Your search keyword '"Kai P. Voss-Fels"' showing total 21 results

1. A chickpea genetic variation map based on the sequencing of 3,366 genomes

Author

Pallavi Sinha, Sushil K. Chaturvedi, Wallace Cowling, Guangyi Fan, Annapurna Chitikineni, Mohammad Yasin, Anne Céline Thuillet, Yves Vigouroux, Shiv Kumar, Aladdin Hamwieh, Eric von Wettberg, Amit Deokar, Himabindu Kudapa, Abhishek Rathore, Ben J. Hayes, Khela Ram Soren, Vikas K. Singh, Yue Wang, G. P. Dixit, Mahendar Thudi, Reka Howard, Jian Wang, Kadambot H. M. Siddique, Diego Jarquin, Prasad Bajaj, Eric Lyons, David Edwards, Aleena Francis, Trilochan Mohapatra, José Crossa, Bunyamin Tar’an, Shuai Sun, Motisagar S. Pithia, Debasis Chattopadhyay, Hari D. Upadhyaya, Narendra Singh, Vanika Garg, Aamir W. Khan, Swapan K. Datta, Manish Roorkiwal, Rajeev K. Varshney, Ramu Punna, Philippe Cubry, Xiao Du, Laurent Gentzbittel, Henry T. Nguyen, Kai P. Voss-Fels, Muneendra K. Singh, Servejeet Singh, Jeffrey L. Bennetzen, Chellapilla Bharadwaj, Xin Liu, Huanming Yang, Xun Xu, Cécile Ben, Vinod Valluri, and Lee T. Hickey

Subjects

Crops, Agricultural, Whole genome sequencing, Germplasm, Agricultural genetics, Genetic diversity, Multidisciplinary, Genetic Variation, Genomics, Sequence Analysis, DNA, Biology, Polymorphism, Single Nucleotide, Cicer, Article, Plant breeding, Natural variation in plants, Haplotypes, Evolutionary biology, Genetic variation, Structural variation, Domestication, Genome, Plant, Selection (genetic algorithm)

Abstract

Zero hunger and good health could be realized by 2030 through effective conservation, characterization and utilization of germplasm resources1. So far, few chickpea (Cicer arietinum) germplasm accessions have been characterized at the genome sequence level2. Here we present a detailed map of variation in 3,171 cultivated and 195 wild accessions to provide publicly available resources for chickpea genomics research and breeding. We constructed a chickpea pan-genome to describe genomic diversity across cultivated chickpea and its wild progenitor accessions. A divergence tree using genes present in around 80% of individuals in one species allowed us to estimate the divergence of Cicer over the last 21 million years. Our analysis found chromosomal segments and genes that show signatures of selection during domestication, migration and improvement. The chromosomal locations of deleterious mutations responsible for limited genetic diversity and decreased fitness were identified in elite germplasm. We identified superior haplotypes for improvement-related traits in landraces that can be introgressed into elite breeding lines through haplotype-based breeding, and found targets for purging deleterious alleles through genomics-assisted breeding and/or gene editing. Finally, we propose three crop breeding strategies based on genomic prediction to enhance crop productivity for 16 traits while avoiding the erosion of genetic diversity through optimal contribution selection (OCS)-based pre-breeding. The predicted performance for 100-seed weight, an important yield-related trait, increased by up to 23% and 12% with OCS- and haplotype-based genomic approaches, respectively., Whole-genome sequencing of 3,171 cultivated and 195 wild chickpea accessions is used to construct a chickpea pan-genome, providing insight into chickpea evolution and enabling breeding strategies that could improve crop productivity.

Published

2021

2. Improved genomic prediction of clonal performance in sugarcane by exploiting non-additive genetic effects

Author

Karen S. Aitken, Seema Yadav, Priya Joyce, Felicity Atkin, Elizabeth M. Ross, Kai P. Voss-Fels, Xianming Wei, Yue Sun, Loan T. Nguyen, Tony Cavallaro, Emily Deomano, and Ben J. Hayes

Subjects

0106 biological sciences, Genotype, Genomics, Context (language use), Computational biology, Best linear unbiased prediction, Biology, 01 natural sciences, 03 medical and health sciences, Genetic variation, Genetics, Additive genetic effects, 030304 developmental biology, 0303 health sciences, Models, Genetic, Robustness (evolution), Genetic Variation, General Medicine, Saccharum, Plant Breeding, Phenotype, Trait, Original Article, Agronomy and Crop Science, Predictive modelling, 010606 plant biology & botany, Biotechnology

Abstract

Key message Non-additive genetic effects seem to play a substantial role in the expression of complex traits in sugarcane. Including non-additive effects in genomic prediction models significantly improves the prediction accuracy of clonal performance. Abstract In the recent decade, genetic progress has been slow in sugarcane. One reason might be that non-additive genetic effects contribute substantially to complex traits. Dense marker information provides the opportunity to exploit non-additive effects in genomic prediction. In this study, a series of genomic best linear unbiased prediction (GBLUP) models that account for additive and non-additive effects were assessed to improve the accuracy of clonal prediction. The reproducible kernel Hilbert space model, which captures non-additive genetic effects, was also tested. The models were compared using 3,006 genotyped elite clones measured for cane per hectare (TCH), commercial cane sugar (CCS), and Fibre content. Three forward prediction scenarios were considered to investigate the robustness of genomic prediction. By using a pseudo-diploid parameterization, we found significant non-additive effects that accounted for almost two-thirds of the total genetic variance for TCH. Average heterozygosity also had a major impact on TCH, indicating that directional dominance may be an important source of phenotypic variation for this trait. The extended-GBLUP model improved the prediction accuracies by at least 17% for TCH, but no improvement was observed for CCS and Fibre. Our results imply that non-additive genetic variance is important for complex traits in sugarcane, although further work is required to better understand the variance component partitioning in a highly polyploid context. Genomics-based breeding will likely benefit from exploiting non-additive genetic effects, especially in designing crossing schemes. These findings can help to improve clonal prediction, enabling a more accurate identification of variety candidates for the sugarcane industry.

