DHIA BOUKTILA¹, MAHA MEZGHANI², MOHAMED MAKNI³ and HANEM MAKNI⁴

¹ Associate Professor at the Higher Institute of Biotechnology of Béja (Tunisia), Post-Doc Researcher at the Laboratory of Molecular Genetics, Immunology and Biotechnology - Faculty of Sciences of Tunis (Tunisia). dhia_bouktila2000@yahoo.fr. Author for correspondance.

² Associate Professor at the Faculty of Sciences of Tunis (Tunisia), Post-Doc Researcher at the Laboratory of Molecular Genetics, Immunology and Biotechnology - Faculty of Sciences of Tunis (Tunisia).

³ Professor at the Faculty of Sciences of Tunis (Tunisia), Research Director at the Laboratory of Molecular Genetics, Immunology and Biotechnology - Faculty of Sciences of Tunis (Tunisia).

⁴ Professor at the Higher Institute of Animation for Youth and Culture of Bir El Bey (Tunisia), Research Director at the Laboratory of Molecular Genetics, Immunology and Biotechnology - Faculty of Sciences of Tunis (Tunisia).

Received: 5-apr-09 - Accepted: 25-sep-09

In North Africa, the genus Mayetiola includes two phytophagous species, namely the Hessian fly Mayetiola destructor (Say, 1817) and the barley stem gall midge Mayetiola hordei (Kieffer, 1909) (Gagne et al. 1991). In the southern arid regions of Tunisia, barley is infested by M. hordei, whereas in the northern sub-humid regions, the highest infestations occur on wheat and to a lesser extent on barley, by M. destructor.

In order to establish a controlling strategy based on the development of cereal varieties genetically resistant to Mayetiola, the insect populations occurring on wheat and barley in Tunisia should be studied in regard to taxonomical identity and divergence. In this context, there have been several morphological, biochemical and molecular assays trying to confirm the existence of two groups of reproductively isolated individuals corresponding to M. destructor and M. hordei. Morphologically, the two phytophageous species of Mayetiola can be hardly distinguished, but Gagne et al. (1991), using scanning electron microscopy, reported differences in the shape of the female postabdomen, the structure of male terminalia and the number of spicules covering the puparium. At the biochemical level, Makni et al. (2000) identified allozyme markers of taxonomic value for the two species. Molecular markers allowing an efficient and rapid distinction between the two species of Mayetiola were developed by Mezghani et al. (2002a), on the basis of Restriction Fragment Length Polymorphism (RFLP) of the cytochrome bgene. Although these approaches can be simple and reliable, inferences regarding taxonomical specificity, genetic structure and species divergence need to be further consolidated by conducting a cytogenetical analysis.

Only the Hessian fly M. destructor from the USA populations was karyotyped (Stuart and Hatchett 1988) and the authors found that female somatic cells have two pairs of autosomes and two pairs of sex chromosomes (2n = 8), while male somatic cells have two pairs of autosomes and two monosomic sex chromosomes (2n – 2 = 6). The complexity of the Hessian fly karyotype is also manifested by the presence of two distinct chromosome classes: eliminated (E) chromosomes and somatic (S) chromosomes (Lobo et al. 2006). Indeed, just after the sperm and ovules combine, each zygote contains a diploid set of S chromosomes and 30-40 E chromosomes (A1 A2 X1 X2 / A1 A2 X1 X2 + E). The E chromosomes are eliminated from the presumptive somatic nuclei during the fifth nuclear division of embryogenesis. During that division, the paternallyderived X1 and X2 chromosomes may also be eliminated from the somatic nuclei. If they are retained, the somatic cells have a female karyotype (A1 A2 X1 X2 / A1 A2 X1 X2). If they are eliminated, the somatic cells have a male karyotype (A1 A2 X1 X2 / A1 A2 O O).

The objective of the present study was to analyse for the first time the structure of the karyotype of M. hordei from Tunisia and compare it with Tunisian samples of M. destructor and with the relevant literature. Karylogical results are used to discuss genetic mechanisms underlying divergence of Mayetiola species.

M. destructor and M. hordei flies used in this study were at third-instar and adult stages. Specimens of M. destructor were collected from wheat plants located in north Tunisia (Jédéida and Goubellat cities), whereas those of M. hordei were collected from barley plants in the southern region of Gabès. Species and sex of these samples were identified on the basis of morphological characteristics (Gagne et al. 1991) and diagnostic alleles at the Pgi and Mdh2 loci (Makni et al. 2000).

Polytene chromosome preparations were made from salivary glands of third-instar larvae. Salivary glands were dissociated, treated by acetic acid (45%) for 1 min, then fixed in a solution of acetic acid : lactic acid : water (1:2:3 ratio). The material was stained with 1% lacto-aceto-orcein for 15 min and squashed (Ashburner 1967).

