Arbuscular mycorrhizal fungi community in coffee agroforestry, consortium and monoculture systems

BARROS, WELLUMA T.; BARRETO-GARCIA, PATRÍCIA A.B.; SAGGIN JÚNIOR, ORIVALDO JOSÉ; SCORIZA, RAFAEL N.; SILVA, MAICON S. DA

doi:10.1590/0001-3765202220201228

Abstract

Understanding the effects of different production systems on arbuscular mycorrhizal fungi (AMF) can help to interpret interactions between their components and to define management strategies. As a result, our study was conducted on soils under three coffee production systems (one homogeneous and two heterogeneous) and in a native forest located in the Bahia state, Brazil. This study aimed to answer the following questions: 1) Does the organization and management of the coffee production system affect the occurrence and diversity of AMF?; and 2) Is the seasonality effect similar between systems? To do so, soil samples (0-10 cm depth) were collected at two times of the year (rainy and dry). Number of spores (NS) and average richness did not show differences between the systems, only between seasons. There was a reduction in NS in the dry season (1.4 and 2.7 spores g^-1 soil) in relation to the rainy season (3.8 to 12.5 spores g^-1 soil). The influence of coffee production systems was observed in the presence and absence of some AMF species. The AMF community was shown to be related to the plant species composition of the system, which was reflected in the dissimilarity of heterogeneous systems in relation to the coffee monoculture system.

Key words
Grevillea robusta; Coffea arabica; Musa spp; Mycorrhizae; seasonality

INTRODUCTION

Coffee (Coffea arabica L. and C. canephora Pierre) is widely cultivated in Brazil and constitutes one of the most important products for the national and world economy, giving the country the title of largest producer and exporter of coffee in the world. The state of Bahia is the fourth largest coffee producer among the Brazilian states, with relevant participation in regional development with an annual production of about 3.8 million 60-kilo sacks of coffee (CONAB 2020CONAB – COMPANHIA NACIONAL DE ABASTECIMENTO. 2020. Acompanhamento da safra brasileira: café – Safra 2020, nº 1, Brasília: Companhia Nacional de Abastecimento (Conab), 62 p.).

The coffee production system most adopted is monoculture in full sun. However, adopting systems which optimize land use and enable biological and socioeconomic benefits has been gaining importance nationally and worldwide. Agroforestry systems (AFS) are considered the land use models which most ecologically resemble native forests (Nair 1993NAIR PKR. 1993. An Introduction do Agroforestry, 1st ed., Dordrecht: Springer Science & Business Media, 499 p., Gama-Rodrigues 2004GAMA-RODRIGUES AC. 2004. Ciclagem de nutrientes em sistemas agroflorestais na região tropical: funcionalidade e sustentabilidade. In: Sistemas agroflorestais, tendência da agricultura ecológica nos trópicos: sustento da vida e sustento de vida. Ilhéus: Sociedade Brasileira de Sistemas Agroflorestais, p. 67-87., Miccolis et al. 2016MICCOLIS A, PENEIREIRO FM & MARQUES HR. 2016. Restauração ecológica com Sistemas Agroflorestais: Como conciliar conservação com produção: Opções para Cerrado e Caatinga. Brasília: Instituto Sociedade, População e Natureza – ISPN/Centro Internacional de Pesquisa Agorflorestal – ICRAF, 266 p.). In these systems there is the association of agricultural crops with tree components which enables an increase in the entry of organic matter into the soil, and as a consequence favors improving its chemical, physical and biological characteristics. In addition, AFS can contribute to greater diversity in the microbial community and soil fauna, which act as biological control agents and soil conditioners (Young 1994YOUNG A. 1994. Agroforestry for soil conservation. Wallingford: CAB/ICRAF, 276 p.).

Understanding the effects of different production systems on soil quality can assist in interpreting interactions between its components and in defining management strategies (Marshall 2000MARSHALL VG. 2000. Impacts of forest harvesting on biological processes in northern forest soils. For Ecol Manag 1331: 43-60.). Arbuscular mycorrhizal fungi (AMF) are among the biological attributes of the soil which are considered sensitive to changes in the environment. These organisms form symbiotic associations in the roots of host plants (Pereira et al. 2018PEREIRA JES, GARCIA P, SCORIZA RN, SAGGIN JUNIOR OJ & GOMES VS. 2018. Arbuscular mycorrhizal fungi in soils of arboreal Caatinga submitted to forest management. Rev. Bras. Cienc. Agrar 13: 1-6.). Thus, plants are able to meet the demands of the AMF for carbon compounds through this relationship (Moreira & Siqueira 2006MOREIRA FMS & SIQUEIRA JO. 2006. Microbiologia e bioquímica do solo, 2ª ed., Lavras: Editora UFLA, 744 p., Ghazanfar et al. 2016GHAZANFAR B, ZHIHUI C, WU C, LIU H, LI H, REHMAN RNU, AHMAD I & KHAN AR. 2016. Glomus etunicatum root inoculation and foliar application of acetyl salicylic acid induced nacl tolerance by regulation of Nac1 & Lenhx1 gene expression and improved photosynthetic performance in tomato seedlings. Pak J Bot 48: 1209-1217.), while fungi favor absorption of nutrients from the soil (Mergulhão et al. 2014MERGULHÃO ACES, SILVA MV, LYRA MCCP, FIGUEIREDO MVB, SILVA MLRB & MAIA LC 2014. Caracterização morfológica e molecular de fungos micorrízicos arbusculares isolados de áreas de mineração de gesso, Araripina, PE, Brasil. Hoehnea 41: 393-400.). In addition, AMF provide several other benefits such as favoring moisture retention, aggregate formation, soil stability (Nobre et al. 2015NOBRE CP, LÁZARO, ML, SANTO MME, PEREIRA MG & BERBARA RLL. 2015. Agregação, glomalina e carbono orgânico na chapada do Araripe, Ceará, Brasil. Rev Caatinga 28: 138-147.) and stimulating the primary defense system of plants to attack pathogens (Mechri et al. 2014MECHRI B, MANGA AG, TEKAYA M, ATTIA F, CHEHEB H, MERIEM FB, BRAHAMD M, BOUJNAHD D & HAMMAMI M. 2014. Changes in microbial communities and carbohydrate profiles induced by the mycorrhizal fungus (Glomus intraradices) in rhizosphere of olive trees (Olea europaea L.). Appl Soil Ecol 75: 124-133.), which increases their tolerance to biotic stress caused by diseases (Calvo-Polanco et al. 2016CALVO-POLANCO M, SÁNCHEZ-CASTRO I, CANTOS M, GARCÍA JL, AZCÓN R, RUIZ-LOZANO JM, BEUZÓN CR & AROCA R. 2016. Effects of different arbuscular mycorrhizal fungal backgrounds and soils on olive plants growth and water relation properties under well-watered and drought conditions. Plant Cell & Environ 39: 2498-2514., Meddad-Hamza et al. 2017MEDDAD-HAMZA A, HAMZA N, NEFFAR S, BEDDIAR A, GIANINAZZI S & CHENCHOUNI H. 2017. Spatiotemporal variation of arbuscular mycorrhizal fungal colonization in olive (Olea europaea L.) roots across a broad mesic-xeric climatic gradient in North Africa. Sci Total Environ 583: 176-189.).

