motifs X; motifs are neuroethologically relevant sequences of son

motifs.X; motifs are neuroethologically relevant sequences of song notes, Hahnloser et al., DNA Methyltransferas inhibitor 2002), with 1,132 genes common to both. In sharp contrast, 0 probes in the VSP had significant GS.singing.V or GS.motifs.V scores (Table S2). We observed small differences in probe expression values in the singing versus nonsinging birds: in area X, only 177 probes (∼0.9% of the total) showed > 100%

up- or downregulation, 65 probes > 200%, 3 probes > 1000%. In the VSP, only 17 probes showed > 100% up- or downregulation (∼0.08%), 6 probes > 200%, and 0 probes > 1000%. We also measured correlations to individual acoustic features such as Wiener entropy (a measure of width and uniformity of the power spectrum (Tchernichovski et al., 2000; GS.entropy) that are typically used to assess song (Figures 2B and S3, Table S2). GS.age was computed for

each bird as a negative control. Importantly, GS results did not influence network construction in any way. During preprocessing, all samples were hierarchically clustered to visualize interarray correlations ABT-199 solubility dmso and remove outliers (Supplemental Experimental Procedures). The area X versus VSP samples segregated into two distinct clusters, as would be expected if tissue source influences gene expression (Figure S1A). Within area X, the singing versus nonsinging birds segregated into two distinct subclusters (Figure S1B), indicating that singing is a profound regulator of gene expression in area X. Singing birds sang throughout the 2 hr recording period (Figures 2A and S2). There was a significant correlation between the number of motifs sung and Wiener entropy, replicating our prior finding of heightened vocal variability after 2 hr of singing (Figure 2B; Miller et al., 2010). To identify ensembles of genes that were tightly

coregulated (modules) during singing, we performed WGCNA (Experimental Procedures) of the area X samples and quantitatively related the resulting modules to traits. Coexpression networks were built based exclusively on expression levels, via unsupervised hierarchical clustering on a biologically significant not distance metric (topological overlap, TO; Experimental Procedures), and relationships between GS and network structure were only examined post hoc. Modules were defined as branches of the dendrogram obtained from clustering and labeled by colors beneath the dendrogram (Figure 3A; probes outside properly defined modules were considered background and colored gray). To study module composition we defined the first principal component of each module as the module eigengene (ME), which can be considered a weighted average of the probe expression profiles that make up the module. Correlating MEs to traits, e.g., number of motifs sung, is an efficient way to relate expression variability within modules to trait variability.

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