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Logo of nihpaAbout Author manuscriptsSubmit a manuscriptNIH Public Access; Author Manuscript; Accepted for publication in peer reviewed journal;
Nature. Author manuscript; available in PMC Sep 7, 2008.
Published in final edited form as:
PMCID: PMC2531203
NIHMSID: NIHMS60674

Behaviourally driven gene expression reveals song nuclei in hummingbird brain

Abstract

Hummingbirds have developed a wealth of intriguing features, such as backwards flight, ultraviolet vision, extremely high metabolic rates, nocturnal hibernation, high brain-to-body size ratio and a remarkable species–specific diversity of vocalizations14. Like humans, they have also developed the rare trait of vocal learning, this being the ability to acquire vocalizations through imitation rather than instinct5,6. Here we show, using behaviourally driven gene expression in freely ranging tropical animals, that the forebrain of hummingbirds contains seven discrete structures that are active during singing, providing the first anatomical and functional demonstration of vocal nuclei in hummingbirds. These structures are strikingly similar to seven forebrain regions that are involved in vocal learning and production in songbirds and parrots713—the only other avian orders known to be vocal learners5. This similarity is surprising, as songbirds, parrots and hummingbirds are thought to have evolved vocal learning and associated brain structures independently5,14, and it indicates that strong constraints may influence the evolution of forebrain vocal nuclei.

We conducted our study at a Nature Reserve of the Museu de Biologia Mello Leitão (Espírito Santo, Brazil), an enclave of the Atlantic Tropical Forest with over 30 hummingbird species15. We focused on the sombre hummingbird (Aphantochroa cirrhochloris) and the rufous-breasted hermit (Glaucis hirsuta) (Fig. 1). We identified brain areas involved in vocal communication, by monitoring expression of the transcriptional regulator ZENK (an acronym for Zif-268, Egr-1, NGFI-A and Krox-24) in freely ranging birds after hearing and vocalizing behaviours. ZENK messenger RNA synthesis in the brain is driven by neuronal depolarization, and its detection can be used to identify select regions that are activated by specific stimuli or behaviours16. This methodology has allowed us to map vocal communication areas throughout the brains of songbirds12,17 and a parrot13 (in both laboratory and natural18 settings) without disrupting the natural behaviour of the birds. This is important as hummingbird singing behaviour can be difficult to obtain under captivity, and it is currently not possible to identify relevant brain areas in freely ranging small animals using other methods such as electrophysiology.

Figure 1
Song sonograms (frequency versus time) of the hummingbird species studied: Aphantochroa cirrhochloris and Glaucis hirsuta15. Aphantochroa has a stereotyped song, consisting of an introductory note followed by several renditions of a two-note sequence: ...

Hummingbirds often sing while perched on a tree branch, and feed on nectar from nearby flowers between singing bouts. We located tree perches where individual birds sang most frequently, and set feeding traps consisting of a sugar-water bottle (a flower substitute) inside a small cage on nearby tree branches. The birds were caught upon entering the cage at a specific time after a certain behavioural state. We compared three groups: silent controls (birds caught early in the morning before the start of the dawn chorus); hearing only (birds caught around the same time after hearing a 25– 30-min conspecific song playback, but that did not sing in response); hearing and vocalizing (birds caught early in the morning after hearing song and singing one or more song bouts per min during the 25–30-min period) n = 3 males per group for Aphantochroa and one male per group for Glaucis. The birds were killed immediately upon capture and their brains processed for ZENK mRNA expression12,17.

Relative to silent controls, hearing only birds showed hearing-induced ZENK expression in seven brain areas that are conserved among avian species13,17: five telencephalic (NCM, CMHV, PC, Ndc, Ai); one thalamic (DIP); and one mesencephalic (MLd) (Figs 2 and and3a;3a; for all abbreviations, see Box 1). Relative to hearing only birds, hearing and vocalizing birds showed vocalizing-induced ZENK expression in eight discrete areas. Of these, seven are telencephalic, which we named and placed into three groups: first, a ‘posterior-medial cluster’ containing two nuclei (VMN and VMH); second, an ‘anterior cluster’ containing three nuclei (VAH, VAN and VAP); and last, a ‘posterior-lateral cluster’ containing two nuclei (VLN and VA) (Figs 2 and and3a).3a). The most marked vocalizing-induced expression occurred in VAN and VLN (Fig. 2b). The eighth structure was DM in the mesencephalon (Figs 2a and and3a),3a), a conserved avian vocal nucleus13,19. ZENK expression in these eight structures was proportional to the number of song bouts produced during the 25–30-min singing period (Fig. 3b).

