Bibliography
- Page ID
- 41399
[1] 1000 genomes project.
[2] et al Ciccarelli, Francesca. Toward automatic reconstruction of a highly resolved tree of life. Science, 311, 2006.
[3] Tal Dagan and William Martin. The tree of one percent. Genome Biology, Nov 2006.
[4] Ochman Howard Daubin Vincent, Moran Nancy A. Phylogenetics and the cohesion of bacterial genomes.
Science, 301, 2003.
[5] A.J. Enright, S. Van Dongen, and C. A. Ouzounis. An ecient algorithm for large-scale detection of
protein familes. Nucleic Acids Research, 30(7):1575–1584, Apr 2002.
[6] Stephanie Guindon and Olivier Gascuel. A simple, fast, and accurate algorithm to estimate large
phylogenies by maximum likelihood. Systems Biology, 52(5):696–704, 2003.
[7] Sanderson MJ. r8s: Inferring absolute rates of molecular evolution and divergence times in the absence
of a molecular clock. Bioinformatics, 19(2):301–302, Jan 2003.
[8] R. Thane Papke, Olga Zhaxybayeva, Edward J Fiel, Katrin Sommerfeld, Denise Muise, and W. Ford
Doolittle. Searching for species in haloarchaea. PNAS, 104(35):14092–14097, 2007.
[9] Pere Puigbo, Yuri I Wolf, and Eugene V Koonin. Search for a ’tree of life’ in the thicket of the
phylogenetic forest. Journal of Biology, 8(59), July 2009.
[10] Sagi Snir, Yuri I Wolf, and Eugene V Koonin. Universal pacemaker of genome evolution. PLoS compu-
tational biology, 8(11), 2012.
[11] Douglas L Theobald. A formal test of the theory of universal common ancestry. Nature, 465:219–222, 2010.