Eurasian Journal of Soil Science

Volume 12, Issue 2, Apr 2023, Pages 122 - 126
DOI: 10.18393/ejss.1211180
Stable URL: http://ejss.fess.org/10.18393/ejss.1211180
Copyright © 2023 The authors and Federation of Eurasian Soil Science Societies



The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil

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Muminova ,S., Bayadilova,G., Mukhametzhanova,O., Seilgazina,S., Zhumabayeva ,R., Rvaidarova ,G., 2023. The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil. Eurasian J Soil Sci 12(2):122 - 126. DOI : 10.18393/ejss.1211180
Muminova ,S.Bayadilova,G.,Mukhametzhanova,O.Seilgazina,S.Zhumabayeva ,R.,& Rvaidarova ,G. The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil Eurasian Journal of Soil Science, 12(2):122 - 126. DOI : 10.18393/ejss.1211180
Muminova ,S.Bayadilova,G.,Mukhametzhanova,O.Seilgazina,S.Zhumabayeva ,R., and ,Rvaidarova ,G."The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil" Eurasian Journal of Soil Science, 12.2 (2023):122 - 126. DOI : 10.18393/ejss.1211180
Muminova ,S.Bayadilova,G.,Mukhametzhanova,O.Seilgazina,S.Zhumabayeva ,R., and ,Rvaidarova ,G. "The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil" Eurasian Journal of Soil Science,12(Apr 2023):122 - 126 DOI : 10.18393/ejss.1211180
S,Muminova .G,Bayadilova.O,Mukhametzhanova.S,Seilgazina.R,Zhumabayeva .G,Rvaidarova "The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil" Eurasian J. Soil Sci, vol.12, no.2, pp.122 - 126 (Apr 2023), DOI : 10.18393/ejss.1211180
Muminova ,Sholpan S. ;Bayadilova,Gulsun ;Mukhametzhanova,Oryngul ;Seilgazina,Saule M. ;Zhumabayeva ,Roza ;Rvaidarova ,Gulnissam The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil. Eurasian Journal of Soil Science, (2023),12.2:122 - 126. DOI : 10.18393/ejss.1211180

How to cite

Muminova , S., Bayadilova, G., Mukhametzhanova, O., Seilgazina, S., Zhumabayeva , R., Rvaidarova , G., 2023. The effects of feeding with organic waste by terrestrial isopod Philoscia Muscorum on enzyme activities in an incubated soil. Eurasian J. Soil Sci. 12(2): 122 - 126. DOI : 10.18393/ejss.1211180

Author information

Sholpan S. Muminova , University named after Zhumabek Akhmetuly Tashenev, Shymkent, Kazakhstan
Gulsun Bayadilova , Kazakh National Agrarian Research University, Almaty, Kazakhstan
Oryngul Mukhametzhanova , Shakarim State University of Semey, Kazakhstan
Saule M. Seilgazina , Shakarim State University of Semey, Kazakhstan
Roza Zhumabayeva , M. Auezov South Kazakhstan State University, Shymkent, Kazakhstan
Gulnissam Rvaidarova , LLP "Kazakh Research Institute of Plant Protection and Quarantine named after Zh. Zhiembaev", Almaty, Kazakhstan

Publication information

Article first published online : 28 Nov 2022
Manuscript Accepted : 25 Nov 2022
Manuscript Received: 21 Apr 2022
DOI: 10.18393/ejss.1211180
Stable URL: http://ejss.fesss.org/10.18393/ejss.1211180

Abstract

Soil fauna are important biological factors that affect litter decomposition and play an important role in the release of nutrients and improve soil enzyme activities. This study focused on the effects of isopods on enzymatic activities of soil. Lab experiments were conducted to assess the influence of terrestrial isopod Philoscia Muscorum on enzyme activities during the incubation.In Lab experimental food sources from wheat straw were prepared. Dehydrogenase, urease, alkaline phosphatase and arylsulphatase activity in soil treated with different number of isopods with wheat straw were determined in 28 days incubation. Results showed that the presence of isopods significantly increased (P<0.05) enzymatic activities of soil except arylsulphatase compared with the control treatment. The findings demonstrate that the isopods could accelerate litter decomposition and improve soil dehydrogenase, urease and alkaline phosphatase activities in soil. This work provides evidence demonstrating that soil fauna can improve soil enzyme activity by promoting wheat straw decomposition.

Keywords

Isopod, dehydrogenase, urease, alkaline phosphatase, arylsulphatase, soil.

Corresponding author

References

Akça, M.O., Namlı, A., 2015. Effects of poultry litter biochar on soil enzyme activities and tomato, pepper and lettuce plants growth. Eurasian Journal of Soil Science 4(3): 161 - 168.

