Research Article
Karyological Studies on Some Wild Species of Family Cruciferae in Egypt
Department of Botany, Faculty of Science, Mansoura University, El-Mansoura, Egypt
Cytological characters, including chromosome number and karyotype analysis have been considered as reliable guides in studies of taxonomic and evolutionary relationships by many authors (Davis and Heywood, 1963; Moore, 1968 and Stace, 1980). A range of examples has been reviewed by Moore (1968), Stace (1980) and Elkington (1984) showing that chromosome studies, especially when combined with hybridization and genetic analysis, have provided essential clues in tracing the origin and the evolutionary history of plant species. The number, size and shape of chromosomes were used to characterize the karyotypes of plants and define the taxonomic differences between them.
In Cruciferae, in particular the cytology of a number of genera have been studied in detail, leading to a much clearer understanding of their variation patterns, for example Cochlearia (Gill, 1965; 1976; Gill et al., 1978), Brassica (Stebbins, 1971 and Harberd, 1972, 1976) and Matthiola.
Chromosomal morphology is usually studied on the basis of the position of the primary constriction (centromere or kinetochore) (Battaglia, 1955; Huziwara, 1958; Levan et al., 1964 and Adhikary, 1974). A modification of all the previous systems was proposed by Abraham and Prasad (1983). In this system four fixed points and six intermediate regions are recognized in each chromosome segment. Thus according to this last system, the chromosomes can be labeled effectively and it can be successfully used in determining the karyotype more precisely than other systems.
The present study is carried out on some Cruciferous taxa. The objectives of this work are to standardize the cytological analysis of mitotic chromosomes, construct karyotypes of the species and to reveal the types of mitotic irregularities if present and their frequencies in Cruciferae taxa.
The present study was carried out on some Cruciferous taxa. These are Cakile maritima Scop. ssp. aegyptiaca (Willd.) Nyman and Erucaria hispanica (L.) Druce within tribe Brassiceae, Eremobium aegyptiacum (Spreng.) Schweinf. Et Asch. ex Bioss in tribe Hesperideae, Matthiola arabica Boiss, M. livida (Del.) DC. and M. longipetala (Vent.) DC. in tribe Matthioleae.
For Matthiola longipetala and Erucaria hispanica the materials were collected from barley fields of Burg-El-Arab in Alexandria, while Matthiola livida and Eremobium aegyptiacum from Cairo-Suez desert road, El-Salhia Ismalia and Belbies desert. The specimens of Matthiola arabica were collected from rocky mountains in Sant-Kathrin (Sinai). Finally, Cakile maritima specimens were collected from three different localities namely: coastal salt marshes of Burg Rashid, Baltim and Alexandria.
Seeds of the taxa were collected at the fruiting time. Germination at 17-20°C was found to give the highest germination percentage.
Root tips 1-1.5 cm long were collected, pre-treated with 0.002 μ of 8-hydroxyquinoline (Tjio and Levan, 1950) for 2-4 hours for karyotype analysis. However for the analysis of mitotic chromosomal aberrations root tips were not pre-treated.
Different staining techniques were tried like, 2% aceto-orcein (La Cour, 1941) and 2% aceto-orcein after acid treatment (Chattopadhyay and Sharma, 1988). It was found that aceto-orcein stain after acid treatment gave the best results.
Well spread metaphase plates were selected and photographed. The negatives were developed, magnified using a photo enlarger and the image was projected onto a flat table surface. By careful focussing a sharp image obtained and Karyograms were drawn, lengths of long arm (L) and short arm (S) were measured for karyotype analysis.
Types of chromosomes were identified and classified according to Abraham and Prasad (1983). The total form percent (TF%) i.e. the average degree of symmetry over the whole karyotype was calculated according to Huziwara (1962).
All the taxa under study were diploid. In the analyzed species, 10, 12, 14, 16, 18 and 20 chromosomes were observed in somatic cells (Plate 1).
Karyotype analyses include chromosome number, arm ratio, total complement length as well as karyotype formula carried out for all the taxa under study, data is summarized (Table 1). In case of Eremobium aegyptiacum the very small apparent size of the chromosomes did not permit a detailed study of their morphology. Karyograms of the species were illustrated (Plates 2 & 3). The types and proportions of abnormalities observed at mitotic division are summarized and shown (Table 2, Plate 1), respectively.
