Alteration of Bark Proteins Associated with Citrus Tristeza Virus (CTV) Infection on Susceptible Citrus Species and Scion-Rootstock Combinations

The effect of citrus tristeza virus (CTV) on bark protems of susceptible citrus species and scion-rootstock combinations was studied by polyaerylamide gel electrophoresis (PAGE). Protein pattern of sour orange bark from CTV-infected trees on this rootstock showed reduced intensity in a protein band, about 20,000 daltons molecular weight, as compared with similar CTV-free trees. This protein modification appears specifically associated with decline induced by tristeza since it was observed on trees of different ages and scion-rootstock combinations, grown in various locations and infected with several CTV isolates, but not on trees exhibiting decline from other causes. The observed protein alteration was localized in the ribosomic fraction. No protein alteration, associated with CTV infection could be found on lemon bark, although this citrus species also behaves as a CTV-susceptible rootstock. Electrophoretic profiles obtained from CTV infected Mexican lime and Etrog citron seedlings also showed reduced intensity in a protein band with the same electrophoretic mobility as the tnodified band of sour orange.     

Acquisition and transmission of selected CTV isolates by Aphis gossypii

Citrus tristeza virus (CTV) is a severe threat to the citrus industry. Disease symptoms and severity may vary depending on the CTV isolates. These are responsible for the decline of trees grafted on sour orange rootstock, or stem pitting on some citrus commercial cultivars regardless of rootstock. In the Calabria region (Italy), CTV was first reported on cultivars imported from other countries. However, recent observations suggested that natural spread of CTV was occurring and a study was needed to determine the epidemiological status and aphid transmission of CTV in Calabria. The role played by local A. gossypii in the spread of CTV was analyzed in the laboratory using various viral acquisition, inoculation periods with three different CTV isolates. Single aphid vectors acquired CTV after a minimum of 30 min acquisition access period (AAP) and were able to transmit the virus after a 60 min inoculation access period (IAP) to healthy plants. A minimum of four aphid vectors were needed to reach 50% transmission probability. The results suggested that the three tested strains are transmitted by A. gossypii in a semi-persistent mode. The results demonstrated that local A. gossypii population can acquire and transmit efficiently the tested virus isolates with serious implications on the virus spread.     

Production of additional allotetraploid somatic hybrids combining mandarings and sweet orange with pre-selected pummelos as potential candidates to replace sour orange rootstock

Summary Sour orange (Citrus aurantium L.) rootstock has historically been a widely utilized eitrus rootstock throughout the world due to its wide soil adaptability and superior horticultural performance. However, quick-decline isolates of citrus tristeza virus (CTV) have demolished entire industries of sour orange rootstock in some countries, including Brazil and Venezuela. CTV is presently destroying millions of trees of sour orange rootstock in Florida and threatens the citrus industries of Texas and Mexico, where sour orange is the predominant rootstock. Efforts to replace sour orange rootstock are combining traditional breeding and biotechnology approaches, including somatic hybridization and transformation. Molecular techniques have confirmed that sour orange is probably a hybrid of mandarin and pummelo. A major focus of our program continues to be the somatic hybridization of superior mandarins with pre-selected pummelo parents. Here, we report the regeneration of allotetraploid somatic hybrid plants from seven new mandarin+pummelo combinations and one new sweet orange+pummelo combination. All new somatic hybrids were confirmed by leaf morphology, ploidy analysis via flow cytometry, and random amplified polymorphic DNA analysis to show nuclear contributions from both parents in corresponding hybrids. These new somatic hybrids are being propagated by tissue culture and/or rooted cuttings for further evaluation of disease resistance and horticultural performance in field trials.     