Published

2021

3. Regional association analysis coupled with transcriptome analyses reveal candidate genes affecting seed oil accumulation in Brassica napus

Author

Habib U. Jan, Kai P. Voss-Fels, Chunyun Guan, Xin He, Lunwen Qian, Xinghua Xiong, Wei Qian, Wei Hua, Qian Yang, Min Yao, Christian R. Werner, Luyao Huang, Mei Guan, and Rod J. Snowdon

Subjects

0106 biological sciences, Candidate gene, Rapeseed, Brassica, 01 natural sciences, Chromosomes, Plant, Transcriptome, Gene Expression Regulation, Plant, Genetics, Plant Oils, Allele, Gene, Plant Proteins, Genetic association, biology, Gene Expression Profiling, Brassica napus, Haplotype, Chromosome Mapping, General Medicine, biology.organism_classification, Plant Breeding, Phenotype, Seeds, Agronomy and Crop Science, Genome-Wide Association Study, 010606 plant biology & botany, Biotechnology

Abstract

Regional association analysis of 50 re-sequenced Chinese semi-winter rapeseed accessions in combination with co-expression analysis reveal candidate genes affecting oil accumulation in Brassica napus. One of the breeding goals in rapeseed production is to enhance the seed oil content to cater to the increased demand for vegetable oils due to a growing global population. To investigate the genetic basis of variation in seed oil content, we used 60 K Brassica Infinium SNP array along with phenotype data of 203 Chinese semi-winter rapeseed accessions to perform a genome-wide analysis of haplotype blocks associated with the oil content. Nine haplotype regions harbouring lipid synthesis/transport-, carbohydrate metabolism- and photosynthesis-related genes were identified as significantly associated with the oil content and were mapped to chromosomes A02, A04, A05, A07, C03, C04, C05, C08 and C09, respectively. Regional association analysis of 50 re-sequenced Chinese semi-winter rapeseed accessions combined with transcriptome datasets from 13 accessions was further performed on these nine haplotype regions. This revealed natural variation in the BnTGD3-A02 and BnSSE1-A05 gene regions correlated with the phenotypic variation of the oil content within the A02 and A04 chromosome haplotype regions, respectively. Moreover, co-expression network analysis revealed that BnTGD3-A02 and BnSSE1-A05 were directly linked with fatty acid beta-oxidation-related gene BnKAT2-C04, thus forming a molecular network involved in the potential regulation of seed oil accumulation. The results of this study could be used to combine favourable haplotype alleles for further improvement of the seed oil content in rapeseed.

Published

2021

4. A linkage disequilibrium-based approach to position unmapped SNPs in crop species

Author

Ben J. Hayes, Owen Powell, Karen S. Aitken, Xianming Wei, Seema Yadav, Lee T. Hickey, Elizabeth M. Ross, and Kai P. Voss-Fels

Subjects

Linkage disequilibrium, Genotype, Genetic Linkage, Research, Chromosome Mapping, food and beverages, Single-nucleotide polymorphism, Computational biology, QH426-470, Biology, Polymorphism, Single Nucleotide, Genome, Single nucleotide polymorphism, Plant Breeding, Genetic map, Chromosome (genetic algorithm), Chromosome regions, Genetics, SNP, DNA microarray, TP248.13-248.65, Genome-Wide Association Study, Biotechnology, Genetic association

Abstract

Background High-density SNP arrays are now available for a wide range of crop species. Despite the development of many tools for generating genetic maps, the genome position of many SNPs from these arrays is unknown. Here we propose a linkage disequilibrium (LD)-based algorithm to allocate unassigned SNPs to chromosome regions from sparse genetic maps. This algorithm was tested on sugarcane, wheat, and barley data sets. We calculated the algorithm’s efficiency by masking SNPs with known locations, then assigning their position to the map with the algorithm, and finally comparing the assigned and true positions. Results In the 20-fold cross-validation, the mean proportion of masked mapped SNPs that were placed by the algorithm to a chromosome was 89.53, 94.25, and 97.23% for sugarcane, wheat, and barley, respectively. Of the markers that were placed in the genome, 98.73, 96.45 and 98.53% of the SNPs were positioned on the correct chromosome. The mean correlations between known and new estimated SNP positions were 0.97, 0.98, and 0.97 for sugarcane, wheat, and barley. The LD-based algorithm was used to assign 5920 out of 21,251 unpositioned markers to the current Q208 sugarcane genetic map, representing the highest density genetic map for this species to date. Conclusions Our LD-based approach can be used to accurately assign unpositioned SNPs to existing genetic maps, improving genome-wide association studies and genomic prediction in crop species with fragmented and incomplete genome assemblies. This approach will facilitate genomic-assisted breeding for many orphan crops that lack genetic and genomic resources.