Genera and species examined in this study were diploid. No polyploidy were encountered in different investigated taxa. Some taxa under study were characterized by more than one chromosomal number.
Plate 1: | Somatic chromosomes of : (A) Cakile maritima (Alexandria), (B) Rashid, (C) Baltim, (D) Eremobium aegyptiacum (2n=18), (E) 2n=20, (F) Erucaria hispanica 2n=14, (G) 2n=16, (H) Mathiola arabica, (I) M. livida (2n=10), (J) 2n=12 and (K) M. longipetala; (L,N,R) Bridge in anaphase stage, (M,Q) laggard chromosome (O) stickiness and (P) Irregular distribution of chromosomes. (X = 1700) |
Table 1: | Chromosome data for all the species examined (somatic chromosome number, average size, TF%, total complement length and karyotype formulae) |
Table 2: | Mitotic abnormalities observed in species of Matthiola studied |
Plate 2: | Karyograms of: (A) Cakile maritima (Rashid), (B) Baltim, (C) Alexandria, (D) Erucaria hispanica 2n = 14 and (E) E. hisponica 2n = 16 |
This phenomenon is not rare in the family Cruciferae since in the genus Erysimum which is closely related to the genus Matthiola n = 6, 7, 8, 9, 10, 11 and 13 were reported by Favargel and Goodhue (1977). Also Bocher (1966) and Mulligan (1971 and 1974) reported dibasic number of n = 6 and 7 in the genus Draba.
The cytological features of the three studied species of Matthiola showed three basic numbers of n = 5, 6 and 7. Earlier studies of chromosome number of the genus Matthiola showed that the majority of the species have n = 6 or 7 (Renzoni, 1969; Larsen and Lagaard, 1971; Sharma and Sikka, 1976; Kuzmanov and Jurukova, 1977 and Soliman and Parker, 1986). Matthiola arabica with 2n = 14 and M. livida with 2n = 10 and 12 are reported for the first time in the present study. M. longipetala in the present study has 2n = 12. Most previous records reported 2n = 14 (Kuzmanov and Jurukova, 1977; Al-Shehbaz and Al-Omar, 1982) whereas it is reported 2n = 12 which is confirmed by this investigation.
Plate 3: | Karyograms of: (A) Matthiola arabica, (B) M. livida (2n = 10), (C) M. livida 2n = 12 and (D) M. longipetala |
Cakile maritima has 2n= 18. This chromosome number had already been investigated (Delay and Petit, 1971; Strid, 1971; Gadella and Kliphis, 1973; Vanloon, 1974 and Engelskjon, 1979). For Erucaria hispanica two chromosome numbers were recorded, namely 2n = 14 and 16. The former (2n = 14) is a new record for this species while 2n = 16 was previously reported by Harberd (1972), Sharma and Sikka (1976).
Eremobium aegyptiacum characterized by tiny chromosomes had n = 9 and 10 (reported here for the first time). Rodman (1978) found that n = 13 which don't agree with our results. The observed variation in chromosome number as compared with other records may be due to two factors: firstly, different phytochoria and secondly, chromosomal structural alterations that might have taken place during speciation.
Different dibasic chromosome numbers reported in this study in the same root tip has been observed previously in Sorghum purpeurosericeum (Darlington and Thomas, 1941); Haplopappus gracilis (Ostergren and Frost, 1962), Oryza (Sampath, 1950) and in Hymencollis calathenum (Snoad, 1955).