Box 1

Anatomical structures

A, archistriatum; AAc, central nucleus of the anterior archistriatum; AC, anterior commissure; ACM, caudomedial archistriatum; Ai, intermediate archistriatum; Area X, area X of the paleostriatum; Av, nucleus avalanche; Cb, cerebellum; cp, choroid plexus; CMHV, caudomedial hyperstriatum ventrale; DIP, dorsointermediate nucleus of the posterior thalamus; DLM, medial nucleus of the dorsolateral thalamus; DM, dorsomedial nucleus; DMm, magnocellular nucleus of the dorsomedial thalamus; ex, extensions of LPOm; HA, hyperstriatum accessorium; HD, hyperstriatum dorsale; Hp, hippocampus; HV, hyperstriatum ventrale; HVC, high vocal center; HVoc, complex including the oval nucleus of the hyperstriatum ventrale and surrounds; ICo, intercollicular nucleus of the mesencephalon; L2, primary telencephalic auditory area; lAHV, lateral nucleus of the anterior hyperstriatum ventrale; lAN, lateral nucleus of the anterior neostriatum; LPOm, magnocellular nucleus of the parolfactory lobe; MAN, magnocellular nucleus of the anterior neostriatum; MLd, dorsal part of the lateral mesencephalic nucleus; N, neostriatum (not the same as the mammalian neostriatum); NAoc, complex including the oval nucleus of the anterior neostriatum and surrounds; NCM, caudomedial neostriatum; Ndc, dorsocaudal neostriatum; NIDL, neostriatum intermedium pars dorsolateralis; NIf, nucleus interfacialis; NLc, central nucleus of the lateral neostriatum; nXIIts, tracheosyringeal subdivision of the hypoglossal nucleus; OC, optic chiasm; OM, occipitomesencephalic tract; OT, optic tectum; Ov, nucleus ovoidalis of the thalamus; P, paleostriatum; PC, caudal paleostriatum; PP, paleostriatum primitivum; RA, robust nucleus of the archistriatum; S, septum; T, thalamus; v, ventricle; VA, vocal nucleus of the archistriatum; VAH, vocal nucleus of the anterior hyperstriatum ventrale; VAN, vocal nucleus of the anterior neostriatum; VAP, vocal nucleus of the anterior paleostriatum; VLN, vocal nucleus of the lateral neostriatum; VMH, vocal nucleus of the medial hyperstriatum ventrale; VMN, vocal nucleus of the medial neostriatum.

Figure 2
Identification of vocal control brain areas. a, Camera lucida drawings of parasagittal sections from Aphantochroa. Dashed lines, regions of vocalizing-induced ZENK expression. Numbers indicate mm from midline. b, Dark-field views of ZENK-hybridized sections. ...
Figure 3
Quantification of ZENK expression. a, Regions with hearing-induced expression (left, P, 0.03 to <0.0001), vocalizing-induced expression (centre, P, 0.02 to <0.0005), or no induced expression (right, P, 0.2 to 0.84; two-tailed unpaired ...

All seven forebrain structures with vocalizing-induced expression have distinct histological features that differentiate them from surrounding tissues (Fig. 2d). The same seven structures were found in NissI-stained sections from males of two other hummingbird species that we caught at the Museu Mello Leitão: swallowtailed (Eupetomena macroura) and white-throated (Leucochloris albicollis). The four species that we studied cover the two hummingbird lineages, Glaucis being one of the most ancient Phaethornithinae (hermits), Aphantochroa and Eupetomena two ancient Trochilinae (non-hermits), and Leucochloris a more recently derived Trochilinae (ref. 1; and K. L. Schuchmann and R. Bleiweiss, personal communication). Thus, forebrain vocal nuclei appear to have been present early among hummingbirds. Vocal learning has been demonstrated directly by raising birds in isolation from conspecifics for one species of the Trochilinae lineage, and indirectly through the analysis of individual variability in seven species of the Phaethornithinae lineage1,46. Thus, it is generally assumed that vocal learning was also present early in hummingbirds.

