Analysis of the synaptonemal complex of the nine-banded armadillo, Dasypus novemcinctus

Scavone, Márcia Denise da Paixão; Oliveira, Claudio; Bagagli, Eduardo; Foresti, Fausto

doi:10.1590/S1415-47572000000300020

Abstracts

The synaptonemal complex (SC) of three specimens of the nine-banded armadillo (Dasypus novemcinctus) was analyzed. Thirty-two bivalents (2n = 64) were observed, 31 of them being autosomes and one an XY sexual bivalent. Chromosome synapsis processes and nucleolus structure changes were analyzed in zygotene and pachytene cells, allowing a detailed description of the beginning of meiotic prophase in this species. There was complete synapsis of X and Y chromosomes. Some abnormalities in SC were observed in cells during zygotene and at the beginning of pachytene, but not in cells in the middle and late pachytene, suggesting the occurrence of synaptic adjustments in their SC.

Foi analisado o complexo sinaptonêmico (SC) de três espécimens de tatu galinha (Dasypus novemcinctus). Foi observada a ocorrência de 32 bivalentes (2n = 64), 31 dos quais correspondiam aos autossomos e um ao bivalente sexual XY. Os processos de sinapse cromossômica e transformação na estrutura do nucléolo foram analisados em células em zigóteno e paquíteno, permitindo uma detalhada descrição do início da prófase meiótica dessa espécie. Uma característica importante observada foi o completo emparelhamento dos cromossomos X e Y. Algumas anormalidades do SC foram observadas em células em zigóteno e no início de paquíteno, porém essas anormalidades não foram observadas em células no meio e fim de paquíteno, sugerindo a ocorrência de ajustamentos sinápticos no SC.

SHORT COMMUNICATION

Analysis of the synaptonemal complex of the nine-banded armadillo, Dasypus novemcinctus

Márcia Denise da Paixão Scavone¹, Claudio Oliveira¹, Eduardo Bagagli² and Fausto Foresti¹

¹²

Send correspondence to C.O. Fax: +55-14-6802-6264. E-mail: claudio@ibb.unesp.br

ABSTRACT

The synaptonemal complex (SC) of three specimens of the nine-banded armadillo (Dasypus novemcinctus) was analyzed. Thirty-two bivalents (2n = 64) were observed, 31 of them being autosomes and one an XY sexual bivalent. Chromosome synapsis processes and nucleolus structure changes were analyzed in zygotene and pachytene cells, allowing a detailed description of the beginning of meiotic prophase in this species. There was complete synapsis of X and Y chromosomes. Some abnormalities in SC were observed in cells during zygotene and at the beginning of pachytene, but not in cells in the middle and late pachytene, suggesting the occurrence of synaptic adjustments in their SC.

INTRODUCTION

The Dasypodidae family has nine genera, and the genus Dasypus, six species. The species of this family have a highly conserved phenotype, making its taxonomy problematic (Jorge et al., 1985). Widely distributed, the nine-banded armadillo, D. novemcinctus, is found in northeastern Argentina, all of eastern South America, Central America, Mexico, and in the southeastern part of the United States (Storrs et al., 1974). The importance of D. novemcinctus as a model for basic research on reproduction and genetics has long been recognized (Storrs et al., 1974).

The D. novemcinctus karyotype was described by Beath et al. (1962), with 2n = 64 chromosomes, consisting of two large metacentric pairs, four large acrocentric pairs, 14 medium-sized acrocentric pairs, six medium-sized metacentric pairs and five small acrocentric pairs. The X chromosome is a large metacentric and the Y chromosome is the smallest acrocentric. Benirschke et al. (1969) and Jorge et al. (1985) found several chromosomal polymorphisms in this species in North America.

