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Machine learning can pinpoint genes of importance that help crops to grow with less fertilizer, according to a new study published in Nature Communications. It can also predict additional traits in plants and disease outcomes in animals, illustrating its applications beyond agriculture.

Using genomic data to predict outcomes in agriculture and medicine is both a promise and challenge for systems biology. Researchers have been working to determine how to best use the vast amount of genomic data available to predict how organisms respond to changes in nutrition, toxins, and pathogen exposurewhich in turn would inform crop improvement, disease prognosis, epidemiology, and public health. However, accurately predicting such complex outcomes in agriculture and medicine from genome-scale information remains a significant challenge.

In the Nature Communications study, NYU researchers and collaborators in the U.S. and Taiwan tackled this challenge using machine learning, a type of artificial intelligence used to detect patterns in data.

We show that focusing on genes whose expression patterns are evolutionarily conserved across species enhances our ability to learn and predict genes of importance to growth performance for staple crops, as well as disease outcomes in animals, explained Gloria Coruzzi, Carroll & Milton Petrie Professor in NYUs Department of Biology and Center for Genomics and Systems Biology and the papers senior author.

Our approach exploits the natural variation of genome-wide expression and related phenotypes within or across species, added Chia-Yi Cheng of NYUs Center for Genomics and Systems Biology and National Taiwan University, the lead author of this study. We show that paring down our genomic input to genes whose expression patterns are conserved within and across species is a biologically principled way to reduce dimensionality of the genomic data, which significantly improves the ability of our machine learning models to identify which genes are important to a trait.

As a proof-of-concept, the researchers demonstrated that genes whose responsiveness to nitrogen are evolutionarily conserved between two diverse plant speciesArabidopsis, a small flowering plant widely used as a model organism in plant biology, and varieties of corn, Americas largest cropsignificantly improved the ability of machine learning models to predict genes of importance for how efficiently plants use nitrogen. Nitrogen is a crucial nutrient for plants and the main component of fertilizer; crops that use nitrogen more efficiently grow better and require less fertilizer, which has economic and environmental benefits.

The researchers conducted experiments that validated eight master transcription factors as genes of importance to nitrogen use efficiency. They showed that altered gene expression in Arabidopsis or corn could increase plant growth in low nitrogen soils, which they tested both in the lab at NYU and in cornfields at the University of Illinois.

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Machine Learning Uncovers Genes of Importance in Agriculture and Medicine - NYU News