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Transforming the understanding
and treatment of mental illnesses.

Research Topics

Dr. Bourne’s interest in systems neuroscience led to a fascination with how reliably and capably the brain develops and becomes tightly interconnected to enable the complex behaviors species have evolved to perform. However, development is an area of neuroscience that is often overlooked in terms of trying to define the substrate and cause of neurological and psychiatric disorders. Therefore, Dr. Bourne’s overarching research goal is to probe the neural substrate of certain diseases and conditions through the development lens. A region of the brain that will be part of a significant focus is the pulvinar nuclei of the thalamus, which has expanded in size, complexity and function throughout mammalian evolution. Therefore, an overarching aim of the Section on Cellular and Cognitive Neurodevelopment is to take a multi-technique approach to explore the development of thalamocortical circuits and their plasticity into adulthood. This approach has the potential to identify the neural underpinnings of disorders, including schizophrenia, autism and cortical blindness, as well as help us understand how the brain differentially operates at different stages of life.

Biography

Dr. James A. Bourne is the Chief of the Section on Cellular and Cognitive Neurodevelopment. He received his BSc in Biochemistry from Imperial College of Science, Technology and Medicine (London) and his Ph.D. in Neuropharmacology from King’s College London. He then spent the next two decades in Australia at the University of Queensland and later at Monash University. In 2003, he was awarded an Australian Research Council (ARC) Fellowship and started to advance an independent area of research exploring the development and maturation of the primate visual system. Through a multidisciplinary cell-to-system approach, his group has influenced views on the developmental organization and plasticity of the primate visual system and how perturbations to specific circuits at a particular period in development can have life-long implications on visually-guided behaviors.

Selected Publications

Ma S, Skarica M, Li Q, Xu C, Risgaard RD, Tebbenkamp ATN, Mato-Blanco X, Kovner R, Krsnik Ž, de Martin X, Luria V, Marti-Perez X, Liang D, Karger A, Schmidt DK, Gomez-Sanchez Z, Qi C, Gobeske KT, Pochareddy S, Debnath A, Hottman CJ, Spurrier J, Teo L, Boghdadi AG, Homman-Ludiye J, Ely JJ, Daadi EW, Mi D, Daadi M, Marin O, Hof PR, Rasin MR, Bourne J, Sherwood CC, Santpere G, Girgenti MJ, Strittmatter SM, Sousa AMM, Sestan N (2022). Molecular and cellular evolution of the primate dorsolateral prefrontal cortex. Science 377, eabo7257. https://doi.org/10.1126/science.abo7257. [Pubmed Link ]

Hosseini Fin NS, Yip A, Teo L, Homman-Ludiye J, Bourne JA (2024). Developmental dynamics of the prefrontal cortical SST and PV interneuron networks: Insights from the monkey highlight human-specific features. bioRxiv . https://doi.org/10.1101/2024.07.10.602904. [Pubmed Link ]

BETHESDA, MD 20814-4486

Phone: +1 301 451 4545

james.bourne@nih.gov