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DNA and Tree Populus trichocarpa

Life too complex to fit into computer algorithm

A new computer model aims to predict genetic changes that have unintended consequences in trees that researchers genetically modify. However, it is highly unlikely to be effective as it greatly underestimates the complexity of genetic functioning, warns Dr Michael Antoniou, a genetic engineer unconnected with the research.

The background to the new model, details of which are published in a new paper in PLOS Computational Biology, is that researchers are trying to genetically modify trees for a variety of applications, from biofuels to paper production – but they want to steer clear of modifications with unintended consequences. These consequences can arise when intended modifications to one gene result in unexpected changes in the function of other genes.

The new computer model is intended to predict these changes, enabling researchers to avoid unintended consequences that may negatively impact on the tree’s growth and other characteristics and thus pave the way for more efficient research in genetically modified trees.

The research focuses on lignin, a complex material found in trees that helps to give trees their structure. It is, in effect, what makes wood feel like wood.

“Whether you want to use wood as a biofuel source or to create pulp and paper products, there is a desire to modify the chemical structure of lignin by manipulating lignin-specific genes, resulting in lignin that is easier to break down,” says Cranos Williams, corresponding author of a paper on the work and an associate professor of electrical and computer engineering at North Carolina (NC) State University (USA). “However, you don’t want to make changes to a tree’s genome that compromise its ability to grow or thrive.”

The researchers focused on a tree called Populus trichocarpa, which is a widely used model organism – meaning that scientists who study genetics and tree biology spend a lot of time studying P. trichocarpa.

“Previous research generated models that predict how independent changes to the expression of lignin genes impacted lignin characteristics,” says Megan Matthews, first author of the paper, a former PhD student at NC State and a current postdoc at the University of Illinois. “These models, however, do not account for cross-regulatory influences between the genes. So when we modify a targeted gene, the existing models do not accurately predict the changes we see in how non-targeted genes are being expressed. Not capturing these changes in expression of non-targeted genes hinders our ability to develop accurate gene modification strategies, increasing the possibility of unintended outcomes in lignin and wood traits.

“To address this challenge, we developed a model that was able to predict the direct and indirect changes across all of the lignin genes, capturing the effects of multiple types of regulation. This allows us to predict how the expression of the non-targeted genes is impacted, as well as the expression of the targeted genes,” Matthews says.

“Another of the key merits of this work, versus other models of gene regulation, is that previous models only looked at how the RNA is impacted when genes are modified,” Matthews says. “Those models assume the proteins will be impacted in the same way, but that’s not always the case. Our model is able to capture some of the changes to proteins that aren’t seen in the RNA, or vice versa.

“This model could be incorporated into larger, multi-scale models, providing a computational tool for exploring new approaches to genetically modifying tree species to improve lignin traits for use in a variety of industry sectors.”

Dangers of narrow focus

Commenting on the new research, the London-based molecular geneticist Dr Michael Antoniou warned that it is too narrowly focused to solve the issues of unintended effects from the genetic engineering of trees.

Dr Antoniou said, "It's good that these researchers are acknowledging that changing one gene can affect functioning of others. But focusing just on the lignin pathway is far too restrictive – we also have to consider the rest of the plant. Genomes function as an integrated network, an ‘omnigenic’ totality, so the functioning of genes of one biosynthetic pathway will be linked to the functioning of everything else. Using genetic engineering to make changes to the lignin pathway will thus also affect other pathways.”

Dr Antoniou continued, "No one can model this with a computer algorithm because it is too complex. A blind faith in computer programs is misplaced, as they are only as good as the inputs that go into writing them. Tens of thousands of genes, and all their possible interactions, would have to be factored into the program. If you start with an incomplete knowledge base, then your computer predictions will also miss the mark."

GMWatch adds that the researchers do not appear to be thinking of biosafety considerations, but rather efficient product development. They are therefore not considering aspects crucial to environmental sustainability, such as the likelihood that reduced lignin, or alterations in the balance of different types of lignin, will make the GM trees more susceptible to pests and diseases, leading to increased pesticide use and even to crashes in tree populations through pest or disease attack. It's not only the GM trees that could be affected in this way, but also any crosses with wild relatives resulting from GM contamination through cross-pollination.

In addition, the researchers have not looked at whether unexpected new proteins have been produced in the trees, which could lead to toxicity to wildlife species. Therefore the new research could lead GMO developers and regulators to falsely claim safety and predictability of GM technology where in fact, they do not exist.

Details of the new paper

The new paper, “Modeling cross-regulatory influences on monolignol transcripts and proteins under single and combinatorial gene knockdowns in Populus trichocarpa,” is published in the journal PLOS Computational Biology. The paper was co-authored by Ronald Sederoff, a professor emeritus of forestry and environmental resources at NC State; Jack Wang, an assistant professor of forestry and environmental resources at NC State; and Vincent Chiang, a Jordan Family Distinguished Professor Emeritus and Alumni Outstanding Research Professor with the Forest Biotechnology Group at NC State.

This work was supported by the National Science Foundation Grant DBI-0922391 to Chiang and by a National Physical Science Consortium Graduate Fellowship to Matthews.

Report by Claire Robinson
Source for researchers’ comments: NC State University
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Modeling cross-regulatory influences on monolignol transcripts and proteins under single and combinatorial gene knockdowns in Populus trichocarpa
Megan L. Matthews, Jack P. Wang, Ronald Sederoff, Vincent L. Chiang, Cranos M. Williams
PLOS Computational Biology, April 10, 2020
https://doi.org/10.1371/journal.pcbi.1007197

Abstract

Accurate manipulation of metabolites in monolignol biosynthesis is a key step for controlling lignin content, structure, and other wood properties important to the bioenergy and biomaterial industries. A crucial component of this strategy is predicting how single and combinatorial knockdowns of monolignol specific gene transcripts influence the abundance of monolignol proteins, which are the driving mechanisms of monolignol biosynthesis. Computational models have been developed to estimate protein abundances from transcript perturbations of monolignol specific genes. The accuracy of these models, however, is hindered by their inability to capture indirect regulatory influences on other pathway genes. Here, we examine the manifestation of these indirect influences on transgenic transcript and protein abundances, identifying putative indirect regulatory influences that occur when one or more specific monolignol pathway genes are perturbed. We created a computational model using sparse maximum likelihood to estimate the resulting monolignol transcript and protein abundances in transgenic Populus trichocarpa based on targeted knockdowns of specific monolignol genes. Using in-silico simulations of this model and root mean square error, we showed that our model more accurately estimated transcript and protein abundances, in comparison to previous models, when individual and families of monolignol genes were perturbed. We leveraged insight from the inferred network structure obtained from our model to identify potential genes, including PtrHCT, PtrCAD, and Ptr4CL, involved in post-transcriptional and/or post-translational regulation. Our model provides a useful computational tool for exploring the cascaded impact of single and combinatorial modifications of monolignol specific genes on lignin and other wood properties.