Abstract

Hummingbirds (Trochilidae) are one of the most enigmatic avian groups, and also among the most diverse, with approximately 360 recognized species in 106 genera, of which 43 are monotypic. This fact has generated considerable interest in the evolutionary biology of the hummingbirds, which is reflected in a number of DNA-based studies. However, only a few of them explored chromosomal data. Given this, the present study provides an analysis of the karyotypes of three species of Neotropical hummingbirds, Anthracothorax nigricollis (ANI), Campylopterus largipennis (CLA), and Hylocharis chrysura (HCH), in order to analyze the chromosomal processes associated with the evolution of the Trochilidae. The diploid number of ANI is 2n=80 chromosomes, while CLA and HCH have identical karyotypes, with 2n=78. Chromosome painting with Gallus gallus probes (GGA1-12) shows that the hummingbirds have a karyotype close to the proposed ancestral bird karyotype. Despite this, an informative rearrangement was detected: an in-tandem fusion between GGA7 and GGA9 found in CLA and HCH, but absent in ANI. A comparative analysis with the tree of life of the hummingbirds indicated that this fusion must have arisen following the divergence of a number of hummingbird species.

Keywords:
Karyotype; FISH; bird; chromosome; evolution

Introduction

Hummingbirds (family Trochilidae) form one of the most enigmatic and diverse avian groups, with some 360 recognized species representing 106 genera, of which, 43 are monotypic (Gill and Donsker, 2018Gill F and D Donsker (2018) IOC World Bird List (v 10.1), https://www.worldbirdnames.org/ioc-lists/crossref/
https://www.worldbirdnames.org/ioc-lists... ). These birds are exclusive to the New World, although fossils from the early Oligocene indicate that they may have originated in Europe around 34-28 million years ago, and subsequently dispersed to South America through Beringia (Mayr, 2004Mayr G (2004). Old World fossil record of modern-type Hummingbirds. Science 304:861-864., 2007Mayr G (2007) New specimens of the early Oligocene Old World hummingbird Eurotrochilus inexpectatus. J Ornithol 148:105-111.; Bochenski and Bochenski, 2008Bochenski Z and Bochenski ZM (2008) An Old World hummingbird from the Oligocene: a new fossil from Polish Carpathians. J Ornithol 149:211-216.; Mcguire et al., 2014McGuire JA, Witt CC, Remsen JV, Corl A, Rabosky DL, Altshuler DL and Dudley R (2014) Molecular phylogenetics and the diversification of Hummingbirds. Current Biology 24:910-916.). In the New World, these birds have established intimate evolutionary relationships with a wide range of angiosperms through adaptations for nectar feeding. These adaptations have allowed the hummingbirds to occupy an enormous range of ecological niches within their geographic range, which extends from Alaska and Canada to Tierra del Fuego, in Argentina (Feinsinger and Colwell, 1978Feinsinger P and Colwell RK (1978) Community organization among Neotropical nectar-feeding birds. Am Zool 18:779-795.).

The family Trochilidae has been the subject of a number of DNA studies (Bleiweiss et al., 1997Bleiweiss R, Kirsch JAW and Matheus JC (1997) DNA hybridization evidence for the principal lineages of Hummingbirds (Aves: Trochilidae). Mol Biol Evol 14:325-343.; Bleiweiss, 1998Bleiweiss R (1998) Origin of Hummingbird faunas. Biol J Linn Soc Lond 65:77-97.; Graham et al., 2009Graham CH, Parra JL, Rahbek C and McGuire JA (2009) Phylogenetic structure in tropical Hummingbird communities. Proc Natl Acad Sci USA 106:19673-19678.; Mcguire et al., 2007McGuire JA, Witt CC, Altshuler DL and Remsen JV (2007) Phylogenetic systematics and biogeography of Hummingbirds: Bayesian and maximum likelihood analyses of partitioned data and selection of an appropriate partitioning strategy. Syst Biol 56:837-856., 2008McGuire JA, Witt CC, Remsen JV, Dudley R and Altshuler DL (2008) A higher-level taxonomy for Hummingbirds. J Ornithol 150:155-165., 2014McGuire JA, Witt CC, Remsen JV, Corl A, Rabosky DL, Altshuler DL and Dudley R (2014) Molecular phylogenetics and the diversification of Hummingbirds. Current Biology 24:910-916.). Using a multilocus DNA approach, McGuire et al. (2014McGuire JA, Witt CC, Remsen JV, Corl A, Rabosky DL, Altshuler DL and Dudley R (2014) Molecular phylogenetics and the diversification of Hummingbirds. Current Biology 24:910-916.) concluded that the considerable diversity of trochilid species was the result of a rapid evolutionary radiation, which occurred 22 million years ago. These authors defined nine hummingbird clades: Bees, Brilliants, Coquettes, Emeralds, Hermits, Mangoes, Mountain Gems, Patagona, and Topazes. Trochilids have also been the subject of considerable taxonomic controversy, being originally assigned to order Apodiformes (Apodidae, Hemiprocnidae, and Trochilidae), and were later elevated to their own order, the Trochilifomes, which included only the family Trochilidae (Sibley and Ahlquist, 1990Sibley CG and Ahlquist JE (1990) Phylogeny and Classification of Birds. Yale University Press, New Haven, 976 p.). More recent analyses of the complete bird genome have nevertheless assigned the hummingbirds to the order Caprimulgiformes, which also includes the Apodidae and the nightjars, family Caprimulgidae (Jarvis et al., 2014Jarvis ED, Mirarab S, Aberer AJ, Li B, Houde P, Li C, Ho SYW, Faircloth BC, Nabholz B, Howard JT et al. (2014) Whole-genome analyses resolve early branches in the tree of life of modern birds. Science 346:1320-1331.).

