Comparison of Diagnostic Techniques for Detecting Tomato Infectious Chlorosis Virus

Development of a RT-LAMP assay for real-time detection of criniviruses infecting tomato

Yellowing symptoms caused by tomato chlorosis virus (ToCV) and tomato infectious chlorosis virus (TICV), both assigned to the genus Crinivirus, resemble nutrient deficiencies. Therefore, early diagnosis of infections will prevent crop damage and the spread of the viruses. In this study, we established a rapid detection method for ToCV and TICV by reverse transcription-loop-mediated isothermal amplification (RT-LAMP). We first designed primer sets for RT-LAMP specific for ToCV and TICV. Next, by selecting the optimum primer set and determining the optimum conditions for the RT-LAMP reaction, each virus was detected within 50 min by piercing the diseased area of a tomato leaf with a toothpick, immersing the toothpick in the reaction solution, and conducting the RT-LAMP reaction. To verify the accuracy of the procedure, 61 tomato leaf samples showing disease symptoms were collected from five regions of Indonesia, and the RT-LAMP results for the samples were identical to those obtained with the commonly used reverse transcription-polymerase chain reaction.

A New Perspective on the Co-Transmission of Plant Pathogens by Hemipterans

Co-infection of plants by pathogens is common in nature, and the interaction of the pathogens can affect the infection outcome. There are diverse ways in which viruses and bacteria are transmitted from infected to healthy plants, but insects are common vectors. The present review aims to highlight key findings of studies evaluating the co-transmission of plant pathogens by insects and identify challenges encountered in these studies. In this review, we evaluated whether similar pathogens might compete during co-transmission; whether the changes in the pathogen titer in the host, in particular associated with the co-infection, could influence its transmission; and finally, we discussed the pros and cons of the different approaches used to study co-transmission. At the end of the review, we highlighted areas of study that need to be addressed. This review shows that despite the recent development of techniques and methods to study the interactions between pathogens and their insect vectors, there are still gaps in the knowledge of pathogen transmission. Additional laboratory and field studies using different pathosystems will help elucidate the role of host co-infection and pathogen co-transmission in the ecology and evolution of infectious diseases.

Viruses in artichoke

Most of the 25 viruses found in globe artichoke (Cynara scolymus L.) and cardoon (Cynara cardunculus L.) were recorded from Europe and the Mediterranean basin, where they decrease both the productivity and the quality of the crop. Although, sometimes, these viruses are agents of diseases of different severity, most often their infections are symptomless. These conditions have contributed to spread virus-infected material since farmers multiply traditional artichoke types vegetatively with no effective selection of virus-free plants. This review reports the main properties of these viruses and the techniques used for their detection and identification. ELISA kits are commercially available for most of the viruses addressed in this review but have seldom been used for their detection in artichoke. Conversely, nucleic acid-based diagnostic reagents, some of which are commercially available, have successfully been employed to identify some viruses in artichoke sap. Control measures mainly use virus-free stocks for new plantations. A combined procedure of meristem-tip culture and thermotherapy proved useful for producing virus-free regenerants of the reflowering southern Italian cultivar Brindisino, which kept earliness and typical heads shape.

Methods for detection and differentiation of existing and new crinivirus species through multiplex and degenerate primer RT-PCR

A method was developed for rapid identification and differentiation of both known and novel crinivirus species involving both multiplex and degenerate reverse transcription-polymerase chain reaction (RT-PCR). The multiplex method can discriminate among known criniviruses infecting vegetable and small fruit crops, and rapidly identify viruses associated with disease symptoms, as well as identification of mixed crinivirus infections. Four host groups for multiplex detection of criniviruses were selected based on the types of crops where specific criniviruses would be expected to occur. Each detection group contained three to four crop-specific primers designed to the same region of the gene encoding the highly conserved RNA-dependent RNA polymerase gene (RdRp) of criniviruses for rapid, single-reaction determination of which crinivirus(es) may be infecting a plant. Degenerate reverse primers used for RT and in PCR were designed to amplify all members of each host group, and were coupled with species-specific forward primers resulting in four separate single-reaction cocktails for detection of most criniviruses sequenced to date, whether present in single or mixed virus infections. Additional viruses can be added to multiplex detection by adjustment of primer concentration for balanced detection of target viruses. In order to identify unknown putative criniviruses or those for which sequence information is not yet available, a genus-wide, universal degenerate primer set was developed. These primers also targeted the crinivirus RdRp gene, and amplify a wide range of crinivirus sequences. Both detection systems can be used with most RNA extraction methods, and with RT-PCR reagents common in most laboratories.

