Karyotypic characterization of Ramphastidae (Piciformes, Aves)

Márcio Siqueira Castro1, Shirlei M. Recco-Pimentel1 and Guaracy Tadeu Rocha2

1Departamento de Biologia Celular, Instituto de Biologia, Universidade Estadual de Campinas, Campinas,

SP, Brazil.
2Departamento de Genética, Instituto de Biociências, Universidade Estadual Paulista, Botucatu, SP, Brazil.

Abstract

The karyotypes of nine species of the family Ramphastidae were determined and compared with that of the toco
toucan (Ramphastos toco), the only ramphastid karyotype so far reported in the literature. Differences in the
morphology of the largest chromosomes allowed to identify three karyotype groups. The first group included the
species R. toco, Baillonius bailloni, Pteroglossus castanotis, P. aracari and Selenidera maculirostris, in which only
the first pair of chromosomes was metacentric. The second group included four Ramphastos species (R. dicolorus,
R. ariel, R. vitellinus, R. tucanus cuvieri) with two pairs of metacentric macrochromosomes (the first and the seventh).
The third group was represented by a single species, A. laminirostris, in which all the autosomal chromosomes were
telocentric. All of the species had subtelocentric Z chromosomes, similar in size to homologues of the first pair. Sex
chromosome W was a small chromosome. The chromosome number ranged from 2n = 62 in P. aracari to 114 in R.
toco. The cytotaxonomic relationships among toucan species are discussed, based on chromosome analysis.

Key words: karyotypes, Rhamphastidae, toucans.

Received: March 5, 2002; accepted: May 27, 2002.

Introduction

The family Ramphastidae (Piciformes - Aves) is

composed of toucans, the most typical neotropical birds

(Haffer, 1974), endowed with extraordinary characteristics

and exuberant colors (Sick, 1997). Fifty-five species were

described in this family, 27 of which are found in Brazil.

The only one whose karyotype had been described so far is

Ramphastos toco. The family Ramphastidae comprises two

subfamilies: Capitonidae, with three genera and 14 species,

and Ramphastinae, with six genera and 41 species (Sibley,

1996).

The chromosome number of R. toco is 2n = 106

(Takagi and Sasaki, 1980). Sex chromosome Z is subtelo-

centric and equivalent in size to the first chromosome pair,

which is metacentric. The remaining chromosomes are

telocentric. Sex chromosome W is a microchromosome,

not identified by these authors. Nogueira and Goldshimidt

(1994) analyzed six specimens of R. toco, and reported

2n = 80 chromosomes. Cytogenetic data are important for

the characterization of each species, and can help to estab-

lish their karyotype evolution. In this work, we examined

the karyotypes of ten Ramphastidae species, in order to

assess chromosomal evolution and cytotaxonomic relation-

ships in this family.

Materials and Methods

Ten Ramphastidae species of the subfamily

Ramphastinae (Piciformes, Aves) were cytogenetically an-

alyzed: Ramphastos toco Mueller, 1776 (25 males, 26 fe-

males), R. dicolorus Linnaeus, 1776 (9 males, 11 females),

R. ariel Vigors, 1826 (2 males, 7 females), R. vitellinus

Reiser, 1905 (2 females), R. tucanus cuvieri Wagler, 1827

(1 male), Baillonius bailloni Vieillot, 1819 (2 males, 5 fe-

males), Pteroglossus castanotis Gould, 1834 (1 male, 3 fe-

males), P. aracari Linnaeus, 1758 (2 males), Selenidera

maculirostris Lichtenstein, 1823 (4 males, 3 females), and

Andigena laminirostris Gould, 1850 (2 males). All speci-

mens showed adult characteristics, and were maintained by

ecological parks, zoological gardens or with private bird

breeders in the State of São Paulo.

The chromosome preparations were obtained using

the dermal pulp tissue of growing feathers (approximately

15-30 days growth). This tissue was macerated and incu-

bated in culture medium (RPMI) for 30 min. with 0.016%

colchicine, at room temperature. The cell suspension was

then centrifuged at 1000 g for 10 min, and the pellet resus-

pended in 10 mL of 0.075 M KCl (hypotonic solution) for

30 min, after which the cells were fixed in a 3:1 (v/v)

Genetics and Molecular Biology, 25, 2, 147-150 (2002)

Copyright by the Brazilian Society of Genetics. Printed in Brazil

www.sbg.org.br

Send correspondence to Shirlei M. Recco Pimentel. Departamento
de Biologia Celular, IB, UNICAMP, 13084-971 Campinas, SP,
Brazil. E-mail: shirlei@unicamp.br.



methanol:acetic acid solution. Following two rinses with

fixative, the suspension was spotted onto slides. These

steps were done in the field. The slides were subsequently

stained with 10% Giemsa solution (in phosphate buffer, pH

6.8), and examined at a 100x magnification.

