Adapting Crops for Extreme Weather

In late September, an international team of researchers fanned out across a remote New Mexico mountain range, in search of an elusive plant. The group trekked through the rugged landscape looking for signs of delicate vines hugging a tree, or lingering low on a dried creek bank.

After seven days in the desert scrubland, the scientists left with a sample of nature’s bounty: wild tepary bean plants.

The scientists wanted to collect the legume, which is native to arid regions of the southwestern United States and northwestern Mexico, for its hardy constitution: “They have evolved in this very hot, dry climate, so they have exceptional drought and heat tolerance, and potential tolerance to some extreme soil conditions as well,” said Sarah Dohle, a bean curator with the U.S. Department of Agriculture, who was part of the New Mexico collection effort.

Those qualities could prove beneficial on a warming planet, as scientists figure out how to breed beans, peppers, potatoes, and various other grains, fruits, and vegetables that can withstand the harsh conditions of a changing climate.

Such effects are already wreaking havoc on agriculture around the globe. In the western U.S., a severe drought crushed California’s tomato and rice production. In Guatemala, the combined effects of both drought and rain devastated corn and black bean harvests, both major food staples. In Sub-Saharan Africa, searing conditions have reduced yields of wheat and corn by more than a third since the early 1960s.

Climate and agricultural models predict a worsening scenario. The production of corn, a leading crop that feeds billions around the world, could decline by 24 percent as early as 2030, according to a 2021 study conducted by NASA. While other staple foods, such as wheat, may actually see an increase in production, researchers say it’s important to diversify agriculture in order to foster resilient and sustainable food systems. In 2014, only nine crops accounted for two-thirds of global production, out of more than 6,000 cultivated plant species and more than 50,000 edible plants found on the planet.

Underutilized and hardy crops like the tepary bean could help diversify food production, said Richard Pratt, a plant scientist and professor at New Mexico State University. And their genetic material may help make other crops more drought- and heat-tolerant. Pratt took part in the September expedition, along with colleagues from the USDA and the Colombia-based International Center for Tropical Agriculture, or CIAT. They’re among a growing number of researchers, plant breeders, and other scientists working to both preserve overlooked wild crops — keeping them safe for future generations — as well as breeding more resilient plants in the race to adapt to climate change.

To wit: The University of California, Davis, is leading a multi-state $15 million project involving 20 institutions to speed up the breeding cycles of wheat and to research ways to help the crop thrive in a toughened environment. At Auburn University in Alabama, scientists are working to breed a peanut variety that can better tolerate drought conditions. In parts of Asia and Africa, some farmers already grow a high-stress tolerant “green super rice” developed by the International Rice Research Institute in the Philippines. And scientists from various institutions have taken part in a sprawling effort, funded by the Norwegian government, to identify, collect, and evaluate wild crops for future development.

For example, about 9,000 years ago, early Indigenous farmers in current-day Mexico transformed wild teosinte, a type of grass, into the single-stalked, plump corn produced around the world today.

As the science of genetics evolved, plant scientists could better select for a plant’s more desirable traits, like taste, color, and size, and develop improved varieties for cultivation. But capturing such limited traits can result in less genetic diversity, which may make plants more susceptible to diseases, pests, and environmental impact. For example, the Irish Potato Famine was in part due to farmers propagating their plants so that each potato was a clone of itself. When a fungus started infecting the root vegetable in the 1840s, much of the crop fell to rot, and about 1 million people died from starvation.

To avoid a similar agricultural catastrophe, scientists such as Pratt are turning to wild varieties, since they could offer valuable genetic traits that may have been overlooked in decades past.“There’s still probably a lot of genetic diversity in the wild tepary populations that are not present in the cultivated teparies,” Pratt said. By crossing the wild specimen with a black bean or a pinto bean, for example, scientists may be able to breed a new variety that can better endure similar harsh environmental conditions that its relative thrived in.

The first step, though, is finding crops that can offer those hardier genetic traits in the wild.

Similar to how Pratt and his New Mexico team have searched for the wild tepary bean, other plant scientists are working to collect and preserve close wild cousins of crops that can help develop climate-adapted varieties and ensure food security for a burgeoning global population.

“Crop wild relatives just have a tolerance to more extreme conditions,” said Perin McNelis, native plant program manager for the Borderlands Restoration Network, a conservation nonprofit in Southern Arizona. “They don’t have nutrient-rich soils and daily watering, so they’re just hardier.”

