Kondo T, Johnson C H, Hastings J W
National Institute for Basic Biology, Myodaiji, Okazaki, 444, Japan.
Plant Physiol. 1991 Jan;95(1):197-205. doi: 10.1104/pp.95.1.197.
We have developed protocols for phase shifting the circadian rhythm of Chlamydomonas reinhardtii by light pulses. This paper describes the photobiology of phase-resetting the Chlamydomonas clock by brief (3 seconds to 15 minutes) light pulses administered during a 24 hour dark period. Its action spectrum exhibited two prominent peaks, at 520 and 660 nanometers. The fluence at 520 nanometers required to elicit a 4 hour phase shift was 0.2 millimole photon per square meter, but the pigment that is participating in resetting the clock under these conditions is unknown. The fluence needed at 660 nanomoles to induce a 4 hour phase shift was 0.1 millimole photon per square meter, which is comparable with that needed to induce the typical low fluence rate response of phytochrome in higher plants. However, the phase shift by red light (660 nanometers) was not diminished by subsequent administration of far-red light (730 nanometers), even if the red light pulse was as short as 0.1 second. This constitutes the first report of a regulatory action by red light in Chlamydomonas.
我们已经开发出通过光脉冲使莱茵衣藻的昼夜节律发生相移的方案。本文描述了在24小时黑暗期内施加短暂(3秒至15分钟)光脉冲对衣藻生物钟进行相位重置的光生物学特性。其作用光谱在520和660纳米处呈现出两个显著峰值。引发4小时相移所需的520纳米处的光通量为每平方米0.2毫摩尔光子,但在这些条件下参与重置生物钟的色素尚不清楚。660纳米处诱导4小时相移所需的光通量为每平方米0.1毫摩尔光子,这与诱导高等植物中光敏色素典型的低光通量率反应所需的光通量相当。然而,即使红光脉冲短至0.1秒,随后施加远红光(730纳米)也不会减弱红光(660纳米)引起的相移。这是关于红光在衣藻中的调节作用的首次报道。