A recent research confirms the role of our body's internal molecular clock in controlling blood pressure.
It has been known for decades that heart attacks and strokes occur most frequently in the early-morning hours. Published online next week in the Proceedings of the National Academy of Sciences, this report points to the novel possibility of modifying blood pressure and the early-morning risk of heart attack.
The upswing in heart attacks tracks with rising blood pressure; which in turn, undergoes a 24-hour, or circadian rhythm. This rise in blood pressure is amplified in patients with high blood pressure. However, scientists have debated as to whether this event signifies a role for the molecular clock, or merely reflects the relationship of clock time to stresses in our environment - such as awakening, hurried dressing, and the rush to work.
'This study provides evidence that integrates both explanations for the variation in blood pressure with clock time and, by inference, the daily variation in heart attack and stroke,' explains first author and postdoctoral fellow Annie M. Curtis, PhD.
The molecular clock is a complex set of genes located in a discrete brain area that tightly regulate circadian rhythms in behavior, temperature, and metabolism. Researchers now appreciate that this 'master clock' also interacts with clocks in almost all types of tissues.
Using mice in which the function of major clock genes has been disrupted, the investigators found distinct and complimentary effects on blood pressure and its circadian variation. What's more, genes relevant to the production and breakdown of catecholamines - the hormones that equip mammals for 'fight and flight' behavior were under the control of the clock.
Catecholamines - norepinephrine and epinephrine - undergo a daily variation, but also rise in response to stress. The investigators wondered if they might provide a link between the two explanations for the early morning rise in heart attacks.
Using a mouse model in which catecholamines and blood pressure were made to surge, the researchers found that the rise in both blood pressure and catecholamines depended on the time of the stress. The greatest response occurred at a time that would correspond to the early morning hours in humans.
However, the greater surprise was yet to come, say the investigators. Deletion of a core clock gene completely abolished both the catecholamine and blood pressure response to stress, irrespective of when the stress was applied during the daily clock cycle. This effect was specific to the catecholamines, as the stress response of another hormone - a steroid - was unaltered.
'These results integrate for the first time the two leading explanations for the diurnal variation in blood pressure and reveal an unexpected role for a clock gene in regulating the stress response' says senior author Garret A. FitzGerald, MD, Director of the Institute for Translational Medicine and Therapeutics at Penn FitzGerald.
'They raise the novel possibility of modifying blood pressure and consequently the early-morning risk of heart attack and stroke by using drugs to 'reset' the molecular clock.'
Since blood pressure response (via rising catecholamines) to stress in the early morning is tied to one's internal clock, tamping down the clock using drugs could be a treatment for people with high blood pressure, whose upswing in pressure is amplified in the morning anyway.