1. Molecular Identification of Unknown Yellowstone Shrews
Nathan Stack &
Dr. Hayley Lanier

2. Acknowledgements Wyoming INBRE Field collection Lab assistance
Dr. Scott Seville
Dr. Zac Roehrs
Meredith Roehrs
Kevin Crouch-Jacobs
Ashkia Campbell
Andy Kulikowski, II
Lab assistance
Dr. John Chase
Dr. Motriuk-Smith
UW Core facility
UW Macromolecular Analysis Core

3. Introduction
Ecological & biodiversity studies

4. Introduction Ecological & biodiversity studies Challenges
Difficult to see
Hard to collect

5. Introduction Ecological & biodiversity studies Challenges Collection
Difficult to see
Hard to collect
Collection
Different methods
Types of traps

6. Introduction Ecological & biodiversity studies Challenges Collection
Difficult to see
Hard to collect
Collection
Different methods
Types of traps
Identification of cryptic species
External characters

7. Introduction Ecological & biodiversity studies Challenges Collection
Difficult to see
Hard to collect
Collection
Different methods
Types of traps
Identification of cryptic species
External characters

8. Introduction Ecological & biodiversity studies Challenges Shrews
Difficult to see
Hard to collect
Collection
Different methods
Types of traps
Identification of cryptic species
External characters
Shrews
Hard to determine species in the field
Look very similar

9. Introduction

10. Introduction

11. Sorex Unicuspids
1st upper incisor – large hooked, posterior cusp appears to be distinct tooth.

12. Sorex unicuspids
1st upper incisor – large hooked, posterior cusp appears to be distinct tooth.
Multiple species share the same unicuspid formula.

13. Yellowstone Project 1988 fire in Greater Yellowstone Area (GYA)
~570,000 ha
Shrews – features to specialize on eating insects. Short dense hair, no auditory bulla, zygomatic arch.
Soricidae family w/ true shrews. 3 subfamilies.

14. Yellowstone Project 1988 fire in Greater Yellowstone Area (GYA) Shrews
~570,000 ha
Shrews
Mammals
Must eat large quantities of invertebrates.
Invertebrate abundance
Shrews – features to specialize on eating insects. Short dense hair, no auditory bulla, zygomatic arch.
Soricidae family w/ true shrews. 3 subfamilies.

15. Yellowstone Project 1988 fire in Greater Yellowstone Area (GYA) Shrews
~570,000 ha
Shrews
Mammals
Must eat large quantities of invertebrates
Invertebrate abundance
Species identification
Field
Lab
Molecular identification methods
DNA barcoding
© L. Olson
Shrews – features to specialize on eating insects. Short dense hair, no auditory bulla, zygomatic arch.
Soricidae family w/ true shrews. 3 subfamilies.

16. DNA Barcoding

17. DNA Barcoding

18. DNA Barcoding

19. DNA Barcoding

21. Yellowstone Project
Shrews – features to specialize on eating insects. Short dense hair, no auditory bulla, zygomatic arch.
Soricidae family w/ true shrews. 3 subfamilies.

22. Methods & Materials Collection
222 shrews trapped, 173 specimens (& tissues) kept
Sherman traps & pitfall traps

23. Methods & Materials
Extraction
Genomic DNA
DNeasy Blood & Tissue Kit

24. Methods & Materials PCR optimization
Custom cycles designed based on thermal gradients
DNA amplification
Polymerase chain reaction (PCR) using thermocycler
Primers
Cytochrome b
Breast Cancer Susceptibility
1 Gene
Apoplipoprotein B gene

25. Methods & Materials Electrophoresis
After amplification, gels visualized
DNA visualization

26. Methods & Materials Sequencing DNA cleanup & sequencing preparation
Exosap
Sequencing

27. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp.

28. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

29. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

30. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2 4
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

31. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2 4 - 71
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

32. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2 4 - 71 3
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

33. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2 4 - 71 3 78
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

34. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2 4 - 71 3 78
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

35. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2 4 - 71 3 78 15
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

36. Originally designated species
Results
Total of 50 samples sequenced
Actual Species
Originally designated species
Number Captured
Sorex cinereus
Sorex monticolus
Sorex spp. 24 2 4 - 71 3 78 15 1
Sorex sp. that stayed sp.  contamination issue. 22 species had more than one band, which complicated resulting chromatograms

37. Discussion East facing burn East facing control
More shrews in both types of plots. They now make up 25-35% of species diversity.

38. Discussion

39. Discussion

40. Discussion
28 sequences were clear enough to have nucleotide BLAST results on NCBI with a similar species
5 identified correctly in the field
4 misidentified in the field
19 newly identified to species
More species to be verified
or identified
More species from 2014 and past years waiting for molecular verification of identifications.

41. Beyond shrews… Habitat change Molecular techniques have many uses
Impacts biodiversity
Molecular techniques have many uses
Universal tool
Any species
Habitats are changing quickly, and this has impacts on biodiversity
These types of techniques can be used to very quickly assess diversity in an area.