Native forests but not agroforestry systems preserve arbuscular mycorrhizal fungal species richness in southern Ethiopia

Belay, Zerihun; Negash, Mesele; Kaseva, Janne; Vestberg, Mauritz; Kahiluoto, Helena

doi:10.1007/s00572-020-00984-6

Cited by 20 publications

(26 citation statements)

References 59 publications

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“…Delelegn et al (2017) and Birhane et al (2020), on the contrary, reported a significant reduction of AMF SA. According to Belay et al (2020) findings, while a significant reduction in AMF SA and morphospecies richness was recorded due to natural forest conversion into Agroforestry, they recorded no significant change in the case of natural forest conversion to a monoculture perennial shrub cultivation. Hence, owing to contrasting findings regarding the AMF resilience to DAF degradation and deforestation and considering the frequent high AMF resilience to tropical forests degradation and deforestation reported from elsewhere (Carrillo‐Saucedo et al, 2018; Johnson & Wedin, 1997; Picone, 2000; Stürmer & Siqueira, 2011; Violi et al, 2008; Zangaro et al, 2013; Zhang et al, 2004), additional AMF resilience studies of DAF degradation and deforestation are merited.…”

Section: Introductionmentioning

confidence: 95%

“…In the past, Lemenih et al (2005) and Tesfaye et al (2016) have studied the effects of DAF degradation and deforestation on the soil physicochemical property. Delelegn et al (2017), Birhane et al (2018, 2020), and Belay et al (2020), on‐the‐other‐hand, investigated the soil physicochemical property and AMF resilience to the degradation and deforestation of DAF. These studies reported a similar and significant reduction in soil organic carbon and total nitrogen due to DAF degradation and deforestation.…”

Section: Introductionmentioning

confidence: 99%

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Soil physicochemical property and arbuscular mycorrhizal fungi resilience to degradation and deforestation of a dry evergreen Afromontane forest in central Ethiopia

et al. 2021

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We investigated the soil physicochemical property and arbuscular mycorrhizal fungi (AMF) resilience to the degradation and deforestation of a dry evergreen Afromontane forest, the Chilimo Forest (CF). Topsoil (1‐10 cm) physicochemical property, AMF spore abundance (SA), and AMF infectivity were determined across four land uses, viz., natural forest (NF), shrubland (ShL), cropland (CrL), and grazing land (GrL). According to the permutational multivariate analysis of variance and nonmetric multidimensional scaling results, soil physicochemical property was resilient to degradation (NF‐ShL conversion) but not deforestation (NF‐CrL or NF‐GrL conversions) of CF. The one‐way ANOVA results indicated that most soil physicochemical variables were significantly (p < 0.05) affected by land‐use change. Soil organic matter and total nitrogen, in particular, reduced significantly (p < 0.05) by up to 48% and 57% due to NF‐CrL and NF‐GrL conversions, respectively. Whereas SA was found to be resilient to both CF degradation and deforestation, AMF infectivity was resilient only to NF‐CrL conversion. Generally, our results did not show a similar pattern in soil physicochemical property, SA, and AMF infectivity resilience to degradation and deforestation. However, in the case of NF‐GrL conversion, both soil physicochemical property and AMF infectivity exhibited significantly (p < 0.05) low resilience. Based on our results, we conclude that soil physicochemical property and AMF are important factors to consider in CF restoration planning. When planting sites are either the croplands or grazing lands, soil amendment could be recommended. AMF inoculation, however, could be recommended when the planting sites are grazing lands. These recommendations may also apply widely to dry evergreen Afromontane forests restoration but additional studies are required.

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Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Soil physicochemical property and arbuscular mycorrhizal fungi resilience to degradation and deforestation of a dry evergreen Afromontane forest in central Ethiopia

et al. 2021

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“…Clay soil is thought to be a suitable condition for the development of Glomus spores. Belay et al (2020) stated that clay fractions dominated native forest plots, 37 morphotypes belonging to 12 genera of Glomeromycota were found and dominated by members of Acaulospora and Glomus. In comparison, soil in the rhizosphere of pine roots was found to have the least diversity, dominated by Glomus (Figure 3).…”

Section: Density and Genus Of Arbuscular Mycorrhizal Fungi In Soilsmentioning

confidence: 99%

The Role of Arbuscular Mycorrhizal Fungi Density and Diversity on The Growth and Biomass of Corn and Sorghum Forage in Trapping Culture

Husein

Umami

Pertiwiningrum

et al. 2022

Trop. Anim. Sci. J.

