Response of Different Coffee-Based Agroforestry Management on Microbial Respiration and Density

Nugroho, R. Muhammad Yusuf Adi Pujo; Ustiatik, Reni; Prasetya, Budi; Kurniawan, Syahrul

doi:10.12911/22998993/169179

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Tytuł artykułu

Response of Different Coffee-Based Agroforestry Management on Microbial Respiration and Density

Autorzy

Nugroho R. Muhammad Yusuf Adi Pujo , Ustiatik Reni , Prasetya Budi , Kurniawan Syahrul

Treść / Zawartość

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Identyfikatory

DOI

10.12911/22998993/169179

Warianty tytułu

Języki publikacji

Abstrakty

Coffee agroforestry has become a land use system that provides both ecological and economic benefits, so it is managed in various ways. Pruning and fertilizer management is a combination that is applied for optimal production. However, understanding the effect of combined management on soil respiration and functional microbial populations remains unclear. This study aimed to determine the effect of combining pruning and fertilizer management on soil respiration and functional bacterial populations as well as to elucidate the relationship between tested parameters. The study was conducted in UB Forest. A factorial randomized block design consisting of three factors, i.e., coffee pruning, type of fertilizer, and fertilizer doses was used. The results showed that combining three factors affected the diazotrophic bacterial population and soil respiration, which is sensitive to management changes. Coffee pruning and mixed fertilizer (inorganic + organic) application affected soil respiration and microbial populations, while the dose affected each parameter differently. The conducted study suggests that pruning management with mixed fertilizer application can substitute inorganic fertilizer as more environmentally sustainable management in coffee-based agroforestry.

Słowa kluczowe

coffee-based agroforestry diazotrophic bacteria fertilization pruning P-solubilizing bacteria soil respiration

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2023

Tom

Vol. 24, nr 9

Strony

158--170

Opis fizyczny

Bibliogr. 58 poz., rys., tab.

Twórcy

autor

Nugroho R. Muhammad Yusuf Adi Pujo

Soil and Water Management Study Program, Faculty of Agriculture, Universitas Brawijaya, Jl. Veteran No. 1, Malang 65145, Indonesia

autor

Ustiatik Reni

Soil Science Department, Faculty of Agriculture, Universitas Brawijaya, Jl. Veteran No. 1, Malang 65145, Indonesia

https://orcid.org/0000-0001-7703-1874

autor

Prasetya Budi

Soil Science Department, Faculty of Agriculture, Universitas Brawijaya, Jl. Veteran No. 1, Malang 65145, Indonesia

autor

Kurniawan Syahrul

syahrul.fp@ub.ac.id

Soil Science Department, Faculty of Agriculture, Universitas Brawijaya, Jl. Veteran No. 1, Malang 65145, Indonesia

