Abstract
The C4Urochloa species (syn. Brachiaria) and Megathyrsus maximus (syn. Panicum maximum) are used as pasture for cattle across vast areas in tropical agriculture systems in Africa and South America. A key target for variety improvement is forage quality: enhanced digestibility could decrease the amount of land required per unit production, and enhanced lipid content could decrease methane emissions from cattle. For these traits, loss-of-function (LOF) alleles in known gene targets are predicted to improve them, making a reverse genetics approach of allele mining feasible. We therefore set out to look for such alleles in diverse accessions of Urochloa species and Megathyrsus maximus from the genebank collection held at the CIAT. We studied allelic diversity of 20 target genes (11 for digestibility, nine for lipid content) in 104 accessions selected to represent genetic diversity and ploidy levels of U. brizantha, U. decumbens, U. humidicola, U. ruziziensis and M. maximum. We used RNA sequencing and then bait capture DNA sequencing to improve gene models in a U. ruziziensis reference genome to assign polymorphisms with high confidence. We found 953 non-synonymous polymorphisms across all genes and accessions; within these, we identified seven putative LOF alleles with high confidence, including those in the non-redundant SDP1 and BAHD01 genes present in diploid and tetraploid accessions. These LOF alleles could respectively confer increased lipid content and digestibility if incorporated into a breeding programme. We demonstrated a novel, effective approach to allele discovery in diverse accessions using a draft reference genome from a single species. We used this to find gene variants in a collection of tropical grasses that could help reduce the environmental impact of cattle production.
Highlights
INTRODUCTIONThe environmental impact of cattle production could be decreased by reducing the amount of land required (e.g. landsparing, sustainable intensification; IPCC, 2019) and the amount of methane (CH4) emitted per unit production (i.e. emission intensity)
The environmental impact of cattle production could be decreased by reducing the amount of land required and the amount of methane (CH4) emitted per unit production
This could be achieved by genetic improvement of pasture grass on which they feed (O’Mara, 2012): an increase in digestibility and energy content would allow the same production to be achieved on a smaller land area, and an increase in lipid content in vegetative matter would decrease CH4 emitted per unit production (Hegarty et al, 2013), provided that these two traits could be improved without negative side effects, such as reduced growth or susceptibility to biotic or abiotic stresses
Summary
The environmental impact of cattle production could be decreased by reducing the amount of land required (e.g. landsparing, sustainable intensification; IPCC, 2019) and the amount of methane (CH4) emitted per unit production (i.e. emission intensity). Breeding of commercial tropical forage grass varieties in diploid and polyploid species and interspecific hybrids of Urochloa has been achieved by recurrent selection over many years, identifying superior-performing populations for key traits such as biomass production in different environments, resistance to pests and digestibility (Worthington and Miles, 2014). These targets increase the efficiency of forage grass, such that less land is required for production. We conducted a comprehensive screening of alleles for these genes in 104 diverse accessions of U. brizantha, U. decumbens, U. humidicola, U. ruziziensis and M. maximum using RNA sequencing (RNAseq) and bait capture genomic DNA sequencing (DNAseq)
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