Karyotype analysis of the taxa in this study was recorded for the first time except that of M. longipetala which has been studied earlier but on Russian and British accessions. Karyotypic differences were observed between M. arabica, M. livida and M. longipetala with regard to chromosomal morphology and chromosomal length. The chromosomes of M. arabica falls in 5 groups: metacentric, nearly metacentric, nearly submetacentric (-), nearly submetacentric (+) and nearly subtelocentric (-) types whereas M. livida had 3 groups of chromosomes: metacentric, nearly metacentric and nearly submetacentric (-) groups. In case of M. longipetala the types of chromosomes appeared to be metacentric, nearly metacentric, nearly submetacentric (-) and nearly submetacentric (+) (Table 1). Also the length of chromosomes showed considerable differences where the total complement length varied from 15.66 to 11.37 μm, with M. livida showing the lowest value. Not only the chromosomal morphology was variable but also the arm ratio exhibited a considerable variation in Matthiola ranging from 4.25 to 1.00. Similar results have been reported in other plant species, Pederick (1970) found differences in the chromosome lengths between karyotypes of different species of Pinus and considered length differences to be due were the accumulation of small duplications. In Amaranthus, Madhusoodanan and Nazeer (1983) and in Hebenari, Kashyap and Mehra (1983) have shown that variation in chromatin length as well as in the karyotypic formulae is indicative of structural chromosomal alterations in the form of repatterning and chromatic deletions or additions. Ved Brat (1965) reported that inversions have been the main cause for karyotype differentiation in the whole genus Allium. Numerous studies have reported that variation in mitotic chromosomes may have originated either by translocation or by pericentric inversions or both, for example: Crotalaria (Chennaveeraiah and Patil, 1973), Blumea (Matthew and Matthew, 1982), Ornithogalum (Vosa, 1983), Monochoria (Christopher, 1983), on Australian grass species (Jadhav et al., 1983) and Guizotia (Patel et al., 1983). There is therefore a strong probability that similar forces have been operative in Matthiola.
Karyotypic variations exist not only between different species but also within the same species with different base numbers, thus in Erucaria hispanica it is obvious that the most conspicuous karyological difference between 16 and 14 cells is the addition of two nearly metacentric chromosomes. Cells with 2n = 16 had 2 metacentric, 6 nearly metacentric, 6 nearly submetacentric (-) and 2 nearly submetacentric (+), while cells having 2n = 14 had 2 metacentric, 4 nearly metacentric, 6 nearly submetacentric (-) and 2 nearly submetacentric (+). The total complement length varied from 8.54 (2n = 14) to 10.18 μm (2n = 16). In M. livida there was an addition of a pair of chromosomes in nearly submetacentric (-) group in the cells with 2n = 12 where they have 2 metacentric, 4 nearly metacentric and 6 nearly submetacentric (-) chromosomes whereas the cells with 10 chromosomes have 2 metacentric, 4 nearly metacentric and 4 nearly submetacentric (-) chromosomes. The total complement length varied from 11.37 to 11.77 μm. Some chromosomal aberrations that are important tools in bringing about variation in chromosomal number may as well play a role in inducing such difference in chromosomal morphology.
Also, interpopulation differences were observed among Cakile maritima from three different areas. The total complement length varied from 10.61 to 12.70 μm. With those plants from Rashid showing the lowest value the karyotype formulae were to some extent different. Specimens from both Rashid and Alexandria were similar in the karyotype classes (three classes) with different chromosome number in each class. Also they were similar in having the longest chromosome being nearly submetacentric (-). Meanwhile, Baltim specimens have four chromosome classes as well as the longest chromosome being nearly metacentric. This karyologic differences within different cytotypes of the same species have been observed previously in some species such as Amaryllis balladonna (Guha, 1979) and Astragalus (Ashraf & Gohil, 1988).
The karyotype formulae of the studied species revealed that all of them had symmetrical karyotype except in M. arabica where nearly subtelocentric (-) chromosomes appeared and thus gave the asymmetric affinity. Stebbins (1971) has stated that one of the basic features which bring about karyotype asymmetry is shifting of the centromere from median to sub-median and subterminal position and it has been considered as a progressive step in karyotype evolution. Taxa with asymmetric karyotype tend to have low TF% (Huziwara, 1962). Therefore, M. arabica can be presumed to have more asymmetrical karyotype than other two species of Matthiola. The growth habit of M. arabica (perennial) confirms this suggestion since Sveshnikovas'work (1927) on Vicia species revealed that in the section Cracca of Vicia in which both annuals and perennials occur; the annuals have a more symmetric karyotype than the perennials.
In this study Matthiola species showed the mitotic chromatin bridge, irregular distribution of chromosomes, stickiness and laggards. This mitotic irregular chromosome behaviour had been reported in other plants where during the study of karyotype and meiosis of Aloe vera (Vig, 1968). Such abnormalities have been known to arise from abnormal metaphase spindle (Varaama, 1949). On the other hand, in study of mitosis in Aloe aristata (Brandham, 1970), bridges and fragment were extremely rare but the existence of them at mitosis confirms that some sort (U-type) of chromatid exchanges at meiosis can be due to breakage and reunion between sister chromatids.