Determinants of minor satellite RNA function in chromosome segregation in mouse embryonic stem cells.

The centromere is a fundamental higher-order structure in chromosomes ensuring their faithful segregation upon cell division. Centromeric transcripts have been described in several species and suggested to participate in centromere function. However, low sequence conservation of centromeric repeats appears inconsistent with a role in recruiting highly conserved centromeric proteins. Here, we hypothesized that centromeric transcripts may function through a secondary structure rather than sequence conservation. Using mouse embryonic stem cells (ESCs), we show that an imbalance in the levels of forward or reverse minor satellite (MinSat) transcripts leads to severe chromosome segregation defects. We further show that MinSat RNA adopts a stem-loop secondary structure, which is conserved in human α-satellite transcripts. We identify an RNA binding region in CENPC and demonstrate that MinSat transcripts function through the structured region of the RNA. Importantly, mutants that disrupt MinSat secondary structure do not cause segregation defects. We propose that the conserved role of centromeric transcripts relies on their secondary RNA structure.

Nuclear stress bodies: Interaction of its components in oncogenic regulation.

Oncogenesis involves continuous genetic alterations that lead to compromised cellular integrity and immortal cell fate. The cells remain under excessive stress due to endo- and exogenous influences. Human Satellite III long noncoding RNA (SatIII lncRNA) is a key regulator of the global cellular stress response, although its function is poorly explained in cancers. The principal regulator of cancer meshwork is tumor protein p53, which if altered may result in chemoresistance. The heat shock factor 1 (HSF1) being a common molecule between the oncogenic control and global cellular stress acts as an oncogene as well as transcribes SatIII upon heat shock. This prompted us to determine the structure of SatIII RNA and establish the association between SatIII-HSF1-p53. We determined the most stable structure of SatIII RNA with the least energy of - 115.7 kcal/mol. Also, we observed a possible interaction of p53 with SatIII and HSF1 using support vector machine (SVM) algorithm for predicting RNA-protein interaction (RPI). Further, we employ the STRING database to understand if p53 is an interacting component of the nuclear stress bodies (nSBs). A precise inference was drawn from molecular docking which confirmed the interaction of SatIII-HSF1-p53, where a mutated p53 resulted in an altered DNA-binding property with the SatIII molecule. This study being first of its kind infers p53 to be a possible integral component of the nSBs, which may regulate cellular stress response during cancer progression in the presence of HSF1 and SatIII. An extended research on the regulations of SatIII and p53 may open new avenues in the field of apoptosis in cancer and the early approach of molecular targeting.

SELEX and SHAPE reveal that sequence motifs and an extended hairpin in the 5' portion of Turnip crinkle virus satellite RNA C mediate fitness in plants.

Noncoding RNAs use their sequence and/or structure to mediate function(s). The 5' portion (166 nt) of the 356-nt noncoding satellite RNA C (satC) of Turnip crinkle virus (TCV) was previously modeled to contain a central region with two stem-loops (H6 and H7) and a large connecting hairpin (H2). We now report that in vivo functional selection (SELEX) experiments assessing sequence/structure requirements in H2, H6, and H7 reveal that H6 loop sequence motifs were recovered at nonrandom rates and only some residues are proposed to base-pair with accessible complementary sequences within the 5' central region. In vitro SHAPE of SELEX winners indicates that the central region is heavily base-paired, such that along with the lower stem and H2 region, one extensive hairpin exists composing the entire 5' region. As these SELEX winners are highly fit, these characteristics facilitate satRNA amplification in association with TCV in plants.

Biologically-supported structural model for a viral satellite RNA.

Satellite RNAs (satRNAs) are a class of small parasitic RNA replicon that associate with different viruses, including plus-strand RNA viruses. Because satRNAs do not encode a polymerase or capsid subunit, they rely on a companion virus to provide these proteins for their RNA replication and packaging. SatRNAs recruit these and other required factors via their RNA sequences and structures. Here, through a combination of chemical probing analysis of RNA structure, phylogenetic structural comparisons, and viability assays of satRNA mutants in infected cells, the biological importance of a deduced higher-order structure for a 619 nt long tombusvirus satRNA was assessed. Functionally-relevant secondary and tertiary RNA structures were identified throughout the length of the satRNA. Notably, a 3'-terminal segment was found to adopt two mutually-exclusive RNA secondary structures, both of which were required for efficient satRNA accumulation. Accordingly, these alternative conformations likely function as a type of RNA switch. The RNA switch was also found to engage in a required long-range kissing-loop interaction with an upstream sequence. Collectively, these results establish a high level of conformational complexity within this small parasitic RNA and provide a valuable structural framework for detailed mechanistic studies.