The occurrence of AMF is regulated by several biotic and abiotic factors which influence the abundance and survival of infectious propagules (Mello et al. 2012MELLO CMA SILVA IR, PONTES JS, GOTO BT, SILVA GA & MAIA LC. 2012. Diversidade de fungos micorrízicos arbusculares em área de Caatinga, PE, Brasil. Acta Bot Bras 26: 938-943.) and the richness of communities (Sousa et al. 2014SOUSA CS, MENEZES RSC, SAMPAIO EVSB, LIMA FS, MAIA LC & OEHL F. 2014. Arbuscular mycorrhizal fungi in successional stages of Caatinga in the semi-arid region of Brazil. Ciência Florestal 24: 137-148., Ferreira et al. 2018FERREIRA PFA, SILVA LC, MARTINEZ HAR, FERREIRA KAL & NOBRE CP. 2018. Efeito da sazonalidade na comunidade de Fungos Micorrízicos Arbusculares em áreas com Mimosa caesalpiniifolia. R Tróp Ci Agr Biol 10: 105-113.), altering the root colonization process in plants (Rocha et al. 2020ROCHA LPM, MOREIRA FW, OLIVEIRA CM & OLIVEIRA LA. 2020. Ocorrência de fungos micorrízicos arbusculares em um plantio de cupuaçu na estrada de Balbina, Amazonas. Rev Ibero-Am Ciênc Ambient 11: 78-84., Moreira et al. 2019MOREIRA FW, DE OLIVEIRA CM, MAIA JLZ & OLIVEIRA LA. 2019. Fungos micorrízicos arbusculares nas plantas e características químicas dos solos de clareiras da Província Petrolífera de Urucu, Am. Rev Ibero-Am Ciênc Ambient 10: 56-68.). Among these factors there are climatic conditions, the cultivation system organization (homogeneous or heterogeneous) and the adopted management (Martínez-García et al. 2012MARTÍNEZ-GARCÍA LB, MIRANDA JD & PUGNAIRE FI. 2012. Impacts of changing rainfall patterns on mycorrhizal status of a shrub from arid environments. Eur J Soil Biol 50: 64-67., Carrenho et al. 2010CARRENHO R, GOMES-DA-COSTA SM, BALOTA EL & COLOZZI-FILHO A. 2010. Fungos micorrízicos arbusculares em agroecossistemas Brasileiros. In: Micorrizas: 30 anos de pesquisa no Brasil. 7th ed., Lavras: Editora UFLA, p. 215-278.).

The climate directly controls forming an association and establishing AMF communities due to temperature variations and water availability, and indirectly according to the plants’ demand for water and nutrients which is higher at certain times of the year (Santos et al. 2014SANTOS RS, BARRETO PAB & SCORIZA RN. 2014. Efeito da sazonalidade na comunidade de fungos micorrízicos arbusculares em um fragmento de mata de cipó em Vitória da Conquista, Bahia. Rev Bras Biocienc 12: 46-51.). Similarly, the cultivation system also influences the AMF community according to its characteristics (Posada et al. 2016POSADA RH, DE PRAGER MS, HEREDIA-ABARCA G & SIEVERDING E. 2016. Effects of soil physical and chemical parameters, and farm management practices on arbuscular mycorrhizal fungi communities and diversities in coffee plantations in Colombia and Mexico. Agrofor Syst 92: 555-574.). For example, a homogeneous (monoculture) system tends to provide a less favorable environment to root colonization and diversity of AMF species when compared to heterogeneous systems such as AFS or a native forest (Siqueira et al. 2010SIQUEIRA JO, SOUZA FA, CARDOSO EJBN & TSAI SM. 2010. Micorrizas: 30 anos de pesquisas no Brasil. Lavras: Editora UFLA, 716 p., Prates Júnior et al. 2019PRATES JÚNIOR P, MOREIRA BC, SILVA MDCS, VELOSO TGR, STÜRMER SL, FERNANDES RBA & KASUYA MCM. 2019. Agroecological coffee management increases arbuscular mycorrhizal fungi diversity. Plos One 14: 1-9.). This is because the species composition of the system interferes with plant-fungus interactions because AMF occurrence and distribution are conditioned by the existence of suitable hosts (Verbruggen et al. 2012VERBRUGGEN E, VAN DER HEIJDEN MG, WEEDON JT, KOWALCHUK GA & RÖLING WF. 2012. Community assembly, species richness and nestedness of arbuscular mycorrhizal fungi in agricultural soils. Mol Ecol 21: 2341-2353.) and by the release of root exudates (Ajeesh et al. 2015AJEESH R, VIKAS K, SANTOSHKUMAR AV & SURENDRA GKH. 2015. Arbuscular Mycorrhizal Fungi (AMF) for Quality Seedling Production. Res J Agriculture Forestry Sci 3: 22-40.). In addition, implementing management techniques such as soil movement also affects the AMF as it causes hyphae disruption, and as a consequence propagule and spore exposure, thus decreasing their infectious capacity (Jasper et al. 1991JASPER DA, ABBOTT LK & ROBSON AD. 1991. The effect of soil disturbance on vesicular-arbuscular mycorrhizal fungi in soils from different vegetation types. New Phytol 118: 471-476., Kabir et al. 1997KABIR Z, O’HALLORAN IP, FYLES JW & HAMEL C. 1997. Seasonal changes of arbuscular mycorrhizal fungi asaffected by tillage pratices and fertilization: hyphaldensity and mycorrhizal root colonization. Plant Soil 192: 285-293., Caproni et al. 2003CAPRONI AL, FRANCO AA, BERBARA RLL, TRUFEM SB, GRANHAI JRDO & MONTEIRO AB. 2003. Ocorrência de fungos micorrízicos arbusculares em áreas revegetadas após mineração de bauxita em Porto Trombetas, Pará. Pesq Agropec Bras 38: 1409-1418., Hu et al. 2015HU J, YANG A, WANG J, ZHU A, DAI J, WONG MH & LIN X. 2015. Arbuscular mycorrhizal fungal species composition, propagule density, and soil alkaline phosphatase activity in response to continuous and alternate no-tillage in Northern China. Catena 133: 215-220.).

