Calcium, energy metabolism and the development of selective neuronal loss following short-term cerebral ischemia

Abstract

Short-term cerebral ischemia results in the delayed loss of specific neuronal subpopulations. This review discusses changes in energy metabolism and Ca²⁺ distribution during ischemia and recirculation and considers the possible contribution of these changes to the development of selective neuronal loss. Severe ischemia results in a rapid decline of ATP content and a subsequent large movement of Ca²⁺ from the extracellular to the intracellular space. Similar changes are seen in tissue subregions containing neurons destined to die and those areas largely resistant to short-term ischemia, although differences have been observed in Ca²⁺ uptake between individual neurons. The large accumulation of intracellular Ca²⁺ is widely considered as a critical initiating event in the development of neuronal loss but, as yet, definitive evidence has not been obtained. The increased intracellular Ca²⁺ content activates a number of additional processes including lipolysis of phospholipids and degradation or inactivation of some specific proteins, all of which could contribute to altered function on restoration of blood flow to the brain. Reperfusion results in a rapid recovery of ATP production. Cytoplasmic Ca²⁺ concentration is also restored during early recirculation as a result of both removal to the extracellular space and uptake into mitochondria. Within a few hours of recirculation, subtle increases in intracellular Ca²⁺ and a reduced capacity for mitochondrial respiration have been detected in some ischemia-susceptible regions. Both of these changes could potentially contribute to the development of neuronal loss. More pronounced alterations in Ca²⁺ homeostasis, resulting in a second period of increased mitochondrial Ca²⁺, develop with further recirculation in ischemia-susceptible regions. The available evidence suggests that these increases in Ca²⁺, although developing late, are likely to precede the irreversible loss of neuronal function and may be a necessary contributor to the final stages of this process.