Busza Ania, Murad Alejandro, Emery Patrick
Department of Neurobiology and Program in Neuroscience, University of Massachusetts Medical School, Worcester, Massachusetts 01605, USA.
J Neurosci. 2007 Oct 3;27(40):10722-33. doi: 10.1523/JNEUROSCI.2479-07.2007.
Most animals rely on circadian clocks to synchronize their physiology and behavior with the day/night cycle. Light and temperature are the major physical variables that can synchronize circadian rhythms. Although the effects of light on circadian behavior have been studied in detail in Drosophila, the neuronal mechanisms underlying temperature synchronization of circadian behavior have received less attention. Here, we show that temperature cycles synchronize and durably affect circadian behavior in Drosophila in the absence of light input. This synchronization depends on the well characterized and functionally coupled circadian neurons controlling the morning and evening activity under light/dark cycles: the M cells and E cells. However, circadian neurons distinct from the M and E cells are implicated in the control of rhythmic behavior specifically under temperature cycles. These additional neurons play a dual role: they promote evening activity and negatively regulate E cell function in the middle of the day. We also demonstrate that, although temperature synchronizes circadian behavior more slowly than light, this synchronization is considerably accelerated when the M cell oscillator is absent or genetically altered. Thus, whereas the E cells show great responsiveness to temperature input, the M cells and their robust self-sustained pacemaker act as a resistance to behavioral synchronization by temperature cycles. In conclusion, the behavioral responses to temperature input are determined by both the individual properties of specific groups of circadian neurons and their organization in a neural network.
大多数动物依靠生物钟来使其生理和行为与昼夜循环同步。光和温度是能够使昼夜节律同步的主要物理变量。尽管在果蝇中已经对光对昼夜行为的影响进行了详细研究,但昼夜行为温度同步的神经元机制却较少受到关注。在这里,我们表明,在没有光输入的情况下,温度循环能使果蝇的昼夜行为同步并产生持久影响。这种同步依赖于在光/暗循环下控制早晚活动的特征明确且功能耦合的昼夜节律神经元:M细胞和E细胞。然而,与M细胞和E细胞不同的昼夜节律神经元特别在温度循环下参与节律行为的控制。这些额外的神经元发挥双重作用:它们促进夜间活动并在白天中期对E细胞功能起负调节作用。我们还证明,尽管温度使昼夜行为同步的速度比光慢,但当M细胞振荡器不存在或发生基因改变时,这种同步会显著加速。因此,虽然E细胞对温度输入表现出很大的反应性,但M细胞及其强大的自我维持起搏器对温度循环引起的行为同步起到了阻碍作用。总之,对温度输入的行为反应是由特定组昼夜节律神经元的个体特性及其在神经网络中的组织方式共同决定的。