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New method developments in pollen DNA barcoding for forensic applications Karen Leanne Bell, Emory University Homeland Security Symposium Series, University.

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Presentation on theme: "New method developments in pollen DNA barcoding for forensic applications Karen Leanne Bell, Emory University Homeland Security Symposium Series, University."— Presentation transcript:

1 New method developments in pollen DNA barcoding for forensic applications Karen Leanne Bell, Emory University Homeland Security Symposium Series, University of Texas El Paso, June 2016 1

2 Overview Background and aims Testing the DNA metabarcoding method Quantification Whole genome shotgun approach Removal of non-pollen material Ongoing method development 2

3 Pollen species identification Applications: Forensics Allergen monitoring Pollination ecology Determining plant community composition Typical sample: Mixture of pollen species May be low quantity 3

4 Pollen DNA metabarcoding Advantages over microscopic examination: Greater taxonomic resolution 4 SPECIES FAMILY GENUS FAMILY GENUS Visual DNA SPECIES Visual DNA Image: C. Chu

5 Pollen DNA metabarcoding Advantages over microscopic examination: Some species lack features on pollen Few people trained in palynology Many more could be trained in pollen DNA metabarcoding 5

6 Pollen DNA metabarcoding Advantages over microscopic examination: Some species lack features on pollen Few people trained in palynology Faster with large numbers of samples 6

7 Pollen DNA metabarcoding Advantages over microscopic examination: Some species lack features on pollen Few people trained in palynology Faster with large numbers of samples Disadvantages: Not quantitative Species missing from databases No standard bioinformatics pipeline 7

8 Overview Background and aims Testing the DNA metabarcoding method Quantification Whole genome shotgun approach Removal of non-pollen material Ongoing method development 8

9 ITS rbcL matK trnL Pollen DNA metabarcoding Testing the method with known pollen mixtures 9

10 Pollen DNA metabarcoding: Concepts and definitions DNA barcoding: The identification of species based on DNA sequence of a standard gene region DNA metabarcoding: Simultaneous identification of all species in a mixture using high-throughput sequencing of a standard gene region 10

11 Mixed -species pollen samples from objects of interest Pollen exine lysis DNA isolation Amplification of barcoding marker Species 1 Species 2 Sample A Species 3 Species 4 Sample B Sample C … Apply unique index to each sample Index A Index B Index C Pool and sequence Sort and remove index sequences Sample A: -Species 1 -Species 2 Sample B: -Species 1 -Species 3 -Species 4 Sample C … -Species 1 -Species 2 -Species 3 DNA sequence data Sample A: -DNA barcode 1 -DNA barcode 2 Sample B: -DNA barcode 1 -DNA barcode 3 -DNA barcode 4 Sample C … -DNA barcode 1 -DNA barcode 2 -DNA barcode 3 Search DNA sequence database Bell, K.L., Burgess, K.S., Okamoto, K.C., Aranda, R., and Brosi, B.J. (2016). Forensic Science International: Genetics, 21: 110-116. 11

12 Testing the DNA metabarcoding method Why test the method? Don’t know how accurate the method is Don’t know how many samples can be multiplexed Don’t know if it is quantitative 12

13 Testing the basic pollen DNA metabarcoding method How many species can be detected within a sample? To what extent is this affected by taxonomic relatedness? How rare can a species be in a sample before it becomes undetectable? 13

14 Testing the method with “knowns” Mixtures of varying complexity: Number of species Relatedness Proportion of rarest species 450bp ITS2 500bp rbcL Illumina MiSeq: Dual-index 96 samples/flow cell Species identification with customized bioinformatics pipeline Bell, K.L., Burgess, K.S., Loeffler, V.M., Read, T.D., and Brosi, B.J. (in prep.). Testing the success of DNA metabarcoding of pollen for species identification and quantification with artificial mixtures of increasing complexity 14