Biological characterization and complete genomic sequence of Apium virus Y infecting celery

A celery isolate of Apium virus Y (ApVY-Ce) from diseased plants in a commercial field in California was characterized. The experimental host range of the virus included 13 plant species in the families Apiaceae, Chenopodiaceae and Solanaceae. Almost all infected plant species showed foliar chlorosis and distortion or severe stunting and systemic chlorosis. ApVY-Ce was transmitted to all 10 host species in the Apiaceae by green peach aphids. It reacted with the potyvirus group antibody and Celery mosaic virus (CeMV) antiserum. The complete genomic sequence of ApVY-Ce was determined to be 9917 nucleotides, excluding the 3' poly(A) tail, and it comprises a large open reading frame encoding a polyprotein of 3184 amino acid residues. Its genomic organization is typical of potyviruses, and contains conserved motifs found in the genus Potyvirus. Comparisons with available genomic sequences of other potyviruses indicate that ApVY-Ce shares 26.1-52.9% identities with species of the existing genera and unassigned viruses in the Potyviridae at the polyprotein sequence level. Extensive phylogenetic analysis based on the 3'-partial sequences confirms that ApVY-Ce is most closely related to CeMV and is a distinct species of the genus Potyvirus.

The complete nucleotide sequence of the RNA2 of the crinivirus tomato infectious chlorosis virus: isolates from North America and Europe are essentially identical

The complete nucleotide sequences of the RNA2 of two isolates of Tomato infectious chlorosis virus (TICV, genus Crinivirus, family Closteroviridae) from the United States and Spain, respectively, were determined. The sequences of both isolates were found to be nearly identical. TICV RNA2 consisted of 7,914 nucleotides in both isolates and contains eight open reading frames that encompass the Closteroviridae hallmark gene array represented by a heat shock protein 70 family homologue, a protein of 59 kDa, the major coat protein, and a divergent copy of the coat protein. Phylogenetic analysis suggested that TICV is most similar to Lettuce infectious yellows virus (LIYV), the type species of the genus Crinivirus.

Co-infection by two criniviruses alters accumulation of each virus in a host-specific manner and influences efficiency of virus transmission

Tomato chlorosis virus (ToCV), and Tomato infectious chlorosis virus (TICV), family Closteroviridae, genus Crinivirus, cause interveinal chlorosis, leaf brittleness, and limited necrotic flecking or bronzing on tomato leaves. Both viruses cause a decline in plant vigor and reduce fruit yield, and are emerging as serious production problems for field and greenhouse tomato growers in many parts of the world. The viruses have been found together in tomato, indicating that infection by one Crinivirus sp. does not prevent infection by a second. Transmission efficiency and virus persistence in the vector varies significantly among the four different whitefly vectors of ToCV; Bemisia tabaci biotypes A and B, Trialeurodes abutilonea, and T. vaporariorum. Only T. vaporariorum can transmit TICV. In order to elucidate the effects of co-infection on Crinivirus sp. accumulation and transmission efficiency, we established Physalis wrightii and Nicotiana benthamiana source plants, containing either TICV or ToCV alone or both viruses together. Vectors were allowed to feed separately on all virus sources, as well as virus-free plants, then were transferred to young plants of both host species. Plants were tested by quantitative reverse-transcription polymerase chain reaction, and results indicated host-specific differences in accumulation by TICV and ToCV and alteration of accumulation patterns during co-infection compared with single infection. In N. benthamiana, TICV titers increased during co-infection compared with levels in single infection, while ToCV titers decreased. However, in P. wrightii, titers of both TICV and ToCV decreased during mixed infection compared with single infection, although to different degrees. Vector transmission efficiency of both viruses corresponded with virus concentration in the host in both single and mixed infections. This illustrates that Crinivirus epidemiology is impacted not only by vector transmission specificity and incidence of hosts but also by interactions between viruses and efficiency of accumulation in host plants.

Multiplex Detection of Criniviruses Associated with Epidemics of a Yellowing Disease of Tomato in Greece

Since 1997, a yellowing disease has been observed in greenhouse tomato (Lycopersicon escu-lentum). By 2001, the disease was widespread, including open field tomato crops, and in most cases its incidence was 80 to 90% or even 100%. Epidemics in glasshouses were mainly associated with high populations of the whitefly Trialeurodes vaporariorum and Bemisia tabaci, the major whitefly pests in vegetable crops in Greece. The main leaf symptoms were severe yellowing, rolling, and brittleness. Samples from symptomatic plants were analyzed by polymerase chain reaction (PCR) and shown to be infected with Tomato infectious chlorosis virus (TICV) and Tomato chlorosis virus (ToCV) (family Closteroviridae, genus Crinivirus). TICV was found in 164 of 183 symptomatic samples, while ToCV was less representative (25/183). Sequence comparisons of the amplified 229-bp and 466-bp products revealed 99 and 100% identity with the reported sequences of TICV and ToCV, respectively. A reverse transcription (RT) multiplex PCR assay using a simple sample preparation procedure was developed to allow rapid, specific, and simultaneous detection of both ToCV and TICV sequences in two steps. The method involves a one-tube RT-PCR step in which the combination of primers amplifies part of the heat shock protein to homologue gene of both ToCV and TICV, followed by a multiplex nested PCR amplification. This is the first report of TICV and ToCV in Greece and, as far as we know, the first report of TICV in Europe.

