Minimizing ergot infection in hybrid rye by a SMART breeding approach

In Hybridsorten bei Winterroggen führt das Restorergen Rfp1 zu einer vollständigen Restauration der männlichen Fertilität und trägt dazu bei, die Kontamination des Erntegutes mit Mutterkorn zu minimieren. Wir beschreiben Ergebnisse zur Validierung neuer Rfp1-Selektionsmarker an Elitezuchtmaterial des Roggens. Für alle per molekularer Markeranalyse genotypisierten Individuen wurde eine perfekte Übereinstimmung zwischen der postulierten genetischen Konstitution am Restorerlocus Rfp1 und dem Pollenschüttungsvermögen in den Testkreuzungsnachkommenschaften beobachtet. Rekombination zwischen den untersuchten Rfp1-Markern zeigt, dass die neuen Selektionsmarker dazu geeignet sind, rekombinativ verkleinerte, Rfp1-tragende Genomsegmente zu identifizieren. Es konnte gezeigt werden, dass die mit Rfp1 assoziierten, eng gekoppelten Markerallele diagnostisch für Rfp1 sind. Die vorgestellten Ergebnisse belegen, dass die neuen Selektionsmarker eine effiziente Genotypisierung aktueller Elitezuchtlinien im Hinblick auf das Rfp1-Restorergen ermöglichen. Für die mit Rfp1 assoziierten Selektionsmarker konnte in der vorliegenden Studie auch Kopplung mit dem Restorergen Rfc1 nachgewiesen werden. Diese Kopplungsbeziehungen lassen die validierten Marker daher für eine indirekte Selektion von Maintainer-Genotypen des C-Plasmas geeignet erscheinen. Die beobachtete Kopplung von STS-Markern zu Rfp1 bzw. Rfc1 bestätigt frühere Vermutungen, dass in dieser Region auf Chromosom 4RL entweder mehrere Restorergene lokalisiert sind oder es sich bei den betreffenden Restorergenen um Allele desselben Genortes handelt.The restorer gene Rfp1 results in an almost complete restoration of male fertility in hybrid rye varieties and, thus, contributes to minimize harvest contamination with ergot. Here, we report on the validation of recently established Rfp1 markers located on chromosome 4RL in elite breeding lines of rye. The Rfp1 genotypes, as deduced by molecular-marker analysis, perfectly corresponded with the degree of male fertility assessed in test crosses of individual genotpes with male sterile testers. Recombination could be observed between Rfp1 markers indicating their potential to reduce the donor chromosome segment carrying Rfp1. These marker alleles proved to be diagnostic for Rfp1 in current breeding lines. Taken together, results presented qualify the novel markers as efficent molecular tools to assess the restorer gene Rfp1 in elite breeding lines of rye. In addition, we have observed linkage of the Rfp1 markers to the restorer gene Rfc1. Thus, the validated markers should be applicable for marker-assisted selection strategies of maintainer genotypes of the male sterility inducing C cytoplasm, which occur at low frequency in European rye populations as well. The observed linkage of the STS markers to both Rfp1 and Rfc1 supports the assumption that the restorer genes identified on chromosome 4RL are either alleles of a single restorer gene or represent different linked genes located in this sub-genomic region

Improving Yield and Yield Stability in Winter Rye by Hybrid Breeding

Rye is the only cross-pollinating small-grain cereal. The unique reproduction biology results in an exceptional complexity concerning genetic improvement of rye by breeding. Rye is a close relative of wheat and has a strong adaptation potential that refers to its mating system, making this overlooked cereal readily adjustable to a changing environment. Rye breeding addresses the emerging challenges of food security associated with climate change. The systematic identification, management, and use of its valuable natural diversity became a feasible option in outbreeding rye only following the establishment of hybrid breeding late in the 20th century. In this article, we review the most recent technological advances to improve yield and yield stability in winter rye. Based on recently released reference genome sequences, SMART breeding approaches are described to counterbalance undesired linkage drag effects of major restorer genes on grain yield. We present the development of gibberellin-sensitive semidwarf hybrids as a novel plant breeding innovation based on an approach that is different from current methods of increasing productivity in rye and wheat. Breeding of new rye cultivars with improved performance and resilience is indispensable for a renaissance of this healthy minor cereal as a homogeneous commodity with cultural relevance in Europe that allows for comparatively smooth but substantial complementation of wheat with rye-based diets, supporting the necessary restoration of the balance between human action and nature

Studying Stem Rust and Leaf Rust Resistances of Self-Fertile Rye Breeding Populations

Stem rust (SR) and leaf rust (LR) are currently the two most important rust diseases of cultivated rye in Central Europe and resistant cultivars promise to prevent yield losses caused by those pathogens. To secure long-lasting resistance, ideally pyramided monogenic resistances and race-nonspecific resistances are applied. To find respective genes, we screened six breeding populations and one testcross population for resistance to artificially inoculated SR and naturally occurring LR in multi-environmental field trials. Five populations were genotyped with a 10K SNP marker chip and one with DArTseqTM. In total, ten SR-QTLs were found that caused a reduction of 5–17 percentage points in stem coverage with urediniospores. Four QTLs thereof were mapped to positions of already known SR QTLs. An additional gene at the distal end of chromosome 2R, Pgs3.1, that caused a reduction of 40 percentage points SR infection, was validated. One SR-QTL on chromosome 3R, QTL-SR4, was found in three populations linked with the same marker. Further QTLs at similar positions, but from different populations, were also found on chromosomes 1R, 4R, and 6R. For SR, additionally seedling tests were used to separate between adult-plant and all-stage resistances and a statistical method accounting for the ordinal-scaled seedling test data was used to map seedling resistances. However, only Pgs3.1 could be detected based on seedling test data, even though genetic variance was observed in another population, too. For LR, in three of the populations, two new large-effect loci (Pr7 and Pr8) on chromosomes 1R and 2R were mapped that caused 34 and 21 percentage points reduction in leaf area covered with urediniospores and one new QTL on chromosome 1R causing 9 percentage points reduction