A severe citrus tristeza virus isolate causing the collapse of trees of sour orange before virus is detectable throughout the canopy§

A rapidly spreading decline of ‘Minneola’ tangelos, ‘Shamouti’ and ‘Valencia’ sweet oranges grafted on sour orange rootstock in the Morasha area, in the coastal plain of Israel, was found to be caused by a severe ‘seedling yellows’ strain of the citrus tristeza virus (CTV). Repeated ELISA tests revealed great variation in distribution of CTV throughout the canopies, even in declining trees. In a substantial number of the declining trees, samples of up to 10 twigs per tree were not always sufficient for CTV detection. The ELISA values (O.D. 405 nm) in the parts found infected were high, whereas in most of the twigs showing negative ELISA results the virus was absent as indicated by biological indexing. The Morasha strain of CTV was also characterised by rapid annual spread rates. The ratio D/E (the proportion of Declining trees found among ELISA-positive ones) is proposed as a simple index of strain severity. The epidemiological consequences of the uneven distribution of CTV and rapid decline are discussed.     

The movement and distribution of citrus tristeza virus and citrus exocortis viroid in citrus seedlings1

The systemic movement of citrus tristeza virus (CTV) in sour orange (Citrus aurantium) seedlings and of citrus exocortis viroid (CEVd) in Etrog citron (C. medica) seedlings was studied. The movement of the two pathogens was analysed by detection in sections of roots and stems at different time intervals. Both pathogens were detected initially in the basal parts and the roots and subsequently spread to the shoot. CTV and CEVd moved in young citrus seedlings at similar rates. The findings are consistent with long distance phloem transport of the virus and the viroid. The practical implications of the pattern of systemic movement for diagnosis of infected trees are discussed.     

The resistance of sour orange to Citrus tristeza virus is mediated by both the salicylic acid and RNA silencing defence pathways

Citrus tristeza virus (CTV) induces in the field the decline and death of citrus varieties grafted on sour orange (SO) rootstock, which has forced the use of alternative decline‐tolerant rootstocks in affected countries, despite the highly desirable agronomic features of the SO rootstock. Declining citrus plants display phloem necrosis below the bud union. In addition, SO is minimally susceptible to CTV compared with other citrus varieties, suggesting partial resistance of SO to CTV. Here, by silencing different citrus genes with a Citrus leaf blotch virus‐based vector, we have examined the implication of the RNA silencing and salicylic acid (SA) defence pathways in the resistance of SO to CTV. Silencing of the genes RDR1, NPR1 and DCL2/DCL4, associated with these defence pathways, enhanced virus spread and accumulation in SO plants in comparison with non‐silenced controls, whereas silencing of the genes NPR3/NPR4, associated with the hypersensitive response, produced a slight decrease in CTV accumulation and reduced stunting of SO grafted on CTV‐infected rough lemon plants. We also found that the CTV RNA silencing suppressors p20 and p23 also suppress the SA signalling defence, with the suppressor activity being higher in the most virulent isolates.     

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.     

Citrus tristeza virus: survival at the edge of the movement continuum

Systemic invasion of plants by viruses is thought to involve two processes: cell-to-cell movement between adjacent cells and long-distance movement that allows the virus to rapidly move through sieve elements and unload at the growing parts of the plant. There is a continuum of proportions of these processes that determines the degrees of systemic infection of different plants by different viruses. We examined the systemic distribution of Citrus tristeza virus (CTV) in citrus species with a range of susceptibilities. By using a "pure" culture of CTV from a cDNA clone and green fluorescent protein-labeled virus we show that both cell-to-cell and long-distance movement are unusually limited, and the degree of limitation varies depending on the citrus host. In the more-susceptible hosts CTV infected only a small portion of phloem-associated cells, and moreover, the number of infection sites in less-susceptible citrus species was substantially decreased further, indicating that long-distance movement was reduced in those hosts. Analysis of infection foci in the two most differential citrus species, Citrus macrophylla and sour orange, revealed that in the more-susceptible host the infection foci were composed of a cluster of multiple cells, while in the less-susceptible host infection foci were usually single cells, suggesting that essentially no cell-to-cell movement occurred in the latter host. Thus, CTV in sour orange represents a pattern of systemic infection in which the virus appears to function with only the long-distance movement mechanism, yet is able to survive in nature.     

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.     

