The Ry-fsto gene from Solanum stoloniferum for extreme resistant to Potato virus Y maps to potato chromosome XII and is diagnosed by PCR marker GP122718 in PVY resistant potato cultivars

A novel locus for extreme resistance to Potato virus Y (PVY), Ry-f_sto, was identified on potato chromosome XII. The gene Ry-f_sto has been introgressed from the wild potato species Solanum stoloniferum. Inheritance of Ry-f_sto in the tetraploid potato population Rysto was consistent with the model of a single, dominant gene. Bulked segregant analysis identified an ISSR (inter-simple sequence repeat) marker UBC 857₉₈₀ linked to Ry-f_sto. This marker mapped to linkage group XII of a reference potato RFLP (restriction fragment length polymorphism) map. Chromosome XII specific RFLP markers were converted into PCR-based STS and CAPS markers and tested for linkage with Ry-f_sto in the population Rysto. CAPS marker GP122₇₁₈ was tightly linked to the resistance gene and was successfully used to identify Polish and German cultivars expressing extreme resistance to PVY. This indicates that the source of Ry-f_sto has been widely utilized in various potato breeding programs and can be monitored by a diagnostic marker in marker-assisted selection.     

Evidence for utility of the same PCR-based markers for selection of extreme resistance to Potato virus Y controlled by Rysto of Solanum stoloniferum derived from different sources

The tuber‐bearing wild potato species, Solanum stoloniferum, carries a dominant gene, Ry_sto, which confers extreme resistance (ER) to Potato virus Y (PVY). This gene was introgressed to cultivated potato germplasm (Solanum tuberosum) using accessions of S. stoloniferum maintained in European gene banks. It is mainly used in potato breeding programmes in Europe. Ry_sto was recently mapped to potato chromosome XII. However, in this study, a different accession of S. stoloniferum (PI275244; Haw1293) was used as a female parent in a cross to obtain a diploid (2n = 2x = 24) potato population of 112 F1 genotypes. From this accession, ER to PVY has been introgressed to the potato breeding programmes at the International Potato Center (Peru). As expected, ER to PVY was inherited in a dominant, monogenic fashion in the F1 population. Marker‐specific choices of DNA polymerase and adjustments of PCR conditions were made to optimise marker detection. The corresponding gene (Ry_sto) was mapped to the chromosome XII using the previously described and new cleaved amplified polymorphic sequence (CAPS) markers, which are based on the restriction fragment length polymorphism loci GP122 (six markers) and GP269 (one marker), and the simple sequence repeat marker STM0003. Four GP122‐based CAPS markers and STM0003 detected the same genotypes expressing ER to PVY. Because of a few recombinants, that is ER genotypes lacking the markers and the genotypes that react with necrosis but contain the markers, the marker distance from Ry_sto was estimated as 15.2 cM in this F1 population. However, the distance may be less if necrosis was considered an altered response also controlled by Ry_sto. The markers also specifically detected independent European potato cultivars that express ER to PVY derived from S. stoloniferum. Phylogenetic analysis of the sequences amplified from the GP122 locus of S. stoloniferum and potato cultivars further confirmed that the Ry_sto gene from independent accessions of S. stoloniferum can be selected using the same markers and the protocols described in this study.     

Molecular mapping of the potato virus Y resistance gene Rysto in potato

Ry _sto is a dominant gene which confers resistance to potato virus Y (PVY) in potato. We have used bulked segregant analysis of an F₁ tetraploid potato population to identify three AFLP markers linked to and on either side of Ry _sto . The tomato homologue of one of these AFLP markers was assigned to linkage group XI by analysis of an F₂ mapping population of tomato, suggesting that Ry _sto is also on chromosome XI of the potato genome. This map position was confirmed by the demonstration that Ry _sto was linked to markers which had been previously mapped to chromosome XI of the potato genome. Four additional AFLP markers were identified that were closely linked to Ry _sto in a population of 360 segregating progeny of a potato cross between a resistant (Ry _sto ) and a susceptible parent. Two of these markers were on either side of Ry _sto , separated by only a single recombination event. The other two markers co-segregated with Ry _sto . Received: 29 July 1996 / Accepted: 30 August 1996     