Published

2021

5. High-resolution mapping of rachis nodes per rachis, a critical determinant of grain yield components in wheat

Author

Kai P. Voss-Fels, Raj K. Pasam, Wolfgang Friedt, Rudi Appels, Gabriel Keeble-Gagnère, Lee T. Hickey, Josquin Tibbits, Surya Kant, Rod J. Snowdon, Sergej Nagornyy, Benjamin Wittkop, and Matthew J. Hayden

Subjects

Genetic Markers, 0106 biological sciences, Germplasm, Candidate gene, Linkage disequilibrium, Genetic Linkage, Quantitative Trait Loci, Plant Development, Quantitative trait locus, Biology, Polymorphism, Single Nucleotide, 01 natural sciences, Chromosomes, Plant, Linkage Disequilibrium, Genetics, Plant breeding, Triticum, Plant Proteins, Genetic association, Panicle, Haplotype, Chromosome Mapping, food and beverages, General Medicine, Haplotypes, Edible Grain, Agronomy and Crop Science, Genome-Wide Association Study, 010606 plant biology & botany, Biotechnology

Abstract

Exploring large genomic data sets based on the latest reference genome assembly identifies the rice ortholog APO1 as a key candidate gene for number of rachis nodes per spike in wheat. Increasing grain yield in wheat is a key breeding objective worldwide. Several component traits contribute to grain yield with spike attributes being among the most important. In this study, we performed a genome-wide association analysis for 12 grain yield and component traits measured in field trials with contrasting agrochemical input levels in a panel of 220 hexaploid winter wheats. A highly significant, environmentally consistent QTL was detected for number of rachis nodes per rachis (NRN) on chromosome 7AL. The five most significant SNPs formed a strong linkage disequilibrium (LD) block and tagged a 2.23 Mb region. Using pairwise LD for exome SNPs located across this interval in a large worldwide hexaploid wheat collection, we reduced the genomic region for NRN to a 258 Kb interval containing four of the original SNP and six high-confidence genes. The ortholog of one (TraesCS7A01G481600) of these genes in rice was ABBERANT PANICLE ORGANIZATION1 (APO1), which is known to have significant effects on panicle attributes. The APO1 ortholog was the best candidate for NRN and was associated with a 115 bp promoter deletion and two amino acid (C47F and D384 N) changes. Using a large worldwide collection of tetraploid and hexaploid wheat, we found 12 haplotypes for the NRN QTL and evidence for positive enrichment of two haplotypes in modern germplasm. Comparison of five QTL haplotypes in Australian yield trials revealed their relative, context-dependent contribution to grain yield. Our study provides diagnostic SNPs and value propositions to support deployment of the NRN trait in wheat breeding.

Published

2019

6. Breeding improves wheat productivity under contrasting agrochemical input levels

Author

Sylvia Seddig, Agim Ballvora, Jens Léon, Matthew J. Hayden, Till Rose, Benjamin Wittkop, Henning Kage, Holger Zetzsche, Tsu-Wei Chen, Frank Ordon, Wolfgang Friedt, Mirza Majid Baig, Sabrina Nagler, Elizabeth M. Ross, Matthias Frisch, Rod J. Snowdon, Carolin Lichthardt, Kai P. Voss-Fels, Andreas Stahl, Hartmut Stützel, and Ben J. Hayes

Subjects

0106 biological sciences, 0301 basic medicine, Agrochemical, Plant Science, Biology, 01 natural sciences, 03 medical and health sciences, Grain quality, Plant breeding, Cultivar, Photosynthesis, Productivity, Triticum, Food security, business.industry, fungi, food and beverages, Plant Breeding, 030104 developmental biology, Haplotypes, Agronomy, Agriculture, Seeds, Agrochemicals, business, Cropping, Genome, Plant, 010606 plant biology & botany

Abstract

The world cropping area for wheat exceeds that of any other crop, and high grain yields in intensive wheat cropping systems are essential for global food security. Breeding has raised yields dramatically in high-input production systems; however, selection under optimal growth conditions is widely believed to diminish the adaptive capacity of cultivars to less optimal cropping environments. Here, we demonstrate, in a large-scale study spanning five decades of wheat breeding progress in western Europe, where grain yields are among the highest worldwide, that breeding for high performance in fact enhances cultivar performance not only under optimal production conditions but also in production systems with reduced agrochemical inputs. New cultivars incrementally accumulated genetic variants conferring favourable effects on key yield parameters, disease resistance, nutrient use efficiency, photosynthetic efficiency and grain quality. Combining beneficial, genome-wide haplotypes could help breeders to more efficiently exploit available genetic variation, optimizing future yield potential in more sustainable production systems.

Published

2019

7. Perspectives on Applications of Hierarchical Gene-To-Phenotype (G2P) Maps to Capture Non-stationary Effects of Alleles in Genomic Prediction

Author

Owen M. Powell, Kai P. Voss-Fels, David R. Jordan, Graeme Hammer, and Mark Cooper

Subjects

0106 biological sciences, 0301 basic medicine, epistasis, multi-trait prediction, Variation (game tree), Plant Science, Biology, 01 natural sciences, Genetic correlation, non-linear relationships, GxE interactions, SB1-1110, 03 medical and health sciences, Pleiotropy, non-additive genetic effects, pleiotropy, Plant breeding, Allele, Gene, Plant culture, crop growth models, genetic correlation, 030104 developmental biology, Evolutionary biology, Perspective, Trait, Epistasis, 010606 plant biology & botany

Abstract

Genomic prediction of complex traits across environments, breeding cycles, and populations remains a challenge for plant breeding. A potential explanation for this is that underlying non-additive genetic (GxG) and genotype-by-environment (GxE) interactions generate allele substitution effects that are non-stationary across different contexts. Such non-stationary effects of alleles are either ignored or assumed to be implicitly captured by most gene-to-phenotype (G2P) maps used in genomic prediction. The implicit capture of non-stationary effects of alleles requires the G2P map to be re-estimated across different contexts. We discuss the development and application of hierarchical G2P maps that explicitly capture non-stationary effects of alleles and have successfully increased short-term prediction accuracy in plant breeding. These hierarchical G2P maps achieve increases in prediction accuracy by allowing intermediate processes such as other traits and environmental factors and their interactions to contribute to complex trait variation. However, long-term prediction remains a challenge. The plant breeding community should undertake complementary simulation and empirical experiments to interrogate various hierarchical G2P maps that connect GxG and GxE interactions simultaneously. The existing genetic correlation framework can be used to assess the magnitude of non-stationary effects of alleles and the predictive ability of these hierarchical G2P maps in long-term, multi-context genomic predictions of complex traits in plant breeding.

