Biological Activity of Artificial Plant Peptides Corresponding to the Translational Products of Small ORFs in Primary miRNAs and Other Long "Non-Coding" RNAs.

Generally, lncPEPs (peptides encoded by long non-coding RNAs) have been identified in many plant species of several families and in some animal species. Importantly, molecular mechanisms of the miPEPs (peptides encoded by primary microRNAs, pri-miRNAs) are often poorly understood in different flowering plants. Requirement for the additional studies in these directions is highlighted by alternative findings concerning positive regulation of pri-miRNA/miRNA expression by synthetic miPEPs in plants. Further extensive studies are also needed to understand the full set of their roles in eukaryotic organisms. This review mainly aims to consider the available data on the regulatory functions of the synthetic miPEPs. Studies of chemically synthesized miPEPs and analyzing the fine molecular mechanisms of their functional activities are reviewed. Brief description of the studies to identify lncORFs (open reading frames of long non-coding RNAs) and the encoded protein products is also provided.

Constriction of endoplasmic reticulum tubules by the viral movement protein BMB2 is associated with local BMB2 anchorage at constriction sites.

Plant virus-encoded movement proteins (MPs) interact with endoplasmic reticulum (ER) membranes, the cytoskeleton, and plasmodesmata (PD) to mediate intracellular delivery of the virus genome to PD and its further transport through PD from infected to healthy cells. The Hibiscus green spot virus MP termed BMB2 has been shown to induce constrictions of ER tubules and to occur at highly curved membranes, thus showing properties similar to those of reticulons, a class of cellular proteins inducing membrane curvature and shaping the ER tubules. Consistent with this BMB2 function, mRFP-BMB2 localizes to discrete, constricted regions scattered along the ER tubules. Here, using BMB2-mRFP fusion protein as a BMB2 derivative with partially disabled functionality, we demonstrate that the focal localization of BMB2 to discrete sites along the ER tubules is insufficient to induce local tubule constrictions at these sites, suggesting that the formation of ER tubule constrictions represents a specific BMB2 function and is not simply a mechanistic consequence of its localization to the ER. The presented data suggest that the formation of ER-residing BMB2-containing distinct small aggregates, or protein platforms, can be uncoupled from BMB2-induced ER tubule constrictions, whereas the anchoring of platforms at particular ER sites appears to be linked to the constriction of ER tubules at these sites.

Membrane Contacts in Plasmodesmata: Structural Components and Their Functions.

Plasmodesmata (PD) are intercellular channels in plant tissues providing continuity of the cytoplasm, the plasma membrane (PM) and the endoplasmic reticulum (ER) of neighboring cells. These channels allow the active transport of macromolecules such as proteins or RNAs. Thus, PD are believed to play a critical role in the functional unity of plant tissues and the transport of signals required for plant development and responses to external stimuli. Recent findings indicate that the PD channel contains a specialized type of ER-PM membrane contact sites (MCSs), structural links formed between ER and PM with tethering proteins. As shown for animal cells, MCSs are essential for lipid and protein trafficking between ER and PM membranes as well as for stress responses or the maintenance of ER structural integrity. On the other hand, our knowledge of the PD-specific MCSs is still scarce, and experimentally supported models of organization of their structural elements are only starting to emerge. Here, we review the structural and functional properties of proteins that can take part in establishing MCSs in PD. We also discuss the significance of cytoskeleton, lipid membrane microdomains and cell wall components for the maintenance and remodeling of PD-specific MCS in response to various biotic and abiotic stresses.

Double-Stranded RNAs in Plant Protection Against Pathogenic Organisms and Viruses in Agriculture.

Recent studies have shown that plants are able to express the artificial genes responsible for the synthesis of double-stranded RNAs (dsRNAs) and hairpin double-stranded RNAs (hpRNAs), as well as uptake and process exogenous dsRNAs and hpRNAs to suppress the gene expression of plant pathogenic viruses, fungi, or insects. Both endogenous and exogenous dsRNAs are processed into small interfering RNAs (siRNAs) that can spread locally and systemically through the plant, enter pathogenic microorganisms, and induce RNA interference-mediated pathogen resistance in plants. There are numerous examples of the development of new biotechnological approaches to plant protection using transgenic plants and exogenous dsRNAs. This review summarizes new data on the use of transgenes and exogenous dsRNAs for the suppression of fungal and insect virulence genes, as well as viruses to increase the resistance of plants to these pathogens. We also analyzed the current ideas about the mechanisms of dsRNA processing and transport in plants.