Amador, J.A., Glucksman, A.M., Lyons, J.B., Gorres, J.H., 1997. Spatial distribution of soil phosphatase activity within a riparian forest. Soil Science 162(11): 808-825.

Anderson, J.M., 1988a. Spatiotemporal effects of invertebrates on soil processes. Biology and Fertility of Soils 6: 216–227.

Anderson, J.M., 1988b. Invertebrate-mediated transport processes in soils. Agriculture, Ecosystems & Environment 24(1-3): 5–19.

Bandick, A.K., Dick, R.P., 1999. Field management effects on soil enzyme activities. Soil Biology and Biochemistry 31(11): 1471-1479.

Benefield, C.B., Howard P.J.A., Howard, D.M., 1977. The estimation of dehydrogenase activity in soil. Soil Biology and Biochemistry 9(1): 67-70.

Bolton Jr., H., Elliott, L.F. Papendick, R.I., Bezdicek, D.F., 1985. Soil microbial biomass and selected soil enzyme activities: effect of fertilization and cropping practices. Soil Biology and Biochemistry 17(3): 297-302.

Bragina T.M., Khisametdinova D.D., 2014. About fauna of terrestrial isopoda (crustacea; isopoda) of the state natural reserve at "Altyn Dala". International Scientific and Practical conference on “Successes in the formation and functioning of the network of specially protected natural areas and the study of biological diversity”, 26-27 February 2014, Kostanay, Kazakhstan.

Bremner, J.M., Mulvaney, R.L., 1978. Urease activity in soils. In: Soil enzymes. Burns, R.G. (Ed.). Academic Press, New York, USA. pp. 149-196.

Clark, K.L., Skowronski, N., Hom, J., 2010. Invasive insects impact forest carbon dynamics. Global Change Biology 16(1): 88–101.

Eijsackers, H., 1991. Litter fragmentation by isopods as affected by herbicide application. Netherlands Journal of Zoology 41(4): 277-303.

Hoffmann, G.G., Teicher, K. 1961. Ein Kolorimetrisches Verfahren zur Bestimmung der Urease Aktivitat in Böden. Zeitschrift für Pflanzenernährung und Bodenkunde 95(1): 55–63.

Hunter, M.D., 2001. Insect population dynamics meets ecosystem ecology: effects of herbivory on soil nutrient dynamics. Agricultural and Forest Entomology 3(2): 77–84.

Jia, Y.Y., Lv, Y., Kong, X.S., Jia, X.Q., Tian, K., Du, J.J., Tian, X.J., 2015. Insight into the indirect function of isopods in litter decomposition in mixed subtropical forests in China. Applied Soil Ecology 86: 174–181.

Karaca, A., Naseby, D.C., Lynch, J.M., 2002. Effect of cadmium contamination with sewage sludge and phosphate fertiliser amendments on soil enzyme activities, microbial structure and available cadmium. Biology and Fertility of Soils 35: 428-434.

Kızılkaya, R., 2008. Dehydrogenase activity in Lumbricus terrestris casts and surrounding soil affected by addition of different organic wastes and Zn. Bioresource Technology 99(5): 946–953.

Kızılkaya, R., Bayraklı, B., 2005. Effects of N-enriched sewage sludge on soil enzyme activities. Applied Soil Ecology 30(3): 192-202.

Masciandaro, G., Ceccanti, B., Ronchi, V., Bauer, C., 2000. Kinetic parameters of dehydrogenase in the assessment of the response of soil to vermicompost and inorganic fertilisers. Biology and Fertility of Soils 32: 479-483.

Morgan, C.R., Mitchell, M.J., 1987. The effects of feeding byOniscus asellus on leaf litter sulfur constituents. Biology and Fertility of Soils 3: 107–111.

Obbard, J.P., 2001. Measurement of dehydrogenase activity using 2-p-iodophenyl-3-p-nitrophenyl - 5-phenyltetrazolium chloride (INT) in the presence of copper. Biology and Fertility of Soils 33: 328-330.

Pascual, J.A., Hernandez, T., Garcia, C., Ayuso, M., 1998. Enzymatic activities in an arid soil amended with urban organic wastes: laboratory experiment. Bioresource Technology 64(2): 131-138.

Pascual, J.A., Moreno, J.L., Hernández, T., García, C., 2002. Persistence of immobilised and total urease and phosphatase activities in a soil amended with organic wastes. Bioresource Technology 82(1): 73-78.

Pepper, I.L., Gerba, C.P., Brendecke, J.W., 1995. Environmental microbiology: a laboratory manual. Academic Press Inc. New York, USA.

Rossel, D., Tarradellas, J., 1991. Dehydrogenase activity of soil microflora: significance in ecotoxicological tests. Environmental Toxicology and Water Quality 6(1): 17-33.