Published

2021

8. Wheat root systems as a breeding target for climate resilience

Author

Michelle Watt, Marco Maccaferri, Samir Alahmad, Giuseppe Sciara, Roberto Tuberosa, Matthew J. Milner, Charlotte Rambla, Cristian Forestan, Kai P. Voss-Fels, Emma J. Wallington, Matthew P. Reynolds, Josefine Kant, Eric S. Ober, Emily C. Marr, James Cockram, Cristobal Uauy, Lee T. Hickey, Francisco de Assis de Carvalho Pinto, Silvio Salvi, Pauline Thomelin, Rod J. Snowdon, Ober E.S., Alahmad S., Cockram J., Forestan C., Hickey L.T., Kant J., Maccaferri M., Marr E., Milner M., Pinto F., Rambla C., Reynolds M., Salvi S., Sciara G., Snowdon R.J., Thomelin P., Tuberosa R., Uauy C., Voss-Fels K.P., Wallington E., and Watt M.

Subjects

Crops, Agricultural, 0106 biological sciences, Root (linguistics), Climate Change, media_common.quotation_subject, Review, Agricultural engineering, Biology, Genes, Plant, Plant Roots, 01 natural sciences, Wheat, root, breeding, target, resilience, 03 medical and health sciences, ddc:570, Genetics, Plant breeding, Triticum, Selection (genetic algorithm), 030304 developmental biology, media_common, 0303 health sciences, Food security, business.industry, General Medicine, Climate resilience, Genetic architecture, Plant Breeding, Phenotype, Agriculture, Psychological resilience, business, Agronomy and Crop Science, 010606 plant biology & botany, Biotechnology

Abstract

In the coming decades, larger genetic gains in yield will be necessary to meet projected demand, and this must be achieved despite the destabilizing impacts of climate change on crop production. The root systems of crops capture the water and nutrients needed to support crop growth, and improved root systems tailored to the challenges of specific agricultural environments could improve climate resiliency. Each component of root initiation, growth and development is controlled genetically and responds to the environment, which translates to a complex quantitative system to navigate for the breeder, but also a world of opportunity given the right tools. In this review, we argue that it is important to know more about the ‘hidden half’ of crop plants and hypothesize that crop improvement could be further enhanced using approaches that directly target selection for root system architecture. To explore these issues, we focus predominantly on bread wheat (Triticum aestivum L.), a staple crop that plays a major role in underpinning global food security. We review the tools available for root phenotyping under controlled and field conditions and the use of these platforms alongside modern genetics and genomics resources to dissect the genetic architecture controlling the wheat root system. To contextualize these advances for applied wheat breeding, we explore questions surrounding which root system architectures should be selected for, which agricultural environments and genetic trait configurations of breeding populations are these best suited to, and how might direct selection for these root ideotypes be implemented in practice.

Published

2021

9. Modelling selection response in plant-breeding programs using crop models as mechanistic gene-to-phenotype (CGM-G2P) multi-trait link functions

Author

Daniel Ortiz-Barrientos, Dean Podlich, Carlos D. Messina, Kai P. Voss-Fels, Carla Gho, Mark E. Cooper, Frank Technow, Graeme Hammer, Scott Chapman, Owen Powell, and Christine A. Beveridge

Subjects

0106 biological sciences, 0301 basic medicine, business.industry, food and beverages, Plant Science, Quantitative genetics, Biology, 01 natural sciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), 03 medical and health sciences, 030104 developmental biology, Agriculture, Evolutionary biology, Modeling and Simulation, Genetic variation, Trait, Plant breeding, Allele, business, Agronomy and Crop Science, Gene, Selection (genetic algorithm), 010606 plant biology & botany

Abstract

Plant-breeding programs are designed and operated over multiple cycles to systematically change the genetic makeup of plants to achieve improved trait performance for a Target Population of Environments (TPE). Within each cycle, selection applied to the standing genetic variation within a structured reference population of genotypes (RPG) is the primary mechanism by which breeding programs make the desired genetic changes. Selection operates to change the frequencies of the alleles of the genes controlling trait variation within the RPG. The structure of the RPG and the TPE has important implications for the design of optimal breeding strategies. The breeder’s equation, together with the quantitative genetic theory behind the equation, informs many of the principles for design of breeding programs. The breeder’s equation can take many forms depending on the details of the breeding strategy. Through the genetic changes achieved by selection, the cultivated varieties of crops (cultivars) are improved for use in agriculture. From a breeding perspective, selection for specific trait combinations requires a quantitative link between the effects of the alleles of the genes impacted by selection and the trait phenotypes of plants and their breeding value. This gene-to-phenotype link function provides the G2P map for one to many traits. For complex traits controlled by many genes, the infinitesimal model for trait genetic variation is the dominant G2P model of quantitative genetics. Here we consider motivations and potential benefits of using the hierarchical structure of crop models as CGM-G2P trait link functions in combination with the infinitesimal model for the design and optimization of selection in breeding programs.