The sex chromosomes were determined using the best

metaphase plates, and the maximum chromosome number

found was considered as being the diploid number of the re-

spective species. The description of chromosome morphol-

ogy was based on that of Levan et al. (1964).

Results

In this study on toucan species, sex was determined

by cytogenetic analysis. The female specimens of the ten

species had sex chromosomes (ZW) that differed in size

and/or morphology. Based on the morphology of the largest

chromosomes, three groups of species were identified in

this family.

Group I

Ramphastos toco, Baillonius bailloni, Pteroglossus
castanotis, P. aracari and Selenidera maculirostris

All 51 specimens of R. toco had the same karyotype

as described by Takagi and Sasaki (1980). The chromo-

somes of the first pair were the only metacentric ones, their

size being twice the size of the second pair (Figure 1: A1

and A2 - male; A3 and A4 - female). The Z chromosome was

subtelocentric and was similar in size to the autosomes of

the first pair. The remaining chromosomes were telocentric

and progressively decreasing in size. It was not possible to

identify the homologues, nor the w chromosome. This spe-

cies had a diploid number of 114 chromosomes.

The same karyotype pattern was found in Baillonius

bailloni (Figure 1F), Pteroglossus castanotis (Figure 1G),

P. aracari (Figure 1H), and Selenidera maculirostris (Fig-

ure 21I), but they differed in their diploid chromosome

numbers (2n = 92; 2n = 86; 2n = 62; and 2n = 98 , respec-

tively).

Group II

Ramphastos dicolorus, R. ariel, R. vitellinus and R.
tucanus cuvieri

The analysis of metaphases from these species

showed chromosome groups similar to those observed in R.

toco. A pair of large metacentric chromosomes was identi-

fied as the first pair. The Z chromosome was subtelocentric

and equivalent in size to the first pair. Among the telo-

centric chromosomes, there was one metacentric pair that

corresponded in size to the seventh pair of the previous

group. The W chromosome was impossible to identify. The

diploid chromosome numbers were: 2n = 98 for R.

dicolorus (Figure 1B), 2n = 106 for R. ariel (Figure 1C),

2n = 102 for R. vitellinus (Figure 1D), and 2n = 88 for R.

tucanus cuvieri (Figure 1E).

Group III

Andigena laminirostris

The only species included in this group, Andigena

laminirostris (Figure 1J), does not inhabit Brazil, but oc-

curs in Ecuador (Gould, 1992). Two males of this species

were included in this analysis, to compare their karyotype

with that of the various Brazilian species. A. laminirostris

had 2n = 108 chromosomes, one of them being an unusual

chromosome that corresponded in size and morphology to

the Z chromosome described above. The second chromo-

some pair was 2/3 the size of the first pair. The second pair

and all the other chromosomes were telocentric and gradu-

ally decreasing in size.

The two specimens of A. laminirostris were consid-

ered to be males, because no heteromorphic chromosome

pair, corresponding to ZW, was found. They were both sub-

sequently sexed as males by DNA analysis. The unusually

large pair of chromosomes found in A. laminirostris was

similar in size and morphology to the Z sex chromosomes

of the other Ramphastidae species , and was therefore con-

sidered to represent the Z chromosomes. This will only be

confirmed after karyotype analysis of females and identifi-

cation of the ZW sex chromosome pair.

Discussion

Based on our chromosome analysis, we worked out

the following hypothesis: R. toco may descend from a more

ancient branch, and the metacentric seventh pair may be the

result of a single translocation that occurred late in the ori-

gin of the R. toco branch, but early enough to be present in

the ancestry of R. dicolorus, R. tucanus, R. vitellinus and R.

ariel.

The metacentric chromosomes identified as the sev-

enth pair were good marker chromosomes, because of their

similar size and morphology in the various Ramphastos

species, except for R. toco. Independent translocations in-

volving different chromosomes are unusual events. The

presence of these chromosomes in different species sug-

gests that they were inherited via a common ancestor. This

interpretation is even more consistent when the diploid

chromosome number of different species is considered.

According to Takagi and Sasaki (1980), the ancestors

of many orders of birds had karyotypes with many chromo-

somes, all of them telocentric, except for the first pair. This

same ancestral pattern was reported by Beltermann and De

Boer (1984), after their analysis of the karyotypes of vari-

ous species from 15 orders, and by Rodionov (1997), after

examining the published karyotypes of almost 800 avian

species. R. toco and A. laminirostris have probably main-

148 Castro et al.



tained the ancestral karyotype pattern of these genera from

800,000 years ago.

