The gene A protein of bacteriophage phiX174 has been used in vitro to convert phiX RFI DNA into the relaxed RFII form by nicking the viral strand. The nucleotide sequence at the 3' end of the nick has been determined as -- T G C T C C C C C A A C T T Goh. This sequence gives the exact position of the origin of phiX RF DNA replication.
Five viruses causing colour-breaking of tulip flowers were isolated from tulips and lilies. Tulip-breaking virus (TBV), tulip top-breaking virus (TTBV), tulip bandbreaking virus, Rembrandt tulip-breaking virus and lily mottle virus were all characterized as potyviruses by serology and potyvirus-specific PCR. Sequence analysis of amplified DNA fragments spanning a conserved area of the coat protein cistron ofpotyviruses was performed in order to classify the isolates as distinct viruses or strains. It appears that all tulip-breaking viruses are distinct viruses and TTBV was found to be strain-related to turnip mosaic virus.
Conserved carlavirus and potyvirus primers were used in reverse transcriptase‐polymerase chain reaction (RT‐PCR) to amplify virus fragments from Chinese narcissus (Narcissus tazetta var. chinensis) in China and the fragments were subsequently sequenced and compared in phylogenetic analyses. Samples from Fujiang province and Shanghai contained either one or two potyviruses and a carlavirus. One potyvirus (PY1) showed a distant relationship to Iris severe mosaic virus, Onion yellow dwarf virus and Shallot yellow stripe virus, while the other (only in the Fujiang sample, PY2) was most closely related to Turnip mosaic virus (TuMV). Similar experiments using glasshouse grown Narcissus originating from the UK contained Ornithogalum mosaic virus and another potyvirus (PY3) in the TuMV/PY2 cluster. Comparisons with previously determined sequence fragments indicated that PY2 was probably Narcissus yellow stripe virus and PY3 Narcissus late season yellow virus. Carlavirus fragments from both Chinese sites seemed to be of the same virus, which was most closely related in phylogenetic analyses to Potato virus M, Aconitum latent virus and Hop latent virus. It is most probably a new member of the genus Carlavirus and has been tentatively named Narcissus common latent virus.
The purified A protein and A* protein of bacteriophage phi X174 have been tested for endonuclease activity on single stranded viral phi X174 DNA. The A protein (55.000 daltons) nicks single-stranded DNA in the same way and at the same place as it does superhelical RFI DNA, at the origin of DNA replication. The A* protein (37.000 daltons) can cleave the single-stranded viral DNA at many different sites. It has however a strong preference for the origin of replication. Both proteins generate 3'OH ends and blocked 5' termini at the nick site.
The A* protein of bacteriophage phi X174 is a single-stranded DNA specific nuclease. It can cleave phi X viral ss DNA in many different places. The position of these sites have been determined within the known phi X174 nucleotide sequence (1). From the sequences at these sites it is clear that the A* protein recognizes and cleaves at sites that show only partial homology with the origin of RF DNA replication in the phi X DNA. Different parts of the origin sequence can be deduced that function as a signal for recognition and cleavage by the A* protein. We conclude that different parts within the DNA recognition domain of the A* protein are functional in the recognition of the origin sequence in single-stranded DNA. The existence of different DNA recognition domains in the A* protein, and therefore also in the A protein, leads to a model that can explain how the A protein performs its multiple function in the phi X174 DNA replication process (2).
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