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This study aimed to determine the effectiveness of arbuscular mycorrhizal fungi (AMF) in the absorption of nutrients in trapping culture and its effects on the growth and biomass production of corn (Zea mays L.) and sorghum (Sorghum sp.). Soil samples with rhizosphere were collected from three different places: Bambusa sp., Cichorium intybus L., and Pinus merkusii. The density and genus of AMF spores were evaluated. AMF effectiveness was tested using six levels of rhizosphere and two species (corn and sorghum) of plants with a 2×6 factorial experiment with eight replications of each treatment. Six types of rhizospheres were: (i) bamboo rhizosphere (Bambusa sp.) (T1), (ii) control for T1 (C1), (iii) chicory rhizosphere (C. intybus L.) (T2), (iv) control for T2 (C2), (v) Pine rhizosphere (P. merkusii) (T3), and (vi) control for T3 (C3). The control treatment was derived from sterilized planting media. The results showed that the root rhizosphere of Bambusa sp. had more density and diversity of AMF spores than the root rhizosphere of C. intybus L. and P. merkusii. At the end of the trapping culture, the host plants sorghum and corn increased the density of spores in the carrier medium or propagules of the three rhizosphere types. The difference in the amount of initial AMF had a significant (p<0.05) effect on plant height, the number of leaves, and the biomass production of trapping plants. It can be concluded that more density and colonization of arbuscular mycorrhizal spores show higher growth and biomass of trapping plants.

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“…The AMF carry out key ecological activities for the operation and management of natural and agricultural systems (Davison et al, 2020;Belay et al, 2020), contributing to plant development, nutrition, and health (Ismail et al 2013;Giovannini et al, 2020;Jaitieng et al, 2020). The best performance of mycorrhizal plants is related to its higher efficiency in water and nutrient absorption (Andrade et al, 2009;Püschel et al 2020) and to improvements in this association in soil quality (Zhang et al, 2017).…”

Section: Introduction and Objectivesmentioning

confidence: 99%

“…The most diversified management of coffee plants in agroforestry systems and native forests increases the diversity of AMF (Dobo et al, 2018;Prates Júnior et al, 2019;Belay et al, 2020). This is related, among others, to the AMF enhancing the soil physical-chemical and biological properties, with better exploitation of ecological interactions.…”

Section: Introduction and Objectivesmentioning

confidence: 99%

Structure of AMF Community in an Agroforestry System of Coffee and Macauba Palm

et al. 2021

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Coffee crop in Brazil is typically grown as a monoculture. However, we hypothesized that agroforestry system is favorable association for arbuscular mycorrhizal fungi (AMF), affecting its community structure and potentially impacting crop productivity and agroecosystem health. This study evaluated how the microclimate, soil depth, macauba field spacing and distance between coffee plants and palms affect the structure of the AMF community. The structure of the AMF community was influenced by the soil depth, microclimate features, soil moisture, maximum air temperature, and photosynthetically active radiation (PAR). The distance at which coffee-macauba influences ecological diversity indices of AMF, and higher diversity are related to the proximity between plants. AMF diversity (Richness and Shannon) in the agroforestry system exceeded that observed in the full-sun coffee in the 0-20 soil depth layer. Our results showed that the microclimate, soil depth, plant density, and distance between coffee from macauba affected the AMF community structure.

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Native forests but not agroforestry systems preserve arbuscular mycorrhizal fungal species richness in southern Ethiopia

Cited by 20 publications

References 59 publications

Soil physicochemical property and arbuscular mycorrhizal fungi resilience to degradation and deforestation of a dry evergreen Afromontane forest in central Ethiopia

Soil physicochemical property and arbuscular mycorrhizal fungi resilience to degradation and deforestation of a dry evergreen Afromontane forest in central Ethiopia

The Role of Arbuscular Mycorrhizal Fungi Density and Diversity on The Growth and Biomass of Corn and Sorghum Forage in Trapping Culture

Structure of AMF Community in an Agroforestry System of Coffee and Macauba Palm

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