Research Summary

Research in the Pike Lab is broadly focused on Alzheimer’s disease (AD), with the general goals of elucidating factors that regulate AD pathogenesis and pursuing translational strategies for the prevention and treatment of the disease. Our approach to investigating research questions involves the use of complementary cellular, biochemical and molecular techniques to analyze relationships in human tissues, rodent models, and cultured cells. Current areas of research focus in the Pike Lab include the contributions of the genetic risk factor APOE4 to AD pathogenesis, sex differences in AD, and the protective efficacy of longevity-promoting interventions including fasting mimicking diet and candidate compounds. We seek to identify and elucidate the mechanisms underlying AD risks and use this information to develop therapeutic interventions.

Research Summary

Dr. Rissman is Professor Physiology and Neuroscience and founding Director of the Neuroscience Translational Research Division (NTRD) of USC’s Alzheimer’s Therapeutic Research Institute in San Diego. Dr. Rissman’s basic science research goal is to identify and validate plasma biomarkers for Alzheimer’s Disease and Related Disorders (ADRD) to better understand mechanisms of neurodegeneration and to streamline clinical trials recruitment. Work from Dr. Rissman’s lab has led to the validation of plasma biomarkers that predict AD brain neuropathology and progression of dementia. Also, through analysis of plasma-derived extracellular vesicles, his group was the first to demonstrate that TDP-43 protein within astrocyte extracellular vesicles can identify Limbic-predominant age-related TDP-43 encephalopathy (LATE).

Research Summary

The Schier lab seeks to understand how the chemical constituents of foods and fluids are sensed, how these oral and postoral signals are processed in the brain and channeled into the behavioral outputs that subserve energy balance.

Research Summary

Research Summary

Research in the Tabbaa lab leverages genetically diverse mouse genetic reference panels to model individual differences in complex behaviors and susceptibility to a high-confidence autism risk gene. The goal of these projects is to better model genetically diverse populations in mice in order to address the challenging issue of developmental heterogeneity and genetic risk factor susceptibility in human neurodevelopmental disorders.

Research Summary

Our lab aims to push the boundary of our understanding of human brain in development and related disorders with discoveries focused on non-neuronal cells, environmental stress, and genetic mutations, leveraging the stem cell-based organoid/PCCO-assembled model in combination with the state-of-art genetic and genomic (single cell level) strategies to expand our knowledge of the cell-cell communication, fate dynamics, and niche homeostatic of the non-neuronal cells (astrocytes and pericytes) in health, and emergency rescue when they are under stress or in disease. Ultimately, our collective efforts, alongside those of others in the field, will pave the way for groundbreaking interventions in the realm of neurological disease.