A couple of years ago, McNelis’ team set out with USDA staffers to collect the wild chiltepin that grows profusely under the protective shade of mesquite and ironwood trees in a vast protected area within the mountainous canyons of the borderlands. Scientists from near and far come to study the tiny, round red chiltepin, considered the mother of all peppers. The hot pepper also grows wild in parts of Texas, New Mexico, and Mexico.

The collection of wild chiltepin specimens, which were sent to USDA labs, McNelis said, will aid in future research and safeguarding of genetic material that may be used to breed improved crops.

A more massive collection of wild varieties of crops involved more than 100 scientists in 25 countries working with the Crop Trust, an international nonprofit based in Germany. The initiative, called the Crop Wild Relatives Project, was funded by the Norwegian government, and is co-managed by the Royal Botanic Gardens, Kew.

In 2018, scientists wrapped up six years of scouring far-reaching corners of the world for the wild plants. In its published report the following year, the organization said it had secured more than 4,600 seed samples of 371 wild relatives of domesticated crops, for distribution to global gene banks, which collect and store seeds, with the idea that scientists and breeders can then use those seeds for further research and development. Some of the varieties they found were not represented in the gene banks at all.

In some cases, collectors learned that some wild crops relatives had disappeared from their historical habitats. Others returned with specimens never collected before, including a tiny wild relative of the common bean growing near a Costa Rican beach. Scientists have already found useful traits in seed samples, including varying combinations of tolerance to drought, heat, and salinity in crops such as carrots, sorghum, and alfalfa.

“Crop wild relatives have been either ignored, forgotten, or seen as a threat to agriculture,” said Luis Salazar, a communications manager for the Crop Trust. “But they’ve been so resilient, they’ve been able to find a way to survive on their own.”

Those resilient traits, Salazar said, “are what we need now and what we’ll be needing more and more moving forward.”

Wild crop relatives may be tough, but they’re usually not suited for cultivation because they lack traits — such as good taste and rapid growth — that farmers want. The question, then, is how to develop new species that preserve the desirable traits of cultivated breeds, but are able to survive trying conditions.

Cultivating new plant species can take many approaches, but Pratt prefers conventional breeding methods: In New Mexico, he has grown different varieties of the viney, pod-bearing tepary plant on a campus field plot and other sites to see how well they adapt to the semi-arid soil. He selects plants with the characteristics he’s looking for, like drought resistance and high yield, which can then be used to create offspring with the desired characteristics.

As part of his research, Pratt has studied cultivated tepary varieties’ potential to produce high yields at different elevations and in mild to moderate drought stress. He’s found that “tepary beans don’t need as much water as common beans to produce a comparable yield,” he said.

With the hunt for wild teparies, Pratt and his colleagues hope to boost representation of the resilient bean in the collections of seeds, plants, and tissue cultures that gene banks preserve worldwide and share with farmers to feed the world. But, Pratt said, there’s still a lot of discussion about how best to integrate that beneficial genetic material into common beans that succumb to the heat or can potentially improve the hardiness of cultivated tepary beans.

Conventional breeding is not without limitations. It can often take many years to produce desired results, and selecting specific genetic characteristics without pulling in unwanted traits can be difficult.

Advances in genetic technologies have made it possible to speed up plant breeding. A plant’s genes are like a blueprint, outlining how it will look and what traits it will have. Plant geneticists can identify specific genes of interest in those blueprints more quickly than they have in the past, due largely to increasingly powerful DNA sequencing, which essentially read through the plants’ genetic material to identify genes and the traits that they control.

Scientists at McGill University in Montreal, for example, have sequenced the DNA of nearly 300 types of potatoes, including wild varieties, to create a “super pangenome” — a species’ entire set of genes. To do this, the researchers used gene banks, such as the ones that the Wild Crop Relatives Project helped populate. Sequencing the DNA is something like a roadmap that makes it easier to select traits that make potatoes more resistant to disease and environmental burdens, said Shelley Jansky, a longtime research geneticist with the USDA.

“That pangenome really gives us a very powerful tool for manipulating the genetics of the potato and creating potato plants that are better than what we have,” said Jansky, who recently retired and was not involved in the research, but specializes in potato genetics.

This article was originally published on Undark. Read the original article.