Published

2020

10. Modelling selection response in plant breeding programs using crop models as mechanistic gene-to-phenotype (CGM-G2P) multi-trait link functions

Author

Frank Technow, Owen Powell, Christine A. Beveridge, Graeme Hammer, Scott Chapman, Carla Gho, Carlos D. Messina, Kai P. Voss-Fels, D Ortiz-Barientos, Mark E. Cooper, and Dean Podlich

Subjects

Evolutionary biology, Agriculture, business.industry, Genetic variation, Trait, food and beverages, Plant breeding, Quantitative genetics, Biology, Allele, business, Gene, Selection (genetic algorithm)

Abstract

Plant breeding programs are designed and operated over multiple cycles to systematically change the genetic makeup of plants to achieve improved trait performance for a Target Population of Environments (TPE). Within each cycle, selection applied to the standing genetic variation within a structured reference population of genotypes (RPG) is the primary mechanism by which breeding programs make the desired genetic changes. Selection operates to change the frequencies of the alleles of the genes controlling trait variation within the RPG. The structure of the RPG and the TPE has important implications for the design of optimal breeding strategies. The breeder’s equation, together with the quantitative genetic theory behind the equation, informs many of the principles for design of breeding programs. The breeder’s equation can take many forms depending on the details of the breeding strategy. Through the genetic changes achieved by selection, the cultivated varieties of crops (cultivars) are improved for use in agriculture. From a breeding perspective, selection for specific trait combinations requires a quantitative link between the effects of the alleles of the genes impacted by selection and the trait phenotypes of plants and their breeding value. This gene-to-phenotype link function provides the G2P map for one to many traits. For complex traits controlled by many genes, the infinitesimal model for trait genetic variation is the dominant G2P model of quantitative genetics. Here we consider motivations and potential benefits of using the hierarchical structure of crop models as CGM-G2P trait link functions in combination with the infinitesimal model for the design and optimisation of selection in breeding programs.

Published

2020

11. Genetic characterization of adult-plant resistance to tan spot (syn, yellow spot) in wheat

Author

Eric G, Dinglasan, Tamaya, Peressini, Kalai A, Marathamuthu, Pao Theen, See, Lisle, Snyman, Greg, Platz, Ian, Godwin, Kai P, Voss-Fels, Caroline S, Moffat, and Lee T, Hickey

Subjects

Plant Breeding, Phenotype, Ascomycota, Gene Expression Regulation, Plant, Host-Pathogen Interactions, Quantitative Trait Loci, Chromosome Mapping, Chromosomes, Plant, Triticum, Disease Resistance, Plant Diseases, Plant Proteins

Abstract

QTL mapping identified key genomic regions associated with adult-plant resistance to tan spot, which are effective even in the presence of the sensitivity gene Tsn1, thus serving as a new genetic solution to develop disease-resistant wheat cultivars. Improving resistance to tan spot (Pyrenophora tritici-repentis; Ptr) in wheat by eliminating race-specific susceptibility genes is a common breeding approach worldwide. The potential to exploit variation in quantitative forms of resistance, such as adult-plant resistance (APR), offers an alternative approach that could lead to broad-spectrum protection. We previously identified wheat landraces in the Vavilov diversity panel that exhibited high levels of APR despite carrying the sensitivity gene Tsn1. In this study, we characterised the genetic control of APR by developing a recombinant inbred line population fixed for Tsn1, but segregating for the APR trait. Linkage mapping using DArTseq markers and disease response phenotypes identified a QTL associated with APR to Ptr race 1 (producing Ptr ToxA- and Ptr ToxC) on chromosome 2B (Qts.313-2B), which was consistently detected in multiple adult-plant experiments. Additional loci were also detected on chromosomes 2A, 3D, 5A, 5D, 6A, 6B and 7A at the seedling stage, and on chromosomes 1A and 5B at the adult stage. We demonstrate that Qts.313-2B can be combined with other adult-plant QTL (i.e. Qts.313-1A and Qts.313-5B) to strengthen resistance levels. The APR QTL reported in this study provide a new genetic solution to tan spot in Australia and could be deployed in wheat cultivars, even in the presence of Tsn1, to decrease production losses and reduce the application of fungicides.

Published

2020

12. Strategies and considerations for implementing genomic selection to improve traits with additive and non-additive genetic architectures in sugarcane breeding

Author

Kai P, Voss-Fels, Xianming, Wei, Elizabeth M, Ross, Matthias, Frisch, Karen S, Aitken, Mark, Cooper, and Ben J, Hayes

Subjects

Plant Breeding, Genetics, Population, Phenotype, Models, Genetic, Quantitative Trait Loci, Chromosome Mapping, Genomics, Selection, Genetic, Chromosomes, Plant, Genome, Plant, Saccharum

Abstract

Simulations highlight the potential of genomic selection to substantially increase genetic gain for complex traits in sugarcane. The success rate depends on the trait genetic architecture and the implementation strategy. Genomic selection (GS) has the potential to increase the rate of genetic gain in sugarcane beyond the levels achieved by conventional phenotypic selection (PS). To assess different implementation strategies, we simulated two different GS-based breeding strategies and compared genetic gain and genetic variance over five breeding cycles to standard PS. GS scheme 1 followed similar routines like conventional PS but included three rapid recurrent genomic selection (RRGS) steps. GS scheme 2 also included three RRGS steps but did not include a progeny assessment stage and therefore differed more fundamentally from PS. Under an additive trait model, both simulated GS schemes achieved annual genetic gains of 2.6-2.7% which were 1.9 times higher compared to standard phenotypic selection (1.4%). For a complex non-additive trait model, the expected annual rates of genetic gain were lower for all breeding schemes; however, the rates for the GS schemes (1.5-1.6%) were still greater than PS (1.1%). Investigating cost-benefit ratios with regard to numbers of genotyped clones showed that substantial benefits could be achieved when only 1500 clones were genotyped per 10-year breeding cycle for the additive genetic model. Our results show that under a complex non-additive genetic model, the success rate of GS depends on the implementation strategy, the number of genotyped clones and the stage of the breeding program, likely reflecting how changes in QTL allele frequencies change additive genetic variance and therefore the efficiency of selection. These results are encouraging and motivate further work to facilitate the adoption of GS in sugarcane breeding.