Despite the considerable interest in the evolutionary biology of the hummingbirds, very few cytogenetic data are available, and little is known of the chromosomal complement of these diminutive birds. Calypte anna was the first species to be karyotyped (Beçak et al., 1973Beçak ML, Beçak W, Roberts FL, Shoffner RN and Volpe EP (1973) Rhea americana (Rhea) 2n = 82. In: Beçak ML, Beçak W, Roberts FL, Shoffner RN and Volpe EP (eds) Chromosome atlas: Fish, Amphibians, Reptiles and Birds. Springer, New York, vol. 2, pp 129-207. ), with 2n=74; afterwards, four species - Amazilia lactea, Colibri serrirostris, Lophornis magnificus, and Chlorestes notatus - were analyzed and showed the same diploid number (2n=82) (Christidis, 1990Christidis L (1990) Animal cytogenetics 4: Chordata 3 B: Aves. Gebrüder Borntraeger, Stuttgart, 116 p.).

The study of bird karyotypes and chromosome structure has helped to elucidate important evolutionary questions, in particular through the identification of phylogenetically informative chromosomal signatures (Griffin et al., 2007Griffin DK, Robertson LB, Tempest HG and Skinner BM (2007) The evolution of the avian genome as revealed by comparative molecular cytogenetics. Cytogenet Genome Res 117:64-77.; Kretschmer et al., 2018Kretschmer R, Ferguson-Smith MA and de Oliveira EHC (2018) Karyotype Evolution in birds: From conventional staining to chromosome painting. Genes 9:181., Degrandi et al., 2020aDegrandi TM, Gunski RJ, Garnero ADV, de Oliveira EHC, Kretschmer R, Souza MS, Barcellos AS and Hass I (2020a) The distribution of 45S rDNA sites in bird chromosomes suggests multiple evolutionary histories. Genet Mol Biol 43:e20180331.). The advances obtained by Fluorescence in situ Hybridization (FISH) analyses using whole chromosome probes (WCP) of Gallus gallus 2n=78 (GGA 1-10) have shown that the macrochromosomes are conserved completely among highly divergent lineages from the Paleognathae to the Neognathae groups (Griffin et al., 1999Griffin DK, Haberman F, Masabanda J, O’brien PCM, Bagga M, Sazanov A, Smith J, Burt DW, Ferguson-Smith M and Wienberg J (1999) Micro- and macrochromosome paints generated by flow cytometry and microdissection: tools for mapping the chicken genome. Cytogenet Cell Genet 87:278-281.; de Oliveira et al., 2005de Oliveira EHC, Habermann FA, Lacerda O, Sbalqueiro IJ, Wienberg J and Müller S (2005) Chromosome reshuffling in birds of prey: The karyotype of the world’s largest eagle (Harpy eagle, Harpia harpyja) compared to that of the chicken (Gallus gallus). Chromosoma 114:338-343.; Nishida-Umehara et al., 2007Nishida-Umehara C, Tsuda Y, Ishijima J, Ando J, Fujiwara A, Matsuda Y and Griffin DK (2007) The molecular basis of chromosome orthologies and sex chromosomal differentiation in Palaeognathous birds. Chromosome Res 15:721-734.; Kretschmer et al., 2014Kretschmer R, Gunski RJ, Garnero ADV, Furo IDO, O’Brien PCM, Ferguson-Smith MA, de Oliveira EHC (2014) Molecular cytogenetic characterization of multiple intrachromosomal rearrangements in two representatives of the genus Turdus (Turdidae, Passeriformes). PLoS One 9:e103338.).