Extreme resistance to Potato virus Y in potato carrying the Rysto gene is mediated by a TIR‐NLR immune receptor

Potato virus Y (PVY) is a major potato (Solanum tuberosum L.) pathogen that causes severe annual crop losses worth billions of dollars worldwide. PVY is transmitted by aphids, and successful control of virus transmission requires the extensive use of environmentally damaging insecticides to reduce vector populations. Ry_sto, from the wild relative S. stoloniferum, confers extreme resistance (ER) to PVY and related viruses and is a valuable trait that is widely employed in potato resistance breeding programmes. Ry_sto was previously mapped to a region of potato chromosome XII, but the specific gene has not been identified to date. In this study, we isolated Ry_sto using resistance gene enrichment sequencing (RenSeq) and PacBio SMRT (Pacific Biosciences single‐molecule real‐time sequencing). Ry_sto was found to encode a nucleotide‐binding leucine‐rich repeat (NLR) protein with an N‐terminal TIR domain and was sufficient for PVY perception and ER in transgenic potato plants. Ry_sto‐dependent extreme resistance was temperature‐independent and requires EDS1 and NRG1 proteins. Ry_sto may prove valuable for creating PVY‐resistant cultivars of potato and other Solanaceae crops.     

The Potato virus S resistance gene Ns maps to potato chromosome VIII

The dominant allele Ns confers in potato resistance to Potato virus S (PVS). To identify the chromosomal location of Ns, we mapped the Ns-linked marker SCG17₄₄₈ and the ISSR marker UBC811₆₀₀ to linkage group VIII of the RFLP map of a population that did not segregate for Ns. The map position of the Ns locus on chromosome VIII was confirmed with the detection of linkage between Ns and three RFLP markers, GP126, GP189 and CP16, known to be located in a corresponding region on potato chromosome VIII. PCR-based assays were developed for these RFLP markers. The PCR primers specific for GP126 generated polymorphic products (STS marker). In the case of markers GP189 and CP16, informative polymorphism was revealed in the Ns population after digestion with the restriction enzymes HaeIII and HindIII, respectively. The genetic distance between Ns and the closest CP16 locus was 4.2 cM.     

Extreme resistance to potato virus V in clones of Solanum tuberosum that are also resistant to potato viruses Y and A: evidence for a locus conferring broad-spectrum potyvirus resistance

 Extreme resistance to the potato V potyvirus (PVV) was found in four potato cultivars that contain Ry genes from Solanum stoloniferum. When plants of these cultivars, were inoculated by grafting in shoot tips from PVV-infected tomato plants, necrotic symptoms developed in some cultivars, although a full hypersensitive reaction was not elicited, while other cultivars were symptomless. PVV replication was not detected in any of the inoculated plants by ELISA, an infectivity assay of leaf extracts by manual inoculation to Nicotiana benthamiana indicator plants, or by ‘return grafting’ of shoot tips taken from newly developed shoots of the potato plants to virus-free indicator plants of tomato. These methods readily detected PVV infection in inoculated plants of cv ‘Flourball’, which does not contain an Ry gene and is susceptible, and in cvs ‘Maris Piper’ and ‘Dr Macintosh’, which contain gene Nv conditioning a hypersensitive reaction to inoculation. One of the Ry-containing cultivars, ‘Barbara’, has been previously shown to contain two genes that control extreme resistance, defined as no viral replication in intact plants, to the potyviruses potato viruses Y and A (PVY and PVA). These genes are: Ry _sto , which conditions resistance to PVY and PVA, and gene Ra, which conditions resistance to PVA only. It was found that in genotypes from a progeny of the cross ‘Barbara’ (Ry _sto /Ra)בFlourball’ (ry/ra), extreme resistance to PVV segregated with gene Ry _sto . It is proposed that either gene Ry _sto conditions broad-spectrum extreme resistance to the distinct potyviruses PVY, PVA, and PVV or that Ry _sto represents a family of genetically closely linked genes each controlling resistance to a specific virus. Received: 27 December 1996 / Accepted: 9 June 1997     

