Functional significance of a hepta nucleotide motif present at the junction of Cucumber mosaic virus satellite RNA multimers in helper-virus dependent replication

The non-template functions of helper virus RNAs create optimal replication conditions to enhance the proliferation of satellite RNAs

As a type of parasitic agent, satellite RNAs (satRNAs) rely on cognate helper viruses to achieve their replication and transmission. During the infection of satRNAs, helper virus RNAs serve as templates for synthesizing viral proteins, including the replication proteins essential for satRNA replication. However, the role of non-template functions of helper virus RNAs in satRNA replication remains unexploited. Here we employed the well-studied model that is composed of cucumber mosaic virus (CMV) and its associated satRNA. In the experiments employing the CMV trans-replication system, we observed an unexpected phenomenon the replication proteins of the mild strain LS-CMV exhibited defective in supporting satRNA replication, unlike those of the severe strain Fny-CMV. Independent of translation products, all CMV genomic RNAs could enhance satRNA replication, when combined with the replication proteins of CMV. This enhancement is contingent upon the recruitment and complete replication of helper virus RNAs. Using the method developed for analyzing the satRNA recruitment, we observed a markedly distinct ability of the replication proteins from both CMV strains to recruit the positive-sense satRNA-harboring RNA3 mutant for replication. This is in agreement with the differential ability of both 1a proteins in binding satRNAs in plants. The discrepancies provide a convincing explanation for the variation of the replication proteins of both CMV strains in replicating satRNAs. Taken together, our work provides compelling evidence that the non-template functions of helper virus RNAs create an optimal replication environment to enhance satRNA proliferation.

Molecular interactions of plant viral satellites

Plant viral satellites fall under the category of subviral agents. Their genomes are composed of small RNA or DNA molecules a few hundred nucleotides in length and contain an assortment of highly complex and overlapping functions. Each lacks the ability to either replicate or undergo encapsidation or both in the absence of a helper virus (HV). As the number of known satellites increases steadily, our knowledge regarding their sequence conservation strategies, means of replication and specific interactions with host and helper viruses is improving. This review demonstrates that the molecular interactions of these satellites are unique and highly complex, largely influenced by the highly specific host plants and helper viruses that they associate with. Circularized forms of single-stranded RNA are of particular interest, as they have recently been found to play a variety of novel cellular functions. Linear forms of satRNA are also of great significance as they may complement the helper virus genome in exacerbating symptoms, or in certain instances, actively compete against it, thus reducing symptom severity. This review serves to describe the current literature with respect to these molecular mechanisms in detail as well as to discuss recent insights into this emerging field in terms of evolution, classification and symptom development. The review concludes with a discussion of future steps in plant viral satellite research and development.

Riboproteomics: A versatile approach for the identification of host protein interaction network in plant pathogenic noncoding RNAs

Pathogenic or non-pathogenic small (17 to 30 nt) and long (>200 nt) non-coding RNAs (ncRNAs) have been implicated in the regulation of gene expression at transcriptional, post-transcriptional and epigenetic level by interacting with host proteins. However, lack of suitable experimental system precludes the identification and evaluation of the functional significance of host proteins interacting with ncRNAs. In this study, we present a first report on the application of riboproteomics to identify host proteins interacting with small, highly pathogenic, noncoding satellite RNA (sat-RNA) associated with Cucumber mosaic virus, the helper virus (HV). RNA affinity beads containing sat-RNA transcripts of (+) or (-)-sense covalently coupled to cyanogen bromide activated sepharose beads were incubated with total protein extracts from either healthy or HV-infected Nicotiana benthamiana leaves. RNA-protein complexes bound to the beads were eluted and subjected to MudPIT analysis. Bioinformatics programs PANTHER classification and WoLF-PSORT were used to further classify the identified host proteins in each case based on their functionality and subcellular distribution. Finally, we observed that the host protein network interacting with plus and minus-strand transcripts of sat-RNA, in the presence or absence of HV is distinct, and the global interactome of host proteins interacting with satRNA in either of the orientations is very different.