Despite the value of cytogenetic data for evolutionary analyses, less than 10% of all birds have been karyotyped (Degrandi et al., 2020bDegrandi TM, Barcelos SA, Costa AL, Garnero ADV, Hass I and Gunski RJ (2020b) Introducing the Bird Chromosome Database: an overview of cytogenetic studies on birds. Cytogenet Genome Res 160:199-205.). This lacuna is even larger for chromosome painting, which has been applied to less than 1% of bird species, and in fact, many bird orders and families, including the Trochilidae, lack any data concerning comparative chromosome painting (Degrandi et al., 2020bDegrandi TM, Barcelos SA, Costa AL, Garnero ADV, Hass I and Gunski RJ (2020b) Introducing the Bird Chromosome Database: an overview of cytogenetic studies on birds. Cytogenet Genome Res 160:199-205.). Given this, the present study investigated the evolutionary processes that have molded the chromosomal characteristics of the trochilids, from the perspective of their karyotype evolution and their phylogenetic relationships with other birds.

Material and Methods

Samples of three hummingbird species - Anthracothorax nigricollis (ANI), Campylopterus largipennis (CLA), and Hylocharis chrysura (HCH) - were collected during field expeditions in Porto Vera Cruz, in the state of Rio Grande do Sul, Brazil, and in Belém, in the Brazilian state of Pará. A single female of each species was captured, according to the norms established by federal specimen collecting license SISBIO number 61047-2 and the Research Ethics Committee (UNIPAMPA 010/2018).

Mitotic chromosomes were obtained from a culture of fibroblasts, following Sasaki et al. (1968Sasaki M, Ikeuchi T and Makino S (1968) A feather pulp culture technique for avian chromosomes, with notes on the chromosomes of the peafowl and the ostrich. Experientia 24:1292-1293.), with modifications. In brief, skin biopsies were collected and cells were dissociated in Colagenase type IV solution (0.45%) at 37 °C for 1 h. Cell suspensions were then added to 25 cm² culture flasks containing 5 mL of DMEM (GIBCO) medium supplemented with 20% fetal bovine serum, 100 u/ml of penicillin, and 100 μg/ml of streptomycin, and incubated at 37 ^oC. Cell growth was monitored daily and, when satisfactory, cell division was blocked by the addition of 100 µl of 0.005% Colchicine directly into the flask, which was then incubated at 37 ºC for 4 h. Subsequently, there followed hypotonic treatment with KCl solution (0.75 M) for 20 minutes, and fixation by three washes with methanol and acetic acid (3:1).

For each species, the diploid number was established by the analysis of 40 metaphases stained with Giemsa under an optical microscope, with a 100 x lens. The complete karyotype of each species was organized and the chromosome morphology classes were determined using the centromeric index (CI), following Guerra (1986Guerra MS (1986) Reviewing the chromosome nomenclature of Levan et al. Rev Bras Genet 9:741-743.).

Whole chromosome probes of G. gallus (GGA), covering the first 12 pairs (Cambridge Resource Center for Comparative Genomics, Cambridge, UK) were used in comparative chromosome painting. The probes were labeled by DOP-PCR, with biotin or digoxigenin, and detected using streptavidin-CY3 and/or anti-digoxygenin-fluorescein (Telenius et al., 1992Telenius H, Ponder BAJ, Tunnacliffe A, Pelmear AH, Carter NP, Ferguson-Smith MA, Nordenskjöld M, Pfragner R and Ponder BA (1992) Cytogenetic analysis by chromosome painting using DOP-PCR amplified flow-sorted chromosomes. Genes Chromosomes Cancer 4:257-263.). FISH experiments followed de Oliveira et al. (2010de Oliveira EHC, Tagliarini MM, Rissino JD, Pieczarka JC, Nagamachi CY, O’Brien PCM and Ferguson-Smith MA (2010) Reciprocal chromosome painting between white hawk (Leucopternis albicollis) and chicken reveals extensive fusions and fissions during karyotype evolution of Accipitridae (Aves, Falconiformes). Chromosome Res 18:349-355.). The results of the FISH-WCP procedure were analyzed and photographed under a Zeiss microscope with a 63 x lens and Axiovision 4.8 software (Zeiss, Germany).

