Bt Crops with Multiple Toxins Not As Effective As Assumed

THIRD WORLD NETWORK BIOSAFETY INFORMATION SERVICE 
Dear Friends and Colleagues 
Bt crops with multiple toxins not as effective as assumed 

Commercially grown since 1996, the first generation of genetically engineered (GE) insect-resistant crops produced a single toxin of Bacillus thuringiensis (Bt) to kill specific insect pests. However, in some cases, the pests quickly developed resistance to the toxin. To delay the evolution of such resistance, the biotech industry subsequently developed Bt crops called “pyramids” to produce two or more Bt toxins to kill the same pests. These have been adopted in many countries including the U.S. since 2003.  

A meta-analysis led by the University of Arizona to assess the potential of pyramids to achieve the goal of delaying resistance, analyzed data from 38 studies reporting the effects of ten Bt toxins used in GE crops against 15 insect pests. The researchers found that in about half the cases, the actual efficacy of the pyramids against pests did not live up to expectations. In fact, contrary to the ideal scenario typically assumed in simulation modelling, resistance to one toxin in a pyramid often caused cross-resistance to another toxin in the same pyramid. This, according to the researchers, was due to amino acid sequence similarity in two particular domains. 

These findings have an important bearing on the size of refuges needed to delay pest resistance to Bt crops. The widely used refuge strategy is based on the idea of planting non-Bt plants near or in fields of Bt crops to host susceptible pests that will mate with any Bt-resistant insects. Assumptions of higher than actual efficacy of a Bt crop may lead farmers to prepare smaller than effective refuges.  

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Item 1

OPTIMIZING PYRAMIDED TRANSGENIC BT CROPS FOR SUSTAINABLE PEST MANAGEMENT 

Carrière, Y., Crickmore, N., Tabashnik, B.E. (2015)
Nature Biotechnology.
http://www.nature.com/nbt/journal/vaop/ncurrent/full/nbt.3099.html

Abstract

Transgenic crop pyramids producing two or more Bacillus thuringiensis (Bt) toxins that kill the same insect pest have been widely used to delay evolution of pest resistance. To assess the potential of pyramids to achieve this goal, we analyze data from 38 studies that report effects of ten Bt toxins used in transgenic crops against 15 insect pests. We find that compared with optimal low levels of insect survival, survival on currently used pyramids is often higher for both susceptible insects and insects resistant to one of the toxins in the pyramid. Furthermore, we find that cross-resistance and antagonism between toxins used in pyramids are common, and that these problems are associated with the similarity of the amino acid sequences of domains II and III of the toxins, respectively. This analysis should assist in future pyramid design and the development of sustainable resistance management strategies.

 
Item 2 
TRANSGENIC CROPS: MULTIPLE TOXINS NOT A PANACEA FOR PEST CONTROL  
University of Arizona

Overly optimistic assumptions about transgenic crops that produce two or more Bt toxins active against the same pest can lead to inadequate strategies for delaying evolution of pest resistance

Strategies for delaying insect resistance to transgenic crops rely on assumptions that often are overly optimistic, a new study led by UA scientists shows. Published as an advance online publication by the journal Nature Biotechnology, the findings could improve management practices for current biotech crops and promote development of new varieties that are more effective and more durable. 

Crops genetically engineered to produce proteins from the bacterium Bacillus thuringiensis (Bt) to control insect pests have been planted on a cumulative total of more than a billion acres worldwide since 1996. With some pests rapidly evolving resistance to Bt crops that make only one toxin, biotech companies introduced Bt crops called "pyramids" that produce two or more Bt toxins active against the same pest. Such pyramids have been adopted in many countries since 2003, including the United States, India and Australia. 

To assess the potential of pyramids to delay evolution of resistance by pests, the paper’s lead author, Yves Carrière, and co-author Bruce Tabashnik, both in the College of Agriculture and Life Sciences, analyzed data from 38 studies that report effects of 10 Bt toxins used in transgenic crops against 15 insect pests. They found that in many cases, the crops’ actual efficacy against pests did not live up to the expectations used to inform computer simulation models that aim to predict the evolution of pest resistance. Thus, the simulations could underestimate how quickly pests adapt to Bt crops and lead to inadequate management guidelines. 

"The idea behind Bt crop pyramids can be explained with a lock-and-key analogy," said Tabashnik, who heads the UA’s Department of Entomology and also is a member of the UA’s BIO5 Institute. "The lock on the door is the receptor protein in the insect’s gut, and the key is the Bt toxin that binds to that receptor. To be able to kill the insect, the toxin must fit the lock to open the door and get inside. 

"If you have only one key – one toxin – and a mutation has changed the lock – the receptor – then the toxin can’t open the door and get inside. The insect is resistant and survives. Now imagine you have two keys, one for the front door and a different one for the back door. Let’s say you’re trying to get in through the front door, but the key doesn’t work because the lock has changed. Your second key will get you in through the back door, provided the lock there hasn’t changed as well. So, if you can’t kill the insect one way, you can kill it another way. That’s how pyramids work. It’s like having two different keys, so the insect needs two different mutations to become resistant." 

