Odile Hemmer

Intracellular Localization of the Peanut Clump Virus Replication Complex in Tobacco BY-2 Protoplasts Containing Green Fluorescent Protein-Labeled Endoplasmic Reticulum or Golgi Apparatus

ABSTRACT RNA-1 of Peanut clump virus (PCV) encodes the proteins P131 and P191, containing the signature motifs of replication proteins, and P15, which regulates viral RNA accumulation. In PCV-infected protoplasts both P131 and P191 were immunodetected in the perinuclear region. Laser scanning confocal microscopy (LSCM) showed that P131 and P191 colocalized with neosynthesized 5-bromouridine 5′-triphosphate-labeled RNA and double-stranded RNA, demonstrating that they belong to the replication complex. On the contrary, the P15 fused to the enhanced green fluorescent protein (EGFP) never colocalized with the two proteins. In endoplasmic reticulum (ER)-GFP transgenic BY-2 protoplasts, the distribution of the green fluorescent-labeled ER was strongly modified by PCV infection. LSCM showed that both P131 and P191 colocalized with ER green fluorescent bodies accumulating around the nucleus during infection. The replication process was not inhibited by cerulenin and brefeldin A, suggesting that PCV replication does not depend on de novo-synthesized membrane and does not require transport through the Golgi apparatus. Electron microscopy of ultrathin sections of infected protoplasts showed aggregates of broken ER but also visualized vesicles, some of which resembled modified peroxisomes. The results suggest that accumulation of PCV during infection is accompanied by specific association of PCV RNA-1-encoded proteins with membranes of the ER and other organelles. The concomitant extensive rearrangement of these membranous structures leads to the formation of intracellular compartments in which synthesis and accumulation of the viral RNA occur in defined areas.

Peanut Clump Virus RNA-1-Encoded P15 Regulates Viral RNA Accumulation but Is Not Abundant at Viral RNA Replication Sites

ABSTRACT RNA-1 of peanut clump pecluvirus (PCV) encodes N-terminally overlapping proteins which contain helicase-like (P131) and polymerase-like (P191) domains and is able to replicate in the absence of RNA-2 in protoplasts of tobacco BY-2 cells. RNA-1 also encodes P15, which is expressed via a subgenomic RNA. To investigate the role of P15, we analyzed RNA accumulation in tobacco BY-2 protoplasts inoculated with RNA-1 containing mutations in P15. For all the mutants, the amount of progeny RNA-1 produced was significantly lower than that obtained for wild-type RNA-1. If RNA-2 was included in the inoculum, the accumulation of both progeny RNAs was diminished, but near-normal yields of both could be recovered if the inoculum was supplemented with a small, chimeric viral replicon expressing P15, demonstrating that P15 has an effect on viral RNA accumulation. To further analyze the role of P15, transcripts were produced expressing P15 fused to enhanced green fluorescent protein (EGFP). Following inoculation to protoplasts, epifluorescence microscopy revealed that P15 accumulated as spots around the nucleus and in the cytoplasm. Intracellular sites of viral RNA synthesis were visualized by laser scanning confocal microscopy of infected protoplasts labeled with 5-bromouridine 5′-triphosphate (BrUTP). BrUTP labeling also occured in spots distributed within the cytoplasm and around the nucleus. However, the BrUTP-labeled RNA and EGFP/P15 very rarely colocalized, suggesting that P15 does not act primarily at sites of viral replication but intervenes indirectly to control viral accumulation levels.

Analysis of the in vitro cleavage products of the tomato black ring virus RNA-1-encoded 250K polyprotein.

Tomato black ring virus RNA-1 was translated in a rabbit reticulocyte lysate. The primary translation product of Mr 250K, which corresponds to its whole coding capacity, was synthesized within 45 min and, during further incubation in the translation medium, was proteolytically processed. Essentially, four cleavage products (P190, P120, P60 and P50) were detected and located within P250 by pulse-chase and immunoprecipitation experiments. P190 is an intermediate cleavage product which is further cleaved to form P60 and P120. P120, which contains the region that has been assigned to the virus protease and the virus polymerase, was not further cleaved in vitro.

