Abstract
ABSTRACT We propose that plant foods containing high quantities of starch were essential for the evolution of the human phenotype during the Pleistocene. Although previous studies have highlighted a stone tool-mediated shift from primarily plant-based to primarily meat-based diets as critical in the development of the brain and other human traits, we argue that digestible carbohydrates were also necessary to accommodate the increased metabolic demands of a growing brain. Furthermore, we acknowledge the adaptive role cooking played in improving the digestibility and palatability of key carbohydrates. We provide evidence that cooked starch, a source of preformed glucose, greatly increased energy availability to human tissues with high glucose demands, such as the brain, red blood cells, and the developing fetus. We also highlight the auxiliary role copy number variation in the salivary amylase genes may have played in increasing the importance of starch in human evolution following the origins of cooking. Salivary amylases are largely ineffective on raw crystalline starch, but cooking substantially increases both their energy-yielding potential and glycemia. Although uncertainties remain regarding the antiquity of cooking and the origins of salivary amylase gene copy number variation, the hypothesis we present makes a testable prediction that these events are correlated.
Highlights
THE global increase in the incidence of obesity and diet-related metabolic diseases has intensified interest in ancestral or “Paleolithic” diets
We propose that after cooking became widespread, starch digestion became the rate-limiting step in starch utilization, and the coevolution of cooking and copy number variation (CNV) in the AMY1 gene(s) increased availability of preformed dietary glucose, permitting the acceleration in brain size increase observed from the Middle Pleistocene onward
Noting that there is considerable overlap in date estimates for the origins of controlled fire use and the origins of AMY1 CNV, we hypothesize a gene-culture coadaptation scenario whereby cooking starch-rich plant foods coevolved with increased salivary amylase activity in the human lineage
Summary
Jennie Brand-Miller School of Molecular Bioscience and Charles Perkins Centre, University of Sydney. Brown Research Department of Genetics, Environment and Evolution, University College London. Thomas Research Department of Genetics, Environment and Evolution, University College London
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