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5. Towards complete and error-free genome assemblies of all vertebrate species

Author

Rhie, Arang, McCarthy, Shane A., Fedrigo, Olivier, Damas, Joana, Formenti, Giulio, Koren, Sergey, Uliano-Silva, Marcela, Chow, William, Fungtammasan, Arkarachai, Kim, Juwan, Lee, Chul, Ko, Byung June, Chaisson, Mark, Gedman, Gregory L., Cantin, Lindsey J., Thibaud-Nissen, Francoise, Haggerty, Leanne, Bista, Iliana, Smith, Michelle, Haase, Bettina, Mountcastle, Jacquelyn, Winkler, Sylke, Paez, Sadye, Howard, Jason, Vernes, Sonja C., Lama, Tanya M., Grutzner, Frank, Warren, Wesley C., Balakrishnan, Christopher N., Burt, Dave, George, Julia M., Biegler, Matthew T., Iorns, David, Digby, Andrew, Eason, Daryl, Robertson, Bruce, Edwards, Taylor, Wilkinson, Mark, Turner, George, Meyer, Axel, Kautt, Andreas F., Franchini, Paolo, Detrich, III, H. William, Svardal, Hannes, Wagner, Maximilian, Naylor, Gavin J. P., Pippel, Martin, Malinsky, Milan, Mooney, Mark, Simbirsky, Maria, Hannigan, Brett T., Pesout, Trevor, Houck, Marlys, Misuraca, Ann, Kingan, Sarah B., Hall, Richard, Kronenberg, Zev, Sović, Ivan, Dunn, Christopher, Ning, Zemin, Hastie, Alex, Lee, Joyce, Selvaraj, Siddarth, Green, Richard E., Putnam, Nicholas H., Gut, Ivo, Ghurye, Jay, Garrison, Erik, Sims, Ying, Collins, Joanna, Pelan, Sarah, Torrance, James, Tracey, Alan, Wood, Jonathan, Dagnew, Robel E., Guan, Dengfeng, London, Sarah E., Clayton, David F., Mello, Claudio V., Friedrich, Samantha R., Lovell, Peter V., Osipova, Ekaterina, Al-Ajli, Farooq O., Secomandi, Simona, Kim, Heebal, Theofanopoulou, Constantina, Hiller, Michael, Zhou, Yang, Harris, Robert S., Makova, Kateryna D., Medvedev, Paul, Hoffman, Jinna, Masterson, Patrick, Clark, Karen, Martin, Fergal, Howe, Kevin, Flicek, Paul, Walenz, Brian P., Kwak, Woori, Clawson, Hiram, Diekhans, Mark, Nassar, Luis, Paten, Benedict, Kraus, Robert H. S., Crawford, Andrew J., Gilbert, M. Thomas P., Zhang, Guojie, Venkatesh, Byrappa, Murphy, Robert W., Koepfli, Klaus-Peter, Shapiro, Beth, Johnson, Warren E., Di Palma, Federica, Marques-Bonet, Tomas, Teeling, Emma C., Warnow, Tandy, Graves, Jennifer Marshall, Ryder, Oliver A., Haussler, David, O’Brien, Stephen J., Korlach, Jonas, Lewin, Harris A., Howe, Kerstin, Myers, Eugene W., Durbin, Richard, Phillippy, Adam M., and Jarvis, Erich D.

Published
2021
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6. Bird song comparison using deep learning trained from avian perceptual judgments.

Author

Zandberg, Lies, Morfi, Veronica, George, Julia M., Clayton, David F., Stowell, Dan, and Lachlan, Robert F.

Subjects
OPERANT conditioning, BIRDSONGS, ZEBRA finch, ANIMAL communication, SONGBIRDS, DEEP learning
Abstract

Our understanding of bird song, a model system for animal communication and the neurobiology of learning, depends critically on making reliable, validated comparisons between the complex multidimensional syllables that are used in songs. However, most assessments of song similarity are based on human inspection of spectrograms, or computational methods developed from human intuitions. Using a novel automated operant conditioning system, we collected a large corpus of zebra finches' (Taeniopygia guttata) decisions about song syllable similarity. We use this dataset to compare and externally validate similarity algorithms in widely-used publicly available software (Raven, Sound Analysis Pro, Luscinia). Although these methods all perform better than chance, they do not closely emulate the avian assessments. We then introduce a novel deep learning method that can produce perceptual similarity judgements trained on such avian decisions. We find that this new method outperforms the established methods in accuracy and more closely approaches the avian assessments. Inconsistent (hence ambiguous) decisions are a common occurrence in animal behavioural data; we show that a modification of the deep learning training that accommodates these leads to the strongest performance. We argue this approach is the best way to validate methods to compare song similarity, that our dataset can be used to validate novel methods, and that the general approach can easily be extended to other species. Author summary: How do birds hear the differences between their songs? This fascinating question carries implications, since the study of bird song, a model system for the neurobiology of learning and animal communication, depends critically on our ability to assess the similarity of songs. Traditionally, researchers compare sounds by human assessment, or use computational methods based on human intuitions about similarity. However, neither approach is connected to birds' own perception of sound similarity. Here, using a novel automated operant conditioning system, we recorded many thousands of acoustic judgments of similarity from zebra finches, and used this perceptual decision data for the first time to train a deep learning system. The trained system outperforms other computational methods for the task of making the same judgments as birds. This algorithm to compare song similarity, together with the potential of extending the general approach to other species, places the study of bird song on a firmer footing. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Transcript‐ and annotation‐guided genome assembly of the European starling.

Author

Stuart, Katarina C., Edwards, Richard J., Cheng, Yuanyuan, Warren, Wesley C., Burt, David W., Sherwin, William B., Hofmeister, Natalie R., Werner, Scott J., Ball, Gregory F., Bateson, Melissa, Brandley, Matthew C., Buchanan, Katherine L., Cassey, Phillip, Clayton, David F., De Meyer, Tim, Meddle, Simone L., and Rollins, Lee A.

