Langford G M, Inoué S
J Cell Biol. 1979 Mar;80(3):521-38. doi: 10.1083/jcb.80.3.521.
The rhythmic movement of the microtubular axostyle in the termite flagellate, Pyrsonympha vertens, was analyzed with polarization and electron microscopy. The protozoan axostyle is birefringent as a result of the semi-crystalline alignment of approximately 2,000 microtubules. The birefringence of the organelle permits analysis of the beat pattern in vivo. Modifications of the beat pattern were achieved with visible and UV microbeam irradiation. The beating axostyle is helically twisted and has two principal movements, one resembling ciliary and the other flagellar beating. The anterior portion of the beating axostyle has effective and recovery phases with each beat thereby simulating the flexural motion of a beating cilium. Undulations develop from the flexural flipping motion of the anterior segment and travel along the axostyle like flagellar waves. The shape of the waves differs from that of flagellar waves, however, and are described as sawtooth waves. The propagating sawtooth waves contain a sharp bend, approximately 3 micron in length, made up of two opposing flexures followed by a straight helical segment approximately 23 micron long. The average wavelength is approximately 25 micron, and three to four sawtooth waves travel along the axostyle at one time. The bends are nearly planar and can travel in either direction along the axostyle with equal velocity. At temperatures between 5 degrees and 30 degrees C, one sees a proportionate increase or decrease in wave propagation velocity as the temperature is raised or lowered. Beating stops below 5 degrees C but will resume if the preparation is warmed. A microbeam of visible light shone on a small segment of the axostyle causes the typical sawtooth waves to transform into short sine-like waves that accumulate in the area irradiated. Waves entering the affected region appear to stimulate waves already accumulated there to move, and waves that emerge take on the normal sawtooth wave pattern. The effective wavelengths of visible light capable of modifying the wave pattern is in the blue region of the spectrum. The axostyle is severed when irradiated with an intense microbeam of UV light. Short segments of axostyle produced by severing it at two places with a UV microbeam can curl upon themselves into shapes resembling lockwashers. We propose that the sawtooth waves in the axostyle of P. vertens are generated by interrow cross-bridges which are active in the straight regions.
利用偏振显微镜和电子显微镜分析了白蚁鞭毛虫(Pyrsonympha vertens)微管轴柱的节律性运动。原生动物的轴柱具有双折射性,这是约2000根微管半结晶排列的结果。细胞器的双折射性使得能够在活体中分析其搏动模式。通过可见光和紫外微束照射实现了搏动模式的改变。搏动的轴柱呈螺旋状扭曲,有两种主要运动,一种类似于纤毛搏动,另一种类似于鞭毛搏动。搏动轴柱的前部在每次搏动时有有效期和恢复期,从而模拟了搏动纤毛的弯曲运动。波动由前部节段的弯曲翻转运动产生,并像鞭毛波一样沿着轴柱传播。然而,这些波的形状与鞭毛波不同,被描述为锯齿波。传播的锯齿波包含一个尖锐的弯曲,长度约为3微米,由两个相反的弯曲组成,后面跟着一个约23微米长的直螺旋段。平均波长约为25微米,三到四个锯齿波同时沿着轴柱传播。这些弯曲几乎是平面的,可以以相同的速度沿轴柱的任何一个方向传播。在5摄氏度至30摄氏度之间的温度下,随着温度升高或降低,波的传播速度会相应增加或减少。低于5摄氏度时搏动停止,但如果标本升温,搏动会恢复。一束可见光微束照射在轴柱的一小段上会使典型的锯齿波转变为短的正弦样波,这些波会在照射区域聚集。进入受影响区域的波似乎会刺激已经聚集在那里的波移动,而出现的波则呈现出正常的锯齿波模式。能够改变波模式的可见光的有效波长在光谱的蓝色区域。用强紫外微束照射时,轴柱会被切断。用紫外微束在两个位置切断轴柱产生的短轴柱段可以自行卷曲成类似锁紧垫圈的形状。我们认为,P. vertens轴柱中的锯齿波是由在直区域活跃的排间交叉桥产生的。