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1.
Arch Virol ; 162(2): 501-504, 2017 Feb.
Article in English | MEDLINE | ID: mdl-27738845

ABSTRACT

An isometric virus was isolated from a cultivated Adonis plant (A. ramosa). The purified virus particle is 28 nm in diameter and is composed of a single coat protein and a single RNA genome of 3,991 nucleotides. Sequence analysis showed that the virus is closely related to carnation mottle virus. The virus was used to mechanically infect healthy A. ramosa plants, resulting in mosaic and leaf curl symptoms; however, attempts to inoculate carnation plants did not result in infection. We propose the virus as a new carmovirus and have named it adonis mosaic virus (AdMV).


Subject(s)
Adonis/virology , Carmovirus/genetics , Genome, Viral , Mosaic Viruses/genetics , Phylogeny , Capsid Proteins/genetics , Capsid Proteins/metabolism , Carmovirus/classification , Carmovirus/isolation & purification , Carmovirus/ultrastructure , Gene Expression , Mosaic Viruses/classification , Mosaic Viruses/isolation & purification , Plant Diseases/virology , Virion/genetics , Virion/ultrastructure
2.
J Virol Methods ; 189(2): 250-7, 2013 May.
Article in English | MEDLINE | ID: mdl-23466632

ABSTRACT

Enteric viruses are etiological agents of waterborne disease that may be detected using molecular techniques such as PCR. However, processing water samples in preparation for PCR typically involves concentration of samples and extraction of nucleic acids, steps that have low and variable recovery efficiencies. This study evaluated a plant virus, turnip crinkle virus (TCV), for its ability to serve as a process control for human enteroviruses during concentration and extraction procedures. Enteroviruses and TCV have similar sizes and morphologies, and both contain single stranded, positive-sense RNA genomes. Results from the study demonstrate that the tested viruses experience similar losses during sample processing. Virus recoveries averaged 0.03% for EV and 0.02% for TCV from DI water, and 0.004% for EV and 0.009% for TCV from a creek sample. Surface water and wastewater samples from around the U.S. were evaluated for the presence of TCV to ensure the virus is not present in environmental samples. All were negative. With similar recovery efficiencies to EV, TCV may be a suitable process control for enteroviruses in environmental water samples in the U.S. Use of process controls as proposed in this study would allow better detection and quantitation methods to be employed in water quality monitoring.


Subject(s)
Carmovirus/isolation & purification , Enterovirus/isolation & purification , Specimen Handling/methods , Virology/methods , Water Microbiology/standards , Biomarkers , Sensitivity and Specificity , Specimen Handling/standards , Staining and Labeling/methods , United States , Virology/standards
3.
Article in English | MEDLINE | ID: mdl-19478438

ABSTRACT

Hibiscus chlorotic ringspot virus (HCRSV) is a positive-sense monopartite single-stranded RNA virus that belongs to the Carmovirus genus of the Tombusviridae family, which includes carnation mottle virus (CarMV). The HCRSV virion has a 30 nm diameter icosahedral capsid with T = 3 quasi-symmetry containing 180 copies of a 38 kDa coat protein (CP) and encapsidates a full-length 3.9 kb genomic RNA. Authentic virus was harvested from infected host kenaf leaves and was purified by saturated ammonium sulfate precipitation, sucrose density-gradient centrifugation and anion-exchange chromatography. Virus crystals were grown in multiple conditions; one of the crystals diffracted to 3.2 A resolution and allowed the collection of a partial data set. The crystal belonged to space group R32, with unit-cell parameters a = b = 336.4, c = 798.5 A. Packing considerations and rotation-function analysis determined that there were three particles per unit cell, all of which have the same orientation and fixed positions, and resulted in tenfold noncrystallography symmetry for real-space averaging. The crystals used for the structure determination of southern bean mosaic virus (SBMV) have nearly identical characteristics. Together, these findings will greatly aid the high-resolution structure determination of HCRSV.