https://orcid.org/0000-0003-3053-9755

Bibliografia

1. Adeleke R., Nwangburuka C., Oboirien B. 2017. Origins, Roles and Fate of Organic Acids in Soils: A Review. South African Journal of Botany, 108, 393–406.
2. Aldrich-Wolfe L., Black K.L., Hartmann E.D.L., Shivega W.G., Schmaltz L.C., McGlynn R.D., Johnson P.G., Keller R.J.A., Vink S.N. 2020. Taxonomic Shifts in Arbuscular Mycorrhizal Fungal Communities with Shade and Soil Nitrogen across Conventionally Managed and Organic Coffee Agroecosystems. Mycorrhiza, 30(4), 513–27.
3. Asfaw A., Zewudie S. 2021. Soil Macrofauna Abundance, Biomass and Selected Soil Properties in the Home Garden and Coffee-Based Agroforestry Systems at Wondo Genet, Ethiopia. Environmental and Sustainability Indicators, 12, 100153.
4. Batista M.B., Dixon R. 2019. Manipulating Nitrogen Regulation in Diazotrophic Bacteria for Agronomic Benefit. Biochemical Society Transactions, 47(2), 603–14.
5. Bickel S., Or D. 2020. Soil Bacterial Diversity Mediated by Microscale Aqueous-Phase Processes across Biomes. Nature Communications, 11(1), 116.
6. Butterly C.R., Baldock J.A., Tang C. 2013. The Contribution of Crop Residues to Changes in Soil pH under Field Conditions. Plant and Soil, 366(1), 185–98.
7. Cameron C. 2007. MicroRespTM Technical Manual—A Versatile Soil Respiration System. Macaulay Institute, Craigiebuckler, Aberdeen, Scotland, UK.
8. Chen H., Zheng C., Qiao Y., Du S., Li W., Zhang X., Zhao Z., Cao C., Zhang W. 2021. Long-Term Organic and Inorganic Fertilization Alters the Diazotrophic Abundance, Community Structure, and Co-Occurrence Patterns in a Vertisol. Science of The Total Environment, 766, 142441.
9. Chen Z., Xu Y., Castellano M.J., Fontaine S., Wang W., Ding W. 2019. Soil Respiration Components and Their Temperature Sensitivity Under Chemical Fertilizer and Compost Application: The Role of Nitrogen Supply and Compost Substrate Quality. Journal of Geophysical Research: Biogeosciences, 124(3), 556–71.
10. Chen Z., Xu Y., Fan J., Yu H., Ding W. 2017. Soil Autotrophic and Heterotrophic Respiration in Response to Different N Fertilization and Environmental Conditions from a Cropland in Northeast China. Soil Biology and Biochemistry, 110, 103–15.
11. Comeau L.P., Hergoualc’h K., Hartill J., Smith J., Verchot L.V., Peak D., Salim A.M. 2016. How Do the Heterotrophic and the Total Soil Respiration of an Oil Palm Plantation on Peat Respond to Nitrogen Fertilizer Application?. Geoderma, 268, 41–51.
12. Cooper J., Greenberg I., Ludwig B., Hippich L., Fischer D., Glaser B., Kaiser M. 2020. Effect of Biochar and Compost on Soil Properties and Organic Matter in Aggregate Size Fractions under Field Conditions. Agriculture, Ecosystems & Environment, 295, 106882.
13. Cui J., Holden N.M. 2015. The Relationship between Soil Microbial Activity and Microbial Biomass, Soil Structure and Grassland Management. Soil and Tillage Research, 146, 32–38.
14. Dufour B.P., Kerana 1.W., Ribeyre F. 2019. Effect of Coffee Tree Pruning on Berry Production and Coffee Berry Borer Infestation in the Toba Highlands (North Sumatra). Crop Protection, 122(November 2018), 151–58.
15. Ebrahimi M., Sarikhani M.R., Sinegani A.A.S., Ahmadi A., Keesstra S. 2019. Estimating the Soil Respiration under Different Land Uses Using Artificial Neural Network and Linear Regression Models. CATENA, 174, 371–82.
