|dc.description||Appendix D content removed due to copyright restrictions:
Mohandsen, E., Mowla, S. J., Noobari, A. H., Hofreiter, M. (2008) "Ancient DNA from human and animal remains from north-west Iran", Journal of Sciences, Islamic Republic of Iran 19(1), 3-8.
Hay, J. M., Subramanian, S., Millar, C. D., Mohandesan, E., Lambert, D. M. (2008) "Rapid molecular evolution in a living fossil", Trends in Genetics, 24(3), 106-109.
Millar, C. D., Huynen, L., Subramanian, S., Mohandesan, E., Lambert, D. M. (2008) "New developments in ancient genomics", Trends in Ecology and Evolution, 23(7), 386-393.
Subramanian, S., Hay, J. M., Mohandesan, E., Millar, C. D., Lambert, D. M. (2008) "Molecular and morphological evolution in tuatara are decoupled", Trends in Genetics, 25(1), 16-18.||en_US
|dc.description.abstract||The enigmatic tuatara from New Zealand, occupies a central place in the evolution
of vertebrates and tuatara have changed little morphologically since the Cretaceous period
approximately 200 millions of years ago. A central aim of this thesis was to examine rates of
molecular evolution in tuatara using entire mitochondrial genomes of both ancient and
modern samples. A total of 51 complete mitochondrial genomes from 42 modern (from
eight island groups) and 9 ancient samples (from eight locations on mainland) were
sequenced using Sanger method.
These complete genomes were used to investigate the population genetic structure
of tuatara. Diverse phylogenetic analyses suggest that Sphenodon is a monotypic genus. This
is in contrast to the suggestion made by Daugherty et al. (1990 b) that there are two species
of tuatara. This two species model was subsequently almost universally accepted. The
current result illustrates that when species are incorrectly identified scarce conservation
resources are inappropriately used to ensure their conservation.
Using these complete mitochondrial genomes and by employing three very
different analytical methods, I have also estimated molecular evolutionary rates for tuatara.
Using modern and ancient complete mitochondrial genomes, I showed that the rates of
molecular evolution in tuatara are higher than other vertebrates. This result and the stable
morphology of tuatara over tens of millions of years suggest a disconnect between
molecular and anatomical evolution, as originally suggested by Allan Wilson in the 1970s.
From a biological perspective perhaps this is not surprising, since morphological and
molecular evolution are governed by very different biological processes.
I then explored the possibility that tuatara might be characterised by high mutation
rates. Using Roche 454 next generation DNA sequencing, I recovered seven complete
mitochondrial genomes in tuatara. A total of 28 potential heteroplasmies were detected
among these genomes. These sites were also shown to be polymorphic among the 42
modern aligned genomes suggesting that they are characterised by high mutation rates.
This result suggests that a high level of heteroplasmic sites in tuatara mitochondrial genome
contributes to the high molecular rates estimated when comparing modern and ancient