Two million year old fossil ‘links 9ft giant ape to living orangutan’

Fossilized Gigantopithecus jawbones found in Guangxi Liu Chen Zhu Yuan cave in 1955, believed to be fr. Wild Man, mythic man/ape reported sighted over yrs.  (Photo by Forrest Anderson/The LIFE Images Collection via Getty Images/Getty Images)
Fossilized Gigantopithecus jawbones (Photo by Forrest Anderson/The LIFE Images Collection via Getty Images/Getty Images)

Genetic material found in an ancient tooth from a gigantic ape that lived in southern China millions of years ago has offered a link to orangutans living today.

The breakthrough could offer a new way for us to analyse our own ancestors, scientists believe

The dental enamel dates from 1.9 million years ago, and genetic materials were retreived from the fossils by breaking down their proteins.

The tooth is from a giant ape known as ‘Gigantopithecus blacki’, native to China, which was up to nine feet tall.


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The researchers say the genetic materials are "the oldest known skeletal proteins sequenced to date" - and offer hope to finding information on our own ancestors.

The researchers say that the findings, published in the journal Nature, show the possibility of extending "the evolutionary relationships between modern humans and extinct ones further back in time, at least up to two million years".

The oldest human fossil remains with conserved DNA date back 400,000 years - leaving a void in evolutionary history.

Frido Welker, a postdoctoral researcher at the Globe Institute, University of Copenhagen, and first author of the study, said: "Primates are relatively close to humans, evolutionary speaking."

He added: "This means that we can potentially retrieve similar information on the evolutionary line leading to humans."

The researchers used a technique known as mass spectrometry to sequence the dental enamel proteins of the Gigantopithecus.

The process involves breaking down proteins into peptides - which are short chains of amino acids - and analysing their masses to figure out their chemical composition.

King Kong / Gigantopithecus, Dinosaurier-Austellung, "Die Welt der Dinos" (" World of Dinosaurs") - "Im Reich der Giganten", Messe Centrum Bremen, Deutschland, Europa, Ausstellung, ausgestorbenes Tier (Modell), Reise, AS, DIG; P.-Nr.: 585/2011, 20.05.2011;  (Photo by Peter Bischoff/Getty Images)
A possible look for Gigantopithecus, courtesy of a German exhibition (Photo by Peter Bischoff/Getty Images)

This technique was also recently used to extract genetic information from a 1.7-million-year-old rhino tooth.

The method has been hailed as a "game changer" by scientists as it is able to acquire genetic information - especially from fossils excavated from subtropical regions - that were previously unobtainable using DNA testing.

Dr Welker said: "Until now, it has only been possible to retrieve genetic information from up to 10,000-year-old fossils in warm, humid areas."

The fossil remains of the Gigantopithecus - comprising a few lower jaws and lots of teeth - were initially discovered in 1935 in Chuifeng Cave in southern China but due to lack of cranial remains, scientists were unable to reconstruct the physical appearance of this mysterious animal.