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NIH Director鈥檚 Award to Develop Framework to Pinpoint Disease-Causing Genetic Mutations

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Male scientist holding NVIDIA Titan V graphics card
Gerald Quon is using computational models to understand the relationship between genetics and cellular behavior that can lead to schizophrenia or bipolar disorder. (College of Biological Sciences/嘿嘿视频)

Gerald Quon, an assistant professor in the Department of Molecular and Cellular Biology, College of Biological Sciences, has received a Director鈥檚 New Innovator Award from the National Institutes of Health (NIH). The award will support the development of a computational framework for characterizing how genetic variants associated with risk of psychiatric diseases like schizophrenia and bipolar disorder work at the cellular level.

鈥淭he science put forward by this cohort is exceptionally novel and creative and is sure to push at the boundaries of what is known,鈥 said NIH Director Francis S. Collins in a news release announcing the awards. 鈥淭hese visionary investigators come from a wide breadth of career stages and show that groundbreaking science can happen at any career level given the right opportunity.鈥

Quon鈥檚 project, entitled 鈥淟inking genetics to cellular behavior and disease via multimodal data integration,鈥 will receive $1.5 million in support over five years. The project aims to characterize the relationship between gene regulation, neuron firing patterns and the morphology of those neurons.

鈥淎 lot of people who study the genetics of different disorders in humans look at the impact of genetic variants on the molecular level,鈥 said Quon. 鈥淲e're trying to connect what happens at the molecular level in neurons to cellular-level phenotypes.鈥

Learning how genetic variants associated with different psychiatric disorders work at the cellular level requires significant amounts of computing power. With the award, Quon and his colleagues can acquire the hardware needed to build, train and deploy complex digital models.

鈥淲e use a lot of graphics cards and those get expensive quickly,鈥 Quon said.

Identifying targets for therapy

The award will also support efforts to validate predictions about which genetic variants are harmful and which are benign. Quon and his colleagues will be able to introduce specific DNA mutations into a neuron and evaluate how they impact a neuron鈥檚 response patterns.

鈥淗undreds of places in the genome might harbor mutations that affect our risk of disease,鈥 said Quon, 鈥渂ut we don鈥檛 actually know which mutations are the most important to target with therapies. Our work is trying to identify which mutations may have the biggest effect on neuron function and should therefore be prioritized for therapy.鈥

This type of research is often stymied by the lack of an integral component: live neurons.

鈥淪ome types of neuron function studies need access to live neurons; it鈥檚 hard to get access to live human neurons, so those datasets are rare and small,鈥 said Quon.

Small datasets are a huge obstacle to data analysis, so the computational framework Quon hopes to develop will enable the integration of data from both live and postmortem samples, from both humans and mice. Ultimately, using all this extra data will allow researchers to more accurately pinpoint which mutations actually result in disorders like schizophrenia.  

鈥淏y using our proposed framework to pool additional data from other sources,鈥 said Quon, 鈥渨e can boost the amount of statistical power we have, and we鈥檒l need fewer neurons to do proper data analysis.鈥

The High-Risk, High-Reward Research Program is part of the NIH Common Fund, which oversees programs that pursue major opportunities and gaps throughout the research enterprise that are of great importance to NIH and require collaboration across the agency to succeed. The program recognizes unusually innovative research from early career investigators.

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