Rapid evolution of in vivo-selected sequences and structures replacing 20% of a subviral RNA.

The 356 nt noncoding satellite RNA C (satC) of Turnip crinkle virus (TCV) is composed of 5' sequences from a second TCV satRNA (satD) and 3' sequences derived from TCV. SHAPE structure mapping revealed that 76 nt in the poorly-characterized satD-derived region form an extended hairpin (H2). Pools of satC in which H2 was replaced with 76, 38, or 19 random nt were co-inoculated with TCV helper virus onto plants and satC fitness assessed using in vivo functional selection (SELEX). The most functional progeny satCs, including one as fit as wild-type, contained a 38-39 nt H2 region that adopted a hairpin structure and exhibited an increased ratio of dimeric to monomeric molecules. Some progeny of satC with H2 deleted featured a duplication of 38 nt, partially rebuilding the deletion. Therefore, H2 can be replaced by a 38-39 nt hairpin, sufficient for overall structural stability of the 5' end of satC.

Fluorescence in situ hybridization of small non-coding RNAs.

RNA FISH is a powerful method to detect specific RNAs in fixed cells. It allows both localization and quantification of RNA molecules within individual cells and tissues. Refined RNA FISH methods have also been developed to determine RNA transcription and degradation rates. This chapter describes an RNA FISH protocol that we developed in order to study the expression and localization of satellite III RNAs. This specific class of non-coding RNAs is expressed in response to various cellular stresses including heat shock. This protocol is based on the use of a biotinylated LNA probe subsequently detected by a streptavidin-Alexa Fluor(®) 488 conjugate. A protocol allowing efficient coupling of RNA FISH and protein detection by immunofluorescence is also described in this chapter.

Structural and functional analysis of CMV satellite RNAs in RNA silencing.

Viroids and satellite RNAs, which are the smallest infectious agents in plants, have noncoding RNA genomes and characteristic secondary structures. Some satellite RNAs (satRNAs) cause disease symptoms that are different from those induced by their helper virus. This phenomenon has been implicated in RNA silencing of host gene(s) as a result of sequence identity or complementarity between satRNAs and host RNAs. To investigate the effects of satRNA sequence on direct coincident interference with host gene expression, we developed a transient RNA silencing assay using protoplasts. With this protoplast system, we can induce various forms and lengths of silencing inducers at various concentrations to uniform cells without viral infection, and then we can use the satRNA-treated protoplasts in further analyses such as real-time RT-PCR and northern blot hybridization analyses to investigate whether the satRNA-induced symptoms are due to down-regulation of the target gene expression.

Helper virus-independent transcription and multimerization of a satellite RNA associated with cucumber mosaic virus.

Satellite RNAs are the smallest infectious agents whose replication is thought to be completely dependent on their helper virus (HV). Here we report that, when expressed autonomously in the absence of HV, a variant of satellite RNA (satRNA) associated with Cucumber mosaic virus strain Q (Q-satRNA) has a propensity to localize in the nucleus and be transcribed, generating genomic and antigenomic multimeric forms. The involvement of the nuclear phase of Q-satRNA was further confirmed by confocal microscopy employing in vivo RNA-tagging and double-stranded-RNA-labeling assays. Sequence analyses revealed that the Q-satRNA multimers formed in the absence of HV, compared to when HV is present, are distinguished by the addition of a template-independent heptanucleotide motif at the monomer junctions within the multimers. Collectively, the involvement of a nuclear phase in the replication cycle of Q-satRNA not only provides a valid explanation for its persistent survival in the absence of HV but also suggests a possible evolutionary relationship to viroids that replicate in the nucleus.

The conserved 5' apical hairpin stem loops of bamboo mosaic virus and its satellite RNA contribute to replication competence.

