Спектральный конфокальной микроскопии флуоресцентно помеченный никотиновые рецепторы в плей-офф у мышей с хроническим Никотин администрации
Summary
Мы разработали новый метод количественной никотиновые рецепторы ацетилхолина изменений в субклеточных регионах конкретных подтипов нейронах ЦНС, чтобы лучше понять механизмы никотиновой зависимости с помощью комбинации подходов, в том числе люминесцентные пометки белка рецептора помощи стука в подходе и спектральные конфокальной микроскопии.
Abstract
Ligand-gated ion channels in the central nervous system (CNS) are implicated in numerous conditions with serious medical and social consequences. For instance, addiction to nicotine via tobacco smoking is a leading cause of premature death worldwide (World Health Organization) and is likely caused by an alteration of ion channel distribution in the brain1. Chronic nicotine exposure in both rodents and humans results in increased numbers of nicotinic acetylcholine receptors (nAChRs) in brain tissue1-3. Similarly, alterations in the glutamatergic GluN1 or GluA1 channels have been implicated in triggering sensitization to other addictive drugs such as cocaine, amphetamines and opiates4-6.
Consequently, the ability to map and quantify distribution and expression patterns of specific ion channels is critically important to understanding the mechanisms of addiction. The study of brain region-specific effects of individual drugs was advanced by the advent of techniques such as radioactive ligands. However, the low spatial resolution of radioactive ligand binding prevents the ability to quantify ligand-gated ion channels in specific subtypes of neurons.
Genetically encoded fluorescent reporters, such as green fluorescent protein (GFP) and its many color variants, have revolutionized the field of biology7.By genetically tagging a fluorescent reporter to an endogenous protein one can visualize proteins in vivo7-10. One advantage of fluorescently tagging proteins with a probe is the elimination of antibody use, which have issues of nonspecificity and accessibility to the target protein. We have used this strategy to fluorescently label nAChRs, which enabled the study of receptor assembly using Förster Resonance Energy Transfer (FRET) in transfected cultured cells11.More recently, we have used the knock-in approach to engineer mice with yellow fluorescent protein tagged α4 nAChR subunits (α4YFP), enabling precise quantification of the receptor ex vivo at submicrometer resolution in CNS neurons via spectral confocal microscopy12. The targeted fluorescent knock-in mutation is incorporated in the endogenous locus and under control of its native promoter, producing normal levels of expression and regulation of the receptor when compared to untagged receptors in wildtype mice. This knock-in approach can be extended to fluorescently tag other ion channels and offers a powerful approach of visualizing and quantifying receptors in the CNS.
In this paper we describe a methodology to quantify changes in nAChR expression in specific CNS neurons after exposure to chronic nicotine. Our methods include mini-osmotic pump implantation, intracardiac perfusion fixation, imaging and analysis of fluorescently tagged nicotinic receptor subunits from α4YFP knock-in mice (Fig. 1). We have optimized the fixation technique to minimize autofluorescence from fixed brain tissue.We describe in detail our imaging methodology using a spectral confocal microscope in conjunction with a linear spectral unmixing algorithm to subtract autofluoresent signal in order to accurately obtain α4YFP fluorescence signal. Finally, we show results of chronic nicotine-induced upregulation of α4YFP receptors in the medial perforant path of the hippocampus.
Protocol
Discussion
Disclosures
The authors have nothing to disclose.
Acknowledgements
Энтони Ренда была поддержана Университета Виктории премию стипендий. Это исследование было поддержано естественным наукам и инженерным исследованиям Совета Канады Discovery Грант, NARSAD премия для молодых следователь (РН), Виктория Foundation – Myre и Уинифред Сим фонда, Канадского фонда инноваций грант Британской Колумбии знаний Фонда развития и естественным наукам и инженерным исследованиям Совета Канады исследовательских инструментов и приборов Грант. Мы благодарим Джиллиан Маккей, Кристина Барнс, Ариэль Sullivan, Дженнифер Макдональд и Даниэль Morgado за отличную хозяйства мыши.
Materials
| Name of the reagent | Company | Catalogue number | Comments |
| mini-osmotic pumps | Alzet | model 2002 | |
| saline | Teknova | S5819 | |
| (-)-nicotine hydrogen tartrate salt | Sigma | N5260 | |
| eye drops | Novartis | Tear-Gel | |
| Vetbond glue | 3M | 1469SB | |
| heparin sodium salt | Sigma | H4784 | |
| 10x PBS | Invitrogen | 70011 | |
| ketamine | Wyeth Animal Health | 0856-4403-01 | |
| medatomidine hydrochloride | Pfizer | 1950673 | |
| 23G butterfly needle | Becton Dickinson | 367253 | |
| paraformaldehyde | Electron Microscopy Sciences | 15710 | |
| plastic embedding mold | VWR | 18986-1 | |
| O.C.T. Mounting Compound | Tissue-Tek | 4583 | |
| Mowiol 4-88 | EMD-Calbiochem | 475904 | pH 8.5 |
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