Buckingham Steven D, Sattelle David B
MRC Functional Genomics Unit, Department of Physiology, Anatomy and Genetics, University of Oxford, South Parks Road, Oxford, OX1 3QX, UK.
BMC Neurosci. 2009 Jul 20;10:84. doi: 10.1186/1471-2202-10-84.
The "thrashing assay", in which nematodes are placed in liquid and the frequency of lateral swimming ("thrashing") movements estimated, is a well-established method for measuring motility in the genetic model organism Caenorhabditis elegans as well as in parasitic nematodes. It is used as an index of the effects of drugs, chemicals or mutations on motility and has proved useful in identifying mutants affecting behaviour. However, the method is laborious, subject to experimenter error, and therefore does not permit high-throughput applications. Existing automation methods usually involve analysis of worm shape, but this is computationally demanding and error-prone. Here we present a novel, robust and rapid method of automatically counting the thrashing frequency of worms that avoids morphometry but nonetheless gives a direct measure of thrashing frequency. Our method uses principal components analysis to remove the background, followed by computation of a covariance matrix of the remaining image frames from which the interval between statistically-similar frames is estimated.
We tested the performance of our covariance method in measuring thrashing rates of worms using mutations that affect motility and found that it accurately substituted for laborious, manual measurements over a wide range of thrashing rates. The algorithm used also enabled us to determine a dose-dependent inhibition of thrashing frequency by the anthelmintic drug, levamisole, illustrating the suitability of the system for assaying the effects of drugs and chemicals on motility. Furthermore, the algorithm successfully measured the actions of levamisole on a parasitic nematode, Haemonchus contortus, which undergoes complex contorted shapes whilst swimming, without alterations in the code or of any parameters, indicating that it is applicable to different nematode species, including parasitic nematodes. Our method is capable of analyzing a 30 s movie in less than 30 s and can therefore be deployed in rapid screens.
We demonstrate that a covariance-based method yields a fast, reliable, automated measurement of C. elegans motility which can replace the far more time-consuming, manual method. The absence of a morphometry step means that the method can be applied to any nematode that swims in liquid and, together with its speed, this simplicity lends itself to deployment in large-scale chemical and genetic screens.
“摆动试验”是一种成熟的方法,即将线虫置于液体中,估算其侧向游动(“摆动”)运动的频率,用于测量遗传模式生物秀丽隐杆线虫以及寄生线虫的运动能力。它被用作衡量药物、化学物质或突变对运动能力影响的指标,并已证明在鉴定影响行为的突变体方面很有用。然而,该方法费力,容易出现实验者误差,因此不适合高通量应用。现有的自动化方法通常涉及对线虫形状的分析,但这在计算上要求很高且容易出错。在此,我们提出一种新颖、稳健且快速的自动计算线虫摆动频率的方法,该方法避免了形态测量,但仍能直接测量摆动频率。我们的方法使用主成分分析去除背景,然后计算剩余图像帧的协方差矩阵,从中估计统计相似帧之间的间隔。
我们使用影响运动能力的突变测试了我们的协方差方法在测量线虫摆动速率方面的性能,发现它在广泛的摆动速率范围内准确替代了费力的手动测量。所使用的算法还使我们能够确定驱虫药左旋咪唑对摆动频率的剂量依赖性抑制,这说明了该系统适用于检测药物和化学物质对运动能力的影响。此外,该算法成功测量了左旋咪唑对寄生线虫捻转血矛线虫的作用,该线虫在游动时会呈现复杂的扭曲形状,而无需对代码或任何参数进行更改,这表明它适用于不同的线虫物种,包括寄生线虫。我们的方法能够在不到30秒的时间内分析一段30秒的视频,因此可用于快速筛选。
我们证明基于协方差的方法能够快速、可靠且自动地测量秀丽隐杆线虫的运动能力,可取代耗时得多的手动方法。无需形态测量步骤意味着该方法可应用于任何在液体中游泳的线虫,并且由于其速度快,这种简单性使其适用于大规模化学和遗传筛选。
