Eva Zyprian

Genetic diversity and population structure assessed by SSR and SNP markers in a large germplasm collection of grape

BackgroundThe economic importance of grapevine has driven significant efforts in genomics to accelerate the exploitation of Vitis resources for development of new cultivars. However, although a large number of clonally propagated accessions are maintained in grape germplasm collections worldwide, their use for crop improvement is limited by the scarcity of information on genetic diversity, population structure and proper phenotypic assessment. The identification of representative and manageable subset of accessions would facilitate access to the diversity available in large collections. A genome-wide germplasm characterization using molecular markers can offer reliable tools for adjusting the quality and representativeness of such core samples.ResultsWe investigated patterns of molecular diversity at 22 common microsatellite loci and 384 single nucleotide polymorphisms (SNPs) in 2273 accessions of domesticated grapevine V. vinifera ssp. sativa, its wild relative V. vinifera ssp. sylvestris, interspecific hybrid cultivars and rootstocks. Despite the large number of putative duplicates and extensive clonal relationships among the accessions, we observed high level of genetic variation. In the total germplasm collection the average genetic diversity, as quantified by the expected heterozygosity, was higher for SSR loci (0.81) than for SNPs (0.34). The analysis of the genetic structure in the grape germplasm collection revealed several levels of stratification. The primary division was between accessions of V. vinifera and non-vinifera, followed by the distinction between wild and domesticated grapevine. Intra-specific subgroups were detected within cultivated grapevine representing different eco-geographic groups. The comparison of a phenological core collection and genetic core collections showed that the latter retained more genetic diversity, while maintaining a similar phenotypic variability.ConclusionsThe comprehensive molecular characterization of our grape germplasm collection contributes to the knowledge about levels and distribution of genetic diversity in the existing resources of Vitis and provides insights into genetic subdivision within the European germplasm. Genotypic and phenotypic information compared in this study may efficiently guide further exploration of this diversity for facilitating its practical use.

Genome diversity and gene haplotypes in the grapevine (Vitis vinifera L.), as revealed by single nucleotide polymorphisms

EST (expressed sequence tags) sequencing, SNP (single nucleotide polymorphisms) development and haplotype assessment are powerful tools for the support of marker-assisted selection. The grapevine genome is currently being scavenged in our laboratory using an EST-SNP approach. Nine parental genotypes, used to create five inter- or intra-specific hybrids, have been tested to evaluate the degree of polymorphism between Vitis vinifera, Vitis riparia and a further intraspecific hybrid, measuring their nucleotide diversity. The SNPs were analysed on cDNA sequences of 4 functional classes of genes based on homology with genes present in a public database: sugar metabolism, cell signalling, anthocyanin metabolism and defence related. Primer pairs were deduced and used to amplify corresponding genomic sequences. Almost 12,000 bp of DNA have been scanned revealing differences among genotypes of up to 247 SNPs, with the highest rate of one SNP occurring every 78 bp when clones of different Vitis species are compared. Re-sequencing allowed the definition of haplotypes in the nine genotypes studied and these were confirmed by analysing segregating populations. The efficiency of SSCP, in comparison with re-sequencing, was considered for 25 gene fragments of the same 9 genotypes.

QTL analysis of flowering time and ripening traits suggests an impact of a genomic region on linkage group 1 in Vitis.

In the recent past, genetic analyses of grapevine focused mainly on the identification of resistance loci for major diseases such as powdery and downy mildew. Currently, breeding programs make intensive use of these results by applying molecular markers linked to the resistance traits. However, modern genetics also allows to address additional agronomic traits that have considerable impact on the selection of grapevine cultivars. In this study, we have used linkage mapping for the identification and characterization of flowering time and ripening traits in a mapping population from a cross of V3125 (‘Schiava Grossa’ × ‘Riesling’) and the interspecific rootstock cultivar ‘Börner’ (Vitis riparia × Vitis cinerea). Comparison of the flowering time QTL mapping with data derived from a second independent segregating population identified several common QTLs. Especially a large region on linkage group 1 proved to be of special interest given the genetic divergence of the parents of the two populations. The proximity of the QTL region contains two CONSTANS-like genes. In accordance with data from other plants such as Arabidopsis thaliana and Oryza sativa, we hypothesize that these genes are major contributors to control the time of flowering in Vitis.