Subjects
STURNUS vulgaris, GENOMICS, ZEBRA finch, NUCLEAR matrix, GENE mapping, STARLINGS
Abstract

The European starling, Sturnus vulgaris, is an ecologically significant, globally invasive avian species that is also suffering from a major decline in its native range. Here, we present the genome assembly and long‐read transcriptome of an Australian‐sourced European starling (S. vulgaris vAU), and a second, North American, short‐read genome assembly (S. vulgaris vNA), as complementary reference genomes for population genetic and evolutionary characterization. S. vulgaris vAU combined 10× genomics linked‐reads, low‐coverage Nanopore sequencing, and PacBio Iso‐Seq full‐length transcript scaffolding to generate a 1050 Mb assembly on 6222 scaffolds (7.6 Mb scaffold N50, 94.6% busco completeness). Further scaffolding against the high‐quality zebra finch (Taeniopygia guttata) genome assigned 98.6% of the assembly to 32 putative nuclear chromosome scaffolds. Species‐specific transcript mapping and gene annotation revealed good gene‐level assembly and high functional completeness. Using S. vulgaris vAU, we demonstrate how the multifunctional use of PacBio Iso‐Seq transcript data and complementary homology‐based annotation of sequential assembly steps (assessed using a new tool, saaga) can be used to assess, inform, and validate assembly workflow decisions. We also highlight some counterintuitive behaviour in traditional busco metrics, and present buscomp, a complementary tool for assembly comparison designed to be robust to differences in assembly size and base‐calling quality. This work expands our knowledge of avian genomes and the available toolkit for assessing and improving genome quality. The new genomic resources presented will facilitate further global genomic and transcriptomic analysis on this ecologically important species. [ABSTRACT FROM AUTHOR]

Published
2022
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19. The genome of a songbird

Author

Warren, Wesley C., Clayton, David F., Ellegren, Hans, Arnold, Arthur P., Hillier, LaDeana W., Künstner, Axel, Searle, Steve, White, Simon, Vilella, Albert J., Fairley, Susan, Heger, Andreas, Kong, Lesheng, Ponting, Chris P., Jarvis, Erich D., Mello, Claudio V., Minx, Pat, Lovell, Peter, Velho, Tarciso A. F., Ferris, Margaret, Balakrishnan, Christopher N., Sinha, Saurabh, Blatti, Charles, London, Sarah E., Li, Yun, Lin, Ya-Chi, George, Julia, Sweedler, Jonathan, Southey, Bruce, Gunaratne, Preethi, Watson, Michael, Nam, Kiwoong, Backström, Niclas, Smeds, Linnea, Nabholz, Benoit, Itoh, Yuichiro, Whitney, Osceola, Pfenning, Andreas R., Howard, Jason, Völker, Martin, Skinner, Bejamin M., Griffin, Darren K., Ye, Liang, McLaren, William M., Flicek, Paul, Quesada, Victor, Velasco, Gloria, Lopez-Otin, Carlos, Puente, Xose S., Olender, Tsviya, Lancet, Doron, Smit, Arian F. A., Hubley, Robert, Konkel, Miriam K., Walker, Jerilyn A., Batzer, Mark A., Gu, Wanjun, Pollock, David D., Chen, Lin, Cheng, Ze, Eichler, Evan E., Stapley, Jessica, Slate, Jon, Ekblom, Robert, Birkhead, Tim, Burke, Terry, Burt, David, Scharff, Constance, Adam, Iris, Richard, Hugues, Sultan, Marc, Soldatov, Alexey, Lehrach, Hans, Edwards, Scott V., Yang, Shiaw-Pyng, Li, XiaoChing, Graves, Tina, Fulton, Lucinda, Nelson, Joanne, Chinwalla, Asif, Hou, Shunfeng, Mardis, Elaine R., and Wilson, Richard K.

Published
2010
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26. High throughput analysis reveals dissociable gene expression profiles in two independent neural systems involved in the regulation of social behavior

Author

Stevenson Tyler J, Replogle Kirstin, Drnevich Jenny, Clayton David F, and Ball Gregory F

Subjects
Songbird, Microarray, Plasticity, Reproduction, Starling, POA, HVC, Area X, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurophysiology and neuropsychology, QP351-495
Abstract

Abstract Background Production of contextually appropriate social behaviors involves integrated activity across many brain regions. Many songbird species produce complex vocalizations called ‘songs’ that serve to attract potential mates, defend territories, and/or maintain flock cohesion. There are a series of discrete interconnect brain regions that are essential for the successful production of song. The probability and intensity of singing behavior is influenced by the reproductive state. The objectives of this study were to examine the broad changes in gene expression in brain regions that control song production with a brain region that governs the reproductive state. Results We show using microarray cDNA analysis that two discrete brain systems that are both involved in governing singing behavior show markedly different gene expression profiles. We found that cortical and basal ganglia-like brain regions that control the socio-motor production of song in birds exhibit a categorical switch in gene expression that was dependent on their reproductive state. This pattern is in stark contrast to the pattern of expression observed in a hypothalamic brain region that governs the neuroendocrine control of reproduction. Subsequent gene ontology analysis revealed marked variation in the functional categories of active genes dependent on reproductive state and anatomical localization. HVC, one cortical-like structure, displayed significant gene expression changes associated with microtubule and neurofilament cytoskeleton organization, MAP kinase activity, and steroid hormone receptor complex activity. The transitions observed in the preoptic area, a nucleus that governs the motivation to engage in singing, exhibited variation in functional categories that included thyroid hormone receptor activity, epigenetic and angiogenetic processes. Conclusions These findings highlight the importance of considering the temporal patterns of gene expression across several brain regions when engaging in social behaviors.