However, the scenario described above is an ideal situation that is often not achieved in the real world, according to the new study. At the other extreme, some Bt crop pyramids could have two toxins that bind to the same receptor. 

"In that scenario, the keys are so similar that each only opens the front door, and if that lock is changed, you’re out of luck," Tabashnik said. 

The reality, the authors found in this study, is often somewhere in between. 

"If each toxin is highly effective on its own and two toxins act independently, the pyramid should kill at least 99.75 percent of the Bt-susceptible pests," explained Carrière, a professor of entomology in the UA’s College of Agriculture and Life Sciences. "In other words, fewer than three of every thousand susceptible insects should survive." 

Scrutinizing the scientific literature, Carrière and Tabashnik discovered that this assumption was met only in about half of the cases. They also found that, contrary to the ideal scenario typically assumed, selection for resistance to one toxin in a pyramid often causes cross-resistance to another toxin in the pyramid. 

One goal of this study, Carrière explained, is to help biotech companies decide which toxins to put in their pyramided crops based on data that already exist, rather than by a time-consuming process of trial and error. "Will two toxins behave as one key or two keys, or somewhere in between?" he said. "And can we use understanding of how these toxins work to answer that question?" 

To help find answers, Neil Crickmore of the University of Sussex, an expert in Bt toxin structure and function who co-authored the study, used data available online to analyze the similarity of toxins in each of their three component parts, called domains. Consistent with previous biochemical work showing that the middle domain of the toxins plays a key role in binding to receptors, the new study shows that cross-resistance between toxins is associated with their amino acid sequence similarity in this domain. Results from the new study also indicate that amino acid sequence similarity in another domain contributes to mortality of Bt-susceptible insects on pyramids. 

"We identified specific domains involved in expression of traits that govern evolution of resistance to pyramids, and propose that toxins with different amino acid similarity in these domains could be combined to produce more effective and durable pyramids," Carrière said. "With the available technology, it is now possible to swap domains and engineer each Bt toxin with the desired domain configuration. The information provided in our study could help the design of such chimeric toxins used in pyramids." 

The authors emphasized that their work provides the community with systematic procedures that can be used by anyone working on these questions, including larger datasets and other toxins. 

"Our results mean that the keys – toxins – used in Bt crops by farmers worldwide are often not as different from each other as we would like," Tabashnik said. "And that, in turn, has huge implications for agencies tasked with setting standards for the size of refuges to be planted." 

The refuge strategy is the primary approach used to delay pest resistance to Bt crops in the United States and elsewhere. This strategy is based on the idea that refuges, which consist of non-Bt host plants near or in fields of Bt crops, produce susceptible pests that mate with the rare resistant individuals surviving on Bt crops. In Arizona, the refuge strategy worked brilliantly against the pink bollworm, where the pest had plagued cotton farmers for a century but is now scarce. In India, on the other hand, where farmers did not plant refuges, pink bollworm rapidly evolved resistance to Bt cotton. 

The data from this study could help modelers make more accurate predictions of how a certain pyramided Bt crop will perform and help policy makers determine refuge strategies more realistically. 

"We provide a realistic assessment of which Bt toxins do meet the two-key assumption and work well together so farmers can use small refuges," Tabashnik said, "and which ones are closer to the one-key scenario, so larger refuges are needed or we’ll have problems."

Bt Crops with Multiple Toxins Not As Effective As Assumed

Item 1

OPTIMIZING PYRAMIDED TRANSGENIC BT CROPS FOR SUSTAINABLE PEST MANAGEMENT 

Carrière, Y., Crickmore, N., Tabashnik, B.E. (2015)
Nature Biotechnology.
http://www.nature.com/nbt/journal/vaop/ncurrent/full/nbt.3099.html

Abstract

Transgenic crop pyramids producing two or more Bacillus thuringiensis (Bt) toxins that kill the same insect pest have been widely used to delay evolution of pest resistance. To assess the potential of pyramids to achieve this goal, we analyze data from 38 studies that report effects of ten Bt toxins used in transgenic crops against 15 insect pests. We find that compared with optimal low levels of insect survival, survival on currently used pyramids is often higher for both susceptible insects and insects resistant to one of the toxins in the pyramid. Furthermore, we find that cross-resistance and antagonism between toxins used in pyramids are common, and that these problems are associated with the similarity of the amino acid sequences of domains II and III of the toxins, respectively. This analysis should assist in future pyramid design and the development of sustainable resistance management strategies.

 
Item 2 
 
TRANSGENIC CROPS: MULTIPLE TOXINS NOT A PANACEA FOR PEST CONTROL  
 
University of Arizona

Overly optimistic assumptions about transgenic crops that produce two or more Bt toxins active against the same pest can lead to inadequate strategies for delaying evolution of pest resistance

Strategies for delaying insect resistance to transgenic crops rely on assumptions that often are overly optimistic, a new study led by UA scientists shows. Published as an advance online publication by the journal Nature Biotechnology, the findings could improve management practices for current biotech crops and promote development of new varieties that are more effective and more durable. 

