Genetic transformation of sweet orange with the coat protein gene of <Emphasis Type="Italic">Citrus psorosis virus</Emphasis> and evaluation of resistance against the virus

Citrus psorosis is a serious viral disease affecting citrus trees in many countries. Its causal agent is Citrus psorosis virus (CPsV), the type member of genus Ophiovirus. CPsV infects most important citrus varieties, including oranges, mandarins and grapefruits, as well as hybrids and citrus relatives used as rootstocks. Certification programs have not been sufficient to control the disease and no sources of natural resistance have been found. Pathogen-derived resistance (PDR) can provide an efficient alternative to control viral diseases in their hosts. For this purpose, we have produced 21 independent lines of sweet orange expressing the coat protein gene of CPsV and five of them were challenged with the homologous CPV 4 isolate. Two different viral loads were evaluated to challenge the transgenic plants, but so far, no resistance or tolerance has been found in any line after 1 year of observations. In contrast, after inoculation all lines showed characteristic symptoms of psorosis in the greenhouse. The transgenic lines expressed low and variable amounts of the cp gene and no correlation was found between copy number and transgene expression. One line contained three copies of the cp gene, expressed low amounts of the mRNA and no coat protein. The ORF was cytosine methylated suggesting a PTGS mechanism, although the transformant failed to protect against the viral load used. Possible causes for the failed protection against the CPsV are discussed.     

Polyclonal antibodies against the recombinantly expressed coat protein of the Citrus psorosis virus

Psorosis is a damaging disease of citrus that is widespread in many parts of the world. Citrus psorosis virus (CPsV), the type species of the genus Ophiovirus, is the putative causal agent of psorosis. Detection of CPsV by laboratory methods, serology in particular is a primary requirement for large-scale surveys but their production has been impaired by the difficulty of obtaining sufficient clean antigen for immunization. Specific PAbs against coat protein were produced in E. coli using recombinant DNA approach. The full length CP gene fragment was amplified by RT-PCR using total RNA extracted from CPsV infected citrus leaves and CP specific primers. The obtained product (1320bp) was cloned, sequenced and sub-cloned into p^ET-30(+) expression vector. Expression was induced and screened in different bacterial clones by the presence of the expressed protein (48kDa) and optimized in one clone. Expressed CP was purified using batch chromatography under denaturing conditions. Specificity of expressed protein was demonstrated by ELISA before used as antigen for raising PAbs in mice. Specificity of the raised PAbs to CPsV was verified by ELISA and western blotting. The raised PAbs were showed highly effectiveness in screening by ELISA comparing with the commercial antibodies purchased from Agritest, Valanzano, Italy.The expression of CPsV CP gene in E. coli, production of PAbs using recombinant protein as an antigen, the suitability of these antibodies for use in immunodiagnostics against the CPsV Egyptian isolate have been accomplished in this work.     

<Emphasis Type="Italic">Citrus psorosis virus</Emphasis> coat protein-derived hairpin construct confers stable transgenic resistance in citrus against psorosis A and B syndromes

Citrus psorosis virus (CPsV) is the causal agent of psorosis, a serious and widespread citrus disease. Two syndromes of psorosis, PsA and PsB, have been described. PsB is the most aggressive and rampant form. Previously, we obtained Pineapple sweet orange plants transformed with a hairpin construct derived from the CPsV coat protein gene (ihpCP). Some of these plants were resistant to CPsV 90-1-1, a PsA isolate homologous to the transgene. In this study, we found that expression of the ihpCP transgene and siRNA production in lines ihpCP-10 and -15 were stable with time and propagation. In particular, line ihpCP-15 has been resistant for more than 2 years, even after re-inoculation. The ihpCP plants were also resistant against a heterologous CPsV isolate that causes severe PsB syndrome. Line ihpCP-15 manifested complete resistance while line ihpCP-10 was tolerant to the virus, although with variable behaviour, showing delay and attenuation in PsB symptoms. These lines are promising for a biotech product aimed at eradicating psorosis.     