Published

2020

13. Accuracy of genomic prediction of complex traits in sugarcane

Author

Ben J, Hayes, Xianming, Wei, Priya, Joyce, Felicity, Atkin, Emily, Deomano, Jenny, Yue, Loan, Nguyen, Elizabeth M, Ross, Tony, Cavallaro, Karen S, Aitken, and Kai P, Voss-Fels

Subjects

Multifactorial Inheritance, Plant Breeding, Genetics, Population, Quantitative Trait, Heritable, Gene Expression Regulation, Plant, Chromosome Mapping, Flowers, Polymorphism, Single Nucleotide, Chromosomes, Plant, Genome, Plant, Plant Proteins, Saccharum

Abstract

Complex traits in sugarcane can be accurately predicted using genome-wide DNA markers. Genomic single-step prediction is an attractive method for genomic selection in commercial breeding programs. Sugarcane breeding programs have achieved up to 1% genetic gain in key traits such as tonnes of cane per hectare (TCH), commercial cane sugar (CCS) and Fibre content over the past decades. Here, we assess the potential of genomic selection to increase the rate of genetic gain for these traits by deriving genomic estimated breeding values (GEBVs) from a reference population of 3984 clones genotyped for 26 K SNP. We evaluated the three different genomic prediction approaches GBLUP, genomic single step (GenomicSS), and BayesR. GenomicSS combining pedigree and SNP information from historic and recent breeding programs achieved the most accurate predictions for most traits (0.3-0.44). This method is attractive for routine genetic evaluation because it requires relatively little modification to the existing evaluation and results in breeding value estimates for all individuals, not only those genotyped. Adding information from early-stage trials added up to 5% accuracy for CCS and Fibre, but 0% for TCH, reflecting the importance of competition effects for TCH. These GEBV accuracies are sufficiently high that, combined with the right breeding strategy, a doubling of the rate of genetic gain could be achieved. We also assessed the flowering traits days to flowering, gender and pollen viability and found high heritabilities of 0.57, 0.78 and 0.72, respectively. The GEBV accuracies indicated that genomic selection could be used to improve these traits. This could open new avenues for breeders to manage their breeding programs, for example, by synchronising flowering time and selecting males with high pollen viability.

Published

2020

14. Accelerating Genetic Gain in Sugarcane Breeding Using Genomic Selection

Author

Ben J. Hayes, Elizabeth M. Ross, Phillip Jackson, Felicity Atkin, Emily Deomano, Kai P. Voss-Fels, Seema Yadav, Karen S. Aitken, and Xianming Wei

Subjects

0106 biological sciences, 0303 health sciences, genetic gain, quantitative genetics, business.industry, lcsh:S, Context (language use), Quantitative genetics, Quantitative trait locus, Heritability, Biology, 01 natural sciences, Biotechnology, genomic selection, lcsh:Agriculture, 03 medical and health sciences, Bioenergy, Genetic gain, Plant breeding, sugarcane breeding, business, Agronomy and Crop Science, Selection (genetic algorithm), 030304 developmental biology, 010606 plant biology & botany

Abstract

Sugarcane is a major industrial crop cultivated in tropical and subtropical regions of the world. It is the primary source of sugar worldwide, accounting for more than 70% of world sugar consumption. Additionally, sugarcane is emerging as a source of sustainable bioenergy. However, the increase in productivity from sugarcane has been small compared to other major crops, and the rate of genetic gains from current breeding programs tends to be plateauing. In this review, some of the main contributors for the relatively slow rates of genetic gain are discussed, including (i) breeding cycle length and (ii) low narrow-sense heritability for major commercial traits, possibly reflecting strong non-additive genetic effects involved in quantitative trait expression. A general overview of genomic selection (GS), a modern breeding tool that has been very successfully applied in animal and plant breeding, is given. This review discusses key elements of GS and its potential to significantly increase the rate of genetic gain in sugarcane, mainly by (i) reducing the breeding cycle length, (ii) increasing the prediction accuracy for clonal performance, and (iii) increasing the accuracy of breeding values for parent selection. GS approaches that can accurately capture non-additive genetic effects and potentially improve the accuracy of genomic estimated breeding values are particularly promising for the adoption of GS in sugarcane breeding. Finally, different strategies for the efficient incorporation of GS in a practical sugarcane breeding context are presented. These proposed strategies hold the potential to substantially increase the rate of genetic gain in future sugarcane breeding.

Published

2020

15. Speed breeding for multiple quantitative traits in durum wheat

Author

Eric Dinglasan, Filippo M. Bassi, Nora Derbal, Samir Alahmad, Adnan Riaz, Lee T. Hickey, Jason A. Able, Jack Christopher, Kai P. Voss-Fels, and Kung Ming Leung

Subjects

0106 biological sciences, 0301 basic medicine, Crown rot, Segregating populations, Leaf rust, Plant Science, Biology, Quantitative trait locus, Plant disease resistance, lcsh:Plant culture, 01 natural sciences, Transgressive segregation, 03 medical and health sciences, Fusarium, Genetics, lcsh:SB1-1110, Plant breeding, Cultivar, Allele, lcsh:QH301-705.5, Selection (genetic algorithm), Methodology, food and beverages, Root architecture, Drought adaptation, 030104 developmental biology, Agronomy, lcsh:Biology (General), Trait, Trait pyramiding, Speed breeding, 010606 plant biology & botany, Biotechnology