Comparison of the nucleotide sequences of five tomato black ring virus satellite RNAs

Summary The nucleotide sequences of the satellite RNAs associated with tomato black ring virus isolates L, G, E and C were determined and compared with the sequence of the satellite associated with strain S determined earlier. The sequence of satellite L closely resembled that of satellite S and both were to a lesser extent similar to satellites G, E and C which themselves were closely similar. There was 90% or more sequence homology between satellites in each group, G and E being the most closely related, with only one nucleotide (nt) difference between them. There was about 60% homology between the groups. Satellites G, E and C had longer 5′ non-coding regions (40 nt) than satellites L and S (14 nt), but were shorter by 11 to 13 nt in their 3′ non-coding regions. The sequences all contained a single large open reading frame for proteins of mol. wt. 47808 (424 amino acids) (L), 47792 (419 amino acids) (G, E) and 47698 (419 amino acids) (C). The deduced amino acid sequences differed principally in their N-terminal 65 residues. Several regions of sequence comprising 10 or more amino acids, and one of 31 amino acids, were identical in all satellite sequences. No marked sequence similarities were detected between the satellite sequences and a number of viral protein and nucleic acid sequences available in databases. The extent of homology between the 3′ ends of satellite sequences and those of RNA-1 or RNA-2 of TBRV was slight, consisting of several hexa- and heptanucleotides.

Functional characterization of the proteolytic activity of the tomato black ring nepovirus RNA-1-encoded polyprotein.

Translation of tomato black ring virus (TBRV) RNA-1 in a rabbit reticulocyte lysate leads to the synthesis of a 250K polyprotein which cleaves itself into smaller proteins of 50, 60, 120, and 190K. Polypeptides synthesized from synthetic transcripts corresponding to different regions of TBRV RNA-1 are processed only when they encode the 23K protein delimited earlier by sequence homology with the cowpea mosaic virus 24K protease. The proteolytic activity of this protein is completely lost by mutating residues C170 (to I) or L188 (to H), residues which align with conserved residues of the viral serine-like proteases. The 120K protein is generated by cleavage of the dipeptide K/A localized in front of the VPg but is not further cleaved in vitro at the K/S site (at the C terminus of the VPg) or between the protease and polymerase domains. However, both the protein VPgProPol (120K) and the protein ProPol (117K) produced in vitro from synthetic transcripts can cleave in trans the RNA-2-encoded 150K polyprotein, but they cannot cleave in trans polypeptides containing a cleavage site expressed from RNA-1 transcripts in which the protease cistron is absent or modified.

The Valine Anticodon and Valylatability of Peanut Clump Virus RNAs Are Not Essential but Provide a Modest Competitive Advantage in Plants

ABSTRACT The role of valine aminoacylation of the two genomic RNAs ofPeanut clump virus (PCV) was studied by comparing the amplification in vivo of RNAs with GAC, GΔC, or CCA anticodons in the tRNA-like structure (TLS) present at the 3′ end of each viral RNA. The PCV RNA1 TLS of isolate PCV2 possesses a GAC anticodon and is capable of highly efficient valylation, whereas the RNA2 TLS has a GΔC anticodon that does not support valylation. The presence in RNA1 of GΔC or CCA anticodons that conferred nonvalylatability resulted in about 2- to 4-fold and a 14- to 24-fold reduction, respectively, in RNA accumulations in tobacco BY-2 protoplasts inoculated with the RNA1 variants together with wild-type RNA2(GΔC). No differences in RNA levels were observed among protoplasts inoculated with the three variant RNA2s in the presence of wild-type RNA1(GAC). All combinations of valylatable and nonvalylatable RNAs 1 and 2 were similarly infectious in Nicotiana benthamiana plants, and viral RNAs accumulated to similar levels; all input TLS sequences were present unchanged in apical leaves. In direct competition experiments in N. benthamiana plants, however, both RNA1 and RNA2 with GAC valylatable anticodons outcompeted the nonvalylatable variants. We conclude that valylation provides a small but significant replicational advantage to both PCV RNAs. Sequence analysis of the TLS from RNA2 of a second PCV isolate, PO2A, revealed the presence of an intact GAC valine anticodon, suggesting that the differential valylation of the genomic RNAs of isolate PCV2 is not a general characteristic of PCV.

Detection of a proteolytic activity in the micrococcal nuclease used for preparation of messenger‐dependent reticulocyte lysates

Some, but not all, commercial preparations of micrococcal nuclease used to remove endogenous mRNA from reticulocyte lysates were found to contain proteolytic activity. The protease(s) caused a time‐dependent cleavage of the polyprotein primary translation products of genome RNA of several plant viruses, but did not affect the translation products of some other virus mRNA. The activity resulted in the production of smaller proteins and was inhibited by zinc ions. Thus the protease(s) mimicked virus‐coded proteases and represents a potential artifact in studies of translation products of virus RNA.