Subcellular Localization and Detection of Tobacco mosaic virus ORF6 Protein by Immunoelectron Microscopy.

Members of the genus Tobamovirus represent one of the best-characterized groups of plant positive, single stranded RNA viruses. Previous studies have shown that genomes of some tobamoviruses contain not only genes coding for coat protein, movement protein, and the cistron coding for different domains of RNA-polymerase, but also a gene, named ORF6, coding for a poorly conserved small protein. The amino acid sequences of ORF6 proteins encoded by different tobamoviruses are highly divergent. The potential role of ORF6 proteins in replication of tobamoviruses still needs to be elucidated. In this study, using biochemical and immunological methods, we have shown that ORF6 peptide is accumulated after infection in case of two isolates of Tobacco mosaic virus strain U1 (TMV-U1 common and TMV-U1 isolate A15). Unlike virus particles accumulating in the cytoplasm, the product of the ORF6 gene is found mainly in nuclei, which correlates with previously published data about transient expression of ORF6 isolated from TMV-U1. Moreover, we present new data showing the presence of ORF6 genes in genomes of several tobamoviruses. For example, in the genomes of other members of the tobamovirus subgroup 1, including Rehmannia mosaic virus, Paprika mild mottle virus, Tobacco mild green mosaic virus, Tomato mosaic virus, Tomato mottle mosaic virus, and Nigerian tobacco latent virus, sequence comparisons revealed the existence of a similar open reading frame like ORF6 of TMV.

RNA-binding properties of the plant protein Nt-4/1.

The tobacco α-helical protein Nt-4/1 with unknown function forms ribonucleoprotein (RNP) complexes in vitro. Results obtained by retardation of RNP complexes in agarose gel were confirmed by Western-Northern hybridization. Several deletion and point mutants of Nt-4/1 were constructed, and the RNA-binding site was mapped in a positively charged region of the C-terminal domain of the protein. The results of this study and those described earlier support our hypothesis of the participation of Nt-4/1 protein in spreading RNA-containing pathogens in the plant.

TAS3 Genes for small ta-siARF RNAs in plants belonging to subtribe Senecioninae: occurrence of prematurely terminated RNA precursors.

The various classes of plant 21 - to 24-nt siRNAs derive from long dsRNA precursors that are processed by the ribonuclease Dicer-like (DCL). The species of ta-siRNA were originally discovered in Arabidopsis thaliana. Four gene families have been identified in Arabidopsis that each produces a number of ta-siRNAs: TAS1, TAS2, TAS3 and TAS4. The TAS3 genes encode tasiR-ARF species which target the mRNA of three Auxin Response Factor (ARF) genes (ARF2, ARF3/ETT and ARF4) for subsequent degradation. The function of TAS3 precursor RNA is controlled by two miR390 target sites flanking tandem of ta-siARF sequences. In this paper, we have studied the presence ofta-siARF RNA genes in the representatives of subtribe Senecioninae. Senecioneae is the largest tribe of Asteraceae, comprised of ca. 150 genera and 3,000 species which include many common succulents of greenhouses. Approximately one-third of species are placed in genus Senecio, making it one of the largest genera of flowering plants. However, there was no information on the structure of TAS genes in these plants. We revealed that the TAS3 species (TAS3-Sen1) in Senecio representatives was actively transcribed, and its homologues are distributed among many Asteracea plants and found to be similar to Arabidopsis AtTAS3a gene. We revealed several prematurely terminated transcripts of TAS3-Sen1. Finding the alternative shortened transcripts of TAS3-Sen1 lacking the 3'-terminal site cleaved by miR390 and retaining the 5'-terminal miR390 non-cleaved site suggested their using as decoys for the modulation of miR390 activity to regulate synthesis of ta-siARF RNAs in different Senecioninae species.

Subcellular localization and self-interaction of plant-specific Nt-4/1 protein.

