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Docosahexaenoic acid and human brain evolution: missing the forest for the trees – Comments by Cunnane

Published online by Cambridge University Press:  01 May 2007

Stephen C. Cunnane*
Affiliation:
Research Center on Aging, Departments of Medicine and Physiology and Biophysics, Université de Sherbrooke, Sherbrooke, QC, CanadaJ1H 4C4, [email protected]
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Abstract

Type
Full Papers
Copyright
Copyright © The Author 2007

Langdon (Reference Langdon2006) amasses the evidence that DHA is not a sufficiently ‘limiting resource’ for human brain function to have played a significant role in human brain evolution. Low intake of few if any nutrients is life threatening in the short term, so he shouldn't be surprised that DHA alone couldn't possibly carry sole responsibility for human brain evolution. But Langdon misses the forest for the trees. For instance, he overlooks Zellweger syndrome, an inherited defect in which peroxisomal and mitochrondrial abnormalities lead to severe mental and physical retardation, usually resulting in death within the first year of life. Amongst several other metabolic disturbances, Zellweger syndrome causes a massive depletion of brain DHA, an effect that seems central to the subsequent retardation because supplementary DHA helps attenuate the clinical symptoms (Martinez, Reference Martinez2001). Hence, while some dietary n-3 fatty acid depletion or supplementation studies are inconclusive about the role of DHA in brain development (partly because the right studies are not ethical to do in human subjects), Zellweger syndrome leaves little doubt about the role of preformed DHA in supplying sufficient brain DHA for normal human brain development.

Langdon claims that essentially any deficit in DHA intake at birth can later be made up. In humans, this is categorically incorrect. Notwithstanding the presence of the enzyme pathway for humans of all ages to make some DHA and the availability of DHA in newborn body fat stores, 6-month-old breast-fed babies have 50 % more brain DHA levels compared with what is observed in those not given any preformed dietary DHA (Cunnane et al. Reference Cunnane, Francescutti, Brenna and Crawford2000). Thus, babies depend on dietary DHA to acquire ‘adequate’ brain DHA. There is also fairly widespread agreement that blood DHA levels in adult humans are not altered by even large dietary supplements of α-linolenate (for reviews, see Brenna, Reference Brenna2002; Cunnane, Reference Cunnane, Muir and Westcott2002). It is therefore incorrect to imply that, in humans, dietary shorter-chain n-3 fatty acids can substitute for DHA. Equally, the few reported studies using n-3 supplements containing EPA but no DHA also show that even preformed dietary EPA is insufficient to change plasma DHA (James et al. Reference James, Ursin and Cleland2003; Boston et al. Reference Boston, Bennett, Horrobin and Bennett2004). Hence, animal studies and in vitro biochemical data miss the point that, in humans, plasma DHA is heavily dependent on intake of preformed DHA.

Agreeing or disagreeing with the foregoing points does not prove or disprove the role of DHA, fish or seafood in human brain evolution; for that, conclusive evidence in the fossil record is essential. Langdon says that human exploitation of shore-based food resources only dates from about 100 000 years ago, i.e. long after evolution of the anatomically modern human and long after acquisition of technical, artistic and cultural skills associated with humans. In fact, the fossil record from East Africa shows that certain hominins were consuming large amounts of catfish and perch, not 100 000 years ago but at least 2 million years ago (Stewart, Reference Stewart1994). Hence, at least some groups of the first Homo species (habilis) purposefully fished and were very familiar with shore-based food resources. Freshwater fish are not as rich in DHA as marine coldwater species but East African catfish contain more than sufficient DHA to provide a very good source (Pauletto et al. Reference Pauletto, Puato, Caroli, Casiglia, Munhambo, Cazzalato, Bittolo, Angeli, Gallki and Pessina1996; Broadhurst et al. Reference Broadhurst, Cunnane and Crawford1998). Furthermore, catfish are easily caught by hand, obviating the need to postulate any advanced brain power, skills or technology, as would have been necessary to hunt live animals, marine fish or, indeed, to dissect the skulls or long bones of dead savannah herbivores.

