骨骼中的长期增强作用——谷氨酸在应变诱导的细胞记忆中起作用?
Long-term potentiation in bone--a role for glutamate in strain-induced cellular memory?
作者信息
Spencer Gary J, Genever Paul G
机构信息
Biomedical Tissue Research, Department of Biology, University of York, York, YO10 5YW, UK.
出版信息
BMC Cell Biol. 2003 Jul 31;4:9. doi: 10.1186/1471-2121-4-9.
BACKGROUND
The adaptive response of bone cells to mechanical strain is a primary determinant of skeletal architecture and bone mass. In vivo mechanical loading induces new bone formation and increases bone mineral density whereas disuse, immobilisation and weightlessness induce bone loss. The potency of mechanical strain is such that a single brief period of loading at physiological strain magnitude is able to induce a long-lasting osteogenic response that lasts for days. Although the process of mechanotransduction in bone is incompletely understood, observations that responses to mechanical strain outlast the duration of stimulation necessitate the existence of a form of cellular memory through which transient strain episodes are recorded, interpreted and remembered by bone cells. Recent evidence supports the existence of a complex multicellular glutamate-signalling network in bone that shares functional similarities to glutamatergic neurotransmission in the central nervous system. In neurones, these signalling molecules coordinate synaptic communication required to support learning and memory formation, through a complex process of long-term potentiation.
PRESENTATION OF THE HYPOTHESIS
We hypothesise that osteoblasts use a cellular mechanism similar or identical to neuronal long-term potentiation in the central nervous system to mediate long-lasting changes in osteogenesis following brief periods of mechanical strain.
TESTING THE HYPOTHESIS
N-methyl-D-aspartate (NMDA) receptor antagonism should inhibit the saturating response of mechanical strain and reduce the enhanced osteogenicity of segregated loading to that of an equivalent period of uninterrupted loading. Changes in alpha-amino-3-hydroxy-5-methyl-isoxazole propionate (AMPA) receptor expression, localisation and electrophysiological responses should be induced by mechanical strain and inhibited by modulators of neuronal long-term potentiation.
IMPLICATIONS OF THE HYPOTHESIS
If true, this hypothesis would provide a mechanism through which the skeleton could be pharmacologically primed to enhance or retrieve the normal osteogenic response to exercise. This would form a basis through which novel therapies could be developed to target osteoporosis and other prevalent bone disorders associated with low bone mass.
背景
骨细胞对机械应变的适应性反应是骨骼结构和骨量的主要决定因素。体内机械负荷可诱导新骨形成并增加骨矿物质密度,而废用、固定和失重则会导致骨质流失。机械应变的作用很强,以至于在生理应变幅度下单次短暂的负荷就能诱导持续数天的长期成骨反应。尽管骨中机械转导的过程尚未完全了解,但对机械应变的反应持续时间超过刺激持续时间的观察结果表明,必然存在一种细胞记忆形式,通过这种形式,短暂的应变事件被骨细胞记录、解读和记忆。最近的证据支持骨中存在一个复杂的多细胞谷氨酸信号网络,该网络与中枢神经系统中的谷氨酸能神经传递具有功能相似性。在神经元中,这些信号分子通过一个复杂的长期增强过程来协调支持学习和记忆形成所需的突触通讯。
假说的提出
我们假设成骨细胞利用一种与中枢神经系统中神经元长期增强相似或相同的细胞机制来介导短暂机械应变后成骨的长期变化。
对假说的验证
N-甲基-D-天冬氨酸(NMDA)受体拮抗作用应抑制机械应变的饱和反应,并将分隔负荷增强的成骨能力降低至与同等时间不间断负荷相同的水平。α-氨基-3-羟基-5-甲基异恶唑丙酸(AMPA)受体的表达、定位和电生理反应的变化应由机械应变诱导,并被神经元长期增强调节剂抑制。
假说的意义
如果这一假说成立,将提供一种机制,通过该机制可以对骨骼进行药理学预处理,以增强或恢复对运动的正常成骨反应。这将为开发针对骨质疏松症和其他与低骨量相关的常见骨疾病的新疗法奠定基础。
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