The fixed tissues were transferred to a drop of 60% acetic acid on a clean slide. Finally, the slide was placed on a warm hot-plate (45°C) and the drop allowed evaporation. The prepared slides were stained with 3% Giemsa in phosphate buffer (pH 6.8) for 17 min. Slides for C-banding were treated according to the technique described by Sumner (1972) with minor modifications. Twenty individuals of each M. destructor and M. Hordei, four females, and six males each were successfully karyotyped. Preparations with clear and welldistributed chromosomes were examined under a light microscope “Zeiss 63” equipped with a JVC TK-1270 colour video camera and Image Grabber, then processed with Adobe Photoshop.

Mayetiola destructor karyotype. Four polytene chromosomes A1, A2, X1 and X2 were easily recognized in M. destructor females where they had an identifiable structure, as described by Stuart and Hatchett (1988). In males, only autosomes were recognized, whereas sex chromosomes had a diffused structure (Fig 1A). The observation of mitotic chromosomes showed a sexual chromosomal dimorphism within M. destructor samples. Female somatic cells have two pairs of autosomes and two pairs of sex chromosomes (2n = 8), whereas male somatic cells have two pairs of autosomes and two monosomic sex chromosomes (2n – 2 = 6) (Fig. 1B).

Mayetiola hordei karyotype. The salivary glands of M. hordei contained about 100 round-shaped cells. Only a few basal cells contained polytene chromosomes. In all preparations, polytene chromosomes of M. hordei were characterized by a smaller size, than those observed from Tunisian samples of M. destructor (Fig. 1C). The mitotic karyotype of M. hordei exhibited a sexual chromosomal dimorphism in chromosome number. Somatic testicular cells contained six chromosomes (2n – 2 = 6), wheareas eight chromosomes were present in somatic ovarian cells of larvae (2n = 8). That indicated a similarity with the mitotic karyotype of M. destructor (Fig. 1D). Metaphase cells showed two metacentric autosomal pairs in both sexes. The sexual chromosomes X1 and X2, disomic in females and monosomic in males, were also metacentric. For all chromosomes, the C-banding pattern showed a heterochromatic region that extended from the centromere, indicating that heterochromatin is mainly localized in the pericentromeric regions (Fig. 1E). Spermatogonial and oogonial meioses of M. hordei showed that the behaviour of chromosomes at all stages of meiotic divisions was similar to that described by Stuart and Hatchett (1988) (Fig. 1F).

Many previous investigations were reported on the cytogenetics of insect species from different orders such as Hymenoptera (Rousselet et al. 2000), Orthoptera (Turkoglu and Coka 2002) or Diptera (Campos et al. 2007). In many cases, such studies contributed to the distinction between species with little morphological and behavioural variation (Rousselet et al. 1998). Concerning the two species, M. destructor and M. hordei, only the karyotype of M. destructor from the USA has been studied (Stuart and Hatchett 1988). The present note is the first report on the karyotype of M. hordei, in comparison with that of M. destructor. Concerning the number of chromosomes, our data demonstrate that in the two species, the karyotype was numerically stable. As the Mayetiola genus is characterized by low chromosome numbers, interspecific polymorphisms in number may be rare, in contrast with some insect genera with high chromosome numbers, where polymorphisms in chromosome numbers have been reported (Rousselet et al. 1998).

Chromosomal sexual dimorphism was also similar to that observed in M. destructor samples, indicating that sex in M. hordei was determined, as well as in other Cecidomyiidae species that have been examined cytologically (White 1973), by a sex chromosome to autosome balance system with two X chromosomes. The similarity between M. hordei and M. destructor in chromosome morphology indicates that the breaking of gene flow between two groups of Mayetiola, belonging initially to the same species (Mezghani et al. 2002b), may have resulted in independent accumulation of genic (non chromosomal) mutations in the two new species. This hypothesis is supported by the genic variability of both Mayetiola species, with regard to the cytochrome b, ITS1 and ITS2 genes (Mezghani et al. 2002a, 2002b). Nevertheless, the speciation process may also have been accompanied by chromosomal fusion or translocation, not affecting the number of chromosomes. Indeed, in the Drosophila melanogaster (Meigen, 1810) species complex, chromosomal variation was reported between two morphologically similar species, D. yakuba (Burla, 1954) and D. teissieri (Tsacas, 1971). Even though the karyotypes of these species were similar, the study of the puffing activities of polytene chromosomes revealed para- and pericentric inversions, enabling the establishment of their phylogeny (Ashburner and Lemeunier 1972). We, therefore, think that further cytogenetic analyses that would encompass In situ hybridization (ISH) and puffing activities will be needed in order to better understand the genetic mechanisms underlying divergence of Mayetiola species. The present study showed similarity between M. destructor and M. hordei in chromosome number, shape and sex chromosomal dimorphism, implying the absence of chromosome fission, amplification or polyploidization (Rousselet et al. 1998). Finally, polytene chromosomes of M. hordei were characterized by a smaller size, than those observed from Tunisian samples of M. destructor. This could be explained by a difference in the degree of polytenization or in gene transcriptional activity between both species (Lemeunier 1973).