One of the most important characteristics of the first meiotic prophase is the presence of the synaptonemal complex (SC), a protein structure formed at the beginning of prophase I between the sister chromatids of each bivalent. In the SC, kinetochores are seen as a prominent differentiation of the lateral elements (LEs), while the telomeres, attached to the nuclear envelope, are seen as dark regions in the SC extremities (Moses, 1977). New cytological techniques developed to analyze the SC have allowed detailed studies of chromosome synapsis at meiosis, including the identification of zygotene and pachytene substages (Solari, 1980; Dollin et al., 1989; Greenbaum et al., 1990; Villagomez, 1993). Moreover, SC studies have greatly contributed to karyotypic studies of several species, mainly mammals (Gillies, 1989).

We examined SC in Dasypus novemcinctus spermatocytes, in different zygotene and pachytene substages, to determine the structure and behavior of the autosomes, sex chromosomes, and nucleoli.

MATERIAL AND METHODS

Spermatogenic cells were collected from three male nine-banded armadillos, Dasypus novemcinctus, about one year old, collected in Botucatu, SP, Brazil. The SC was analyzed by the surface spread technique (Santos, 1993). Spermatocytes were lysed with 0.01% Triton X100, fixed in 4% paraformaldehyde and stained with 50% silver nitrate (Howell and Black, 1980). SC were transferred to 75-mesh electron microscope grids, examined with a Phillips EM301 electron microscope, at 80 kV, and photographed on Kodak-Eastman film. Photographs of 41 cells were taken.

RESULTS AND DISCUSSION

Complete cells of D. novemcinctus in zygotene and pachytene stages contained 32 bivalents, 31 autosomes and one XY sex pair (Figure 1a). Previous cytogenetic studies of this species also indicated 2n = 64 chromosomes including the XY sex chromosomes (Beath et al., 1962; Jorge et al., 1985). In the extremities of the LEs, darkly stained telomeric plaques were observed, as has been found for other organisms (Solari, 1989).

D. novemcinctus spermatocytes were classified into two substages of zygotene and three substages of pachytene by examination of autosome and sex chromosome LEs according to criteria proposed by Greenbaum et al. (1990). Early and late zygotene processes were identified according to the autosomal synapsis complexity. The early, middle and late substages of pachytene were identified by the degree of LE shortening, sexual vesicle condensation and nucleolus dispersion.

Synapsis is asynchronous in D. novemcinctus. Totally paired bivalents were observed simultaneously with other bivalents at the beginning of the pairing process (Figure 1b). Autosome synapsis begins either at one telomere and continues linearly towards the opposite telomere or begins at both telomeres and progresses towards the centromere (Figure 1c). These observations can be explained by the occurrence of one- and two-armed chromosomes (Beath et al., 1962). D. novemcinctus autosome behavior resembles that observed in other mammalian species with one- and two-armed chromosomes (Moses, 1977; Gillies, 1989).

In some centromeric regions there was a longer delay in LE synapsis (Figure 1d), possibly due to the presence of heterochromatic segments, which have been observed in chromosomes of several armadillo species (Jorge et al., 1985). Asynapsed areas at early pachytene has been observed in some heterochromatic human chromosome segments (Solari, 1980) and more recently in other mammalian species (Koykul and Basrur, 1995; Fagundes and Yonenaga-Yassuda, 1996).

Nucleoli were identified in chromosomes 2 and 24. Association of nucleoli with LEs was frequently seen during zygotene and early pachytene (Figure 1a). This association disappeared during the middle and late pachytene. The sequence of nucleolus fragmentation was similar to that described for other mammals (Solari, 1989). Secondary association of the nucleolus with the XY bivalent, as seen in humans and mice (Solari, 1989), was not observed.