A shift in plant proteome profile for a Bromodomain containing RNA binding Protein (BRP1) in plants infected with Cucumber mosaic virus and its satellite RNA

Host proteins are the integral part of a successful infection caused by a given RNA virus pathogenic to plants. Therefore, identification of crucial host proteins playing an important role in establishing the infection process is likely to help in devising approaches to curbing disease spread. Cucumber mosaic virus (Q-CMV) and its satellite RNA (QsatRNA) are important pathogens of many economically important crop plants worldwide. In a previous study, we demonstrated the biological significance of a Bromodomain containing RNA-binding Protein (BRP1) in the infection cycle of QsatRNA, making BRP1 an important host protein to study. To further shed a light on the mechanistic role of BRP1 in the replication of Q-CMV and QsatRNA, we analyzed the Nicotiana benthamiana host protein interactomes either for BRP1 alone or in the presence of Q-CMV or QsatRNA. Co-immunoprecipitation, followed by LC-MS/MS analysis of BRP1-FLAG on challenging with Q-CMV or QsatRNA has led us to observe a shift in the host protein interactome of BRP1. We discuss the significance of these results in relation to Q-CMV and its QsatRNA infection cycle.

BIOLOGICAL SIGNIFICANCE

Host proteins play an important role in replication and infection of eukaryotic cells by a wide-range of RNA viruses pathogenic to humans, animals and plants. Since a given eukaryotic cell typically contains ~30,000 different proteins, recent advances made in proteomics and bioinformatics approaches allowed the identification of host proteins critical for viral replication and pathogenesis. Although Cucumber mosaic virus (CMV) and its satRNA are well characterized at molecular level, information concerning the network of host factors involved in their replication and pathogenesis is still on its infancy. We have recently observed that a Bromodomain containing host protein (BRP1) is obligatory to transport satRNA to the nucleus. Consequently, it is imperative to apply proteomics and bioinformatics approaches in deciphering how host interactome network regulates the replication of CMV and its satRNA. In this study, first we established the importance of BRP1 in CMV replication. Then, application of co-immunoprecipitation in conjunction with LC-MS/MS allowed the identification of a wide range of host proteins that are associated with the replication of CMV and its satRNA. Interestingly, a shift in the plant proteome was observed when plants infected with CMV were challenged with its satRNA.

Plant subviral RNAs as a long noncoding RNA (lncRNA): Analogy with animal lncRNAs in host-virus interactions

Satellite RNAs (satRNAs) and viroids belong to the group called subviral agents and are the smallest pathogens of plants. In general, small satRNAs and viroids are 300-400 nt in size and do not encode any functional proteins; they are thus regarded as so-called long noncoding RNAs (lncRNAs). These lncRNAs are receiving great attention as a new RNA class involved in gene regulation to control important biological processes such as gene transcription and epigenetic regulation. A substantial number of lncRNAs in animal cells have been found to play important roles in the interactions between a virus and its host. We here discuss the pathogenicity of subviral RNAs (especially satRNAs) in plant cells and their functions as lncRNAs associated with viral diseases, using animal lncRNAs as an analogy. Because, unlike animal lncRNAs, plant subviral RNAs can replicate and accumulate at very high levels in infected cells, we here considered the unique possibility that the RNA silencing machinery of plants, an important defense mechanism against virus infection, may have brought about the replication ability of subviral molecules. In addition, we also discuss the possibility that satRNAs may have arisen from plant-virus interactions in virus-infected cells. Understanding the molecular functions of these unique lncRNAs in plants will enable us to reveal the most plausible origins of these subviral RNAs.

Infectious long non-coding RNAs

Long non protein coding RNAs (lncRNAs) constitute a large category of the RNA world, able to regulate different biological processes. In this review we are focusing on infectious lncRNAs, their classification, pathogenesis and impact on the infected organisms. Here they are presented in two separate groups: 'dependent lncRNAs' (comprising satellites RNA, Hepatitis D virus and lncRNAs of viral origin) which need a helper virus and 'independent lncRNAs' (viroids) that can self-replicate. Even though these lncRNA do not encode any protein, their structure and/or sequence comprise all the necessary information to drive specific interactions with host factors and regulate several cellular functions. These new data that have emerged during the last few years concerning lncRNAs modify the way we understand molecular biology's 'central dogma' and give new perspectives for applications and potential therapeutic strategies.

