Jorge A. Abad

A reliable and inexpensive method of nucleic acid extraction for the PCR-based detection of diverse plant pathogens

A reliable extraction method is described for the preparation of total nucleic acids from at least ten plant genera for subsequent detection of plant pathogens by PCR-based techniques. The method combined a modified CTAB (cetyltrimethylammonium bromide) extraction protocol with a semi-automatic homogenizer (FastPrep) instrument) for rapid sample processing and low potential of cross contamination. The method was applied to sample preparation for PCR-based detection of 28 different RNA and DNA viruses, six viroids, two phytoplasmas and two bacterial pathogens from a range of infected host plants including sweet potato, small fruits and fruit trees. The procedure is cost-effective and the qualities of the nucleic acid preparations are comparable to those prepared by commonly used commercial kits. The efficiency of the procedure permits processing of numerous samples and the use of a single nucleic acid preparation for testing both RNA and DNA genomes by PCR, making this an appealing method for testing multiple pathogens in certification and quarantine programs.

Sweetpotato Viruses: 15 Years of Progress on Understanding and Managing Complex Diseases

Sweetpotato is a member of the morning glory family that is thought to have originated in Central or South America but also has a secondary center of diversity in the southwest Pacific islands. It is grown in all tropical and subtropical areas of the world and consistently ranks among the 10 most important food crops worldwide on the basis of dry weight produced, yielding about 130 million metric tons per year on about 9 million hectares. Sweetpotato is an important crop for food security. It has been relied on as a source of calories in many circumstances. Vines and/or storage roots can be used for direct human consumption or animal feed. Growing awareness of health benefits attributed to sweetpotato has stimulated renewed interest in the crop. Orange-fleshed cultivars, a source of vitamin A, were introduced to developing countries with hope that they would replace the white-flesh varieties and help alleviate vitamin A deficiencies. In East Africa, sweetpotato virus disease, which is caused by the synergistic interaction of the whitefly-transmitted crinivirus and the aphid-transmitted potyvirus, can cause losses of 80 to 90% in many high-yielding genotypes. During the past 15 years, as molecular methods have been adopted, much has been learned about the composition of the sweetpotato virus complexes, the effects of virus diseases on production systems, the biology of the virus–plant interaction, and management approaches to sweetpotato virus diseases. This article is intended to summarize what has been learned since earlier reviews, integrate knowledge gleaned from experiences in tropical and temperate production systems, and suggest courses of action to develop sustainable management programs for these diseases.

Another Look at the Origin of Late Blight of Potatoes, Tomatoes, and Pear Melon in the Andes of South America

Late blight of potatoes (Solanum tuberosum L.), caused by Phytophthora infestans (Mont.) De Bary, is one of the most devastating plant diseases in human history. During the 1840s, the fungus caused epidemics in the United States and Europe culminating in the famous Irish potato famine of 1845. These late blight epidemics brought hunger to many people and the migration and death of many others. Indirectly, late blight also was a stimulus to the origins of plant pathology as a science. Plant pathology began with the contributions of Berkeley and De Bary. Reverend Berkeley became the main supporter of the “fungal theory” of late blight (1845) (12), and Anton De Bary provided evidence that late blight was caused by the fungus that he named Phytophthora infestans (1876) (22). These pioneers also believed that the fungus was imported to Europe from the Andes of South America, the native land of potatoes (12,21,22). Many other notable plant pathologists supported this idea until 1939, when Reddick presented the new concept that central Mexico was the center of origin of late blight (59). Today, Mexico is widely considered to be the center of origin of P. infestans (26,27,31,47,74). According to current plant pathology literature, P. infestans was introduced from central Mexico to the United States in 1842, and thence to Europe in 1845 (26,27,31). In South America, the presence of late blight in Argentina in 1887 and Brazil in 1898 has been attributed to an introduction of potatoes from Europe in the 1880s (47). In current scientific literature, the first appearance of late blight in Peru was in 1929 (47) or 1947 (61), in Bolivia in 1943, and in Chile in 1949 (47); no dates have been established for other Andean countries such as Colombia or Ecuador (47,61). The origins of the disease in South American countries other than Argentina and Brazil have not been definitively explained. It is widely accepted that Peru is the center of origin of potato, tomato (Lycopersicon esculentum Mill.), and pear melon (Solanum muricatum Ait.) (36,48), the three major hosts of P. infestans (1,3,19,67). Contrary to the concept that late blight is of recent occurrence in Peru and other Andean countries, strong evidence exists in the historical literature that the disease has been endemic in the area for centuries. This report examines the historical literature on the origin of P. infestans in hopes of shedding more light on this fascinating mystery. A preliminary report on this assessment has been published (2).