To our knowledge, our results represent a first anatomical and functional demonstration of vocal control brain nuclei in hummingbirds. Moreover, we have identified a whole set of fore-brain vocal control structures in a vocal learning order—something that has taken years in other species using different methodologies. This now provides a map for future anatomical, physiological and behavioural investigations. Interestingly, both songbirds and budgerigars (a parrot), have also been shown to have exactly seven forebrain structures with singing-induced ZENK expression12,13. Three of these nuclei are at the same relative positions in the anterior telencephalon in parrots, hummingbirds and songbirds (Fig. 4, structures in red). The other four nuclei are in different locations of the posterior and/or lateral telencephalon (Fig. 4, structures in yellow) but within the same brain subdivisions (Table 1). These nuclei have marked morphological similarities across orders. For example, parrot NLc11,13, hummingbird VLN (Fig. 2) and songbird HVC7 bulge into the overlying ventricle. Parrot AAc11,13, hummingbird VA (Fig. 2) and songbird RA7 have an oval shape and constitute cytoarchitectonically very distinct nuclei within the archistriatum. The posterior-lateral nuclei in songbirds and budgerigars (Fig. 4, structures in yellow) are part of a pathway whose output is to the syrinx11,20, and in songbirds controls production of learned vocalizations7,9,12. The anterior nuclei (Fig. 4, structures in red) control vocal learning in songbirds8, and are part of a pathway comparable to cortico-basal ganglia-thalamo-cortical loops1012 in mammals, which participate in the learning and maintenance of sequential motor actions dependent on sensorimotor integration21.

Figure 4
Comparative brain anatomy of hearing- and vocalizing-induced ZENK expression in avian vocal learners. Left, partial phylogenetic tree based on Sibley and Ahlquist24, with one common species name per order; colours indicate evidence for vocal learning ...
Table 1
Telencephalic subdivisions and their vocalizing-activated nuclei across vocal learning avian orders*

Our findings have implications for the evolution of brain structures that control a complex behaviour. Vocal learning is a rare trait known to occur in only three groups of birds (parrots, hummingbirds and songbirds) and three groups of mammals (humans, cetaceans (whales/dolphins) and bats)5,6,14,22,23. Because they are phylogenetically separated by vocal non-learners24 (Fig. 4), it is thought that the three avian vocal learning groups, and presumably the mammalian ones, evolved vocal learning independently5,14. Similarly, the associated forebrain vocal control structures are absent in avian vocal non-learners, and it is believed that songbirds, parrots and presumably hummingbirds evolved such structures independently14,25. Modern birds evolved from a common ancestor thought to have lived about 65 million years ago near the Cretaceous/Tertiary transition26. Of the descendents, parrots are the oldest vocal learning order, followed by hummingbirds and then oscine songbirds24 (Fig. 4). According to the dominant hypothesis5,14, our results indicate that within the past 65 million years 3 out of 23 avian orders24 may have independently evolved 7 similar forebrain vocal structures for a complex behaviour (Fig. 4). This would suggest that the evolution of these structures is under strong epigenetic constraints; in which case, similar structures may have also evolved in vocal learning mammals (humans, cetaceans and bats). Alternatively, vocal learning and associated brain structures may have been present in a common ancestor to avian vocal learners. In this regard, there is a shift in the posterior forebrain vocal structures from more anterior-lateral to posterior-medial positions, in accordance with the relative age of the vocal learning orders (Fig. 4). This hypothesis requires that the forebrain vocal structures were lost in the intervening vocal non-learning orders at least four times independently (Fig. 4). Such a loss could be due to the considerable expense required to maintain vocal learning and associated brain structures, with many birds possibly evolving in adaptive zones that did not require complex learned vocalizations. Another alternative hypothesis is that avian vocal non-learners have some rudimentary form of forebrain vocal areas that were previously missed by Nissl and tract tracing studies14,19,25. If true, this would constitute a challenge to the hypothesis that forebrain vocal structures are unique to vocal learners14.

