Spatial patterns of rice paddy microbial communities and the associated drivers in Qianjiangyuan National Park system pilot

doi:10.17520/biods.2022392

Abstract

Abstract:

Aims: The establishment of national parks is crucial in protecting the integrity of natural ecosystems and biodiversity. As one of the first ten pilots, the Qianjiangyuan National Park system pilot (hereafter referred to as Qianjiangyuan) has developed the easement-inspired adaptive management and achieved remarkable outcomes. However, it remains unclear how this creative management might influence the soil microorganisms and systematic evaluation is in need.

Methods: We took Qianjiangyuan as the study area and collected surface soils from rice paddies in the different districts and under different management types. Four management types were included, namely, reformed land within the park, abandoned land within the park, unreformed land within the park, and unreformed land outside the park. We employed high-throughput sequencing techniques to characterize the community composition and structure of both bacteria and fungi. We then analyzed the driving forces behind the spatial patterns of bacterial and fungal communities.

Results: Compared to the other three types of lands, contents of soil nitrogen and phosphorus and heavy metals were relatively low in the abandoned land, but they were similar in the other three types. The bacterial communities were dominated by Proteobacteria (48.57%) and Acidobacteria (31.62%), while the fungal communities were dominated by Ascomycota (78.31%) and Basidiomycota (16.28%). Bacterial communities varied largely in lands under different management types, with significant difference between abandoned land and other three types, while the other three types were similar. Fungal communities showed slight variation, with significant difference being identified only between abandoned land and outside unreformed land. We found significant correlation between soil environmental factors and spatial variation of bacterial communities. The most important five factors driving bacterial spatial patterns were pH, chromium, total nitrogen, available phosphorus, and organic matter. However, no significant correlation was detected between fungal communities and soil environmental factors. Analysis of neutral community models found that neutral processes played an important role in the spatial distribution of both bacterial and fungal communities.

Conclusion: Based on these findings, we conservatively conclude that no significant impacts have been produced by land reforming policy so far. In contrast, the abandoned land may have begun rewilding. Therefore, long-term monitoring is needed to comprehensively assess whether and how ecological protection easement will impact the recovery of rice soils.

Key words: national park, ecological protection easement, soil microbial communities, bacteria, fungi

Yuzhan Yang, Jianping Yu, Haiyuan Qian, Xiaonan Chen, Shengwen Chen, Zhilin Yuan. Spatial patterns of rice paddy microbial communities and the associated drivers in Qianjiangyuan National Park system pilot[J]. Biodiv Sci, 2023, 31(2): 22392.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2022392

https://www.biodiversity-science.net/EN/Y2023/V31/I2/22392

Figures/Tables 8

Fig. 1 Map of Qianjiangyuan and location of sampling sites

Fig. 2 Heatmap of soil environmental factors. The upper ribbon represents four districts with red for Suzhuang, brown for Changhong, green for Hetian, and Blue for Qixi. The lower ribbon represents lands of four reform types with red for reformed land within the park, brown for unreformed land within the park, green for outside unreformed land, and blue for abandoned land within the park. TN, Total nitrogen; AvP, Available phosphorous; OM, Organic matter; TP, Total phosphorus; HN, Hydrolyzable nitrogen; AvK, Available potassium; EC, Electrical conductivity.

Fig. 3 PCA plot of environmental factors. RefIn: Reformed land inside; UnrefIn: Unreformed land inside; AbdIn: Abandonded land inside; UnrefOut: Unreformed land outside.

Fig. 4 Taxonomic composition of soil bacterial and fungal communities in Qianjiangyuan. (A) Bacterial communities at the phylum or class level. (B) Bacterial communities at the genus level. (C) Fungal communities at the phylum or class level. (D) Fungal communities at the genus level. Abbreviations of 4 management types see Fig. 3.

Fig. 5 Alpha diversity of soil bacterial and fungal communities in Qianjiangyuan. (A-C) Soil bacterial communities. (D-F) Soil fungal communities. Group pairs that had significant difference were marked (** P < 0.01; * P < 0.05). Abbreviations of 4 management types see Fig. 3.

Fig. 6 NMDS plot of soil bacterial and fungal communities. (A) Bacterial communities. (B) Fungal communities. Abbreviations of 4 management types see Fig. 3.

Table 1 Explanatory power of environmental factors to spatial variation of bacterial community composition

因子 Factor	独立解释度 Independent variance	共同解释度 Shared variance	因子总解释度 Total variance	因子相对重要性 Dominance (%)
pH	0.020	0.009	0.029	14.74
铬 Cr	0.004	0.022	0.026	13.32
总氮 TN	0.002	0.016	0.018	9.34
有效磷 AvP	0.011	0.006	0.017	8.67
有机质 OM	-0.004	0.020	0.016	8.06
锌 Zn	-0.002	0.014	0.012	6.33
镉 Cd	-0.002	0.013	0.011	5.56
总磷 TP	0.000	0.010	0.011	5.41
镍 Ni	0.000	0.009	0.009	4.69
铜 Cu	0.001	0.008	0.009	4.59
砷 As	0.005	0.004	0.009	4.44
铅 Pb	0.003	0.004	0.007	3.62
苯并芘 BaP	0.005	0.002	0.007	3.47
水解性氮 HN	-0.002	0.006	0.004	2.24
有效钾 AvK	0.001	0.004	0.004	2.19
汞 Hg	0.001	0.003	0.004	1.89
电导率 EC	-0.003	0.005	0.003	1.33

Fig. 7 Fit of the Sloan’s neutral community model of (A) bacterial and (B) fungal communities. OTUs that occur more or less frequently than predicted by the model are shown in blue or red, while OTUs that occur as predicted are shown in black. The dashed blue lines represent 95% confidence intervals around the model prediction. R2 represents the goodness of fit of neutral community model and m represents the community-level migration.

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