In late zygotene unpaired sex chromosomes were in close proximity (Figure 1f). Synapsis of these chromosomes started during early pachytene in the long arm extremity of X chromosome (Figure 1g). This is also observed in cattle (Switonski et al., 1990), mink (Koykul and Basrur, 1995) and mice (Fagundes and Yonenaga-Yassuda, 1996). During middle pachytene, the homologous segment and the pseudoautosomal portion of the sex chromosome were almost totally synapsed. The remainder of the X chromosome was totally heteropycnotic (Figure 1h). Synapsis of the sex chromosomes was completed during late pachytene, as indicated by a marked thickening of the unsynapsed X segment and formation of the sexual vesicle (Figure 1i). Synapsis of the sexual chromosomes occurred in a such way that the X and Y chromosomes became entirely paired (Figure 1h). Complete X and Y chromosome synapsis is uncommon but has been observed in mammalian species such as mice (Joseph and Chandley, 1984), cats (Gillies and Cowan, 1985) and mink (Koykul and Basrur, 1995).

Several chromosome pairing failures were observed in the zygotene and pachytene cells, e.g., telomere associations (Figure 1e), univalents, pairing delays and interlockings. The frequency of these cell anomalies declined from late zygotene to late pachytene. This could be because synaptic adjustment reduces pairing failures, as has been proposed for several mammalian species (Ashley et al., 1981; Moses and Poorman, 1981; Gabriel-Robez et al., 1986; Dollin et al., 1991).

ACKNOWLEDGMENTS

The authors thank Dr. E.A. Gregório for making an electron microscope available and Dr. M.K. Tansey for critical review of the original manuscript. Financial aid for the research was provided by FAPESP and CNPq. Publication supported by FAPESP.

RESUMO

Foi analisado o complexo sinaptonêmico (SC) de três espécimens de tatu galinha (Dasypus novemcinctus). Foi observada a ocorrência de 32 bivalentes (2n = 64), 31 dos quais correspondiam aos autossomos e um ao bivalente sexual XY. Os processos de sinapse cromossômica e transformação na estrutura do nucléolo foram analisados em células em zigóteno e paquíteno, permitindo uma detalhada descrição do início da prófase meiótica dessa espécie. Uma característica importante observada foi o completo emparelhamento dos cromossomos X e Y. Algumas anormalidades do SC foram observadas em células em zigóteno e no início de paquíteno, porém essas anormalidades não foram observadas em células no meio e fim de paquíteno, sugerindo a ocorrência de ajustamentos sinápticos no SC.

REFERENCES

(Received September 16, 1999)