16. Furtak K., Gajda A.M. 2018. Activity and Variety of Soil Microorganisms Depending on the Diversity of the Soil Tillage System. in Sustainability of Agroecosystems. IntechOpen.
17. Gu Z., Wan S., Hua K., Yin Y., Chu H.Y., Wang D., Guo X. 2020. Fertilization Regime Has a Greater Effect on Soil Microbial Community Structure than Crop Rotation and Growth Stage in an Agroecosystem. Applied Soil Ecology, 149(40), 103510.
18. Huang K., Xu C., Qian Z., Zhang K., Tang L. 2023. Effects of Pruning on Vegetation Growth and Soil Properties in Poplar Plantations. Forests, 14(3), 501.
19. Huang K., Li Y., Hu J., Tang C., Zhang S., Fu S., Jiang P., Ge T., Yu L., Xinzhang S., Li Y., Cai Y. 2021. Rates of Soil Respiration Components in Response to Inorganic and Organic Fertilizers in an Intensively-Managed Moso Bamboo Forest. Geoderma, 403, 115212.
20. Iovieno P., Morra L., Leone A., Pagano L., Alfani A. 2009. Effect of Organic and Mineral Fertilizers on Soil Respiration and Enzyme Activities of Two Mediterranean Horticultural Soils. Biology and Fertility of Soils, 45(5), 555–61.
21. Kabiri V., Raiesi F., Ghazavi M.A. 2016. Tillage Effects on Soil Microbial Biomass, SOM Mineralization and Enzyme Activity in a Semi-Arid Calcixerepts. Agriculture, Ecosystems & Environment, 232, 73–84.
22. Kästner M., Miltner A., Thiele-Bruhn S., Liang C. 2021. Microbial Necromass in Soils—Linking Microbes to Soil Processes and Carbon Turnover. Frontiers in Environmental Science, 9.
23. Kawahigashi M., Prokushkin A., Sumida H. 2011. Effect of Fire on Solute Release from Organic Horizons under Larch Forest in Central Siberian Permafrost Terrain. Geoderma, 166(1), 171–80.
24. Kurniawan S., Hariyanto P., Ishaq R.M. 2021. Soil Management Practices in Coffee-Based Agroforestry Systems within Universitas Brawijaya Forest Impact on Maintaining Soil Carbon Stock. IOP Conference Series: Earth and Environmental Science, 824(1).
25. Lai R., Arca P., Lagomarsino A., Cappai C., Seddaiu G., Demurtas C.E., Roggero P.P. 2017. Manure Fertilization Increases Soil Respiration and Creates a Negative Carbon Budget in a Mediterranean Maize (Zea Mays L.)-Based Cropping System. CATENA, 151, 202–12.
26. Lazcano C., Gómez-Brandón M., Revilla P., Domínguez J. 2013. Short-Term Effects of Organic and Inorganic Fertilizers on Soil Microbial Community Structure and Function. Biology and Fertility of Soils, 49(6), 723–33.
27. Liu Y.R., Delgado-Baquerizo M., Wang J.T., Hu H.W., Yang Z., He J.Z. 2018. New Insights into the Role of Microbial Community Composition in Driving Soil Respiration Rates. Soil Biology and Biochemistry, 118, 35–41.
28. Mahgoub H.A.M., Fouda A., Eid A.M., Ewais E.E.D., Hassan S.E.D. 2021. Biotechnological Application of Plant Growth-Promoting Endophytic Bacteria Isolated from Halophytic Plants to Ameliorate Salinity Tolerance of Vicia Faba L. Plant Biotechnology Reports, 15(6), 819–43.
29. Martins M.Q., Rodrigues W.P., Fortunato A.S., Leitão A.E., Rodrigues A.P., Pais I.P., Martins L.D., Silva M.J., Reboredo F.H., Partelli F.L., Campostrini E., Tomaz M.A., Scotti-Campos P., Ribeiro-Barros A.I., Lidon F.J.C., DaMatta F.M., Ramalho J.C. 2016. Protective Response Mechanisms to Heat Stress in Interaction with High (CO2) Conditions in Coffea spp. Frontiers in Plant Science, 7.
30. Mhete M., Eze P.N., Rahube T.O., Akinyemi F.O. 2020. Soil Properties Influence Bacterial Abundance and Diversity under Different Land-Use Regimes in Semi-Arid Environments. Scientific African, 7, e00246.