Several studies on the AMF community have been carried out in Brazil on monoculture crop systems, agroforestry systems and native forests (Loss et al. 2009LOSS A, ANGELINI GAR, PEREIRA ACC, LÃ RR, MAGALHÃES MOL, SILVA EMR & SAGGIN JUNIOR OJ. 2009. Atributos químicos do solo e ocorrência de fungos micorrízicos sob áreas de pastagem e sistema agroflorestal, Brasil. Acta Agron. 58: 91-95, Ferreira et al. 2012FERREIRA DA, CARNEIRO MAC & SAGGIN JUNIOR OJ. 2012. Fungos micorrízicos arbusculares em um Latossolo Vermelho sob manejos e usos no Cerrado. Rev Bras Cienc Solo 36: 51-61., Costa et al. 2013COSTA RSC, MENDES AM, RODRIGUES VGS & LEÔNIDAS FC. 2013. Micorrizas arbusculares em sistemas agroflorestais. Porto Velho: Embrapa, 18 p., Santos et al. 2014SANTOS RS, BARRETO PAB & SCORIZA RN. 2014. Efeito da sazonalidade na comunidade de fungos micorrízicos arbusculares em um fragmento de mata de cipó em Vitória da Conquista, Bahia. Rev Bras Biocienc 12: 46-51., Lima et al. 2015LIMA KB, NETTO AFR, MARTINS MA & FREITAS MSM. 2015. Crescimento, acúmulo de nutrientes e fenóis totais de mudas de cedro-australiano (Toona ciliata) inoculadas com fungos micorrízicos. Ciência Florestal 25: 853-862., Souza et al. 2016SOUZA CA, GALLARDO ALCF, SILVA ÉD, MELLO YC, RIGHI CA & SOLERA ML. 2016. Serviços Ambientais Associados à Recuperação de Áreas degradadas por Mineração: Potencial para Pagamento de Serviços Ambientais. Ambient Soc 19: 139-166., Durazzini et al. 2016DURAZZINI AM, TEIXEIRA MA & ADAMI AA. 2016. Quantificação de esporos de fungos micorrízicos arbusculares (FMAs) em solo sob diferentes cultivos de cafeeiros. Rev Agrogeoambiental 8: 83-91., Pereira et al. 2018PEREIRA JES, GARCIA P, SCORIZA RN, SAGGIN JUNIOR OJ & GOMES VS. 2018. Arbuscular mycorrhizal fungi in soils of arboreal Caatinga submitted to forest management. Rev. Bras. Cienc. Agrar 13: 1-6., Martins et al. 2019MARTINS EM, SILVA ERD, CAMPELLO EFC, LIMA SSD, NOBRE CP, CORREIA MEF & RESENDE ASD. 2019. O uso de sistemas agroflorestais diversificados na restauração florestal na Mata Atlântica. Ciência Florestal 29: 632-648.). However, studies comparing different coffee production systems are still scarce (Bonfim et al. 2010BONFIM JA, MATSUMOTO SN, LIMA JM, CÉSAR FRCF & SANTOS MAF. 2010. Fungos micorrízicos arbusculares (FMA) e aspectos Fisiológicos em cafeeiros cultivados em sistema agroflorestal e a pleno sol. Bragantia 69: 201-206., Durazzini et al. 2016DURAZZINI AM, TEIXEIRA MA & ADAMI AA. 2016. Quantificação de esporos de fungos micorrízicos arbusculares (FMAs) em solo sob diferentes cultivos de cafeeiros. Rev Agrogeoambiental 8: 83-91.), especially those which evaluate native forest as a reference system.

Given the above, our study aimed to answer the following questions: 1) Does the organization and management of the coffee production system affect the occurrence and diversity of AMF community?; and 2) Is the seasonality effect similar between systems? To do so, the AMF community in three coffee production systems (one homogeneous and two heterogeneous) and in a native forest (which was used as a reference) were evaluated. It was assumed that the production system causes different magnitudes of change in the structure and composition of the AMF community according to its organization and management.

MATERIALS AND METHODS

Area descriptions

The study was conducted in the district of Lucaia, municipality of Planalto, Southwest region of the state of Bahia, Brazil. Three coffee production systems and a natural vegetation area were evaluated: (1) AFS - Coffea arabica L. with Grevillea robusta agroforestry system, 17 years old and spacing 3.5 x 15.0 m (between trees) and 1.5 x 2.5 m (among coffee trees) (14° 44’ 58” S and 40° 32’ 21” W); (2) BC - Coffea arabica L. with banana (Musa spp.) consortium, aged 17 years old, including drastic coffee pruning (Stumping) at the age of eight, and established in 1.5 x 4 spacing, 0 m (among coffee trees) and 1.0 x 16.0 m (among banana trees) (14° 45’ 01” S and 40° 31’ 24” W); and (3) MC - Coffea arabica L. monoculture, 15 years old, with two stumpings and 1.5 x 2.5 m spacing (14° 45’ 08” S and 40° 32’ 27” W); and (4) NF - native forest, which was used as a reference system and is located in an area adjacent to the coffee systems (14° 44’ 52” S and 40° 31’ 21” W).

The native forest fragment has vegetation classified as Semi-deciduous Seasonal Forest and a total area of about 30 hectares. It is a forest with relatively low arboreal stratum (between 10 and 15 m high), with a predominance of the Parapiptadenia and Anadenanthera genera (IBGE 2012IBGE - INSTITUTO BRASILEIRO DE GEOGRAFIA E ESTATÍSTICA. 2012. Manual técnico da vegetação brasileira: sistema fitogeográfico, inventário das formações florestais e campestres, técnicas e manejo de coleções botânicas, procedimentos para mapeamentos. Rio de Janeiro-RJ: IBGE - Diretoria de Geociências, (Manuais Técnicos de Geociências, 1), 271 p.) and intermediate regeneration stage according to criteria described in CONAMA Resolution #01/1994 (Brasil 1994BRASIL. 1994. Resolução CONAMA nº. 1, de 31 de Janeiro de 1994. Brasília: Diário Oficial da União, 1684-1685 p.), since it has not been submitted to any intervention for over 20 years.

The AFS was established from opening furrows with planting fertilization (20 Mg ha^-1 of simple superphosphate) and annual organic cover-maintenance fertilization (32 Mg ha^-1 of bovine manure). Soil tillage with plowing, harrowing and furrowing, planting fertilization (20 Mg ha^-1 of simple superphosphate) and annual maintenance (17 Mg ha^-1 of urea and 33 Mg ha^-1 of NPK 20-00-20) were adopted in the BC and MC systems. Maintenance was performed twice a year in all systems with clearing to control spontaneous herbs.

