Dr. J. Josh Lawrence - Faculty Page
Research Interests:
Nutrigenomics, cellular and synaptic physiology of Alzheimer’s disease, role of excitation/inhibition balance in disease states, hippocampal learning and memory circuitry, GABAergic inhibition, cell type specificity of neuromodulation, antioxidant depletion over lifespan, neuroinflammation, effects of diet on healthy aging, computational neuroscience, bioinformatics
Current Projects
Collapse of Vitamin A homeostasis in Alzheimer’s Disease pathogenesis and progression.
In this project, we are determining how disruption of Vitamin A homeostasis occurs
in Alzheimer’s disease (AD). Early stages of AD (mild cognitive impairment) show elevated
activity and hyperexcitability of the dentate gyrus of the hippocampus are accompanied
by a failure to detect novelty. However, causal upstream signaling mechanisms occurring
in DG circuits during AD pathogenesis remain poorly understood. Mitochondria produce
excess reactive oxygen species (ROS), which damages proteins, lipids, and DNA ¾ a
process termed oxidative stress. Dietary antioxidants (AOs) normally scavenge excess
ROS, preventing oxidative stress. However, in disease states, we hypothesize that
the homeostatic balance between antioxidants and oxidative stress is disrupted due
to antioxidant depletion. The antioxidant all-trans retinoic acid (ATRA), the active
form of dietary retinol, plays a dual role not only as a ROS scavenger but also as
a hormone-like nuclear receptor ligand, binding as an agonist to the retinoic acid
receptor (RAR). We propose that ATRA depletion in memory circuits is an early event
in AD pathogenesis, leading to reduced occupancy of RARs, excess ROS, and mitochondrial
dysfunction across hippocampal cell types, accelerating amyloidosis, network hyperexcitability,
and cognitive impairment. We use an innovative multidisciplinary approach that uniquely
combines DG-dependent learning, single cell transcriptomics, measures of OS and mitochondrial
dysfunction, and functional circuit analysis in two AD mouse models. The project is
currently funded by an NIH R01 grant.
“Reverse aging” the genome to prevent Alzheimer’s Disease-related learning deficits.
Prominent roles of oxidative stress in Alzheimer’s disease (AD) imply that antioxidant
depletion is a critical mechanism occurring at prodromal stages. Yet, to date, clinical
trials involving antioxidant supplementation have paradoxically failed. Several histone
deacetylases (HDACs) have been shown to be upregulated, providing evidence that deacetylation
is a molecular mechanism that leads to transcriptional repression in AD. We hypothesize
that HDAC inhibition is required to restore function of key transcription factors
that support hippocampal-dependent learning. This project tests the idea that vitamin
A supplementation and HDAC inhibition act synergistically to restore transcription
of vitamin A-sensitive genes for hippocampal learning and memory operations. We use
an innovative multidisciplinary approach that uniquely combines hippocampal-dependent
learning, transcriptomic/metabolomic/lipidomic profiling, and multi-omic integration
in two AD mouse models. The project is currently funded by an NIH R01 grant.
Vitamin D deficiency in health disparities, co-morbidities, and cognitive decline.
Vitamin D (VD) deficiency is associated with age, health disparities, and related
co-morbidities that increase the risk of Alzheimer’s disease (AD). Age and skin pigmentation
interferes with VD synthesis. Therefore, aging dark-skinned individuals (African Americans
and Hispanics) are particularly at risk for VD deficiency. Moreover, VD is a lipid
soluble vitamin; therefore, overweight/obesity further increases the risk of VD deficiency.
Our current projects examine relationships between VD deficiency and co-morbidities
among Hispanics using the Garrison Institute on Aging’s Project FRONTIER database.
The knowledge obtained will, through future clinical trials and community-based interventions,
increase visibility of readily available VD supplements for therapeutic interventions,
prevention, and/or mitigation of VD-related cognitive and co-morbidities, thereby
reducing AD risk.
Click here to visit Dr. Lawrence's lab page.