Replicating minichromosomes as a new tool for plastid genome engineering.

Plant molecular farming, that is, using plants as hosts for production of therapeutic proteins and high-value compounds, has gained substantial interest in recent years. Chloroplasts in particular are an attractive subcellular compartment for expression of foreign genes. Here, we present a new method for transgene introduction and expression in chloroplasts that, unlike classically used approaches, does not require transgene insertion into the chloroplast genome. Instead, the transgene is amplified as a physically independent entity termed a 'minichromosome'. Amplification occurs in the presence of a helper protein that initiates the replication process via recognition of specific sequences flanking the transgene, resulting in accumulation of extremely high levels of transgene DNA. Importantly, we demonstrate that such amplified transgenes serve as a template for foreign protein expression, are maintained stably during plant development and are maternally transmitted to the progeny. These findings indicate that the minichromosome-based approach is an attractive tool for transgene expression in chloroplasts and for organelle genome engineering.

Arabidopsis DRB4 protein in antiviral defense against Turnip yellow mosaic virus infection.

RNA silencing is an important antiviral mechanism in diverse eukaryotic organisms. In Arabidopsis DICER-LIKE 4 (DCL4) is the primary antiviral Dicer, required for the production of viral small RNAs from positive-strand RNA viruses. Here, we showed that DCL4 and its interacting partner dsRNA-binding protein 4 (DRB4) participate in the antiviral response to Turnip yellow mosaic virus (TYMV), and that both proteins are required for TYMV-derived small RNA production. In addition, our results indicate that DRB4 has a negative effect on viral coat protein accumulation. Upon infection DRB4 expression was induced and DRB4 protein was recruited from the nucleus to the cytoplasm, where replication and translation of viral RNA occur. DRB4 was associated with viral RNA in vivo and directly interacted in vitro with a TYMV RNA translational enhancer, raising the possibility that DRB4 might repress viral RNA translation. In plants the role of RNA silencing in viral RNA degradation is well established, but its potential function in the regulation of viral protein levels has not yet been explored. We observed that severe infection symptoms are not necessarily correlated with enhanced viral RNA levels, but might be caused by elevated accumulation of viral proteins. Our findings suggest that the control of viral protein as well as RNA levels might be important for mounting an efficient antiviral response.

The ubiquitin-proteasome system regulates the accumulation of Turnip yellow mosaic virus RNA-dependent RNA polymerase during viral infection.

Replication of positive-strand RNA viruses, the largest group of plant viruses, is initiated by viral RNA-dependent RNA polymerase (RdRp). Given its essential function in viral replication, understanding the regulation of RdRp is of great importance. Here, we show that Turnip yellow mosaic virus (TYMV) RdRp (termed 66K) is degraded by the proteasome at late time points during viral infection and that the accumulation level of 66K affects viral RNA replication in infected Arabidopsis thaliana cells. We mapped the cis-determinants responsible for 66K degradation within its N-terminal noncatalytic domain, but we conclude that 66K is not a natural N-end rule substrate. Instead, we show that a proposed PEST sequence within 66K functions as a transferable degradation motif. In addition, several Lys residues that constitute target sites for ubiquitylation were mapped; mutation of these Lys residues leads to stabilization of 66K. Altogether, these results demonstrate that TYMV RdRp is a target of the ubiquitin-proteasome system in plant cells and support the idea that proteasomal degradation may constitute yet another fundamental level of regulation of viral replication.

Regulation of positive-strand RNA virus replication: the emerging role of phosphorylation.

Protein phosphorylation is a reversible post-translational modification that plays a fundamental role in the regulation of many cellular processes. Phosphorylation can modulate protein properties such as enzymatic activity, stability, subcellular localization or interaction with binding partners. The importance of phosphorylation of the replication proteins of negative-strand RNA viruses has previously been documented but recent evidence suggests that replication of positive-strand RNA viruses--the largest class of viruses, including significant human, animal and plant pathogens--may also be regulated by phosphorylation events. The objective of this review is to summarize current knowledge regarding the various regulatory roles played by phosphorylation of nonstructural viral proteins in the replication of positive-strand RNA viruses.

Proteolytic processing of turnip yellow mosaic virus replication proteins and functional impact on infectivity.

Turnip yellow mosaic virus (TYMV), a positive-strand RNA virus belonging to the alphavirus-like supergroup, encodes its nonstructural replication proteins as a 206K precursor with domains indicative of methyltransferase (MT), proteinase (PRO), NTPase/helicase (HEL), and polymerase (POL) activities. Subsequent processing of 206K generates a 66K protein encompassing the POL domain and uncharacterized 115K and 85K proteins. Here, we demonstrate that TYMV proteinase mediates an additional cleavage between the PRO and HEL domains of the polyprotein, generating the 115K protein and a 42K protein encompassing the HEL domain that can be detected in plant cells using a specific antiserum. Deletion and substitution mutagenesis experiments and sequence comparisons indicate that the scissile bond is located between residues Ser879 and Gln880. The 85K protein is generated by a host proteinase and is likely to result from nonspecific proteolytic degradation occurring during protein sample extraction or analysis. We also report that TYMV proteinase has the ability to process substrates in trans in vivo. Finally, we examined the processing of the 206K protein containing native, mutated, or shuffled cleavage sites and analyzed the effects of cleavage mutations on viral infectivity and RNA synthesis by performing reverse-genetics experiments. We present evidence that PRO/HEL cleavage is critical for productive virus infection and that the impaired infectivity of PRO/HEL cleavage mutants is due mainly to defective synthesis of positive-strand RNA.