Phylogenetic relationships of closely related potyviruses infecting sweet potato determined by genomic characterization of Sweet potato virus G and Sweet potato virus 2

Complete nucleotide sequences of Sweet potato virus G (SPVG) and Sweet potato virus 2 (SPV2) were determined to be 10,800 and 10,731 nucleotides, respectively, excluding the 3′-poly(A) tail. Their genomic organizations are typical of potyviruses, encoding a polyprotein which is likely cleaved into 10 mature proteins by three viral proteinases. Conserved motifs of orthologous proteins of viruses in the genus Potyvirus are found in corresponding positions of both viruses. Pairwise comparisons of individual protein sequences of the two viruses with those of 78 other potyviruses show that P1 protein and coat protein (CP) of both viruses are significantly large, with the SPVG CP as the largest among the all the known species of the genus Potyvirus. The extended N-terminal region of the P1 protein is conserved in the potyviruses and ipomovirus infecting sweet potato. A novel ORF, PISPO, is identified within the P1 region of SPVG, SPV2, Sweet potato feathery mottle virus (SPFMV), and Sweet potato virus C (SPVC). The C-terminal half of CP is highly conserved among SPFMV, SPVC, SPVG, SPV2, and Sweet potato virus-Zimbabwe. Phylogenetic analysis based on the deduced CP amino acid sequences supports the view that these five viruses are grouped together in a SPFMV lineage. The analysis also reveals that Sweet potato virus Y and Ipomoea vein mosaic virus are grouped with SPV2 as one species, and these two viruses should be consolidated with SPV2.

Phytophthora niederhauserii sp. nov., a polyphagous species associated with ornamentals, fruit trees and native plants in 13 countries

A non-papillate, heterothallic Phytophthora species first isolated in 2001 and subsequently from symptomatic roots, crowns and stems of 33 plant species in 25 unrelated botanical families from 13 countries is formally described here as a new species. Symptoms on various hosts included crown and stem rot, chlorosis, wilting, leaf blight, cankers and gumming. This species was isolated from Australia, Hungary, Israel, Italy, Japan, the Netherlands, Norway, South Africa, Spain, Taiwan, Turkey, the United Kingdom and United States in association with shrubs and herbaceous ornamentals grown mainly in greenhouses. The most prevalent hosts are English ivy (Hedera helix) and Cistus (Cistus salvifolius). The association of the species with acorn banksia (Banksia prionotes) plants in natural ecosystems in Australia, in affected vineyards (Vitis vinifera) in South Africa and almond (Prunus dulcis) trees in Spain and Turkey in addition to infection of shrubs and herbaceous ornamentals in a broad range of unrelated families are a sign of a wide ecological adaptation of the species and its potential threat to agricultural and natural ecosystems. The morphology of the persistent non-papillate ellipsoid sporangia, unique toruloid lobate hyphal swellings and amphigynous antheridia does not match any of the described species. Phylogenetic analysis based on sequences of the ITS rDNA, EF-1α, and β-tub supported that this organism is a hitherto unknown species. It is closely related to species in ITS clade 7b with the most closely related species being P. sojae. The name Phytophthora niederhauserii has been used in previous studies without the formal description of the holotype. This name is validated in this manuscript with the formal description of Phytophthora niederhauserii Z.G. Abad et J.A. Abad, sp. nov. The name is coined to honor Dr John S. Niederhauser, a notable plant pathologist and the 1990 World Food Prize laureate.

Simultaneous detection and differentiation of four closely related sweet potato potyviruses by a multiplex one-step RT-PCR

Four closely related potyviruses, Sweet potato feathery mottle virus (SPFMV), Sweet potato virus C (SPVC), Sweet potato virus G (SPVG) and/or Sweet potato virus 2 (SPV2), are involved in sweet potato virus disease complexes worldwide. Identification and detection of these viruses are complicated by high similarity among their genomic sequences, frequent occurrence as mixed infections and low titer in many sweet potato cultivars. A one-tube multiplex reverse transcription-PCR (mRT-PCR) assay was developed for simultaneous detection and differentiation of SPFMV, SPVC, SPVG and SPV2. Four specific forward primers unique to each virus and one reverse primer based on the region conserved in all four viruses were selected and used in the assay. The mRT-PCR assay was optimized for primer concentration and cycling conditions. It was tested using sweet potato plants infected naturally with one to four target viruses and then evaluated using field samples collected from southwestern China. The mRT-PCR assay is reliable and sensitive as a simple, rapid and cost-effective method to detect these pathogens in sweet potato. This assay will be useful to quarantine and certification programs and virus surveys when large numbers of samples are tested.