Crops genetically engineered to produce proteins from the bacterium Bacillus thuringiensis (Bt) to control insect pests have been planted on a cumulative total of more than a billion acres worldwide since 1996. With some pests rapidly evolving resistance to Bt crops that make only one toxin, biotech companies introduced Bt crops called "pyramids" that produce two or more Bt toxins active against the same pest. Such pyramids have been adopted in many countries since 2003, including the United States, India and Australia. 

To assess the potential of pyramids to delay evolution of resistance by pests, the paper’s lead author, Yves Carrière, and co-author Bruce Tabashnik, both in the College of Agriculture and Life Sciences, analyzed data from 38 studies that report effects of 10 Bt toxins used in transgenic crops against 15 insect pests. They found that in many cases, the crops’ actual efficacy against pests did not live up to the expectations used to inform computer simulation models that aim to predict the evolution of pest resistance. Thus, the simulations could underestimate how quickly pests adapt to Bt crops and lead to inadequate management guidelines. 

"The idea behind Bt crop pyramids can be explained with a lock-and-key analogy," said Tabashnik, who heads the UA’s Department of Entomology and also is a member of the UA’s BIO5 Institute. "The lock on the door is the receptor protein in the insect’s gut, and the key is the Bt toxin that binds to that receptor. To be able to kill the insect, the toxin must fit the lock to open the door and get inside. 

"If you have only one key – one toxin – and a mutation has changed the lock – the receptor – then the toxin can’t open the door and get inside. The insect is resistant and survives. Now imagine you have two keys, one for the front door and a different one for the back door. Let’s say you’re trying to get in through the front door, but the key doesn’t work because the lock has changed. Your second key will get you in through the back door, provided the lock there hasn’t changed as well. So, if you can’t kill the insect one way, you can kill it another way. That’s how pyramids work. It’s like having two different keys, so the insect needs two different mutations to become resistant." 

However, the scenario described above is an ideal situation that is often not achieved in the real world, according to the new study. At the other extreme, some Bt crop pyramids could have two toxins that bind to the same receptor. 

"In that scenario, the keys are so similar that each only opens the front door, and if that lock is changed, you’re out of luck," Tabashnik said. 

The reality, the authors found in this study, is often somewhere in between. 

"If each toxin is highly effective on its own and two toxins act independently, the pyramid should kill at least 99.75 percent of the Bt-susceptible pests," explained Carrière, a professor of entomology in the UA’s College of Agriculture and Life Sciences. "In other words, fewer than three of every thousand susceptible insects should survive." 

Scrutinizing the scientific literature, Carrière and Tabashnik discovered that this assumption was met only in about half of the cases. They also found that, contrary to the ideal scenario typically assumed, selection for resistance to one toxin in a pyramid often causes cross-resistance to another toxin in the pyramid. 

One goal of this study, Carrière explained, is to help biotech companies decide which toxins to put in their pyramided crops based on data that already exist, rather than by a time-consuming process of trial and error. "Will two toxins behave as one key or two keys, or somewhere in between?" he said. "And can we use understanding of how these toxins work to answer that question?" 

To help find answers, Neil Crickmore of the University of Sussex, an expert in Bt toxin structure and function who co-authored the study, used data available online to analyze the similarity of toxins in each of their three component parts, called domains. Consistent with previous biochemical work showing that the middle domain of the toxins plays a key role in binding to receptors, the new study shows that cross-resistance between toxins is associated with their amino acid sequence similarity in this domain. Results from the new study also indicate that amino acid sequence similarity in another domain contributes to mortality of Bt-susceptible insects on pyramids. 

"We identified specific domains involved in expression of traits that govern evolution of resistance to pyramids, and propose that toxins with different amino acid similarity in these domains could be combined to produce more effective and durable pyramids," Carrière said. "With the available technology, it is now possible to swap domains and engineer each Bt toxin with the desired domain configuration. The information provided in our study could help the design of such chimeric toxins used in pyramids." 

The authors emphasized that their work provides the community with systematic procedures that can be used by anyone working on these questions, including larger datasets and other toxins. 

"Our results mean that the keys – toxins – used in Bt crops by farmers worldwide are often not as different from each other as we would like," Tabashnik said. "And that, in turn, has huge implications for agencies tasked with setting standards for the size of refuges to be planted." 

The refuge strategy is the primary approach used to delay pest resistance to Bt crops in the United States and elsewhere. This strategy is based on the idea that refuges, which consist of non-Bt host plants near or in fields of Bt crops, produce susceptible pests that mate with the rare resistant individuals surviving on Bt crops. In Arizona, the refuge strategy worked brilliantly against the pink bollworm, where the pest had plagued cotton farmers for a century but is now scarce. In India, on the other hand, where farmers did not plant refuges, pink bollworm rapidly evolved resistance to Bt cotton. 

The data from this study could help modelers make more accurate predictions of how a certain pyramided Bt crop will perform and help policy makers determine refuge strategies more realistically. 

"We provide a realistic assessment of which Bt toxins do meet the two-key assumption and work well together so farmers can use small refuges," Tabashnik said, "and which ones are closer to the one-key scenario, so larger refuges are needed or we’ll have problems."

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