Potential vectors of Xylella fastidiosa: a study of leafhoppers and treehoppers in citrus agroecosystems affected by Citrus Variegated Chlorosis

This study investigated the predominant leafhopper and treehopper (Hemiptera, Auchenorrhyncha) species in Citrus Variegated Chlorosis (CVC)‐affected citrus agroecosystems in Argentina, their seasonal fluctuation, and their potential role as vectors of Xylella fastidiosa Wells et al., using molecular methods for detection. More than 6 000 Auchenorrhyncha were collected from three citrus agroecosystems over a period of 3 years using yellow sticky traps and entomological nets. Cicadellidae and Membracidae were the most abundant families. Of the 43 species identified, five were predominant in citrus orchards, and three were predominant in weeds surrounding citrus plants. All predominant species and another four non‐predominant species tested positive for X. fastidiosa in PCR and real‐time PCR assays. In a transmission assay, Dechacona missionum (Berg), Tapajosa rubromarginata (Signoret), and Cyphonia clavigera (Fabricius) transmitted X. fastidiosa successfully. Scaphytopius bolivianus Oman and Frequenamia spiniventris (Linnavuori) populations increased once (during the summer), possibly due to favorable weather conditions, and Bucephalogonia xanthophis (Berg), Molomea lineiceps Young, and T. rubromarginata populations increased twice a year: once in summer and once in winter, coinciding with the increase in early citrus shoots (flush). Among the X. fastidiosa‐positive species, those with the higher population densities during the sprouting period, where trees are highly susceptible to infection, must be considered as most relevant vectors of CVC in the citrus‐growing areas in Argentina.     

Evaluation of consistency in quantification of gene copy number by real‐time reverse transcription quantitative polymerase chain reaction and virus titer by plaque‐forming assay for human respiratory syncytial virus

The plaque‐forming assay is the standard technique for determining viral titer, and a critical measurement for investigating viral replication. However, this assay is highly dependent on experimental technique and conditions. In the case of human respiratory syncytial virus (RSV) in particular, it can be difficult to objectively confirm the accuracy of plaque‐forming assay because the plaques made by RSV are often small and unclear. In recent studies, RT‐qPCR methods have emerged as a supportive procedure for assessment of viral titer, yielding highly sensitive and reproducible results. In this report, we compare the viral replication, as determined by plaque‐forming assay, and the copy numbers of RSV genes NS1, NS2, N, and F, as determined by RT‐qPCR. Two real‐time PCR systems, SYBR Green and TaqMan probe, gave highly similar results for measurement of copy numbers of RSV N genes of virus subgroups A. We determined the RSV gene copy numbers in the culture cell supernatant and cell lysate measured at various multiplicities of infection. We found that copy number of the RSV N gene in the culture supernatant and cell lysate was highly correlated with plaque‐forming units. In conclusion, RT‐qPCR measurement of RSV gene copy number was highly dependent on viral titer, and the detailed comparison between each gene copy number and virus titer should be useful and supportive in confirming RSV plaque‐forming assay and virus dynamics. The technique may also be used to estimate the amount of RSV present in clinical specimens.

     

Modification of the PthA4 effector binding elements in Type I CsLOB1 promoter using Cas9/sgRNA to produce transgenic Duncan grapefruit alleviating XccΔpthA4:dCsLOB1.3 infection

