Comparative cytogenetic analysis between Lonchorhina aurita and Trachops cirrhosus (Chiroptera, Phyllostomidae)

Barros, Helen Maria Duarte do Rêgo; Sotero-Caio, Cibele Gomes de; Santos, Neide; Souza, Maria José de

doi:10.1590/S1415-47572009005000095

Abstract

Phyllostomidae comprises the most diverse family of neotropical bats, its wide range of morphological features leading to uncertainty regarding phylogenetic relationships. Seeing that cytogenetics is one of the fields capable of providing support for currently adopted classifications through the use of several markers, a comparative analysis between two Phyllostomidae species was undertaken in the present study, with a view to supplying datasets for the further establishment of Phyllostomidae evolutionary relationships. Karyotypes of Lonchorhina aurita (2n = 32; FN = 60) and Trachops cirrhosus (2n = 30; FN = 56) were analyzed by G- and C-banding, silver nitrate staining (Ag-NOR) and base-specific fluorochromes. Chromosomal data obtained for both species are in agreement with those previously described, except for X chromosome morphology in T. cirrhosus, hence indicating chromosomal geographical variation in this species. A comparison of G-banding permitted the identification of homeologies in nearly all the chromosomes. Furthermore, C-banding and Ag-NOR patterns were comparable to what has already been observed in the family. In both species CMA3/DA/DAPI staining revealed an R-banding-like pattern with CMA3, whereas DAPI showed uniform staining in all the chromosomes. Fluorochrome staining patterns for pericentromeric constitutive heterochromatin (CH) regions, as well as for nucleolar organizing regions (NORs), indicated heterogeneity regarding these sequences among Phyllostomidae species.

bats; chromosome banding; fluorochromes; NOR

ANIMAL GENETICS

RESEARCH ARTICLE

Comparative cytogenetic analysis between Lonchorhina aurita and Trachops cirrhosus (Chiroptera, Phyllostomidae)

Helen Maria Duarte do Rêgo Barros; Cibele Gomes de Sotero-Caio; Neide Santos; Maria José de Souza

Laboratório de Genética e Citogenética Animal, Departamento de Genética, Centro de Ciências Biológicas, Universidade Federal de Pernambuco, Recife, PE, Brazil

^{Send correspondence to} Send Correspondence to: Maria José de Souza Laboratório de Genética e Citogenética Animal Departamento de Genética, Centro de Ciências Biológicas Universidade Federal de Pernambuco Av. Prof. Moraes Rego SN, Cidade Universitária 50732-970 Recife, PE, Brazil E-mail: mjslopes.ufpe@yahoo.com.br

ABSTRACT

Phyllostomidae comprises the most diverse family of neotropical bats, its wide range of morphological features leading to uncertainty regarding phylogenetic relationships. Seeing that cytogenetics is one of the fields capable of providing support for currently adopted classifications through the use of several markers, a comparative analysis between two Phyllostomidae species was undertaken in the present study, with a view to supplying datasets for the further establishment of Phyllostomidae evolutionary relationships. Karyotypes of Lonchorhina aurita (2n = 32; FN = 60) and Trachops cirrhosus (2n = 30; FN = 56) were analyzed by G- and C-banding, silver nitrate staining (Ag-NOR) and base-specific fluorochromes. Chromosomal data obtained for both species are in agreement with those previously described, except for X chromosome morphology in T. cirrhosus, hence indicating chromosomal geographical variation in this species. A comparison of G-banding permitted the identification of homeologies in nearly all the chromosomes. Furthermore, C-banding and Ag-NOR patterns were comparable to what has already been observed in the family. In both species CMA₃/DA/DAPI staining revealed an R-banding-like pattern with CMA₃, whereas DAPI showed uniform staining in all the chromosomes. Fluorochrome staining patterns for pericentromeric constitutive heterochromatin (CH) regions, as well as for nucleolar organizing regions (NORs), indicated heterogeneity regarding these sequences among Phyllostomidae species.

