Research Article
Cytogenetic Effects of Some Fungicides on Barley Root Tip Meristem Cells
Department of Biology, Faculty of Art and Science, Adnan Menderes University, 09010 Aydin Turkey
Pesticides have some hazardous effects in addition to their benefits. Their undesirable residues in water, food and in environment may cause health problems. Pesticides may also be effective to chance plant genetic system as a result of their mutagenicity (Aokin and Sümer, 1996; Badr, 1988; Bilalolu, 1984; Bilalolu and Ozorgueu, 1988).
A number of studies aiming to explain and to understand effects of fungicides in plant are present in literature. Rayburn et al. (1993) stated out that amount of nuclear DNA is decreased by the fungicide, Captan. This fungicide has carcinogenic, mutagenic and teratogenic effects on many organisms. Its highest effects on nucleic acids are due to DNA synthesis inhibition and activity decrease of DNA-polymerase B.
Pusztai (1993) used two fungicides in his experiments, Vitavax and Topsin-Methyl 70 WP. He examined the differences in chlorophyll mutation frequency and cytogenetic effects of fungicides on barley. He found deviations on chromatids and chromosomes types after metaphase observations on barley seed root tip cells. An increase which depends on application time intervals was also found. Similar results were found by Samashekar and Gowda (1984) in Allium cepa root tip cells using Vitavax that can cause deviations in mitotic index and mitosis. They stated out that, the most important effects were mito-depressive behaviour in the lowest concentration and total disappearance of mitosis by prophase inhibition in higher concentrations (mitostatic effects). Vitavax caused chromosome breakes, gaps, chromosome and chromatid changes, lagging chromosomes, chromosome bridges and as a result of disappearance of spindle fiber disorders. As a result of inhibited cytoplasmic division, fragmented nuclei and polynucleotide cells were also observed.
It is stated that, two different fungicide (Nimrod and Ribigon-4) causing chromosomal deviations on the root tip cells of Vicia faba, had genotoxic effects (Shahin and El Amoodi, 1991). Different application times and different concentrations were used for each fungicides. Chromosomal deviations and numerical chromosomal deviations were found. It was also reported that cells with 2 nucleus, c-metaphases, sticky chromosomes, polyploid cells and lagging chromosomes were formed depending on drastical changes in number of chromosomes. Depending on the increase of application time, there was a remarkable increase in deviations by comprising with control group.
Hemavathy and Krisnamurty (1988) examined cytogenic effects of Cuman L (containing dithiocarbamate) on albino male mices bone marrow erythrocytes. They found a remarkable increase in univalent and polyploidy, an increase in micronucleus frequency. In their experiment, no translocations in both control and treated groups were observed.
Decreasing effects of fungicides on barley meristem root tip cells in terms of frequency were also reported (Sharma et al., 1983). Researchers explained the decrease of chiasma frequency by fungicide use. In another report, chromosomal breakes, lagging chromosomes and micronuclei in Allium cepa L. root tip meristematic cells had been shown (Samashekar and Gowda, 1984).
Derosal 50 WP and Korsikol 18 Dust are widely used seed pesticides having fungicide characteristics. In this study, we aimed to examine the effects of these pesticides on mitotic activity and chromosomes in barley root tip meristem cells.
Barley seeds (Hordeum vulgare L.) were purchased from Eskişehir Agricultural Research Instıtute. These seeds were treated with Korsikol 18 Dust (pentachloronitrobenzene) and Derosal 50 Wp (carbendazim-methylbenzimidazole-2yl-carbamate), having fungicide characteristics. 100, 200 and 300 ppm concentrations of these substances were prepared with distilled water. Distilled water was also used as control. These concentrations were selected according to their uses in agriculture.
Fifity barley seeds were selected for each applications and they were taken into fungicide solutions for 6, 12 and 24 h. At the end of the application period, seeds were washed with tap water for 5-10 min and taken on to the dryer paper. Barley seeds treated with fungicide were transferred to the petri dishes having dryer papers on both inner sides under optimum temperature (18-20°C) for germination. Seed root tips in 1.5-2 cm length were fixed using farmer fixative (3:1 ethyl alcohol: glacial acetic acid). Root tips were squashed in aceto-orcein and examined microscopically for Mitotic Index (MI) and chromosomal aberrations. Chromosomal aberrations were determined by scoring cells with fragments, non- separated chromosomes, mis-polarized chromosomes in randomly picked 3 zones per slide. For each group of concentrations and control, the mean values were calculated. In order to determinate the significance among the means, Independent Samples t-test was applied (p<0.05).
Korsikol 18 Dust and Derosal 50 WP, which were applied to the barley seeds, depending on concentration and application time were found to have effects on cell division.