Ashley, T., Moses, M.J. and Solari, A.J. (1981). Fine structure and behaviour of a pericentric inversion in the sand rat, Psammomys obesus. J. Cell Sci 50: 105-119.
Beath, M.M., Benirschke, K. and Brownhill, L.E. (1962). The chromosomes of the nine-banded armadillo, Dasypus novencinctus. Chromosoma 13: 27-38.
Benirschke, K., Low, R.J. and Ferm, V.H. (1969). Cytogenetic studies of some armadillos. In: Comparative Mammalian Cytogenetics (Benirschke, K., ed.). Springer-Verlag, New York, pp. 330-345.
Dollin, A.E., Murray, J.D. and Gillies, C.B. (1989). Synaptonemal complex analysis of hybrid cattle. I. Pachytene substaging and the normal full bloods. Genome 32: 856-864.
Dollin, A.E., Murray, J.D. and Gillies, C.B. (1991). Synaptonemal complex analysis of hybrid cattle. III. Meiotic pairing mechanisms in F1 Brahman x Hereford hybrids. Genome 34: 228-235.
Fagundes, V. and Yonenaga-Yassuda, Y. (1996). The analysis of synaptonemal complex formation in Trichomys apereoides (Rodentia, Echimyidae) with detailed XY pairing. Caryologia 49: 183-192.
Gabriel-Robez, O., Ratomponirina, C., Rumpler, Y., Le Marec, B., Luciani, J.M. and Guichaoua, M.R. (1986). Synapsis and synaptic adjustment in an infertile human male heterozygous for a pericentric inversion in chromosome 1. Hum. Genet. 72: 148-152.
Gillies, C.B. (1989). Fertility and Chromosome Pairing: Recent Studies in Plants and Animals CRC Press, Boca Raton.
Gillies, C.B. and Cowan, S.K. (1985). The pachytene synaptonemal complex complement of the cat. Genetica 67: 99-107.
Greenbaum, I.F., Hale, D.W., Sudman, P.D. and Nevo, E. (1990). The mechanism of autosomal synapsis and the substaging of zygonema and pachynema from deer mouse spermatocytes. Chromosoma 93: 203-212.
Howell, W.M. and Black, D.A. (1980). Controlled silver-staining of nucleolus organizer regions with a protective colloidal developer: a 1-step method. Experientia 36: 1014-1015.
Jorge, W., Orsi-Souza, A.T. and Best, R. (1985). The somatic chromosomes of Xenarthra In: The Evolution and Ecology of Armadillos, Sloths, and Vermilinguas (Montgomery, G.G., ed.). Smithsonian Institution Press, Washington.
Joseph, A.M. and Chandley, A.C. (1984). The morphological sequence of XY pairing in the Norway rat Rattus norvegicus Chromosoma 89: 381-386.
Koykul, W. and Basrur, P.K. (1995). The XY pair of the mink (Mustela vision) during different periods of testicular activity. Hereditas 122: 169-176.
Moses, M.J. (1977). Synaptonemal complex karyotyping in spermatocytes of the Chinese hamster (Cricetulus griseus). I. Morphology of the autosomal complement in spread preparations. Chromosoma 60: 99-125.
Moses, M.J. and Poorman, P.A. (1981). Synaptonemal complex analysis of mouse chromosomal rearrangements. II. Synaptic adjustment in a tandem duplication. Chromosoma 81: 519-535.
Santos, J.L. (1993). Spreading synaptonemal complex from the grasshopper Chorthippus jacobsi: pachytene and observations. Hereditas 118: 235-241.
Solari, A.J. (1980). Synaptonemal complex and associated structures in microspread human spermatocytes. Chromosoma 81: 315-337.
Solari, A.J. (1989). Sex chromosome pairing and fertility in the heterogametic sex of mammals and birds. In: Fertility and Chromosome Pairing: Recent Studies in Plants and Animals (Gillies, C.B., ed.). CRC Press, Boca Raton, pp. 77-135.
Storrs, E.E., Walsh, G.P., Burchfield, H.P. and Binford, C.H. (1974). Leprosy in the armadillo: new model for biomedical research. Science 183: 851-852.
Switonski, M., Ansari, H.A., Mathew, A., Jung, H.R. and Stranzinger, G. (1990). Synaptonemal complex analysis in primary spermatocytes of cattle x zebu hybrids (Bos taurus x Bos indicus). Breed Genet. 107: 229-238.
Villagomez, D.A.F. (1993). Zygotene-pachytene substaging and synaptonemal complex karotyping of boar spermatocytes. Hereditas 118: 87-99.

Publication Dates

Publication in this collection
04 May 2001
Date of issue
Sept 2000

History

Received
16 Sept 1999

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

[1] Ashley, T., Moses, M.J. and Solari, A.J. (1981). Fine structure and behaviour of a pericentric inversion in the sand rat, Psammomys obesus. J. Cell Sci 50: 105-119.

[2] Beath, M.M., Benirschke, K. and Brownhill, L.E. (1962). The chromosomes of the nine-banded armadillo, Dasypus novencinctus. Chromosoma 13: 27-38.

[3] Benirschke, K., Low, R.J. and Ferm, V.H. (1969). Cytogenetic studies of some armadillos. In: Comparative Mammalian Cytogenetics (Benirschke, K., ed.). Springer-Verlag, New York, pp. 330-345.

[4] Dollin, A.E., Murray, J.D. and Gillies, C.B. (1989). Synaptonemal complex analysis of hybrid cattle. I. Pachytene substaging and the normal full bloods. Genome 32: 856-864.

