[DP1] Illuminating Neuropeptide Modulation of Substance Abuse Withdrawal: Novel Photochemical Tools for Precision Control
Ente: National Institute on Drug Abuse
Scadenza: 2031-04-30
Importo max: 462.000 EUR
Paese: US
Descrizione
Project Summary/Abstract
Methamphetamine use disorder afflicts millions of Americans and precipitates a debilitating withdrawal syndrome
marked by hypodopaminergia, anxiety, and somatic distress, yet our ability to interrogate its neuropeptidergic
underpinnings is hindered by a lack of versatile, high precision chemical probes in neuroscience. We hypothesize
that corticotropin releasing factor (CRF) mediates negative affect and stress responsivity, neuropeptide Y (NPY)
promotes resilience within reward circuits, and orexin (ORX) governs motivational and somatic outputs during
withdrawal. To test this, we will engineer a modular library of cyclic, photolabile caging scaffolds that render CRF,
NPY, and ORX both inert and proteolysis resistant (enhancing in vivo stability and bioavailability), thereby
enabling multiplexed interrogation of multiple peptide systems reducing the need to generate or maintain multiple
mouse lines to modulate each peptidergic system. Each probe will undergo a rigorous validation pipeline:
biophysical photolysis and binding assays to quantify release kinetics and receptor engagement, cell culture
studies to confirm receptor specificity and downstream signaling, and acute brain slice experiments in both naïve
and methamphetamine-withdrawn mice (focused uncaging on genetically identified cell types with whole cell
electrophysiology and two photon calcium imaging) to verify functional efficacy and altered peptide
responsiveness. We will then deploy genetically encoded peptide sensors to dynamically monitor CRF in the
bed nucleus of the stria terminalis (BNST), NPY in the ventral tegmental area (VTA), and ORX in the nucleus
accumbens (NAc) both before methamphetamine exposure and during withdrawal in behaving mice, an
approach that will reveal how peptide activity in discrete circuits drives specific withdrawal features. Separate
experiments using time locked uncaging manipulations will test causality by modulating peptide signal and
assessing effects on withdrawal phenotypes. Behavioral endpoints will include quantitative somatic withdrawal
scoring (for example, jumps and tremors), validated anxiety assays (elevated plus maze and open field), and
reward related paradigms (sucrose preference and conditioned place preference), analyzed in both male and
female mice to uncover sex specific peptide mechanisms. Because CRF, NPY, and ORX, along with their
respective brain circuits, are conserved across mammals, these mechanistic insights will be directly relevant to
human neurobiology and withdrawal physiology. Leveraging these findings will pave the way to rationally design
peptide-based agonists and antagonists as prototype therapeutics to restore neuropeptide balance and
ameliorate withdrawal symptoms. Finally, we will disseminate our chemical reagents, protocols, and data through
open access repositories, empowering the broader neuroscience community to apply these spatiotemporal
control strategies across diverse research domain
Istituzione: UTAH STATE HIGHER EDUCATION SYSTEM--UNIVERSITY OF UTAH
PI: Ismail A. Ahmed
Progetto: 1DP1DA066060-01
Settori: National Institute on Drug Abuse
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