Key words: bats, chromosome banding, fluorochromes, NOR.

Introduction

The family Phyllostomidae, which comprises the New World leaf-nosed bats, is considered the third largest of the order Chiroptera. This family is the most diverse group among Neotropical bats, with approximately 56 genera and 141 species (Baker et al., 2003; Simmons, 2005). Phyllostomidae bats exhibit wide variation in morphological features, and are adapted to a extensive range of ecological niches, with dietary specialization which includes fruit, nectar, pollen, insects, vertebrates and blood. This great diversity has been problematic for systematics, and concurs to hindering efforts to reconstruct the phylogenetic history of the family (Wetterer et al., 2000; Jones, 2002; Baker et al., 2003).

The subfamily Phyllostominae is one of the groups which has been questioned by researchers, but without consensus. Several authors agree that this subfamily is not a monophyletic group, although only recently has a new proposal been made as to its subdivision. Baker et al. (2003), on analyzing mtDNA sequence data, grouped this information together with previous phylogenies based on the RAG2 gene (Baker et al., 2000), morphology (Wetterer et al., 2000) and karyotypes (Baker et al., 1973, 1989; Baker and Bass, 1979), to suggest a classification with 56 genera in 11 subfamilies for the Phyllostomidae. In this classification, members were distributed among five subfamilies: Macrotinae, Micronycterinae, Lonchorhininae, Phyllostominae and Glyphonycterinae. Lonchorhininae, which is comprised of a single genus (Lonchorhina), diverged before the radiation of Phyllostominae and nectarivorous bats, appearing as a basal branch relative to Phyllostominae.

Cytogenetic studies constitute an important approach for understanding phylogenetic relationships among bats. By comparing banding patterns and the localization and constitution of different markers, it has been possible to characterize several taxa and develop hypotheses on evolutionary relationships, as well as models of chromosomal evolution (Baker et al., 1989; Baker, 2006).

Thus, in this work, chromosomal features of Lonchorhina aurita (Lonchorhininae) and Trachops cirrhosus (Phyllostominae) were studied by conventional analysis, G- and C-banding, staining with silver nitrate and base-specific fluorochromes (CMA₃ and DAPI) in order to establish mutual cytogenetic differences. These data will be helpful in understanding the chromosome structure and evolution of the family Phyllostomidae, as well as systematic aspects and phylogenetic relationships among members.

Materials and Methods

Chromosome analyses were carried out on 12 specimens (seven males and five females) of Lonchorhina aurita (Tomes, 1863) and eight specimens (four males and four females) of Trachops cirrhosus (Spix, 1823). L. aurita individuals were captured in the locality of Toritama (8° 0' 24" S, 36° 3' 24" W) and T. cirrhosus specimens were captured in the Reserva Biológica de Saltinho, Rio Formoso (8° 39' 49" S, 35° 9' 31" W), both in the state of Pernambuco, northeastern Brazil. Metaphase chromosome preparations were obtained from bone-marrow cells according to conventional procedures.

Silver staining and G- and C-banding procedures were undertaken through routine cytogenetic techniques, according to Howell and Black (1980), Seabright (1971) and Sumner (1972), respectively. Triple staining CMA₃/DA/DAPI was carried out according to Schweizer (1980) with various modifications (Santos and Souza, 1998a). For sequential staining (AgNO₃/CMA₃/DAPI), the slides stained with silver nitrate were distained after photographing (Dos Santos Guerra, 1991) and re-stained with CMA₃/DA/DAPI.

Photomicrographs were taken by means of a Leica DMLB photomicroscope for conventional, silver staining and fluorescence staining. G- and C-banding were captured by a CytoVision image capture system.

