The only risk factor identified so far for sporadic late onset AD (LOAD) is aging. The inheritance of APOEï¿½4 allele of apolipoprotein E is the major genetic risk factor for LOAD but molecular mechanisms underlying this susceptibility are unknown. It is possible that similar to other multifactorial (systemic) diseases, the underlying quantitative variation in susceptibility to develop LOAD is probably controlled by multiple genes. The role of environmental factors in the risk and pathogenesis of AD has been increasingly appreciated. In this regard, the research on epigenetic reprogramming inflicted by exposure to environmental factors, strongly suggests that changes induced at certain chromatin marks during the development and postnatal life can influence development of dementia and AD progression. We are proposing investigation in animal models to advance the understanding of the role of environmental arsenic (As) exposure in the etiology and progression of AD. We capitalize on the results generated with the support of our ongoing NIEHS R21: 1) exposure of adult mice, with already developed AD phenotype, to human relevant As concentrations (100 ï¿½g/ml) in drinking water further deteriorates their cognitive performance, increases amyloid plaques and reactive astrocytosis in hippocampus; the expression of nuclear liver X receptors (LXR) and important target genes, is decreased. 2) Young mice exposed to as are cognitively impaired and the expression level of and activity dependent transcription factor EGR1 (Early growth response 1), implicated in memory formation and cognitive performance is lower. 3) prenatal exposure to As and high fat diet (HFD) causes global hypoacetylation at Lysine 9 of histone 3 (H3K9) and alterations in acetylation pattern of genes, components of Polycomb Repressive Complexes PRC1 and PRC2, that modulate gene expression genome-wide through changes in histone modifications. We hypothesize that prenatal, perinatal and postnatal as exposure impairs cognitive reserve and inhibits adaptive capacity of the adult organism to environmental insults (e.g. HFD). The outcome is a predisposition to AD or aggravated existing AD phenotype, with the APOE genetic background significantly impacting the pathology. We are proposing that histone modifications, including those catalyzed by PRC2 and loss of essential transcriptional programs (e.g. LXR and EGR1) are molecular mechanisms underlying as effects. To test the hypothesis we will accomplish two Specific Aims: Aim 1. To elucidate the effects of as exposure on the development of AD-like phenotype in AD model mice. Aim 2: To identify epigenetic molecular mechanisms underlying changes in cognitive performance and AD phenotype in response to as exposure.