The Half-life of DNA in Bone: Measuring Decay Kinetics in 158 Dated Fossils

Overview

Journal Proc Biol Sci

Specialty Biology

Date 2012 Oct 12

PMID 23055061

Citations 156

Authors

Morten E Allentoft

Matthew Collins

David Harker

James Haile

Charlotte L Oskam

Marie L Hale

Paula F Campos

Jose A Samaniego

M Thomas P Gilbert

Eske Willerslev

Guojie Zhang

R Paul Scofield

Richard N Holdaway

Michael Bunce

Affiliations

Soon will be listed here.

Abstract

Claims of extreme survival of DNA have emphasized the need for reliable models of DNA degradation through time. By analysing mitochondrial DNA (mtDNA) from 158 radiocarbon-dated bones of the extinct New Zealand moa, we confirm empirically a long-hypothesized exponential decay relationship. The average DNA half-life within this geographically constrained fossil assemblage was estimated to be 521 years for a 242 bp mtDNA sequence, corresponding to a per nucleotide fragmentation rate (k) of 5.50 × 10(-6) per year. With an effective burial temperature of 13.1°C, the rate is almost 400 times slower than predicted from published kinetic data of in vitro DNA depurination at pH 5. Although best described by an exponential model (R(2) = 0.39), considerable sample-to-sample variance in DNA preservation could not be accounted for by geologic age. This variation likely derives from differences in taphonomy and bone diagenesis, which have confounded previous, less spatially constrained attempts to study DNA decay kinetics. Lastly, by calculating DNA fragmentation rates on Illumina HiSeq data, we show that nuclear DNA has degraded at least twice as fast as mtDNA. These results provide a baseline for predicting long-term DNA survival in bone.

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