Marker Development for Important Grapevine Traits by Genetic Diversity Studies and Investigation of Differential Gene Expression

Grapevine (Vitis vinifera L.) needs to be improved for disease resistance to allow the development of sustainable viticulture. Resistance genes from American or Asian wild relatives acting against downy and powdery mildew pathogens have to be introduced by cross breeding. Physical attributes like the density of fruit clusters also contribute to the variability of susceptibility and need to be considered in breeding.

QTL ANALYSIS OF PATHOGEN RESISTANCE FACTORS AND RIPENING TIME TRAITS IN A GENETIC MAP FROM GRAPEVINE BREEDING LINE GF.GA-47-42 CROSSED TO 'VILLARD BLANC'

Marker-assisted selection is an important tool of current grapevine breeding which aims to improve cultivars for more sustainable viticulture. Markers genetically linked to traits of interest are hence required. These can be identified by QTL (quantitative trait loci) analysis scanning genetic maps elaborated from controlled crosses for marker genotypes correlating with segregating phenotypes. Major traits of interest are resistances to pathogens like powdery and downy mildew (Erysiphe necator resp. Plasmopara viticola) of leaves and fruits. In addition, phenological traits have recently acquired special attention. Breeders wish to select grapes with a better defined ?window? of ripening time as ripening behavior affects both pathogen susceptibility and fruit quality. Ripening time needs to be considered within the context of the climate change debate. To identify genomic regions carrying loci affecting resistance traits and ripening time we constructed a genetic map using 151 individuals from the cross of grapevine breeding line Gf.GA-47-42 (?Bacchus? × ?Seyval?) with ?Villard blanc? (?Seibel 6468? × ?Subereux?). Both parental lines are resistant to powdery and downy mildew and vary considerably in ?veraison? time as an indicator of ripening. While Gf.GA-47-42 is rather early, ?Villard blanc? exhibits middle to late ?veraison? and this trait segregates clearly in the cross. Linkage/recombination analysis for map construction was based on more than 350 simple sequence repeat (SSR)-derived markers. Many of these loci were newly extracted from the Vitis reference genome sequence of PN40024 (http://www.genoscope.cns.fr/externe/GenomeBrowser/Vitis/). In addition, the mapping included 210 newly developed SNP (single nucleotide polymorphisms) markers. A subset of these was analyzed with two different techniques permitting to assess the reliability of SNP genotyping with both methods. The resulting map was scanned for QTL influencing powdery and downy mildew disease resistance and the time of ?veraison?. Several major QTL were identified.

Genetic mapping of acidity-relevant traits

Organic acids are an important determinant for wine quality. A mapping population from a cross between the breeding strain Gf.Ga-47-42 (?Bacchus? × ?Seyval?) and the cultivar ?Villard Blanc? (?Seibel 6468? × ?Subereux?) was investigated in detail regarding differences in the acidity level of the must. The acidity profile was recorded in three consecutive years under field conditions at Geilweilerhof (Palatinate, Germany). The obtained data were subjected to QTL analysis in order to identify genetic regions involved in acidity regulation. Investigated traits included total acidity, tartaric and malic acid levels as well as pH values in musts and wines. The identification of genomic regions which carry genes with a significant influence on these traits will give new insights into the acidity characteristics of grape cultivars. Newly identified trait-linked molecular markers are intended for application in marker-assisted selection (MAS) during the breeding process. This will contribute to accelerate grapevine breeding by early selection for quality traits.