Abstract

Background Plant breeding requires numerous generations to be cycled and evaluated before an improved cultivar is released. This lengthy process is required to introduce and test multiple traits of interest. However, a technology for rapid generation advance named ‘speed breeding’ was successfully deployed in bread wheat (Triticum aestivum L.) to achieve six generations per year while imposing phenotypic selection for foliar disease resistance and grain dormancy. Here, for the first time the deployment of this methodology is presented in durum wheat (Triticum durum Desf.) by integrating selection for key traits, including above and below ground traits on the same set of plants. This involved phenotyping for seminal root angle (RA), seminal root number (RN), tolerance to crown rot (CR), resistance to leaf rust (LR) and plant height (PH). In durum wheat, these traits are desirable in environments where yield is limited by in-season rainfall with the occurrence of CR and epidemics of LR. To evaluate this multi-trait screening approach, we applied selection to a large segregating F2 population (n = 1000) derived from a bi-parental cross (Outrob4/Caparoi). A weighted selection index (SI) was developed and applied. The gain for each trait was determined by evaluating F3 progeny derived from 100 ‘selected’ and 100 ‘unselected’ F2 individuals. Results Transgressive segregation was observed for all assayed traits in the Outrob4/Caparoi F2 population. Application of the SI successfully shifted the population mean for four traits, as determined by a significant mean difference between ‘selected’ and ‘unselected’ F3 families for CR tolerance, LR resistance, RA and RN. No significant shift for PH was observed. Conclusions The novel multi-trait phenotyping method presents a useful tool for rapid selection of early filial generations or for the characterization of fixed lines out-of-season. Further, it offers efficient use of resources by assaying multiple traits on the same set of plants. Results suggest that when performed in parallel with speed breeding in early generations, selection will enrich recombinant inbred lines with desirable alleles and will reduce the length and number of years required to combine these traits in elite breeding populations and therefore cultivars. Electronic supplementary material The online version of this article (10.1186/s13007-018-0302-y) contains supplementary material, which is available to authorized users.

Published

2018

16. Q&A: modern crop breeding for future food security

Author

Lee T. Hickey, Kai P. Voss-Fels, and Andreas Stahl

Subjects

Crops, Agricultural, Physiology, Population, Plant Science, Biology, General Biochemistry, Genetics and Molecular Biology, Food Supply, Crop, 03 medical and health sciences, Extreme weather, 0302 clinical medicine, Structural Biology, Food supply, Production (economics), Plant breeding, education, lcsh:QH301-705.5, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, education.field_of_study, Food security, Agroforestry, business.industry, fungi, food and beverages, Agriculture, Cell Biology, Plant Breeding, lcsh:Biology (General), General Agricultural and Biological Sciences, business, 030217 neurology & neurosurgery, Question and Answer, Developmental Biology, Biotechnology

Abstract

Farmers around the world have recently experienced significant crop losses due to severe heat and drought. Such extreme weather events and the need to feed a rapidly growing population have raised concerns for global food security. While plant breeding has been very successful and has delivered today’s highly productive crop varieties, the rate of genetic improvement must double to meet the projected future demands. Here we discuss basic principles and features of crop breeding and how modern technologies could efficiently be explored to boost crop improvement in the face of increasingly challenging production conditions.

Published

2019

17. Need for speed: manipulating plant growth to accelerate breeding cycles

Author

Pablo Sandro, Lucía Gutiérrez, Madhav Bhatta, Kai P. Voss-Fels, Millicent R. Smith, Oscar Delaney, and Lee T. Hickey

Subjects

Crops, Agricultural, 0106 biological sciences, 0301 basic medicine, Plant growth, Plant Development, food and beverages, Capacity building, Genomics, Plant Science, Agricultural engineering, Biology, 01 natural sciences, Plant Breeding, 03 medical and health sciences, 030104 developmental biology, Plant breeding, Triticum, Genomic selection, 010606 plant biology & botany

Abstract

To develop more productive and resilient crops that are capable of feeding 10 billion people by 2050, we must accelerate the rate of genetic improvement in plant breeding programs. Speed breeding manipulates the growing environment by regulating light and temperature for the purpose of rapid generation advance. Protocols are now available for a range of short-day and long-day species and the approach is highly compatible with other cutting-edge breeding tools such as genomic selection. Here, we highlight how speed breeding hijacks biological processes for applied plant breeding outcomes and provide a case study examining wheat growth and development under speed breeding conditions. The establishment of speed breeding facilities worldwide is expected to provide benefits for capacity building, discovery research, pre-breeding, and plant breeding to accelerate the development of productive and robust crops.

Published

2021

18. Accelerating crop genetic gains with genomic selection

Author

Mark E. Cooper, Kai P. Voss-Fels, and Ben J. Hayes

Subjects

0106 biological sciences, Crops, Agricultural, Animal breeding, Livestock, Genotyping Techniques, Biology, 01 natural sciences, Genetics, Additive genetic effects, Animals, Plant breeding, Selection, Genetic, Selection (genetic algorithm), Genetic diversity, Food security, business.industry, food and beverages, Epistasis, Genetic, General Medicine, Genomics, Biotechnology, Agriculture, Genetic gain, business, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Genomic prediction based on additive genetic effects can accelerate genetic gain. There are opportunities for further improvement by including non-additive effects that access untapped sources of genetic diversity. Several studies have reported a worrying gap between the projected global future demand for plant-based products and the current annual rates of production increase, indicating that enhancing the rate of genetic gain might be critical for future food security. Therefore, new breeding technologies and strategies are required to significantly boost genetic improvement of future crop cultivars. Genomic selection (GS) has delivered considerable genetic gain in animal breeding and is becoming an essential component of many modern plant breeding programmes as well. In this paper, we review the lessons learned from implementing GS in livestock and the impact of GS on crop breeding, and discuss important features for the success of GS under different breeding scenarios. We highlight major challenges associated with GS including rapid genotyping, phenotyping, genotype-by-environment interaction and non-additivity and give examples for opportunities to overcome these issues. Finally, the potential of combining GS with other modern technologies in order to maximise the rate of crop genetic improvement is discussed, including the potential of increasing prediction accuracy by integration of crop growth models in GS frameworks.