This work is dedicated to the memory of late Prof. Mohamed MARRAKCHI. We gratefully acknowledge Françoise LEMEUNIER (Centre National de la Recherche Scientifique Gif-sur-Yvette, France) for her technical assistance and Abderrazzak DAALOUL, Secretary of State to the Minister of Agriculture and Water Resources in charge of Hydraulic Resources and Fishing (Tunisia) for his constant support. We address special thanks to the referees who have reviewed this work for “Revista Colombiana de Entomologia”.

ASHBURNER, M. 1967. Gene activity dependent on chromosome synapsis in the polytene chromosomes of Drosophila melanogaster. Nature 214: 1159-1160.        [ Links ]

ASHBURNER, M.; LEMEUNIER, F. 1972. Patterns of puffing activity in the salivary gland of Drosophila. Homology of puffing patterns on chromosome arm 3L in D. melanogaster and D. yakuba, with notes on puffing in D. teissieri. Chromosoma 38: 283-295.        [ Links ]

CAMPOS, S. R. C.; RIEGER, T. T.; SANTOS, J. F. 2007. Homology of polytene elements between Drosophila and Zaprionus determined by in situ hybridization in Zaprionus indianus. Genetics and Molecular Research 6: 262-276.        [ Links ]

GAGNE, R. J.; HATCHETT, J. H.; LHALOUI, S.; EL-BOUHSSINI, M. 1991. Hessian fly and barley stem gall midge, two different species of Mayetiola (Diptera: Cecidomyiidae) in Morocco. Annals of the Entomological Society of America 84: 436-443.        [ Links ]

GUEST, W. C.; HSU, T. C. 1973. A new technique for preparing Drosophila neuroblast chromosomes. Drosophila Information Service 50: 193-194.        [ Links ]

LEMEUNIER, F. 1973. Les chromosomes polyténiques dans le genre Drosophila. Année biologique. Tome XII. Fascicules 11-12. p 565-578.        [ Links ]

LOBO, N. F.; BEHURA, S. K.; AGGARWAL, R.; CHEN, M.; COLLINS, F. H.; STUART, J. J. 2006. Genomic analysis of a 1 Mb region near the telomere of Hessian fly chromosome X2 and avirulence gene vH13. BMC Genomics 7: 7.        [ Links ]

MAKNI, H.; MARRAKCHI, M.; PASTEUR, N. 2000. Biochemical characterization of sibling species of Mayetiola (Diptera: Cecidomyiidae). Biochemical Systematics and Ecology 28: 101-109.        [ Links ]

MEZGHANI, K. M.; MAKNI, H.; MARRAKCHI, M. 2002a. Identification par PCR-RFLP de marqueurs mitochondriaux chez deux espèces de Mayetiola (Diptera: Cecidomyiidae) nuisibles aux cultures de céréales. Annales de la Société d'Entomologie de France 38: 277-282.        [ Links ]

MEZGHANI, K. M.; MAKNI, H.; PASTEUR, N.; NAVAJAS, M.; MARRAKCHI, M. 2002b. Species distinction and population structure in Mayetiola species (Diptera: Cecidomyiidae) based on nuclear and mitochondrial sequences. International Journal of Dipterological Research 13: 93-107.        [ Links ]

ROUSSELET, J.; GERI, C.; HEWITTS, G. M.; LEMEUNIER, F. 1998. The chromosomes of Diprion pini and D. similis (Hymenoptera: Diprionidae): implications for karyotype evolution. Heredity 81: 573-578.        [ Links ]

ROUSSELET, J.; MONTI, L.; AUGER-ROZENBERG, M. A.; PARKER, J. S.; LEMEUNIER, F. 2000. Chromosome fission associated with growth of ribosomal DNA in Neodiprion abietis (Hymenoptera: Diprionidae). Proceedings of the Royal Society of London B 267: 1819-1823.        [ Links ]

STUART, J. J.; HATCHETT, J. H. 1988. Cytogenetics of the Hessian fly: I. Mitotic karyotype analysis and polytene chromosome correlations. Journal of Heredity 79: 184-189.        [ Links ]

SUMNER, A. T. 1972. A Simple technique for demonstrating centromere heterochromatin. Experimental Cell Research 75: 304-306.        [ Links ]

TURKOGLU, S.; COKA, S. 2002. Chromosomes of Oedipoda schochi schochi and Acrotylus insbricus (Orthoptera, Acrididae, Oedipodinae). Karyotypes and C- and G-band Patterns. Turkish Journal of Zoology 26: 327-332.        [ Links ]

WHITE, M. J. D. 1973. Animal cytology and evolution. 3^rd ed. Cambridge University Press, London. 542 p.        [ Links ] ]]> 1967 214 1159-1160 1972 38 283-295 2007 6 262-276 1991 84 436-443 1973 50 193-194 1973 565-578 2006 7 7 2000 28 101-109 2002 38 277-282 2002 13 93-107 1998 81 573-578 2000 267 1819-1823 1988 79 184-189 1972 75 304-306 2002 26 327-332 1973 3 542