Molecular characterization of domestic and exotic potato virus S isolates and a global analysis of genomic sequences

Five potato virus S (PVS) isolates from the USA and three isolates from Chile were characterized based on biological and molecular properties to delineate these PVS isolates into either ordinary (PVSO) or Andean (PVSA) strains. Five isolates – 41956, Cosimar, Galaxy, ND2492-2R, and Q1 – were considered ordinary strains, as they induced local lesions on the inoculated leaves of Chenopodium quinoa, whereas the remaining three (FL206-1D, Q3, and Q5) failed to induce symptoms. Considerable variability of symptom expression and severity was observed among these isolates when tested on additional indicator plants and potato cv. Defender. Additionally, all eight isolates were characterized by determining the nucleotide sequences of their coat protein (CP) genes. Based on their biological and genetic properties, the 41956, Cosimar, Galaxy, ND2492-2R, and Q1 isolates were identified as PVSO. PVS-FL206-1D and the two Chilean isolates (PVS-Q3 and PVS-Q5) could not be identified based on phenotype alone; however, based on sequence comparisons, PVS-FL206-1D was identified as PVSO, while Q3 and Q5 clustered with known PVSA strains. C. quinoa may not be a reliable indicator for distinguishing PVS strains. Sequences of the CP gene should be used as an additional criterion for delineating PVS strains. A global genetic analysis of known PVS sequences from GenBank was carried out to investigate nucleotide substitution, population selection, and genetic recombination and to assess the genetic diversity and evolution of PVS. A higher degree of nucleotide diversity (π value) of the CP gene compared to that of the 11K gene suggested greater variation in the CP gene. When comparing PVSA and PVSO strains, a higher π value was found for PVSA. Statistical tests of the neutrality hypothesis indicated a negative selection pressure on both the CP and 11K proteins of PVSO, whereas a balancing selection pressure was found on PVSA.

Morphological and molecular characterization of Phytophthora glovera sp. nov. from tobacco in Brazil

A root rot disease of cultivated tobacco called yellow stunt has been observed in the burley tobacco production areas of Brazil since the early 1990s. Root infecting fungi and straminipiles were isolated from the roots of diseased tobacco plants, including a semi-papillate, homothallic, slow growing Phytophthora species. Pathogenicity trials confirmed that Phytophthora sp. caused root rot and stunting of burley and flue-cured tobaccos. Morphological characteristics of the asexual and sexual stages of this organism did not match any reported Phytophthora species and were very different from the widely known tobacco black shank pathogen P. nicotianae. Phylogenetic analysis based on sequences of the internal transcribed spacer rDNA, β-tubulin and translation elongation factor 1-α regions indicated that this organism represents a previously unreported Phytophthora species that is significantly supported in clade 2 and most closely related to P. capsici. However P. glovera differs from P. capsici in a number of morphological characters, most significantly P. glovera is homothallic and produces both paragynous and amphigynous antheridia while P. capsici is heterothallic and produces only amphigynous antheridia. In this paper we confirmed pathogenicity of this species on tobacco and describe the morphological and molecular characteristics of Phytophthora glovera sp. nov.

Genome characterization of sweet potato symptomless virus 1: a mastrevirus with an unusual nonanucleotide sequence

Complete genomic sequences of nine isolates of sweet potato symptomless virus 1 (SPSMV-1), a virus of the genus Mastrevirus in the family Geminiviridae, were determined from sweet potato accessions from different countries and found to be 2,559-2,602 nucleotides in length. These isolates shared 97-100% genome sequence identity and had an unusual nonanucleotide sequence (TAAGATTCC) in a large intergenic region as well as an additional open reading frame, C3, which is conserved in dicot-infecting mastreviruses.

Simultaneous detection and differentiation of three Potyviridae viruses in sweet potato by a multiplex TaqMan real time RT-PCR assay

A multiplex TaqMan real time RT-PCR was developed for detection and differentiation of Sweet potato virus G, Sweet potato latent virus and Sweet potato mild mottle virus in one tube. Amplification and detection of a fluorogenic cytochrome oxidase gene was included as an internal control. The assay was compared with a multiplex RT-PCR developed in the initial study for the detection and differentiation of the three viruses and host 18S rRNA. Primers and/or probes of the two assays were designed from conserved regions of each virus. The two assays were optimized for primers/probes and primer concentrations and thermal cycling conditions. Sensitivity and specificity of the assays were compared each other and with other assay. Both assays were evaluated by 74 field samples original from five different provinces of China. RESULTS showed that the TaqMan real time RT-PCR offered rapid, sensitive, effective and reliable for the simultaneous detection and differentiation of the three viruses in sweet potato plants. The assay will be useful to quarantine and certification programs and virus surveys when large numbers of samples are tested.