The region has a tropical altitude climate (Cwb) according to the Köppen classification, with an average altitude of 923 meters above sea level (SEI 2013SEI. 2013. Estatística dos municípios baianos: Território de Identidade - Vitória da Conquista. Publicações SEI. Salvador 4: 433-452.), average annual temperature of 19.2°C and an average annual rainfall of 750 mm. The monthly rainfall data from September 2017 to July 2018 are shown in Figure 1. The soil in the studied areas is classified as Oxisol according to the USDA-Natural Resources Conservation Service classification (Soil Survey Staff, 2014), and dystrophic Yellow Latossol according to the Brazilian Classification System (Santos et al. 2018aSANTOS HG, JACOMINE PKT, ANJOS LHC, OLIVEIRA VA, LUMBRERAS JF, COELHO MR, ALMEIDA JÁ, ARAUJO FILHO JC, OLIVEIRA JB & CUNHA TJF. 2018a. Sistema Brasileiro de Classificação de Solos, 5ª ed., Brasília: Embrapa, 356 p.).

Figure 1
Monthly rainfall recorded at the station closest to the study site (municipality of Vitória da Conquista, Bahia, Brazil), from September 2017 to July 2018 (Source: INMET 2020INMET - INSTITUTO NACIONAL DE METEOROLOGIA. 2020. Banco de Dados Meteorológicos para Ensino e Pesquisa — BDMEP. Disponível em: http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep. Acesso em: 02 de junho de 2020.
http://www.inmet.gov.br/portal/index.php... ).

Soil and litter sampling

First, four plots of 20 m x 20 m (400 m²) were demarcated randomly in each system, ensuring a minimum distance of 10 m between plots. The soil and litter collections were carried out in the months of December 2017 (beginning of the rainy season) and April 2018 (beginning of the dry season).

Random soil sampling was performed after removing (cleaning) the litter, collecting 10 individual samples (depth 0-10 cm) which were gathered to form a composite sample from each plot. The accumulated surface litter was collected with a square wooden template of 0.25 m² (0.5 m x 0.5 m) which was randomly thrown over the area of each plot. The litter samples were dried in an oven at 65ºC, then weighed on a precision scale (0.01g) and the dry mass results were converted to Mg ha^-1.

The soils were chemically characterized according to Table I following the procedures described by EMBRAPA (2017)EMBRAPA. 2017. Serviço Nacional de Pesquisa do Solo. Manual de métodos de análises de solo, 3ª ed., Brasília: Embrapa, 575 p.: pH in water; extractable P and K by Mehlich^-1; Ca²⁺, Mg²⁺ and Al³⁺ exchangeable with 1 mol L^-1 of KCl; and organic matter by oxidation with 0.4 mol L^-1 of K₂Cr₂O₇.

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Table I
Chemical attributes and humidity of Dystrophic Yellow Latossol (depth 0-10 cm) under three coffee production systems and in native forest.

Spore extraction, counting and identification

First, 50 g of each soil sample were used to extract the arbuscular mycorrhizal fungi (AMF) spores, adopting an adapted procedure described for nematodes according to the wet-sieving methodology (Gerdemann & Nicolson 1963GERDEMANN JW & NICOLSON TH. 1963. Spores of mycorrhizal endogone species extracted from soil by wet-sieving and decanting. Trans Br Mycol Soc 46: 235-244.) and centrifugation in density gradient with water and 45% sucrose (Jenkins 1964JENKINS WR. 1964. A rapid centrifugal-flotation technique for separating nematodes from soil. Plant Dis 28: 692.). Next, spore counting and species identification were performed using a stereoscopic microscope, referring to the Schenck & Pérez manual (1988SCHENCK NC & PÉREZ Y. 1988. Manual for the identification of VA mycorrhizal fungi, 2nd ed., Gainesville: INVAM, 245 p.) and the international collection website of AMF - INVAM (2020INVAM. 2020. International culture collection of (vesicular) arbuscular mycorrhizal fungi. Disponivel em: http://www.invam.caf.wvu.edu/ Acesso em: maio. 2020.
http://www.invam.caf.wvu.edu/ Acesso em:... , https://invam.wvu.edu/).

Data analysis

The number of AMF spores counted in 50 cm³ of soil was transformed into the abundance of spores g^-1 of soil. Furthermore, total spore richness, mean richness and occurrence frequency have been calculated in each of the four plots (repetitions) per site.

The obtained data were analyzed for normality (Shapiro-Wilk) and homogeneity (Cochran and Bartlett test) of the error variances, and converted when necessary. Parametric data were subjected to analysis of variance (ANOVA) when found, according to a completely randomized design (CRD). Multiple comparisons of the means were performed between times and between treatments by the Tukey test at 5% significance when ANOVA showed a significant result in the F-test (p < 5%). The analyzes were performed using the Assistat® v.7.7 statistical software program.

The presence-absence of the AMF species (occurrence or non-occurrence of species, respectively), accumulated litter and soil moisture data were complementarily submitted to a principal component analysis (PCA) using the Addinsoft XLSTAT® Version 2020.1.3 (1995-2020) program. This analysis was performed to synthesize the multidimensional variation of the treatments in a diagram and order them into the components according to their similarities around the measured soil variables. The interrelationships between attributes of soil, litter, spore numbers and AMF richness were analyzed using Pearson’s 5% correlation using the SAEG® v.9.1 program.

RESULTS

The variation pattern in litter accumulation between the systems was the same at both times of the year (Table II). The highest value was observed in the native forest (12.26 Mg ha^-1), followed by AFS (6.07 Mg ha^-1), which was not distinguished from the consortium (3.66 Mg ha^-1), which in turn was similar to monoculture (0.78 Mg ha^-1).

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Table II
Accumulated litter (Mg ha^-1), average number of spores (in 50 g of soil) and richness of arbuscular mycorrhizal fungi species in three coffee production systems and in native forest at two times of the year.

A total of 16 AMF species were identified and presented different occurrence frequencies according to the systems and time of year (Table III). Of this total, 15 species occurred in the rainy season and ten species in the dry season. This was reflected in greater total species richness in the rainy season for all studied systems (Table II), although the average richness only showed differences between seasons in the NF. Following this same pattern, a reduction in the number of spores (NS) was observed in the dry season for most systems. The total density in the rainy season varied from 3.8 to 12.5 spores g^-1 soil, while the density in the dry season was between 1.4 and 2.7 spores g^-1 soil (Table II).

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Table III
Frequency of occurrence (%) of arbuscular mycorrhizal fungi species at two times of the year in three coffee production systems and in native forest.

Although no significant variations were observed between the systems regarding the number of spores and AMF richness (Table II), significant correlations were observed between mean species richness and soil pH (r = -0.66; p < 0.05), litter (r = 0.67; p<0.05), soil moisture (r = 0.87; p<0.05) and SOM (r = 0.70; p<0.05). In addition, differences were observed regarding the presence and absence of AMF species (Table III). The Acaulospora denticulata, Acaulospora mellea, Acaulospora scrobiculata and Claroideoglomus etunicatum species only occurred in coffee production systems. Glomus macrocarpum and Sclerocystis clavispora occurred in all systems studied at both times of the year. Acaulospora tuberculata, Gigaspora sp. and Racocetra persica exclusively occurred in the native forest during the rainy season. On the other hand, Claroideoglomus etunicatum only occurred in monoculture in the dry season, and Sieverdingia tortuosa occurred in all systems in the rainy season and in almost all of them in the dry season.