Sensitive and Specific Digoxigenin-labelled RNA Probes for Routine Detection of Citrus tristeza virus by Dot-blot Hybridization

A non‐radioactive dot‐blot hybridization assay for the successful detection of Citrus tristeza virus (CTV) RNA in total nucleic acid extracts of infected citrus was developed. Two digoxigenin (DIG)‐labelled minus‐sense riboprobes, complementary to the coat protein gene sequence of a Chinese and an Apulian CTV isolate were synthesized. Several citrus tissues were evaluated as optimal virus source and leaf petioles were found appropriate material for reliable detection. The hybridization assay showed a detection limit corresponding to 0.2 mg of fresh infected tissue. The riboprobes allowed CTV detection in isolates from different geographical areas, grown in the screenhouse or in the field, resulting in similar hybridization patterns. The infected trees were tested during different seasons with positive results, although from July to August most of the samples gave a weaker hybridization signal, compared to other seasons. The high sensitivity and reliability of the molecular hybridization assay described make it a good alternative to serological methods for CTV detection.     

Antigenic presentation of heterologous epitopes engineered into the outer surface-exposed helix 4 loop region of human papillomavirus L1 capsomeres

The molecular characterization of isolates of citrus tristeza virus (CTV) from eight locations in Mexico was undertaken by analyzing five regions located at the opposite ends of the virus genome. Two regions have been previously used to study CTV variability (coat protein and p23), while the other three correspond to other genomic segments (p349-B, p349-C and p13). Our comparative nucleotide analyses included CTV sequences from different geographical origins already deposited in the GenBank databases. The largest nucleotide differences were located in two fragments located at the 5' end of the genome (p349-B and p349-C). Phylogenetic analyses on those five regions showed that the degree of nucleotide divergence among strains tended to correlate with their pathogenicity. Two main groups were defined: mild, with almost no noticeable effects on the indicator plants and severe, with drastic symptoms. Mild isolates clustered together in every analyzed ORF sharing a genetic distance below 0.022, in contrast with the severe isolates, which showed a more disperse distribution and a genetic distance of 0.276. Analyses of the p349-B and p349-C regions evidenced two lineages within the severe group: severe common subgroup (most of severe isolates) and severe divergent subgroup (T36-like isolates). This study represents the first attempt to analyze the genetic variability of CTV in Mexico by constructing phylogenetic trees based on new genomic regions that use group-specific nucleotide and amino acid sequences. These results may be useful to implement specific assays for strain discrimination. Moreover, it would be an excellent reference for the CTV situation in México to face the recent arrival of brown citrus aphid.     

Intra-farm diversity and evidence of genetic recombination of Citrus tristeza virus in Delhi region of India

Infection of Citrus tristeza virus (CTV) in different citrus orchards of New Delhi was detected by direct antigen coated-ELISA and RT-PCR. Sweet orange (Citrus sinensis) orchards were found to be susceptible to CTV with estimated disease incidence up to 39%. Kagzi kalan (C. lemon), Pumello (C. paradisi) and Kinnow mandarin (C. reticulata) orchards did not show CTV infection. Three CTV isolates, D1, D7 and D15 randomly selected from infected sweet orange orchards were considered for biological and molecular characterization. In the host range study, all the Delhi isolates infected Darjeeling mandarin (C. reticulata), Kagzi lime (C. aurantifolia), sour orange (C. aurantium) and sweet orange but not Kinnow mandarin. A fragment of 5??ORF1a and complete coat protein (CP) gene of these three isolates were cloned, sequenced and compared with other Indian and international CTV isolates. Delhi isolates shared 85?C92% sequence identity for 5??ORF1a fragment and 89?C91% for CP gene among them. Phylogenetic analysis segregated three Delhi isolates into three genogroups for each of 5??ORF1a fragment and CP gene, however phylogenetic relationships for both the genomic regions was incongruent. Recombination detecting program RDP3 detected CTV isolate D7 as recombinant, indicating genetic variability in CTV isolates might be the outcome of recombination events between divergent CTV sequences. An attempt was made in present study to characterize CTV isolates biologically and at genetic level, and to determine genetic diversity at farm level and study the recombination of CTV isolates in Delhi region.     