In late September, an international team of researchers fanned out across a remote New Mexico mountain range, in search of an elusive plant. The group trekked through the rugged landscape looking for signs of delicate vines hugging a tree, or lingering low on a dried creek bank.

After seven days in the desert scrubland, the scientists left with a sample of nature’s bounty: wild tepary bean plants.

The scientists wanted to collect the legume, which is native to arid regions of the southwestern United States and northwestern Mexico, for its hardy constitution: “They have evolved in this very hot, dry climate, so they have exceptional drought and heat tolerance, and potential tolerance to some extreme soil conditions as well,” said Sarah Dohle, a bean curator with the U.S. Department of Agriculture, who was part of the New Mexico collection effort.

Those qualities could prove beneficial on a warming planet, as scientists figure out how to breed beans, peppers, potatoes, and various other grains, fruits, and vegetables that can withstand the harsh conditions of a changing climate.

Such effects are already wreaking havoc on agriculture around the globe. In the western U.S., a severe drought crushed California’s tomato and rice production. In Guatemala, the combined effects of both drought and rain devastated corn and black bean harvests, both major food staples. In Sub-Saharan Africa, searing conditions have reduced yields of wheat and corn by more than a third since the early 1960s.

Climate and agricultural models predict a worsening scenario. The production of corn, a leading crop that feeds billions around the world, could decline by 24 percent as early as 2030, according to a 2021 study conducted by NASA. While other staple foods, such as wheat, may actually see an increase in production, researchers say it’s important to diversify agriculture in order to foster resilient and sustainable food systems. In 2014, only nine crops accounted for two-thirds of global production, out of more than 6,000 cultivated plant species and more than 50,000 edible plants found on the planet.

Underutilized and hardy crops like the tepary bean could help diversify food production, said Richard Pratt, a plant scientist and professor at New Mexico State University. And their genetic material may help make other crops more drought- and heat-tolerant. Pratt took part in the September expedition, along with colleagues from the USDA and the Colombia-based International Center for Tropical Agriculture, or CIAT. They’re among a growing number of researchers, plant breeders, and other scientists working to both preserve overlooked wild crops — keeping them safe for future generations — as well as breeding more resilient plants in the race to adapt to climate change.

To wit: The University of California, Davis, is leading a multi-state $15 million project involving 20 institutions to speed up the breeding cycles of wheat and to research ways to help the crop thrive in a toughened environment. At Auburn University in Alabama, scientists are working to breed a peanut variety that can better tolerate drought conditions. In parts of Asia and Africa, some farmers already grow a high-stress tolerant “green super rice” developed by the International Rice Research Institute in the Philippines. And scientists from various institutions have taken part in a sprawling effort, funded by the Norwegian government, to identify, collect, and evaluate wild crops for future development.

For example, about 9,000 years ago, early Indigenous farmers in current-day Mexico transformed wild teosinte, a type of grass, into the single-stalked, plump corn produced around the world today.

As the science of genetics evolved, plant scientists could better select for a plant’s more desirable traits, like taste, color, and size, and develop improved varieties for cultivation. But capturing such limited traits can result in less genetic diversity, which may make plants more susceptible to diseases, pests, and environmental impact. For example, the Irish Potato Famine was in part due to farmers propagating their plants so that each potato was a clone of itself. When a fungus started infecting the root vegetable in the 1840s, much of the crop fell to rot, and about 1 million people died from starvation.

To avoid a similar agricultural catastrophe, scientists such as Pratt are turning to wild varieties, since they could offer valuable genetic traits that may have been overlooked in decades past.“There’s still probably a lot of genetic diversity in the wild tepary populations that are not present in the cultivated teparies,” Pratt said. By crossing the wild specimen with a black bean or a pinto bean, for example, scientists may be able to breed a new variety that can better endure similar harsh environmental conditions that its relative thrived in.

The first step, though, is finding crops that can offer those hardier genetic traits in the wild.

Similar to how Pratt and his New Mexico team have searched for the wild tepary bean, other plant scientists are working to collect and preserve close wild cousins of crops that can help develop climate-adapted varieties and ensure food security for a burgeoning global population.

“Crop wild relatives just have a tolerance to more extreme conditions,” said Perin McNelis, native plant program manager for the Borderlands Restoration Network, a conservation nonprofit in Southern Arizona. “They don’t have nutrient-rich soils and daily watering, so they’re just hardier.”