The most abundant genera in the two seasons considering all the studied systems were Acaulospora and Glomus (Table III), representing approximately 56% of the total number of AMF identified.

When analyzed together using PCA, the accumulated litter, soil moisture and presence and absence of AMF species explained more than 86% of the variation between treatments using the first two principal components in the two studied seasons (87.0% in the rainy season) and 92.6% in the dry season) (Figure 2). The graphic dispersion of the treatments in relation to the axes showed a similar pattern between the two periods (Figure 2b and 2d), with isolation of the NF (next to the principal component 1, PC1) and the MC (next to the principal component 2, PC2), which were in different quadrants. It also showed clustering of AFS and BC, which were located in the same quadrant between PC1 and PC2.

Figure 2
Diagram of the ordering of variables and treatments in the rainy season (a and b) and in the dry season (c and d) produced by the principal components analysis of the presence-absence of arbuscular mycorrhizal fungi, litter and soil moisture in three coffee production systems and in native forest in Planalto, Bahia, Brazil.

Eigenvalues of 63.5% for PC1 and 23.5% for PC2 were verified in the rainy season. The variables most associated with PC1 (and therefore the most prevalent for differentiating the native forest, AFS and BC) were: litter, moisture and A. scrobiculata, A. tuberculata, Am. Leptoticha, Gigaspora sp., R. persica (Figure 2a, Table IV). In turn, the variables most strongly associated with PC2 and consequently with MC were A. denticulata, A. foveata, A. mellea, Glomus sp.1 and Glomus sp. (Figure 2a, Table IV).

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Table IV
Factor loadings and variability explained by the axes in the principal component analysis (PCA) of the presence-absence of arbuscular mycorrhizal fungi, litter and soil moisture in three coffee production systems and in native forest in the rainy and dry seasons in Planalto, Bahia, Brazil.

The PCA for the dry season presented eigenvalues of 52.3% (PC1) and 40.4% (PC2). In addition to the A. mellea and A. scrobiculata species, litter and moisture were among the variables most associated with PC1 in the dry season following a similar pattern to the rainy season. The most important variables for PC2 were the Am. Leptoticha, C. pellucida, Cl. etunicatum and G. glomerulatum species (Figure 2c, Table IV).

DISCUSSION

The greater litter accumulation in the NF can be attributed to the species composition and diversity in the native ecosystem which enables greater plant residue additions. This highlights the significant contribution of the tree component to the litter supply and also explains the fact that the AFS has the second most significant accumulation, although without distinction from the BC. Likewise, the smaller amount of litter stocked in the monoculture compared to NF and AFS is explained by the system’s homogeneous characteristic which provides less diversity and less litter. In evaluating different coffee production systems, Meylan et al. (2017)MEYLAN L, GARY C, ALLINNE C, ORTIZ J, JACKSON L & RAPIDEL B. 2017. Evaluating the effect of shade trees on provision of ecosystem services in intensively managed coffee plantations. Agric Ecosyst Environ 245: 32-42. observed a greater amount of litter in the shaded systems with Erythrina and or with banana in relation to the system in full sun.

Litter accumulation was maintained in most of the studied systems when comparing the seasons, with the exception of the native forest which showed a significant increase in the rainy season (Table II). The fact that it only varied in the NF is related to the typical seasonal pattern of semi-deciduous seasonal forests, with litter deposition peaks coinciding with the end of the dry season as a vegetation response to climatic variation (Dias & Oliveira-Filho 1997DIAS HCT & OLIVEIRA-FILHO AT. 1997. Variação temporal e espacial da produção de serapilheira em uma área de floresta estacional semidecídua Montana em Lavras-MG. Rev Arvore 21: 11-26., Santos Neto et al. 2015SANTOS NETO AP, BARRETO PAB, GAMA-RODRIGUES EF, NOVAES AB & PAULA A. 2015. Produção de serapilheira em Floresta Estacional Semidecidual e em plantios de Pterogyne nitens Tul. e Eucalyptus urophylla S. T. Blake no sudoeste da Bahia. Ciência Florestal 25: 633-643., Barreto-Garcia et al. 2019BARRETO-GARCIA PAB, OLIVEIRA MF, OLIVEIRA FGR & LACERDA LRL. 2019. Edge Effect on the Litter Production of a Semi-Deciduous Seasonal Forest Fragment. Floresta Ambient 26: 1- 9.), which in turn is reflected in greater litter accumulations at the beginning of the rainy season. These larger accumulations are usually associated with the influence of rain which creates more favorable conditions for leaf renewal and due to leaves and branches falling by mechanical action (Dias & Oliveira-Filho 1997DIAS HCT & OLIVEIRA-FILHO AT. 1997. Variação temporal e espacial da produção de serapilheira em uma área de floresta estacional semidecídua Montana em Lavras-MG. Rev Arvore 21: 11-26., Vendrami et al. 2012VENDRAMI JP, JURINITZ CF & CASTANHO CT. 2012. Litterfall and leaf decomposition in forest fragments under different successional phases on the Atlantic Plateau of the state of Sao Paulo, Brazil. Biota Neotrop 12: 136-143.).

The reduction in the number of species, NS and richness in the dry season indicates that only the species which are more resistant to water deficit conditions would present reproduction and dispersion structures in the dry season. This denotes that the AMF community becomes less complex in low water availability conditions, thus preserving the most tolerant species (Santos et al. 2014SANTOS RS, BARRETO PAB & SCORIZA RN. 2014. Efeito da sazonalidade na comunidade de fungos micorrízicos arbusculares em um fragmento de mata de cipó em Vitória da Conquista, Bahia. Rev Bras Biocienc 12: 46-51.). Despite this, no significant differences in soil moisture were observed between the seasons of the year in all studied sites (Table I), which must be related to the fact that the soil was sampled on only one date, and therefore did not reflect average humidity conditions. According to Mangan et al. (2004)MANGAN SA, EOM AH, ADLER GH, YAVITT JB & HERRE EA. 2004. Diversity of arbuscular mycorrhizal fungi across a fragmented forest in Panama: insular spore communities differ from mainland communities. Oecologia 141: 687-700., seasonality affects the occurrence of AMF as the species produce their spores at different times of the year, and these become physiologically active in seasons which are more conducive to their development. Reductions in the number of spores in the dry season were also observed by Khaekhum et al. (2017)KHAEKHUM S, LUMYONG S, KUYPER TW & BOONLUE S. 2017. Species richness and composition of arbuscular mycorrhizal fungi occurring on eucalypt trees (Eucalyptus camaldulensis Dehnh.) in rainy and dry season. Curr Res Environ Appl Mycol 7: 282-292. and Ramos-Zapata et al. (2011)RAMOS-ZAPATA JA, ZAPATA-TRUJILLO R, ORTÍZ-DÍAZ JJ & GUADARRAMA P. 2011. Arbuscular mycorrhizas in a tropical coastal dune system in Yucatan, Mexico. Fungal Ecol 4: 256-261. in eucalyptus stands and coastal dunes, respectively.