Published
2012
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27. Song exposure regulates known and novel microRNAs in the zebra finch auditory forebrain

Author

Kim Jong H, Creighton Chad J, Tennakoon Jayantha B, Coarfa Cristian, Drnevich Jenny, Benham Ashley L, Lin Ya-Chi, Gunaratne Preethi H, Milosavljevic Aleksandar, Watson Michael, Griffiths-Jones Sam, and Clayton David F

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background In an important model for neuroscience, songbirds learn to discriminate songs they hear during tape-recorded playbacks, as demonstrated by song-specific habituation of both behavioral and neurogenomic responses in the auditory forebrain. We hypothesized that microRNAs (miRNAs or miRs) may participate in the changing pattern of gene expression induced by song exposure. To test this, we used massively parallel Illumina sequencing to analyse small RNAs from auditory forebrain of adult zebra finches exposed to tape-recorded birdsong or silence. Results In the auditory forebrain, we identified 121 known miRNAs conserved in other vertebrates. We also identified 34 novel miRNAs that do not align to human or chicken genomes. Five conserved miRNAs showed significant and consistent changes in copy number after song exposure across three biological replications of the song-silence comparison, with two increasing (tgu-miR-25, tgu-miR-192) and three decreasing (tgu-miR-92, tgu-miR-124, tgu-miR-129-5p). We also detected a locus on the Z sex chromosome that produces three different novel miRNAs, with supporting evidence from Northern blot and TaqMan qPCR assays for differential expression in males and females and in response to song playbacks. One of these, tgu-miR-2954-3p, is predicted (by TargetScan) to regulate eight song-responsive mRNAs that all have functions in cellular proliferation and neuronal differentiation. Conclusions The experience of hearing another bird singing alters the profile of miRNAs in the auditory forebrain of zebra finches. The response involves both known conserved miRNAs and novel miRNAs described so far only in the zebra finch, including a novel sex-linked, song-responsive miRNA. These results indicate that miRNAs are likely to contribute to the unique behavioural biology of learned song communication in songbirds.

Published
2011
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28. Genomic and neural analysis of the estradiol-synthetic pathway in the zebra finch

Author

London Sarah E and Clayton David F

Subjects
Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurophysiology and neuropsychology, QP351-495
Abstract

Abstract Background Steroids are small molecule hormones derived from cholesterol. Steroids affect many tissues, including the brain. In the zebra finch, estrogenic steroids are particularly interesting because they masculinize the neural circuit that controls singing and their synthesis in the brain is modulated by experience. Here, we analyzed the zebra finch genome assembly to assess the content, conservation, and organization of genes that code for components of the estrogen-synthetic pathway and steroid nuclear receptors. Based on these analyses, we also investigated neural expression of a cholesterol transport protein gene in the context of song neurobiology. Results We present sequence-based analysis of twenty steroid-related genes using the genome assembly and other resources. Generally, zebra finch genes showed high homology to genes in other species. The diversity of steroidogenic enzymes and receptors may be lower in songbirds than in mammals; we were unable to identify all known mammalian isoforms of the 3β-hydroxysteroid dehydrogenase and 17β-hydroxysteroid dehydrogenase families in the zebra finch genome assembly, and not all splice sites described in mammals were identified in the corresponding zebra finch genes. We did identify two factors, Nobox and NR1H2-RXR, that may be important for coordinated transcription of multiple steroid-related genes. We found very little qualitative overlap in predicted transcription factor binding sites in the genes for two cholesterol transport proteins, the 18 kDa cholesterol transport protein (TSPO) and steroidogenic acute regulatory protein (StAR). We therefore performed in situ hybridization for TSPO and found that its mRNA was not always detected in brain regions where StAR and steroidogenic enzymes were previously shown to be expressed. Also, transcription of TSPO, but not StAR, may be regulated by the experience of hearing song. Conclusions The genes required for estradiol synthesis and action are represented in the zebra finch genome assembly, though the complement of steroidogenic genes may be smaller in birds than in mammals. Coordinated transcription of multiple steroidogenic genes is possible, but results were inconsistent with the hypothesis that StAR and TSPO mRNAs are co-regulated. Integration of genomic and neuroanatomical analyses will continue to provide insights into the evolution and function of steroidogenesis in the songbird brain.

Published
2010
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29. The zebra finch neuropeptidome: prediction, detection and expression

Author

Annangudi Suresh P, Southey Bruce R, London Sarah E, Xie Fang, Amare Andinet, Rodriguez-Zas Sandra L, Clayton David F, and Sweedler Jonathan V

Subjects
Biology (General), QH301-705.5
Abstract

Abstract Background Among songbirds, the zebra finch (Taeniopygia guttata) is an excellent model system for investigating the neural mechanisms underlying complex behaviours such as vocal communication, learning and social interactions. Neuropeptides and peptide hormones are cell-to-cell signalling molecules known to mediate similar behaviours in other animals. However, in the zebra finch, this information is limited. With the newly-released zebra finch genome as a foundation, we combined bioinformatics, mass-spectrometry (MS)-enabled peptidomics and molecular techniques to identify the complete suite of neuropeptide prohormones and final peptide products and their distributions. Results Complementary bioinformatic resources were integrated to survey the zebra finch genome, identifying 70 putative prohormones. Ninety peptides derived from 24 predicted prohormones were characterized using several MS platforms; tandem MS confirmed a majority of the sequences. Most of the peptides described here were not known in the zebra finch or other avian species, although homologous prohormones exist in the chicken genome. Among the zebra finch peptides discovered were several unique vasoactive intestinal and adenylate cyclase activating polypeptide 1 peptides created by cleavage at sites previously unreported in mammalian prohormones. MS-based profiling of brain areas required for singing detected 13 peptides within one brain nucleus, HVC; in situ hybridization detected 13 of the 15 prohormone genes examined within at least one major song control nucleus. Expression mapping also identified prohormone messenger RNAs in areas associated with spatial learning and social behaviours. Based on the whole-genome analysis, 40 prohormone probes were found on a commonly used zebra finch brain microarray. Analysis of these newly annotated transcripts revealed that six prohormone probes showed altered expression after birds heard song playbacks in a paradigm of song recognition learning; we partially verify this result experimentally. Conclusions The zebra finch peptidome and prohormone complement is now characterized. Based on previous microarray results on zebra finch vocal learning and synaptic plasticity, a number of these prohormones show significant changes during learning. Interestingly, most mammalian prohormones have counterparts in the zebra finch, demonstrating that this songbird uses similar biochemical pathways for neurotransmission and hormonal regulation. These findings enhance investigation into neuropeptide-mediated mechanisms of brain function, learning and behaviour in this model.