Results

The diploid number of A. nigricollis is 2n=80 chromosomes (Figure 1A). The macrochromosomes (1, 2, 6, 7, 8, 9, Z and W) are submetacentric, while 5 is metacentric, 3 and 4 are acrocentric, and chromosomes 10 through 39 are all telocentric, forming a gradual decline in the length of the chromosomes. Identical karyotypes of 2n=78 chromosomes were observed in C. largipennis (Figure 1B) and H. chrysura (Figure 1C). In both cases, macrochromosomes 1, 2, 4, 6, 7, 8, 9, and Z, are submetacentric, 3 is metacentric, 5 is acrocentric, and chromosomes 10 through 38, plus the W are all telocentric.

Figure 1 -
Karyotypes of the three hummingbird species (family Trochilidae) analyzed in the present study. (A) Anthracothorax nigricollis 2n=80, (B) Campylopterus largipennis 2n=78, and (C) Hylocharis chrysura 2n=78.

The comparative chromosome painting indicated that the syntenies corresponding to GGA1-GGA12 were conserved in A. nigricollis, with the exception of GGA4, which corresponded to two distinct pairs (Figure 2 A-H). Similar results were found in C. largipennis and H. chrysura, except for pairs GGA7 and GGA9, which were fused in a single chromosome pair, corresponding to chromosomes 4q (GGA7) and 4p (GGA9) in the two species (Figure 2 I-L). The chromosomal homology between the three species was represented in ideograms and is shown in Figure 3.

Figure 2 -
Representative metaphases showing Fluorescence in situ Hybridization using Gallus gallus (GGA 1-GGA12) chromosomal probes in Anthracothorax nigricollis, ANI (metaphases A-H), and the GGA7 and GGA9 probes in Campylopterus largipennis, CLA (metaphases I and J) and Hylocharis chrysura, HCH (metaphases K and L).

Figure 3 -
Comparative ideograms showing the homologies among the macrochromosomes of the hummingbirds Anthracothorax nigricollis (A), Campylopterus largipennis (B), and Hylocharis chrysura (C). This scheme was obtained by Fluorescence in situ Hybridization using the Gallus gallus chromosomal probes (GGA 1-GGA12).

Discussion

Hummingbirds show karyotypes similar to those found in the majority of birds, with diploid numbers of around 2n=80, together with the preservation of the syntenies corresponding to G. gallus (GGA) macrochromosomes. This uniformity of bird karyotypes has been known since the first cytogenetic studies in these animals, which reported only basic chromosome numbers and the structural characteristics of the karyotype (Ohno et al., 1964Ohno S, Stenius C, Christian LC, Beçak W and Beçak ML (1964) Chromosoma l uniformity in the avian subclass Carinatae. Chromosoma 15:280-288.; Garnero et al., 2006Garnero ADV, Ledesma MA and Gunski RJ (2006) Alta homeologia cariotípica na family Tinamidae (Aves: Tinamiformes). Rev Bras Ornitol 14:53-58.). These observations were confirmed subsequently by chromosome painting, which supports that the putative ancestral karyotype of the birds (PAK) had 2n = 80 chromosomes (Griffin et al., 2007Griffin DK, Robertson LB, Tempest HG and Skinner BM (2007) The evolution of the avian genome as revealed by comparative molecular cytogenetics. Cytogenet Genome Res 117:64-77.).

In this work, although it included a small number of species in the analysis, the homology maps (Figure 3) compared to G. gallus reveal that A. nigricollis, C. largipennis and H. chrysura show highly similar karyotypes (Figure 1), which preserve most of the syntenic groups represented by the G. gallus macrochromosome probes (GGA1, GGA2, GGA3, GGA5, GGA6, GGA8, GGA10, GGA11, and GGA12) (Figures 2 and 3). However, it was possible to observe that the karyotypes of C. largipennis and H. chrysura correspond to one another in chromosome number and morphology, and differ from the karyotype of A. nigricollis, by a centric fusion between chromosomes homologous to GGA7 and GGA9.