New insights in the molecular structure and function of the resistance locus Ren3 against powdery mildew ( Erysiphe necator ) from the grapevine cultivar 'Regent'

The project is dealing with the improvement of a universal pneumatic seeder which is suitable for sowing a wide range of different seeds in order to decrease particulate emissions of seed dressings. Aim of the project is to identify leakages in the pneumatic system in order to develop opportunities for the subsequent improvement of existing equipment to fulfill the high demands of user and environmental protection. Pneumatic seeders are characterized by a central, funnelshaped hopper. The batch feeder being an airlock and dosing feeder is located in the outlet of the seeder. The metered seed is fed into the air stream and transported to the sowing distributor by a conveying air stream.Due to climatic change, phenology traits are becoming increasingly important in grapevine breeding, since a premature flowering and ripening time could be observed for grapevine in the last decades. However, knowledge about these traits is still limited as they are genetically very complex and highly influenced by environmental factors. The analysis of the genetic basis of flowering time therefore will enable the development of tightly linked molecular markers useful for markerassisted selection of especially late flowering breeding lines.One recently occurred invasive insect pest has caught the attention for investigating biological control mechanisms and systems: The spotted wing drosophila (SWD, Drosophila suzukii Matsumura) is endemic in East China and Japan but has been introduced to the western hemisphere about 10 years ago and has been found in Europe since 2009. Nowadays, it has emerged to one of the most harmful pests to commercially grown fruit plants like stone fruits and nearly all kind of berries while it prefers ripe and overripe fruits. Our intention is to investigate the possible usage of natural antagonists for biological control. Therefore, we examine the natural load of parasites and pathogens (i.e. fungi, bacteria, viruses, microsporidia and protista) in fruit flies, isolate them and re-infect lab populations of D. suzukii for investigating the antagonistic potential. Furthermore, we will integrate the fruit pest codling moth (Cydia pomonella), which is an ongoing problem in apple orchards also because the pest develops resistance against commercially available insecticides. The long-term aim is to establish a stable system for pathogen detection that can be used for rapid identification of microbial antagonists in natural populations.Two main problems have to be considered in the development of control agents against the Fire Blight pathogen Erwinia amylovora: First, the ability of exponential growth leads to high cell densities in a short amount of time. Second, the most critical phase of Fire Blight infection occurs during blossoming, when the pathogen is transported to open flowers by various insects. To prevent infection, it is important to avoid invasion inside the plants tissue by interfering with growth of E. amylovora cells.The entomopathogenic fungus Isaria fumosorosea, formerly known as Paecilomyces fumosoroseus, has got a relatively wide host range. Within the scope of the EU project BIOCOMES investigations were done to validate the use of I. fumosorosea as a BCA against several pest insects. Under laboratory conditions it could be shown that I. fumosorosea seems to be a suitable BCA against Bemisia tabaci (silverleaf whitefly) and Spodoptera exigua (beet armyworm).Since the last two decades a number of fingerprinting methods have been developed to analyze microbial communities and their dynamics, including Terminal Restriction Fragment Length Polymorphism (T-RFLP), Length Heterogeneity-Polymerase Chain Reaction (LHPCR) and Automated Ribosomal Intergenic Spacer Analysis (ARISA). Because the latter provides a quick and cheap way together with high accuracy, we