Mitochondrial Point Mutations and Evolution: A Comparative Study Plethodon stormi Plethodon elongatus Stephanie Weitz Mentor: Dr.
Download ReportTranscript Mitochondrial Point Mutations and Evolution: A Comparative Study Plethodon stormi Plethodon elongatus Stephanie Weitz Mentor: Dr.
Mitochondrial Point Mutations and Evolution: A Comparative Study Plethodon stormi Plethodon elongatus Stephanie Weitz Mentor: Dr. Dee Denver Plethodon asupak Department of Zoology <http://www.californiaherps.com/salamanders/images> General Background on Weste Plethodons Important distinction between three species is range: • P. elongatus has large range in SW Oregon and NW California • P. stormi is restricted to small pockets in Siskiyou mountains of California • P. asupak is found a few miles west of P. stormi in the Siskiyous <http://www.bioone.org/perlserv/?request=displayfigures&name=i0018-0831-61-2-158-f01> Evolution Darwinian Theory: Species adapt to environment by natural selection http://www.biology-blog.com/images/blogs/12-2007/charles-darwin8221.jpg Neutral Theory of Molecular Evolution: Introduced by Motoo Kimura in the late 1960s At molecular level evolution occurs via random drift of neutral mutations Foundation of molecular clock hypothesis http://www.philo5.com/images/VraisPens eurs/KimuraMotoo200.jpg www.ccc.columbia.edu/Mitochondrial_Diseases/mito/round Hypothesis The mitochondrial genomes of these three Plethodons have large amounts of noncoding sequences that experience faster rates of evolution than proteincoding sequences. Muller et al. 2006 Objectives 1. Compare rates of evolution between three species using three different measures 2. Use rates to calculate time to the most recent common ancestor between species <http://www.californiaherps.com/salamanders/pages/p. asupak.html> Methods Obtained tissue samples Perform DNA sequence alignments DNA extraction MtDNA sequencing Data analysis in MEGA 4.1 and DNAsp 4.1 Designed primers PCR-amplify Measuring Rates of Evolution Ka: rate of substitution at amino acid-changing (replacement) codon positions Ks: rate of substitution at silent codon positions Knc: rate of substitution at any site in non-coding regions http://evolution.berkeley.edu/evosite/evo101/i mages/codon_GCA.gif http://www.mun.ca/biology/scarr/MGA2-03-28_mtDNA_code.jpg Molecular Clock Equation K TMRCA 2 TMRCA=Time to the most recent common ancestor (millions of years) K= Rate of evolution (Ka, Ks, Knc) µ= Mutation rate (humans=.95/base pair/Million year) Assumptions necessary to use equation Data Not all primers worked in all species P. asupak: only half of the primers worked Used pairwise DNA sequence alignments to calculate Ka, Ks, Knc Objective I Results Rates of Evolution Between Pairwise Comparisons 0.4 0.35 Rate 0.3 0.25 P. elongatus + P. stormi 0.2 P. elongatus + P. asupak P. stormi + P. asupak 0.15 0.1 0.05 0 Ks Ka Knc Highest rates of evolution occurred at silent sites Lowest rates of evolution occurred at replacement sites Rate of evolution intermediate for Knc Objective II Results Time to the Most Recent Common Ancestor Millions of Years 0.25 0.2 Ks TMRCA 0.15 Ka TMRCA 0.1 Knc TMRCA 0.05 0 P. elongatus + P. stormi P. elongatus + P. asupak P. stormi + P. asupak Ka and Knc give comparable, more recent times P. elongatus and P. stormi are the most closely related P. stormi and P. asupak are the most distantly related Conclusion Highest rate of evolution occurred at silent sites P. elongatus and P. stormi are the most closely related. P. stormi and P. asupak are the most distantly related Speciation occurred 250,000 years ago Future Research Amplify entire mitochondrial genomes for all three species Find divergence times within species Acknowledgements Denver lab: Dee, Dana, Sam, Caroline, Ashley, Bobby, Peter, Larry Dr. Kevin Ahern HHMI Albert Lee, PharmD Candidate 2010 Dr. Stevan Arnold and Douglas DeGross