单苍蝇检测方法的觅食行为的<em>果蝇</em
Summary
在这个视频文章中,我们描述了一个自动检测测量饥饿或过饱的嗅觉依赖食物搜索行为的影响在成年果蝇果蝇。
Abstract
对于许多动物,饥饿促进了有利于寻找适当的食物来源的方式变化的嗅觉系统。在这个视频文章中,我们描述了一个自动检测测量饥饿或过饱的嗅觉依赖食物搜索行为的影响在成年果蝇果蝇 。在一个不透光的盒子由红灯是看不见的果蝇照明,链接到自定义数据采集软件的摄像机同时监控6苍蝇的位置。每个飞局限于走在包含在该中心食物的气味个别领域。测试领域休息多孔层的功能,以防止气味的积累。延迟来定位气味源,它反映在不同的生理状态嗅觉灵敏度的度量,是通过软件分析确定。在这里,我们讨论运行此行为范式的关键力学和涉及有关飞LOADI具体问题纳克,气味污染,检测温度,数据质量和统计分析。
Introduction
饥饿的国家促进两种欲求行为:寻找食物和食品消费1。这个简单的行为测定法是与觅食2,3相关的趋化行为的研究非常有用。具体来说,它跟踪飞位置,行走速度和延迟定位食物气味的目标。食品发现的延迟作为度量测量的变化在苍蝇的气味探测系统的变化在其内部欲求状态的下游的灵敏度。此法的手动版是以前用来显示GABA-B受体信号是很重要的气味本地化行为,成蝇3。检测的电流自动版本是有助的在多短神经肽F(sNPF)信令重塑地图嗅觉的果蝇和影响欲求行为2的研究。
测试是在黑暗的,温度和湿度控制的房间进行。数字上面的透明亚克力板的测试设置摄像机跟踪苍蝇由660 nm的LED照明背光。从相机信息是实时由驻旁边的测试区域的计算机进行处理。我们使用的数据采集软件在测试期间录制和保存苍蝇位置的坐标。
在这个范例中,受试者被释放到包含在该中心食品气味的舞台;气味对象创建诱导苍蝇的食物搜索行为竞技场内食品串味梯度。类似的气味搜索协议已对chemosensation在单一果蝇幼虫7的研究应用。而其他行为分析,如四场嗅觉4,5或T型迷宫6评估厌恶的气味或退房的行为,这种模式是最适合评估嗅觉的灵敏度和趋化行为。
几个关键的优势伴随着这个ASSA年。首先,它允许快速获取大数据集,因为数据收集和分析大多是自动化的。第二,该测定分离和测量单个苍蝇的行为,从而消除社会嗅觉可能影响他们的行为。三,协议和简单的实验设计的简单性使检测效率,容易教别人。
另外,此法可用于进一步探讨神经回路基本食品的搜索行为由它提供给果蝇 8的广泛的遗传工具箱结合。转基因的靶向表达,沉默或激发的神经元可以与如GAL4-UAS系统,以及无人机,shibire TS1,UAS-破伤风毒素,和UAS-TRPA1(B)工具来实现转基因9-12。
Protocol
Representative Results
Discussion
在这个协议中,我们描述了食物搜索行为分析一步一步的过程。除了食物有关的气味,它也可适于用于苍蝇的定位其他气味物体的能力的研究。例如,它可能会朝雄蝇3在队友的本地化行为的研究应用还有几个额外的考虑这个协议,我们将在这里提到有关此过程:
首先,饲养温度决定实验苍蝇多久应该进行老化测试之前。建议年龄的范围进行检查,以确定最合适的年?…
Divulgazioni
The authors have nothing to disclose.
Acknowledgements
这项工作是由研究经费JWW从美国国立卫生研究院(R01DK092640)和美国国家科学基金会(0920668)的支持。
Materials
| Name of Reagent/Material | Company | Catalog Number | Comments |
| Apple Cider Vinegar | Spectrum | commercially available | |
| Agarose, Type VII | Sigma-Aldrich | A0701 | low gelling temperature agarose |
| Acrylic Testing Plate | custom | Plate contains 6 arenas. Each arena is 60 mm in diameter 6 mm in height. See testing plate diagrams for specific measurements. | |
| LabVIEW V.8.5 | National Instruments | 776670-09 | platform for programs: PositioningTool.vi, FlyTracking–Six Zones.vi NOTE: "elapsed time.vi", "time into file.vi", and "two object detect.vi" are included subroutines that must be available in order for the main data acquisition program "FlyTracking–Six zones.vi" to run. |
| LabVIEW Vision 8.5 | |||
| LabVIEW Vision Acquisition Software 8.5 | |||
| LabVIEW Vision Builder AI 3.5 | |||
| Igor Pro V.6 | Wavemetric, Inc. | platform for macro: Data Analysis for Fly Tracking–Six Zones | |
| Basler scA1390-17fm | National Instruments | 779980-01 | Digital Camera NOTE: driver for camera available at Baslerweb.com |
| 8 mm lens | National Instruments | 780024-01 | Lens for Basler Digital Camera |
| Ground Glass Diffuser Plate | Edmund Optics | custom | Diffuses light, 25 cm x 30 cm |
| US Std. No. 100 | Fischer Scientific | 04-881X | Sieve with nominal opening of 150 μm |
| Lighting Option 1 | |||
| LED backlight 660 nm (20 cm x 20 cm) | Spectra West | BL47192 | a simpler but more expensive lighting option. |
| Power Supply for LED Backlight | Spectra West | ||
| Lighting Option 2 | |||
| 660 nm LEDs | Superbrightleds | RL5R1330 | Wavelength 660 nm (approximately 7 x 7 LED array for a 14.7 inch x 9.75 inch panel) |
| Linear DC Power Supply | GW Instek | GPS-1830D | Power supply for LED Panel |
| Solderless Breadboard | Digikey | 922354-ND | Breadboard for LEDs |
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