Results

The karyotype of L. aurita presented the diploid number 2n = 32,XX;XY and the fundamental number FN = 60, and included metacentric (1, 4, 6, 8, 9, 11, 13 and 15), submetacentric (2, 3, 5 and 7) and subtelocentric (10, 12 and 14) chromosomes. The X chromosome was medium-sized submetacentric and the Y minute. In the T. cirrhosus karyotype, the diploid number was 2n = 30, XX;XY and FN = 56, and was comprised of metacentric (1, 6, 8, 10, 13 and 14), submetacentric (2, 3, 4 and 5) and subtelocentric (7, 9, 11 and 12) chromosomes. The X and Y chromosomes were acrocentric.

The G-banding pattern disclosed the precise identification of all chromosome pairs. Comparative banding analysis inferred homeologies between the two species in pairs 1 to 3 and 5 to 8 (Figures 1a and 1b). Furthermore, in L. aurita the chromosome pairs 9, 10, 11 and 15 appeared to correspond to pairs 13, 12, 10 and 14 in T. cirrhosus, respectively. C-banding revealed constitutive heterochromatin (CH) in the pericentromeric regions of all the autosomes and the X chromosome, whereas the Y chromosome was almost completely heterochromatic in both species (Figures 2a and 2b).

Triple staining CMA₃/DA/DAPI in these species revealed an R-banding-like pattern with the CMA₃ dye (GC-rich regions) (Figures 3a and 3c), and uniform staining of all chromosomes with DAPI (Figures 3b and 3d). In addition, CMA₃-positive blocks were observed in the pericentromeric region of some chromosomes, thereby indicating the GC-richness of CH.

Staining with silver nitrate (AgNO₃) revealed a single pair of NORs located at the secondary constriction in both species: in the short arm of pair 13 in L. aurita (Figure 4a) and in the long arm of pair 11 in T. cirrhosus (Figure 4c). The signals resulting from sequential staining AgNO₃/CMA₃/DAPI, revealed CMA₃ positive NORs in L. aurita (Fig. 4b), whereas these regions were CMA₃ neutral in T. cirrhosus (Figure 4d).

Discussion

Our data regarding diploid number, chromosome morphology and sex determination system obtained for both L. aurita and T. cirrhosus are in agreement with those previously described, except for the X chromosome in T. cirrhosus. We observed an acrocentric X in specimens from Pernambuco, Brazil, although this has been described as subtelocentric in individuals from Mexico and Trinidad (Baker, 1967; Hsu et al. 1968; Baker and Hsu, 1970).

The majority of Phyllostomidae species have a biarmed X chromosome (metacentric, submetacentric or subtelocentric) this condition being considered basal for the family (Rodrigues et al., 2003). Acrocentric morphology of the X chromosome has been described in only three other Phyllostomidae species, Micronycteris hirsuta (Micronycterinae), Mesophylla macconnelli and Vampyressa pusilla (Stenodermatinae) (Baker and Hsu, 1970; Baker et al., 1973; Gardner, 1977). However, despite having encountered the same morphology, we suggest that the acrocentric morphology of the X chromosome in T. cirrhosus (Phyllostominae) is an apomorphic character that has evolved independent of the condition observed in the three aforementioned species, as they are distantly related. The most probable event involved in the morphological change of the X chromosome in T. cirrhosus could be pericentric inversion occurring in an ancestral metacentric or submetacentric X.

The CH in Phyllostomidae is generally located in the pericentromeric regions of chromosomes (Varella-Garcia et al., 1989), as observed in L. aurita and T. cirrhosus. However, additional CH blocks have been found in interstitial and telomeric regions in several species, notably Carollia perspicillata, Choeroniscus minor, Glossophaga soricina, Artibeus lituratus, A. planirostris, A. jamaicencis, A. cinereus, Sturnira lilium, Platyrrhinus lineatus, Uroderma magnirostrum, U. bilobatum, Diaemus youngi, Desmodus rotundus and Diphylla ecaudata (Varella-Garcia et al., 1989; Souza and Araújo, 1990; Santos and Souza, 1998a, 1998b; Neves et al., 2001; Santos et al., 2001; Silva et al., 2005). The Y chromosomes of L. aurita and T. cirrhosus were almost entirely heterochromatic, which is a common pattern in Phyllostomidae species (Varella-Garcia et al., 1989; Souza and Araújo, 1990).