Citrus canker caused by Xanthomonas citri subspecies citri (Xcc) is a severe disease for most commercial citrus cultivars and responsible for significant economic losses worldwide. Generating canker‐resistant citrus varieties will provide an efficient and sustainable solution to control citrus canker. Here, we report our progress in generating canker‐resistant grapefruit by modifying the PthA4 effector binding elements (EBEs) in the CsLOB1 Promoter (EBE_PthA4‐CsLOBP) of the CsLOB1 (Citrus sinensis Lateral Organ Boundaries) gene. CsLOB1 is a susceptibility gene for citrus canker and is induced by the pathogenicity factor PthA4, which binds to the EBE_PthA4‐CsLOBP to induce CsLOB1 gene expression. There are two alleles, Type I and Type II, of CsLOB1 in Duncan grapefruit. Here, a binary vector was designed to disrupt the PthA4 EBEs in Type I CsLOB1 Promoter (TI CsLOBP) via epicotyl transformation of Duncan grapefruit. Four transgenic Duncan plants with targeted modification of EBE_PthA4‐T1 CsLOBP were successfully created. As for Type I CsLOB1 promoter, the mutation rate was 15.63% (#D13), 14.29% (#D17), 54.54% (#D18) and 81.25% (#D22). In the presence of wild‐type Xcc, transgenic Duncan grapefruit developed canker symptoms similarly as wild type. An artificially designed dTALE dCsLOB1.3, which specifically recognizes Type I CsLOBP, but not the mutated Type I CsLOBP or Type II CsLOBP, was developed to infect Duncan transformants. Consequently, #D18 had weakened canker symptoms and #D22 had no visible canker symptoms in the presence of XccΔpthA4:dCsLOB1.3. Our data suggest that activation of a single allele of susceptibility gene CsLOB1 by PthA4 is sufficient to induce citrus canker disease, and mutation in the promoters of both alleles of CsLOB1 is probably required to generate citrus canker‐resistant plants. This work lays the groundwork to generate canker‐resistant citrus varieties via Cas9/sgRNA in the future.     

Specific and Rapid Detection of Lily symptomless virus and Arabis mosaic virus in Lily by Dual IC‐RT‐PCR

Lily symptomless virus (LSV) and Arabis mosaic virus (ArMV) cause severe losses of quantity and quality of lily flower and bulb production. Specificity, sensitivity and speed of detection methods for viruses need to be improved greatly to prevent LSV and ArMV from spreading from infected lilies. A dual IC‐RT‐PCR procedure for detection was developed in which the antibodies of LSV and ArMV were mixed and the mixture used to coat the PCR tubes. The particles of the two viruses were captured by the respective antibodies. Interference by other RNA viruses in infected lily was eliminated in the RT‐PCR. Also, an RNA extraction step was omitted. The dual IC‐RT‐PCR products of LSV and ArMV were 521 bp and 691 bp, respectively. The specificity of the method was validated; only LSV and ArMV of four viruses were detected by dual IC‐RT‐PCR. The sensitivity of the detection method is 1 mg leaf tissue and higher than DAS‐ELISA due to enrichment by dual immunocapture.     

Biological and Molecular Detection of Citrus Psorosis Virus in Citrus in the Eastern Mediterrenean Region of Turkey

Fifty bud sticks exhibiting vein flecking, vein clearing and oak-leaf pattern symptoms of ‘Satsuma’ and ‘Clementine’ mandarins, and ‘Washington navel’ and local oranges in the field in Mersin, Kozan and Adana provinces were collected and grafted on one-year-old sour orange seedlings to maintain Citrus psorosis virus (CPsV) in indicators. Thirty two indicator plants showed typical symptoms of vein flecking, vein clearing, and vein banding with oak-leaf pattern. Eighteen plants gave mild leaf symptoms. CPsV was detected by RT-PCR from CPsV-infected sources. Leaf samples for RT-PCR were collected from symptomatic field trees. In all, thirty samples from different trees of mandarin and twenty samples from different trees of sweet oranges were collected. A 434 by specific DNA for the coat protein was amplified from the cDNA of CPsV-infected leaf samples. This specific DNA product was not amplified from healthy leaf samples or asymptomatic leaves collected from CPsV-infected trees.     

Production of Polyclonal Antibodies to the Recombinant Coat Protein of Citrus tristeza virus and their Effectiveness for Virus Detection