have chosen this method to investigate the fungal communities on grapevine, wood, leaves and berries.Saoussen Ben Tiba, Andreas Larem, Eva Fritsch, Karin Undorf-Spahn, Asma Laarif, Sami Fattouch, Johannes A. Jehle 1 Julius Kuhn-Institut, Institute for Biological Control, Darmstadt, Germany 2 Regional Center for Agriculture and Biological Agriculture, Chott Meriem, Tunisia 3 National Institute for applied technological Science Tunis (INSAT), Carthage University, Tunisia Email of corresponding author: saoussen.ben.tiba@jki.bund.deOne promising approach to a more environmentally friendly viticulture is growing fungus resistant cultivars with the novel cultivation method of the minimal pruning of trellis trained grapevines (MPTS). This practice reduces the tremendous amounts of fungicides needed to protect traditional cultivars and is expected to increase biodiversity compared to vineyards with traditional trellis trained grapevines (TS).Meiosis as the specialized cell division of sexual reproduction plays a crucial role in the exchange and reorganization of genetic material between two individuals by dividing the chromosome set in half and forming gametes. Even though in the last years major findings in the field of meiosis have been achieved, especially in plants, some key questions remain concealed. For a proper meiosis the initiation of double strand breaks (DSBs) during early prophase I is essential. Without DSBs no physical connection can occur between homologous chromosomes and recombination, pairing, and crossing over are excluded. So far in all analyzed eukaryotes SPO11, a meiosis specific transesterase, is the key enzyme inducing DSBs. But other than in animals and fungi where a single SPO11 is sufficient, plants need at least two different SPO11, referred to as SPO11-1 and SPO11-2, for proper meiosis. In Arabidopsis thaliana both have crucial functions and are essential in a functional form for the induction of meiotic DSBs as single knock out mutants are leading to near sterility by random chromosome distribution. Despite the same function of the homologs SPO111 and -2, the identity between both proteins is quite low. Homology of the orthologous SPO11 from different organisms is much higher. By exchanging SPO11-1 and -2 in Arabidopsis by their orthologs from various organisms we could demonstrate a species specific function of each SPO11, as a functional complementation of sterility could only be achieved with SPO11 from closely related species from the Brassicaceae. By exchanging non conserved regions between SPO11-1 and -2 of Arabidopsis we additionally could show a sequence specific function for each SPO11, as a functional rescue could not be achieved with all chosen regions. Interestingly, we could reveal a specific pattern of aberrant spliced isoforms for each SPO11 which are also sequence as well as species specific. By producing antibodies against AthSPO11-1 and -2 we were able to analyze for the first time the binding of SPO11-2 onto the DNA and perform co-immunolocalization studies with SPO11-1 and -2.European Stone Fruit Yellows (ESFY) is one of the most serious diseases in European fruit production. Infected Prunus cultivars yield poorly and lead to high economic losses. ESFY is caused by a specialized bacterium located in the phloem tissue of Prunus ssp., the Phytoplasma ‘Candidatus Phytoplasma prunorum’. It is spread by the phloemfeeding plum psyllid (Cacopsylla pruni) which acquires the bacterium by feeding on infected plants and is able to transmit it to healthy plants.Leaf rust caused by Puccinia triticina can cause yield losses up to 60 % and is the most common rust disease of wheat in the world. Vertical leaf rust resistance genes (Lr-genes) have been introduced in cultivars. Many of these resistances are broken down by virulent pathotypes. Horizontal resistances which are independent from races of a pathogen are known but show a quantitative characteristic which is carried by a few cultivars.