The Nicotiana tabacum Nt-4/1 protein is a plant-specific protein of unknown function. Analysis of bacterially expressed Nt-4/1 protein in vitro revealed that the protein secondary structure is mostly alpha-helical and suggested that it could consist of three structural domains. Earlier studies of At-4/1, the Arabidopsis thaliana-encoded ortholog of Nt-4/1, demonstrated that GFP-fused At-4/1 was capable of polar localization in plant cells, association with plasmodesmata, and cell-to-cell transport. Together with the At-4/1 ability to interact with a plant virus movement protein, these data supported the hypothesis of the At-4/1 protein involvement in viral transport through plasmodesmata. Studies of the Nt-4/1-GFP fusion protein reported in this paper revealed that the protein was localized to cytoplasmic bodies, which were co-aligned with actin filaments and capable of actin-dependent intracellular movement. The Nt-4/1-GFP bodies, being non-membrane structures, were found in association with the plasma membrane, the tubular endoplasmic reticulum and endosome-like structures. Bimolecular fluorescence complementation experiments and inhibition of nuclear export showed that the Nt-4/1 protein was capable of nuclear-cytoplasmic transport. The nuclear export signal (NES) was identified in the Nt-4/1 protein by site-directed mutagenesis. The Nt-4/1 NES mutant was localized to the nucleoplasm forming spherical bodies. Immunogold labeling and electron microscopy of cytoplasmic Nt-4/1-containing bodies and nuclear structures containing the Nt-4/1 NES mutant revealed differences in their fine structure. In mammalian cells, Nt-4/1-GFP formed cytoplasmic spherical bodies similar to those found for the Nt-4/1 NES mutant in plant cell nuclei. Using dynamic laser light scattering and electron microscopy, the Nt-4/1 protein was found to form multimeric complexes in vitro.

Novel miR390-dependent transacting siRNA precursors in plants revealed by a PCR-based experimental approach and database analysis.

TAS loci in plant genomes encode transacting small interfering RNAs (ta-siRNAs) that regulate expression of a number of genes. The function of TAS3 precursor in Arabidopsis thaliana is controlled by two miR390 target sites flanking two ta-siARF sequences targeting mRNAs of ARF transcription factors. Cleavage of the 3'-miR390-site initiates ta-siRNAs biogenesis. Here we describe the new method for identification of plant ta-siRNA precursors based on PCR with oligodeoxyribonucleotide primers mimicking miR390. The method was found to be efficient for dicotiledonous plants, cycads, and mosses. Based on sequences of amplified loci and a database analysis, a novel type of miR390-dependent TAS sequences was identified in dicots. These TAS loci are characterized by a smaller distance between miR390 sites compared to TAS3, a single copy of ta-siARF, and a sequence conservation pattern pointing to the possibility that processing of novel TAS-like locus is initiated by cleavage of the 5'-terminal miR390 target site.

Complementation of the movement-deficient mutations in potato virus X: potyvirus coat protein mediates cell-to-cell trafficking of C-terminal truncation but not deletion mutant of potexvirus coat protein.

The cell-to-cell movement of the GUS-tagged potato virus X (PVX) coat protein (CP) movement-deficient mutant was restored by potyviral CPs of potato virus A (PVA) and potato virus Y (PVY) in Nicotiana benthamiana leaves in transient cobombardment experiments. Viral cell-to-cell movement of PVX CP mutant was complemented in Nicotiana tabacum cv. SR1 transgenic plants expressing PVY CP: PVX RNA and polymerase were detected in the PVX CP mutant-inoculated leaves of transgenic plants. These findings demonstrated the ability of the PVX CP-deficient mutant to move from cell to cell but not long distances in the transgenic plants and suggest that CPs of potex- and potyviruses display complementary activities in the movement process. Potyviral CP alone is not able to carry out these activities, since the mutated PVX CP is indispensable for restored movement. No trans-encapsidation between potyviral CP and PVX RNA was observed. Therefore, potyviral CP facilitates the PVX CP mutant movement by the mechanism that cannot be explained by coat protein substitution. Our data also suggest that CP functioning in cell-to-cell movement is not restricted to a simple passive role in forming virions.

Subcellular sorting of small membrane-associated triple gene block proteins: TGBp3-assisted targeting of TGBp2.

We studied subcellular distribution of green fluorescent protein (GFP)-tagged movement proteins encoded by the second and the third genes of poa semilatent hordeivirus (PSLV) triple gene block (TGB), 15K TGBp2 and 18K TGBp3. GFP-15K transiently expressed in Nicotiana benthamiana leaf epidermal cells was associated with the endomembrane system elements. GFP-18K appeared in the membrane bodies at cell periphery. Mutation analysis demonstrated that subcellular targeting of GFP-15K depended on the protein transmembrane segment(s), whereas the TGBp3 central hydrophilic region was responsible for targeting of GFP-18K. Coexpression of GFP-15K with the intact 18K protein induced drastic changes in the TGBp2 localization: GFP-15K appeared in the cell peripheral bodies similar to those in the cells expressing GFP-18K alone. Coexpression experiments with mutant forms of both proteins argue against involvement of direct interaction between small TGB proteins in the TGBp3-assisted targeting of TGBp2 to the cell peripheral compartments. This conclusion was further confirmed by similar effects on the PSLV 15K TGBp2 localization induced by TGBp3 proteins of PSLV and potato virus X, which have no detectable sequence similarity to each other.

