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使用光学镊子对活神经元细胞进行PicoNewton力光谱分析

PicoNewton Force Spectroscopy of Live Neuronal Cells, using Optical Tweezers
课程网址: http://videolectures.net/slonano07_cojoc_pnf/  
主讲教师: Dan Cojoc
开课单位: 国家实验室
开课时间: 2008-02-12
课程语种: 英语
中文简介:
众所周知,神经元轴突的迁移是由位于生长锥上的受体感应到的引导线索驱动的。1丝状足和纤毛虫是从生长锥尖端伸出的高度活动性的结构,可以探索环境。已经分析了它们的运动,但对于这些神经元结构在导航过程中可能发现的结构上施加的作用力知之甚少。实际上,对该力的分析仅限于理论上的考虑,而实验分析则仅限于分离的细丝样品2或迁移细胞。3在这项研究中,我们使用了光镊子4来测量丝状伪足和片状脂蛋白与毫秒时间分辨率。我们发现单个fi可以施加不超过3 pN的力。相反,片状脂膜瘤所施加的力高达20 pN或更高,持续时间从不到1秒到超过30秒不等。这些测量表明在没有肌动蛋白聚合的情况下不能产生力,并且为了产生大于3pN的力需要微管聚合。这些结果表明,神经元不仅处理信息,而且还作用于环境,并施加1到2个数量级的变化力。直径1 µm的硅珠被氨基官能化以减少粘附,被1064 nm红外光镊子(样品处的mW功率)捕获,靠近靠近轴突的生长锥(图1a).5。生长锥使珠子从其平衡位置横向和轴向偏移了2或3微米(图1b)。最后,珠子没有保持附着在生长锥上,而是可能返回到陷阱中的原始位置(图1c)。我们通过使用带象限光电二极管(QPD)4的后焦干涉仪和视频跟踪来跟踪磁珠位置,从而测量了生长锥Fneu =(Fx,Fy)施加的横向力。当珠子远离生长锥时,Fx和Fy的QPD记录很安静,标准偏差σ约为0.18 pN(图1d上部轨迹),但是当珠子移动时,会观察到产生大于5σ的力的碰撞靠近生长锥(图1d下迹)。在某些情况下,Fx和Fy在1 10秒内增加,达到20 pN的量级(图1e),并且当生长锥停止推动时,磁珠通常在不到1 ms的时间内返回其平衡位置。由于在珠子附近存在漂浮的碎片和丝状伪足可能影响入射到QPD的光图案,因此当QPD和视频跟踪获得的珠子位移一致时,碰撞被认为是可靠的(图中分别为黑色和黄色轨迹)。 1f),并通过电影的目视检查来验证碰撞的氟罗珀或lamellipodium的存在。我们已经在200多个实验中分析了生长锥和捕获的珠子之间的碰撞。每个实验持续3分钟,在许多实验中,观察到了一些对统计分析有意义的碰撞。这些碰撞产生的最大力范围从小于1 pN到至少20 pN,最大增加速率为10 pN /秒。这些碰撞从不到1秒持续到大约40 60秒。通常在长时间的碰撞中观察到较大的力。由于这些力的强度和持续时间范围很广,我们分别测量了数百次实验中丝状足和纤毛虫产生的力,以便获得良好的统计数据。
课程简介: It is known that migration of the axons of neuronal cells is driven by guidance cues sensed by receptors located on the growth cone.1 Filopodia and lamellipodia, the highly motile structures extruding from the tip of the growth cone, explore the environment. Their motion has been analysed, but little is known about the force these neuronal structures exert on the structures they might find during their navigation. In fact, the analysis of this force has been limited to theoretical considerations and experimental analysis have been restricted to samples of isolated filaments2 or to migrating cells.3 In this study, we used optical tweezers4 to measure the forces exerted by filopodia and lamellipodia with a millisecond temporal resolution. We found that a single filopodium exerts a force not exceeding 3 pN. In contrast, the force exerted by lamellipodia ranged up to 20 pN or more with a duration varying from less than 1 second to more than 30 seconds. These measurements suggest that in the absence of actin polymerisation no force can be produced and that microtubule polymerisation is required in order to develop forces larger than 3 pN. These results show that neurons not only process information but also they act on their environment exerting forces varying by 1 to 2 orders of magnitude. Silica beads of 1 µm in diameter, functionalised with amino groups to reduce sticking, were trapped with an 1064 nm infrared (IR, mW power at the sample) optical tweezers close to the growth cone of a migrating axon (Fig.1a).5 The growth cone displaced the bead both laterally and axially from its equilibrium position by even 2 or 3 microns (Fig.1b). At the end the bead did not remain attached to the growth cone and could return to its original position in the trap (Fig.1c). We measured the lateral force exerted by the growth cone Fneu = (Fx, Fy) by following the bead position both by using back focal interferometry with quadrant photo diode (QPD)4 and by video tracking. When the bead was far from the growth cone the QPD recordings of Fx and Fy were quiet with a standard deviation σ of approximately 0.18 pN (Fig. 1d upper trace), but collisions producing a force larger than 5σ were observed when the bead was moved near the growth cone (Fig.1d lower trace). In several occasions, Fx and Fy increased within 1-10 seconds, reaching values of the order of 20 pN (Fig.1e) and, when the growth cone stopped pushing, the bead returned to its equilibrium position, often in less than 1 ms. As the presence of floating debris and wandering filopodia near the bead could affect the light pattern impinging on the QPD, a collision was considered reliable when the bead displacement obtained with the QPD and videotracking were in agreement (black and yellow traces respectively, in Fig. 1f) and the presence of a colliding filopodium or lamellipodium was verified by visual inspection of the movie. We have analysed collisions between growth cones and trapped beads in more than 200 experiments. Each experiment lasted for 3 minutes and in many experiments several collisions significant for statistical analysis were observed. These collisions produced maximal forces ranging from less than 1 pN to at least 20 pN with a maximal rate of increase of 10 pN/second. These collisions lasted from less than 1 sec to about 40-60 seconds. Larger forces were usually observed during long lasting collisions. As these forces extend over a wide range of intensities and durations, we measured separately the forces developed by filopodia and lamellipodia for hundreds experiments in order to have a good statistics.
关 键 词: 神经元轴突; 细丝样品; 迁移细胞
课程来源: 视频讲座网
最后编审: 2019-09-21:cwx
阅读次数: 82