The resistance locus Ren3 and its powdery mildew isolate-specificity

The project is dealing with the improvement of a universal pneumatic seeder which is suitable for sowing a wide range of different seeds in order to decrease particulate emissions of seed dressings. Aim of the project is to identify leakages in the pneumatic system in order to develop opportunities for the subsequent improvement of existing equipment to fulfill the high demands of user and environmental protection. Pneumatic seeders are characterized by a central, funnelshaped hopper. The batch feeder being an airlock and dosing feeder is located in the outlet of the seeder. The metered seed is fed into the air stream and transported to the sowing distributor by a conveying air stream.Due to climatic change, phenology traits are becoming increasingly important in grapevine breeding, since a premature flowering and ripening time could be observed for grapevine in the last decades. However, knowledge about these traits is still limited as they are genetically very complex and highly influenced by environmental factors. The analysis of the genetic basis of flowering time therefore will enable the development of tightly linked molecular markers useful for markerassisted selection of especially late flowering breeding lines.One recently occurred invasive insect pest has caught the attention for investigating biological control mechanisms and systems: The spotted wing drosophila (SWD, Drosophila suzukii Matsumura) is endemic in East China and Japan but has been introduced to the western hemisphere about 10 years ago and has been found in Europe since 2009. Nowadays, it has emerged to one of the most harmful pests to commercially grown fruit plants like stone fruits and nearly all kind of berries while it prefers ripe and overripe fruits. Our intention is to investigate the possible usage of natural antagonists for biological control. Therefore, we examine the natural load of parasites and pathogens (i.e. fungi, bacteria, viruses, microsporidia and protista) in fruit flies, isolate them and re-infect lab populations of D. suzukii for investigating the antagonistic potential. Furthermore, we will integrate the fruit pest codling moth (Cydia pomonella), which is an ongoing problem in apple orchards also because the pest develops resistance against commercially available insecticides. The long-term aim is to establish a stable system for pathogen detection that can be used for rapid identification of microbial antagonists in natural populations.Two main problems have to be considered in the development of control agents against the Fire Blight pathogen Erwinia amylovora: First, the ability of exponential growth leads to high cell densities in a short amount of time. Second, the most critical phase of Fire Blight infection occurs during blossoming, when the pathogen is transported to open flowers by various insects. To prevent infection, it is important to avoid invasion inside the plants tissue by interfering with growth of E. amylovora cells.The entomopathogenic fungus Isaria fumosorosea, formerly known as Paecilomyces fumosoroseus, has got a relatively wide host range. Within the scope of the EU project BIOCOMES investigations were done to validate the use of I. fumosorosea as a BCA against several pest insects. Under laboratory conditions it could be shown that I. fumosorosea seems to be a suitable BCA against Bemisia tabaci (silverleaf whitefly) and Spodoptera exigua (beet armyworm).Since the last two decades a number of fingerprinting methods have been developed to analyze microbial communities and their dynamics, including Terminal Restriction Fragment Length Polymorphism (T-RFLP), Length Heterogeneity-Polymerase Chain Reaction (LHPCR) and Automated Ribosomal Intergenic Spacer Analysis (ARISA). Because the latter provides a quick and cheap way together with high accuracy, we have chosen this method to investigate the fungal communities on grapevine, wood, leaves and berries.Saoussen Ben Tiba, Andreas Larem, Eva Fritsch, Karin Undorf-Spahn, Asma Laarif, Sami Fattouch, Johannes A. Jehle 1 Julius Kuhn-Institut, Institute for Biological Control, Darmstadt, Germany 2 Regional Center for Agriculture and Biological Agriculture, Chott Meriem, Tunisia 3 National Institute for applied technological Science Tunis (INSAT), Carthage University, Tunisia Email of corresponding author: saoussen.ben.tiba@jki.bund.deOne promising approach to a more environmentally friendly viticulture is growing fungus resistant cultivars with the novel cultivation method of the minimal pruning of trellis trained grapevines (MPTS). This practice reduces the tremendous amounts of fungicides needed to protect traditional cultivars and is expected to increase biodiversity compared to vineyards with traditional trellis trained grapevines (TS).Meiosis as the specialized cell division of sexual reproduction plays a crucial role in the exchange and reorganization of genetic material between two individuals by dividing the chromosome set in half and forming gametes. Even though in the last years major findings in the field of meiosis have been achieved, especially in plants, some key questions remain concealed. For a proper meiosis the initiation of double strand breaks (DSBs) during early prophase I is essential. Without DSBs no physical connection can occur between homologous chromosomes and recombination, pairing, and crossing over are excluded. So far in all analyzed eukaryotes SPO11, a meiosis specific transesterase, is the key enzyme inducing DSBs. But other than in animals and fungi where a single SPO11 is sufficient, plants need at least two different SPO11, referred to as SPO11-1 and SPO11-2, for proper meiosis. In Arabidopsis thaliana both have crucial functions and are essential in a functional form for the induction of meiotic DSBs as single knock out mutants are leading to near sterility by random chromosome distribution. Despite the same function of the homologs SPO111 and -2, the identity between both proteins is quite low. Homology of the orthologous SPO11 from different organisms is much higher. By exchanging SPO11-1 and -2 in Arabidopsis by their orthologs from various organisms we could demonstrate a species specific function of each SPO11, as a functional complementation of sterility could only be achieved with SPO11 from closely related species from the Brassicaceae. By exchanging non conserved regions between SPO11-1 and -2 of Arabidopsis we additionally could show a sequence specific function for each SPO11, as a functional rescue could not be achieved with all chosen regions. Interestingly, we could reveal a specific pattern of aberrant spliced isoforms for each SPO11 which are also sequence as well as species specific. By producing antibodies against AthSPO11-1 and -2 we were able to analyze for the first time the binding of SPO11-2 onto the DNA and perform co-immunolocalization studies with SPO11-1 and -2.European Stone Fruit Yellows (ESFY) is one of the most serious diseases in European fruit production. Infected Prunus cultivars yield poorly and lead to high economic losses. ESFY is caused by a specialized bacterium located in the phloem tissue of Prunus ssp., the Phytoplasma ‘Candidatus Phytoplasma prunorum’. It is spread by the phloemfeeding plum psyllid (Cacopsylla pruni) which acquires the bacterium by feeding on infected plants and is able to transmit it to healthy plants.Leaf rust caused by Puccinia triticina can cause yield losses up to 60 % and is the most common rust disease of wheat in the world. Vertical leaf rust resistance genes (Lr-genes) have been introduced in cultivars. Many of these resistances are broken down by virulent pathotypes. Horizontal resistances which are independent from races of a pathogen are known but show a quantitative characteristic which is carried by a few cultivars.

