The DNA carries covalently closed hairpins at their ends. Hence we propose the name "hairpin prophage." Two of the phages, PY54 of Yersinia enterocolitica and PKO2 of Klebsiella oxytoca, have been discovered very recently (4, 27). However, the paradigm of the linear prophages, N15 of Escherichia coli, was described already in 1967 by Victor Ravin (13). The linear DNA form is also known from brown algae viruses (7,8) and in the pathogens Borrelia burgdorferi and Agrobacterium tumefaciens (2,14). Although a straightforward mechanistic scheme has been suggested by Rybchin and Svarchevsky (31), the replication of the linear DNA is still poorly understood. The replication model is still valid today. The crucial components are (i) an origin of replication of the theta type proposing bidirectional DNA synthesis, (ii) a multifunctional phage-encoded replication protein guiding the initiation of replication, and (iii) a protelomerase essential for the conversion of circular precursor DNA into the linear form at a sequence called the telomere resolution site. The initial work on the phage systems apparently stimulated studies on the Borrelia system (5).The protelomerase is a tyrosine integrase-like enzyme that catalyzes the intermolecular strand transfer in the double-stranded DNA molecule by cleavage and rejoining of phosphodiester bonds to yield the linear prophage with closed hairpin ends (9, 10). The same principle of action of protelomerases has been confirmed on several enzymes of different origins (4, 16, 21). It was rather simple to predict and locate the telomere resolution sites because they map at the ends of the linear DNA. In the c...

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Section: Discussionmentioning

confidence: 99%

“…The P4 ␣ protein has origin binding ability (39) and interacts with the copy number regulation protein Cnr (34,38). The ␣ gene has been reported to contain the sequence for a secondary replication origin for P4 prophage replication (35).…”

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The repA Gene of the Linear Yersinia enterocolitica Prophage PY54 Functions as a Circular Minimal Replicon in Escherichia coli

et al. 2005

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“…Furthermore, these residues specify the domain required for the oligomerization of ␣ molecules, since the large complex structures of gp␣⌬4.3-th bridging ori and crr were also observed with ␣ wild-type protein (31). In addition, this domain is also involved in interacting with the P4 Cnr protein (30), which regulates the P4 copy number (28).…”

Section: Construction Of Truncated ␣ Genesmentioning

confidence: 99%

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confidence: 99%

“…This protein has primase and helicase activities, binds DNA specifically, and interacts with the phage-encoded protein Cnr (copy number regulation) (30,33). Defined domains indicate the modular structure of the ␣ protein (30,32). The primase domain of gene product ␣ (gp␣) is related in sequence to that of primases of conjugative plasmids (27), and one of the essential motifs is present in each of the known prokaryotic priming enzymes (20,31).…”

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The helicase domain of phage P4 alpha protein overlaps the specific DNA binding domain

1997

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Replication initiation depends on origin recognition, helicase, and primase activities. In phage P4, a second DNA region, the cis replication region (crr), is also required for replication initiation. The multifunctional ␣ protein of phage P4, which is essential for DNA replication, combines the three aforementioned activities on a single polypeptide chain. Protein domains responsible for the activities were identified by mutagenesis. We show that mutations of residues G506 and K507 are defective in vivo in phage propagation and in unwinding of a forked helicase substrate. This finding indicates that the proposed P loop is essential for helicase activity. Truncations of gene product ␣ (gp␣) demonstrated that 142 residues of the C terminus are sufficient for specifically binding ori and crr DNA. The minimal binding domain retains gp␣'s ability to induce loop formation between ori and crr. In vitro and in vivo analysis of short C-terminal truncations indicate that the C terminus is needed for helicase activity as well as for specific DNA binding.The DNA replication of the temperate satellite phage P4 of Escherichia coli is driven by the phage-encoded, multifunctional ␣ protein of 777 amino acid residues (12,16,31). This protein has primase and helicase activities, binds DNA specifically, and interacts with the phage-encoded protein Cnr (copy number regulation) (30,33). Defined domains indicate the modular structure of the ␣ protein (30, 32). The primase domain of gene product ␣ (gp␣) is related in sequence to that of primases of conjugative plasmids (27), and one of the essential motifs is present in each of the known prokaryotic priming enzymes (20, 31). The domain for primase, containing the motif -EGYATA-, occupies the N-terminal half of gp␣. The DNA binding activity is specific for the 6 and 10 TGTTC ACC repeating octamers of the bidirectional replication origin (ori) and the cis replication region (crr), respectively. The iterons located in ori are completely conserved, whereas in crr, five of the octamers deviate in one position. The DNA binding domain occupies the C-terminal third of gp␣. The primase and DNA binding domains can function independently of one another: the N-terminal truncation containing the primase domain complements a P4 primase-null phage, and it retains primase activity in vitro (32). The primase-defective ␣ protein, which has an E214Q mutation, can still bind DNA specifically. The Cnr protein functions as a negative regulator of P4 replication, and P4 phage does not replicate in cells that overexpress cnr (28). Mutants suppressing this phenotype map in the DNA binding domain of gp␣ residing between amino acid residues 675 and 737. Cnr does not bind to DNA by itself, but it alters the DNA binding properties of gp␣.The helicase activity seems to be marked by the Walker type A nucleotide binding site (NBS) motif in the middle of the protein. gp␣ has 3Ј35Ј unwinding polarity. The enzyme prefers substrates with non-base-paired tails, resembling the situation of the replication fork. Except fo...

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The Plasmid Status of Satellite Bacteriophage P4

Briani

Dehò

Forti

et al. 2001

Plasmid

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Cnr protein, the negative regulator of bacteriophage P4 replication, stimulates specific DNA binding of its initiator protein alpha

Cited by 9 publications

References 26 publications

The repA Gene of the Linear Yersinia enterocolitica Prophage PY54 Functions as a Circular Minimal Replicon in Escherichia coli

The repA Gene of the Linear Yersinia enterocolitica Prophage PY54 Functions as a Circular Minimal Replicon in Escherichia coli

The helicase domain of phage P4 alpha protein overlaps the specific DNA binding domain

The Plasmid Status of Satellite Bacteriophage P4

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