In the Derosal applied seeds, no significant changes in the frequency of dividing cells were occurred (Table 1). Mitotic index values in Table 1, also reflect the same situation. Korsikol 18 Dust application also effected dividing cell ratio depending on concentration and application time. While dividing cell ratio was decreased with concentrations of the fungicide between 100 and 200 ppm, it was increased in 300 ppm (Table 2). Interestingly, application of Derosal decreased chromosomal breakes in comparison of the control.
Table 1: | Effect of Derosal treatment on the mitotic index and chromosome aberrations in the root tip meristem cells in Hordeum vulgare L. |
D-1-1: Derosal-100 ppm-6 h, D-1-2: Derosal-100 ppm-12 h, D-1-3: Derosal-100 ppm-24 h, D-2-1: Derosal-200 ppm-6 h, D-2-2: Derosal-200 ppm-12 h, D-2-3: Derosal-200 ppm-24 h, D-3-1: Derosal-300 ppm-6 h, D-3-2: Derosal-300 ppm-12 h, D-3-3: Derosal-300 ppm-24 h |
Table 2: | Effect of Korsikol treatment on the mitotic index and chromosome aberrations in the root tip meristem cells in Hordeum vulgare L. |
K-1-1: Korsikol-100 ppm-6 h, K-1-2: Korsikol-100 ppm-12 h, K-1-3: Korsikol-100 ppm-24 h, K-2-1: Korsikol-200 ppm-6 h, K-2-2: Korsikol-200 ppm-12 h, K-2-3: Korsikol-200 ppm-24 h, K-3-1: Korsikol-300 ppm-6 h, K-3-2: Korsikol-300 ppm-12 h, K-3-3: Korsikol-300 ppm-24 h |
The highest increase in chromosomal breakes were obtained from the application of 300 ppm for 24 h. Korsikol had an increasing effect on chromosomal breakes in every dosage and time. Korsikol was more effective in bridge formation than Derosal.
In stickness of chromosomes, no correlation was observed between different doses and time intervals of Derosal. For example, 300 ppm for 24 h was the most. effective dose. Korsikol application increased chromosomal stickness independently from dose and time.
Mispolarization was observed in Derosal 50 WP and Korsikol 18 Dust application. It was not depended on application doses but it seems to be depended on application time
In other doses, there were no correlation. In all Korsikol applications, when compared with the control group except 100 ppm application, an increase of mis-polarization was investigated. It can be stated out that both Derosal 50 WP and Korsikol 18 Dust applications are effective on chromosomal behaviour. This effect is significant in p<0.05.
Fungicides used in these experiments, have different effects on cell division and chromosomes changes.
When Derosal 50 WP applied to barley seeds in different doses and times, no effect was obtained on cell division when compared with control group. In Korsikol 18 Dust applications, similar results were also observed, except 300 ppm application for 24 h, which increased the rate of dividing cells. Mitotic index values also supported these results.
Many researchers, reported that different pesticides effect mitotic activity and cause mitotic deviations. For example, Samashekar and Gowda (1984), stated that Vitavax causes mito-depressive behaviour in Allium cepa L. root tip cells treated with lowest concentration and prophase inhibition in the highest concentration, it causes inhibition of mitosis (mitotic effect).
Derosal and Korsikol changed chromosome structure and chromosomal behaviour depending on applied concentrations and time. Structural and behavioral changes observed in chromosomes were; fragments, chromosome bridges, mis-polarizations and sticky chromosomes.
Pusztai and Vegh (1978) observed that two fungicides called Topsin-methyl 70 SWP and Vitavax cause chromatid and chromosome aberrations in barleys root tip cells. He also found that Vitavax cause chromosome breakes, gaps, chromatidal deviations, lagging chromosomes and chromosome bridges depending on both disappearance of spindle fiber and some irregularities during cell division (Hemavathy and Krıshnamurthy, 1988). Also, many other researchers reported similar results, regarding with fungicide application (Rayburn et al., 1993; Shahin and El Amoodi, 1991; Sharma et al., 1983).
Derosal and Korsikol also caused chromosome stickiness. Although chromosome stickiness were observed in Derosal treatment, these were not related with application time and dose.
Although, chromosomal stickness in Korsikol application was depended on application time, it was not correlated with doses which were applied. Different researchers also reported chromosome stickiness and accumulations as a result of pesticide applications (Hemavathy and Krıshnamurthy, 1988; Sharma et al., 1983; Chauhan et al., 1986; Yuzbaoiolu, 2003; Zakia et al., 1990).
Furthermore, Derosal and Korsikol caused mis-polarization. Different researchers reported that, Afolon (Bilalolu, 1985) and Diuron (Badr, 1988) cause multipolar divisions.
Although, applied fungicides have different effects on cell division mechanism depending on concentration and time, according to our findings, they are acting like a mutagen. They change chromosome structure and behaviour. Our results are concordance with the results of other researchers.