Evidence for two nonoverlapping functional domains in the potato virus X 25K movement protein.

To study subdomain organization of the potato virus X (PVX) movement protein (MP) encoded by the first gene in the triple gene block (TGB), we mutated the 25-kDa TGBp1 protein. The N-terminal deletion of the helicase motifs I, IA, and II resulted in loss of the ATPase activity and RNA binding. A frameshift mutation truncating the C-terminal motifs V and VI gave rise to increase of the TGBp1 ATPase activity and had little effect on RNA binding in vitro. Fusions of the green fluorescent protein with 25-kDa MP and its derivative lacking motifs V-VI exhibited similar fluorescence patterns in epidermal cells of Nicotiana benthamiana leaves. Cell-to-cell movement of the 25K-deficient PVX genome was not complemented by the TGBp1 of Plantago asiatica mosaic potexvirus (PlAMV) but was efficiently complemented by a chimeric TGBp1 consisting of the N-terminal part of PlAMV protein (motifs I-IV) and the PVX-specific C-terminal part (motifs V-VI). These results suggest that NTP hydrolysis, RNA binding, and targeting to the specific cellular compartment(s) are associated with the N-terminal domain of the TGBp1 including the helicase motifs I-IV and that the C-terminal domain is involved in specific interactions with other virus proteins.

Movement of hordeivirus hybrids with exchanges in the triple gene block.

The barley stripe mosaic virus (BSMV) triple gene block (TGB) coding for movement proteins (MPs) was replaced with the respective TGB genes from two other hordeiviruses, poa semilatent virus (PSLV) or lychnis ringspot virus (LRSV). The BSMV/LRSV recombinant did not exhibit infectivity on the plants tested, whereas the infection rate and host range of the BSMV/PSLV hybrid were similar to those of BSMV. In particular, the BSMV/PSLV hybrid infected Nicotiana benthamiana, a nonhost plant for PSLV, indicating a contribution of non-MP elements of BSMV genome to host specificity of virus transport. Assuming that the PSLV TGB was functional in the BSMV genome context, a further series of recombinants was constructed, in which smaller portions of the BSMV TGB were replaced by the corresponding PSLV sequences. Examination of the infectivity of the hybrid viruses suggested that the TGB-coded proteins could interact in a host-dependent manner to mediate cell-to-cell movement. Analysis of recombinants with hybrid sequences of the first gene in the TGB (beta b gene) indicated that (i) sequence-independent binding of beta b to viral RNAs could occur during formation of beta b-RNA complexes in vivo, and that (ii) the beta b MP is involved in virus long-distance movement, for which homologous N- and C-terminal beta b domains are required.

Analysis of six DNA components of the faba bean necrotic yellows virus genome and their structural affinity to related plant virus genomes.

Faba bean necrotic yellows virus (FBNYV) has a multicomponent circular ssDNA genome. In addition to a previously described genome component (C1) coding for a replicase-associated protein (Rep), five further components (C2 to C6) have now been identified. Each of the six components is about 1 kb in size, contains one major open reading frame (ORF) in the virion sense with a TATA box and polyadenylation signal, and has a noncoding region containing a highly conserved sequence possibly forming a stem-loop structure. Similar to C1, C2 encodes another putative Rep of 33.1 kDa, which is closely related to the Rep of banana bunchy top virus (BBTV). Based on bacterial expression and immunoblot analysis, the ORF of C5 encodes the capsid protein (CP) with a deduced molecular mass of 19 kDa. The FBNYV CP shares the highest amino acid (aa) identity (56.2%) with that of subterranean clover stunt virus (SCSV). The ORF of C4 potentially codes for a hydrophobic protein which appears to be structurally and functionally similar to the BBTV-C4 and SCSV-C1 proteins. No protein sequence similarities were found in databases for the C3 and C6 ORFs of FBNYV. FBNYV is clearly distinct from any known virus but is taxonomically related to BBTV and SCSV.

Comparisons of the genomic cis-elements and coding regions in RNA beta components of the hordeiviruses barley stripe mosaic virus, lychnis ringspot virus, and poa semilatent virus.

