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1.
Front Plant Sci ; 8: 766, 2017.
Article in English | MEDLINE | ID: mdl-28539933

ABSTRACT

Plant reoviruses are able to multiply in gramineae plants and delphacid vectors encountering different defense strategies with unique features. This study aims to comparatively assess alterations of small RNA (sRNA) populations in both hosts upon virus infection. For this purpose, we characterized the sRNA profiles of wheat and planthopper vectors infected by Mal de Río Cuarto virus (MRCV, Fijivirus, Reoviridae) and quantified virus genome segments by quantitative reverse transcription PCR We provide evidence that plant and insect silencing machineries differentially recognize the viral genome, thus giving rise to distinct profiles of virus-derived small interfering RNAs (vsiRNAs). In plants, most of the virus genome segments were targeted preferentially within their upstream sequences and vsiRNAs mapped with higher density to the smaller genome segments than to the medium or larger ones. This tendency, however, was not observed in insects. In both hosts, vsiRNAs were equally derived from sense and antisense RNA strands and the differences in vsiRNAs accumulation did not correlate with mRNAs accumulation. We also established that the piwi-interacting RNA (piRNA) pathway was active in the delphacid vector but, contrary to what is observed in virus-infected mosquitoes, virus-specific piRNAs were not detected. This work contributes to the understanding of the silencing response in insect and plant hosts.

2.
Virology ; 430(2): 81-9, 2012 Sep 01.
Article in English | MEDLINE | ID: mdl-22608534

ABSTRACT

The in vivo subcellular localization of Mal de Río Cuarto virus (MRCV, Fijivirus, Reoviridae) non-structural proteins fused to GFP was analyzed by confocal microscopy. P5-1 showed a cytoplasmic vesicular-like distribution that was lost upon deleting its PDZ binding TKF motif, suggesting that P5-1 interacts with cellular PDZ proteins. P5-2 located at the nucleus and its nuclear import was affected by the deletion of its basic C-termini. P7-1 and P7-2 also entered the nucleus and therefore, along with P5-2, could function as regulators of host gene expression. P6 located in the cytoplasm and in perinuclear cloud-like inclusions, was driven to P9-1 viroplasm-like structures and co-localized with P7-2, P10 and α-tubulin, suggesting its involvement in viroplasm formation and viral intracellular movement. Finally, P9-2 was N-glycosylated and located at the plasma membrane in association with filopodia-like protrusions containing actin, suggesting a possible role in virus cell-to-cell movement and spread.


Subject(s)
Reoviridae , Spodoptera/virology , Viral Nonstructural Proteins/analysis , Viral Nonstructural Proteins/physiology , Animals , Cell Line , Cell Membrane/chemistry , Cell Membrane/virology , Cell Nucleus/chemistry , Cell Nucleus/virology , Cytoplasm/chemistry , Cytoplasm/virology , Cytoskeleton/virology , Genome, Viral , Green Fluorescent Proteins/genetics , Microscopy, Confocal , Recombinant Fusion Proteins/analysis , Reoviridae/genetics , Reoviridae/physiology , Spodoptera/ultrastructure , Subcellular Fractions/chemistry , Subcellular Fractions/virology , Viral Nonstructural Proteins/genetics
3.
Virol J ; 8: 308, 2011 Jun 16.
Article in English | MEDLINE | ID: mdl-21679431

ABSTRACT

BACKGROUND: Planthoppers not only severely affect crops by causing mechanical damage when feeding but are also vectors of several plant virus species. The analysis of gene expression in persistently infected planthoppers might unveil the molecular basis of viral transmission. Quantitative real-time RT-PCR (RT-qPCR) is currently the most accurate and sensitive method used for quantitative gene expression analysis. In order to normalize the resulting quantitative data, reference genes with constant expression during the experimental procedures are needed. RESULTS: Partial sequences of the commonly used reference genes actin (ACT), α1-tubulin (TUB), glyceraldehyde 3-phosphate dehydrogenase (GAPDH), elongation factor 1 alpha (EF1A), ribosomal protein S18 (RPS18) and polyubiquitin C (UBI) from Delphacodes kuscheli, a planthopper capable of persistently transmitting the plant fijivirus Mal de Río Cuarto virus (MRCV), were isolated for the first time. Specific RT-qPCR primers were designed and the expression stability of these genes was assayed in MRCV-infective and naïve planthoppers using geNorm, Normfinder and BestKeeper tools. The overall analysis showed that UBI, followed by 18S and ACT, are the most suitable genes as internal controls for quantitative gene expression studies in MRCV-infective planthoppers, while TUB and EF1A are the most variable ones. Moreover, EF1A was upregulated by MRCV infection. CONCLUSIONS: A RT-qPCR platform for gene expression analysis in the MRCV-infected planthopper vector Delphacodes kuscheli was developed. Our work is the first report on reference gene selection in virus-infected insects, and might serve as a precedent for future gene expression studies on MRCV and other virus-planthopper pathosystems.