Published
2010
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31. Sexual differentiation of the zebra finch song system: potential roles for sex chromosome genes

Author

Clayton David F, Replogle Kirstin, Peabody Camilla, Tomaszycki Michelle L, Tempelman Robert J, and Wade Juli

Subjects
Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurophysiology and neuropsychology, QP351-495
Abstract

Abstract Background Recent evidence suggests that some sex differences in brain and behavior might result from direct genetic effects, and not solely the result of the organizational effects of steroid hormones. The present study examined the potential role for sex-biased gene expression during development of sexually dimorphic singing behavior and associated song nuclei in juvenile zebra finches. Results A microarray screen revealed more than 2400 putative genes (with a false discovery rate less than 0.05) exhibiting sex differences in the telencephalon of developing zebra finches. Increased expression in males was confirmed in 12 of 20 by qPCR using cDNA from the whole telencephalon; all of these appeared to be located on the Z sex chromosome. Six of the genes also showed increased expression in one or more of the song control nuclei of males at post-hatching day 25. Although the function of half of the genes is presently unknown, we have identified three as: 17-beta-hydroxysteroid dehydrogenase type IV, methylcrotonyl-CoA carboxylase, and sorting nexin 2. Conclusion The data suggest potential influences of these genes in song learning and/or masculinization of song system morphology, both of which are occurring at this developmental stage.

Published
2009
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33. The Songbird Neurogenomics (SoNG) Initiative: Community-based tools and strategies for study of brain gene function and evolution

Author

Lewin Harris A, Kim Ryan, Hernandez Alvaro G, Hasselquist Dennis, Gong George, George Julia M, Ferris Margaret, Drnevich Jenny, Dong Shu, Brenowitz Eliot A, Bensch Staffan, Band Mark, Ball Gregory F, Arnold Arthur P, Replogle Kirstin, Liu Lei, Lovell Peter V, Mello Claudio V, Naurin Sara, Rodriguez-Zas Sandra, Thimmapuram Jyothi, Wade Juli, and Clayton David F

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background Songbirds hold great promise for biomedical, environmental and evolutionary research. A complete draft sequence of the zebra finch genome is imminent, yet a need remains for application of genomic resources within a research community traditionally focused on ethology and neurobiological methods. In response, we developed a core set of genomic tools and a novel collaborative strategy to probe gene expression in diverse songbird species and natural contexts. Results We end-sequenced cDNAs from zebra finch brain and incorporated additional sequences from community sources into a database of 86,784 high quality reads. These assembled into 31,658 non-redundant contigs and singletons, which we annotated via BLAST search of chicken and human databases. The results are publicly available in the ESTIMA:Songbird database. We produced a spotted cDNA microarray with 20,160 addresses representing 17,214 non-redundant products of an estimated 11,500–15,000 genes, validating it by analysis of immediate-early gene (zenk) gene activation following song exposure and by demonstrating effective cross hybridization to genomic DNAs of other songbird species in the Passerida Parvorder. Our assembly was also used in the design of the "Lund-zfa" Affymetrix array representing ~22,000 non-redundant sequences. When the two arrays were hybridized to cDNAs from the same set of male and female zebra finch brain samples, both arrays detected a common set of regulated transcripts with a Pearson correlation coefficient of 0.895. To stimulate use of these resources by the songbird research community and to maintain consistent technical standards, we devised a "Community Collaboration" mechanism whereby individual birdsong researchers develop experiments and provide tissues, but a single individual in the community is responsible for all RNA extractions, labelling and microarray hybridizations. Conclusion Immediately, these results set the foundation for a coordinated set of 25 planned experiments by 16 research groups probing fundamental links between genome, brain, evolution and behavior in songbirds. Energetic application of genomic resources to research using songbirds should help illuminate how complex neural and behavioral traits emerge and evolve.

Published
2008
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34. Dosage compensation is less effective in birds than in mammals

Author

Itoh Yuichiro, Melamed Esther, Yang Xia, Kampf Kathy, Wang Susanna, Yehya Nadir, Van Nas Atila, Replogle Kirstin, Band Mark R, Clayton David F, Schadt Eric E, Lusis Aldons J, and Arnold Arthur P

Subjects
Biology (General), QH301-705.5
Abstract

Abstract Background In animals with heteromorphic sex chromosomes, dosage compensation of sex-chromosome genes is thought to be critical for species survival. Diverse molecular mechanisms have evolved to effectively balance the expressed dose of X-linked genes between XX and XY animals, and to balance expression of X and autosomal genes. Dosage compensation is not understood in birds, in which females (ZW) and males (ZZ) differ in the number of Z chromosomes. Results Using microarray analysis, we compared the male:female ratio of expression of sets of Z-linked and autosomal genes in two bird species, zebra finch and chicken, and in two mammalian species, mouse and human. Male:female ratios of expression were significantly higher for Z genes than for autosomal genes in several finch and chicken tissues. In contrast, in mouse and human the male:female ratio of expression of X-linked genes is quite similar to that of autosomal genes, indicating effective dosage compensation even in humans, in which a significant percentage of genes escape X-inactivation. Conclusion Birds represent an unprecedented case in which genes on one sex chromosome are expressed on average at constitutively higher levels in one sex compared with the other. Sex-chromosome dosage compensation is surprisingly ineffective in birds, suggesting that some genomes can do without effective sex-specific sex-chromosome dosage compensation mechanisms.

Published
2007
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36. Acute social isolation alters neurogenomic state insongbird forebrain.

Author

George, Julia M., Bell, Zachary W., Condliffe, Daniel, Dohrer, Kirstin, Abaurrea, Teresa, Spencer, Karen, Leitão, Albertine, Gahr, Manfred, Hurd, Paul J., and Clayton, David F.