The absence of variation in NS and average richness between systems suggests that the coffee production systems did not cause changes in these attributes for the AMF community under the studied conditions. However, variations in NS were observed by Bonfim et al. (2010)BONFIM JA, MATSUMOTO SN, LIMA JM, CÉSAR FRCF & SANTOS MAF. 2010. Fungos micorrízicos arbusculares (FMA) e aspectos Fisiológicos em cafeeiros cultivados em sistema agroflorestal e a pleno sol. Bragantia 69: 201-206. and Durazzini et al. (2016)DURAZZINI AM, TEIXEIRA MA & ADAMI AA. 2016. Quantificação de esporos de fungos micorrízicos arbusculares (FMAs) em solo sob diferentes cultivos de cafeeiros. Rev Agrogeoambiental 8: 83-91. when comparing agroforestry coffee systems with monoculture coffee systems.

The occurrence of the Acaulospora denticulata, Acaulospora mellea, Acaulospora scrobiculata and Claroideoglomus etunicatum species only in the coffee production systems is in line with the results found by Fernandes & Siqueira (1989)FERNANDES AB & SIQUEIRA JO. 1989. Micorrizas vesicular-arbusculares em cafeeiros da região sul do Estado de Minas Gerais. Pesqui Agropecu Bras 24: 1489-1498., who observed the occurrence of these same species (except Acaulospora denticulate) in coffee plantations in the south of Minas Gerais. This reveals a high adaptation of these species to the edaphoclimatic conditions prevalent in coffee ecosystems (Theodoro et al. 2003THEODORO VCA, ALVARENGA MIN, GUIMARÃES RJ & MOURÃO-JÚNIOR M. 2003. Carbono biomassa e micorriza em solo sob mata nativa e agroecossistemas cafeeiros. Acta Sci Agron 25: 147-153.). For example, Acaulospora mellea was one of the species most commonly found in coffee plantations in Colombia and Mexico (Posada et al. 2016POSADA RH, DE PRAGER MS, HEREDIA-ABARCA G & SIEVERDING E. 2016. Effects of soil physical and chemical parameters, and farm management practices on arbuscular mycorrhizal fungi communities and diversities in coffee plantations in Colombia and Mexico. Agrofor Syst 92: 555-574.).

The presence of Glomus macrocarpum and Sclerocystis clavispora in all systems studied and at both times of the year suggests that these fungi have adapted well to the conditions of all studied systems. Glomus macrocarpum is usually reported as a species with a high capacity to adapt to stress and climatic variations, and therefore it is commonly found in different environmental conditions (Carvalho et al. 2012CARVALHO F, SOUZA FA, CARRENHO R, MOREIRA FMS, JESUS EC & FERNANDES GW. 2012. The mosaic of habitats in the high-altitude Brazilian rupestrian fields is a hotspot for arbuscular mycorrhizal fungi. Agric Ecosyst Environ Appl Soil Ecol 52: 9-19., Ferreira et al. 2012FERREIRA DA, CARNEIRO MAC & SAGGIN JUNIOR OJ. 2012. Fungos micorrízicos arbusculares em um Latossolo Vermelho sob manejos e usos no Cerrado. Rev Bras Cienc Solo 36: 51-61., Carneiro et al. 2015CARNEIRO M AC, FERREIRA DA, SOUZA EDD, PAULINO HB, JUNIOR OJS & SIQUEIRA JO. 2015. Arbuscular mycorrhizal fungi in soil aggregates from fields of “murundus” converted to agriculture. Pesq Agropec Bras 50: 313-321., Silva et al. 2016SILVA CFD, PEREIRA MG, SANTOS VLD, MIGUEL DL & SILVA EMRD. 2016. Fungos micorrízicos arbusculares: composição, comprimento de micélio extrarradicular e glomalina em áreas de Mata Atlântica, Rio de Janeiro. Ciência Florestal 26: 419-430.). On the other hand, the occurrence of Sclerocystis clavispora is more common in the dry season (Al-Yahya’Ei et al. 2011AL-YAHYA’EI MN, OEHL F, VALLINO M, LUMINI E, REDECKER D, WIEMKEN A & BONFANTE P. 2011. Unique arbuscular mycorrhizal fungal communities uncovered in date palm plantations and surrounding desert habitats of Southern Arabia. Mycorrhiza 21: 195-209., Silva et al. 2016SILVA CFD, PEREIRA MG, SANTOS VLD, MIGUEL DL & SILVA EMRD. 2016. Fungos micorrízicos arbusculares: composição, comprimento de micélio extrarradicular e glomalina em áreas de Mata Atlântica, Rio de Janeiro. Ciência Florestal 26: 419-430., 2019).

The exclusivity of Acaulospora tuberculata, Gigaspora sp. and Racocetra persica in the native forest is possibly related to the characteristics of this environment which is more biologically complex than coffee systems, has higher levels of organic matter in the soil and is less subject to temperature and moisture variations. This would favor the survival of more demanding species in climate and soil conditions. Several records of the occurrence of these species are found in the literature (Santos et al. 2014SANTOS RS, BARRETO PAB & SCORIZA RN. 2014. Efeito da sazonalidade na comunidade de fungos micorrízicos arbusculares em um fragmento de mata de cipó em Vitória da Conquista, Bahia. Rev Bras Biocienc 12: 46-51., 2018b, Pereira et al. 2018PEREIRA JES, GARCIA P, SCORIZA RN, SAGGIN JUNIOR OJ & GOMES VS. 2018. Arbuscular mycorrhizal fungi in soils of arboreal Caatinga submitted to forest management. Rev. Bras. Cienc. Agrar 13: 1-6., Silva et al. 2019SILVA FF, SANTOS TA, JESUS EC & CHAER GM. 2019. Caracterização de rizóbios e fungos micorrízicos arbusculares em áreas impactadas pela exploração de piçarra na Caatinga. Rev Caatinga 32: 995-1004.).

