Potential involvement of a cucumber homolog of phloem protein 1 in the long-distance movement of Cucumber mosaic virus particles.

The systemic movement of Cucumber mosaic virus (CMV) in cucumber plants was analyzed. The structure that is translocated and its putative interactions with phloem components were analyzed in phloem exudate (PE) samples, which reflect sieve tubes stream composition. Rate zonal centrifugation and electron-microscopy analyses of PE from CMV-infected plants showed that CMV moves through sieve tubes as virus particles. Gel overlay assays revealed that CMV particles interact with a PE protein, p48. The amino-acid sequence of several tryptic peptides of p48 was determined. Partial amino-acid sequence of p48 showed it was a cucumber homolog of phloem protein 1 (PP1) from pumpkin, with which p48 also shares several chemical properties. PP1 from pumpkin has plasmodesmata-gating ability and translocates in sieve tubes. Encapsidated CMV RNA in PE samples from infected plants was less accessible to digestion by RNase A than RNA in purified CMV particles, a property that was reconstituted by the in vitro interaction of purified CMV particles and protein p48. These results indicate that the interaction with p48 modifies CMV particle structure and suggest that CMV particles interact with the cucumber homolog of PP1 during translocation in the sieve tubes.

Preservation of 5'-end integrity of a potyvirus genomic RNA is not dependent on template specificity.

Full-length in vitro transcripts of plum pox potyvirus (PPV) genomic RNA with mutations altering the number of 5'-terminal adenosine residues were able to infect Nicotiana clevelandii plants, whereas a mutant with a substitution of adenosine in position 2 by guanosine failed to infect. The genomic 5' end was template-independently repaired during in vivo RNA synthesis producing wild-type viral progeny. Putative models of replication initiation are discussed.

Virus particles of cucumber green mottle mosaic tobamovirus move systemically in the phloem of infected cucumber plants.

Systemic movement through the phloem of infected host plants is a key process in the life cycle of plant viruses, knowledge of which is scant. A main point to be elucidated is the structural form in which virus infection moves within the phloem. Indirect evidence suggests that virions might be the viral structure that moves in the phloem, but data from direct analysis in phloem sap have not been reported. We have done such analysis in the system cucumber (from which phloem exudate can be collected)/cucumber green mottle mosaic tobamovirus (CGMMV). CGMMV has structurally well-characterized particles. Both CGMMV coat protein and RNA were found in phloem exudate from infected cucumbers. Analysis of the accessibility of CGMMV RNA in phloem exudate to RNase A indicates that it is protected within a ribonucleoprotein structure. The accessibility to RNase A of the RNA in these structures was as in virus particles. Centrifugation analyses showed that the ribonucleoprotein structures in the phloem exudate have the same mass and isopycnic density as virions. Virus particles indistinguishable from purified virions were detected by electron microscopy in phloem exudate. No evidence of free RNA or other CGMMV-related structure was found in phloem exudate of infected plants. These results indicate that CGMMV movement in the phloem occurs mainly, if not exclusively, in the form of virus particles.

A regulatory locus, pehSR, controls polygalacturonase production and other virulence functions in Ralstonia solanacearum.

We previously identified a locus that regulates production of polygalacturonase (PG), an extracellular plant cell wall-degrading enzyme important in bacterial wilt of plants caused by Ralstonia (Pseudomonas) solanacearum. The DNA sequence of this locus, called pehSR, was determined and two consecutive open reading frames (ORFs) of 1,905 and 1,680 bp were identified. The amino acid sequences predicted to be encoded by these ORFs are similar to those of regulators of pilin synthesis in Pseudomonas aeruginosa and Myxococcus xanthus and to a regulator of flagellin synthesis and adhesion in P. aeruginosa, as well as to other two-component regulators of the NtrB/C subfamily. pehSR mutants produced negligible levels of endo-PG activity, while exo-PG activity was reduced by 50%. Northern (RNA) blot analysis showed that PehSR regulates endo-PG expression at the transcriptional level. pehSR mutants grew normally in culture and in planta but were dramatically reduced in virulence; this loss of virulence was substantially greater than that observed for endo-PG structural gene mutants, suggesting that pehSR regulates additional factors important in virulence. Although pehSR mutants were essentially nonmotile, like the wild-type strain, multiple copies of pehSR conferred motility on the bacterium. Reporter gene studies indicated that pehSR expression increased when bacteria grew in plant tissue, and that the pehSR locus was itself negatively regulated by the global virulence gene regulator PhcA.

Long sequences in the 5' noncoding region of plum pox virus are not necessary for viral infectivity but contribute to viral competitiveness and pathogenesis.

The 5'-terminal 31 nucleotides of the 146-nucleotides-long 5' noncoding region of plum pox potyvirus (PPV) are highly conserved in all the members of the Potyvirus genus. To map the sequences of the 5' noncoding region that are necessary in vivo for infectivity, we have constructed a nested set of substitution and deletion mutants. While we were not able to infect Nicotiana clevelandii plants with full-length PPV transcripts bearing mutations in the 5'-terminal 35 nucleotides of the viral genome, the deletion of long sequences located between nucleotides 39 and 145 did not alter either the rate of infection or viral accumulation. Nevertheless, these mutants were not able to compete with the wild-type strain in coinoculation experiments. Plants infected with a PPV mutant that lacked nucleotides 127 to 145 showed a very mild symptomathology; the wild-type symptom severity was recovered after spontaneous second-site mutations.

Cap-independent leaky scanning as the mechanism of translation initiation of a plant viral genomic RNA.

The genome of plum pox virus contains a single open reading frame that is translated into a large polyprotein. Although the open reading frame starts at nucleotide 36 (36AUG), it is translated from the second, 147AUG, which is in a more favourable context for translation initiation. We have carried out in vitro translation and transient expression analysis in protoplasts of a nested set of substitution and deletion mutants, and the results show that no internal structure in the 5' noncoding region of plum pox virus is necessary for efficient translation initiation. On the other hand, when the cryptic 36AUG was placed in a favourable context, it turned into an efficient initiation codon in vitro. Furthermore, AUGs that were placed in a favourable context, initiating short intraleader open reading frames, repressed translation initiation from the 147AUG in vitro and in vivo. These results point to leaky scanning as the mechanism of translation initiation of plum pox virus RNA. Nevertheless, it is a peculiar leaky scanning where the initiation of translation does not require a cap structure at the 5' end. This fact is congruent with the experimentally predicted absence of a stable secondary structure at the 5' noncoding region.

The motif V of plum pox potyvirus CI RNA helicase is involved in NTP hydrolysis and is essential for virus RNA replication.

The plum pox potyvirus (PPV) protein CI is an RNA helicase whose function in the viral life cycle is still unknown. The CI protein contains seven conserved sequence motifs typical of RNA helicases of the superfamily SF2. We have introduced several individual point mutations into the region coding for motif V of the PPV CI protein and expressed these proteins in Escherichia coli as maltose binding protein fusions. Mutations that abolished RNA helicase activity also disturbed NTP hydrolysis. No mutations affected the RNA binding capacity of the CI protein. These mutations were also introduced in the PPV genome making use of a full-length cDNA clone. Mutant viruses carrying CI proteins with reduced RNA helicase activity replicated very poorly in protoplasts and were unable to infect whole plants without rapid pseudoreversion to wild-type. These results indicate that motif V is involved in the NTP hydrolysis step required for potyvirus RNA helicase activity, and that this activity plays an essential role in virus RNA replication inside the infected cell.