دانلود رایگان مقاله انگلیسی نقش شیمی خاک و مناطق گیاهی در پروش قارچ در سه جنگل بارانی پانامایی - وایلی 2017

Summary

1. Fungi play critical roles in ecosystem processes and interact with plant communities in mutualistic, pathogenic, and commensal ways. Fungal communities are thought to depend on both associated tree communities and soil properties. However, the relative importance of the biotic and abiotic drivers of soil fungal community structure and diversity in lowland tropical forests remains poorly understood. 2. We examined the community structure of trees and fungi at different levels of phosphorus (0
17– 16
3 mg kg1 ) in moist tropical forests in Panama. We predicted that arbuscular mycorrhizal (AM) fungal composition would be more strongly associated with soil properties than with local tree communities while the composition of other fungal clades would be more strongly correlated with local tree communities than soil properties. We also predicted that fungal operational taxonomic unit (OTU) richness would be negatively correlated with soil fertility and positively correlated with tree species diversity within and among forests. 3. We characterized soil chemistry, fine root biomass, and sequenced the ITS1 barcode region to describe fungal community composition from 70 soil cores across three 1-ha tropical rainforest sites in Panama. The sites vary in soil chemistry, including P, and in tree species community composition, but experience similar annual rainfall. 4. AM fungal community composition was partially correlated with soil chemistry (r = 0
32, P ≤ 0
001), but not with local tree communities, while non-AM fungal communities were nearly equally correlated with soil chemistry (Partial Mantel test, r = 0
38, P ≤ 0
001) as with tree communities (r = 0
36, P ≤ 0
001). Linear models showed that AM OTU richness was not explained by any independent variable. For non-AM fungi, phosphorus, pH, and soil moisture better predicted OTU richness across all cores than other biotic and abiotic factors. 5. Synthesis. Our results show that AM fungal structure is driven primarily by soil chemistry. For non-AM fungi, soil properties and the local tree community can play a joint role in structuring communities. Furthermore, we found that more diverse local tree communities did not harbour more fungal species. Our results suggest that soil properties act as an environmental filter for both trees and fungi, setting the stage for interactions between the two.

Discussion

Our results provide support for our first hypothesis that AM fungal communities show low turnover and variation among sites and non-AM fungi show greater differences among sites. We found that AM fungal communities showed high overlap in species composition among sites despite marked variation in vegetation composition and soil chemistry, including P availability. Non-AM fungal community structure differed strongly among sites. Our results agree with previous studies that have found most AM fungi to be generalists (Opik € et al. 2006; Davison et al. 2015) while other groups like Ascomycota and Basidiomycota show some degree of host specificity (Ferrer & Gilbert 2003; Tedersoo et al. 2010). Our second hypothesis, that AM fungi would be better explained by abiotic soil chemistry and non-AM better explained by local biotic variables, was partially supported by the results of the partial Mantel tests. These tests showed that variation in AM fungi among cores was correlated with soil chemistry but not local tree neighbourhoods. The partial Mantel test revealed that non-AM fungal communities were roughly equally correlated with soil chemistry and local tree community composition. Finally, our results do not support our third hypothesis that fungal OTU richness within soil cores was negatively correlated with soil P and positively correlated with tree diversity. Instead, we found no relationship between AM richness and any biotic or abiotic variable. We did find a positive relationship between non-AM richness and resin P, soil pH, and soil moisture, which was contrary to our initial hypothesis. Overall, our study suggests that AM fungal community structure varies at fine spatial scales and is generally correlated with soil properties. For other fungi, soil properties and the local tree community play equivalent roles in structuring their communities.