Your search keyword '"Christina R. Muratore"' showing total 2 results

1. Cell-type Dependent Alzheimer's Disease Phenotypes: Probing the Biology of Selective Neuronal Vulnerability

Author

Christina R. Muratore, Constance Zhou, Meichen Liao, Marty A. Fernandez, Walter M. Taylor, Valentina N. Lagomarsino, Richard V. Pearse, II, Heather C. Rice, Joseph M. Negri, Amy He, Priya Srikanth, Dana G. Callahan, Taehwan Shin, Monica Zhou, David A. Bennett, Scott Noggle, J. Christopher Love, Dennis J. Selkoe, and Tracy L. Young-Pearse

Subjects

Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Summary: Alzheimer's disease (AD) induces memory and cognitive impairment in the absence of motor and sensory deficits during its early and middle course. A major unresolved question is the basis for this selective neuronal vulnerability. Aβ, which plays a central role in AD pathogenesis, is generated throughout the brain, yet some regions outside of the limbic and cerebral cortices are relatively spared from Aβ plaque deposition and synapse loss. Here, we examine neurons derived from iPSCs of patients harboring an amyloid precursor protein mutation to quantify AD-relevant phenotypes following directed differentiation to rostral fates of the brain (vulnerable) and caudal fates (relatively spared) in AD. We find that both the generation of Aβ and the responsiveness of TAU to Aβ are affected by neuronal cell type, with rostral neurons being more sensitive than caudal neurons. Thus, cell-autonomous factors may in part dictate the pattern of selective regional vulnerability in human neurons in AD. : In this article, Muratore et al. examine differential vulnerability of neuronal subtypes in AD by directing iPSC lines from control and familial AD subjects to different regional neuronal fates. APP processing and TAU proteostasis are differentially affected between regional fates, such that neuronal cell type dictates generation of and responsiveness to Aβ. Keywords: Alzheimer's disease, disease modeling, iPSCs, neural stem cells, Abeta, Tau, selective vulnerability, amyloid, familial AD, differential susceptibility

Published

2017

2. Genomic DISC1 Disruption in hiPSCs Alters Wnt Signaling and Neural Cell Fate

Author

Priya Srikanth, Karam Han, Dana G. Callahan, Eugenia Makovkina, Christina R. Muratore, Matthew A. Lalli, Honglin Zhou, Justin D. Boyd, Kenneth S. Kosik, Dennis J. Selkoe, and Tracy L. Young-Pearse

Subjects

Biology (General), QH301-705.5

Abstract

Genetic and clinical association studies have identified disrupted in schizophrenia 1 (DISC1) as a candidate risk gene for major mental illness. DISC1 is interrupted by a balanced chr(1;11) translocation in a Scottish family in which the translocation predisposes to psychiatric disorders. We investigate the consequences of DISC1 interruption in human neural cells using TALENs or CRISPR-Cas9 to target the DISC1 locus. We show that disruption of DISC1 near the site of the translocation results in decreased DISC1 protein levels because of nonsense-mediated decay of long splice variants. This results in an increased level of canonical Wnt signaling in neural progenitor cells and altered expression of fate markers such as Foxg1 and Tbr2. These gene expression changes are rescued by antagonizing Wnt signaling in a critical developmental window, supporting the hypothesis that DISC1-dependent suppression of basal Wnt signaling influences the distribution of cell types generated during cortical development.

Published

2015