Satellite RNAs associated with Bamboo mosaic virus (satBaMVs) depend on BaMV for replication and encapsidation. Certain satBaMVs isolated from natural fields significantly interfere with BaMV replication. The 5' apical hairpin stem loop (AHSL) of satBaMV is the major determinant in interference with BaMV replication. In this study, by in vivo competition assay, we revealed that the sequence and structure of AHSL, along with specific nucleotides (C(60) and C(83)) required for interference with BaMV replication, are also involved in replication competition among satBaMV variants. Moreover, all of the 5' ends of natural BaMV isolates contain the similar AHSLs having conserved nucleotides (C(64) and C(86)) with those of interfering satBaMVs, suggesting their co-evolution. Mutational analyses revealed that C(86) was essential for BaMV replication, and that replacement of C(64) with U reduced replication efficiency. The non-interfering satBaMV interfered with BaMV replication with the BaMV-C64U mutant as helper. These findings suggest that two cytosines at the equivalent positions in the AHSLs of BaMV and satBaMV play a crucial role in replication competence. The downregulation level, which is dependent upon the molar ratio of interfering satBaMV to BaMV, implies that there is competition for limited replication machinery.

Phosphorylation of bamboo mosaic virus satellite RNA (satBaMV)-encoded protein P20 downregulates the formation of satBaMV-P20 ribonucleoprotein complex.

Bamboo mosaic virus (BaMV) satellite RNA (satBaMV) depends on BaMV for its replication and encapsidation. SatBaMV-encoded P20 protein is an RNA-binding protein that facilitates satBaMV systemic movement in co-infected plants. Here, we examined phosphorylation of P20 and its regulatory functions. Recombinant P20 (rP20) was phosphorylated by host cellular kinase(s) in vitro, and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and mutational analyses revealed Ser-11 as the phosphorylation site. The phosphor-mimic rP20 protein interactions with satBaMV-translated mutant P20 were affected. In overlay assay, the Asp mutation at S11 (S11D) completely abolished the self-interaction of rP20 and significantly inhibited the interaction with both the WT and S11A rP20. In chemical cross-linking assays, S11D failed to oligomerize. Electrophoretic mobility shift assay and subsequent Hill transformation analysis revealed a low affinity of the phospho-mimicking rP20 for satBaMV RNA. Substantial modulation of satBaMV RNA conformation upon interaction with nonphospho-mimic rP20 in circular dichroism analysis indicated formation of stable satBaMV ribonucleoprotein complexes. The dissimilar satBaMV translation regulation of the nonphospho- and phospho-mimic rP20 suggests that phosphorylation of P20 in the ribonucleoprotein complex converts the translation-incompetent satBaMV RNA to messenger RNA. The phospho-deficient or phospho-mimicking P20 mutant of satBaMV delayed the systemic spread of satBaMV in co-infected Nicotiana benthamiana with BaMV. Thus, satBaMV likely regulates the formation of satBaMV RNP complex during co-infection in planta.

Structural and sequence integrity are essential for the replication of the viroid-like satellite RNA of lucerne transient streak virus.

Lucerne transient streak virus (LTSV, genus Sobemovirus) supports the replication and encapsidation of a 322 nt untranslated small-circular RNA (scLTSV). Since scLTSV does not code for any proteins or share sequence similarity with its helper virus (LTSV), it is presumed that it uses structural and sequence motifs to signal the helper virus (and host) machinery for its replication and encapsidation. Insertion and deletion mutations were introduced at various locations within the scLTSV molecule. Our results showed that most mutants were not infectious, with only two exceptions, a (-1) nucleotide deletion and a 9 nt, palindromic insertion mutant which preserved the overall rod-like structure of the scLTSV. Sequence analysis of cDNA clones revealed that the palindromic sequence was replicated for up to 12 days of infection, before the sequence reverted back to its wild-type form. Our results indicate that scLTSV has an optimal sequence and secondary structure for replication, movement and/or packaging within the LTSV helper virus.

Properties of a novel satellite RNA associated with tomato bushy stunt virus infections.

The biological and molecular properties of a novel satellite RNA (satRNA L) associated with tomato bushy stunt virus (TBSV) are described. satRNA L consisted of a linear single-stranded RNA of 615 nt, lacked significant open reading frames (ORFs) and had no sequence identity with the helper genome other than in the 5'-proximal 7 nt and in a central region that is also conserved in all tombusvirus genomic, defective interfering and satellite RNAs. Secondary-structure analysis showed the presence of high-order domains similar to those described for other tombusvirus RNAs. Shorter-than-unit-length molecules were shown not to be related to a silencing mechanism. satRNA L did not modify the symptoms induced by TBSV under any of the temperature conditions tested. A full-length cDNA clone was constructed and used in co-inoculations with transcripts of carnation Italian ringspot virus (CIRV) and cymbidium ringspot virus (CymRSV). CIRV, but not CymRSV, supported the replication of satRNA L. Using CIRV-CymRSV hybrid infectious clones, two regions were identified as possible determinants of the different ability to support satRNA L replication. The first region was in the 5'-untranslated region, which folds differently in CymRSV in comparison with CIRV and TBSV; the second region was in the ORF1-encoded protein where a more efficient satRNA L-binding domain is suggested to be present in CIRV.