Mapping of extreme resistance to PVY (Ry sto) on chromosome XII using anther-culture-derived primary dihaploid potato lines

The inheritance of extreme resistance to PVY (Ry _sto) by a single dominant locus was confirmed by obtaining a 1:1 segregation ratio in a virus inoculation test with 28 resistant (Ryry) to 29 susceptible (ryry) anther culture-derived dihaploid lines (2n=2x=24) from cv. “Assia” (2n=4x=48) having extreme resistance derived from Solanum stoloniferum in simplex constitution (Ryryryry). Twelve Ry _sto markers selected in AFLP assays using bulked segregant analysis were applied to 106 tested potato cultivars from Germany, The Netherlands and Poland and 19 potato cultivars were identified by these markers as extremely resistant to PVY in alignment with phenotypic data. The locus for extreme resistance (Ry _sto) to PVY was mapped on chromosome XII co-segregating with the SSR marker STM0003. The utility of anther-culture derived dihaploid potatoes for genetic marker development was demonstrated. Marker transferability from diploids to tetraploids provides an optimistic potential for marker-assisted selection in potato breeding programs.     

Molecular Characterization of a Phytoplasma Associated with Potato Witches’‐broom Disease in Iran

Potato plants showing symptoms suggestive of potato witches’‐broom disease including witches’‐broom, little leaf, stunting, yellowing and swollen shoots formation in tubers were observed in the central Iran. For phytoplasma detection, Polymerase Chain Reaction (PCR) and nested PCR assays were performed using phytoplasma universal primer pair P1/P7, followed by primer pair R16F2n/R16R2. Random fragment length polymorphism analysis of potato phytoplasma isolates collected from different production areas using the CfoI restriction enzyme indicated that potato witches’‐broom phytoplasma isolate (PoWB) is genetically different from phytoplasmas associated with potato purple top disease in Iran. Sequence analysis of the partial 16S rRNA gene amplified by nested PCR indicated that ‘Candidatus Phytoplasma trifolii’ is associated with potato witches’‐broom disease in Iran. This is the first report of potato witches’‐broom disease in Iran.     

Epidemiological analysis of risk factors for the spread of potato viruses in Switzerland

Virus diseases represent important economic threats to the production of seed potatoes worldwide, yet little quantitative information is available on the relative merits of different measures of virus control applied singly or in combination. In this study, we compiled data from the national seed certification programme on the incidence of Potato Virus Y (PVY) and Potato Leaf‐roll Virus (PLRV) in potato tubers in Switzerland for the years 1990–2009 and used generalised linear models to investigate the influence of key epidemiological factors on infection risk. Results showed that post‐harvest virus incidence increased with initial inoculum levels, with the largest change in infection risk occurring between fields with no inoculum and those with low levels of inoculum. Virus incidence decreased with increasing altitude of fields. Surprisingly, infection risk was considerably lower for imported seed lots even though the model controlled for the effect of inoculum level, potato variety and other confounders. Overall, variety was the most important factor influencing virus risk. The results of the present analysis are useful to fine‐tune decision‐support systems that predict disease risk under different epidemiological scenarios.     

