PROJECT SUMMARY Aging is by far the most important driver and risk factor for developing a variety of neurodegenerative diseases, including the common forms of Alzheimer’s disease (AD) and related dementias. Recent evidence from our laboratory and others indicate that a cell fate termed cellular senescence is an effective driver of a diverse group of age-related diseases ranging from neurodegeneration to cancer. Senescent cells increase with age. Owing to their complex senescence-associated secretory phenotype (SASP), senescent cells can have profound effects on tissue structure and function, and can foster chronic inflammation, a major contributor to numerous age- related pathologies. There is also recent, albeit sparse, evidence that senescent cells can contribute to age- related neurodegeneration, including AD and related dementias. Project 1 of this Program Project Grant (PPG) will characterize in depth the senescence responses, particularly the SASPs, of human and mouse astrocytes, microglia and neurons induced to senescent by different stressors. It will then determine how these senescent cells affect the function of non-senescent cells, using both homotypic and heterotypic cell cultures, and a variety of endpoints ranging from differentiated functions to metabolic state and single cell analyses of transcriptomes to understand the heterogeneity of senescent brain cell populations. In addition, the Project will use three dimensional cortical organoids, including organoids containing human cells with wild-type genotypes and those with genotypes containing mutations that predispose to early onset AD and related dementias. These cells will be derived from induced pluripotent stem cells. Finally, Project 1 will take advantage of a novel transgenic mouse model that permits the selective elimination of senescent cells in order to determine whether and how senescent cells are causally related to age-related brain function in vivo. These collaborative analyses will complement experiments proposed by Projects 2 and 3 and rely heavily on Cores B, C and D. Together, these experiments will provide unprecedented knowledge about senescent cells in the brain, critically test their role in driving AD and related dementias, and open possibilities for novel interventions into these devasting pathologies.