Subject(s)
Carmovirus/chemistry , Hibiscus/virology , Amino Acid Sequence , Capsid/chemistry , Capsid/ultrastructure , Capsid Proteins/chemistry , Capsid Proteins/ultrastructure , Carmovirus/isolation & purification , Carmovirus/ultrastructure , Crystallization , Data Collection , Dimerization , Light , Molecular Sequence Data , Molecular Weight , Particle Size , Plant Leaves/virology , Protein Folding , Protein Structure, Secondary , Protein Structure, Tertiary , RNA, Viral/chemistry , RNA, Viral/ultrastructure , Rotation , Scattering, Radiation , Sequence Homology, Amino Acid , Statistics as Topic , Temperature , Virion/chemistry , Virion/ultrastructure , X-Ray Diffraction
4.
Commun Agric Appl Biol Sci ; 74(3): 861-5, 2009.
Article in English | MEDLINE | ID: mdl-20222573

ABSTRACT

One of the most important cut-flower crops grown worldwide on commercial scale is Carnation (Dianthus caryophyllus L.). It's the main production of Mahallat where is one of the most important ornamental plants production centers of Iran. Infection of carnation with pathogens Like viral agents causes economic losses in carnation cut-flower crop. One of the viral agents of this flower is Carnation mottle virus (CarMV) which is the type member of genus Carmovirus and belongs to the Tombusviridae family. It is naturally transmitted by grafting and contacting between plants. Although its infection lead to mild symptims, it weakens the plant to infection by other pathogens. The carnation greenhouses of Mahallat were visited during 2008 January to April and 100 samples with mild mosaic symptom were collected and tested by DAS-ELISA using CarMV specific polyclonal antibody. The results showed that 75% of samples wrere infected with this virus. Mechanical inocubation of Chenopodium quinoa, C. amaranticolor and Spinacea oleracea with extracted crude sap of CarMV infected carnation Leaves in phosphate buffer (pH, 7) resulted in appearance of chlorotic and necrotic local lesions on inoculated leaves 4-7 days after incubation. The virus was partially purified using C. amaranticolor locally symptomatic leaves. Total soluble proteins were extracted from healthy and CarMV infected C. amaranticolor plants and beside partially purified preparation electrophoresed through 15% poly acrylamide get according to SDS-PAGE standard procedure. Protein bands were electroblotted onto nitrocelluse membrane and incubated with CarMV polyclonal during western immunoblot analysis according to standard method. The result revealed a distinc protein band with Mr of 35.5 kDa in total protein preparation of infected plant and viral partial pure preparation, without any reaction in those of healthy plant. RT-PCR carried out using total RNA extracted from infected plant by Rneasy Plant Mini Kit (Qiagen)and a pair of primers, CPu, CPd, corresponding to the flanking region of the virus CP resulted in amplification of a DNA fragment in expected size around 1 kbp.


Subject(s)
Carmovirus/isolation & purification , Carmovirus/pathogenicity , Crops, Agricultural/virology , Flowers/virology , Plant Diseases/virology , Carmovirus/classification , Geography , Iran , Plant Leaves/virology
6.
Virology ; 321(2): 349-58, 2004 Apr 10.
Article in English | MEDLINE | ID: mdl-15051394

ABSTRACT

Cowpea mottle virus (CPMoV) is a T = 3 virus that belongs to Carmovirus genus of the Tombusviridae family. Here, we report the crystal structure of CPMoV determined to a resolution of 7.0 angstroms. The structures and sequences of three Carmoviruses, CPMoV, Turnip crinkle virus (TCV), and Carnation mottle virus (CarMV) have been compared to TBSV from the Tombusvirus genus. CPMoV, TCV, and CarMV all have a deletion in betaC strand in the S domain relative to TBSV that may be distinctive to the genus. Although CPMoV has an elongated C-terminus like TBSV, it does not interact with the icosahedrally related P domain as observed in TBSV. In CPMoV, the termini of A and B interact with the icosahedrally related shell domains of A and C, respectively, to form a chain of interactions around the 5-fold axes. The C subunit terminus does not, however, interact with the B subunit because of quasi-equivalent differences in the P domain orientations.