Marker-assisted combination of major genes for pathogen resistance in potato

Closely linked PCR-based markers facilitate the tracing and combining of resistance factors that have been introgressed previously into cultivated potato from different sources. Crosses were performed to combine the Ry _adg gene for extreme resistance to Potato virus Y (PVY) with the Gro1 gene for resistance to the root cyst nematode Globodera rostochiensis and the Rx1 gene for extreme resistance to Potato virus X (PVX), or with resistance to potato wart (Synchytrium endobioticum). Marker-assisted selection (MAS) using four PCR-based diagnostic assays was applied to 110 F1 hybrids resulting from four 2× by 4× cross-combinations. Thirty tetraploid plants having the appropriate marker combinations were selected and tested for presence of the corresponding resistance traits. All plants tested showed the expected resistant phenotype. Unexpectedly, the plants segregated for additional resistance to pathotypes 1, 2 and 6 of S. endobioticum, which was subsequently shown to be inherited from the PVY resistant parents of the crosses. The selected plants can be used as sources of multiple resistance traits in pedigree breeding and are available from a potato germplasm bank.     

Molecular Characterization of Phytoplasmas Associated with Potato Purple Top Disease in Iran

Potato plants with symptoms suggestive of potato purple top disease (PPTD) occurred in the central, western and north‐western regions of Iran. Polymerase chain reaction (PCR) and nested PCR assays were performed using phytoplasma universal primer pair P1/P7 followed by primer pairs R16F2n/R16R2 and fU5/rU3 for phytoplasma detection. Using primer pairs R16F2n/R16R2 and fU5/rU3 in nested PCR, the expected fragments were amplified from 53% of symptomatic potatoes. Restriction fragment length polymorphism (RFLP) analysis using AluI, CfoI, EcoRI, KpnI, HindIII, MseI, RsaI and TaqI restriction enzymes confirmed that different phytoplasma isolates caused PPTD in several Iranian potato‐growing areas. Sequences analysis of partial 16S rRNA gene amplified by nested PCR indicated that ‘Candidatus Phytoplasma solani’, ‘Ca. Phytoplasma astris’ and ‘Ca. Phytoplasma trifolii’ are prevalent in potato plants showing PPTD symptoms in the production areas of central, western and north‐western regions of Iran, although ‘Ca. Phytoplasma solani’ is more prevalent than other phytoplasmas. This is the first report of phytoplasmas related to ‘Ca. Phytoplasma astris’, ‘Ca. Phytoplasma solani’ and ‘Ca. Phytoplasma trifolii’ causing PPTD in Iran.     

Construction of a potato YAC library and identification of clones linked to the disease resistance loci R1 and Gro1

 A yeast artificial chromosome (YAC) library was constructed from high-molecular-weight DNA of potato (Solanum tuberosum). Potato DNA fragments obtained after complete digestion with four different rare-cutter restriction enzymes were cloned using the pYAC-RC vector. The library consists of 21 408 YAC clones with an average insertion size of 140 kb. The frequency of YAC clones having insertions of chloroplast or mitochondrial DNA was estimated to be 0.5% and 0.3%, respectively. The YAC library was screened by PCR with 11 DNA markers detecting single genes or small gene families in the potato genome. YACs for 8 of the 11 markers were detected in the library. Using 2 markers that are linked to the resistance genes R1 and Gro1 of potato, we isolated two individual YAC clones. One of these YAC clones was found to harbour one member of a small family of candidate genes for the nematode resistance gene Gro1. Received : 5 May 1997 / Accepted : 20 May 1997     

The characteristics of action potential and nonselective cation current of cardiomyocytes in rabbit superior vena cava

