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2016 | 21 | 1 |

Tytuł artykułu

Determination of the response of Gypsophila arrostii Guss. to boron under in vitro conditions

Treść / Zawartość

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
In this research, the response of the plant Gypsophila arrostii Guss. to boron (B) under in vitro conditions was examined. The seeds were cultured on MS medium including 0, 10, 20, 40, 80 mg B l-1. Seedlings obtained from germinated seeds and grown in a culture medium for 8 weeks were analyzed. At the end of this period, stem length (cm), root length (cm), plant weight (g) and elemental content (mg kg-1) of the plants were determined. According to the results, the seeds of G. arrostii Guss. could germinate on media with up to 80 mg B l-1, and the seedlings demonstrated an ability to survive, albeit poorly, a dose of boron as high as 80 mg B l-1. In the experiment, the highest stem length (7.5 cm) was obtained from the 20 mg B l-1 treatment and the highest stem fresh weight (0.9 g) and stem dry weight (0.19 g) were measured in the 10 mg B l-1 variant. No significant statistical difference was determined between the boron treatments in terms of root length, root fresh weight and root dry weight. Our evaluation of the elemental content of plants demonstrated that the amount of boron in the root and stem increased parallel to its increase in the growth media. In the 80 mg B l-1 treatment, 601.9 mg kg-1 boron in root and 1,035.4 mg kg-1 boron in stem were determined. Besides, it was discovered that the contents of K, Mg, Zn, Na in root decreased while the contents of P, B, Mn, Cu in root increased in response to the growing amount of boron in the environment. In response to the increasing boron concentrations, the content of K, P, Mn, Cu, Zn and S increased while the amount of Ca, Mg and Na in the plant stem decreased. Consequently, G. arrostii Guss. was found to be a boron hyperaccumulator, collecting boron in tissues (in the roots and stems), in which it resembled some other types of Gypsophilla.

Wydawca

-

Rocznik

Tom

21

Numer

1

Opis fizyczny

p.67-76,ref.

Twórcy

autor
  • Sincan District Directorate of Food, Agriculture and Livestock, Ankara, Turkey
  • Department of Field Crops, Selcuk University Konya, Turkey

Bibliografia

  • Abi Baykal S. and Oncel I. 2006. Changes of soluble phenolic and soluble protein amounts on the tolerance of boron toxicity in wheat seedlings. Qukurova University, Faculty of Sciences-Letters, Journal of Natural Sciences, 7(1): 13-25.
  • Babaoglu M,, Yorgancilah M., Akbudak H.A. 2002. Plant biotechnology. I. Applications of tissue culture. Chapter 1. Tissue culture: basic laboratory techniques. Selęuk University Foundation Publications. ISBN: 975-6652-04-7, 1-35
  • Babaoglu M., Gezgin S., Topal A., Sade В., Dural H. 2004. Gypsophila sphaerocephala Fenzl ex Tchihat.: A boron hyperaccumulator plant species that may phytoremediate soils with toxic B levels. Turk J. Agric For., 28: 273-278.
  • Dogan M. 2012. The effect of different boron practices on the germination of capparis spp. and Carthamuss spp. seeds. Süleyman Demirel University, J. Natur. Appl. Sci., 16(2): 154-161.
  • Gezgin S., Hamurcu M. 2006. The importance of the nutrient elements interaction and the interactions between boron with the other nutrient elements in plant nutrition. Selęuk University, J. Agric. Faculty, 20(39): 24-31.
  • Günes A., Alpaslan M., Ozcan H., Qikili Y. 2000. Tolerance to boron toxicity of maize (Zea mays L.) cultivars widely cultivated in Turkey. Turk. Agric. Foresty, 24: 277-282.
  • Inan M. 2006. Determination of saponin content and root yield different origin soapwort (Gypsophila sp.) species at the Qukurova conditions. Qukurova University, Institute of Natural and Applied Sciences (PhD Thesis).
  • Korkmaz M., Ozcelik H., Ilhan V. 2012. Habitat properties of some Gypsophila L. (Caryophyllaceae) taxa of Turkey. Res. J. Biol. Sci., 5(2): 111-125.
  • MSTAT-C. 1980. MStat User's Quides Statistics (Version 5 ed.). Michigan State Universty. Michigan, USA.
  • Murashige T. and Skoog F. A. 1962. Revised medium for rapid growth and bioassays with tobacco tissue cultures. Physiol Plant, 5(3): 473-497.
  • Nable O. R., Lance R. C. H., caetwright B. 1990. Uptake of boron and silicon by barley genotypes with differing suspectibilities to boron toxicity. Ann. Bot., 66(1): 83-90.
  • Nable O. R., Banuelos g.s., paull j.g. 1997. Boron toxcity. Plant Soil, 193: 181-198.
  • Ozcelik H., Yildirim B. 2011. Opinions on conservation, economical importance and using possibility of Turkish Soapworts (Gypsophila L. and Ankyropetalum Fenzl spp.j. Süleyman Demirel University, Faculty of Forestry Journal, 12: 57-61.
  • Padmanabhan P., Babaoglu M., Terry N. 2012. A comparative transcriptomic analysis of the extremely boron tolerant plant Puccinellia distans with the moderately boron tolerant Gypsophila arrostil. Plant Cell Rep., 31: 1407-1413.
  • Stiles A.R., Bautista D., Atalay E., Babaoglu M., Terry N. 2010. Mechanisms of boron tolerance and accumulation in plants: A physiological comparison of the extremely boron-tolerant plant species, Puccinellia distans, with the moderately boron-tolerant Gypsophila arrostil. Environ. Sci. Technol., 44: 7089-7095.
  • Yorgancilar M., Babaoglu M. 2005. The responses of some wheat varieties to boron as determined by tissue culture. Institute of Natural and Applied Sciences (PhD Thesis).

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

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