The pathogenicity determinant of Citrus tristeza virus causing the seedling yellows syndrome maps at the 3'-terminal region of the viral genome

Citrus tristeza virus (CTV) (genus Closterovirus , family Closteroviridae ) causes some of the more important viral diseases of citrus worldwide. The ability to map disease-inducing determinants of CTV is needed to develop better diagnostic and disease control procedures. A distinctive phenotype of some isolates of CTV is the ability to induce seedling yellows (SY) in sour orange, lemon and grapefruit seedlings. In Florida, the decline isolate of CTV, T36, induces SY, whereas a widely distributed mild isolate, T30, does not. To delimit the viral sequences associated with the SY syndrome, we created a number of T36/T30 hybrids by substituting T30 sequences into different regions of the 3' half of the genome of an infectious cDNA of T36. Eleven T36/T30 hybrids replicated in Nicotiana benthamiana protoplasts. Five of these hybrids formed viable virions that were mechanically transmitted to Citrus macrophylla , a permissive host for CTV. All induced systemic infections, similar to that of the parental T36 clone. Tissues from these C. macrophylla source plants were then used to graft inoculate sour orange and grapefruit seedlings. Inoculation with three of the T30/T36 hybrid constructs induced SY symptoms identical to those of T36; however, two hybrids with T30 substitutions in the p23-3' nontranslated region (NTR) (nucleotides 18 394–19 296) failed to induce SY. Sour orange seedlings infected with a recombinant non-SY p23-3' NTR hybrid also remained symptomless when challenged with the parental virus (T36), demonstrating the potential feasibility of using engineered constructs of CTV to mitigate disease.     

柑橘衰退病毒多克隆和单克隆抗体的制备及检测效果分析

通过改进提纯方法获得了柑橘衰退病毒(Citrustristezavirus,CTV)的提纯液,其产量为1mg/100g植物组织。用CTV免疫大耳白兔,获得多克隆抗体,间接ELISA效价为1∶25600。用CTV免疫小鼠,经细胞融合、ELISA筛选和克隆化培养,获得18株能稳定分泌抗CTV单克隆抗体的杂交瘤单细胞株。对其中4株单克隆腹水抗体进行分析的结果表明,这些抗体的ELISA效价为1∶51200~1∶204800,其中2G和3H的抗体类型及亚类为IgG2a,1E和4H为IgG2b。用所制备抗体对不同来源柑橘样品的CTV检测结果显示,单克隆和多克隆抗体结合使用,采用三抗体夹心ELISA(TAS-ELISA)可以获得理想的检测效果,其特异性强、灵敏度高。同时发现所分析4株单克隆抗体对不同的CTV分离物鉴别能力存在差异,但有关这些CTV分离物的特性及其血清学关系还需进一步研究。     

Symptomatic expression of tristeza-infected citrus plants in Pakistan

Variable symptoms were recorded during a survey in the citrus trees infected or suspected to be infected with citrus tristeza virus based on ELISA tests. Sweet orange manifested main symptoms like bud union crease, pin holing, bark cracking, incompatibility, yellowing and dropping of leaves. Pin holing was particularly prevalent in Sweet orange (Citrus sinensis Osbeck), Kinnow (Citrus reticulata Blanco) and Grapefruit (Citrus paradisii Mcaf.), while incompatibility was only in Sweet orange and Grapefruit.     