Subject(s)
Gene Expression Profiling/methods , Gene Expression Profiling/standards , Hemiptera/virology , Host-Pathogen Interactions , Reoviridae/isolation & purification , Reverse Transcriptase Polymerase Chain Reaction/methods , Reverse Transcriptase Polymerase Chain Reaction/standards , Animals , Carrier State/virology , Insect Proteins/genetics , Molecular Sequence Data , Plant Viruses/isolation & purification , Sequence Analysis, DNA
4.
Virus Res ; 152(1-2): 96-103, 2010 Sep.
Article in English | MEDLINE | ID: mdl-20600394

ABSTRACT

Mal de Río Cuarto virus (MRCV) is a plant virus of the genus Fijivirus within the family Reoviridae that infects several monocotyledonous species and is transmitted by planthoppers in a persistent and propagative manner. Other members of the family replicate in viral inclusion bodies (VIBs) termed viroplasms that are formed in the cytoplasm of infected plant and insect cells. In this study, the protein coded by the first ORF of MRCV segment S9 (P9-1) was shown to establish cytoplasmic inclusion bodies resembling viroplasms after transfection of Spodoptera frugiperda insect cells. In accordance, MRCV P9-1 self-associates giving rise to high molecular weight complexes when expressed in bacteria. Strong self-interaction was also evidenced by yeast two-hybrid assays. Furthermore, biochemical characterization showed that MRCV P9-1 bound single stranded RNA and had ATPase activity. Finally, the MRCV P9-1 region required for the formation of VIB-like structures was mapped to the protein carboxy-terminal half. This extensive functional and biochemical characterization of MRCV P9-1 revealed further similarities between plant and animal reovirus viroplasm proteins.


Subject(s)
Inclusion Bodies, Viral/metabolism , Reoviridae/metabolism , Spodoptera/virology , Viral Proteins/metabolism , Amino Acid Motifs , Animals , Inclusion Bodies, Viral/chemistry , Inclusion Bodies, Viral/genetics , Open Reading Frames , Reoviridae/chemistry , Reoviridae/genetics , Viral Proteins/chemistry , Viral Proteins/genetics
5.
BMC Plant Biol ; 9: 152, 2009 Dec 30.
Article in English | MEDLINE | ID: mdl-20042107

ABSTRACT

BACKGROUND: Micro RNAs (miRs) constitute a large group of endogenous small RNAs that have crucial roles in many important plant functions. Virus infection and transgenic expression of viral proteins alter accumulation and activity of miRs and so far, most of the published evidence involves post-transcriptional regulations. RESULTS: Using transgenic plants expressing a reporter gene under the promoter region of a characterized miR (P-miR164a), we monitored the reporter gene expression in different tissues and during Arabidopsis development. Strong expression was detected in both vascular tissues and hydathodes. P-miR164a activity was developmentally regulated in plants with a maximum expression at stages 1.12 to 5.1 (according to Boyes, 2001) along the transition from vegetative to reproductive growth. Upon quantification of P-miR164a-derived GUS activity after Tobacco mosaic virus Cg or Oilseed rape mosaic virus (ORMV) infection and after hormone treatments, we demonstrated that ORMV and gibberellic acid elevated P-miR164a activity. Accordingly, total mature miR164, precursor of miR164a and CUC1 mRNA (a miR164 target) levels increased after virus infection and interestingly the most severe virus (ORMV) produced the strongest promoter induction. CONCLUSION: This work shows for the first time that the alteration of miR pathways produced by viral infections possesses a transcriptional component. In addition, the degree of miR alteration correlates with virus severity since a more severe virus produces a stronger P-miR164a induction.


Subject(s)
Arabidopsis/genetics , Arabidopsis/virology , MicroRNAs/metabolism , Mosaic Viruses/physiology , Promoter Regions, Genetic , Arabidopsis/metabolism , Cloning, Molecular , Computational Biology , Gene Expression Regulation, Developmental , Gene Expression Regulation, Plant , Genes, Reporter , MicroRNAs/genetics , Plant Diseases/genetics , Plant Diseases/virology , Plant Growth Regulators/pharmacology , Plants, Genetically Modified/genetics , Plants, Genetically Modified/metabolism , Plants, Genetically Modified/virology , RNA, Plant/genetics
6.
Electron. j. biotechnol ; 10(2): 178-190, Apr. 15, 2007. ilus, graf
Article in English | LILACS | ID: lil-499183

ABSTRACT

Gene silencing, also called RNA interference (RNAi) is a specific mechanism of RNA degradation involved in gene regulation, development and defense in eukaryotic organisms. It became an important subject in the teaching programs of molecular biology, genetics and biotechnology courses in the last years. The aim of this work is to provide simple and inexpensive assays to understand and teach gene silencing using plants as model systems. The use of transient and permanent transgenic plants for expressing reporter genes, like those derived from jellyfish green fluorescent protein (gfp) encoding gene, provides a nice, colorful and conclusive image of gene silencing. Three experimental approaches to evidence RNA silencing are depicted. In the first approach gene silencing is demonstrated after transient expression of reporter genes in non-transgenic plants. In the second, silencing is triggered against a reporter gene stably integrated into a transgenic plant. The third approach involves the triggering of RNA silencing against endogenous genes using viral vectors. In addition we illustrate systemic gene silencing showing how the silencing signal is spread over a plant and finally it is also demonstrated the suppression of gene silencing. The first group of experiments is recommended to be tough on undergraduate courses, the following two sections are recommended for graduate courses. Hopefully, it will help students to understand this important phenomenon and to unravel the importance of gene silencing as a key gene regulation mechanism and as a molecular and biotechnological tool.


Subject(s)
RNA, Plant/genetics , Gene Silencing , RNA Interference , Teaching , Biotechnology/education , Green Fluorescent Proteins , Models, Genetic , Plants, Genetically Modified/genetics , Viral Interference
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