低频矩形电脉冲对盘虫的影响

Q4 Environmental Science
A. Kuznetsov, O. Kuleshova, A. Pronozin, O. Krivenko, O. Zavyalova
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引用次数: 1

摘要

极低频电磁场(ELF-EMF)对包括人类在内的动植物的影响是一个颇有争议的问题。关于ELF-EMF对水生生物的影响也知之甚少。我们研究了通过海水的不同振幅、持续时间和占空比的方波对毛虫生物的影响,作为可能的测试实验室模型。实验选用黏着毛刷虫(H1)、毛刷虫sp. (H2)和香港毛刷虫(H13) 3种盘虫菌株。它们是在固定生长阶段采摘的。利用Arduino Uno电子平台生成给定持续时间和占空比的矩形脉冲序列,频率高达2 kHz。通过分压器电路调节平均电压,最高可达500mv。采用钙通道活性抑制剂氨氯地平检测电脉冲效应对毛虫电压门控钙通道的特异性。实验动物在立体显微镜下进行观察,并通过放置在毛虫体附近的载流电极进行刺激。研究了毛盘虫的行为和形态特征的变化。确定了刺激和抑制作用。实验观察记录采用照片和视频技术。追踪单个动物的运动轨迹。以固定频率20 Hz增加电压脉冲,在25 mV电压下,H2单倍型个体在几分钟内离开“电极区”。它们随着电压的升高而丧失活动能力,在500毫伏电压下瘫痪。因此,在进一步的实验中使用50 mV的电压。在实验中,当两个电极位于毛原体的一侧而不是两侧时,动物有更多的机会向不同的方向移动。运动方向被用作特征特征。观察到滴虫迁移到电场线密度低的区域,远离电极或在电极后面。来自古老文化的动物对电刺激不那么敏感。H2菌株比H1菌株活性更强,特别是比H13菌株活性更强;在频率为2hz和2khz,电压为50mv时,表现出更强的生理反应。运动模式和动物形态取决于矩形刺激脉冲的持续时间、脉冲的数量、振幅和频率。观察到的影响范围很广:从动物直接或随机迁移到阳极或阴极或远离阳极到它们的不动性,在trichopla板周围和中间的光密度增加,最后到trichopla折叠并从基底分离。另外,在脉冲持续时间为35 ms、脉冲延迟为1 ms ~ 10 s的条件下,对毛螺旋体H2的实验表明,在最小延迟条件下,瘫痪动物的比例增加了80%。然而,在浓度为25 nM的氨氯地平的作用下,尽管暴露于电压波下,几乎所有的毛虫仍能快速移动几分钟。当使用浓度为250 nM的氨氯地平时,实验动物表现出运动完全不协调,不能离开“电极陷阱”。此外,盘体变得刚性,在运动过程中表现出动物形状的不变性。最后,浓度为50 μM的氨氯地平使动物板状体在腹-背方向迅速折叠成一个平底锅,随后将毛虫板解离成单个细胞。总的来说,电暴露表现出一种累积但可逆的生理效应,正如预期的那样,这与电压门控钙通道的活性有关。高浓度氨氯地平(50 μM)引起毛原体崩解;在中等浓度(250 nM)时,它破坏激活波的传播,导致动物运动不协调;在低浓度(25 nM)下,它可以防止电击。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effects of low frequency rectangular electric pulses on Trichoplax (Placozoa)
The effect of extremely low frequency electric and magnetic fields (ELF-EMF) on plants and animals including humans is quite a contentious issue. Little is known about ELF-EMF effect on hydrobionts, too. We studied the effect of square voltage waves of various amplitude, duration, and duty cycle, passed through seawater, on Trichoplax organisms as a possible test laboratory model. Three Placozoa strains, such as Trichoplax adhaerens (H1), Trichoplax sp. (H2), and Hoilungia hongkongensis (H13), were used in experiments. They were picked at the stationary growth phase. Arduino Uno electronics platform was used to generate a sequence of rectangular pulses of given duration and duty cycle with a frequency up to 2 kHz. Average voltage up to 500 mV was regulated by voltage divider circuit. Amlodipine, an inhibitor of calcium channel activity, was used to check the specificity of electrical pulse effect on voltage-gated calcium channels in Trichoplax. Experimental animals were investigated under a stereo microscope and stimulated by current-carrying electrodes placed close to a Trichoplax body. Variations in behavior and morphological characteristics of Trichoplax plate were studied. Stimulating and suppressing effects were identified. Experimental observations were recorded using photo and video techniques. Motion trajectories of individual animals were tracked. Increasing voltage pulses with fixed frequency of 20 Hz caused H2 haplotype individuals to leave “electrode zone” within several minutes at a voltage of 25 mV. They lost mobility in proportion to voltage rise and were paralyzed at a voltage of 500 mV. Therefore, a voltage of 50 mV was used in further experiments. An animal had more chance to move in various directions in experiments with two electrodes located on one side instead of both sides of Trichoplax. Direction of motion was used as a characteristic feature. Trichoplax were observed to migrate to areas with low density of electric field lines, which are far from electrodes or behind them. Animals from old culture were less sensitive to electrical stimulus. H2 strain was more reactive than H1 strain and especially than H13 strain; it demonstrated stronger physiological responses at frequencies of 2 Hz and 2 kHz with a voltage of 50 mV. Motion patterns and animal morphology depended on the duration of rectangular stimulation pulses, their number, amplitude, and frequency. Effects observed varied over a wide range: from direct or stochastic migration of animals to the anode or the cathode or away from it to their immobility, an increase of optical density around and in the middle of Trichoplax plate, and finally to Trichoplax folding and detach from the substrate. Additional experiments on Trichoplax sp. H2 with pulse duration of 35 ms and pulse delay of 1 ms to 10 s showed that the fraction of paralyzed animals increased up to 80 % with minimum delay. Nevertheless, in the presence of amlodipine with a concentration of 25 nM, almost all Trichoplax remained fast-moving for several minutes despite exposure to voltage waves. Experimental animals showed a total discoordination of motion and could not leave an “electrode trap”, when amlodipine with a concentration of 250 nM was used. Further, Trichoplax plate became rigid, which appeared in animal shape invariability during motion. Finally, amlodipine with a concentration of 50 μM caused a rapid folding of animal plate-like body into a pan in the ventral-dorsal direction and subsequent dissociation of Trichoplax plate into individual cells. In general, the electrical exposure applied demonstrated a cumulative but a reversible physiological effect, which, as expected, is associated with activity of voltage-gated calcium channels. Amlodipine at high concentration (50 μM) caused Trichoplax disintegration; at moderate concentration (250 nM), it disrupted the propagation of activation waves that led to discoordination of animal motion; at low concentration (25 nM), it prevented an electric shock.
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来源期刊
Marine Biological Journal
Marine Biological Journal Environmental Science-Ecology
CiteScore
0.90
自引率
0.00%
发文量
17
审稿时长
21 weeks
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