Human aging is accompanied by dramatic changes in daily sleepwake behavior: Activity shifts to an earlier phase, and the consolidation of sleep and wake is disturbed. Although this daily circadian rhythm is brain-controlled, its mechanism is encoded by cellautonomous circadian clocks functioning in nearly every cell of the body. In fact, human clock properties measured in peripheral cells such as fibroblasts closely mimic those measured physiologically and behaviorally in the same subjects. To understand better the molecular mechanisms by which human aging affects circadian clocks, we characterized the clock properties of fibroblasts cultivated from dermal biopsies of young and older subjects. Fibroblast period length, amplitude, and phase were identical in the two groups even though behavior was not, thereby suggesting that basic clock properties of peripheral cells do not change during aging. Interestingly, measurement of the same cells in the presence of human serum from older donors shortened period length and advanced the phase of cellular circadian rhythms compared with treatment with serum from young subjects, indicating that a circulating factor might alter human chronotype. Further experiments demonstrated that this effect is caused by a thermolabile factor present in serum of older individuals. Thus, even though the molecular machinery of peripheral circadian clocks does not change with age, some age-related circadian dysfunction observed in vivo might be of hormonal origin and therefore might be pharmacologically remediable.chronobiology | peripheral oscillators | human behavior C ircadian clocks possess an endogenous periodicity of about 24 h and play a key role in physiological adaptation to the solar day for all living organisms, from cyanobacteria and fungi (1) to insects (2) and mammals (3). Circadian clocks influence nearly all aspects of physiology and behavior, including sleepwake cycles, body temperature, and the function of many organs (3). During normal aging, clock function is attenuated, with consequences both for health and quality of life. Older individuals have an earlier phase of everyday activity compared with the young (4). Not only is the consolidation of sleep and wake dramatically reduced (5, 6), but overall circadian amplitude of hormones and body temperature are lower (7,8), and many agingassociated sleep-wake pathologies have been reported (9-11). As a result, one in five healthy older individuals reports taking sleep medications regularly (9). In cases of pathological aging, chronobiological disturbance is even more acute: Huntington disease, Parkinson disease, and Alzheimer's disease are all associated with profound alterations in sleeping patterns (10-12). These effects of aging on circadian rhythms-diminished circadian amplitude, earlier phase, shorter circadian period, and desynchronization of rhythms in peripheral organs-have been observed widely in several species of mammals (7,13,14). Paradoxically, however, even though the behavioral phase is earlier in aged humans, m...