Phosphorylation of viral RNA-dependent RNA polymerase and its role in replication of a plus-strand RNA virus.

Central to the process of plus-strand RNA virus genome amplification is the viral RNA-dependent RNA polymerase (RdRp). Understanding its regulation is of great importance given its essential function in viral replication and the common architecture and catalytic mechanism of polymerases. Here we show that Turnip yellow mosaic virus (TYMV) RdRp is phosphorylated, when expressed both individually and in the context of viral infection. Using a comprehensive biochemical approach, including metabolic labeling and mass spectrometry analyses, phosphorylation sites were mapped within an N-terminal PEST sequence and within the highly conserved palm subdomain of RNA polymerases. Systematic mutational analysis of the corresponding residues in a reverse genetic system demonstrated their importance for TYMV infectivity. Upon mutation of the phosphorylation sites, distinct steps of the viral cycle appeared affected, but in contrast to other plus-strand RNA viruses, the interaction between viral replication proteins was unaltered. Our results also highlighted the role of another TYMV-encoded replication protein as an antagonistic protein that may prevent the inhibitory effect of RdRp phosphorylation on viral infectivity. Based on these data, we propose that phosphorylation-dependent regulatory mechanisms are essential for viral RdRp function and virus replication.

Assembly of turnip yellow mosaic virus replication complexes: interaction between the proteinase and polymerase domains of the replication proteins.

Turnip yellow mosaic virus (TYMV), a positive-strand RNA virus in the alphavirus-like supergroup, encodes two nonstructural replication proteins (140K and 66K), both of which are required for its RNA genome replication. The 140K protein contains domains indicative of methyltransferase, proteinase, and NTPase/helicase activities, while the 66K protein encompasses the RNA-dependent RNA polymerase domain. Recruitment of the 66K protein to the sites of viral replication, located at the periphery of chloroplasts, is dependent upon the expression of the 140K protein. Using antibodies raised against the 140K and 66K proteins and confocal microscopy, we report the colocalization of the TYMV replication proteins at the periphery of chloroplasts in transfected or infected cells. The replication proteins cofractionated in functional replication complexes or with purified chloroplast envelope membranes prepared from infected plants. Using a two-hybrid system and coimmunoprecipitation experiments, we also provide evidence for a physical interaction of the TYMV replication proteins. In contrast to what has been found for other members of the alphavirus-like supergroup, the interaction domains were mapped to the proteinase domain of the 140K protein and to a large region encompassing the core polymerase domain within the 66K protein. Coexpression and colocalization experiments confirmed that the helicase domain of the 140K protein is unnecessary for the proper recruitment of the 66K protein to the chloroplast envelope, while the proteinase domain appears to be essential for that process. These results support a novel model for the interaction of TYMV replication proteins and suggest that viruses in the alphavirus-like supergroup may have selected different pathways to assemble their replication complexes.

Targeting of the turnip yellow mosaic virus 66K replication protein to the chloroplast envelope is mediated by the 140K protein.

Turnip yellow mosaic virus (TYMV), a positive-strand RNA virus in the alphavirus-like superfamily, encodes two replication proteins, 140K and 66K, both being required for its RNA genome replication. The 140K protein contains domains indicative of methyltransferase, proteinase, and NTPase/helicase, and the 66K protein encompasses the RNA-dependent RNA polymerase domain. During viral infection, the 66K protein localizes to virus-induced chloroplastic membrane vesicles, which are closely associated with TYMV RNA replication. To investigate the determinants of its subcellular localization, the 66K protein was expressed in plant protoplasts from separate plasmids. Green fluorescent protein (GFP) fusion and immunofluorescence experiments demonstrated that the 66K protein displayed a cytoplasmic distribution when expressed individually but that it was relocated to the chloroplast periphery under conditions in which viral replication occurred. The 66K protein produced from an expression vector was functional in viral replication since it could transcomplement a defective replication template. Targeting of the 66K protein to the chloroplast envelope in the course of the viral infection appeared to be solely dependent on the expression of the 140K protein. Analysis of the subcellular localization of the 140K protein fused to GFP demonstrated that it is targeted to the chloroplast envelope in the absence of other viral factors and that it induces the clumping of the chloroplasts, one of the typical cytological effects of TYMV infection. These results suggests that the 140K protein is a key organizer of the assembly of the TYMV replication complexes and a major determinant for their chloroplastic localization and retention.