Citrus tristeza virus (CTV) is distributed worldwide and causes the most economically important virus diseases of citrus. Enzyme‐linked immunosorbent assay (ELISA) and/or immunoprinting have become an indispensable tools for large‐scale diagnosis of CTV worldwide. Several CTV detection kits are commercially available, based on either polyclonal or monoclonal antibodies developed against purified virus preparations. We have developed polyclonal antibodies to recombinant p25 CTV coat proteins (rCP) and determined their effectiveness for both trapping and as the intermediate antibody in double‐antibody sandwich indirect (DASI) ELISA. The p25 coat protein gene of three CTV isolates was amplified by RT‐PCR and further cloned and expressed in Escherichia coli cells. The rCP was injected into rabbits and goats for antibody production. Western blotting assays with the rCP CTV‐specific antibodies reacted positively with the homologous and heterologous rCP of the three CTV isolates and with the corresponding native coat protein present in crude sap extracts of CTV‐infected citrus tissue, but not with extracts from healthy tissue. The rCP antibodies from goat and rabbit reacted as both plate trapping and intermediate antibodies in DASI‐ELISA, discriminating healthy and CTV‐infected citrus, with optical density (OD₄₀₅) values in the range of 0.151–2.415 for CTV‐infected samples and less than 0.100 for healthy tissue. Commercially available anti‐CTV antibodies were used as a reference. Previous reports indicate that antibodies developed to recombinant antigens, including those of CTV, may not be functional for trapping the target antigens under non‐denaturing conditions. Our results showed the feasibility of CTV antibodies developed to the rCP for use as both trapping and intermediate antibodies in DASI‐ELISA, when the recombinant antigen was fractioned with polyacrylamide electrophoresis gel and further extensively dialysed against phosphate buffer saline prior to its use as immunogen.     

Expanded Strain‐Specific RT‐PCR Assay for Differential Detection of Currently Known Citrus Tristeza Virus Strains: a Useful Screening Tool

Genotypic characterization of Citrus tristeza virus (CTV) strains has progressed significantly, but their phenotypic expression is poorly established as CTV naturally occurs as mixed‐strain populations. A screening system for the analysis of mixed‐strain populations is required for population studies and the correlation with symptom expression. In this study, a published CTV strain‐specific detection assay was expanded and improved to facilitate detection of currently known CTV strains. Supplementary RT‐PCR assays were developed for two variant groups of the RB strain and the HA16‐5 strain, and assays for the T36 strain and generic CTV detection were improved. The value of the strain‐specific assays was shown by the ability to identify the strain components of two CTV cross‐protecting sources, GFMS35 and LMS6, used in the South African budwood certification scheme and to demonstrate the segregation of strains in budwood source trees.     

Pathological categorization of the stem‐pitting and mild strains Citrus tristeza virus in Taiwan and their genomic analysis

Citrus tristeza virus (CTV), the causal agent of tristeza disease, causes the devastating diseases worldwide. In Taiwan, complex cultivars and long‐term infection by CTV result in more than 90% of infected citrus trees, but local strain identification and classification are still incomplete. Here, six CTV strains were categorized by grafting onto eight citrus cultivars and the pathological characteristics of the stem‐pitting mild strains were identified. After 6 months of inoculation, the pummelo stem‐pitting severe strain (CTV‐Pum/SP/T1) only caused severe symptoms in Wentan pummelo (WP) and the mild strain (CTV‐Pum/M/T5) was symptomless in every cultivar; the sweet orange (SO) stem‐pitting severe strain (CTV‐SwO/SP/T7) affected SO, WP and Ponkan mandarin (PM), and the mild strain (CTV‐SwO/M/T51) caused no symptoms in SO except for WP; the mandarin stem‐pitting severe strain (CTV‐Man/SP/T46) caused severe impacts in PM, WP and Eureka lemon, whereas the mild strain (CTV‐Man/M/T2) only caused severe stem‐pitting in WP. The full‐length sequencing of both pummelo stem‐pitting strains and phylogenetic analysis revealed that CTV‐Pum/SP/T1 and CTV‐Pum/M/T5 were related to the HA18‐9 and HA16‐5 strains from Hawaii, respectively. Moreover, recombination analysis revealed that TCT repeat sequences existed at open reading frame 1a in both the CTV‐Pum/SP/T1 and the T36 strains from the United States, indicating that the possible evolution relationship between two regions. Furthermore, improved universal and specific primer pairs were designed for more specific, sensitive detection to meet the needs for quarantine and early prevention. The understanding of strain pathogenicity and genomic analysis provided further characterization of each strain and enabled practical challenge inoculation against CTV disease.     