As a special focus in initiating and maintaining atrial fibrillation (AF), cardiomyocytes in superior vena cava (SVC) have distinctive electrophysiological characters. In this study, we found that comparing with the right atrial (RA) cardiomyoctyes, the SVC cardiomyoctyes had longer APD₉₀ at the different basic cycle lengths; the conduction block could be observed on both RA and SVC cardiomyoctyes. A few of SVC cardiomyoctyes showed slow response action potentials with automatic activity and some others showed early afterdepolarization (EAD) spontaneously. Further more, we found that there are nonselective cation current (I _Ns) in both SVC and RA cardiomyocytes. The peak density of I _Ns in SVC cardiomyocytes was smaller than that in RA cardiomyocytes. Removal of extracellular divalent cation and glucose could increase I _Ns in SVC cardiomyocytes. The agonist or the antagonist of I _Ns may increase or decrease APD. To sum up, some SVC cardiomyocytes possess the ability of spontaneous activity; the difference of transmembrane action potentials between SVC and RA cardiomyocytes is partly because of the different density of I _Ns between them; the agonist or the antagonist of I _Ns can increase or decrease APD leading to the enhancement or reduction of EAD genesis in SVC cardiomyocytes. I _Ns in rabbit myocytes is fairly similar to TRPC3 current in electrophysiological property, which might play an important role in the mechanisms of AF.     

Development of PCR assays diagnostic for RFLP marker alleles closely linked to allelesGro1 andH1, conferring resistance to the root cyst nematodeGlobodera rostochiensis in potato

The use of RFLPs for marker-assisted selection schemes in potato breeding is hampered by the fact that RFLP technology requires good laboratory facilities, technical skills and high financial input. Marker technology based on the polymerase chain reaction (PCR) would facilitate the application of marker-assisted selection. PCR assays have been developed that are diagnostic for RFLP alleles at two marker loci,CP56 andCP113, which are closely linked in coupling to the nematode resistance allelesGro1 on chromosome VII andH1 on chromosome V of potato. By comparing DNA sequences among different marker alleles, point mutations were identified based on which allele-specific oligonucleotides were designed. Using allele-specific oligonucleotides as primers in PCR reactions, single-marker alleles were amplified by which the inheritance ofGro1 andH1 could be followed in crosses of diploid potato genotypes containing the genetically characterizedGro1 orH1 resistance allele. When tested in 136 unrelated tetraploid potato varieties, the marker allele indicative ofGro1 was not correlated with the presence of nematode resistance. The marker allele indicative for theH1 resistance allele was correlated with nematode resistance. It was, however, found in four varieties only of the 136 tested.     

Two allelic or tightly linked genetic factors at the <Emphasis Type="Italic">PLRV.4</Emphasis> locus on potato chromosome XI control resistance to potato leafroll virus accumulation

A novel locus for potato resistance to potato leafroll virus (PLRV) was characterized by inheritance studies and molecular mapping. The diploid parental clone DW 91-1187 was resistant to PLRV accumulation in both inoculated plants and their tuber progeny. The resistance to PLRV accumulation present in DW 91-1187 was not transmitted to any F₁ offspring when crossed with a PLRV susceptible clone. Instead, one half of the F₁ individuals exhibited undetectable amounts of PLRV as determined by ELISA during the primary infection assay, but accumulated PLRV in their tuber progeny plants. The other half was clearly infected both in the inoculated and tuber-born plants. The inheritance of resistance to PLRV accumulation may be explained by a model of two complementary alleles of a single gene (PLRV.4) or by two complementary genes that are closely linked in repulsion phase. Random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) markers linked to the PLRV.4 locus were selected. The two complementary factors were closely linked in coupling phase to the alternative alleles UBC864₆₀₀ and UBC864₈₀₀ of DNA marker UBC864. These markers may be used for marker-assisted selection of genotypes having both factors for resistance to PLRV accumulation. The PLRV.4 locus was mapped to a central position on linkage group XI of the potato molecular map, where no resistance locus has been mapped previously.     