[5] Dollin, A.E., Murray, J.D. and Gillies, C.B. (1991). Synaptonemal complex analysis of hybrid cattle. III. Meiotic pairing mechanisms in F1 Brahman x Hereford hybrids. Genome 34: 228-235.

[6] Fagundes, V. and Yonenaga-Yassuda, Y. (1996). The analysis of synaptonemal complex formation in Trichomys apereoides (Rodentia, Echimyidae) with detailed XY pairing. Caryologia 49: 183-192.

[7] Gabriel-Robez, O., Ratomponirina, C., Rumpler, Y., Le Marec, B., Luciani, J.M. and Guichaoua, M.R. (1986). Synapsis and synaptic adjustment in an infertile human male heterozygous for a pericentric inversion in chromosome 1. Hum. Genet. 72: 148-152.

[8] Gillies, C.B. (1989). Fertility and Chromosome Pairing: Recent Studies in Plants and Animals CRC Press, Boca Raton.

[9] Gillies, C.B. and Cowan, S.K. (1985). The pachytene synaptonemal complex complement of the cat. Genetica 67: 99-107.

[10] Greenbaum, I.F., Hale, D.W., Sudman, P.D. and Nevo, E. (1990). The mechanism of autosomal synapsis and the substaging of zygonema and pachynema from deer mouse spermatocytes. Chromosoma 93: 203-212.

[11] Howell, W.M. and Black, D.A. (1980). Controlled silver-staining of nucleolus organizer regions with a protective colloidal developer: a 1-step method. Experientia 36: 1014-1015.

[12] Jorge, W., Orsi-Souza, A.T. and Best, R. (1985). The somatic chromosomes of Xenarthra In: The Evolution and Ecology of Armadillos, Sloths, and Vermilinguas (Montgomery, G.G., ed.). Smithsonian Institution Press, Washington.

[13] Joseph, A.M. and Chandley, A.C. (1984). The morphological sequence of XY pairing in the Norway rat Rattus norvegicus Chromosoma 89: 381-386.

[14] Koykul, W. and Basrur, P.K. (1995). The XY pair of the mink (Mustela vision) during different periods of testicular activity. Hereditas 122: 169-176.

[15] Moses, M.J. (1977). Synaptonemal complex karyotyping in spermatocytes of the Chinese hamster (Cricetulus griseus). I. Morphology of the autosomal complement in spread preparations. Chromosoma 60: 99-125.

[16] Moses, M.J. and Poorman, P.A. (1981). Synaptonemal complex analysis of mouse chromosomal rearrangements. II. Synaptic adjustment in a tandem duplication. Chromosoma 81: 519-535.

[17] Santos, J.L. (1993). Spreading synaptonemal complex from the grasshopper Chorthippus jacobsi: pachytene and observations. Hereditas 118: 235-241.

[18] Solari, A.J. (1980). Synaptonemal complex and associated structures in microspread human spermatocytes. Chromosoma 81: 315-337.

[19] Solari, A.J. (1989). Sex chromosome pairing and fertility in the heterogametic sex of mammals and birds. In: Fertility and Chromosome Pairing: Recent Studies in Plants and Animals (Gillies, C.B., ed.). CRC Press, Boca Raton, pp. 77-135.

[20] Storrs, E.E., Walsh, G.P., Burchfield, H.P. and Binford, C.H. (1974). Leprosy in the armadillo: new model for biomedical research. Science 183: 851-852.

[21] Switonski, M., Ansari, H.A., Mathew, A., Jung, H.R. and Stranzinger, G. (1990). Synaptonemal complex analysis in primary spermatocytes of cattle x zebu hybrids (Bos taurus x Bos indicus). Breed Genet. 107: 229-238.

[22] Villagomez, D.A.F. (1993). Zygotene-pachytene substaging and synaptonemal complex karotyping of boar spermatocytes. Hereditas 118: 87-99.

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Analysis of the synaptonemal complex of the nine-banded armadillo, Dasypus novemcinctus

Abstracts

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History