Mimicry of molecular pretenders: the terminal structures of satellites associated with plant RNA viruses.

Satellite RNAs (satRNAs) and satellite viruses depend on the replicase complexes provided by their cognate helper viruses and host plants for replication, pretending that they are part of the viral genomes. Although satRNAs and satellite viruses do not share significant nucleotide sequence similarity with the helper viruses, the essential cis-acting elements recognized by the replicase complexes must reside on their genomes, acting as the mimicry for the molecular pretenders. By understanding how this molecular mimicry deceives the helper viruses into supporting the satellites, a significant amount of knowledge of the basic requirements and mechanisms for replication of viruses and satellites has been obtained. Here we review the recent advances in understanding the effects of the cis elements at the termini of satRNAs and satellite viruses on their accumulation. Several well-characterized satellite/helper virus systems, representing the non-coding short satRNAs, mRNA-type long satRNAs, circular satRNAs and satellite viruses, are compared and contrasted. It is concluded that different satellites may adopt different strategies to exploit the replication/transcription/translation machineries of their helper viruses, and different mimicries may be implemented by the same molecular pretender for different biological functions.

Structural and functional analyses of the 3' untranslated region of Bamboo mosaic virus satellite RNA.

The 3'-untranslated region (UTR) of RNA genomes of viruses and satellite RNAs plays essential roles in viral replication and transcription. The structural features of the 3'-UTR of the satellite RNA of Bamboo mosaic virus (satBaMV) involved in its replication were analyzed in this study. By the use of enzymatic probing, the secondary structure of satBaMV 3'-UTR was confirmed to comprise two small stem-loops (SLA and SLB), one large stem-loop (SLC), and a poly(A) tail of mainly 75-200 adenylate residues, which is similar to those on the genomic RNA of the helper virus, BaMV. Five sets of mutants of satBaMV were constructed to analyze the biological functions of the structural elements of the 3'-UTR. The data revealed that both the polyadenylation signal and poly(A) tail are required for satBaMV RNA replication. The structural conservation of SLA, SLB, and SLC is also important for efficient satBaMV accumulation, whereas the nucleotides in these regions may also possess sequence-specific functions. In contrast to the requirement for the accumulation of BaMV genomic RNA, mutations in the conserved hexanucleotide (ACCUAA) in the loop region of SLC had limited effect on the accumulation of satBaMV RNA. In addition, replacing the 5'-, 3'-UTR, or both regions of satBaMV by those of BaMV greatly decreased the accumulation of satBaMV RNA. Taken together, these data indicate that satBaMV might have adopted a 3'-UTR structure similar to that of BaMV but may have evolved distinct features for its efficient replication.

Nucleotide sequence of a satellite RNA associated with carrot motley dwarf in parsley and carrot.

Carrot motley dwarf (CMD) is known to result from a mixed infection by two viruses, the polerovirus Carrot red leaf virus and one of the umbraviruses Carrot mottle mimic virus or Carrot mottle virus. Some umbraviruses have been shown to be associated with small satellite (sat) RNAs, but none have been reported for the latter two. A CMD-affected parsley plant was used for sap transmission to test plants, that were used for dsRNA isolation. The presence of a 0.8-kbp dsRNA indicated the occurrence of a hitherto unrecognized satRNA associated with CMD. The satRNAs of the CMD isolate from parsley and an isolate from carrot have been sequenced and showed 94% sequence identity. Nucleotide sequences and putative translation products had no significant similarities to GenBank entries. To our knowledge, this is the first report of satRNAs associated with CMD.

Structural domains within the 3' untranslated region of Turnip crinkle virus.