Steps to unravel the sequence of the resistance locus Ren3 against powdery mildew (Erysiphe necator) originally identified in the grapevine cultivar 'Regent'

Powdery mildew is one of the most devastating diseases of grapevine (Vitis vinifera L). The disease is caused by Erysiphe necator Schw. (syn. Uncinula necator (Schw.) Burr, anamorph Oidium tuckeri Berk.), an ascomycete fungus, which was introduced from North America to Europe in 1845. The traditional European cultivars are highly susceptible to the fungus and still today huge amounts of fungicides are necessary to defeat the pathogen.Plasmopara viticola is an obligate biotrophic oomycete which infects all cultivars of the European grapevine (Vitis vinifera). In contrast to V. vinifera the native American species such as V. labrusca or V. riparia are resistant to the pathogen. In the 19 century P. viticola was unintendedly imported from Northern America to Europe, where it encountered with the highly susceptible European grapevines. The oomycete infiltrates the host tissue through the stomata of leaves, flowers and small berries. Though infection can happen throughout the whole vegetation phase, it bears the highest potential of severe yield losses at time of flowering. Once stomata penetration occurs, the susceptible European vines fail to stop the proceeding infection. However, American vine species have gained the necessary traits to stop or at least slow down host internal growth of P. viticola. Though resistance mechanisms are not yet fully understood, it is assumed that secondary metabolites are involved as active components or signaling compounds. Thus, we screened leaf metabolites of eleven grapevine genotypes with different P. viticola resistance traits. Leaf homogenates were analyzed by GC-MS and LCMS to cover the patterns of volatile as well as non-volatile metabolites. Nontargeted chemometrical data processing was used to obtain metabolite fingerprints of grapevine leaves at the plant developmental stage of flowering. Leaf metabolites of the eleven tested genotypes were analyzed in two subsequent years. Principal component analyses (PCA) of the metabolite fingerprints arrange all susceptible V. vinifera cultivars close to each other. Interspecific genotypes and the resistant V. labrusca samples are positioned in close proximity, and the V. riparia samples segregate from both groups. These observations apply to the fingerprints of volatiles as well as of non-volatiles. PCA generates groups which divide the grapevine genotypes into their biological filiation which is at the same time a separation into susceptible and resistant genotypes. Resistance traits of the genotypes were correlated with their metabolite profiles. Spearman rank correlation isolated all together four different metabolites with high correlation coefficient moduli in both of the two subsequent years. These were methyl salicylate, (E)beta-ocimene and two known-unknown compounds. Further identification with approved mass spectrometry tools are in progress. Whereas only methyl salicylate could be found in intense correlation with high resistance traits, the other three where strongly correlated with susceptibility.Post-harvest, plant products are stored for a certain time period to ensure a continuous and season-independent food supply. During storage, the goods are highly vulnerable to infestation by microorganisms and insects. In case of a mass propagation of a stored product pest, the means of choice are inorganic insecticidal gases and contact insecticides. Due to the cumulated occurrence of resistances against commonly used pesticides as well as a growing awareness on the environmental risks and consequences of intensive pesticide use, biological and biotechnical approaches to counter stored product pests experience an increasing demand.