The occurrence of one pair of NORs located in secondary constrictions of chromosomes in L. aurita and T. cirrhosus seems to be an ancestral condition among phyllostomid bats (Morielle and Varella-Garcia, 1988; Santos et al., 2002). NOR staining by GC-specific fluorochromes, as observed in L. aurita, has also been discerned in Artibeus lituratus, A. jamaicencis, Desmodus rotundus and Diphylla ecaudata, although these regions were CMA₃ neutral in Carollia perspicillata, Phyllostomus discolor and T. cirrhosus. This indicates heterogeneity regarding the base composition of intergenic regions related to NORs among species of the family Phyllostomidae (Santos and Souza, 1998a, 1998b; Santos et al., 2001.

In L. aurita and T. cirrhosus karyotypes, CMA₃ staining resulted in a pattern similar to R-banding, although, a G-band-like pattern was not observed with DAPI staining. In both species, the pericentromeric CH regions of some chromosomes presented positive staining with CMA₃ (CMA₃⁺). In certain species, such as Carollia perspicillata, the presence of euchromatic bands (R- and G-bands) and heterochromatin heterogeneity (CMA₃-positive, DAPI-positive and CMA₃/DAPI- neutral) after CMA₃/DA/DAPI staining has been observed (Santos and Souza, 1998a). On the other hand, the CH in three species of Artibeus (A. lituratus, A. jamaicencis and A. cinereus), as well as Desmodus rotundus and Diphylla ecaudata, indicated no AT- or CG- richness after staining with these dyes (Santos and Souza, 1998b; Santos et al., 2001). Such a differential response to GC- and AT-specific fluorochromes in several Phyllostomidae species is a result of variability in heterochromatin composition within the family (Santos et al., 2001).

In the family Phyllostomidae, it is common to use the karyotype of Macrotus waterhousii as a reference for the numbering system, since it is believed to represent the ancestral karyotype for the family (Baker, 2006). From the present work, it is obvious that the two species analyzed share considerable homeologies, with 11 identical chromosome pairs. Their karyotypes are highly derived when compared to the ancestral state (see Baker, 1979 for M. waterhousii standard reference G-banded karyotype). However, several chromosomal arms in M. waterhousii can be recognized as being homeologous to arms in the karyotypes of the two studied species. This gives support to the inference that the evolutionary trend in Phyllostomidae appears to lead to a reduction in diploid number by centric fusion events, with retention of the linkage groups. Furthermore, these 11 chromosomes were probably present in the ancestor before the radiation of Lonchorhina, the common ancestor of Phyllostominae (sensu Baker et al. 2003) and nectarivorous bats.

There are three biarmed elements, recognizable in the M. waterhousii karyotype, which remained unchanged in L. aurita and T. cirrhosus. These chromosomes correspond to M. waterhousii arms 6/7, 25/26, and 15/16 (Pairs 8, 9 and 11 of L. aurita and 8, 13 and 10 of T. cirrhosus). They have been described as unchanged in members of different subfamilies (i.e. Desmodontinae, Baker et al. 1988; Glossophaginae, Baker and Bass, 1979; and other Phyllostominae species, Patton and Baker, 1979), thereby indicating that they were already present in the common ancestor of all phyllostomid bats.

We have been unable to detect homeologies among some chromosomes for the studied species, and the banding pattern of distinct arms of these chromosomes is such as not to allow us to be certain of their correspondence. It is likely that most of these arms have undergone inversion prior to translocation, thereby hindering the identification of the rearrangements involved in karyotypic changes between these bats.