To claim that because many modern hunter–gatherer groups do not necessarily consume fish or preformed DHA, therefore DHA cannot have played a central role in human brain evolution (Langdon, Reference Langdon2006) misses two key points. First, extant human hunter–gatherers have only occupied inland niches for at most 100 000 years, so they have the benefit of >2 million years of hominin brain evolution and the experience of many previous generations of their forebears from whom to acquire knowledge about which plants or animals to consume to remain healthy; that is a far cry from the challenge of actually evolving the human brain in those inland regions. Second, it denies the devastating impact on global health of inadequate intake of other key nutrients for the brain found (along with DHA) primarily in shore-based foods, particularly I and Fe. I and Fe deficiencies are the most prevalent nutrient deficiencies worldwide, affecting easily one-fifth of the world's population. Their main impact is on cognitive function. Shore-based foods are richer in I and Fe than other inland foods, especially plants. Many edible plants also contain goitrogens, leading to a further risk of I deficiency in strict vegetarians, a problem that is re-emerging in developed countries where intake of fish, shellfish, meat and table salt is declining. Individuals eating shore-based foods (plant, animal, shellfish or fish) are largely exempt from this extensive nutritional challenge whereas those who are inland or choose not to eat fish or seafood are usually the most susceptible.

It is true that the link between nutrition and human brain evolution initially focused almost exclusively on DHA (Crawford & Marsh, Reference Crawford and Marsh1989). However, the majority of publications on this topic over the past decade have recognised that other key brain-selective nutrients reinforce the role of DHA in supporting human brain development and, ultimately, its evolution. The point is that any amount of shore-based food (plant, animal, shellfish or fish) necessarily contributed to insuring not only adequacy of brain DHA, but also I, and Fe (and also other minerals essential for normal brain development, for example, Zn, Cu and Se). Nutrition is about insurance. Ideally, it should be difficult to induce nutrient deficiencies affecting brain function; rather than implying an unfounded link to brain evolution, the very resistance of the human brain to DHA deficiency argues in favour of its importance.

References

Boston, PF, Bennett, A, Horrobin, DF & Bennett, CN (2004) Ethyl-EPA in Alzheimer's disease – a pilot study. Prostagl Leukotri Essent Fatty Acids 71, 341346.CrossRefGoogle ScholarPubMed
Brenna, JT (2002) Efficiency of conversion of α-linolenic acid to long chain n-3 fatty acids in man. Curr Opin Clin Nutr Metab Care 5, 127132.CrossRefGoogle Scholar
Broadhurst, L, Cunnane, SC & Crawford, MA (1998) Rift Valley lake fish and shellfish provided brain-specific nutrition for early Homo. Br J Nutr 79, 321.CrossRefGoogle ScholarPubMed
Crawford, MA & Marsh, D (1989) The Driving Force: Food in Evolution and the Future. London: William Heinemann.Google Scholar
Cunnane, SC (2002) α-Linolenate in human nutrition. In Flax: the Genus Linum, pp. 150180 [Muir, A and Westcott, N, editors]. New York: Harcourt Academic.Google Scholar
Cunnane, SC, Francescutti, V, Brenna, JT & Crawford, MA (2000) Breast-fed infants achieve a higher rate of brain and whole body docosahexaenoate accumulation than formula-fed infants not consuming docosahexaenoate. Lipids 35, 105111.CrossRefGoogle Scholar
James, MJ, Ursin, VM & Cleland, L (2003) Metabolism of stearidonic acid in human subjects: comparison with the metabolism of other n-3 fatty acids. Am J Clin Nutr 77, 11401145.CrossRefGoogle Scholar
Langdon, J (2006) Has an aquatic diet been necessary for hominin brain evolution and functional development? Br J Nutr 96, 717.CrossRefGoogle ScholarPubMed
Martinez, M (2001) Restoring the DHA levels in the brains of Zellweger patients. J Mol Neurosci 16, 309316.CrossRefGoogle ScholarPubMed
Pauletto, P, Puato, M, Caroli, MG, Casiglia, E, Munhambo, AE, Cazzalato, G, Bittolo, BG, Angeli, MT, Gallki, C & Pessina, AC (1996) Blood pressure and atherogenic lipoprotein profiles of fish diet and vegetarian villagers in Tanzania. The Lugalawa study. Lancet 348, 784788.CrossRefGoogle ScholarPubMed
Stewart, KM (1994) Early hominid utilisation of fish resources and implications for seasonality and behaviour. J Human Evol 27, 229245.CrossRefGoogle Scholar