Nucleotide sequences of the genomic RNA beta components of hordeiviruses poa semilatent virus (PSLV) and lychnis ringspot virus (LRSV) were determined. PSLV and LRSV closely resemble barley stripe mosaic virus (BSMV), type hordeivirus, in the gene arrangement of their RNAs beta, comprising 5'-proximal beta a (coat protein) gene and downstream triple gene block (TGB) coding for the beta b, beta c, and beta d putative transport proteins. The beta a, beta b, beta c, and beta d proteins of the three hordeiviruses showed significant sequence similarity, with the respective proteins of PSLV and BSMV being closer to each other than to their counterparts of LSRV. Comparisons of the TGB-encoded proteins of hordeiviruses, potexviruses, carlaviruses, and furoviruses indicate that the first and second TGB genes belong to the monophyletic groups, whereas the third gene may have multiple ancestry. LRSV, PSLV, and BSMV showed remarkable variation in the 3'-untranslated regions of their genomic RNAs. Among the three hordeiviruses, LRSV has the shortest 3'-noncoding region that lacks tentative pseudoknot-forming elements conserved upstream of the 3'-tRNA-like structure in the BSMV and PSLV genomes. On the other hand, LRSV RNA beta, like that of BSMV, contained the internal poly(A) sequence that is absent from PSLV RNA.

Movement of a barley stripe mosaic virus chimera with a tobacco mosaic virus movement protein.

The tobacco mosaic virus (TMV) 30K movement protein (MP) gene was inserted into a full-length cDNA clone of barley stripe mosaic virus (BSMV) RNA beta replacing the triple gene block (TGB). The resulting recombinant ND-MPT genome, consisting of infectious wt transcripts of BSMV RNAs alpha and gamma, together with the hybrid RNA beta transcript, was inoculated onto test plants to study the functional compatibility between the BSMV TGB-adapted genetic system and the tobamovirus transport gene. ND-MPT infected the inoculated leaves of Nicotiana benthamiana and Chenopodium amaranticolor, which are common hosts for the parental viruses; the size, growth rate, and morphology of local lesions on C. amaranticolor were influenced by the foreign MP gene. However, the hybrid virus failed to infect barley, N. tabacum (var. Samsun), and N. clevelandii, the selective hosts. Thus, the TMV MP was able to functionally substitute for the BSMV TGB-coded MPs, i.e., the 30K MP functioned independently of any other BSMV sequences. However, the TMV MP gene promoted the cell-to-cell movement in a host-dependent manner.

In vitro membrane binding of the translation products of the carlavirus 7-kDa protein genes.

Two double-stranded DNA copies of the genes potentially coding for the 7-kDa proteins of potato virus M (PVM) and potato virus S (PVS) were synthesized and cloned into T7 transcription vectors. Cell-free translation of the corresponding monocistronic transcripts yielded in both cases a single protein of approximately 7-8 kDa that contains a highly hydrophobic N-terminal segment. To analyze their membrane-binding potential, both proteins were synthesized in the membrane-enriched Krebs-2 extract. It was found that the smooth membrane fraction was enriched in the carlavirus 7-kDa proteins. The primary and predicted secondary structures of their N-terminal hydrophobic segments suggest that the latter can function as signals for translocation into the rough endoplasmic reticulum.

Translational efficiency and competitive ability of mRNAs with 5'-untranslated alpha beta-leader of potato virus X RNA.

The 5'-untranslated leader sequence of potato virus X (PVX) RNA (63 nucleotides apart from cap-structure) consists of two sub-sequences referred to as alpha-sequence (41 nucleotides with no G) and beta-sequence (42 nucleotides upstream from the first AUG). Computer-based folding predictions suggest that the 5'-proximal region of alpha beta-leader is unstructured. The second structural feature of alpha beta-leader is the presence of the sequences apparently complementary to the 3'-terminal region of 18S rRNA. The alpha beta-leader has been shown to strongly enhance the translation of the contiguous foreign gene (NPT1) transcripts in cell-free translation systems from rabbit reticulocytes (RRL), wheat germ (WG) and Krebs-2 ascite cell extract (KA). In competitive translation PVX, RNA strongly inhibited tobacco mosaic virus (TMV) RNA, in RRL and WG systems. No competition occurred between PVX and TMV RNAs in KA system. There was no correlation between the translational efficiency and competitive ability of PVX RNA in different cell-free translation systems. The competitive ability did not solely depend on the presence of alpha beta-leader in mRNA. We present evidence to suggest that alpha beta-leader together with about 150 bases of the coding sequence is responsible for the translation competitive ability of PVX RNA.