A couple of years ago, McNelis’ team set out with USDA staffers to collect the wild chiltepin that grows profusely under the protective shade of mesquite and ironwood trees in a vast protected area within the mountainous canyons of the borderlands. Scientists from near and far come to study the tiny, round red chiltepin, considered the mother of all peppers. The hot pepper also grows wild in parts of Texas, New Mexico, and Mexico.

The collection of wild chiltepin specimens, which were sent to USDA labs, McNelis said, will aid in future research and safeguarding of genetic material that may be used to breed improved crops.

A more massive collection of wild varieties of crops involved more than 100 scientists in 25 countries working with the Crop Trust, an international nonprofit based in Germany. The initiative, called the Crop Wild Relatives Project, was funded by the Norwegian government, and is co-managed by the Royal Botanic Gardens, Kew.

In 2018, scientists wrapped up six years of scouring far-reaching corners of the world for the wild plants. In its published report the following year, the organization said it had secured more than 4,600 seed samples of 371 wild relatives of domesticated crops, for distribution to global gene banks, which collect and store seeds, with the idea that scientists and breeders can then use those seeds for further research and development. Some of the varieties they found were not represented in the gene banks at all.

In some cases, collectors learned that some wild crops relatives had disappeared from their historical habitats. Others returned with specimens never collected before, including a tiny wild relative of the common bean growing near a Costa Rican beach. Scientists have already found useful traits in seed samples, including varying combinations of tolerance to drought, heat, and salinity in crops such as carrots, sorghum, and alfalfa.

“Crop wild relatives have been either ignored, forgotten, or seen as a threat to agriculture,” said Luis Salazar, a communications manager for the Crop Trust. “But they’ve been so resilient, they’ve been able to find a way to survive on their own.”

Those resilient traits, Salazar said, “are what we need now and what we’ll be needing more and more moving forward.”

Wild crop relatives may be tough, but they’re usually not suited for cultivation because they lack traits — such as good taste and rapid growth — that farmers want. The question, then, is how to develop new species that preserve the desirable traits of cultivated breeds, but are able to survive trying conditions.

Cultivating new plant species can take many approaches, but Pratt prefers conventional breeding methods: In New Mexico, he has grown different varieties of the viney, pod-bearing tepary plant on a campus field plot and other sites to see how well they adapt to the semi-arid soil. He selects plants with the characteristics he’s looking for, like drought resistance and high yield, which can then be used to create offspring with the desired characteristics.

As part of his research, Pratt has studied cultivated tepary varieties’ potential to produce high yields at different elevations and in mild to moderate drought stress. He’s found that “tepary beans don’t need as much water as common beans to produce a comparable yield,” he said.

With the hunt for wild teparies, Pratt and his colleagues hope to boost representation of the resilient bean in the collections of seeds, plants, and tissue cultures that gene banks preserve worldwide and share with farmers to feed the world. But, Pratt said, there’s still a lot of discussion about how best to integrate that beneficial genetic material into common beans that succumb to the heat or can potentially improve the hardiness of cultivated tepary beans.

Conventional breeding is not without limitations. It can often take many years to produce desired results, and selecting specific genetic characteristics without pulling in unwanted traits can be difficult.

Advances in genetic technologies have made it possible to speed up plant breeding. A plant’s genes are like a blueprint, outlining how it will look and what traits it will have. Plant geneticists can identify specific genes of interest in those blueprints more quickly than they have in the past, due largely to increasingly powerful DNA sequencing, which essentially read through the plants’ genetic material to identify genes and the traits that they control.

Scientists at McGill University in Montreal, for example, have sequenced the DNA of nearly 300 types of potatoes, including wild varieties, to create a “super pangenome” — a species’ entire set of genes. To do this, the researchers used gene banks, such as the ones that the Wild Crop Relatives Project helped populate. Sequencing the DNA is something like a roadmap that makes it easier to select traits that make potatoes more resistant to disease and environmental burdens, said Shelley Jansky, a longtime research geneticist with the USDA.

“That pangenome really gives us a very powerful tool for manipulating the genetics of the potato and creating potato plants that are better than what we have,” said Jansky, who recently retired and was not involved in the research, but specializes in potato genetics.

This article was originally published on Undark. Read the original article.