Characterization of the beet yellow stunt virus coat protein gene

ABSTRACT The beet yellow stunt virus (BYSV) genome contains at least nine open reading frames (ORFs) that code for proteins ranging from 6 to 66 kDa. Based on amino acid sequence comparisons, the coat protein (CP) was previously identified as the product of ORF7. We expressed the product of ORF7 in bacteria and confirmed that ORF7 codes for the BYSV CP by immunoblotting. BYSV is a phloem-limited virus, and virus CP antigen of a quality sufficient for diagnostic antisera production has not been available. To produce BYSV antigen free of plant host contaminants, ORF7 was cloned into a pMAL bacterial expression vector. The resulting fusion protein was affinity-purified and used as an antigen to raise anti-BYSV CP antisera in rabbits and guinea pigs. Using these antisera, an indirect double-antibody sandwich (DAS) enzyme-linked immunosorbent assay (ELISA)-based diagnostic system was developed. This indirect DAS-ELISA format enabled reliable detection of BYSV in tissue extracts from virus-infected lettuce diluted up to 5,000 times. The diagnostic system developed may enable large-scale epidemiological studies of BYSV using simple serological techniques. The antisera raised had a titer exceeding 1 x 10(5) in immunoblots and easily detected the 23.7-kDa BYSV CP in virus-infected lettuce and sowthistle plants. In these two plant species, BYSV CP was detected as two closely migrating bands during electrophoresis, which may suggest posttranslational CP modifications. To further characterize the BYSV CP gene, the 5'-untranslated region (UTR) of the BYSV CP subgenomic RNA (sgRNA) was cloned and sequenced. The CP-encoding, approximately 1.9-kb sgRNA has an AT-rich, 66-nucleotide-long 5'-UTR colinear to the genomic sequence upstream of ORF7.

The GPRIME package: computer programs for identifying the best regions of aligned genes to target in nucleic acid hybridisation-based diagnostic tests, and their use with plant viruses

The GPRIME (Group PRIMEr design) programs examine aligned sets of gene sequences to discover homologous regions to be targeted in diagnostic tests. The core program moves a 'window' over the aligned sequences and calculates, at each window position, a 'redundancy value', namely the number of sequences that would represent all permutations of the variable sequence positions within that window. Regions with minimal redundancy values may then be targeted in diagnostic tests based on oligonucleotide hybridisation. The likely specificity of tests targeting such regions can be assessed by searching the international databases with those regions using FASTA. The GPRIME programs, which include programs for designing primers to distinguish between two sub-sets of a group of aligned sequences, can be obtained from http://life.anu.edu.au/software.html. We have used GPRIME to design redundant primers for RT-PCR tests to detect all potexviruses and tobamoviruses, and then used these, together with a previously reported pair of primers for the Potyviridae, to screen some Australian orchid collections. Two orchid viruses previously reported from Australia were found; cymbidium mosaic potexvirus was common, but odontoglossum ringspot tobamovirus was not. In addition the recently described ceratobium mosaic potyvirus was found to be common, and three other novel potyviruses were also found.

Tomato chlorosis virus: a new whitefly-transmitted, Phloem-limited, bipartite closterovirus of tomato

ABSTRACT Tomato chlorosis virus (ToCV) is the second whitefly-transmitted, phloem-limited, bipartite closterovirus described infecting tomato. ToCV is distinct from tomato infectious chlorosis virus (TICV), based on lack of serological and nucleic acid cross-reactions and differences in vector specificity. TICV is transmitted only by the greenhouse whitefly (Trialeurodes vaporariorum), whereas ToCV is transmitted by the greenhouse whitefly, the banded-wing whitefly (T. abutilonea), and Bemisia tabaci biotypes A and B (B. argentifolii). Double-stranded (ds) RNA analyses of ToCV show two prominent dsRNAs of approximately 7,800 and 8,200 bp, with several small dsRNAs. Digoxigenin-11-UTP-labeled riboprobes derived from cDNA clones representing portions of RNAs 1 and 2 were used in Northern blot hybridizations to detect two large nonhomologous dsRNAs and a subset of smaller dsRNAs. These probes were used in dot blot hybridizations to detect ToCV in infected tomato. Inclusion bodies and cytoplasmic vesicles were consistently observed in phloem tissues of ToCV-infected Nicotiana clevelandii. Computer-assisted sequence analysis showed significant homology between ToCV clones that hybridize specifically with RNAs 1 and 2 and the lettuce infectious yellows virus methyltransferase of RNA 1 and the HSP70 heat shock protein homolog of RNA 2, respectively. Thus, ToCV is another member of the growing subgroup of bipartite closteroviruses transmitted by whiteflies.