1. Quantifying the Impact of Population Size on Natural Selection Across the Genome
Lucas D. Baker1 Vikram E. Chhatre2 Hayley C. Lanier1
1Zoology & Physiology, University of Wyoming at Casper
2Wyoming INBRE Bioinformatics Core, University of Wyoming

2. Why Anthropogenic; adjective
created by people or caused by human activity: anthropogenic pollution
In a world in which humans are having an impact on our environment, as scientists it is important for us to better understand the effect and response nature is taking.

3. Arctic ground squirrel
Mammals of the Alaskan alpine
Alaska & Chugach ranges
All five species are south of the Yukon river
Brooks Range
Only three occur north
Yukon River
collared pika
hoary marmot
singing vole
Arctic ground squirrel
brown lemming
least
most
habitat specificity

4. animals/ha 0.62-7.2 0.6-7.8 1.5-6 5-50 50-200 ground squirrel
collared pika
hoary marmot
singing vole
brown lemming
1.5-6
5-50
50-200
animals/ha

5. Impact of genetic drift
Death by chance
Death by chance
collared pika
hoary marmot
singing vole
ground squirrel
brown lemming
1.5-6
5-50
50-200

6. Genetic Drift Death by Chance (will not pass on genes) Population
In this project, we looked to examine how mechanisms of evolution respond to an animals population size. Especially important was genetic drift.
Population

7. What is the impact of genetic drift on different size populations of Alaskan mammals?

8. Samples for sequencing collected from co-distributed populations throughout Alaska

9. Genomic data collection
Restriction digest
genomic DNA
Ligate adaptors and barcodes
Pool samples, size select, PCR enrich
Illumina paired-end sequencing
Reads filtered and assembled in STACKS
RADseq
We used an approach called RADseq, which yields a reduced-representation genome
For many questions you don’t need a full genome, and by randomly targeting a subset of the genome we can develop a strong understanding of evolutionary processes
Briefly, this approach consists of…
169 million reads
3,035,160 ± 1,271,412 per individual
Lanier et al. 2015, Mol. Ecol.

10. Single Nucleotide Polymorphism (SNP)
STACKS
Stacks (v1.44) variant discovery and analysis pipeline (Catchen et al. 20xx) to identify Single Nucleotide Polymorphisms (SNPs) in [ADD NUMBER] individuals from [ADD NUMBER] populations belonging to the five species.  Nucleotide diversity was estimated for all species and compared with population size.  Using genetic simulations over 50 generations, we applied strong selection pressure (s=0.2) on populations of varying sizes to see the effect of drift.   
We used an approach called RADseq, which yields a reduced-representation genome
For many questions you don’t need a full genome, and by randomly targeting a subset of the genome we can develop a strong understanding of evolutionary processes
Briefly, this approach consists of…
169 million reads
3,035,160 ± 1,271,412 per individual

11. What the simulations tell us
Species with larger population sizes have greater nucleotide diversity
selection coefficient (s) = 0.2
Small populations more likely to lose alleles due to genetic drift.
Selection works more effectively in large populations.
collared pika
hoary marmot
ground squirrel
singing vole
brown lemming

12. What the genomic data tell us
The number of polymorphic loci also differs by species.
Species with larger population sizes show more genomic variation

13. What the genomic data tell us
Species with larger population sizes have greater nucleotide diversity
Species with larger population sizes show more genomic variation

14. Rapid shift in climate Can adaptation keep up?
years before today (0 = 1950)
Vostok ice core data/J.R. Petit et al.; NOAA Mauna Loa CO2 record)

15. Conservation & Monitoring incorporating this information
hoary marmot
ground squirrel
singing vole
brown lemming
collared pika
Selection works more effectively in large populations.
Small populations more likely to lose alleles due to genetic drift.

16. Acknowledgments Wyoming INBRE Dr. Hayley Lanier Dr. Vikram Chhatre
Lewis Hein
Isaac Anderson
Haley Tolbert
Laura Diesburg
Shane Dodge
University of Wyoming’s Advanced Research Computing Center (ARCC)