By Peter Newman
Evolution is pretty wild. A random mutation occurs, and if that is beneficial, the mutation becomes dominant over generations and the species evolves. Does it always happen in one individual and then spread, or can the same trait evolve in different places at the same time?
The latter.
In this recent AHRI research, the same glufosinate resistance mechanism appeared in China and Malaysia at the same time.
Glufosinate (Liberty or Basta) is ″the other″ knockdown herbicide. We don’t use a whole lot of it in Australia at present, but we’re starting to with the release of Liberty Link crops that can tolerate the herbicide. Glufosinate has been used globally for about 30 years, but we currently have low levels of resistance to this herbicide. Global use of glufosinate is increasing in tolerant crops, and as a knockdown herbicide in countries where paraquat has been banned.
AHRI researchers Dr Qin Yu and Dr Heping Han recently teamed up with some visiting Chinese researchers to describe the glufosinate resistance mechanism. They found the same single point, target-site mutation, Ser59Gly in resistant Eleusine indica (Crowsfoot grass) populations from Malaysia and China. The plants had relatively low-level resistance, but given that this mutation evolved independently in different countries, it appears that this may represent a common target-site resistance mechanism to glufosinate.
Once again, our researchers put us in the fortunate position of understanding resistance to a herbicide before its widespread use in Australia.
How glufosinate works
When plants metabolise nitrogen, they use the reaction below to join Ammonia onto glutamate to form glutamine. The enzyme glutamine synthase is a critical part of this reaction. The herbicide glufosinate works like most other herbicides, it binds to an enzyme. In this case the enzyme is glutamine synthase. When this reaction stops, Ammonia builds up to toxic levels and the plant dies.
How glufosinate resistance works
The Ser59Gly rotation is a single point mutation on the glutamine synthase enzyme. The mutation isn’t right in the catalytic centre of the enzyme (as resistance mutations often are), rather it is near the catalytic centre. The mutation is just enough to indirectly influence the binding of glufosinate.
Transgenic breeding of resistant rice
To confirm that the Ser59Gly mutation is the cause of resistance, the researchers use what is now a common lab technique to develop rice that contains that exact mutation using transgenic techniques. The photo below shows susceptible rice at the front with the transgenic rice at the rear at nil or 990g/ha of glufosinate. The low-level resistance is evident here as the glufosinate damages the resistance plants, but not enough to kill them outright.
Low level resistance
The glufosinate resistance is only about 2.5 fold. The dose response curve below shows the susceptible (WT – Wild Type) rice population versus plants with the Ser59Gly mutation. There is a definite shift in dose response, albeit low level resistance. However, glufosinate is known to be a product that often requires two sequential applications of product at robust rates in good conditions to kill the weeds, so any shift in dose response is significant.
Glufosinate dose response of transgenic rice T2 seedlings expressing a single copy of EiGS1-1-R59 versus EiGS1-1-WT. Plants were treated at the three- to four-leaf stage, and survival rate was determined 3 weeks after treatment. Data are means ±SE of pooled results of three WT and three R59 lines.
Summary
Glufosinate could soon become a useful herbicide in Australia as we adopt glufosinate tolerant crops. It’s good to know that internationally, resistance to this herbicide is rare, and when we do face resistance issues we know where to start looking to determine the mechanism.
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