Methods

Behaviour

The behaviour of all birds was monitored by video taping: only those birds that could be monitored during the entire observation period were captured. Video recordings were used to score number of song bouts produced by the hearing and vocalizing group during the observation period. For the hearing only group, playbacks of digitally recorded conspecific song (three song bouts per min, each 3–4 s long, from a bird of another locale) were presented from a nearby speaker (3–4 ft). To capture the birds, a feeding bottle containing 24% sucrose inside a cage was used. After 25–30 min in one of the behavioural conditions, a string attached to a stick holding the cage door open was pulled and the bird caught on a regular visit to the feeding bottle. The birds were immediately killed by decapitation, and their brains were dissected, placed in cryogenic embedding medium, and frozen in dry ice; sex was confirmed by direct inspection of the gonads.

Gene expression

Serial parasagittal (right hemisphere) and frontal (left hemisphere) frozen sections (10 μm) were cut throughout the entire brain of each bird. One section every 0.1 mm of each brain (~100 sections per brain, totalling 1,200 sections) was processed for ZENK expression by in situ hybridization with a 35S radioactively labelled riboprobe for canary ZENK, followed by emulsion autoradiography12,17. Unhybridized adjacent sections (20 μm) were stained with cresyl violet and used as reference for identification of cytoarchitectonic boundaries (Fig. 2d). Quantification (Fig. 3) was performed by counting silver grains over cells12. Regions where ZENK expression was significantly higher in hearing only compared with silent control animals represent areas activated by hearing conspecific song; regions where ZENK expression was higher in hearing and vocalizing compared with hearing only animals represent areas activated by singing. This strategy reveals all known telencephalic vocal control nuclei in songbirds and parrots, and identified previously undetected ones12,13. No obvious differences were detected between Aphantochroa and Glaucis, and thus their values were grouped (total n = 4 per group).

Acknowledgments

We thank the Museu de Biologia Mello Leitão (MBML) in Espírito Santo, Brazil, S. Mendes and D. Loss for providing a natural space and services that made this project possible. We also thank the MBML and A. Ruschi for permission to partially reproduce hummingbird illustrations by E. Demonte; P. Rousselot, K. S. Leon and A. Ferreira for help with recordings, sonograms and behavioural scoring; P. Delgado for histological assistance; S. Baumwell and L. Moore for help in manuscript preparation; S. Durand, R. Mooney and S. Nowicki for comments on the manuscript; L. Katz and N. Cant for use of microscope equipment; J. Ahlquist for discussions on avian evolution; C. Cunningham for assistance with phylogenetic analysis; and F. Nottebohm for his support. This project was approved by the Instituto Brasileiro do Meio Ambiente e dos Recursos Naturais Renováveis (IBAMA) and Conselho Nacional de Desenvolvimento Cientifico e Tecnológico (CNPq); funding was provided by the Kluge Trust Fund and Duke University start-up funds to E.D.J., an NIDCD grant to C.V.M., and personal funds by E.D.J. and C.V.M. We dedicate this paper to the memory of L. Baptista, a pioneer of vocal communication in hummingbirds.

