Elimination of micronuclei from microspores in a Brazilian oat (Avena sativa L.) variety

Baptista-Giacomelli, Flávia Roseli; Pagliarini, Maria Suely; Almeida, Juliano Luiz de

doi:10.1590/S1415-47572000000300029

Abstracts

Chromosome elimination in interspecific hybrids is a powerful tool in breeding programs. Of 12 Brazilian oat varieties recommended for cultivation in southern Brazil, one variety, UFRGS 15, presented a new type of chromosome elimination never described in any other species. Chromosomes that produced micronuclei during meiosis were eliminated from microspores as microcytes. The micronucleus reached the microspore wall and formed a kind of bud, separated from the microspore. The eliminated microcytes gave origin to small and sterile pollen grains. The possible applications of this finding for oat breeding are discussed.

Eliminação de cromossomos em híbridos interespecíficos é uma ferramenta poderosa em programas de melhoramento. Entre 12 variedades brasileiras de aveia recomendadas para cultivo na região Sul, uma (UFRGS 15) apresentou um tipo de eliminação cromossômica nunca antes descrita em outra espécie. Cromossomos que deram origem a micronúcleos durante a meiose foram eliminados do micrósporo como micrócito. O micronúcleo aproximava-se da parede do micrósporo, formava um tipo de brotamento e sofria separação do micrósporo. Os micrócitos eliminados deram origem a grãos de pólen pequenos e estéreis. As possíveis aplicações deste achado para o melhoramento de aveia são discutidas.

Elimination of micronuclei from microspores in a Brazilian oat (Avena sativa L.) variety

Flávia Roseli Baptista-Giacomelli¹, Maria Suely Pagliarini¹ and Juliano Luiz de Almeida²

¹

Send correspondence to M.S.P. E-mail: mspagliarini@uem.br

²Cooperativa Agrária Mista de Entre Rios, Guarapuava, PR, Brasil.

ABSTRACT

Chromosome elimination in interspecific hybrids is a powerful tool in breeding programs. Of 12 Brazilian oat varieties recommended for cultivation in southern Brazil, one variety, UFRGS 15, presented a new type of chromosome elimination never described in any other species. Chromosomes that produced micronuclei during meiosis were eliminated from microspores as microcytes. The micronucleus reached the microspore wall and formed a kind of bud, separated from the microspore. The eliminated microcytes gave origin to small and sterile pollen grains. The possible applications of this finding for oat breeding are discussed.

INTRODUCTION

The genus Avena L. (Poaceae) has a basic chromosome number x = 7 and contains diploid, tetraploid and hexaploid species. Avena sativa, the cultivated and most important commercial oat, is a hexaploid species (2n = 6x = 42) with an AACCDD genomic constitution. In general, A-type genomes of diploid species show metacentric chromosomes, whereas in C-type genomes most chromosomes are subterminal. It is generally believed that hexaploid oats originated by tetraploidization of A. maroccana and A. murphyi, both with AC-type genomes (Leggett, 1984), while the origin of the D-type genome in hexaploid oats remains unknown.

Unlike the large number of cytogenetic studies that have been dedicated to elucidating the origin and evolution of the genus Avena, few studies are available on the evaluation of meiotic behavior. McMullen et al. (1982) evaluated the meiotic process in American hexaploid oats (A. sativa and A. sterilis), while Guillin et al. (1995) investigated these processes in A. sativa lines and hybrids from Argentina. In both of these studies the authors found meiotic irregularities, particularly those types related to chromosome segregation that produced micronuclei in tetrads, although these papers did not discuss the fate of these micronuclei. In an extensive evaluation of meiosis in 12 of the 17 Brazilian oat varieties recommended for planting in southern Brazil we found numerous types of meiotic abnormalities, some of which gave rise to micronuclei that remained until the tetrad stage. In one variety, UFRGS 15, we observed a different pattern, never before described in any other species, with microspore micronuclei being eliminated as microcytes. This phenomenon and its importance for breeding will be discussed in this study.

MATERIAL AND METHODS

The varieties were chosen on the basis of their productivity as determined in a 1997 trial without fungicide application, the strains being UFRGS 16, UPF 16, CTC 3, UPF 17, UFRGS 7 and UFRGS 17 (the 6 most productive ) and CTC 1, UPF 14, UFRGS 10, UPF 7, UFRGS 15 and UPF 13 (the 6 least productive). The varieties were cultivated in fields belonging to the Cooperativa Agrária Mista de Entre Rios (Guarapuava, Entre Rios district, PR, Brazil).

Panicles were collected for meiotic analysis between 8:00 and 10:00 a.m. and fixed for 24 h in Carnoy solution (ethanol:acetic acid, 3:1 v/v), after which they were transferred to 70% alcohol and stored at 4ºC. Pollen mother cells (PMCs) were prepared by the squash technique and stained with 1% propionic carmine. Five plants per variety were analyzed. The same procedures were employed to test pollen fertility.