High‐throughput detection and screening of plants modified by gene editing using quantitative real‐time polymerase chain reaction

Gene editing techniques are becoming powerful tools for modifying target genes in organisms. Although several methods have been developed to detect gene‐edited organisms, these techniques are time and labour intensive. Meanwhile, few studies have investigated high‐throughput detection and screening strategies for plants modified by gene editing. In this study, we developed a simple, sensitive and high‐throughput quantitative real‐time (qPCR)‐based method. The qPCR‐based method exploits two differently labelled probes that are placed within one amplicon at the gene editing target site to simultaneously detect the wild‐type and a gene‐edited mutant. We showed that the qPCR‐based method can accurately distinguish CRISPR/Cas9‐induced mutants from the wild‐type in several different plant species, such as Oryza sativa, Arabidopsis thaliana, Sorghum bicolor, and Zea mays. Moreover, the method can subsequently determine the mutation type by direct sequencing of the qPCR products of mutations due to gene editing. The qPCR‐based method is also sufficiently sensitive to distinguish between heterozygous and homozygous mutations in T₀ transgenic plants. In a 384‐well plate format, the method enabled the simultaneous analysis of up to 128 samples in three replicates without handling the post‐polymerase chain reaction (PCR) products. Thus, we propose that our method is an ideal choice for screening plants modified by gene editing from many candidates in T₀ transgenic plants, which will be widely used in the area of plant gene editing.     

Highly Efficient Immunodiagnosis of Episomal Banana streak MY virus Using Polyclonal Antibodies Raised Against Recombinant Viral‐Associated Protein

Banana streak MY virus (BSMYV) is the causal agent of viral leaf streak disease of banana, which leads to considerable losses in banana production in most of the banana‐growing regions worldwide. Developing high‐throughput virus detection system is essential for managing viral diseases especially in vegetatively propagated crops like banana. In this study, viral‐associated protein (VAP) coded by ORF II of BSMYV was expressed in Escherichia coli, and polyclonal antibodies were raised against purified recombinant VAP (rVAP) fusion protein in rabbits. Specificity and sensitivity of resulting antibodies were tested in Western blot, immunosorbent electron microscopy (ISEM) and enzyme‐linked immunosorbent assays (ELISAs). In direct antigen‐coated (DAC)‐ELISA, antibodies reacted specifically to BSMYV in crude sap, up to 1 : 8000 dilutions, but not to healthy leaf extracts. Using this antiserum, an immunocapture polymerase chain reaction (IC‐PCR) assay was developed and compared with DAC‐ELISA. VAP antibody‐based IC‐PCR is highly specific and could differentiate episomal virus infection from the integrated endogenous BSV (eBSV) sequences. The recombinant antibodies were validated by testing with a large number of banana germplasm conserved in the field gene bank. Field samples collected during surveys and mother cultures used in tissue culture propagation suggest that antibodies generated against rVAP are sensitive and useful for large‐scale detection of BSMYV. To the best of our knowledge, this is the first report on the production of polyclonal antiserum against recombinant VAP of BSMYV and its suitability for serology‐based testing by ELISA and IC‐PCR. This VAP‐based immunodiagnosis can be applied in quarantine, germplasm exchange and certification programmes.     

Development of reverse transcription loop‐mediated isothermal amplification assay for sensitive and rapid detection of Hosta virus X

The one‐step real‐time turbidity loop‐mediated isothermal amplification assay (RealAmp) was developed to detect Hosta virus X (HVX), the most devastating threat to hosta industry. The reaction was performed in a single tube at 63°C for 15 min, and real‐time turbidimetry was used to monitor the amplification results. Specificity and sensitivity analyses demonstrated that this RealAmp method was sensitive as real‐time TaqMan RT‐PCR and about 100‐fold higher than conventional RT‐PCR with no cross‐reaction with other viral pathogens. Field samples detection showed that HVX could be identified effectively with this method. Overall, this RealAmp assay for HVX detection was simple, specific, sensitive, convenient and time‐saving and could assist in the quarantine measures for prevention and control of the disease caused by HVX.