Variation of β-glucosidase enzyme activity and soil development with different slope and land cover under semi moist humid climate conditions
Öz
Microorganisms that live in soil not only play
an active role in many chemical changes that take place in the soil but also
are important components of soil fertility because
they work in the cycle of the nutrients required for plant development. Most of
the microbial activity in the soil is determined by measuring the activities of
the enzymes. The aim of this study is to examine the changes
in β-glucosidase
enzyme aktivities and soil development formed on the same parent
material, but with different slopes, land cover and land use under semihumid
climatic conditions. It was carried out on the soils formed on the basaltic
parent material in different physiographic positions within the Dağköy area of
Engiz District, which is located at the south of the Samsun-Bafra Highway. In this study, β-glycosidase enzyme activity was assessed in order to
detect the biological properties of the soils in the study area. It was
determined that the β-glycosidase enzyme activity of the soil samples taken
from the four profiles classified as Typic Haplustert and Lithic Ustorthent and selected
on southwest and northeast direction changed
between 4.9-98.9 μg p-nitrophenol. In addition, According to the statistical
relationship between β-glycosidase enzyme activity and different profiles, land
uses/land covers and elevations along the southwest and northeast
transect, different profiles and
different elevations were found to be important at 1% level of effect on
β-glycosidase enzyme activity in the soils. Also, it was determined that the effect
of different land use and land cover patterns on the activity of β-glycosidase
enzyme in the soil was insignificant as statistically.
Anahtar Kelimeler
Soil microorganisms β-glycosidase enzyme activity profile land use elevation
Kaynakça
- Arcak S, Karaca A, Haktanır K, 1996. Trifluralin’in üreaz ve alkali fosfataz enzim aktiviteleri üzerine etkisi. Tarım-Çevre İlişkileri Sempozyumu, 384-393, Mersin.
- Bouyoucos G,J, 1951. A recalibration of hydrometer for making mechanical analysis of soils. Agronomy Journal 43(9): 434-443.
- Eivazi F, Tabatabai M A, 1988. Glucosidases and galactosidases in soil. Soil Biology and Biochemistry 20: 601-606.
- Frankberger W, T, Dick W, A, 1983. Relationships with enzyme activities and microbial growth and activity indices in soil. Soil Science Society America Journal 47: 945-951.
- Jackson M, L, 1958. Soil Chemical Analysis. Englewood Cliffs, New Jersey: Prentice Hall Inc.
- Kiss S, Dragan-Bularda M, Radulescu D, 1976. Biological significance of enzymes accumulated in soil. Advances in Agronomy 27: 25-87.
- Rhoades J, D, 1986. Cation exchange capacity, chemical and microbiological properties. Methods of Soil Analysis, Part 2-Chemical and Microbiological Properties. ASA-SSSA, Madison, Winsconsin, USA. pp. 149-157.
- Rowell M, J, Ladd J, N, Paul E, A, 1973. Enzymatically active complexes of proteases and humic and analogues. Soil Biology and Biochemistry 5: 699-703.
- Schinner F, 1986. Veröffenlichung der landwirthschaftlich-chemischen budesanstalt linz / Donau. II. Seminar: Die Anwendung enzymatischer und mikrobiologischer Mthoden in der Bodenalyse.
- Soil Survey Staff, 1993. Soil Survey Manual, USDA Handbook, Washington D.C., No: 18.
- Soil Survey Staff, 1999. Soil Taxonomy. A basic of soil classification for making and interpreting soil survey. USDA Handbook, Washington D.C., No: 436.
- Tabatabai M, A, 1982. Soil enzymes. In Methods of Analysis, Part 2-Chemical and Microbiological Properties. 2nd Edition. Page AL. et al (Eds). ASA-SSSA, Madison, Winsconsin, USA. pp. 903–947.
- Tate R, L, 1987. Soil enzymes and organic matter transformations. In soil organic matter, biological and ecological effects. Wiley-Interscience Publications, 69-94, New York.
