Calcium buffering systems and calcium signaling in aged rat basal forebrain neurons

Abstract

Disturbances of neuronal Ca²⁺ homeostasis are considered to be important determinants of age‐related cognitive impairment. Cholinergic neurons of the basal forebrain (BF) are principal targets of decline associated with aging and dementia. During the last several years, we have attempted to link these concepts in a rat model of ‘normal’ aging. In this review, we will describe some changes that we have observed in Ca²⁺ signaling of aged BF neurons and the reversal of one of these changes by dietary caloric restriction. Our evidence supports a scenario in which subtle changes in the properties of voltage‐gated Ca²⁺ channels result in increased Ca²⁺ influx during aging. This increased Ca²⁺, in turn, triggers an increase in rapid Ca²⁺ buffering in the somatic compartment of aged BF neurons. However, this nominal ‘compensation’, along with other changes in Ca²⁺ handling machinery (notably mitochondria) alters the Ca²⁺ signal with age in a way that is dependent on the magnitude of the Ca²⁺ load. By combining whole‐cell patch clamp electrophysiology, ratiometric Ca²⁺‐sensitive microfluorimetry and single‐cell reverse transcription‐polymerase chain reaction, we have determined that age‐related rapid buffering changes are present in identified cholinergic BF neurons and that these changes can be prevented by a caloric restriction dietary regimen. Because caloric restriction extends lifespan and retards the progression of age‐related dysfunction, these findings suggest that increased Ca²⁺ buffering in cholinergic neurons may be relevant to cognitive decline during normal aging. Importantly, calcium homeostatic mechanisms of BF cholinergic neurons are amenable to dietary interventions that could promote cognitive health during aging.