References

1. Schuchmann K-L. In: Handbook of the birds of the world: barn-owls to hummingbirds. del Hoyo J, Elliott A, Sargatal J, editors. Lynx Ediciones; Barcelona: 1999. pp. 468–680.
2. Ventura DF, Takase E. Ultraviolet color discrimination in the hummingbird. Invest Ophthalmol Vis Sci. 1994;35:2168.
3. Rehkamper G, Schuchmann KL, Schleicher A, Zilles K. Encephalization in hummingbirds (Trochilidae) Brain Behav Evol. 1991;37:85–91. [PubMed]
4. Vielliard J. Catálogo sonográfico dos cantos e piados dos beija-flores do Brasil. Boletim do Museu de Biologia “Mello Leitão” Série Biologia. 1983;58:1–20.
5. Nottebohm F. The origins of vocal learning. Am Nat. 1972;106:116–140.
6. Baptista LF, Schuchmann KL. Song learning in the anna hummingbird (Calypte anna) Ethology. 1990;84:15–26.
7. Nottebohm F, Stokes TM, Leonard CM. Central control of song in the canary, Serinus canarius. J Comp Neurol. 1976;165:457–486. [PubMed]
8. Scharff C, Nottebohm F. A comparative study of the behavioral deficits following lesions of various parts of the zebra finch song system: implications for vocal learning. J Neurosci. 1991;11:2896–2913. [PubMed]
9. Yu AC, Margoliash D. Temporal hierarchical control of singing in birds. Science. 1996;273:1871–1875. [PubMed]
10. Hessler NA, Doupe AJ. Singing-related neural activity in a dorsal forebrain-basal ganglia circuit of adult zebra finches. J Neurosci. 1999;19:10461–10481. [PubMed]
11. Durand SE, Heaton JT, Amateau SK, Brauth SE. Vocal control pathways through the anterior forebrain of a parrot (Melopsittacus undulatus) J Comp Neurol. 1997;377:179–206. [PubMed]
12. Jarvis ED, Scharff C, Grossman MR, Ramos JA, Nottebohm F. For whom the bird sings: context-dependent gene expression. Neuron. 1998;21:775–788. [PubMed]
13. Jarvis ED, Mello CV. Molecular mapping of brain areas involved in parrot vocal communication. J Comp Neurol. 2000;419:1–31. [PMC free article] [PubMed]
14. Brenowitz EA. Comparative approaches to the avian song system. J Neurobiol. 1997;33:517–531. [PubMed]
15. Ruschi A. Hummingbirds of State of Espirito Santo. Rios Editora; São Paulo: 1982.
16. Chaudhuri A. Neural activity mapping with inducible transcription factors. Neuroreport. 1997;8:5–9. [PubMed]
17. Mello CV, Clayton DF. Song-induced ZENK gene expression in auditory pathways of songbird brain and its relation to the song control system. J Neurosci. 1994;14:6652–6666. [PubMed]
18. Jarvis ED, Schwabl H, Ribeiro S, Mello CV. Brain gene regulation by territorial singing behavior in freely ranging songbirds. Neuroreport. 1997;8:2073–2077. [PMC free article] [PubMed]
19. Wild JM, Dongfeng L, Eagleton C. Projections of the dorsomedial nucleus of the intercollicular complex (DM) in relation to respiratory-vocal nuclei in the brainstem of pigeon (Columbia livia) and zebra finch (Taeniopygia guttata) J Comp Neurol. 1997;377:392–413. [PubMed]
20. Nottebohm F, Kelley DB, Paton JA. Connections of vocal control nuclei in the canary telencephalon. J Comp Neurol. 1982;207:344–357. [PubMed]
21. Lidsky TI, Manetto C, Schneider JS. A consideration of sensory factors involved in motor functions of the basal ganglia. Brain Res. 1985;356:133–146. [PubMed]
22. Guinee LH, Payne KB. Rhyme-like repetitions in songs of humpback whales. Ethology. 1988;79:295– 306.
23. Esser KH. Audio-vocal learning in a non-human mammal: the lesser spear-nosed bat Phyllostomus discolor. Neuroreport. 1994;5:1718–1720. [PubMed]
24. Sibley CG, Ahlquist JE. Phylogeny and Classification of Birds: A Study in Molecular Evolution. Yale Univ. Press; New Haven: 1990.
25. Kroodsma DE, Konishi M. A suboscine bird (eastern phoebe, Sayornis phoebe) develops normal song without auditory feedback. Anim Behav. 1991;42:477–487.
26. Feduccia A. Explosive evolution in tertiary birds and mammals. Science. 1995;267:637–638. [PubMed]
27. Koenig C. Vocal patterns as interspecific isolating mechanisms in screech owls of the genus Otus (Aves: Strigidae) of southern South America. Stuttg Beitr Nat kd A Biol. 1994;0(511):1–35.
28. Payne RB. In: Current Ornithology. Johnston RJ, editor. Plenum; New York: 1986. pp. 87–126.
29. Miller EH. In: Ecology and evolution of acoustic communication in birds. Kroodsma DE, Miller EH, editors. Cornell Univ. Press; Ithaca: 1996. pp. 241–257.
30. Ellis DH, Swengel SR, Archibald GW, Kepler CB. A sociogram for the cranes of the world. Behav Processes. 1998;43:125–151.
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