Members of the Phyllostomidae family have conserved karyotypes but show intergeneric variability, making a comparative analysis using classical banding difficult (Baker, 1979; Pieczarka et al., 2005). However, further comparative chromosomal studies with molecular cytogenetic techniques based on fluorescence in situ hybridization (FISH) are expected to provide a better understanding of the karyotypic changes that have occurred during the evolution of this family, as well as the phylogenetic relationships among the members of this complex group of bats.

Acknowledgments

The authors are grateful to Dr. Alfredo Langguth for taxonomic identification of the specimens and to Francisca Tavares Lira and Cirlene Maria da Silva for technical assistance in this work, as well as Mário Ferreira da Silva for assistance in the field work. Additional thanks are extended to Marcela Maria Pereira de Lemos Pinto for her help with C-banding and to Dr. Robert J Baker for reviewing early drafts of this paper. This study was supported by the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and the Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco (FACEPE).

Received: December 17, 2008; Accepted: May 15, 2009.

Associate Editor: Yatiyo Yonenaga-Yassuda

Baker RJ (1967) Karyotypes of bats of the family Phyllostomidae and their taxonomic implications. Southw Nat 12:407-428.
Baker RJ (1979) Karyology. In: Baker RJ, Jones K and Carter DC (eds) Biology of Bats of the New World Family Phyllostomatidae, Part III. Museum of Texas Tech University, Lubbock, 441 pp.
Baker RJ (2006) Order Chiroptera. In: O'Brien SJ, Menninger JC and Nash WG (eds) The Atlas of Mammalian Chromosomes. John Wiley & Sons, Inc., Hoboken, pp. 378-380.
Baker RJ and Bass RA (1979) Evolutionary relationship of the Brachyphyllinae to the Glossophagine genera Glossophaga and Monophyllus J Mammal 60:364-372.
Baker RJ and Hsu TC (1970) Further studies on the sex-chromosome systems of the American leaf-nosed bats (Chiroptera, Phyllostomatidae). Cytogenetics 9:131-138.
Baker RJ, Genoways HH, Bleir WJ and Warner JW (1973) Cytotypes and morphometrics of two phyllostomatid bats, Micronycteris hirsuta and Vampyressa pusilla Occ Pap Mus Texas Tech Univ 17:1-10.
Baker RJ, Honeycutt RL and Bass RK (1988) Genetics. In: Schmidt U and Greenhall A (eds) Natural History of Vampire Bats. CRC Press, Florida, pp 31-40.
Baker RJ, Hood CS and Honeycutt RL (1989) Phylogenetic relationships and classification of the higher categories of the new world bat family Phyllostomidae. Syst Zool 38:228-238.
Baker RJ, Porter CA, Patton JC and Van Den Bussche RA (2000) Systematics of bats of the family Phyllostomidae based on RAG2 DNA sequences. Occ Pap Mus Texas Tech Univ 202:1-16.
Baker RJ, Hoofer SR, Porter CA and Van Den Bussche RA (2003) Diversification among New World leaf-nosed bats: An evolutionary hypothesis and classification inferred from digenomic congruence of DNA sequence. Occ Pap Mus Texas Tech Univ 230:1-32.
Dos Santos Guerra M (1991) Cis-acting regulation of NOR cistrons in Eleutherine bulbosa (Iridaceae). Genetica 83:235-241.
Gardner AL (1977) Chromosomal variation in Vampyressa and a review of chromosomal evolution in the Phyllostomidae (Chiroptera). Syst Zool 26:300-318.
Howell WM and Black DA (1980). Controlled silver-staining of nucleolus organizer regions with a protective colloidal developer: A 1-step method. Experientia 36:1014-1015.