Subjects
SOCIAL isolation, PROSENCEPHALON, ZEBRA finch, GENE expression, DNA methylation
Abstract

Prolonged social isolation has negative effects on brain and behavior in humans and other social organisms, but neural mechanisms leading to these effects are not understood. Here we tested the hypothesis that even brief periods of social isolation can alter gene expression and DNA methylation in higher cognitive centers of the brain, focusing on the auditory/associative forebrain of the highly social zebra finch. Using RNA sequencing, we first identified genes that individually increase or decrease expression after isolation and observed general repression of gene sets annotated for neurotrophin pathways and axonal guidance functions. We then pursued 4 genes of large effect size: EGR1 and BDNF (decreased by isolation) and FKBP5 and UTS2B (increased). By in situ hybridization, each gene responded in different cell subsets, arguing against a single cellular mechanism. To test whether effects were specific to the social component of the isolation experience, we compared gene expression in birds isolated either alone or with a single familiar partner. Partner inclusion ameliorated the effect of solo isolation on EGR1 and BDNF, but not on FKBP5 and UTS2B nor on circulating corticosterone. By bisulfite sequencing analysis of auditory forebrain DNA, isolation caused changes in methylation of a subset of differentially expressed genes, including BDNF. Thus, social isolation has rapid consequences on gene activity in a higher integrative center of the brain, triggering epigenetic mechanisms that may influence processing of ongoing experience. [ABSTRACT FROM AUTHOR]

Published
2020
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38. Variation in Reproductive Success Across Captive Populations: Methodological Differences, Potential Biases and Opportunities.

Author

Griffith, Simon C., Crino, Ondi L., Andrew, Samuel C., Nomano, Fumiaki Y., Adkins‐Regan, Elizabeth, Alonso‐Alvarez, Carlos, Bailey, Ida E., Bittner, Stephanie S., Bolton, Peri E., Boner, Winnie, Boogert, Neeltje, Boucaud, Ingrid C. A., Briga, Michael, Buchanan, Katherine L., Caspers, Barbara A., Cichoń, Mariusz, Clayton, David F., Derégnaucourt, Sebastien, Forstmeier, Wolfgang, and Guillette, Lauren M.

Subjects
ZEBRA finch, CAPTIVE wild birds, SPECIES, BIRD breeding, BIRD behavior, REPRODUCTION
Abstract

Our understanding of fundamental organismal biology has been disproportionately influenced by studies of a relatively small number of 'model' species extensively studied in captivity. Laboratory populations of model species are commonly subject to a number of forms of past and current selection that may affect experimental outcomes. Here, we examine these processes and their outcomes in one of the most widely used vertebrate species in the laboratory - the zebra finch ( Taeniopygia guttata). This important model species is used for research across a broad range of fields, partly due to the ease with which it can be bred in captivity. However despite this perceived amenability, we demonstrate extensive variation in the success with which different laboratories and studies bred their subjects, and overall only 64% of all females that were given the opportunity, bred successfully in the laboratory. We identify and review several environmental, husbandry, life-history and behavioural factors that potentially contribute to this variation. The variation in reproductive success across individuals could lead to biases in experimental outcomes and drive some of the heterogeneity in research outcomes across studies. The zebra finch remains an excellent captive animal system and our aim is to sharpen the insight that future studies of this species can provide, both to our understanding of this species and also with respect to the reproduction of captive animals more widely. We hope to improve systematic reporting methods and that further investigation of the issues we raise will lead both to advances in our fundamental understanding of avian reproduction as well as to improvements in future welfare and experimental efficiency. [ABSTRACT FROM AUTHOR]

Published
2017
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39. Functional genomic analysis and neuroanatomical localization of miR-2954, a song-responsive sex-linked microRNA in the zebra finch.

Author

Ya-Chi Lin, Balakrishnan, Christopher N., and Clayton, David F.

Subjects
RNA sequencing, ZEBRA finch, MOLECULAR genetics, FUNCTIONAL genomics, MICRORNA genetics, MITOGEN-activated protein kinases
Abstract

Natural experience can cause complex changes in gene expression in brain centers for cognition and perception, but the mechanisms that link perceptual experience and neurogenomic regulation are not understood. MicroRNAs (miRNAs or miRs) have the potential to regulate large gene expression networks, and a previous study showed that a natural perceptual stimulus (hearing the sound of birdsong in zebra finches) triggers rapid changes in expression of several miRs in the auditory forebrain. Here we evaluate the functional potential of one of these, miR-2954, which has been found so far only in birds and is encoded on the Z sex chromosome. Using fluorescence in situ hybridization and immunohistochemistry, we show that miR-2954 is present in subsets of cells in the sexually dimorphic brain regions involved in song production and perception, with notable enrichment in cell nuclei.We then probe its regulatory function by inhibiting its expression in a zebra finch cell line (G266) and measuring effects on endogenous gene expression using Illumina RNA sequencing (RNA-seq). Approximately 1000 different mRNAs change in expression by 1.5-fold or more (adjusted p < 0.01), with increases in some but not all of the targets that had been predicted by Targetscan. The population of RNAs that increase after miR-2954 inhibition is notably enriched for ones involved in the MAP Kinase (MAPK) pathway, whereas the decreasing population is dominated by genes involved in ribosomes and mitochondrial function. Since song stimulation itself triggers a decrease in miR-2954 expression followed by a delayed decrease in genes encoding ribosomal and mitochondrial functions, we suggest that miR-2954 may mediate some of the neurogenomic effects of song habituation. [ABSTRACT FROM AUTHOR]

Published
2014
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40. Advancing avian behavioral neuroendocrinology through genomics.

Author

Clayton, David F. and London, Sarah E.

Subjects
*NEUROENDOCRINOLOGY, *GENOMICS, *GENE expression, *CELLULAR signal transduction, *BIRD behavior, *NEUROBIOLOGY
Abstract

Highlights: [•] Genome and transcriptome data are rapidly becoming available in avian species. [•] Genomics can transform research by allowing study of large sets of genes at once instead one gene at a time. [•] Environmental and behavioral signals trigger massive shifts in gene expression in the brain. [•] Comparative approaches may help uncover the genetic roots of behavioral variation. [ABSTRACT FROM AUTHOR]

Published
2014
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41. The Genomics of Memory and Learning in Songbirds.

Author

Clayton, David F.

