Genetische Kartierung und QTL-Analyse agronomischer Eigenschaften der Weinrebe unter besonderer Berücksichtigung der Pilzresistenz

153 Nachkommen einer Kreuzung aus der pilzresistenten Rebsorte ‘Regent‘ und ‘Lemberger‘ als klassischer pilzsensitiver Sorte zeigen quantitative Merkmalsvariation bezüglich der Resistenz gegen Plasmopara viticola und Uncinula necator sowie für weitere Eigenschaften, die z.B. das Eintreten der Beerenreife betreffen. Auf dem Weg über die genetische Kartierung mit molekularen Markern und der Lokalisierung von QTL-Effekten konnten Hinweise auf weinbaulich relevante Genomregionen gewonnen werden; dies liefert z.B. die Basis für markergestützte Selektion bei Zuchtvorhaben mit dem Resistenzträger ‘Regent’ (vgl. auch FISCHER et al., 2004). Ein Major-QTL für die Resistenz gegen den Echten Mehltau Uncinula necator sowie zwei Major QTL für die Resistenz gegen den Erreger des Falschen Mehltau, Plasmopara viticola, traten mit hoher Signifikanz auf drei verschiedenen Kopplungsgruppen von ‘Regent‘ auf. Auch Regionen mit Relevanz für das Eintreten der Beerenreife wurden beschrieben. Über die Isolierung, Sequenzierung und anschließende Analyse einzelner Markerfragmente mit Methoden der Bioinformatik ist es gelungen, ein putatives T10P12.4-Ortholog der Weinrebe (ein thioredoxinähnliches Protein) in enger Kopplung zu einem Major-QTL-Maximum für Plasmopara viticola-Resistenz zu identifizieren, das als Kandidat für die Beteiligung an der Pathogenantwort in Frage kommt. Es konnte exemplarisch gezeigt werden, dass die eingesetzten Methoden der Kartierung und QTL-Analyse unter Verwendung PCR-basierter Markertypen wie SSR und AFLP und einer beschleunigten Analyse über computergestützte Kapillargelelektrophorese in vertretbarem Zeitrahmen bis zur Isolation potentieller Schlüsselgene führen können. Die grundsätzliche Eignung der QTL-Analyse als effizientes Werkzeug gezielter Züchtungsplanung für den Weinbau bestätigte sich. Ihre Anwendung im Rahmen der vorliegenden Dissertation hat die Basis für die Nutzung von QTL-Information bei dem Vergleich etablierter und der Entwicklung neuer Sorten gelegt und zum Verständnis von Prozessen beigetragen, die den betrachteten Eigenschaften wie der Pilzresistenz möglicherweise zu Grunde liegen. Ein großer Teil der gewonnenen Daten bringt auch die Untersuchungen anderer Kultivare voran und ist intervarietal übertragbar. Darüber hinaus haben sich Chancen für vergleichende Studien zwischen der Weinrebe einerseits und der Modellpflanze Arabidopsis thaliana sowie weiteren Kulturpflanzen andererseits abgezeichnet. Die Hinweise auf die zentrale Rolle und universelle Natur des Redox-Signalling haben interessante Perspektiven zum Verständnis organismenübergreifender physiologischer Zusammenhänge eröffnet. Dies betrifft z.B. auch die Reaktion auf Verwundung oder die Pathogenantwort.

Gene expression analysis in ‘Candidatus Phytoplasma mali’-resistant and -susceptible Malus genotypes

Apple proliferation (AP) disease is the most important graft-transmissible and vector-borne disease of apple in Europe. ‘Candidatus Phytoplasma mali’ (Ca. P. mali) is the causal agent of AP. Apple (Malus x domestica) and other Malus species are the only known woody hosts. In European apple orchards, the cultivars are mainly grafted on one rootstock, M. x domestica cv. M9. M9 like all other M. x domestica cultivars is susceptible to ‘Ca. P. mali’. Resistance to AP was found in the wild genotype Malus sieboldii (MS) and in MS-derived hybrids but they were characterised by poor agronomic value. The breeding of a new rootstock carrying the resistant and the agronomic traits was the major aim of a project of which this work is a part. The objective was to shed light into the unknown resistance mechanism. The plant-phytoplasma interaction was studied by analysing differences between the ‘Ca. P. mali’-resistant and -susceptible genotypes related to constitutively expressed genes or to induced genes during infection. The cDNA-Amplified Fragment Length Polymorphism (cDNA-AFLP) technique was employed in both approaches. Differences related to constitutively expressed genes were identified between two ‘Ca. P. mali’-resistant hybrid genotypes (4551 and H0909) and the ‘Ca. P. mali’-susceptible M9. 232 cDNA-AFLP bands present in the two resistant genotypes but absent in the susceptible one were isolated but several different products associated to each band were found. Therefore, two different macroarray hybridisation experiments were performed with the cDNA-AFLP fragments yielding 40 sequences encoding for genes of unknown function or a wide array of functions including plant defence. In the second approach, individuation and analysis of the induced genes was carried out exploiting an in vitro system in which healthy and ‘Ca. P. mali’-infected micropropagated plants were maintained under controlled conditions. Infection trials using in vitro grafting of ‘Ca. P. mali’ showed that the resistance phenotype could be reproduced in this system. In addition, ex vitro plants were generated as an independent control of the genes differentially expressed in the in vitro plants. The cDNA-AFLP analysis in in vitro plants yielded 63 bands characterised by over-expression in the infected state of both the H0909 and MS genotypes. The major part (37 %) of the associated sequences showed homology with products of unknown function. The other genes were involved in plant defence, energy transport/oxidative stress response, protein metabolism and cellular growth. Real-time qPCR analysis was employed to validate the differential expression of the genes individuated in the cDNA-AFLP analysis. Since no internal controls were available for the study of the gene expression in Malus, an analysis on housekeeping genes was performed. The most stably expressed genes were the elongation factor-1 α (EF1) and the eukaryotic translation initiation factor 4-A (eIF4A). Twelve out of 20 genes investigated through qPCR were significantly differentially expressed in at least one genotype either in in vitro plants or in ex vitro plants. Overall, about 20% of the genes confirmed their cDNA-AFLP expression pattern in M. sieboldii or H0909. On the contrary, 30 % of the genes showed down-regulation or were not differentially expressed. For the remaining 50 % of the genes a contrasting behaviour was observed. The qPCR data could be interpreted as follows: the phytoplasma infection unbalance photosynthetic activity and photorespiration down-regulating genes involved in photosynthesis and in the electron transfer chain. As result, and in contrast to M. x domestica genotypes, an up-regulation of genes of the general response against pathogens was found in MS. These genes involved the pathway of H2O2 and the production of secondary metabolites leading to the hypothesis that a response based on the accumulation of H2O2 in MS would be at the base of its resistance. This resembles a phenomenon known as “recovery” where the spontaneous remission of the symptoms is observed in old susceptible plants but occurring in a stochastic way while the resistance in MS is an inducible but stable feature. As additional product of this work three cDNA-AFLP-derived markers were developed which showed independent distribution among the seedlings of two breeding progenies and were associated to a genomic region characteristic of MS. These markers will contribute to the development of molecular markers for the resistance as well as to map the resistance on the Malus genome.