Hypertension, Vol 24, 145-156, Copyright © 1994 by American Heart Association
AB Weder and NJ Schork
Essential hypertension is a "disease of civilization" but has a clear
genetic component. From an evolutionary perspective, persistence in the
human genome of elements capable of raising blood pressure presupposes
their adaptive significance. Recently, two hypotheses that explicitly
appeal to selectionist arguments, the "slavery" and "thrifty gene"
theories, have been forwarded. We find neither completely successful, and
we advance an alternative explanation of the adaptive importance of genes
responsible for hypertension. We propose that blood pressure rises during
childhood and adolescence to subserve homeostatic needs of the organism.
Specifically, we contend that blood pressure is a flexible element in the
repertoire of renal homeostatic mechanisms serving to match renal function
to growth. The effect of modern diet and lifestyle on human growth
stimulates earlier and more vigorous development, straining biologically
necessary relationships between renal and general somatic growth and
requiring compensation via homeostatic mechanisms preserved during
evolution. Prime among such mechanisms is blood pressure, which rises as a
compensation to maintain renal function in the face of greater growth.
Since virtually all members of acculturated societies share in the modern
lifestyle, the demands imposed by accelerated growth and development result
in a populational shift to higher blood pressures, with a consequent
increase in the prevalence of hypertension. We propose that hypertension is
the product of maladaptation of highly genetically conserved mechanisms
subserving important biological homeostatic needs. Elucidation of the
mechanisms underlying hypertension will require approaches that examine the
developmental processes linking growth to blood pressure.
ARTICLES
Adaptation, allometry, and hypertension
Department of Internal Medicine, University of Michigan, Ann Arbor 48104-0356.
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