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Data collection

We collected samples within each of the 50 plots described above underneath bare (unvegetated) soil, a grass individual (Bouteloua eriopoda), and a shrub individual (Prosopis glandulosa) in July 2013 and 2019, resulting in three samples per plot per year, and 300 samples total (3 host types * 2 years * 5 precipitation variation levels * 10 replications). Soil samples were collected with soil corers and trowels to 5 cm depth from the surface within the soil rooting zone of the focal plant. We sprayed equipment down with 10% bleach between samples to minimize contamination. Samples were stored on ice in a cooler in the field and transferred to storage a -20°C freezer until August 2019, when they were transported to the University of Georgia and stored at -80°C for downstream applications.

DNA extraction and sequencing

To characterize soil fungal communities, we subsampled 250 mg of soil from each sample and extracted total genomic DNA using the QIAGEN Dneasy® PowerSoil Pro Kit®, following the manufacturer’s protocol (QIAGEN, Hilden, Germany). Prior to DNA extraction, we performed tissue lysis with a Spex® Genogrinder® at 1500 rpm for 10 minutes. We quantified DNA spectrophotometrically using a Nanodrop One/One© (ND2000; NanoDrop Technologies). Genomic DNA was stored at -20ºC prior to library preparation and sequencing.

We characterized fungi with high-throughput sequencing to detect the variation in marker gene differences. To target fungal taxa, we amplified the ITS2 region using primers fITS7 (5′-GTGARTCATCGAATCTTG-3′; Ihrmark et al., 2012), and ITS4 (5′-TCCTCCGCTTATTGATATGC-3′; White et al., 1990), augmented with multiplexing barcodes. Samples were sequenced on two runs of an Illumina MiSeq instrument (300PE V3 chemistry). Library preparation and DNA sequencing was conducted at the Georgia Genomics and Bioinformatics Core (GGBC) at the University of Georgia in Athens, GA.

Sequence reads are archived at NCBI under project number PRJNA884111.

Bioinformatic processing

Forward and reverse reads were paired, merged, and quality filtered with USEARCH (http://drive5.com/usearch/; Edgar, 2010, 2013). Sequences were then processessed using Mothur (Schloss et al., 2009) to remove sequencing adapters, primers, and chimeras. Combined reads were clustered into Operational Taxonomic Units (OTUs) at 97% identity using the K-nearest algorithm (Wang et al., 2007), which we classified against the UNITE (Version 8.0) reference database (Nilsson et al., 2019). All non-fungal reads were excluded from the analysis. The total dataset included 1308 unique fungal OTUs with 10,370,208 total sequences. Due to uneven sequence depth, we rarefied samples to 3000 reads per sample for all downstream analyses. Samples with less than 3000 reads were excluded from the analysis (27 of 297) due to insufficient sequencing depth (Figure S1).

Statistical analysis

All statistical analyses were performed in R (Version 1.2.1335, R core team, 2017) and conducted on the rarefied OTU abundance matrix. To evaluate the influence of increased precipitation variability on diversity metrics, we calculated the coefficient of variation of the amount of precipitation received for each variability treatment from 2009 to 2013 and from 2014 to 2019, such that precipitation variability can be analyzed as a continuous variable (see Gherardi and Sala, 2015b). Thus, for the remainder of this paper, we refer to increased precipitation variability as the coefficient of variation (CV) of the amounts of growing season precipitation received for the five precipitation variability treatments calculated from the periods between 2009-2013 and 2014-2019, respectively. For for the indicator species and functional guild composition anlyses, we used increased precipitation variability as a categorical variable for three levels of increased precipitation variability: Control, medium (-/+50% and +/-50%) and high (-/+80% and +/-80%). We analyzed the influence of host type, precipitation variability, and sampling year on soil fungal diversity using a linear mixed model (Bates et al., 2015) with Shannon’s diversity index for each sample as a response variable, and host type, precipitation (CV), year and their interactions as fixed effects, and plot as a random intercept accounting for the repeated measures nature of the experiment. We included sampling year as a categorical variable in this and subsequent analyses to account for different ambient conditions between sampling years 2013 and 2019 (Figure 1). We performed post-hoc multiple pairwise comparisons using the false discovery rate (fdr) method to correct p-values (package 'emmeans', Lenth, 2018). To further explain differences observed in Shannon diversity, we also separately analyzed fungal richness (number of OTUs in each sample) and evenness (distribution of relative abundance with the Pielou’s metric of evenness) using the same model structure and post-hoc methods as above for Shannon diversity. To investigate soil fungal community composition, we calculated Bray-Curtis dissimilarities among samples using the rarefied OTU abundance matrices. Using Bray-Curtis dissimilarity matrices, we tested the effect of host type, precipation variability, and year on fungal community composition with a permutational analysis of variance (PERMANOVA) (function adonis in the 'vegan' package) (Dixon, 2003). We further identified soil taxa that were significant indicators of treatment groups using indicator species analysis (Dufrêne and Legendre, 1997) with the 'labdsv' package. To visualize variation in fungal community composition, we performed non-metric multidimensional scaling (NMDS) ordinations using Bray-Curtis dissimilarities. To assign functional guilds, or primary lifestyles to operational taxonomic units, we used only OTUs assigned to genus-level resolution (656 out of 1308 OTUs) and assigned genera to functional identity using the FungalTrait database (Põlme et al., 2020).

To test whether soil fungal diversity responses were due to direct effects of increased precipitation variability or indirect effects via host plant induced changes, we performed stuctural equational modelling (SEM) using the Lavaan Package (Rosseel, 2012). Our model incorporated the direct correlation between increased precipitation variability and soil fungal diversity, and the direct correlation between increased precipitation variability and percentage cover of the host type. The indirect path was modelled as the association between increased precipitation variability and soil fungal diversity, mediated through a change in perentage host type cover. Models were just-identified and therefore no general model fit was reported. We split up the OTU table by the three host types to investigate above-ground induced changes in each host-associated community type separately. We also modeled two different soil fungal responses: richness and evenness. We specifically modelled richness and evennes as separate responses — as apposed to only modelling Shannon Diversity as a response. This led to a total of six (host type by fungal response) models evaluated.