The presence of Claroideoglomus etunicatum only in the dry season is also in agreement with several studies which found the occurrence of this species being associated with water restriction periods, including in studies by Pedone-Bonfim et al. (2018)PEDONE-BONFIM MVL, DA SILVA DKA, MAIA LC & YANO-MELO AM. 2018. Mycorrhizal benefits on native plants of the Caatinga, a Brazilian dry tropical forest. Symbiosis 74: 79-88. and Teixeira-Rios et al. (2013)TEIXEIRA-RIOS T, SOUZA RGD, MAIA LC, OEHL F & LIMA CEP. 2013. Arbuscular mycorrhizal fungi in a semi-arid, limestone miningimpacted area of Brazil. Acta Bot Bras 27: 688-693. in dry tropical forests, and Sousa et al. (2013)SOUSA CS, MENEZES RSC, SAMPAIO EVSB, LIMA FS, OEHL F & MAIA LC. 2013 Arbuscular mycorrhizal fungi within agroforestry and traditional land use systems in semi-arid Northeast Brazil. Acta Sci Agron 35: 307-314. in cultivated areas in the semi-arid region of Brazil. On the other hand, the fact that this species only occurred in the MC suggests that the system provided some factor favorable to its occurrence or sporulation, such as the pH which was relatively higher in this system (Table I). Corroborating this hypothesis, a significant negative correlation was observed between mean species richness and soil pH. According to Zhu et al. (2007)ZHU HH, YAO Q, SUN XT & HU YL. 2007. Colonization, ALP activity and plant growth promotion of native and exotic arbuscular mycorrhizal fungi at low pH. Soil Biol Biochem 39: 942-950., soil pH is a factor which directly or indirectly influences AMF diversity since it can compromise the nutrient availability for the fungus or for the plant.

The occurrence of Acaulospora denticulata, Acaulospora foveata, Acaulospora mellea, Acaulospora tuberculata, Gigaspora sp., Glomus sp. and Racocetra persica species only in the rainy season (Table III) shows that water availability was a limiting factor to sporulation. In turn, the occurrence of Sieverdingia tortuosa in all systems in the rainy season and in almost all the systems in the dry season is explained by the fact that this species is considered generalist, and can therefore occur in preserved or disturbed natural environments and in times with high or low water availability (Santos et al. 2014SANTOS RS, BARRETO PAB & SCORIZA RN. 2014. Efeito da sazonalidade na comunidade de fungos micorrízicos arbusculares em um fragmento de mata de cipó em Vitória da Conquista, Bahia. Rev Bras Biocienc 12: 46-51., Silva et al. 2016SILVA CFD, PEREIRA MG, SANTOS VLD, MIGUEL DL & SILVA EMRD. 2016. Fungos micorrízicos arbusculares: composição, comprimento de micélio extrarradicular e glomalina em áreas de Mata Atlântica, Rio de Janeiro. Ciência Florestal 26: 419-430.).

The greater abundance of the Acaulospora and Glomus genera can be attributed to the fact that they produce smaller spores and in greater quantity, being less influenced by seasonal changes when compared to other genera such as Gigaspora, which have larger spores (Sousa et al. 2014SOUSA CS, MENEZES RSC, SAMPAIO EVSB, LIMA FS, MAIA LC & OEHL F. 2014. Arbuscular mycorrhizal fungi in successional stages of Caatinga in the semi-arid region of Brazil. Ciência Florestal 24: 137-148.). These genera are generally found with great frequency in a wide range of forest ecosystems (Davison et al. 2015DAVISON J, MOORA M, OPIK M, ADHOLEYA A, AINSAAR L, BÂ A, BURLA S, DIEDHIOU AG, HIIESALU I & JAIRUS T. 2015. Global assessment of arbuscular mycorrhizal fungus diversity reveals very low endemism. Science 349: 970-973., Soteras et al. 2015SOTERAS F, GRILLI G, COFRÉ MN, MARRO N & BECERRA A. 2015. Arbuscular mycorrhizal fungal composition in high montane forests with different disturbance histories in central Argentina. Appl Soil Ecol 85: 30-37., Silva et al. 2016SILVA CFD, PEREIRA MG, SANTOS VLD, MIGUEL DL & SILVA EMRD. 2016. Fungos micorrízicos arbusculares: composição, comprimento de micélio extrarradicular e glomalina em áreas de Mata Atlântica, Rio de Janeiro. Ciência Florestal 26: 419-430., Bonfim et al. 2016BONFIM JA, VASCONCELLOS RLF, STÜRMER SL & CARDOSO EJBN. 2016. Arbuscular mycorrhizal fungi in the Brazilian Atlantic forest: A gradient of environmental restoration. Appl Soil Ecol 71: 7-14., Araújo et al. 2019ARAÚJO TM, DA SILVA K, PEREIRA GMD, CURCINO A, STÜRMER SL & GOMIDE PHO. 2019. Diversity of Arbuscular Mycorrhizal Fungi in Agroforestry, Conventional Plantations and Native Forests in Roraima State, Northern Brazil. J Agric Sci 11: 282-290., Pagano et al. 2019PAGANO MC, SILVA DK, SILVA GA & MAIA LC. 2019. Tropical Dry Forest Compared to Rainforest and Associated Ecosystems in Brazil. In: Mycorrhizal Fungi in South America. Cham: Springer, Cham, Suíça, p. 177-192., Becerra et al. 2019BECERRA AG, DIVÁN A & RENISON D. 2019. Bare soil cover and arbuscular mycorrhizal community in the first montane forest restoration in Central Argentina. Restor Ecol 27: 804-812.) and also in agricultural ecosystems (Oehl et al. 2017OEHL F, LACZKO E, OBERHOLZER HR, JANSA J & EGLI S. 2017. Diversity and biogeography of arbuscular mycorrhizal fungi in agricultural soils. Biol Fertil Soils 53:777-797., Cristo et al. 2018CRISTO SC, FORS RO & CARVALHO AG. 2018. Diversity of arbuscular mycorrhizal fungi in pasture areas in the Serra do Itajaí National Park. Rev Bras Cienc Agrar 13: 1-7., Vieira et al. 2020VIEIRA LC, SILVA DKAD, ESCOBAR IEC, SILVA JMD, MOURA IAD, OEHL F & SILVA GAD. 2020. Changes in an Arbuscular Mycorrhizal Fungi Community Along an Environmental Gradient. Plants 9: 1-17.).

A similar dispersion pattern of treatments between the rainy season (Figure 2a and 2b) and dry season (Figure 2c and 2d) in the PCA with AFS and BC clustering and MC and NF isolation demonstrates that AMF dynamics in the studied systems remain between the seasons. The dissimilarity of NF and MC (Figures 2b and 2d) can be attributed to differences in the litter and soil moisture accumulation in these treatments (Tables I and II). The native forest provides greater litter (Table II) and organic matter accumulation in the soil (Table I) due to not suffering anthropic influence and presenting a great diversity of plant species, whereas monoculture causes smaller organic residue entry and a less diverse litter due to its homogeneity characteristic, in addition to presenting only one host species. This would be influencing the occurrence of some AMF species. An example of these are the Gigaspora sp., A. tuberculata, and Racocetra Perssica species which were found exclusively in the native forest, the Glomus sp. species which was only absent in the MC, and Am. Leptoticha and A. scrobiculata which did not occur in the NF. In line with this explanation, significant positive correlations were found between mean species richness and litter, soil moisture and SOM. According to Verbruggen et al. (2012)VERBRUGGEN E, VAN DER HEIJDEN MG, WEEDON JT, KOWALCHUK GA & RÖLING WF. 2012. Community assembly, species richness and nestedness of arbuscular mycorrhizal fungi in agricultural soils. Mol Ecol 21: 2341-2353., the occurrence and distribution of AMF species are related to contemporary ecological processes such as the existence of one or more hosts, and environmental factors such as organic matter content, soil temperature and moisture which act on the fungal community, conditioning its abundance and diversity.