Hsu TC, Baker RJ and Utakoji T (1968) The multiple sex chromosome system of American leaf-nosed bats (Chiroptera, Phyllostomidae). Cytogenetics 7:27-38.
Jones KE (2002) Chiroptera (Bats). In: Encyclopedia of Life Sciences. Macmillan Publishers Ltd and Nature Publishing Group, Basingstoke, pp 1-5.
Morielle E and Varella-Garcia M (1988) Variability of nucleolus organizer regions in phyllostomid bats. Rev Bras Genet 11:853-871.
Neves ACB, Pieczarka JC, Barros RMS, Marques-Aguiar S, Rodrigues LRR and Nagamachi CY (2001) Cytogenetic studies on Choeroniscus minor (Chiroptera, Phyllostomidae) from the Amazon region. Cytobios 105:91-98.
Patton JC and Baker RJ (1979) Chromosomal homology and evolution of Phyllostomatoid bats. Syst Zool 27:449-462.
Pieczarka JC, Nagamachi CY, O'Brien PCM, Yang F, Rens W, Barros RMS, Noronha RCR, Rissino J, Oliveira EHC and Ferguson-Smith MA (2005) Reciprocal chromosome painting between two South American bats: Carollia brevicauda and Phyllostomus hastatus (Phyllostomidae, Chiroptera). Chromosome Res 13:339-347.
Rodrigues LRR, Barros RMS, Marques-Aguiar S, Assis MFL, Pieczarka JC and Nagamachi CY (2003) Comparative cytogenetics of two phyllostomids bats. A new hypothesis to the origin of the rearranged X chromosome from Artibeus lituratus (Chiroptera, Phyllostomidae). Caryologia 56:413-419.
Santos N and Souza MJ (1998a) Characterization of the constitutive heterochromatin of Carollia perspicillata (Phyllostomidae, Chiroptera) using the base-specific fluorochromes, CMA₃ (GC) and DAPI (AT). Caryologia 51:51-60.
Santos N and Souza MJ (1998b) Use of fluorochromes Chromomycin A₃ and DAPI to study constitutive heterochromatin and NORs in four species of bats (Phyllostomidae). Caryologia 51:265-278.
Santos N, Fagundes V, Yonenaga-Yassuda Y and Souza MJ (2001) Comparative karyology of Brazilian vampire bats Desmodus rotundus and Diphylla ecaudata (Phyllostomidae, Chiroptera): Banding patterns, base-specific fluorochromes and FISH of ribossomal genes. Hereditas 134:189-194.
Santos N, Fagundes V, Yonenaga-Yassuda Y and Souza MJ (2002) Localization of rRNA genes in Phyllostomidae bats revels silent NORs in Artibeus cinereus Hereditas 136:137-143.
Schweizer D (1980) Simultaneous fluorescent staining of R bands and specific heterochromatic regions (DA-DAPI bands) in human chromosomes. Cytogenet Cell Genet 27:190-193.
Seabright M (1971) A rapid banding technique for human chromosomes. Lancet 2:971-972.
Silva AM, Marques-Aguiar SA, Barros RMS, Nagamachi CY and Pieczarka JC (2005) Comparative cytogenetic analysis in the species Uroderma magnirostrum and U. bilobatum (cytotype 2n = 42) (Phyllostomidae, Stenodermatinae) in the Brazilian Amazon. Genet Mol Biol 28:248-253.
Simmons NB (2005) Order Chiroptera. In: Wilson DE and Reeder DM (eds) Mammals Species of the World: A Taxonomic and Geographic Reference 3rd edition. Johns Hopkins University Press, Baltimore, pp 312-529.
Souza MJ and Araújo MCP (1990) Conservative pattern of the G-bands and diversity of C-banding patterns and NORs in Stenodermatinae (Chiroptera-Phyllostomatidae). Rev Bras Genet 13:255-268.
Sumner AT (1972) A sample technique for demonstrating centromeric heterochromatin. Exp Cell Res 75:304-306.
Varella-Garcia M, Morielle-Versute E and Taddei VA (1989). A survey of cytogenetic data on brazilian bats. Rev Bras Genet 12:761-793.
Wetterer AL, Rockman MV and Simmons NB (2000) Phylogeny of phyllostomid bats (Mammalia, Chiroptera): Data from diverse morphological systems, sex chromosomes and restriction sites. Bull Am Mus Nat Hist 248:1-200.