Etiology of three recent diseases of citrus in São Paulo State: sudden death, variegated chlorosis and huanglongbing

The state of S?o Paulo (SSP) is the first sweet orange growing region in the world. Yet, the SSP citrus industry has been, and still is, under constant attack from various diseases. In the 1940s, tristeza-quick decline (T-QD) was responsible for the death of 9 million trees in SSP. The causal agent was a new virus, citrus tristeza virus (CTV). The virus was efficiently spread by aphid vectors, and killed most of the trees grafted on sour orange rootstock. Control of the disease resided in replacing sour orange by alternative rootstocks giving tolerant combinations with scions such as sweet orange. Because of its drought resistance, Rangpur lime became the favourite alternative rootstock, and, by 1995, 85% of the SSP sweet orange trees were grafted on this rootstock. Therefore, when in 1999, many trees grafted on Rangpur lime started to decline and suddenly died, the spectre of T-QD seemed to hang over SSP again. By 2003, the total number of dead or affected trees was estimated to be over one million. The new disease, citrus sudden death (CSD), resembles T-QD in several aspects. The two diseases have almost the same symptoms, they spread in time and space in a manner strikingly similar, and the pathological anatomy of the bark at the bud union is alike. Transmission of the CSD agent by graft-inoculation has been obtained with budwood inoculum taken not only on CSD-affected trees (grafted on Rangpur lime), but also on symptomless trees (grafted on Cleopatra mandarin) from the same citrus block. This result shows that symptomless trees on Cleopatra mandarin are tolerant to the CSD agent. Trees on rootstocks such as Sunki mandarin or Swingle citrumelo are also tolerant. Thus, in the CSD-affected region, control consists in replacing Rangpur lime with compatible rootstocks, or in approach-grafting compatible rootstock seedlings to the scions of trees on Rangpur lime (inarching). More than 5 million trees have been inarched in this way. A new disease of sweet orange, citrus variegated chlorosis (CVC), was observed in 1987 in the Triangulo Mineiro of Minas Gerais State and the northern and north-eastern parts of SSP. By 2000, the disease affected already 34% of the 200 million sweet orange trees in SSP. By 2005, the percentage had increased to 43%, and CVC was present in all citrus growing regions of Brazil. Electron microscopy showed that xylem-limited bacteria were present in all symptomatic sweet orange leaves and fruit tissues tested, but not in similar materials from healthy, symptomless trees. Bacteria were consistently cultured from twigs of CVC-affected sweet orange trees but not from twigs of healthy trees. Serological analyses showed the CVC bacterium to be a strain of Xylella fastidiosa. The disease could be reproduced and Koch's postulates fulfilled, by mechanically inoculating a pure culture of X. fastidiosa isolate 8.1.b into sweet orange seedlings. The genome of a CVC strain of X. fastidiosa was sequenced in SSP in the frame of a project supported by FAPESP and Fundecitrus. X. fastidiosa is the first plant pathogenic bacterium, the genome of which has been sequenced. Until recently, America was free of huanglongbing (HLB), but in March 2004 and August 2005, symptoms of the disease were recognized, respectively in the State of S?o Paulo (SSP) and in Florida, USA. HLB was known in China since 1870 and in South Africa since 1928. Because of its destructiveness and its rapid spread by efficient psyllid insect-vectors, HLB is probably the most serious citrus disease. HLB is caused by a phloem sieve tube-restricted Gram negative bacterium, not yet available in culture. In the 1990s, the bacterium was characterized by molecular techniques as a member of the alpha proteobacteria designated Candidatus Liberibacter africanus for the disease in Africa, and Candidatus Liberibacter asiaticus for HLB in Asia. In SSP, Ca. L. asiaticus is also present, but most of the trees are infected with a new species, Candidatus Liberibacter americanus.     

Production of Virus-tree Nucellar Plantlets from Unfertilized Ovules of Citrus in vitro

On a series of Murashige and Tucker (MT) media supplemented with different growth regulators, the 8-week-old unfertilized ovules of Washington navel orange (Citrus sinensis) were able to regenerate perfect plantlets via somatic embryogenesis or organogenesis. The sorts and combinations of exogenous hormones had remarkable effects on the induction, growth and differentiation of its callus. It was found that the most suitable induction medium was MT medium supplemented with 1.0 mg/l BA and 0.5mg/l 1AA. The most suitable differentiation medium was MT medium supplemented with 1.0 mg/l IBA. It was proved by indicator plant examination that the nucellar plantlets free of citrus exocortis virus (CEV) and citrus tristeza virus (CTV) had been obtained from infected trees.