15 ITS2 results: Increasing number of species 2 species detected3 species identified to species, Zea mays undetected, 2 species identified to genus Broussonetia papyrifera correctly identified, Zea mays undetected, Artemisia tridentata identified to genus 4 species identified to species, Zea mays undetected, 2 species identified to genus 2 species identified to species, Zea mays undetected, Artemisia tridentata identified to genus 5 species identified to species, Zea mays undetected, 2 species identified to genus 3 species identified to species, Zea mays undetected, Artemisia tridentata identified to genus 6 species identified to species, Zea mays undetected, 2 species identified to genus 15

16 ITS2 results: Effect of taxonomic relatedness Same genus 2 species detected Different APGIII lineage 2 species detected Same family 2 species detected Zea mays undetected Same APGIII lineage 2 species detected Monocot vs dicot 2 species detected 16

17 ITS2 results: Increasing rarity Different familiesSame family 2 species detected 17

18 Testing the DNA metabarcoding method: conclusions Success varied across species Success dependent on rarity Not affected by: Species richness Taxonomic relatedness Not quantitative 18

19 DNA metabarcdoing: ongoing research Bioinformatics pipeline for mixed-amplicon DNA metabarcoding including rbcL Effect of sequencing depth Standard methodology 19

20 Overview Background and aims Testing the DNA metabarcoding method Quantification Whole genome shotgun approach Removal of non-pollen material Ongoing method development 20

21 Quantitative pollen DNA metabarcoding: goals 21 http://remf.dartmouth.edu/imagesindex.html

22 Quantitative pollen DNA metabarcoding: benefits Benefits for various applications Pollination biology: Proportion of time on a particular plant species impacts pollination effectiveness Forensics: Fine-scale geographic/temporal signature May not differ qualitatively 22

23 Quantification & biases Sources of bias: Pollen preservation bias DNA isolation bias Amplification bias Copy number bias Phylogenetic trends Correction 23

24 Quantification: testing for biases Pollen preservation bias: Quantify DNA obtained from stored specimens DNA isolation bias: Quantify DNA obtained from fresh specimens Amplification bias: Context dependent Testing on mixtures of known species composition Copy number bias: rbcL and ITS2 qPCR methods 24

25 Quantification: copy number bias qPCR: Follows PCR amplification in real time using fluorescent dye Quantifies number of copies of gene of interest Determine copy number of chloroplast, ribosome and single-copy gene Look for phylogenetic patterns in copy number 25

26 Copy number bias: progress Primers developed for chloroplast for all major plant lineages Primers developed for ribosomal DNA for all major plant lineages Primers developed for single-copy nuclear gene for: Pinus taeda – gymnosperm Magnolia grandiflora – basal angiosperm Hibiscus syriacus – eudicot 26

27 Copy number bias: qPCR analysis Step 1: For 3 species with single-copy nuclear DNA primers: Use qPCR to find copy number of chloroplast, ribosome, and single-copy nuclear gene Calculate copy number per pollen grain for chloroplast & ribosome using: qPCR copy number of 3 genes Ploidy Number of cells per pollen grain 27

28 Copy number bias: qPCR analysis Step 1: For 3 species with single-copy nuclear DNA primers: Use qPCR to find copy number of chloroplast, ribosome, and single-copy nuclear gene Step 2: For all other species: Measure DNA concentration Use qPCR to find copy number of chloroplast & ribosome Calculate copy number per pollen grain for chloroplast & ribosome using: qPCR copy number of 3 genes DNA concentration Genome size Number of cells per pollen grain 28

29 Copy number bias: qPCR analysis Step 1: For 3 species with single-copy nuclear DNA primers: Use qPCR to find copy number of chloroplast, ribosome, and single-copy nuclear gene Step 2: For all other species: Measure DNA concentration Use qPCR to find copy number of chloroplast & ribosome For 3 species with single-copy nuclear DNA primers compare copy number calculation from both methods for accuracy 29

30 Copy number bias: sampling & phylogenetic analysis 100 species for analysis: 25 orders, 3 species each in different families 5 orders, 2 species-pairs in same genus, one species from another family Test for phylogenetic patterns in copy number Make generalizations for lineage, order, or family 30