During the differentiation of more recent branches,

in-tandem translocations may have reduced the diploid

chromosome numbers of current species. This would

explain why R. tucanus, a representative of a more recent

lineage than R. toco, had the lowest chromosome number

(2n = 88). Centric fusion after differentiation of the R. toco

Karyotypes of Ramphastidae species 149

Figure 1 - A1. Mitotic metaphase of R. toco (male), A2. karyotype of R. toco (male), A3. Mitotic metaphase of R. toco (female), A4. Karyotype of R. toco

(female). Partial karyotypes of B. Ramphastos dicolorus, C. R. ariel, D. R. vitellinus, E. R. tucanus cuvieri, F. Baillonius bailloni, G. Pteroglossus

castanotis, H. P. aracari, I. Selenidera maculirostris and J. Andigena laminirostris.



lineage would have given rise to the metacentric seventh

chromosome pair of other Ramphastos species.

In-tandem translocations may have occurred after the

separation of R. toco and R. tucanus, and were probably

more recently intensified in R. tucanus (2n = 88), but less

intensive in R. dicolorus (2n = 98), R. ariel (2n = 106) and

R. vitellinus (2n = 102). In Selenidera and Baillonius, 2n is

98 and 92, respectively, whereas the diploid number in P.

aracari is 2n = 62, and in P. castanotis, 2n = 86. In-tandem

translocations could account for this reduction of the chro-

mosome number in Pteroglossus species, although, as

pointed out by Rodionov (1997), the rates of karyotypical

change differ among phylogenetic branches of birds.

In nine of the species studied here, the first autosome

pair was metacentric and was double the size of the second

pair. In A. laminirostris, all the autosomes were telocentric

and gradually decreasing in size. In the karyotypical pat-

terns proposed by Takagi and Sasaki (1980) and

Beltermann and De Boer (1984) for the ancestors of many

avian orders, the first and second pairs are metacentric and

submetacentric. According to Takagi and Sasaki (1980),

centric fission in one of these pairs would culminate in the

karyotype observed in R. toco. According to these authors,

in certain species of some orders (Strigiformes, Gruifor-

mes), centric fission has occurred in both chromosome

pairs, resulting in telocentric chromosomes. Such a series

of events (centric fission of metacentric chromosomes)

could explain the karyotype of A. laminirostris. However,

as pointed out by Beltermann and De Boer (1984), the con-

firmation of this hypothesis would require chromosome

banding analysis, to verify the homology among the largest

chromosomes of different species, families and orders.

All species examined here had subtelocentric Z chro-

mosomes, which were similar in size to the first pair. The

sex chromosome W was a microchromosome not observed

in females, and only C-banding patterns could identify this

small chromosome in these species. This pattern was not

observed in other families of the order Piciformes. Shields

et al. (1982) reported that, in the family Picidae, the Z chro-

mosome may be subtelocentric or metacentric, whereas

chromosome W can be small and telocentric (Dendrocopus

major) or submetacentric, or one of the largest in the karyo-

type (D. minor). Similar variation in sex chromosome size

and morphology occurs in Picoides, Colaptes and

Sphirapicus. Two species of the family Megalaimidae,

Megalaima haemacephala (Shields et al., 1982) and M.

zeylanica (Kaul and Ansari, 1981), have Z chromosomes

which correspond to those seen in Ramphastidae. In con-

trast, the W chromosome is small and telocentric in M.

haemacephala, and larger than the second pair of auto-

somes in M. zeylanica. Among the species of Ramphas-

tidae examined here, the size and morphology of the sex

chromosomes was less variable.

A comparative chromosome analysis of a great num-

ber of Ramphastidae species and of other families of the

same order would improve the interpretation of chromo-

somal evolution in this group. Combining cytogenetic data

with biogeography, phenotypic characteristics, DNA hy-

bridization, and other approaches should provide a better

understanding of the phylogenetic relationships in the

avian family Ramphastidae.

Acknowledgments

The authors thank the curators of: Parques Ecológicos

(Ecologic Parks) of Paulínia, Americana, Leme, Boituva,

Ibirapuera and Tietê; Parques Zoológicos (Zoologic Gar-

dens) of Bauru, Sorocaba and São Paulo; “Bosque dos

Jequitibás” of Campinas; “Fazenda Crisciumal” farm of

Leme; and “Criadouros Conservacionistas” (Conservative

Breeders) of Souzas, Itupeva and Pirassununga, for putting

their specimens at our disposal, and Dr. Edmundo J. De

Lucca (Dept. of Genetics, Institute of Biology, UNESP,

Botucatu, Brazil) for critical reading of the manuscript.

This work was supported by CAPES and FAPESP.

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