Yarı nemli ılıman iklim koşullarında farklı eğim ve farklı arazi örtüsü altında toprak gelişimi ve β-glikosidaz enzim aktivitesi değişimi
Öz
Toprak içerisinde yer alan mikroorganizmalar,
bitki gelişmesi için gerekli olan besin elementlerinin döngüsünde görev
aldıkları için toprak verimliliğinin önemli unsurlarının yanı sıra toprakta
meydana gelen pek çok kimyasal değişimin içinde aktif rol almaktadırlar. Topraktaki mikrobiyal aktivitenin büyük bir kısmı
enzimlerin aktivitelerinin ölçülmesiyle belirlenmektedir. Bu çalışmanın
amacı yarı nemli ılıman iklim koşulları altında aynı ana materyal, farklı eğim
ve arazi kullanımlarında farklı toprakların gelişimlerinin ortaya konulması ve
β-glikosidaz enzim aktivitesi değişimini incelemektir. Bu çalışma, Samsun-Bafra
karayolunun güneyinde, Engiz Beldesine bağlı Dağköy mevkii alanı içerisinde
farklı fizyografik ünitelerin yer aldığı bazaltik ana materyal üzerinde oluşmuş
topraklarda yürütülmüştür. Topraklar Typic
Haplustert ve Lithic Ustorthent olarak sınıflandırılmıştır. Çalışma alanına ait
toprakların biyolojik özelliklerinin ortaya konulması amacıyla β-glikosidaz
enzim aktivitesi değerlendirilmiş ve Güneybatı-Kuzeydoğu doğrultu hattı boyunca dört profil açılmış ve açılan profillerden
alınan toprak örneklerinin β-glikosidaz enzim aktivitesinin 4.9-98.9 μg
p-nitrofenol g-1 kuru top. arasında değiştiği belirlenmiştir. Ayrıca
Güneybatı-Kuzeydoğu hattı boyunca β-glikosidaz
enzim aktivitesi ile farklı profiller, arazi kullanımı ve yükseklik arasındaki
istatistiksel ilişki incelendiğinde farklı profillerin ve farklı yüksekliklerin
topraktaki β-glikosidaz enzim aktivitesi üzerine etkisinin %1 düzeyinde önemli
olduğu (P=0.000<0.01), farklı arazi kullanım şekillerinin ise
topraktaki β-glikosidaz enzim aktivitesi üzerine etkisinin önemsiz olduğu (P =
0.670>0.05) belirlenmiştir.
Anahtar Kelimeler
Toprak mikroorganizmaları β-glikosidaz enzim aktivitesi profil arazi kullanımı yükseklik
Kaynakça
- Arcak S, Karaca A, Haktanır K, 1996. Trifluralin’in üreaz ve alkali fosfataz enzim aktiviteleri üzerine etkisi. Tarım-Çevre İlişkileri Sempozyumu, 384-393, Mersin.
- Bouyoucos G,J, 1951. A recalibration of hydrometer for making mechanical analysis of soils. Agronomy Journal 43(9): 434-443.
- Eivazi F, Tabatabai M A, 1988. Glucosidases and galactosidases in soil. Soil Biology and Biochemistry 20: 601-606.
- Frankberger W, T, Dick W, A, 1983. Relationships with enzyme activities and microbial growth and activity indices in soil. Soil Science Society America Journal 47: 945-951.
- Jackson M, L, 1958. Soil Chemical Analysis. Englewood Cliffs, New Jersey: Prentice Hall Inc.
- Kiss S, Dragan-Bularda M, Radulescu D, 1976. Biological significance of enzymes accumulated in soil. Advances in Agronomy 27: 25-87.
- Rhoades J, D, 1986. Cation exchange capacity, chemical and microbiological properties. Methods of Soil Analysis, Part 2-Chemical and Microbiological Properties. ASA-SSSA, Madison, Winsconsin, USA. pp. 149-157.
- Rowell M, J, Ladd J, N, Paul E, A, 1973. Enzymatically active complexes of proteases and humic and analogues. Soil Biology and Biochemistry 5: 699-703.
- Schinner F, 1986. Veröffenlichung der landwirthschaftlich-chemischen budesanstalt linz / Donau. II. Seminar: Die Anwendung enzymatischer und mikrobiologischer Mthoden in der Bodenalyse.
- Soil Survey Staff, 1993. Soil Survey Manual, USDA Handbook, Washington D.C., No: 18.
- Soil Survey Staff, 1999. Soil Taxonomy. A basic of soil classification for making and interpreting soil survey. USDA Handbook, Washington D.C., No: 436.
- Tabatabai M, A, 1982. Soil enzymes. In Methods of Analysis, Part 2-Chemical and Microbiological Properties. 2nd Edition. Page AL. et al (Eds). ASA-SSSA, Madison, Winsconsin, USA. pp. 903–947.
- Tate R, L, 1987. Soil enzymes and organic matter transformations. In soil organic matter, biological and ecological effects. Wiley-Interscience Publications, 69-94, New York.
Ayrıntılar
| Birincil Dil | Türkçe |
|---|---|
| Konular | Ziraat Mühendisliği |
| Bölüm | Makaleler |
| Yazarlar | |
| Yayımlanma Tarihi | 22 Temmuz 2019 |
| Yayımlandığı Sayı | Yıl 2019 Cilt: 7 Sayı: 1 |
