Crop breeding: Getting to the root of the problem
Date:
August 26, 2020
Source:
American Society of Agronomy
Summary:
Roots play a vital role in crop plants. They take up water and
nutrients for the plant and keep it help firmly in the ground. But
not all roots are the same.
FULL STORY ========================================================================== Roots play a vital role in crop plants. They take up water and nutrients
for the plant and keep it help firmly in the ground. But not all roots
are the same.
========================================================================== Different plants have different kinds of roots that help them survive in
their environment. Two well-known examples are carrots and cactus. Carrots
have a long taproot that penetrates deep into the soil. Cacti usually
have shallow roots. These allow them to quickly soak up the little
rainfall they receive in the desert.
Can studying roots lead to better crops? It's a question that researchers
from Pennsylvania State University set out to answer, focusing on
beans. They know that crops like beans are critical for feeding a rapidly growing population.
"Grain legumes are critical for global food security, but achieve
low yields in most areas," says Jonathan P. Lynch, a professor at
Pennsylvania State University. "This is especially true in areas of the developing world that experience drought, heat, and low soil fertility." Breeding is a way to improve how crops perform in different environments.
However, looking at the roots for beneficial characteristics for breeding
is rarely done.
"Optimizing how plants get resources from the soil in stressful
environments is important for increasing food production, but specific
breeding objectives are ill defined," Lynch says. "We sought to test
hypotheses about the link between root system architecture and life
strategy in order to generate breeding targets." In their study, they
analyzed the root systems of several kinds of beans and other legumes,
like chickpeas. This allowed them to see tradeoffs and to determine
what kind of root characteristics would perform better in certain
environments. This can help plant breeders devise better plants.
========================================================================== Roots explore both the topsoil and subsoil. Nutrients like phosphorus
and potassium are more present in the topsoil, while water and nitrogen
are usually deeper in the soil. They observed that many crops focus on
one or the other of these soil layers, which results in a tradeoff.
"Root architecture is an important component of crop adaptation to
environments where water and nutrients are lacking," Lynch says. "We
suggest that root phenotypes capable of balancing topsoil and subsoil exploration would be useful." The researchers say that breeding
programs could use trait-based selection on root characteristics they are interested in. They could then use various techniques to get well-adapted plants with stronger primary roots or longer root hairs, for example.
"Everyone knows that roots are important for crops, especially in
poor soils and in dry conditions," Lynch adds. "However, very few crop
breeders actively select for these root characteristics because it can be difficult. This paper is one of a growing number by our team and others
showing how specific root characteristics are associated with crop
resilience under stress." Lynch says his personal goal is to improve
food security in developing nations.
850 million people are chronically malnourished around the world and
with the human population expanding, the problem will only increase.
Grain legumes have the potential to help address this problem because
they are good for the soil and for humans. They take nitrogen from the
air and make it usable in the soil and are rich in nutrients humans need
like protein, iron, and zinc.
"It is important for us all to recognize the magnitude of the challenge represented by assuring food security for 10 billion people in a degraded global environment," Lynch says. "We must do what we can to help the
next generation of agricultural scientists meet this challenge."
========================================================================== Story Source: Materials provided by American_Society_of_Agronomy. Note:
Content may be edited for style and length.
========================================================================== Journal Reference:
1. James D. Burridge, Harini Rangarajan, Jonathan P. Lynch. Comparative
phenomics of annual grain legume root architecture. Crop Science,
2020; DOI: 10.1002/csc2.20241 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2020/08/200826083026.htm
--- up 2 days, 6 hours, 51 minutes
* Origin: -=> Castle Rock BBS <=- Now Husky HPT Powered! (1337:3/111)