Published

2018

19. Designer Roots for Future Crops

Author

Rod J. Snowdon, Lee T. Hickey, and Kai P. Voss-Fels

Subjects

2. Zero hunger, 0106 biological sciences, 0301 basic medicine, Plant Components, Crops, Agricultural, Agroforestry, Agriculture, Plant Science, 15. Life on land, Biology, Flowering time, 01 natural sciences, Plant Roots, Crop, 03 medical and health sciences, Plant Breeding, 030104 developmental biology, Sustainable agriculture, 010606 plant biology & botany

Abstract

Despite the importance of roots, they have largely been ignored by modern crop research and breeding. We discuss important progress in crop root research and highlight how the context-dependent optimisation of below- and above-ground plant components provides opportunities to improve future crops in the face of increasing environmental fluctuations.

Published

2018

20. Genome-wide regression models considering general and specific combining ability predict hybrid performance in oilseed rape with similar accuracy regardless of trait architecture

Author

Rod J. Snowdon, Gunhild Leckband, Lunwen Qian, Matthias Frisch, Christian R. Werner, Kai P. Voss-Fels, and Amine Abbadi

Subjects

0106 biological sciences, 0301 basic medicine, Breeding program, Genotype, Heterosis, Population, Computational biology, Best linear unbiased prediction, Biology, 01 natural sciences, Polymorphism, Single Nucleotide, 03 medical and health sciences, Genetics, Hybrid Vigor, education, Selection (genetic algorithm), Crosses, Genetic, education.field_of_study, Models, Genetic, business.industry, Brassica napus, Regression analysis, General Medicine, Biotechnology, Plant Breeding, 030104 developmental biology, Phenotype, Trait, Doubled haploidy, business, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Genomic prediction using the Brassica 60 k genotyping array is efficient in oilseed rape hybrids. Prediction accuracy is more dependent on trait complexity than on the prediction model. In oilseed rape breeding programs, performance prediction of parental combinations is of fundamental importance. Due to the phenomenon of heterosis, per se performance is not a reliable indicator for F1-hybrid performance, and selection of well-paired parents requires the testing of large quantities of hybrid combinations in extensive field trials. However, the number of potential hybrids, in general, dramatically exceeds breeding capacity and budget. Integration of genomic selection (GS) could substantially increase the number of potential combinations that can be evaluated. GS models can be used to predict the performance of untested individuals based only on their genotypic profiles, using marker effects previously predicted in a training population. This allows for a preselection of promising genotypes, enabling a more efficient allocation of resources. In this study, we evaluated the usefulness of the Illumina Brassica 60 k SNP array for genomic prediction and compared three alternative approaches based on a homoscedastic ridge regression BLUP and three Bayesian prediction models that considered general and specific combining ability (GCA and SCA, respectively). A total of 448 hybrids were produced in a commercial breeding program from unbalanced crosses between 220 paternal doubled haploid lines and five male-sterile testers. Predictive ability was evaluated for seven agronomic traits. We demonstrate that the Brassica 60 k genotyping array is an adequate and highly valuable platform to implement genomic prediction of hybrid performance in oilseed rape. Furthermore, we present first insights into the application of established statistical models for prediction of important agronomical traits with contrasting patterns of polygenic control.

Published

2017

21. Understanding and utilizing crop genome diversity via high-resolution genotyping

Author

Rod J. Snowdon and Kai P. Voss-Fels

Subjects

0106 biological sciences, 0301 basic medicine, Crops, Agricultural, Linkage disequilibrium, Quantitative Trait Loci, Population genetics, Genomics, Genome-wide association study, Plant Science, Computational biology, Biology, 01 natural sciences, Genome, Polymorphism, Single Nucleotide, DNA sequencing, Linkage Disequilibrium, 03 medical and health sciences, Hybrid Vigor, Selection, Genetic, Genotyping, Genetics, Genetic Variation, High-Throughput Nucleotide Sequencing, Plant Breeding, 030104 developmental biology, Crop diversity, human activities, Agronomy and Crop Science, Genome, Plant, 010606 plant biology & botany, Biotechnology, Genome-Wide Association Study

Abstract

High-resolution genome analysis technologies provide an unprecedented level of insight into structural diversity across crop genomes. Low-cost discovery of sequence variation has become accessible for all crops since the development of next-generation DNA sequencing technologies, using diverse methods ranging from genome-scale resequencing or skim sequencing, reduced-representation genotyping-by-sequencing, transcriptome sequencing or sequence capture approaches. High-density, high-throughput genotyping arrays generated using the resulting sequence data are today available for the assessment of genomewide single nucleotide polymorphisms in all major crop species. Besides their application in genetic mapping or genomewide association studies for dissection of complex agronomic traits, high-density genotyping arrays are highly suitable for genomic selection strategies. They also enable description of crop diversity at an unprecedented chromosome-scale resolution. Application of population genetics parameters to genomewide diversity data sets enables dissection of linkage disequilibrium to characterize loci underlying selective sweeps. High-throughput genotyping platforms simultaneously open the way for targeted diversity enrichment, allowing rejuvenation of low-diversity chromosome regions in strongly selected breeding pools to potentially reverse the influence of linkage drag. Numerous recent examples are presented which demonstrate the power of next-generation genomics for high-resolution analysis of crop diversity on a subgenomic and chromosomal scale. Such studies give deep insight into the history of crop evolution and selection, while simultaneously identifying novel diversity to improve yield and heterosis.

Published

2015