Walking on two legs, or bipedalism, immediately sets us apart form other apes. It frees our arms for using tools and weapons and is a key part of our evolutionary success. Scientists have put forward a few theories to explain how our upright gait evolved, but the 'savannah theory' is by far the most prolific.
It's nicely illustrated by this misleading image that has become a mainstay of popular culture. It suggests that our ancestors went from four legs to two via the four-legged knuckle-walking gait of gorillas and chimps. Dwindling forests eventually pushed them from knuckle-walking to a full upright posture. This stance is more efficient over long distances and allowed our ancestors to travel across open savannahs.
But this theory fails in the light of new fossils which push back the first appearance of bipedalism to a time before the forests thinned, and even before our ancestors split from those of chimpanzees. Very early hominins, including Lucy (Australopithecus afarensis) and Millennium Man (Orrorin) certainly ambled along on two legs, but they did so through woodland not plains.
Our arms provide a further clue. Even though our ancestors' back legs quickly picked up adaptations for bipedalism, they steadfastly kept long, grasping arms, an adaptation more suited to moving through branches. To Susannah Thorpe at the University of Birmingham, these are signs that bipedalism evolved while our ancestors were still living in trees. And she has found new support for this theory by studying Sumatra's orang-utans, who occasionally take to two legs to negotiate tricky canopies.
Thorpe spent a year in the Sumatran jungle, studying the orang-utan - the only great ape to spend the majority of its life in the trees. She carefully documented over 3,000 sightings of wild orang-utans moving through the treetops. On large sturdy branches, they walk on all fours (below right), and on medium-sized ones, they start to use their arms to support their weight.
But on the thinnest and most unstable branches, the apes use a posture that Thorpe calls 'assisted bipedalism' (below left). They grip multiple branches with their long, prehensile toes and use their arms to balance and transfer their weight. And unlike chimps which bend their knees while standing up, bipedal orang-utans keep their legs straight, just like humans do.
It's a win-win posture - the hands provide extra safety, while the two-legged stance frees at least one hand to grab food or extra support. With it, the apes can venture onto the furthest and thinnest branches, which provides them with several advantages.
As Thorpe says, "Bipedalism is used to navigate the smallest branches where the tastiest fruits are, and also to reach further to help cross gaps between trees." That saves them energy because they don't have to circle around any gaps, and it saves their lives because they don't have to descend to the ground. "The Sumatran tiger is down there licking its lips", she said.
With these strong adaptive benefits, it becomes reasonable to suggest that bipedalism evolved among the branches. Based on this theory, Thorpe, along with Roger Holder and Robin Crompton from the University of Liverpool, have painted an intriguing new picture of ape evolution.
It begins in the same way as many others - with the rainforests of the Miocene epoch (24 to 5 million years ago) becoming increasingly patchy. For tree-dwelling apes, the gaps in the canopy started becoming too big to cross. But in Thorpe's view, these ancestral apes were already using a bipedal stance, and different groups took it in separate directions.
The ancestors of orang-utans remained in the increasingly fragmented canopy and became specialised and restricted there. The ancestors of chimps and those of gorillas specialised in climbing up and down trees to make use of food both in the canopy and on the ground. The postures used in vertical climbing are actually very similar to those used in four-legged knuckle-walking and this became their walk of choice on the ground.
The ancestors of humans abandoned the trees altogether. They used the bipedal stance that served them well on thin branches to exploit the potential of the stable land environment. Over time, they brought in further adaptations for efficient walking, culminating in the human walking style that we now neglect by sitting at a computer all day.
Thorpe's reconstruction fits her data, but isn't directly supported by it. Her study more generates an interesting hypothesis about the origins of human bipedalism than solves its mystery. Nonetheless, I like the idea; it's delightfully non-human-centric. It suggests that in the evolution of movement, we were conservatives who relied on a walk that had been around for millions of years. Chimps and gorillas with their fancy new knuckle-dragging gait were the true innovators.
Reference: Thorpe, Holder & Crompton. 2007. Origin of human bipedalism as an adaptation for locomotion on flexible branches. Science 316: 1328-1331.
Life Science
Comments
(The original article is here, available with a free registration. Also available are a technical comment by Begun, Richmond, and Strait, and a response (I won't provide links since more than one will get my comment bounced to the spam queue.))
IMO this provides considerable support for the theories of Aaron G. Filler, as documented in "The Upright Ape: A New Origin of the Species". Basically he suggests that the early ancestor of the great apes, roughly synchronized with Proconsul, was already bipedal.
Interestingly, this article (Thorpe et. al.) was published in June of 2007, "The Upright Ape" was released in July 2007.
Posted by: AK | March 21, 2009 1:57 PM
But this theory fails in the light of new fossils which push back the first appearance of bipedalism to a time before the forests thinned, and even before our ancestors split from those of chimpanzees.
which fossils are these? and are they ancestral to hominins or a parallel evolution of bipedality?
Posted by: suvrat | March 22, 2009 12:23 AM
http://www.statesman.com/news/content/news/stories/local/02/06/0206lucy.html
"Feature after feature point to her being bipedal," said John Kappelman, the UT professor of anthropology who led the scientific team that conducted the scans at UT's High-Resolution X-ray Computed Tomography Facility.
"But she also has curved fingers and toes, and a joint in her shoulder that points to more overhead movement than we have. She has longer arms relative to her legs than us."
Posted by: Lucy | March 25, 2009 1:16 AM
Posted by: AK | March 25, 2009 11:49 AM
I must point out that you are missing the most important biomechanical ingredient to achieving an upright posture.
In fact, your argument about holding onto limbs in trees is quite humerous.
Better luck next time.
Ken
Posted by: KEN LAY | November 25, 2009 6:22 PM