Seastedt, T.R., Crossley Jr., D.A. 1980. Effects of microarthropods on the seasonal dynamics of nutrients in forest litter. Soil Biology and Biochemistry 12(4): 337–342.

Tabatabai, M.A., 1994. Soil enzymes. In: Methods of soil analysis, Part 2 Microbiological and biochemical properties. Mickelson, S.H., Bighan, J.M. (Eds.). Soil Science Socitety of America, Madison. pp. 775-826.

Tabatabai, M.A., Bremner, J.M., 1969. Use of p-nitrophenyl phosphate for assay of soil phosphatase activity. Soil Biology and Biochemistry 1(4): 301-307.

Tabatabai, M.A., Bremner, J.M., 1970. Arylsulphatase activity of soils. Soil Science Society of America Journal 34(2): 225-229.

Teuben, A., Roelofsma, T.A.P.J., 1990. Dynamic interactions between functional groups of soil arthropods and microorganisms during decomposition of coniferous litter in microcosm experiments. Biology and Fertility of Soils 9:145-151.

Visser, S., 1985. Role of the soil invertebrates in determining the composition of soil microbial communities. In: Ecological interactions in soil: Plants, microbes and animals. Fitter, A.H., Atkinson, D., Read, D., Usher, M.B. (Eds.). Blackwell Scientific Publications, Oxford, UK. pp. 297–317.

Yang, X., Shao, M., Li, T., 2020. Effects of terrestrial isopods on soil nutrients during litter decomposition. Geoderma 376: 114546.

Zhang, D., Wu, Y., Zhang, X., Zhu, Y., 2017. Persistence of myclobutanil and its impact on soil microbial biomass C and dehydrogenase enzyme activity in tea orchard soils. Eurasian Journal of Soil Science 6(2): 106-113.

Abstract

Soil fauna are important biological factors that affect litter decomposition and play an important role in the release of nutrients and improve soil enzyme activities. This study focused on the effects of isopods on enzymatic activities of soil. Lab experiments were conducted to assess the influence of terrestrial isopod Philoscia Muscorum on enzyme activities during the incubation.In Lab experimental food sources from wheat straw were prepared. Dehydrogenase, urease, alkaline phosphatase and arylsulphatase activity in soil treated with different number of isopods with wheat straw were determined in 28 days incubation. Results showed that the presence of isopods significantly increased (P<0.05) enzymatic activities of soil except arylsulphatase compared with the control treatment. The findings demonstrate that the isopods could accelerate litter decomposition and improve soil dehydrogenase, urease and alkaline phosphatase activities in soil. This work provides evidence demonstrating that soil fauna can improve soil enzyme activity by promoting wheat straw decomposition.

Keywords: Isopod, dehydrogenase, urease, alkaline phosphatase, arylsulphatase, soil.

References

Akça, M.O., Namlı, A., 2015. Effects of poultry litter biochar on soil enzyme activities and tomato, pepper and lettuce plants growth. Eurasian Journal of Soil Science 4(3): 161 - 168.

Amador, J.A., Glucksman, A.M., Lyons, J.B., Gorres, J.H., 1997. Spatial distribution of soil phosphatase activity within a riparian forest. Soil Science 162(11): 808-825.

Anderson, J.M., 1988a. Spatiotemporal effects of invertebrates on soil processes. Biology and Fertility of Soils 6: 216–227.

Anderson, J.M., 1988b. Invertebrate-mediated transport processes in soils. Agriculture, Ecosystems & Environment 24(1-3): 5–19.

Bandick, A.K., Dick, R.P., 1999. Field management effects on soil enzyme activities. Soil Biology and Biochemistry 31(11): 1471-1479.

Benefield, C.B., Howard P.J.A., Howard, D.M., 1977. The estimation of dehydrogenase activity in soil. Soil Biology and Biochemistry 9(1): 67-70.

Bolton Jr., H., Elliott, L.F. Papendick, R.I., Bezdicek, D.F., 1985. Soil microbial biomass and selected soil enzyme activities: effect of fertilization and cropping practices. Soil Biology and Biochemistry 17(3): 297-302.

Bragina T.M., Khisametdinova D.D., 2014. About fauna of terrestrial isopoda (crustacea; isopoda) of the state natural reserve at "Altyn Dala". International Scientific and Practical conference on “Successes in the formation and functioning of the network of specially protected natural areas and the study of biological diversity”, 26-27 February 2014, Kostanay, Kazakhstan.

Bremner, J.M., Mulvaney, R.L., 1978. Urease activity in soils. In: Soil enzymes. Burns, R.G. (Ed.). Academic Press, New York, USA. pp. 149-196.

Clark, K.L., Skowronski, N., Hom, J., 2010. Invasive insects impact forest carbon dynamics. Global Change Biology 16(1): 88–101.