RESULTS AND DISCUSSION

The main meiotic abnormalities observed in the 12 varieties were related to chromosome segregation. During diakinesis there was a low frequency of univalent chromosomes, but during metaphase I the number of cells with univalents presenting precocious migration to the poles was high. McMullen et al. (1982) also found an increase in the frequency of univalents from diakinesis to metaphase I in American oat hybrids (A. sativa/A. sterilis), and suggested that desynapsis occurred in the bivalent. We believe that the increase in the frequency of univalents in metaphase I in the varieties analyzed can also result from precocious chiasma terminalization, because the chiasma frequency per microsporocyte was high in all varieties (mean = 41.66 to 42.00), and the majority of bivalents presented two terminal chiasmata.

Because univalents usually do not suffer regular segregation in the first division, the frequency of univalents in diakinesis/metaphase I has been used as a standard measure of meiotic disturbances in other crop species (Scoles and Kaltsikes, 1974). In general, univalents migrate precociously to the poles or behave as laggards in anaphase, but in both cases they can produce micronuclei in telophase I which normally remain until the tetrad stage (Koduru and Rao, 1981). Although chromosome not included in the nucleus during the first or second division can produce micronuclei in the tetrad, the fate of these micronuclei in microspores and pollen grains has not been discussed in the literature. In 11 of the oat varieties used in our experiments, a micronucleus remained in the microspore after dissolution of the callose wall of the tetrad and reached the pollen grain stage (Figure 1a-d). However, Figure 2 shows that in one variety, UFRGS 15, after microspore formation micronuclei were eliminated by a curious mechanism in which one or more micronuclei approached the microspore wall (Figure 2a) and formed a kind of bud (Figure 2b) which separated from the microspore and was eliminated as a microcyte (Figure 2c) that gave rise to small, sterile, pollen grains (Figure 2d).

The elimination of a micronucleus from the microspore is a kind of chromosome elimination, a common phenomenon in interspecific and intergeneric hybrid embryos produced as a result of crosses between certain plant species. Well-known examples being crosses between Hordeum vulgare and H. bulbosum (Davies, 1974), crosses between other Hordeum species (Jorgensen and Bothmer, 1988) and interspecific hybrids in the genera Nicotiana (Gupta, 1969) and Solanum (Pijnacker et al., 1989). The combination of two distinct genomes in hybrids frequently results in aberrant mitotic and meiotic divisions, and sometimes leads to chromosome elimination, and a positive correlation between chromosome elimination and genetic distance between species has been found in Brassicaceae (Sundberg and Glimelius, 1991). In our experiments, the micronucleus elimination observed is surprising because Avena sativa, although being a allohexaploid species, is meiotically stable, with chromosomes pairing as 21 bivalents.

Several examples in the literature show that chromosome elimination can be partial or total for one parental genome (Adamowski et al., 1998) and in some cases such elimination is tissue-dependent and affected by the physiological conditions of the cells. Elimination of micronuclei in the microspore stage, as found in this oat variety, has not been reported for any species.

Many mechanisms of chromosome elimination have been described, including chromosome fragmentation, micronucleus formation, chromatin degradation, non-oriented chromosomes at metaphase and laggards in anaphase (Singh, 1993). Several hypotheses have been suggested in an attempt to explain the phenomenon, including inactivation of chromosomes by nuclease, formation of multipolar spindles, asynchrony in nucleoprotein synthesis, genome ratios, spatial separation of genomes, suppression of centromere function in the eliminated chromosomes, asynchronous cell cycle phases, and asynchronous mitotic and meiotic rhythms (Adamowski et al., 1998), but the exact mechanism is still obscure. Chromosome elimination in interspecific hybrids is a powerful tool in breeding programs, with differential chromosome elimination having facilitated the production of addition and substitution lines, while total elimination of one genome has permitted the formation of haploid lines. Interploidy gene transfer in Avena using monosomic alien substitution lines has been applied in oat breeding (Forsberg, 1990) and molecular cytogenetic techniques (Katsiotis et al., 1997) are being used for chromosome recognition in the genus. The elimination of micronuclei in microspores, accompanied by accurate recognition of the eliminated chromosome might also be useful in oat breeding.

RESUMO

Eliminação de cromossomos em híbridos interespecíficos é uma ferramenta poderosa em programas de melhoramento. Entre 12 variedades brasileiras de aveia recomendadas para cultivo na região Sul, uma (UFRGS 15) apresentou um tipo de eliminação cromossômica nunca antes descrita em outra espécie. Cromossomos que deram origem a micronúcleos durante a meiose foram eliminados do micrósporo como micrócito. O micronúcleo aproximava-se da parede do micrósporo, formava um tipo de brotamento e sofria separação do micrósporo. Os micrócitos eliminados deram origem a grãos de pólen pequenos e estéreis. As possíveis aplicações deste achado para o melhoramento de aveia são discutidas.

