Are we descended from ‘aquatic apes’?

File photo: A Kenyan scientist holds a fossil at the Kenya National Museum. Researchers discovered a 10-million-year-old jaw bone in Kenya they believe belonged to a new species of a great ape that could be the last common ancestor of gorillas, chimpanzees and humans.

File photo: A Kenyan scientist holds a fossil at the Kenya National Museum. Researchers discovered a 10-million-year-old jaw bone in Kenya they believe belonged to a new species of a great ape that could be the last common ancestor of gorillas, chimpanzees and humans.

Published May 9, 2013

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London - Scientists, academics and medics are gathering today in a London hotel to discuss a topic that has been virtually unmentionable in academic circles for decades: are humans descended from “aquatic apes” that spent more time swimming than dragging their knuckles on the ground?

The last time this question was asked, at a conference in 1992, there was much scoffing and ridicule. Other academics sneered and Bernard Levin wrote a full-page article lampooning the idea in a national newspaper.

This week's conference, Human Evolution: Past, Present and Future - Anthropological, Medical and Nutritional Considerations, at the Grange St Paul's Hotel, has also already been the subject of much derision. Followers of the conventional and overwhelmingly accepted belief that our ancestors were very much land-based are launching a parody campaign online to argue we evolved from “space monkeys”. Most scientists will openly scoff at the idea of us deriving from water-bound primates.

But, perhaps emboldened by the presence of Sir David Attenborough - who was booked to attend the conference for one session but asked at the last minute if he could attend both days - the aquatic ape theorists are back.

The conference is chaired by Professor Rhys Evans, an ear, nose and throat surgeon at the Royal Marsden Hospital, who is candid about the scope of the conference. “We are trying to discuss the pros and cons of the theory,” he said. “But many of the things which are unique to humans - such as a descended larynx, walking upright, fat beneath the skin, and most obviously an extremely large brain - it seems can best be accounted for as adaptations to extended periods in an aquatic environment.” The original aquatic ape theory, developed by Sir Alister Hardy and made public in 1960, posited that a population of early humans, or hominoids, was isolated during tectonic upheaval in a flooded forest environment, similar to that of parts of the Amazon. Our ancestors, it was argued, either adapted to water - and climbing in trees - or died out. Over many generations, mutations that made swimming and diving easier reproduced in the population at the expense of the more traditional, water-averse ape genes.

Modern-day apes do not like water. In zoos all around the world, apes are contained by moats of water. Even wadeable moats are sufficient: if you drop a baby orang-utan into water, it sinks like a stone. A human baby, however, will close its larynx and automatically paddle its arms and legs, giving you a few precious seconds to retrieve it.

The aquatic ape theory would explain this ability - unlike the traditional savannah theory of human evolution. Widely accepted wisdom states that when humans came out of the woods and on to the savannah, walking upright gave them an increased field of vision and freed up hands to use tools. Bipedalism also exposed less of the human body to the harsh sun and humans shed hair and increased sweat production to cope with the heat.

But, the aquatic ape proponents point out, deer and antelope kept their fur and their quadrupedal ways on the savannah. Our copious salty sweat production, and water consumption requirements, they argue, are far more indicative of life in the water. And lions co-operate in hunting without evolving significantly larger brains than other cats.

The key ingredients for growing a large brain, according to Professor Michael Crawford, from Imperial College London, are found in fish. “DHA, or docosahexaenoic acid, is essential for developing brain tissue, and in order for our brains to grow to the size we have now, our ancestors must have had to eat a lot of fish.”

This would have taken place over many hundreds of thousands if not millions of years, and is part of the reason that the aquatic ape theory has evolved since its last incarnation, into, tentatively, the waterside theory.

“Molluscs, crabs and snails would be available in abundance in coastal regions, flooded or swamp forests, lagoons and wetlands,” Professor Evans said. “Such lifestyles, climbing and hanging vertically, grasping branches above the water, wading on two legs, floating vertically collecting foods amid floating vegetation - might help explain hominoid body enlargement, tail loss, vertical spine, dorsal shoulder blades, wide thorax and pelvis, great ape tool use and thickening of enamel.” So waterside theorists are now proposing a prolonged exposure and adaptation towards coastal living, stretching over several million years. They argue that fossil evidence seems to back this up.

A sense of playful open-mindedness has made the aquatic theory attractive. Humans like water: waterfront property is more expensive; rich people buy swimming pools; we drive to the sea to eat sandwiches in our cars, just to look at it. No other ape likes water at all. Of course, as the space monkey satirists counter, no other apes have travelled into space, but it doesn't mean we evolved from primates on Pluto.

THE EVIDENCE FOR OUR AQUATIC ANCESTRY

BONES AND SKULLS

Humans have thick skulls and dense bones - unlike modern apes, but in common with shallow diving mammals such as manatees and walruses

PELVIS

Our vertical pelvis allows for upright wading. Only the proboscis monkey in Borneo, which habitually wades in mangrove swamps, has a pelvis like ours. This could be the possible origin of bipedalism

WRINKLED FINGERTIPS IN WATER

These are significantly more efficient at retrieving slippery objects underwater

DESCENDED LARYNX

Unlike other apes our larynx and palate are separated, allowing us to gulp large volumes of air, and hold our breath. It is this ability that has led to language development

SKIN

We are hairless, but also bonded with subcutaneous fat. This is totally unique in apes and rare in terrestrial mammals - but ubiquitous in diving mammals. Even a lean human carries 10 times as much fat as other apes, providing insulation and buoyancy. - The Independent

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