Subjects
*SONGBIRDS, *ANIMAL sound production, *BIRD communication, *GENE expression, *GENOMICS, *RNA
Abstract

Songbirds have unique value as a model for memory and learning. In their natural social life, they communicate through vocalizations that they must learn to produce and recognize. Song communication elicits abrupt changes in gene expression in regions of the forebrain responsible for song perception and production-what is the functional significance of this genomic response? For 20 years, the focus of research was on just a few genes [primarily ZENK, now known as egr1 ( early gene response 1)]. Recently, however, DNA microarrays have been developed and applied to songbird behavioral research, and in 2010 the initial draft assembly of the zebra finch genome was published. Together, these new data reveal that the genomic involvement in song processing is far more complex than anticipated. The concepts of neurogenomic computation and biological embedding are introduced as frameworks for future research. [ABSTRACT FROM AUTHOR]

Published
2013
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42. New Frontiers for Organismal Biology.

Author

KüLTZ, DIETMAR, CLAYTON, DAVID F., ROBINSON, GENE E., ALBERTSON, CRAIG, CAREY, HANNAH V., CUMMINGS, MOLLY E., DEWAR, KEN, EDWARDS, SCOTT V., HOFMANN, HANS A., GROSS, LOUIS J., KINGSOLVER, JOEL G., MEANEY, MICHAEL J., SCHLINGER, BARNEY A., SHINGLETON, ALEXANDER W., SOKOLOWSKI, MARLA B., SOMERO, GEORGE N., STANZIONE, DANIEL C., and TODGHAM, ANNE E.

Subjects
*LIFE history theory, *PHENOTYPES, *ORGANISMS, *BIOLOGY, *GENOTYPE-environment interaction, *ANIMAL behavior, *ANIMAL genetics, *GENES, *MOLECULAR biology
Abstract

Understanding how complex organisms function as integrated units that constantly interact with their environment is a long-standing challenge in biology. To address this challenge, organismal biology reveals general organizing principles of physiological systems and behavior -- in particular, in complex multicellular animals. Organismal biology also focuses on the role of individual variability in the evolutionary maintenance of diversity. To broadly advance these frontiers, cross-compatibility of experimental designs, methodological approaches, and data interpretation pipelines represents a key prerequisite. It is now possible to rapidly and systematically analyze complete genomes to elucidate genetic variation associated with traits and conditions that define individuals, populations, and species. However, genetic variation alone does not explain the varied individual physiology and behavior of complex organisms. We propose that such emergent properties of complex organisms can best be explained through a renewed emphasis on the context and life-history dependence of individual phenotypes to complement genetic data. [ABSTRACT FROM AUTHOR]

Published
2013
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43. Identifying context-specific gene profiles of social, reproductive, and mate preference behavior in a fish species with female mate choice.

Author

Ramsey, Mary E., Maginnis, Tara L., Wong, Ryan Y., Brock, Chad, Cummings, Molly E., Clayton, David F., Konopka, Genevieve, and Ka Wan Li

Subjects
FISH speciation, SENSORY evaluation, STATHMIN, TYROSINE hydroxylase, SOCIAL control
Abstract

Sensory and social inputs interact with underlying gene suites to coordinate social behavior. Here we use a naturally complex system in sexual selection studies, the swordtail, to explore how genes associated with mate preference, receptivity, and social affiliation interact in the female brain under specific social conditions. We focused on 11 genes associated with mate preference in this species (neuroserpin, neuroligin-3, NMDA receptor, tPA, stathmin-2, β-1 adrenergic receptor) or with female sociosexual behaviors in other taxa (vasotocin, isotocin, brain aromatase, α-1 adrenergic receptor, tyrosine hydroxylase). We exposed females to four social conditions, including pairings of differing mate choice complexity (large males, large/small males, small males), and a social control (two females). Female mate preference differed significantly by context. Multiple discriminant analysis (MDA) of behaviors revealed a primary axis (explaining 50.2% between-group variance) highlighting differences between groups eliciting high preference behaviors (LL, LS) vs. other contexts, and a secondary axis capturing general measures distinguishing a non-favored group (SS) from other groups. Gene expression MDA revealed a major axis (68.4% between-group variance) that distinguished amongst differential male pairings and was driven by suites of "preference and receptivity genes"; whereas a second axis, distinguishing high affiliation groups (large males, females) from low (small males), was characterized by traditional affiliative-associated genes (isotocin, vasotocin). We found context-specific correlations between behavior and gene MDA, suggesting gene suites covary with behaviors in a socially relevant context. Distinct associations between "affiliative" and "preference" axes suggest mate preference may be mediated by distinct clusters from those of social affiliation. Our results highlight the need to incorporate natural complexity of mating systems into behavioral genomics. [ABSTRACT FROM AUTHOR]

Published
2012
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44. Seasonal Changes in Patterns of Gene Expression in Avian Song Control Brain Regions.

Author

Thompson, Christopher K., Meitzen, John, Replogle, Kirstin, Drnevich, Jenny, Lent, Karin L., Wissman, Anne Marie, Farin, Federico M., Bammler, Theo K., Beyer, Richard P., Clayton, David F., Perkel, David J., and Brenowitz, Eliot A.

Subjects
PHOTOPERIODISM, GENE expression, RNA, HEPATITIS C, DNA
Abstract

Photoperiod and hormonal cues drive dramatic seasonal changes in structure and function of the avian song control system. Little is known, however, about the patterns of gene expression associated with seasonal changes. Here we address this issue by altering the hormonal and photoperiodic conditions in seasonally-breeding Gambel's white-crowned sparrows and extracting RNA from the telencephalic song control nuclei HVC and RA across multiple time points that capture different stages of growth and regression. We chose HVC and RA because while both nuclei change in volume across seasons, the cellular mechanisms underlying these changes differ. We thus hypothesized that different genes would be expressed between HVC and RA. We tested this by using the extracted RNA to perform a cDNA microarray hybridization developed by the SoNG initiative. We then validated these results using qRT-PCR. We found that 363 genes varied by more than 1.5 fold (>log2 0.585) in expression in HVC and/or RA. Supporting our hypothesis, only 59 of these 363 genes were found to vary in both nuclei, while 132 gene expression changes were HVC specific and 172 were RA specific. We then assigned many of these genes to functional categories relevant to the different mechanisms underlying seasonal change in HVC and RA, including neurogenesis, apoptosis, cell growth, dendrite arborization and axonal growth, angiogenesis, endocrinology, growth factors, and electrophysiology. This revealed categorical differences in the kinds of genes regulated in HVC and RA. These results show that different molecular programs underlie seasonal changes in HVC and RA, and that gene expression is time specific across different reproductive conditions. Our results provide insights into the complex molecular pathways that underlie adult neural plasticity. [ABSTRACT FROM AUTHOR]

Published
2012
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45. The zebra finch neuropeptidome: prediction,detection and expression.

