Abstract
The conversion of forests could change soil characteristics and, in turn, impact the microbial community. However, the long-term effect of forest transformation on bacterial and archaeal composition and diversity, especially on nitrogen functional communities, is poorly understood. This study aimed to explore the response of soil bacterial and archaeal communities, as well as nitrogen functional groups, to the conversion from natural broadleaved forests to Chinese fir (Cunninghamia lanceolate (Lamb.) Hook.) plantations in subtropical China by 16S rRNA amplicon sequencing. Except for soil bulk density (BD) and ammonium nitrogen (NH4+–N) content, other soil properties all decreased with the conversion from natural forests to plantations. Alpha diversity of bacteria and archaea declined with the transformation from natural forests to plantations. The composition of bacteria and archaea was significantly different between natural forests and plantations, which could be mainly attributed to the change in the content of soil organic carbon (SOC), total nitrogen (TN), nitrate nitrogen (NO3−–N), and available phosphorus (AP). The conversion of natural forests to plantations decreased the gene copies of ammonia-oxidizing archaea (AOA), ammonia-oxidizing bacteria (AOB), and nifH (nitrogen fixation function) but increased denitrification gene copies (i.e., nirS, nirK, and nosZ). In summary, our study emphasizes the long-term negative effect of the conversion from natural broadleaved forests into Chinese fir plantations on the diversity and richness of soil microbial communities, thereby deeply impacting the cycling of soil nitrogen.
Highlights
Forest ecosystems play an important role in regulating global biogeochemical cycles, maintaining species diversity, and resisting climate change [1], and are valued worldwide for the services they provide to society [2,3]
This study aims to explore the effect of the forest type transformation on the soil physicochemical characteristics, microbial community structure and diversity, and nitrogen cycling microbial functional groups through sequencing with 16S rRNA to the soil of natural broadleaved forests, mixed-species plantations, and Chinese fir plantations
Soil pH and the content of NO3−–N, total nitrogen (TN), and available phosphorus (AP) decreased significantly (P < 0.05), regardless of the surface or subsurface soil after the natural forest converted to the plantation, while soil bulk density (BD) showed the opposite (P < 0.05)
Summary
Forest ecosystems play an important role in regulating global biogeochemical cycles, maintaining species diversity, and resisting climate change [1], and are valued worldwide for the services they provide to society [2,3]. As one of the most important parameters for the quality and sustainability of the ecosystem, soil organic carbon (SOC) is usually impacted by activities carried out for managing agricultural and forest ecosystems [7] Managed forests, such as timber plantations in North America and oil-palm plantations in Southeast Asia, have replaced many natural forests and currently cover 1.9 million km worldwide [6]. These changes in forest cover will affect various important ecosystem service functions, including biodiversity maintenance, climate regulation, carbon storage, nitrogen cycles, etc. These changes in forest cover will affect various important ecosystem service functions, including biodiversity maintenance, climate regulation, carbon storage, nitrogen cycles, etc. [10]
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