Utility of pentose colorimetric assay for the purification of potato lectin, an arabinose-rich glycoprotein

Potato lectin (Solanum tuberosum agglutinin, STA) is an unusual glycoprotein containing approximately 50% carbohydrates by weight. Of the total carbohydrates, 92% is contributed by L-arabinose, which are O-linked to hydroxyproline residues. The ferric chloride-orcinol assay (Bial’s test), which is specific for pentoses has so far been used only for the determination of free pentoses in biological samples. However, this colorimetric assay has not been used for the detection of pentoses in bound form as it occurs in Solanaceae lectins (potato, tomato, and Datura lectins). Utilizing the pentose colorimetric assay for monitoring the presence of potato lectin, a simpler and shorter procedure for the purification of this lectin from potato tubers has been developed. The yield of potato lectin (1.73 mg per 100 g potato tuber) is twice compared to the yields reported in earlier procedures. Although potato lectin is well known for its specificity to free trimers and tetramers of N-acetyl-D-glucosamine (GlcNAc), it possesses a similar specificity to the core (GlcNAc)₂ of N-linked glycoproteins. The utilization of the pentose assay in the purification of arabinose-rich lectins/agglutinins obviates the necessity for the use of agglutination assay in the various purification steps. The pentose assay appears to be a simple and convenient colorimetric assay for detecting any pentose-rich glycoprotein in plant extracts. The utility of the pentose assay appears to have a significant potential in the detection of hydroxyproline-rich glycoproteins (HRGPs), which are generally O-arabinosylated.     

Novel somatic hybrids (Solanum tuberosum L. + Solanum tarnii) and their fertile BC1 progenies express extreme resistance to potato virus Y and late blight

Solanum tarnii, a wild diploid, tuber-bearing Mexican species belonging to the series Pinnatisecta is highly resistant to Potato virus Y (PVY) and Colorado potato beetle and shows a strong hypersensitive reaction to Phytophthora infestans. Therefore, it could be a potential source of resistance to pathogens for potato breeders. S. tarnii (2n = 2x = 24) is reproductively isolated from tetraploid Solanum tuberosum and hence difficult to include in potato breeding programmes. In this study, interspecific somatic hybrids were produced for the first time by protoplast electrofusion of the cells of potato cv. Delikat (Solanum tuberosum L.) and Solanum tarnii. The hybrid nature of the regenerants was confirmed by simple sequence repeat (SSR) and amplified fragment length polymorphism (AFLP) markers and by morphological analysis and flow cytometry. Selected somatic hybrids were successfully backcrossed with cv. Delikat. Parental lines, primary somatic hybrids and BC₁ progeny were assessed for resistance to PVY by mechanical inoculation, grafting and exposure to viruliferous aphid vectors in the field, and resistance to late blight (P. infestans) by detached leaflet and whole tuber tests. The somatic hybrids showed no symptoms of viral infection and most of them displayed high levels of resistance to foliage blight. The BC₁ progenies were highly resistant to PVY and a few were resistant to foliage blight. Selected hybrids and BC₁ clones were evaluated in the field for tuber quality and tuber yield. Some BC₁ clones produced yields of good quality tubers. The results confirm that both the resistance to PVY and to late blight of S. tarnii is expressed in somatic hybrids, and PVY resistance is transferred to BC₁ progeny, whereas blight resistance is harder to transfer. Somatic hybridization again proved to be a valuable tool for producing pre-breeding material with increased genetic diversity.     

Early detection of white mold caused by <Emphasis Type="Italic">Sclerotinia sclerotiorum</Emphasis> in potato fields using real-time PCR

Potato white mold caused by Sclerotinia sclerotiorum is an important plant disease occurring in many potato-producing areas worldwide. This disease causes considerable yield losses in a large number of potato fields of Hamedan province, Iran. Although several non-chemical methods have been suggested against the pathogen, application of chemicals is considered a major method employed by the growers in Hamedan fields leading to considerable pollution of underground water. Therefore, it is necessary to find techniques to help growers make a more timely decision for chemical application. In this research, a pair of PCR primers was designed according to the nucleotide sequence of a region of DNA amplified by the primer M13. This primer set amplified a 352-bp fragment from all isolates of S. sclerotiorum collected from Hamedan, Iran, and Hangzhou, China. However, this situation was not observed in other tested fungi. A real-time PCR assay was conducted to detect early infection of the pathogen on potato petals. This real-time PCR assay is suggested for growers to make timely decisions on chemical application.