Send Correspondence to:

Maria José de Souza

Laboratório de Genética e Citogenética Animal

Departamento de Genética, Centro de Ciências Biológicas

Universidade Federal de Pernambuco

Av. Prof. Moraes Rego SN, Cidade Universitária

50732-970 Recife, PE, Brazil

E-mail:

mjslopes.ufpe@yahoo.com.br

Publication Dates

Publication in this collection
06 Nov 2009
Date of issue
2009

History

Accepted
15 May 2009
Received
17 Dec 2008

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Baker RJ (1967) Karyotypes of bats of the family Phyllostomidae and their taxonomic implications. Southw Nat 12:407-428.

[2] Baker RJ (1979) Karyology. In: Baker RJ, Jones K and Carter DC (eds) Biology of Bats of the New World Family Phyllostomatidae, Part III. Museum of Texas Tech University, Lubbock, 441 pp.

[3] Baker RJ (2006) Order Chiroptera. In: O'Brien SJ, Menninger JC and Nash WG (eds) The Atlas of Mammalian Chromosomes. John Wiley & Sons, Inc., Hoboken, pp. 378-380.

[4] Baker RJ and Bass RA (1979) Evolutionary relationship of the Brachyphyllinae to the Glossophagine genera Glossophaga and Monophyllus J Mammal 60:364-372.

[5] Baker RJ and Hsu TC (1970) Further studies on the sex-chromosome systems of the American leaf-nosed bats (Chiroptera, Phyllostomatidae). Cytogenetics 9:131-138.

[6] Baker RJ, Genoways HH, Bleir WJ and Warner JW (1973) Cytotypes and morphometrics of two phyllostomatid bats, Micronycteris hirsuta and Vampyressa pusilla Occ Pap Mus Texas Tech Univ 17:1-10.

[7] Baker RJ, Honeycutt RL and Bass RK (1988) Genetics. In: Schmidt U and Greenhall A (eds) Natural History of Vampire Bats. CRC Press, Florida, pp 31-40.

[8] Baker RJ, Hood CS and Honeycutt RL (1989) Phylogenetic relationships and classification of the higher categories of the new world bat family Phyllostomidae. Syst Zool 38:228-238.

[9] Baker RJ, Porter CA, Patton JC and Van Den Bussche RA (2000) Systematics of bats of the family Phyllostomidae based on RAG2 DNA sequences. Occ Pap Mus Texas Tech Univ 202:1-16.

[10] Baker RJ, Hoofer SR, Porter CA and Van Den Bussche RA (2003) Diversification among New World leaf-nosed bats: An evolutionary hypothesis and classification inferred from digenomic congruence of DNA sequence. Occ Pap Mus Texas Tech Univ 230:1-32.

[11] Dos Santos Guerra M (1991) Cis-acting regulation of NOR cistrons in Eleutherine bulbosa (Iridaceae). Genetica 83:235-241.

[12] Gardner AL (1977) Chromosomal variation in Vampyressa and a review of chromosomal evolution in the Phyllostomidae (Chiroptera). Syst Zool 26:300-318.

[13] Howell WM and Black DA (1980). Controlled silver-staining of nucleolus organizer regions with a protective colloidal developer: A 1-step method. Experientia 36:1014-1015.

[14] Hsu TC, Baker RJ and Utakoji T (1968) The multiple sex chromosome system of American leaf-nosed bats (Chiroptera, Phyllostomidae). Cytogenetics 7:27-38.

[15] Jones KE (2002) Chiroptera (Bats). In: Encyclopedia of Life Sciences. Macmillan Publishers Ltd and Nature Publishing Group, Basingstoke, pp 1-5.

[16] Morielle E and Varella-Garcia M (1988) Variability of nucleolus organizer regions in phyllostomid bats. Rev Bras Genet 11:853-871.