Author

Fang Xie, London, Sarah E., Southey, Bruce R., Annangudi, Suresh P., Amare, Andinet, Rodriguez-Zas, Sandra L., Clayton, David F., and Sweedler, Jonathan V.

Subjects
ZEBRA finch, NEURAL transmission, NEUROPEPTIDES, PEPTIDE hormones, BIOINFORMATICS, LEARNING
Abstract

Background: Among songbirds, the zebra finch (Taeniopygia guttata) is an excellent model system for investigating the neural mechanisms underlying complex behaviours such as vocal communication, learning and social interactions. Neuropeptides and peptide hormones are cell-to-cell signalling molecules known to mediate similar behaviours in other animals. However, in the zebra finch, this information is limited. With the newly-released zebra finch genome as a foundation, we combined bioinformatics, mass-spectrometry (MS)-enabled peptidomics and molecular techniques to identify the complete suite of neuropeptide prohormones and final peptide products and their distributions. Results: Complementary bioinformatic resources were integrated to survey the zebra finch genome, identifying 70 putative prohormones. Ninety peptides derived from 24 predicted prohormones were characterized using several MS platforms; tandem MS confirmed a majority of the sequences. Most of the peptides described here were not known in the zebra finch or other avian species, although homologous prohormones exist in the chicken genome. Among the zebra finch peptides discovered were several unique vasoactive intestinal and adenylate cyclase activating polypeptide 1 peptides created by cleavage at sites previously unreported in mammalian prohormones. MS-based profiling of brain areas required for singing detected 13 peptides within one brain nucleus, HVC; in situ hybridization detected 13 of the 15 prohormone genes examined within at least one major song control nucleus. Expression mapping also identified prohormone messenger RNAs in areas associated with spatial learning and social behaviours. Based on the whole-genome analysis, 40 prohormone probes were found on a commonly used zebra finch brain microarray. Analysis of these newly annotated transcripts revealed that six prohormone probes showed altered expression after birds heard song playbacks in a paradigm of song recognition learning; we partially verify this result experimentally. Conclusions: The zebra finch peptidome and prohormone complement is now characterized. Based on previous microarray results on zebra finch vocal learning and synaptic plasticity, a number of these prohormones show significant changes during learning. Interestingly, most mammalian prohormones have counterparts in the zebra finch, demonstrating that this songbird uses similar biochemical pathways for neurotransmission and hormonal regulation. These findings enhance investigation into neuropeptide-mediated mechanisms of brain function, learning and behaviour in this model. [ABSTRACT FROM AUTHOR]

Published
2010
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46. Seasonal Differences of Gene Expression Profiles in Song Sparrow (Melospiza melodia) Hypothalamus in Relation to Territorial Aggression.

Author

Mukai, Motoko, Replogle, Kirstin, Drnevich, Jenny, Gang Wang, Wacker, Douglas, Band, Mark, Clayton, David F., and Wingfield, John C.

Subjects
SONG sparrow, GENE expression, HYPOTHALAMUS, NEUROENDOCRINE cells, BIRD breeding, LUTEINIZING hormone releasing hormone, TESTOSTERONE, MOLECULAR cloning, DNA microarrays, ANIMAL behavior
Abstract

Background: Male song sparrows (Melospiza melodia) are territorial year-round; however, neuroendocrine responses to simulated territorial intrusion (STI) differ between breeding (spring) and non-breeding seasons (autumn). In spring, exposure to STI leads to increases in luteinizing hormone and testosterone, but not in autumn. These observations suggest that there are fundamental differences in the mechanisms driving neuroendocrine responses to STI between seasons. Microarrays, spotted with EST cDNA clones of zebra finch, were used to explore gene expression profiles in the hypothalamus after territorial aggression in two different seasons. Methodology/Principal Findings: Free-living territorial male song sparrows were exposed to either conspecific or heterospecific (control) males in an STI in spring and autumn. Behavioral data were recorded, whole hypothalami were collected, and microarray hybridizations were performed. Quantitative PCR was performed for validation. Our results show 262 cDNAs were differentially expressed between spring and autumn in the control birds. There were 173 cDNAs significantly affected by STI in autumn; however, only 67 were significantly affected by STI in spring. There were 88 cDNAs that showed significant interactions in both season and STI. Conclusions/Significance: Results suggest that STI drives differential genomic responses in the hypothalamus in the spring vs. autumn. The number of cDNAs differentially expressed in relation to season was greater than in relation to social interactions, suggesting major underlying seasonal effects in the hypothalamus which may determine the differential response upon social interaction. Functional pathway analyses implicated genes that regulate thyroid hormone action and neuroplasticity as targets of this neuroendocrine regulation. [ABSTRACT FROM AUTHOR]

Published
2009
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47. Sexual differentiation of the zebra finch song system: potential roles for sex chromosome genes.