31. Mokondoko P., Avila-Foucat V.S., Galeana-Pizaña J.M. 2022. Biophysical Drivers of Yield Gaps and Ecosystem Services across Different Coffee-Based Agroforestry Management Types: A Global Meta- Analysis. Agriculture, Ecosystems & Environment, 337, 108024.
32. Montejo D.A., Valdés S.G.B., Lancho J.F.G., Velarde E.V. 2021. Soil Respiration and Distribution of Aggregates in Modified Agroforestry Systems of Coffee and Avocados in Huatusco, Veracruz, Mexico. Soil Environment, 40(1), 17–26.
33. Niether W., Armengot L., Andres C., Schneider M., Gerold G. 2018. Shade Trees and Tree Pruning Alter Throughfall and Microclimate in Cocoa (Theobroma Cacao L.) Production Systems. Annals of Forest Science, 75(2).
34. Parmar P., Sindhu S.S. 2013. Potassium Solubilization by Rhizosphere Bacteria: Influence of Nutritional and Environmental Conditions. Journal of Microbiology Research, 3(1), 25–31.
35. Pramanik P., Phukan M., Ghosh S., Goswami A.J. 2018. Pruned Tea Bushes Secrete More Root Exudates to Influence Microbiological Properties in Soil. Archives of Agronomy and Soil Science, 64(8), 1172–80.
36. Purnomo B., Sutopo N.R., Nuraini Y. 2021. Utilization of Indigenous Phosphate-Solubilizing Bacteria to Optimize the Use of Coal Fly Ash for Increasing Available P in an Ultisol. Journal of Degraded and Mining Lands Management, 8(4), 2937–46.
37. Rodtassana C., Unawong W., Yaemphum S., Chanthorn W., Chawchai S., Nathalang A., Brockelman W.Y. and Tor‐ngern P. 2021. Different Responses of Soil Respiration to Environmental Factors across Forest Stages in a Southeast Asian Forest. Ecology and Evolution, 11(21), 15430.
38. Rowe R.L., Prayogo C., Oakley S., Hairiah K., Noordwijk M.V., Wicaksono K.P., Kurniawan S., Fitch A., Cahyono E.D., Suprayogo D., McNamara N.P. 2022. Improved Coffee Management by Farmers in State Forest Plantations in Indonesia: An Experimental Platform. Land, 11(5), 671.
39. Sarvade S., Gautam D.S., Upadhyay V.B., Sahu R.K., Shrivastava A.K., Kaushal R., Singh R., Yewale A.G. 2019. Agroforestry and Soil Health: An Overview. 275–97 in Agroforestry for Climate Resilience and Rural Livelihood. Scientific Publisher.
40. Sheng H., Wang J., He X., Lv G. 2022. The Relationship between Soil Respiration and Plant Community Functional Traits in Ebinur Lake Basin. Agronomy, 12(4), 966.
41. Singh S.K., Wu X., Shao C., Zhang H. 2022. Microbial Enhancement of Plant Nutrient Acquisition. Stress Biology, 2(1), 3.
42. Spohn M., Schleuss P.M. 2019. Addition of Inorganic Phosphorus to Soil Leads to Desorption of Organic Compounds and Thus to Increased Soil Respiration. Soil Biology and Biochemistry, 130, 220–26.
43. Sun Q., Wang R., Wang Y., Du L., Zhao M., Gao X., Hu Y., Guo S. 2018. Temperature Sensitivity of Soil Respiration to Nitrogen and Phosphorous Fertilization: Does Soil Initial Fertility Matter?. Geoderma, 325, 172–82.
44. Sun R., Guo X., Wang D., Chu H. 2015. Effects of Long-Term Application of Chemical and Organic Fertilizers on the Abundance of Microbial Communities Involved in the Nitrogen Cycle. Applied Soil Ecology, 95, 171–78.
45. Tang Y., Zhang M., Chen A., Zhang W., Wei W., Sheng R. 2017. Impact of Fertilization Regimes on Diazotroph Community Compositions and N2-Fixation Activity in Paddy Soil. Agriculture, Eco- systems & Environment, 247, 1–8.
