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İncir (Ficus carica) yapraklarının bazı anatomik parametreleri üzerine elektromanyetik alan stresinin etkileri

Effects of electromagnetic field stress on some anatomical parameters of fig (Ficus carica L.) leaves

Journal Name:

  • Biyolojij Çeşitlilik ve Koruma

Publication Year:

  • 2009

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
In this study, the effects of elektromagnetic field stress caused by base stations on the leaf anatomies of fig trees were investigated. Electromagnetic field stress increased the cuticle thickness, epidermis cell number, stomata number, stomata index, stomata width and distance between vascular bundles while it decreased the epidermis cell length, stomata length, trachea diameter, leaf diameter, vascular bundle width and length. On the other hand, the mentioned stress increased the epidermis cell width in the leaf upper surface while it showed the same values as the control in the leaf lower surface.
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Abstract (Original Language): 
Bu çalışmada, incir ağaçlarının yaprak anatomileri üzerine baz istasyonlarının sebep olduğu elektromanyetik alan stresinin etkileri araştırılmıştır. Elektromanyetik alan stresi kutikula kalınlığı, epidermis hücre sayısı, stoma sayısı, stoma indeksi, stoma eni ve iletim demetleri arası mesafeyi artırırken, epidermis hücre boyu, stoma boyu, trake çapı, yaprak çapı, iletim demeti eni ve boyunu azaltmıştır. Diğer yandan, söz konusu stres epidermis hücre enini yaprak üst yüzeyinde artırırken, yaprak alt yüzeyinde kontrol grubu ile aynı değerleri göstermiştir.
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  • 3
107-111
  • Turkish

REFERENCES

References: 

Ahmet, E.
2003
. Effects of magnetic fields on yield and growth in strawberry 'Camarosa'. The Journal of Horticultural
Science and Biotechnology. 78. 145-147. Akoyonoglou, G. 1964. Effect of magnetic field on carboxydismutase. Nature. 4931. 452-454.
Beerling, D.J., Chaloner, W.G. 1993. The impact of atmospheric CO2 and temperature change on stomatal density:
observations from Quercus robur Lammad leaves. Annals of Botany. 71. 231-235. Bhatnagar, D., Deb, A.R. 1978. Some aspects of pregermination exposure of wheat seeds to magnetic field II. effect on
some physiological processes. Seed Research. 6. 14-22. Çavuşoğlu, K., Kılıç, S., Kabar, K.. 2007. Effects of pretreatments of some growth regulators on the stomata
movements of barley seedlings grown under saline (NaCI) conditions. Plant, Soil and Environment. 53. 524-528. Gausman, W.H., Allen, A.W., Escobar, E.D., Rodriguez, R.R., Carednas, R. 1971. Age effect of cotton leaves on light
reflectance, transmitance, and absorbance and water content and thickness. Agronomy Journal. 63. 465-469. Jovanic, B.R., Belca, I., Kasalica, B. 2001. Effect of a high DC electric field on plant leaves reflectivity. International
Journal of Environmental Studies. 58. 357-363. Kavi, P.S. 1977. The effect of magnetic treatment of soybean seed on its moisture absorbing capacity. Science Art
Culture. 43. 405-406.
Kim,
S.J.
, Hahn, E.J., Heo, J.W., Paek, K.Y. 2004. Effects of LEDs on net photosynthetic rate, growth and leaf stomata
of chrysantemum plantlets in vitro. Scientia Horticulturae. 101. 143-151. Lebedev, I.S., Litvinenko, L.G., Shiyan, L.T. 1977. After-effect of a permanent magnetic field on photochemical
activity of chroloplasts. Soviet Plant Physiology. 24. 394-395. Levedev, S.I., Baranskil, P.I., Litrimennko, L.G., Shiyan, L.T. 1975. Physiobiochemical characteristics of plants after
presowing treatment with a permanent magnetic field. Soviet Plant Physiology. 22. 84-89. Mazza, C.A., Battista, D., Zima, A.M., Szwarcberg-Bracchitta, M., Giordano, C.V., Acevedo, A., Scopel, A.L. 1999.
The effects of solar ultraviolet-B radiation on the growth and yield of barley are accompanied by increased DNA
damage and antioxidant responses. Plant Cell and Environment. 22. 61-70. Meidner, H., Mansfield, T.A. 1968. Physiology of stomata. Graw-Hill, New York.
Nechitailo, G., Gordeev, A. 2001. Effect of artificial electric fields on plants grown under microgravity conditions.
Advances in Space Research. 28/4. 629-631. Piacentini, M.P., Fraternale, D., Piatti, E., Ricci, D., Vetrano, F., Dacha, M., Accorsi, A. 2001. Senescence delay and
change of antioxidant enzyme levels in Cucumis sativus L. etiolated seedlings by ELF magnetic fields. Plant
Science. 161. 45-53.
Pietruszewski, S. 1993. Effect of magnetic seed treatment on yields of wheat. Seed Science and Technology. 21. 621¬626.
Romana, R., Igor, J. 2002. Weak magnetic field decreases heat stres in cress seedlings. Electromagnetic Biology and
Medicine. 21. 69-80.
Stagg, R.B., Hawel, L.H., Pastorian, K., Cain, C., Adey, W.R., Buys, C.V. 2001. Effect of immobilization and concurrent exposure to a pulse-modulated microwave field on core body temperature, plasma ACTH and corticosteroid, and brain ornithine decarboxylase, Fos and Jun mRNA. Radiation Research. 155. 584-592.
Strogonov, B.P. 1964. Physiological Basis of Salt Tolerance of Plants (as Affected by Various Types of Salinity). Jerusalem, 1-366.
Wooley, J.T. 1971. Reflectance and transmitance of light by leaves. Plant Physiology. 47. 656-662.
Xi, G., Fu, Z.D., Ling, J. 1994. Change of peroxidase activity in wheat seedlings induced by magnetic field and its
response under dehydration condition. Acta Botanica Sinica. 36. 113-118. Xu, Z., Zhou, G. 2008. Responses of leaf stomatal density to water status and its relationship with photosynthesis in a
grass. Journal of Experimental Botany. 59. 3317-3325. Yang, L., Han, M., Zhou, G., Li, J. 2007. The changes of water-use efficiency and stoma density of Leymus chinensis
along Northeast China transect. Acta Ecologica Sinica. 27. 16-24. Yinan, Y., Yuan, L., Yongqing, Y., Chunyang, L. 2005. Effect of seed pretreatment by magnetic field on the sensitivity
of cucumber (Cucumis sativus) seedlings to ultraviolet-B-radiation. Environmental and Experimental Botany. 54.
286-294.
Zook, B.C., Simmens, S. J. 2001. The effects of 860 MHz radiofrequency radiation on the induction or promotion of brain tumors and other neoplasms in rats. Radiation Research. 155. 572-583.

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