In turn, the ASF and BC grouping (Figures 2b and 2d) can be explained by the fact that these systems are made up of more than one plant species. Thus, the vegetation structure and composition (with the presence of the arboreal component in the AFS and the banana tree in the BC) would provide a specific environment for the AMF, with more diversified litter and a more balanced microclimate when compared to the MC. In other words, the heterogeneous systems would be exercising a similar influence in the AMF community, while the MC (as previously discussed) is distinguished by being composed of a single plant species presenting restriction in the entrance and diversity of organic residues and being more prone to disturbance.

CONCLUSIONS

Although not presenting an effect on spore density and average species richness, coffee production systems cause changes in the presence or absence of arbuscular mycorrhizal fungi (AMF) species. The AMF community was shown to be related to the species composition of the productive system, which was reflected in a similar influence by the heterogeneous systems (agroforestry coffee-grevillea system and banana-coffee consortium), and distinct from the coffee monoculture and native forest in terms of effect on the fungal community. The species distribution and number of spores was shown to be influenced by climatic conditions with a reduction in the dry season, but without differentiation between the studied systems.

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Publication Dates

Publication in this collection
27 June 2022
Date of issue
2022

History

Received
31 July 2020
Accepted
7 Dec 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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System	pH	P	SOM	K	Ca	Mg	H+Al	SB	E	Soil moisture
System	pH	P	SOM	K	Ca	Mg	H+Al	SB	E	Moist	Dry
	H ₂ O	mg dm ^-3	g dm ^-3	------ cmolc dm ^-3 ------
AFS	6.2	41.5	21.0	0.5	3.8	2.6	2.7	6.9	7.0	12.9	13.0
BC	6.2	26.5	17.0	0.6	5.0	2.2	3.3	7.7	7.8	12.6	14.2
MC	7.2	27.0	15.5	0.7	4.0	2.8	1.4	7.4	7.4	12.7	13.0
NF	5.5	3.5	30.0	0.2	4.0	3.0	7.1	7.1	7.3	18.1	19.7

Systems	Litter		NS		TR		AR
Systems	Rainy	Dry	Rainy	Dry	Rainy	Dry	Rainy	Dry
AFS	6.16 Ab	5.98 Ab	202.5 Aa	70.25 Ba	9	5	4.5 Aa	2.75 Aa
BC	3.93 Abc	3.38 Abc	626.75 Aa	126.75 Ba	10	6	5.25 Aa	3.25 Aa
MC	0.84 Ac	0.72 Ac	193.00 Aa	136.75 Aa	10	10	5.50 Aa	4.25 Aa
NF	14.17 Aa	10.34 Ba	474.25 Aa	81.75 Ba	11	6	5.50 Aa	3.25 Ba

Variables/ Treatments	Rainy season			Variables/ Treatments	Dry season
Variables/ Treatments	PC1	PC2	PC3	Variables/ Treatments	PC1	PC2	PC3
	Factor loadings				Factor loadings
Litter	0.912	0.409	-0.042	Litter	-0.828	-0.516	-0.221
Moisture	0.994	0.074	-0.083	Moisture	-0.989	-0.090	0.117
A. denticulata	-0.612	-0.616	-0.497	A. mellea	0.998	0.028	0.050
A. foveata	0.288	-0.679	-0.675	A. scrobiculata	0.998	0.028	0.050
A. mellea	-0.623	0.762	-0.177	Am. leptoticha	-0.592	0.789	-0.165
A. scrobiculata	-0.994	-0.032	0.102	C. pellucida	-0.592	0.789	-0.165
A. tuberculata	0.994	0.032	-0.102	Cl. etunicatum	0.314	0.939	-0.141
Am. leptoticha	-0.994	-0.032	0.102	G. glomerulatum	0.314	0.939	-0.141
G. glomerulatum	0.431	-0.201	0.880	S. tortuosa	0.386	0.591	0.709
Gigaspora sp	0.994	0.032	-0.102
Glomus sp1	0.623	-0.762	0.177
Glomus sp.	0.275	0.912	-0.306
R. persica	0.994	0.032	-0.102
Variability %	63.519	23.461	13.020	Variability %	52.278	40.345	7.377
Cumulative %	63.519	86.980	100.000	Cumulative %	52.278	92.623	100.000

Species	AFS	BC	MC	NF
Species	Rainy season
Acaulospora denticulata Sieverding & Toro.	0	25	25	0
Acaulospora foveata Trappe & Janos.	0	25	25	25
Acaulospora mellea Spain & Schenck.	25	75	0	0
Acaulospora scrobiculata Trappe.	25	25	50	0
Acaulospora tuberculata Janos & Trappe.	0	0	0	25
Ambispora leptoticha (Schenck & Smith) Morton & Redecker.	50	100	75	0
Cetraspora pellucida (T.H. Nicolson & N.C. Schenck) Oehl, F.A. Souza & Sieverd.	25	25	50	25
Gigaspora sp.	0	0	0	50
Glomus glomerulatum Sieverding.	50	0	75	50
Glomus macrocarpum Tulasne & Tulasne.	100	100	100	100
Glomus sp.1	0	0	50	25
Glomus sp.	25	25	0	100
Racocetra persica Oehl, Souza & Sieverd.	0	0	0	25
Sclerocystis clavispora (Trappe) Almeida & Schenck.	100	100	75	75
Sieverdingia tortuosa Schenck & Smith.	50	25	25	50
	Dry season
Acaulospora mellea Spain & Schenck	50	75	25	0
Acaulospora scrobiculata Trappe	25	25	25	0
Ambispora leptoticha (Schenck & Smith) Morton & Redecker	0	0	50	25
Cetraspora pellucida (T.H. Nicolson & N.C. Schenck) Oehl, F.A. Souza & Sieverd	0	0	25	25
Claroideoglomus etunicatum (W.N. Becker & Gerdemann) C. Walker & A. Schüßler	0	0	25	0
Glomus glomerulatum Sieverding	0	0	50	0
Glomus macrocarpum Tulasne & Tulasne	100	100	100	100
Glomus sp.1	25	25	25	50
Sclerocystis clavispora (Trappe) Almeida & Schenck	50	100	50	75
Sieverdingia tortuosa Schenck & Smith	25	0	50	50