Mammalian circannual pacemakers.

GA Lincoln, DG Hazlerigg
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引用次数: 16

Abstract

Circannual clocks drive rhythms in reproduction and many other seasonal characteristics but the underlying control of these long-term oscillators remains a mystery. Now, we propose that circannual timing involves mechanisms that are integral to the ontogenetic life-history programme where annual transitions are generated by cell birth, death and tissue regeneration throughout the life cycle--the histogenesis hypothesis. The intrinsic cycle is then timed by cues from the environment. The concept is that in specific sites in the brain, pituitary and peripheral tissues, residual populations of progenitor cells (adult stem cells) synchronously initiate a phase of cell division to begin a cycle. The progeny cells then proliferate, migrate and differentiate, providing the substrate that drives physiological change over long time-spans (e.g. summer/winter); cell death may be required to trigger the next cycle. We have begun to characterise such a tissue-based timer in our Soay sheep model focusing on the pars tuberalis (PT) of the pituitary gland and the sub-ventricular zone of the mediobasal hypothalamus (MBH) as potential circannual pacemakers. The PT is of special interest because it is a melatonin-responsive tissue containing undifferentiated cells, strategically located at the gateway between the brain and pituitary gland. The PT also governs long-photoperiod activation of thyroid hormone dependant processes in the MBH required for neurogenesis. In sheep, exposure to long photoperiod markedly activates BrDU-labelled cell proliferation in the PT and MBH, and acts to entrain the circannual reproductive cycle. Variation in expression and co-ordination of multiple tissue timers may explain species differences in circannual rhythmicity. This paper is dedicated to the memory of Ebo Gwinner.
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哺乳动物的年度心脏起搏器。
生物钟驱动着生殖节律和许多其他季节性特征,但这些长期振荡器的潜在控制仍然是一个谜。现在,我们提出,在整个生命周期中,由细胞出生、死亡和组织再生产生的年周期转变涉及到个体发生生活史程序中不可或缺的机制——组织发生假说。这个内在的循环是由来自环境的线索来计时的。这个概念是,在大脑、垂体和外周组织的特定部位,残余的祖细胞(成体干细胞)群体同步启动细胞分裂的一个阶段,开始一个周期。然后,后代细胞增殖、迁移和分化,提供驱动长时间(例如夏季/冬季)生理变化的基质;细胞死亡可能需要触发下一个周期。我们已经开始在我们的Soay羊模型中描述这种基于组织的计时器,重点关注垂体结节部(PT)和中基底下丘脑(MBH)的室下区作为潜在的年度起搏器。PT是一种对褪黑激素有反应的组织,含有未分化的细胞,战略性地位于大脑和脑垂体之间的通道。PT还控制神经发生所需的MBH中甲状腺激素依赖性过程的长光周期激活。在绵羊中,暴露于长时间的光周期显著激活brdu标记的细胞在PT和MBH中的增殖,并影响每年的生殖周期。多个组织计时器的表达和协调的变化可以解释物种在年周期节律上的差异。这篇文章是为了纪念Ebo Gwinner。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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