These findings are consistent with the most recent phylogeny of the hummingbirds, in which A. nigricollis is included in a separate clade, while the other two species are sister groups. Hence, A. nigricollis was assigned to the Mangoes clade, one of the first that diverged 20 million years ago (Ma), while C. largipennis and H. chrysura belong to the Emeralds clade, which arose about 8 Ma later (McGuire et al., 2014McGuire JA, Witt CC, Remsen JV, Corl A, Rabosky DL, Altshuler DL and Dudley R (2014) Molecular phylogenetics and the diversification of Hummingbirds. Current Biology 24:910-916.). Hence, A. nigricollis has a more conserved karyotype in relation to PAK suggesting that the fusion of GGA7 and GGA9 emerged after the divergence of these clades. In addition, this chromosomal rearrangement has not previously been observed in any bird group, according to data available in the Bird Chromosome Database (Degrandi et al., 2020bDegrandi TM, Barcelos SA, Costa AL, Garnero ADV, Hass I and Gunski RJ (2020b) Introducing the Bird Chromosome Database: an overview of cytogenetic studies on birds. Cytogenet Genome Res 160:199-205.).

Although only eight species of hummingbirds have been karyotyped so far (three from this present study and five previously published), conventional chromosomal data is available also for six species of swifts, which belong to the family Apodidae, considered sister-group of Throchilidae: Apus apus: 2n=78, Apus affinis affinis: 2n=70, Apus pacificus: 2n=62, Hirundapus caudacutus: 2n= 64, Streptoprocne zonaris: 2n= 66, and Streptoprocne biscutata: 2n= 64 (XiaoZhuang and Qingwei 1989Xiaozhuang B and Qingwei L (1989) Studies on the karyotypes of birds V. The 20 species of climber birds (Aves). Zool Res 10:309-317.; Yadav et al., 1995Yadav JS, Arora RB and Yadav AS (1995) Karyotypes of two species of Indian birds and localization of nucleolus organizer regions. Cytobios 82:159-169.; Ribeiro et al., 2003Ribeiro J, Torres RA, Adam ML and Cornélio DA (2003) Cytotaxonomic diagnoses of two Neotropical swift species: Streptoprocne biscutata and Streptoprocne zonaris (Aves: Apodidae). Zootaxa 224:1-7.; Malinovskaya et al., 2018Malinovskaya L, Shnaider E, Borodin P and Torgasheva A (2018) Karyotypes and recombination patterns of the Common Swift (Apus apus Linnaeus, 1758) and Eurasian Hobby (Falco subbuteo Linnaeus, 1758). Avian Res 9:2018.). Taking into account that hummingbirds and swifts share a common ancestor that must have existed 42 Ma (McGuire et al., 2014McGuire JA, Witt CC, Remsen JV, Corl A, Rabosky DL, Altshuler DL and Dudley R (2014) Molecular phylogenetics and the diversification of Hummingbirds. Current Biology 24:910-916.), a parsimonious scenario would point to an ancestor having a karyotype similar to the PAK. Additionally, despite being limited, these karyotypical data indicate that, while the hummingbirds have followed an evolutionary trajectory, maintaining a karyotype structure similar to the PAK (diploid numbers of 74-82 chromosomes), the chromosome complement of swifts have experienced a series of reductions, with diploid numbers decreasing to 62-78 chromosomes. However, more species need to be studied to determine which chromosomal events are acting on these species and to confirm whether this is an evolutionary trend or whether it is influenced by the low number of species that have been analyzed.

Conclusions

The lack of cytogenetic data for hummingbirds is a major challenge for understanding karyotype evolution in this unique group of birds. The small number of species that have been karyotyped limits the scope of the analysis of chromosomal variation in this group. However, in the present study, chromosome painting demonstrated the occurrence of a fusion between homologues of GGA7 and GGA9 shared by C. largipennis and H. chrysura, reinforcing the molecular proposal that places these two species in the same clade, while A. nigricollis is found in a different clade. An important next step is to increase the number of species studied, including other clades of Trochilids, and also to use other chromosome painting probes from other species with more derives karyotypes, such as Leucopternis albicollis.

Acknowledgments

We are grateful to the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for supporting this research and the PDJ scholarship conceded to TMD. We would also like to thank all our colleagues from the Grupo de Pesquisa Diversidade Genética Animal from Universidade Federal do Pampa (UNIPAMPA), to Laboratório Cultura de Tecidos e Citogenética (SAMAM) from Instituto Evandro Chagas (IEC).

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