Heterologous replicase driven 3' end repair of Cucumber mosaic virus satellite RNA

To investigate the extent of the 3' end repair in a satellite RNA of Cucumber mosaic virus (CMV) strain Q (Q(sat)) by a heterologous Tomato aspermy virus (TAV), a set of biologically active agrotransformants corresponding to the three genomic RNAs of TAV was developed. Analysis of Nicotiana benthamiana plants agroinfiltrated with TAV and either wild type or each of the six 3' deletion mutants of Q(sat) revealed that (i) heterologous replicase failed to generate Q(sat) multimers, a hallmark feature of homologous replicase dependent replication of Qsat; (ii) manifestation of severe symptom phenotypes and progeny analysis suggested that heterologous replicase was competent to repair Q(sat) deletion mutants lacking up to 3'13 nucleotides (nt) but not beyond and (iii) comparative in silico analysis indicated that the 3' secondary structural features of the repaired Q(sat) progeny from heterologous vs homologous driven replicases are remarkably very similar. The significance of these observations is discussed.

Virus-associated small satellite RNAs and viroids display similarities in their replication strategies

Since the discovery of non-coding, small, highly structured, satellite RNAs (satRNAs) and viroids as subviral pathogens of plants , have been of great interest to molecular biologists as possible living fossils of pre-cellular evolution in an RNA world. Despite extensive studies performed in the last four decades, there is still mystery surrounding the origin and evolutionary relationship between these subviral pathogens. Recent technical advances revealed some commonly shared replication features between these two subviral pathogens. In this review, we discuss our current perception of replication and evolutionary origin of these petite RNA pathogens.

Repair of the 3' proximal and internal deletions of a satellite RNA associated with Cucumber mosaic virus is directed toward restoring structural integrity

The phenomenon of rapid turnover of 3' proximal nucleotides (nt) lost by the action of nuclease in RNA viruses is integral to replication. Here, a set of six deletions encompassing the 3' 23 nt region of a satellite RNA (satRNA) of Cucumber mosaic virus (CMV) strain Q (Q-sat), were engineered. Repair of the 3' end was not observed in the absence of CMV. However, co-expression with CMV in planta revealed that Q-sat mutants lacking the 3' 18 nt but not the 3' 23 nt are repaired and the progeny accumulation was inversely proportional to the extent of the deletion. Progeny of the 3'Δ3 mutant were repaired to wild type (wt) while those from the remaining four mutants were heterogeneous, exhibiting a wt secondary structure. Analysis of additional 3' internal deletions mutants revealed that progeny with a repaired sequence reminiscent of wt secondary structure were competent for replication and systemic spread.

A bromodomain-containing host protein mediates the nuclear importation of a satellite RNA of Cucumber mosaic virus

Replication of the satellite RNA (satRNA) of Cucumber Mosaic Virus is dependent on replicase proteins of helper virus (HV). However, we recently demonstrated that like with Potato spindle tuber viroid (PSTVd), a satRNA associated with Cucumber Mosaic Virus strain Q (Q-satRNA) has the propensity to localize in the nucleus and generate multimers that subsequently serve as templates for HV-dependent replication. But the mechanism regulating the nuclear importation of Q-satRNA is unknown. Here we show that the nuclear importation of Q-satRNA is mediated by a bromodomain-containing host protein (BRP1), which is also apparently involved in the nuclear localization of PSTVd. A comparative analysis of nuclear and cytoplasmic fractions from Nicotiana benthamiana plants coinfected with Q-satRNA and its HV confirmed the association of Q-satRNA but not HV with the nuclear compartment. A combination of the MS2-capsid protein-based RNA tagging assay and confocal microscopy demonstrated that the nuclear localization of Q-satRNA was completely blocked in transgenic lines of Nicotiana benthamiana (ph5.2nb) that are defective in BRP1 expression. This defect, however, was restored when the ph5.2nb lines of N. benthamiana were trans-complemented by ectopically expressed BRP1. The binding specificity of BRP1 with Q-satRNA was confirmed in vivo and in vitro by coimmunoprecipitation and electrophoretic mobility shift assays, respectively. Finally, infectivity assays involving coexpression of Q-satRNA and its HV in wild-type and ph5.2nb lines of N. benthamiana accentuated a biological role for BRP1 in the Q-satRNA infection cycle. The significance of these results in relation to a possible evolutionary relationship to viroids is discussed.