Eijsackers, H., 1991. Litter fragmentation by isopods as affected by herbicide application. Netherlands Journal of Zoology 41(4): 277-303.

Hoffmann, G.G., Teicher, K. 1961. Ein Kolorimetrisches Verfahren zur Bestimmung der Urease Aktivitat in Böden. Zeitschrift für Pflanzenernährung und Bodenkunde 95(1): 55–63.

Hunter, M.D., 2001. Insect population dynamics meets ecosystem ecology: effects of herbivory on soil nutrient dynamics. Agricultural and Forest Entomology 3(2): 77–84.

Jia, Y.Y., Lv, Y., Kong, X.S., Jia, X.Q., Tian, K., Du, J.J., Tian, X.J., 2015. Insight into the indirect function of isopods in litter decomposition in mixed subtropical forests in China. Applied Soil Ecology 86: 174–181.

Karaca, A., Naseby, D.C., Lynch, J.M., 2002. Effect of cadmium contamination with sewage sludge and phosphate fertiliser amendments on soil enzyme activities, microbial structure and available cadmium. Biology and Fertility of Soils 35: 428-434.

Kızılkaya, R., 2008. Dehydrogenase activity in Lumbricus terrestris casts and surrounding soil affected by addition of different organic wastes and Zn. Bioresource Technology 99(5): 946–953.

Kızılkaya, R., Bayraklı, B., 2005. Effects of N-enriched sewage sludge on soil enzyme activities. Applied Soil Ecology 30(3): 192-202.

Masciandaro, G., Ceccanti, B., Ronchi, V., Bauer, C., 2000. Kinetic parameters of dehydrogenase in the assessment of the response of soil to vermicompost and inorganic fertilisers. Biology and Fertility of Soils 32: 479-483.

Morgan, C.R., Mitchell, M.J., 1987. The effects of feeding byOniscus asellus on leaf litter sulfur constituents. Biology and Fertility of Soils 3: 107–111.

Obbard, J.P., 2001. Measurement of dehydrogenase activity using 2-p-iodophenyl-3-p-nitrophenyl - 5-phenyltetrazolium chloride (INT) in the presence of copper. Biology and Fertility of Soils 33: 328-330.

Pascual, J.A., Hernandez, T., Garcia, C., Ayuso, M., 1998. Enzymatic activities in an arid soil amended with urban organic wastes: laboratory experiment. Bioresource Technology 64(2): 131-138.

Pascual, J.A., Moreno, J.L., Hernández, T., García, C., 2002. Persistence of immobilised and total urease and phosphatase activities in a soil amended with organic wastes. Bioresource Technology 82(1): 73-78.

Pepper, I.L., Gerba, C.P., Brendecke, J.W., 1995. Environmental microbiology: a laboratory manual. Academic Press Inc. New York, USA.

Rossel, D., Tarradellas, J., 1991. Dehydrogenase activity of soil microflora: significance in ecotoxicological tests. Environmental Toxicology and Water Quality 6(1): 17-33.

Seastedt, T.R., Crossley Jr., D.A. 1980. Effects of microarthropods on the seasonal dynamics of nutrients in forest litter. Soil Biology and Biochemistry 12(4): 337–342.

Tabatabai, M.A., 1994. Soil enzymes. In: Methods of soil analysis, Part 2 Microbiological and biochemical properties. Mickelson, S.H., Bighan, J.M. (Eds.). Soil Science Socitety of America, Madison. pp. 775-826.

Tabatabai, M.A., Bremner, J.M., 1969. Use of p-nitrophenyl phosphate for assay of soil phosphatase activity. Soil Biology and Biochemistry 1(4): 301-307.

Tabatabai, M.A., Bremner, J.M., 1970. Arylsulphatase activity of soils. Soil Science Society of America Journal 34(2): 225-229.

Teuben, A., Roelofsma, T.A.P.J., 1990. Dynamic interactions between functional groups of soil arthropods and microorganisms during decomposition of coniferous litter in microcosm experiments. Biology and Fertility of Soils 9:145-151.

Visser, S., 1985. Role of the soil invertebrates in determining the composition of soil microbial communities. In: Ecological interactions in soil: Plants, microbes and animals. Fitter, A.H., Atkinson, D., Read, D., Usher, M.B. (Eds.). Blackwell Scientific Publications, Oxford, UK. pp. 297–317.

Yang, X., Shao, M., Li, T., 2020. Effects of terrestrial isopods on soil nutrients during litter decomposition. Geoderma 376: 114546.

Zhang, D., Wu, Y., Zhang, X., Zhu, Y., 2017. Persistence of myclobutanil and its impact on soil microbial biomass C and dehydrogenase enzyme activity in tea orchard soils. Eurasian Journal of Soil Science 6(2): 106-113.



Eurasian Journal of Soil Science