Gibbs Marie E, Hertz Leif
Department of Anatomy and Developmental Biology, Monash University, Clayton 3800, Australia.
Neurochem Int. 2008 May;52(6):1012-8. doi: 10.1016/j.neuint.2007.10.014. Epub 2007 Oct 26.
Bead discrimination learning in day-old chicken was inhibited by bilateral injection into the intermediate medial mesopallium (IMM), a homolog of the mammalian brain cortex, of the poorly metabolized enantiomer of L-lactate, D-lactate. The window of vulnerability extended from 10 min before training to 20 min after training. Unilateral injection 10 min before training inhibited only in the left IMM, whereas 10 min after training injection was only inhibitory if made into the right hemisphere. The pre-training administration caused memory loss from the earliest time tested whereas memory was maintained for another 20 min when D-lactate was injected 10 min post-training. The ability of acetate, an astrocyte-specific substrate, injected into the IMM to counteract the inhibitory effect was tested. Following D-lactate injection 10 min before training, rescue of memory immediately after training was achieved by acetate as long as aspartate, an oxaloacetate precursor, was also present. This suggests that pyruvate carboxylation is necessary for net synthesis of glutamate, which is known to occur at this time [Gibbs, M.E., Lloyd, H.G.E., Santa, T., Hertz, L., 2007. Glycogen is a preferred glutamate precursor during learning in 1-day-old chick: biochemical and behavioral evidence. J. Neurosci. Res., 85, 3326-3333]. However, acetate alone rescued memory 20 min post-training (following d-lactate injection 10 min after training), indicating that pyruvate at this time is used for energy production, consistent with memory inhibition by dinitrophenol. These findings suggest that D-lactate acts by inhibiting uptake of L-lactate into astrocytes (an extracellular effect) or metabolism of pyruvate in astrocytic mitochondria (an intracellular effect). An apparent lag phase between the administration of d-lactate and its inhibition of learning favors the latter possibility. Thus, under the present experimental conditions D-lactate acts as an astrocytic metabolic inhibitor rather than as an inhibitor of neuronal L-lactate uptake, as has occasionally been suggested. Analogously, a rare reversible neurological syndrome with memory deficits, D-lactate encephalopathy, may mainly or exclusively be due to astrocytic malfunction.
将代谢缓慢的L-乳酸对映体D-乳酸双侧注射到雏鸡大脑中与哺乳动物大脑皮层同源的内侧中脑皮质(IMM),会抑制雏鸡一日龄时的珠子辨别学习。易损期从训练前10分钟延伸至训练后20分钟。训练前10分钟单侧注射仅在左侧IMM产生抑制作用,而训练后10分钟注射,只有注射到右侧半球才具有抑制作用。训练前给药会导致从最早测试时间起记忆丧失,而训练后10分钟注射D-乳酸时,记忆可维持另外20分钟。测试了注射到IMM的星形胶质细胞特异性底物乙酸盐抵消抑制作用的能力。训练前10分钟注射D-乳酸后,只要草酰乙酸前体天冬氨酸也存在,训练后立即通过乙酸盐恢复记忆。这表明丙酮酸羧化对于谷氨酸的净合成是必需的,已知此时会发生这种情况[吉布斯,M.E.,劳埃德,H.G.E.,桑塔,T.,赫兹,L.,2007年。糖原是1日龄雏鸡学习期间首选的谷氨酸前体:生化和行为证据。《神经科学研究杂志》,85,3326 - 3333]。然而,单独的乙酸盐在训练后20分钟恢复记忆(训练后10分钟注射d - 乳酸后),表明此时丙酮酸用于能量产生,这与二硝基苯酚对记忆的抑制作用一致。这些发现表明,D-乳酸通过抑制L-乳酸进入星形胶质细胞的摄取(细胞外效应)或星形胶质细胞线粒体中丙酮酸的代谢(细胞内效应)起作用。D-乳酸给药与其对学习的抑制之间明显的滞后阶段支持后一种可能性。因此,在当前实验条件下,D-乳酸作为星形胶质细胞代谢抑制剂起作用,而不是如偶尔所认为的那样作为神经元L-乳酸摄取的抑制剂。类似地,一种罕见的伴有记忆缺陷的可逆性神经综合征,D-乳酸脑病,可能主要或完全归因于星形胶质细胞功能障碍。