31 Quantification: DNA isolation bias 31

32 Quantification: other biases Pollen preservation bias: Not examined Could be examined using stored samples Amplification bias: Could be examined with results of known mixtures Results will only apply under same PCR conditions Varies with other species in mixture 32

33 Quantification: ongoing research Test recently designed qPCR primers Quantify copy number of 100 species of pollen Determine phylogenetic trends for all biases Apply correction factors to convert from proportion of DNA sequencing reads to proportion of pollen grains Include correction factors in bioinformatics pipelines 33

34 Overview Background and aims Testing the DNA metabarcoding method Quantification Whole genome shotgun approach Removal of non-pollen material Ongoing method development 34

35 Whole Genome Shotgun (WGS) pollen DNA metabarcoding Random DNA Random DNA Random DNA Random DNA 35

36 WGS pollen DNA metabarcoding Advantages over PCR-based approaches: No amplification bias No copy number bias Finds variation between species identical in “barcode” genes Current challenges: Genome size bias Few species with genome data for reference library 36

37 Testing the WGS method How many species can be detected within a sample? To what extent is this affected by taxonomic relatedness? How rare can a species be in a sample before it becomes undetectable? How does it compare to mixed-amplicon sequencing? 37

38 Testing the method with “knowns” Subset of known mixtures used for mixed-amplicon sequencing Simulated data for same mixtures Illumina MiSeq: 21 indexed samples/flow cell 24-30M paired reads of 150bp Species identification with customized bioinformatics pipeline Bell, K.L., Macpherson, M., Burgess, K.S., Read, T.D., and Brosi, B. (in prep.) Assessing the potential for whole genome shotgun methods in mixed-species pollen identification using artificial mixtures 38

39 WGS results: Simulated data Same mixtures as laboratory samples, with exception of those containing Carya illinoinensis Mixture complexities: Up to 8 species Pairs of varying relatedness Down to 10% of pollen grains, 1% of DNA content 39

40 WGS results: Known pollen mixtures Results better than simulated data Fewer false positives All species identified except Carya illinoinensis 40

41 WGS results: Overall success All species could be identified given presence in reference database Advantages over mixed-amplicon sequencing: Species level identifications of species with identical ITS2 sequences Artemisia tridentata Populus tremuloides Detection of species that amplified poorly with ITS2 Zea mays Disadvantages over mixed-amplicon sequencing: Species absent from database: Carya illinoinensis 41

42 Testing the WGS DNA metabarcoding method: conclusions Demonstrated proof of concept Success varied only with database presence Not affected by: Species richness Taxonomic relatedness Rarity Probably not quantitative 42

43 WGS: ongoing research Is it quantitative? Quantitative comparison to standard DNA metabarcoding Effect of sequencing depth Standard methodology 43

44 Overview Background and aims Testing the DNA metabarcoding method Quantification Whole genome shotgun approach Removal of non-pollen material Ongoing method development 44

45 Ongoing method development Improving bioinformatics pipeline for mixed- amplicon DNA metabarcoding: Including multiple gene regions Correcting for biases Improving methods to remove non-pollen plant material Developing standard methods for DNA metabarcoding and Whole Genome Shotgun methods 45

46 Possible future directions Developing a geographical database to assist with determining geographic origin of pollen samples Trialing standard methods on known mixtures that resemble forensic samples Developing standard methods for specific types of forensic and other analyses 46

47 Acknowledgemen ts 47 Funding and Institutional Support: US Army Research Office (grants W911NF- 13-1-0247 & W911NF-13-1-0100 to Brosi, Read, & Burgess) Emory University Individuals: Berry Brosi (Emory) Kevin Burgess (Columbus State) Tim Read (Emory) Cindy Chu (Emory) Emily Dobbs (Emory) Julie Fowler (Emory) Virginia Loeffler (Emory) Donated plant material: Atlanta Botanical Garden Missouri Botanical Garden New York Botanical Garden Montgomery Botanical Center Royal Botanic Gardens Victoria

48 48 Karen Leanne Bell Emory University karen.bell@emory.edu

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