Author

Tomaszycki, Michelle L., Peabody, Camilla, Replogle, Kirstin, Clayton, David F., Tempelman, Robert J., and Wade, Juli

Subjects
BRAIN, ZEBRAS, SEX differences (Biology), GENES, SEX chromosomes, GENE expression
Abstract

Background: Recent evidence suggests that some sex differences in brain and behavior might result from direct genetic effects, and not solely the result of the organizational effects of steroid hormones. The present study examined the potential role for sex-biased gene expression during development of sexually dimorphic singing behavior and associated song nuclei in juvenile zebra finches. Results: A microarray screen revealed more than 2400 putative genes (with a false discovery rate less than 0.05) exhibiting sex differences in the telencephalon of developing zebra finches. Increased expression in males was confirmed in 12 of 20 by qPCR using cDNA from the whole telencephalon; all of these appeared to be located on the Z sex chromosome. Six of the genes also showed increased expression in one or more of the song control nuclei of males at post-hatching day 25. Although the function of half of the genes is presently unknown, we have identified three as: 17-beta-hydroxysteroid dehydrogenase type IV, methylcrotonyl-CoA carboxylase, and sorting nexin 2. Conclusion: The data suggest potential influences of these genes in song learning and/or masculinization of song system morphology, both of which are occurring at this developmental stage. [ABSTRACT FROM AUTHOR]

Published
2009
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48. Birdsong "Transcriptomics": Neurochemical Specializations of the Oscine Song System.

Author

Lovell, Peter V., Clayton, David F., Replogle, Kirstin L., and Mello, Claudio V.

Subjects
*BIRDSONGS, *SONGBIRDS, *BIRD vocalizations, *BIRD behavior, *LANGUAGE acquisition, *BRAIN, *CELL communication, *FUNCTIONAL genomics, *BIOINFORMATICS
Abstract

Background: Vocal learning is a rare and complex behavioral trait that serves as a basis for the acquisition of human spoken language. In songbirds, vocal learning and production depend on a set of specialized brain nuclei known as the song system. Methodology/Principal Findings: Using high-throughput functional genomics we have identified ,200 novel molecular markers of adult zebra finch HVC, a key node of the song system. These markers clearly differentiate HVC from the general pallial region to which HVC belongs, and thus represent molecular specializations of this song nucleus. Bioinformatics analysis reveals that several major neuronal cell functions and specific biochemical pathways are the targets of transcriptional regulation in HVC, including: 1) cell-cell and cell-substrate interactions (e.g., cadherin/catenin-mediated adherens junctions, collagen-mediated focal adhesions, and semaphorin-neuropilin/plexin axon guidance pathways); 2) cell excitability (e.g., potassium channel subfamilies, cholinergic and serotonergic receptors, neuropeptides and neuropeptide receptors); 3) signal transduction (e.g., calcium regulatory proteins, regulators of G-protein-related signaling); 4) cell proliferation/death, migration and differentiation (e.g., TGF-beta/BMP and p53 pathways); and 5) regulation of gene expression (candidate retinoid and steroid targets, modulators of chromatin/nucleolar organization). The overall direction of regulation suggest that processes related to cell stability are enhanced, whereas proliferation, growth and plasticity are largely suppressed in adult HVC, consistent with the observation that song in this songbird species is mostly stable in adulthood. Conclusions/Significance: Our study represents one of the most comprehensive molecular genetic characterizations of a brain nucleus involved in a complex learned behavior in a vertebrate. The data indicate numerous targets for pharmacological and genetic manipulations of the song system, and provide novel insights into mechanisms that might play a role in the regulation of song behavior and/or vocal learning. [ABSTRACT FROM AUTHOR]

Published
2008
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49. Natural selection in avian protein-coding genes expressed in brain.

Author

AXELSSON, ERIK, HULTIN-ROSENBERG, LINA, BRANDSTRÖM, MIKAEL, ZWAHLÉN, MARTIN, CLAYTON, DAVID F., and ELLEGREN, HANS

Subjects
BIRDS, GENES, HEREDITY, ORGANS (Anatomy), PRESERVATION of organs, tissues, etc., MAMMALS, CENTRAL nervous system, MUSCLE contraction, CELL death
Abstract

The evolution of birds from theropod dinosaurs took place approximately 150 million years ago, and was associated with a number of specific adaptations that are still evident among extant birds, including feathers, song and extravagant secondary sexual characteristics. Knowledge about the molecular evolutionary background to such adaptations is lacking. Here, we analyse the evolution of > 5000 protein-coding gene sequences expressed in zebra finch brain by comparison to orthologous sequences in chicken. Mean dN/ dS is 0.085 and genes with their maximal expression in the eye and central nervous system have the lowest mean dN/ dS value, while those expressed in digestive and reproductive tissues exhibit the highest. We find that fast-evolving genes (those which have higher than expected rate of nonsynonymous substitution, indicative of adaptive evolution) are enriched for biological functions such as fertilization, muscle contraction, defence response, response to stress, wounding and endogenous stimulus, and cell death. After alignment to mammalian orthologues, we identify a catalogue of 228 genes that show a significantly higher rate of protein evolution in the two bird lineages than in mammals. These accelerated bird genes, representing candidates for avian-specific adaptations, include genes implicated in vocal learning and other cognitive processes. Moreover, colouration genes evolve faster in birds than in mammals, which may have been driven by sexual selection for extravagant plumage characteristics. [ABSTRACT FROM AUTHOR]

Published
2008
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50. Functional identification of sensory mechanisms required for developmental song learning.

Author

London, Sarah E. and Clayton, David F.

Subjects
*ZEBRA finch, *PROSENCEPHALON, *ANIMAL sound production, *LEARNING, *HYPOTHESIS
Abstract

A young male zebra finch (Taeniopygia guttata) learns to sing by copying the vocalizations of an older tutor in a process that parallels human speech acquisition. Brain pathways that control song production are well defined, but little is known about the sites and mechanisms of tutor song memorization. Here we test the hypothesis that molecular signaling in a sensory brain area outside of the song system is required for developmental song learning. Using controlled tutoring and a pharmacological inhibitor, we transiently suppressed the extracellular signal–regulated kinase signaling pathway in a portion of the auditory forebrain specifically during tutor song exposure. On maturation, treated birds produced poor copies of tutor song, whereas controls copied the tutor song effectively. Thus the foundation of normal song learning, the formation of a sensory memory of tutor song, requires a conserved molecular pathway in a brain area that is distinct from the circuit for song motor control. [ABSTRACT FROM AUTHOR]

Published
2008
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