The discovery of genes responsible for asexual reproduction in a tropical grass may reduce negative impacts of cattle farming. The grass captures carbon, reduces gas emissions from soils, restores degraded land, and improves cattle health and productivity.
Cattle are a mainstay for many smallholders but their farms are often on degraded lands, which increases cattle’s impact on the environment and lowers their production of milk and meat. Researchers at the International Center for Tropical Agriculture (CIAT) have shown that Brachiaria grass species can reduce greenhouse gas emissions from cattle and increase productivity – and breeding improved varieties can potentially augment the environmental and economic benefits.
But the breeding process is difficult, time-consuming and expensive. A breakthrough on Brachiaria’s complex genome may make breeding much more efficient, and potentially increase the speed with which new grasses begin benefiting cattle farmers and the environment.
Margaret Worthington, a geneticist at CIAT and the University of Arkansas, and colleagues created the first dense molecular map of B. humidicola, a robust and environmentally friendly forage grass. They also pinpointed the candidate genes for the plant’s asexual reproductive mechanism, which is a huge asset for plant breeders. The findings were published in January in BMC Genomics.
“The idea is to create a better crop with less time and less money and to get it out faster to farmers. By using this molecular marker, you increase the odds of finding that rare winner.”Margaret Worthington
Traditional plant-breeding methods for Brachiaria grasses involve one of two complex techniques. One is to grow the plant to seed, and to study the seeds under a microscope to determine if the plant reproduced asexually. The other involves excising the plant’s embryos and conducting a similar analysis. Both techniques require many weeks, significant funds and highly trained specialists.
Asexual reproduction through seed, called apomixis, is key for developing new crop varieties for widespread use. Crops that reproduce through apomixis conserve the same traits from one generation to the next, essentially locking in sought-after characteristics such as drought tolerance or high nutritional value. Plants that reproduce sexually do not reliably pass on desired traits to subsequent generations.
With this molecular marker, plant breeders can run a quick and inexpensive test when Brachiaria grasses are seedlings to identify whether they reproduce through apomixis. The results are available in a couple of weeks. This allows plant breeders to select only asexually reproductive plants for trials, allowing them to allocate more time and resources to plants that have the potential to produce new cultivars.
Brachiaria grasses have often been considered an “orphan crop,” due to a lack of investment in research, but their potential for making tropical farms more productive and better for the environment is well known among tropical forage specialists. One recent study found that B. humidicola was especially adept at reducing the nitrous oxide, a strong greenhouse gas, emitted from soil as result of cattle urine deposition. In addition, CIAT researchers have identified mechanisms that this tropical grass uses to efficiently acquire nutrients from soil.
Brachiaria breeders also value apomixis for smallholders in developing nations who have limited resources for investing in improving their farms. Improved grass varieties that produce sufficient quantities of trait-retaining seeds can eliminate the need to purchase new seeds for every planting, which is a potentially expensive barrier to adoption.
“This breakthrough allows for the acceleration of our breeding program for multiple traits, including the development of tropical forages that can help reduce greenhouse gas emissions and make farming more eco-efficient.”Joe Tohme
“This discovery represents a milestone in the path toward developing mitigation technologies in the livestock production sector.”Jacobo Arango
Partners and funding
The researchers acknowledge support from the Yale University High-Performance Computing Center (supported by NIH grants RR-19895 and RR-029676-01) and the Yale Center for Genome Analysis. This project has been supported in part by a grant from the National Science Foundation Plant Genome Research Program to SLD (NSF 1444478). Development of SSR markers was supported by the JIRCAS project “Development of ecologically sustainable agricultural systems through practical use of the biological nitrification inhibition function.”
Work at CIAT was supported by the Federal Ministry for Economic Cooperation and Development (BMZ, Germany) under the GIZ Project Number 11.7860.7–001.00 and the CGIAR Research Program on Livestock. We thank all donors that globally support the work of the Livestock CRP through their contributions to the CGIAR System. None of the funding agencies played an active role in the design of the study, its execution, or the writing of the manuscript.