46. Tesfay F., Moges Y., Asfaw Z. 2022. Woody Species Composition, Structure, and Carbon Stock of Coffee-Based Agroforestry System along an Elevation Gradient in the Moist Mid-Highlands of Southern Ethiopia. International Journal of Forestry Research, 2022, e4729336.
47. Ustiatik R., Nuraini Y., Suharjono S., Jeyakumar P., Anderson C.W.N., Handayanto E. 2022. Mercury Resistance and Plant Growth Promoting Traits of Endophytic Bacteria Isolated from Mercury-Contaminated Soil. Bioremediation Journal, 26(3), 208-227.
48. Vinci G., Marques I., Rodrigues A.P., Martins S., Leitão A.E., Semedo M.C., Silva M.J., Lidon F.C., DaMatta F.M., Ribeiro-Barros A.I. and Ramalho J.C. 2022. Protective Responses at the Biochemical and Molecular Level Differ between a Coffea Arabica L. Hybrid and Its Parental Genotypes to Supra-Optimal Temperatures and Elevated Air (CO2). Plants, 11(20), 2702.
49. Wahyudi T., Pujiyanto, Misnawi. 2016. Kopi : Sejarah, Botani, Proses Produksi Pengolahan, Produksi Hilir, Dan Sistem Kemitraan. Gadjah Mada University Press. Yogyakarta. (in Indonesian)
50. Waktola T.U., Fekadu K. 2021. Adoption of Coffee Shade Agroforestry Technology and Shade Tree Management in Gobu Seyo District, East Wollega, Oromia. Advances in Agriculture, 2021, e8574214.
51. Wang C., Morrissey E.M., Mau R.L., Hayer M., Piñeiro J., Mack M.C., Marks J.C., Bell S.L., Miller S.N., Schwartz E., Dijkstra P., Koch B.J., Stone B.W., Purcell A.M., Blazewicz S.J., Hofmockel K.S., Pett-Ridge J., Hungate B.A. 2021. The Temperature Sensitivity of Soil: Microbial Biodiversity, Growth, and Carbon Mineralization. The ISME Journal, 15(9), 2738–47.
52. Wang R., Zhang H., Sun L., Qi G., Chen S., Zhao X. 2017. Microbial Community Composition Is Related to Soil Biological and Chemical Properties and Bacterial Wilt Outbreak. Scientific Reports, 7(1), 343.
53. Xue H., Tang H. 2018. Responses of Soil Respiration to Soil Management Changes in an Agropastoral Ecotone in Inner Mongolia, China. Ecology and Evolution, 8(1), 220–30.
54. Yu H., Wu X., Zhang G., Zhou F., Harvey P.R., Wang L., Fan S., Xie X., Li F., Zhou H., Zhao X., Zhang X. 2022. Identification of the Phosphorus-Solubilizing Bacteria Strain JP233 and Its Effects on Soil Phosphorus Leaching Loss and Crop Growth. Frontiers in Microbiology, 13.
55. Zhang Q., Zhang Y., Miao P., Chen M., Du M., Pang X., Ye J., Wang H., Jia X. 2023. Effects of Pruning on Tea Tree Growth, Soil Enzyme Activity and Microbial Diversity. Agronomy, 13(5), 1214.
56. Zhang Q., Lei H.M., Yang D.W. 2013. Seasonal Variations in Soil Respiration, Heterotrophic Respiration and Autotrophic Respiration of a Wheat and Maize Rotation Cropland in the North China Plain. Agricultural and Forest Meteorology, 180, 34–43.
57. Zhao, F., Wang J., Zhang L., Ren C., Han X., Yang G., Doughty R., Deng J. 2018. Understory Plants Regulate Soil Respiration through Changes in Soil Enzyme Activity and Microbial C, N, and P Stoichiometry Following Afforestation. Forests, 9(7), 436.
58. Zhou J., Chen Z., Yang Q., Jian C., Lai S., Chen Y., Xu B. 2021. N and P Addition Increase Soil Respiration but Decrease Contribution of Heterotrophic Respiration in Semiarid Grassland. Agriculture, Ecosystems & Environment, 318, 107493.

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Bibliografia

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