[17] Neves ACB, Pieczarka JC, Barros RMS, Marques-Aguiar S, Rodrigues LRR and Nagamachi CY (2001) Cytogenetic studies on Choeroniscus minor (Chiroptera, Phyllostomidae) from the Amazon region. Cytobios 105:91-98.

[18] Patton JC and Baker RJ (1979) Chromosomal homology and evolution of Phyllostomatoid bats. Syst Zool 27:449-462.

[19] Pieczarka JC, Nagamachi CY, O'Brien PCM, Yang F, Rens W, Barros RMS, Noronha RCR, Rissino J, Oliveira EHC and Ferguson-Smith MA (2005) Reciprocal chromosome painting between two South American bats: Carollia brevicauda and Phyllostomus hastatus (Phyllostomidae, Chiroptera). Chromosome Res 13:339-347.

[20] Rodrigues LRR, Barros RMS, Marques-Aguiar S, Assis MFL, Pieczarka JC and Nagamachi CY (2003) Comparative cytogenetics of two phyllostomids bats. A new hypothesis to the origin of the rearranged X chromosome from Artibeus lituratus (Chiroptera, Phyllostomidae). Caryologia 56:413-419.

[21] Santos N and Souza MJ (1998a) Characterization of the constitutive heterochromatin of Carollia perspicillata (Phyllostomidae, Chiroptera) using the base-specific fluorochromes, CMA₃ (GC) and DAPI (AT). Caryologia 51:51-60.

[22] Santos N and Souza MJ (1998b) Use of fluorochromes Chromomycin A₃ and DAPI to study constitutive heterochromatin and NORs in four species of bats (Phyllostomidae). Caryologia 51:265-278.

[23] Santos N, Fagundes V, Yonenaga-Yassuda Y and Souza MJ (2001) Comparative karyology of Brazilian vampire bats Desmodus rotundus and Diphylla ecaudata (Phyllostomidae, Chiroptera): Banding patterns, base-specific fluorochromes and FISH of ribossomal genes. Hereditas 134:189-194.

[24] Santos N, Fagundes V, Yonenaga-Yassuda Y and Souza MJ (2002) Localization of rRNA genes in Phyllostomidae bats revels silent NORs in Artibeus cinereus Hereditas 136:137-143.

[25] Schweizer D (1980) Simultaneous fluorescent staining of R bands and specific heterochromatic regions (DA-DAPI bands) in human chromosomes. Cytogenet Cell Genet 27:190-193.

[26] Seabright M (1971) A rapid banding technique for human chromosomes. Lancet 2:971-972.

[27] Silva AM, Marques-Aguiar SA, Barros RMS, Nagamachi CY and Pieczarka JC (2005) Comparative cytogenetic analysis in the species Uroderma magnirostrum and U. bilobatum (cytotype 2n = 42) (Phyllostomidae, Stenodermatinae) in the Brazilian Amazon. Genet Mol Biol 28:248-253.

[28] Simmons NB (2005) Order Chiroptera. In: Wilson DE and Reeder DM (eds) Mammals Species of the World: A Taxonomic and Geographic Reference 3rd edition. Johns Hopkins University Press, Baltimore, pp 312-529.

[29] Souza MJ and Araújo MCP (1990) Conservative pattern of the G-bands and diversity of C-banding patterns and NORs in Stenodermatinae (Chiroptera-Phyllostomatidae). Rev Bras Genet 13:255-268.

[30] Sumner AT (1972) A sample technique for demonstrating centromeric heterochromatin. Exp Cell Res 75:304-306.

[31] Varella-Garcia M, Morielle-Versute E and Taddei VA (1989). A survey of cytogenetic data on brazilian bats. Rev Bras Genet 12:761-793.

[32] Wetterer AL, Rockman MV and Simmons NB (2000) Phylogeny of phyllostomid bats (Mammalia, Chiroptera): Data from diverse morphological systems, sex chromosomes and restriction sites. Bull Am Mus Nat Hist 248:1-200.

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