By Kay Ledbetter
Knowing what diseases are turning wheat fields yellow is half the battle, according to a Texas A&M AgriLife Research plant pathologist in Amarillo. And sometimes, there’s more going on than expected.
Mite-vectored wheat streak mosaic virus, triticum mosaic virus and wheat mosaic virus or High Plains virus were the focus of a High Plains survey in 2017.
Dr. Charlie Rush spent the end of the 2017 wheat season conducting a survey of fields exhibiting yellowing. He and his team were in search of the mite-vectored wheat streak mosaic virus, triticum mosaic virus and wheat mosaic virus or High Plains virus. They also identified barley yellow dwarf virus, which is transmitted by aphids.
Mite-vectored virus diseases are the predominant pathogenic constraint to sustainable wheat production each year, as major productivity losses can occur to both grain and forage yields in wheat with these viruses.
“It is difficult to tell for sure in the field whether a particular symptom is caused by wheat streak or something else, and the only way to know for sure is to take the sample into the plant diagnostic lab and have it tested,” Rush said.
He and his team did just that. With help from county agents, samples brought to the Amarillo lab and traveling the back roads of the Panhandle, his team collected 648 samples from 25 counties.
Rush said they were very selective in what they did, making sure the sick plants collected were not suffering from nitrogen deficiency or water flooding.
While samples were solicited from Lubbock north and from Wichita Falls west to the New Mexico line, the majority of the samples came from around Amarillo and in the northern Panhandle.
“The reason we did this survey is because in 2008, a large survey of the Great Plains was conducted and Texas had 60-70 percent of the samples testing positive for wheat streak and 30 percent positive for triticum,” Rush said. “That survey wasn’t as targeted as we would have liked. In 2013, another survey was done in the northern Great Plains targeting just triticum, but Texas was not included.
“We decided to do another survey to see where we are,” he said. “A lot of cultivars have been released by different breeding programs across the Great Plains with resistance to wheat streak. But we also have triticum out there – we had the highest percent in the first survey.
“If the resistance genes being introduced into new cultivars are only effective against wheat streak mosaic virus and not effective against triticum, we would inadvertently be selecting for triticum mosaic virus.”
Know what is turning wheat fields yellow is half the battle; in this case it is wheat streak mosaic virus and not drought conditions.
Rush said the 2017 samples were first run through the common enzyme-linked immunosorbent assay or ELISA test for the virus.
“It is not the most sensitive test, but it is the least expensive,” he said. “We found we had about 80 percent positive for wheat streak and about 30-35 percent for triticum; about what we found in 2008.”
But Rush said he typically uses the more sensitive, more expensive polymerase chain reaction or PCR test in his research now because it allows him to quantify how much virus is in the plant.
So he went back and ran the samples and found 100 percent tested positive for wheat streak and 93 percent of the samples tested positive for triticum.
“So our concern now is that triticum is so much more widespread out there than we had previously thought,” Rush said.
A variety of mite-vectored wheat disease damage can be seen in wheat plots near Bushland, while the border of TAM 204 shows good resistance.
He said they also collected mites off the plants to test them for the different viruses, and they still need to do some variety testing using a mite population collected from the field. They will screen different lines of wheat to see how much resistance they have to triticum.
“It will be important that breeding programs look at triticum as a major virus that needs resistance incorporated,” Rush said. “It would be even better if we could find durable resistance to the wheat curl mite.
“For instance, TAM 112 has resistance to the wheat curl mite, the vector for wheat streak and triticum. If they can capture the resistance in TAM 112 to the wheat curl mite and if that resistance remains durable – won’t break down – that would be the very best outcome because the resistance against the mite vector would essentially confer resistance against all the viruses the mites transmit.”
The plants wouldn’t really be resistant to the virus, he explained saying they could artificially infect plants in the greenhouse and they would get the disease. But for all practical purposes, the plants in the field would be more resistant to the diseases because populations of mites transmitting and spreading the viruses would never build up, thus limiting disease spread.
“We think our survey has been very informative, telling us that it is important to consider triticum as a widespread pathogen and also diagnostic labs throughout the Great Plains cannot simply use the ELISA test, because it is not sensitive enough or as accurate as PCR,” Rush said.Click here to see more...