The genomes of positive-strand RNA viruses undergo conformational shifts that complicate efforts to equate structures with function. We have initiated a detailed analysis of secondary and tertiary elements within the 3' end of Turnip crinkle virus (TCV) that are required for viral accumulation in vivo. MPGAfold, a massively parallel genetic algorithm, suggested the presence of five hairpins (H4a, H4b, and previously identified hairpins H4, H5, and Pr) and one H-type pseudoknot (Psi(3)) within the 3'-terminal 194 nucleotides (nt). In vivo compensatory mutagenesis analyses confirmed the existence of H4a, H4b, Psi(3) and a second pseudoknot (Psi(2)) previously identified in a TCV satellite RNA. In-line structure probing of the 194-nt fragment supported the coexistence of H4, H4a, H4b, Psi(3) and a pseudoknot that connects H5 and the 3' end (Psi(1)). Stepwise replacements of TCV elements with the comparable elements from Cardamine chlorotic fleck virus indicated that the complete 142-nt 3' end, and subsets containing Psi(3), H4a, and H4b or Psi(3), H4a, H4b, H5, and Psi(2), form functional domains for virus accumulation in vivo. A new 3-D molecular modeling protocol (RNA2D3D) predicted that H4a, H4b, H5, Psi(3), and Psi(2) are capable of simultaneous existence and bears some resemblance to a tRNA. The related Japanese iris necrotic ring virus does not have comparable domains. These results provide a framework for determining how interconnected elements participate in processes that require 3' untranslated region sequences such as translation and replication.

Environment determines fidelity for an RNA virus replicase.

The rate of insertion and deletion mutations of the replicase of Cucumber mosaic virus (CMV) was determined in planta by using a parasitic satellite RNA (satRNA) as a reporter. We found that the CMV replicase had different fidelity in different environments, with important implications in viral disease evolution. Insertions were very rare events, irrespective of the region of the satRNA genome assayed and independent of the hosts tested. On the other hand, deletion events were more frequent but were restricted to a highly structured region of the reporter. Deletion mutation rates were different for the two hosts tested, although the mutation distribution was not influenced by the hosts. Moreover, hot spots with high mutation rates were identified on the satRNA genome.

Downregulation of Bamboo mosaic virus replication requires the 5' apical hairpin stem loop structure and sequence of satellite RNA.

Satellite RNAs associated with Bamboo mosaic virus (satBaMV) exhibit different phenotypes. Some isolates could reduce the accumulation of BaMV RNA and attenuate the BaMV-induced symptoms in co-inoculated plants. The determinants of the downregulation of BaMV replication were mapped in the 5' hypervariable region of satBaMV, which folds into a conserved apical hairpin stem loop (AHSL) structure comprising an apical loop and two internal loops, as evidenced by enzymatic probing. We also demonstrated that the integrity of the AHSL structure of interfering satBaMV was essential for the interference of BaMV accumulation. Concurrent analyses of natural satBaMV isolates revealed that all of the interfering isolates contained the same structures and sequences in the internal loops. Further, refined analyses indicated that, besides the AHSL structure, specific nucleotides in the internal loops play a crucial role in the downregulation, which implies that they may be required for the interaction of viral/cellular factors in this process.

Purification of plant viral and satellite double-stranded RNAs on DEAE monoliths.

Replicative double-stranded RNA (dsRNA) is useful in preliminary identification of Cucumber mosaic virus and its satellite RNA (satRNA). This plant pathogen complex yields sufficient quantity of the replicative RNA form that can be isolated by chromatography on chemically unmodified graded cellulose powder (CF-11). In this work, much faster and more efficient procedure using DEAE monoliths was developed in which dsRNA was separated from other species in total nucleic acids extract originating from the infected plant tissue. The developed chromatographic method revealed the pathogens' presence in only 15 min, avoiding nucleic acid precipitation and electrophoretic analysis.

A pseudoknot in a preactive form of a viral RNA is part of a structural switch activating minus-strand synthesis.

RNA can adopt different conformations in response to changes in the metabolic status of cells, which can regulate processes such as transcription, translation, and RNA cleavage. We previously proposed that an RNA conformational switch in an untranslated satellite RNA (satC) of Turnip crinkle virus (TCV) regulates initiation of minus-strand synthesis (G. Zhang, J. Zhang, A. T. George, T. Baumstark, and A. E. Simon, RNA 12:147-162, 2006). This model was based on the lack of phylogenetically inferred hairpins or a known pseudoknot in the "preactive" structure assumed by satC transcripts in vitro. We now provide evidence that a second pseudoknot (Psi(2)), whose disruption reduces satC accumulation in vivo and enhances transcription by the TCV RNA-dependent RNA polymerase in vitro, stabilizes the preactive satC structure. Alteration of either Psi(2) partner caused nearly identical structural changes, including single-stranded-specific cleavages in the pseudoknot sequences and strong cleavages in a distal element previously proposed to mediate the conformational switch. These results indicate that the preactive structure identified in vitro has biological relevance in vivo and support a requirement for this alternative structure and a conformational switch in high-level accumulation of satC in vivo.