REFERENCES

(Received June 5, 2000)

Adamowski, E.V., Pagliarini, M.S. and Batista, L.A.R. (1998). Chromosome elimination in Paspalum subciliatum (Notata group). Sex. Plant Reprod 11: 272-276.
Davies, D.R. (1974). Chromosome elimination in inter-specific hybrids. Heredity 32: 267-270.
Forsberg, R.A. (1990). The use of monosomic alien substitution lines in interploidy gene transfer in Avena. Bulgar. J. Biotech 4: 27-30.
Guillin, E., Poggio, L. and Naranjo, C.A. (1995). Meiotic irregularities in Argentinian hexaploid oats. Cytologia 60: 211-215.
Gupta, S.B. (1969). Duration of mitotic cycle and regulation of DNA replication in Nicotiana plumbaginifolia and a hybrid derivative of N. tabacum showing chromosome instability. Can. J. Genet. Cytol. 11: 133-142.
Jorgensen, R.B. and Bothmer, R. (1988). Haploids of Hordeum vulgare and H. marinum from crosses between the two species. Hereditas 108: 207-212.
Katsiotis, A., Hagidimitriou, M. and Heslop-Harrison, J.S. (1997). The close relationship between the A and B genomes in Avena L. (Poaceae) - Determined by molecular cytogenetic analysis of total genomic, tandemly and dispersed repetitive DNA sequences. Ann. Bot. 79: 103-109.
Kodoru, P.R.K. and Rao, M.K. (1981). Cytogenetics of synaptic mutants in higher plants. Theor. Appl. Genet. 59: 197-214.
Leggett, J.M. (1984). Morphology and metaphase chromosome pairing in three Avena hybrids. Can. J. Genet. Cytol. 26: 641-645.
McMullen, M.S., Phillips, R.L. and Stuthman, D.D. (1982). Meiotic irregularities in Avena sativa L./A. sterilis L. hybrids and breeding implications. Crop Sci. 22: 890-897.
Pijnacker, L.P., Ferwerda, M.A., Puite, K.J. and Schaart, J.G. (1989). Chromosome elimination and mutation in tetraploid somatic hybrids of Solanum tuberosum and Solanum phureja. Plant Cell Rep. 8: 82-85.
Scoles, G.J. and Kaltsikes, P.J. (1974). The cytology and cytogenetics of Triticale. Z. Pflanzenzuchtg. 73: 13-43.
Singh, R.J. (1993). Plant Cytogenetics CRC Press, Boca Raton.
Sundberg, E. and Glimelius, K. (1991). Effects of parental ploidy and genetic divergence on chromosome elimination and chloroplast segregation in somatic hydrids within Brassicaceae. Theor. Appl. Genet. 83: 81-88.

Publication Dates

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

History

Received
05 June 2000

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

[1] Adamowski, E.V., Pagliarini, M.S. and Batista, L.A.R. (1998). Chromosome elimination in Paspalum subciliatum (Notata group). Sex. Plant Reprod 11: 272-276.

[2] Davies, D.R. (1974). Chromosome elimination in inter-specific hybrids. Heredity 32: 267-270.

[3] Forsberg, R.A. (1990). The use of monosomic alien substitution lines in interploidy gene transfer in Avena. Bulgar. J. Biotech 4: 27-30.

[4] Guillin, E., Poggio, L. and Naranjo, C.A. (1995). Meiotic irregularities in Argentinian hexaploid oats. Cytologia 60: 211-215.

[5] Gupta, S.B. (1969). Duration of mitotic cycle and regulation of DNA replication in Nicotiana plumbaginifolia and a hybrid derivative of N. tabacum showing chromosome instability. Can. J. Genet. Cytol. 11: 133-142.

[6] Jorgensen, R.B. and Bothmer, R. (1988). Haploids of Hordeum vulgare and H. marinum from crosses between the two species. Hereditas 108: 207-212.

[7] Katsiotis, A., Hagidimitriou, M. and Heslop-Harrison, J.S. (1997). The close relationship between the A and B genomes in Avena L. (Poaceae) - Determined by molecular cytogenetic analysis of total genomic, tandemly and dispersed repetitive DNA sequences. Ann. Bot. 79: 103-109.

[8] Kodoru, P.R.K. and Rao, M.K. (1981). Cytogenetics of synaptic mutants in higher plants. Theor. Appl. Genet. 59: 197-214.

[9] Leggett, J.M. (1984). Morphology and metaphase chromosome pairing in three Avena hybrids. Can. J. Genet. Cytol. 26: 641-645.

[10] McMullen, M.S., Phillips, R.L. and Stuthman, D.D. (1982). Meiotic irregularities in Avena sativa L./A. sterilis L. hybrids and breeding implications. Crop Sci. 22: 890-897.

[11] Pijnacker, L.P., Ferwerda, M.A., Puite, K.J. and Schaart, J.G. (1989). Chromosome elimination and mutation in tetraploid somatic hybrids of Solanum tuberosum and Solanum phureja. Plant Cell Rep. 8: 82-85.

[12] Scoles, G.J. and Kaltsikes, P.J. (1974). The cytology and cytogenetics of Triticale. Z. Pflanzenzuchtg. 73: 13-43.

[13] Singh, R.J. (1993). Plant Cytogenetics CRC Press, Boca Raton.

[14] Sundberg, E. and Glimelius, K. (1991). Effects of parental ploidy and genetic divergence on chromosome elimination and chloroplast segregation in somatic hydrids within Brassicaceae. Theor. Appl. Genet. 83: 81-88.