Characterizing the Cocaine-responsive peptidome in mammalian telecephalon

哺乳动物端脑可卡因反应肽组的表征

基本信息

批准号：
9036371
负责人：
BRIAN A BALDO
金额：
$ 22.51万
依托单位：
UNIVERSITY OF WISCONSIN-MADISON
依托单位国家：
美国
项目类别：
财政年份：
2015
资助国家：
美国
起止时间：
2015-04-01 至 2018-03-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9036371
关键词：
Acute Adverse effects Affinity Animals Antibodies Attention Behavioral Biogenic Amines Biology Brain Brain region Cocaine Cocaine Dependence Collection Coupled Dependence Development Dopamine Drug Addiction Drug abuse Dynorphins Enkephalins Extracellular Space Gases Gene Expression Goals Gold Grant Guns Health Image Imaging Techniques In Situ Hybridization Injection of therapeutic agent Intoxication Label Leucine Magnetic nanoparticles Maps Mass Spectrum Analysis Methods Microdialysis Morbidity - disease rate Neuraxis Neuromodulator Neurons Neuropeptides Nucleus Accumbens Opioid Pharmaceutical Preparations Pharmacotherapy Phase Play Prefrontal Cortex Procedures Process Proteins Public Health Recovery Relapse Resolution Rewards Role Running Sampling Self Administration Shotguns Signal Transduction Site Slice Spatial Distribution Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization Staging Stimulus Substance abuse problem Technology Testing Therapeutic Time Tissues Translating Withdrawal Work addiction adverse outcome base behavior test beta-Endorphin combinatorial comparative design gene discovery gene product improved innovation insight mRNA Expression mortality nanoparticle neurochemistry next generation novel physical symptom productivity loss psychological symptom response success tandem mass spectrometry temporal measurement theories transmission process treatment strategy

项目摘要

DESCRIPTION (provided by applicant): The public health impact of substance abuse is enormous and widespread; adverse consequences include mortality, morbidity including debilitating physical and psychological symptoms, and loss of productivity. Existing drugs are not completely effective and often characterized by adverse side effects; hence, there is a great need to discover new neurochemical targets for the development of addiction therapeutics. As a neurochemical class, peptides are understudied relative to "classic" neuromodulators such as dopamine. Yet, work on a relatively small number of a priori-identified peptides show that they play profound functional roles across the addiction cycle. The next generation of anti-addiction medications could very conceivably be based on yet undiscovered peptides with specific functional roles in the addiction cycle. In this proposal, we aim to apply a cutting-edge mass spectrometry (MS)-based analytic platform to discover new peptides (peptidomic discovery), and characterize already-known peptides with unprecedented precision, across two drug states: acute cocaine intoxication and peak cocaine withdrawal. The technological platform consists of the following methods: 1. Shotgun peptidomics approach based on gas-phase tandem MS fragmentation methods coupled with isobaric tagging to rapidly quantify a large number of neuropeptides; 2. Matrix-assisted laser desorption/ionization mass spectrometric imaging (MALDI-MSI) of thin tissue slices using a novel gold-nanoparticle matrix, in correlation with in situ hybridization, to map the spatial distribution of peptide fluxes and enable co-localization wih dopamine signals; 3. Affinity-enhanced microdialysis using innovative magnetic nanoparticles to massively amplify the recovery of peptide efflux from the central nervous system (CNS) extracellular space, thereby improving sensitivity and temporal resolution; 4. Synthesis of any novel peptides discovered, and behavioral testing of these sequences in a well- validated brain stimulation-reward threshold procedure. These methods are highly advanced, and some new innovations have never been tried before in mammalian tissues. Hence, considering the time constraints of the R21 grant mechanism, our first goal is to refine and optimize the technological platform by specifically focusing on simultaneous -opioid, -opioid, and dopamine co-transmission in the nucleus accumbens (Acb) and prefrontal cortex (PFC) during acute cocaine intoxication and peak cocaine withdrawal. This type of combinatorial analysis in both brain sites has never been attempted. Our work has the potential to reveal crucial insights regarding an important opponent-process theory in addiction biology, positing diverse and opposing - opioid actions relative to -opioid/dopamine actions across the addiction cycle. Choosing acute cocaine intoxication and peak withdrawal offers the strongest test of the theory. Insights gained from these analyses could translate into uniquely effective combinatorial treatment strategies. Our second goal is to test any new peptide sequences discovered in the MS-based "shotgun" peptidomic analysis in the subsequent stages of our platform, as time permits. This plan will allow us to refine a powerful, technologically advanced platform for peptidomic discovery, and achieve unprecedented 'vertical integration' from the transcriptional to the behavioral levels. At the same time, our studies will ask a discrete question of great scientific importance regarding the interplay among opioid peptides and dopamine in distinct cocaine-associated states.

描述（由申请人提供）：药物滥用对公共健康的影响是巨大且广泛的；不良后果包括死亡、发病（包括使人衰弱的身体和心理症状）以及生产力下降，现有药物并不完全有效，并且通常具有不良副作用。因此，非常需要发现新的神经化学靶点来开发成瘾疗法，作为一种神经化学物质，肽相对于“经典”神经调节剂（如多巴胺）的研究还不够。相对少量的先验鉴定的肽表明它们在成瘾周期中发挥着深远的功能作用，下一代抗成瘾药物很可能基于尚未发现的在成瘾周期中具有特定功能的肽。根据提案，我们的目标是应用基于质谱 (MS) 的尖端分析平台来发现新的肽（肽组学发现），并以前所未有的精度表征已知的肽，涵盖两种药物状态：急性可卡因该技术平台由以下方法组成： 1. 基于气相串联 MS 裂解方法和同量异位标记的鸟枪法肽组学方法，可快速定量大量神经肽； 2. 基质辅助激光解吸/使用新型金纳米粒子基质对薄组织切片进行电离质谱成像 (MALDI-MSI)，与原位杂交相关，以绘制肽通量的空间分布图并实现与多巴胺信号的共定位； 3. 使用创新的磁性纳米颗粒进行亲和力增强的微透析，以大量放大从中枢神经系统 (CNS) 细胞外空间流出的肽的恢复，从而提高灵敏度和时间分辨率 4.发现了新的肽，并在经过充分验证的大脑刺激奖励阈值程序中对这些序列进行了行为测试，这些方法非常先进，并且一些新的创新以前从未尝试过。因此，考虑到 R21 资助机制的时间限制，我们的首要目标是通过特别关注伏隔核（Acb）中的同时 -阿片类药物、-阿片类药物和多巴胺共同传输来完善和优化技术平台。）和前额皮质（PFC）在急性可卡因中毒和可卡因戒断高峰期间的这种类型的组合分析从未被尝试过，我们的工作有可能揭示有关这方面的重要见解。成瘾生物学中重要的对手过程理论，在整个成瘾周期中，相对于 β-阿片/多巴胺作用，提出了不同且相反的 β-阿片类药物作用。选择急性可卡因中毒和峰值戒断提供了对该理论的最有力的检验。我们的第二个目标是在时间允许的情况下，在我们平台的后续阶段测试基于 MS 的“鸟枪”肽组学分析中发现的任何新肽序列。该计划将使我们能够完善一个强大的、技术先进的肽组学发现平台，并实现从转录到行为水平的前所未有的“垂直整合”。同时，我们的研究将提出一个具有重大科学意义的离散问题。阿片肽和多巴胺在不同的可卡因相关状态下的相互作用。