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Computational Genetics Unlocks the Basis for Birdsong & Human Speech Morgan Wirthlin Dept. Behavioral Neuroscience Oregon Health & Science University.

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Presentation on theme: "Computational Genetics Unlocks the Basis for Birdsong & Human Speech Morgan Wirthlin Dept. Behavioral Neuroscience Oregon Health & Science University."— Presentation transcript:

1 Computational Genetics Unlocks the Basis for Birdsong & Human Speech Morgan Wirthlin Dept. Behavioral Neuroscience Oregon Health & Science University

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3 What is the Genomic basis of Complex, Learned Behavior?  How do learned behaviors evolve?  How can we treat underlying causes of behavioral pathologies?

4 Approach: novel computational pipelines informed by evolutionary systematics  Identify: novel, lineage-specific genes subserving behavior  Identify: critical, ‘core’ gene networks underlying behavior  Identify: regulatory elements driving core gene expression

5 Birdsong: a model for vocal learning

6 Birdsong as a model for vocal learning i) dependent on learning

7  Mice deafened at birth: ‘ calls’ develop normally  Mice born with no cortex: ‘calls’ develop normally ‘Calls’ not dependent on learning! Hammerschmidt et al (2012) BMC Neuro Mahrt et al (2013) JNeurosci Hammerschmidt et al (2015) Sci Rep

8 Kanzi the bonobo Koko the gorilla

9 Birdsong as a model for vocal learning i) dependent on learning ii) critical periods

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11 Birdsong as a model for vocal learning i) dependent on learning ii) critical periods iii) babbling phase

12 Adult tutor song Fee & Goldberg (2011) Neuroscience

13 Birdsong as a model for vocal learning i) dependent on learning ii) critical periods iii) babbling phase iv) dialects

14 Marler & Tamura (1962) Condor

15 Birdsong as a model for vocal learning i) dependent on learning ii) critical periods iii) babbling phase iv) dialects v) syntactic structure

16 1 sec 10 kHz motif syllables Gentner et al (2006) Nature phrase song

17 Birdsong as a model for vocal learning i) dependent on learning ii) critical periods iii) babbling phase iv) dialects v) syntactic structure vi) specialized brain areas for vocal learning

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19 Reiner et al (2004) J Comp Neurol

20 i) dependent on learning ii) critical periods iii) babbling phase iv) dialects v) syntactic structure vi) specialized brain areas for vocal learning Genomic Basis?

21 How do brain circuits for vocal learning evolve? 1) evolve new genes

22 Jarvis et al (2014) Science New avian tree of life based on full genomes

23 Genes unique to songbirds? Jarvis et al (2014) Science

24 Wirthlin et al 2014, BMC Genomics Gene locus-based strategy:

25 Wirthlin et al 2014, BMC Genomics Novel genes evolve in chromosomal breakage ‘hot spots’

26 Songbird-unique genes active in vocal circuits Novel gene: TMRA YTHDC2L1 Wirthlin et al 2014, BMC Genomics RA LMAN Motor Gesture Control Center Variability generator

27 How do brain circuits for vocal learning evolve? 1I) use old genes in new ways

28 Jarvis et al (2014) Science Three lineages of avian vocal learners… songbirds parrots hummingbirds

29 Reiner et al (2004) J Comp Neurol Analogous circuits for vocal learning…

30 songbird-unique parrot-unique humming bird- unique ‘core’ vocal learning gene set? human-unique

31 Pfenning et al (2014) Science Generate tissue-specific gene expression databases in songbirds, parrots, hummingbirds, and humans… blind analysis: what regions show similar gene expression patterns?

32 Pfenning et al (2014) Science Shared molecular signatures for vocal learning!

33 The space beyond genes… ~20,000 genes, ~1.5 % of the genome

34 The space beyond genes… ~20,000 genes, ~1.5 % of the genome Non-coding DNA elements regulate gene expression

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36 Transcription factors regulate song circuit genes

37 Could differences in non-coding DNA elements explain the circuit differences between learners and non-learners? songbirds parrots hummingbirds

38 Thanks! The Mello Lab at OHSU Claudio Mello Peter LovellJulia Carleton

39 Co-expressed gene sets contain underlying co-regulated gene networks Co-expressed gene set Enhancers / PromotersGenes

40 Co-expressed gene sets contain underlying co-regulated gene networks Co-expressed gene set Co-regulated gene network 1 Co-regulated gene network 2 Enhancers / PromotersGenes

41 Goal: identify co-regulated gene networks underlying properties of: 1) vocal control nuclei HVC, RA, Area X, nXIIts 2) vocal control nucleus cell types HVC-to-X projection neurons HVC-to-RA projection neurons

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43 2) Laser capture microdissection 1) Retrograde labeling 3) Array profiling Lombardino et al (2006) J Neuro Methods

44 7. Promoter motif discovery + TFBS enrichment analyses 8. Functional gene network building Cell type-specific promoter discovery pipeline Observed Score Expected Score 1. Probe filtering / QC 2. Differential Expression 3. Probe–to–Gene Curation 4. Tissue-specific 5’ UTR / TSS prediction 5. Tissue-specific promoter extraction 6. Validation through double fluorescent in situ hybridization: HVC–RA neurons: 104 cell type marker genes (confirmed through dFISH: n = 7 / 7, 100% confirmed) HVC–X neurons: 44 cell type marker genes (confirmed through dFISH: n = 7 / 7, 100% confirmed)

45 FUTURE DIRECTIONS  Test predicted promoters + enhancers for their ability to drive cell type-specific expression in the brain  Assess evolutionary dynamics of regulatory sequences  Manipulate critical regulatory sequences in vivo

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