Subject(s)
Bromovirus/chemistry , Carmovirus/chemistry , Amino Acid Sequence , Bromovirus/classification , Bromovirus/genetics , Capsid Proteins/chemistry , Capsid Proteins/genetics , Carmovirus/isolation & purification , Crystallography , Models, Molecular , Molecular Sequence Data , Sequence Alignment , X-Ray Diffraction
7.
J Virol Methods ; 113(2): 87-93, 2003 Nov.
Article in English | MEDLINE | ID: mdl-14553894

ABSTRACT

Melon necrotic spot virus (MNSV) is a water and soil-borne pathogen affecting species of the Cucurbitaceae family both in hydroponic and soil crops. Molecular methods for detecting MNSV in water samples, nutrient solutions and melon plants were developed. For this purpose, water samples from a water source pool of a hydroponic culture or from the recirculating nutrient solution were concentrated by ultracentrifugation or PEG precipitation followed by RT-PCR analysis. Both concentration methods were suitable to allow the detection of MNSV and represent, as far as we know, the first time that this virus has been detected in water samples. A non-isotopic riboprobe specific for MNSV was obtained and used to detect the virus in plant tissue. Different parts of mechanically infected plants were examined including the roots, stems, inoculated cotyledons and young leaves. Excluding the inoculated cotyledons, the tissues showing the highest accumulation levels of the virus were the roots. The potential inclusion of such tools in management programs is discussed.


Subject(s)
Carmovirus/genetics , Carmovirus/isolation & purification , Cucumis/virology , Plant Diseases/virology , Water Microbiology , Antibodies, Viral/analysis , Carmovirus/immunology , DNA, Complementary/genetics , Immunoblotting , Nucleic Acid Hybridization , Plant Structures/virology , RNA, Viral/analysis , Reverse Transcriptase Polymerase Chain Reaction
8.
J Gen Virol ; 84(Pt 3): 745-749, 2003 Mar.
Article in English | MEDLINE | ID: mdl-12604827

ABSTRACT

Time-course and in situ hybridization analyses were used to study the spatio-temporal distribution of Carnation mottle virus (CarMV) in Chenopodium quinoa plants. Genomic and subgenomic RNAs of plus polarity accumulated linearly with time, whereas the corresponding minus strands reached a peak during infection in inoculated leaves. Analyses of serial tissue sections showed that plus polarity strands were localized throughout the infection area, whereas minus strands were localized at the borders of the chlorotic lesions. The accumulation kinetics of the coat protein (CP) and the p7 movement protein (MP) as well as their subcellular localization were also studied. Unlike most MPs, CarMV p7 showed a non-transient expression and a mainly cytosolic location. However, as infection progressed the presence of p7 in the cell wall fraction increased significantly. These results are discussed on the basis of a recent model proposed for the mechanism of cell-to-cell movement operating in the genus Carmovirus.


Subject(s)
Carmovirus/isolation & purification , Chenopodium/virology , Blotting, Western , Capsid Proteins/analysis , Carmovirus/chemistry , Carmovirus/genetics , Kinetics , RNA, Viral/analysis , RNA-Binding Proteins/analysis , Viral Proteins/analysis
9.
Arch Virol ; 145(3): 651-7, 2000.
Article in English | MEDLINE | ID: mdl-10795530

ABSTRACT

The genome of Japanese iris necrotic ring virus (JINRV) consists of a positive-sense ssRNA of 4014 nucleotides with six major open reading frames (ORFs). A 5'-non-coding region of 31 nucleotides precedes the first initiation codon. Like Carnation mottle virus (CarMV), the 5'-proximal three ORFs encode a 26 kDa protein (p26) and two readthrough proteins, i.e. an 85 kDa putative RNA replicase (p85) and a 99 kDa protein (p99). The central ORF encodes a small 8 kDa protein (p8). The 3'-proximal ORF encodes a 38 kDa capsid protein (p38). Another ORF encoding a 12 kDa protein (p12) overlaps the p99 ORF.JINRV RNA treated with bacterial alkaline phosphatase and tobacco acid pyrophosphatase could not be ligated to an oligoribonucleotide using T4 RNA ligase, indicating that the 5' end of the viral RNA is uncapped. The 3' end is not polyadenylated. Comparison of the genomic organization and the predicted amino acid sequences with those of other viruses confirmed that JINRV should be classified as a member of the genus Carmovirus, family Tombusviridae.


Subject(s)
Carmovirus/classification , Carmovirus/genetics , Genome, Viral , Sequence Analysis, DNA , Capsid/genetics , Carmovirus/isolation & purification , DNA, Complementary/genetics , Molecular Sequence Data , Plant Diseases/virology , Plant Viruses/classification , Plant Viruses/genetics , Plant Viruses/isolation & purification , RNA, Viral/analysis , RNA, Viral/genetics , Reverse Transcriptase Polymerase Chain Reaction
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