Potential complementary functions among bacteria, fungi, and archaea involved in carbon cycle during reversal of desertification

Wang, Zengru; Wang, Yansong; Zhang, Wenli; Liu, Yubing; Gao, Tianpeng

doi:10.1002/ldr.3804

Cited by 13 publications

(8 citation statements)

References 46 publications

(58 reference statements)

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“…This exception may be due to the relatively high abundance of fungal communities in the lichen‐biocrusted soil (Figure S10); most of the functional genes are derived from bacterial rather than fungal communities (Zhao et al, 2020). Moreover, bacterial decomposers favour labile substrates (such as starch, hemicellulose and pectin), whereas fungi prefer complex substrates (such as cellulose, terpenes, chitin and vanillin/lignin; Güsewell & Gessner, 2009; Wang, Wang, et al, 2021), which is consistent with the results obtained for the lichen‐biocrusted soil.…”

Section: Discussionsupporting

confidence: 85%

“…Previous studies showed that the structure and function of soil microbial communities were different under different types of biocrusts (Wang, Wang, et al, 2021; Zhao et al, 2020). Soil microorganisms can adjust their respiratory function by altering their metabolism and community structure (Brown et al, 2004), and they are the main contributors to soil respiration (Guo et al, 2020; Tian et al, 2022), especially in dryland ecosystems where vascular plants are usually quite sparse (García‐Palacios et al, 2018; Guan et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…Biocrusts are ecosystem engineers at the atmosphere–soil interface, and they regulate a wide range of ecosystem functions, including C budgets (Dacal et al, 2020; García‐Palacios et al, 2018), nitrogen (N) cycles (Koranda & Michelsen, 2021; Maier et al, 2021), phosphorus (P) cycles (Kurth et al, 2021), hydrological processes (Eldridge et al, 2020), soil thermal properties (Xiao, Ma, et al, 2019) and soil stability (Algayer et al, 2014). Specifically, biocrusts regulate soil CO 2 flux not only directly through photosynthesis (Li, Hui, et al, 2021) and respiration (Guan et al, 2021, 2022) but also indirectly by altering the soil temperature (Xiao, Ma, et al, 2019), moisture (Eldridge et al, 2020), N availability (Koranda & Michelsen, 2021) and microbial community and functional structure (Wang, Wang, et al, 2021). For example, soil respiration at microsites with high biocrust coverage is significantly higher than that at microsites with low biocrust coverage (Escolar et al, 2015; Maestre et al, 2013) or in bare soils (Morillas et al, 2017; Yao et al, 2020), and biocrusts can contribute to more than 40% of CO 2 flux via soil respiration (Castillo‐Monroy et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Microbial function regulates the effect of vegetation restoration on the contribution of biocrusts to soil respiration in drylands

et al. 2023

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Biocrusts are special components of dryland ecosystems and play important roles in ecosystem carbon cycles. Vegetation restoration not only affects carbon storage but also changes the characteristics of biocrusts. However, how vegetation restoration influences the contribution of biocrusts to soil carbon cycling in dryland ecosystems is poorly understood. Using continuous field measurements combined with metagenomic shotgun sequencing, we explored the effect and regulatory mechanisms of Caragana korshinskii vegetation restoration on the contribution of biocrusts to total soil respiration. We found that vegetation restoration increased the contribution of biocrusts to total soil respiration, with the biocrust contribution increasing from −5.6% for mixed biocrusts in a typical steppe to 17.1%, 18.1% and 19.6% for cyanobacteria–algae, lichen and moss biocrusts, respectively, in a Caragana korshinskii vegetation restoration area. The driving factors for total soil respiration changed from solely soil temperature to soil temperature and moisture after vegetation restoration. In contrast, the driving factors for soil respiration estimated for biocrust layers changed from precipitation alone to soil temperature and precipitation after vegetation restoration. We reveal that changes in microbial functional structure play important roles in regulating the effect of vegetation restoration and biocrusts on soil respiration. In addition, vegetation restoration also increases the microbial activity in biocrusted soils. This calls for an improved understanding of the effects of biocrusts on soil respiration under vegetation restoration scenarios to advance our ability to evaluate soil carbon releases from dryland ecosystems. Read the free Plain Language Summary for this article on the Journal blog.

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Section: Discussionsupporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Microbial function regulates the effect of vegetation restoration on the contribution of biocrusts to soil respiration in drylands

et al. 2023

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“…While transformation genes of bacterial carbon and nitrogen were significantly associated with SOC and TN contents, transformation genes of only archaeal nitrogen were significantly associated with TN content. Wang et al ( 2021 ) reported that soil bacterial genes contributed 84.53 and 95.62% to carbon decomposition and fixation, respectively, while archaeal genes contributed only 1.09 and 4.05%, respectively, through the detection of functional genes in soils of desert ecosystem. It may be that archaea are more biased toward soil nitrogen transformation, while bacteria specialize in carbon and nitrogen transformations (Monteux et al, 2020 ; Wang et al, 2021 ).…”

Section: Discussionmentioning

confidence: 99%

“…Wang et al ( 2021 ) reported that soil bacterial genes contributed 84.53 and 95.62% to carbon decomposition and fixation, respectively, while archaeal genes contributed only 1.09 and 4.05%, respectively, through the detection of functional genes in soils of desert ecosystem. It may be that archaea are more biased toward soil nitrogen transformation, while bacteria specialize in carbon and nitrogen transformations (Monteux et al, 2020 ; Wang et al, 2021 ). Collectively, the abandonment of ancient rice terraces changed soil properties, such as pH and

-N, which in turn altered the bacterial and archaeal community structures and reduced the gene abundance of the transformationfunctional groups of carbon and nitrogen.…”

Section: Discussionmentioning

confidence: 99%

Reshaping of soil carbon and nitrogen contents in quincentenary ancient rice terraces: The role of both short-term abandonment and prokaryotic functional groups

Liu

et al. 2022

Front. Microbiol.

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Microbial communities and functions play an important role in soil carbon and nitrogen transformations, and, in recent decades, the abandonment of terraces is prevalant in the hilly areas of China. However, it is unclear how soil carbon and nitrogen contents and prokaryotic communities changed as a result of the abandonment of ancient rice terraces. Soil profiles ranging from 0 to 120 cm were excavated on drylands, forestlands (both converted due to the abandonment of ancient rice terraces), and ancient rice terraces. The FAPROTAX database was used to predict soil prokaryotic functional groups. The results showed that soil organic carbon (SOC) and total nitrogen (TN) contents of abandoned ancient rice terraces in drylands (51.09 and 33.20%) and forestlands (31.76 and 16.59%) were significantly reduced. Soil prokaryotic diversity and community composition changed dramatically after the abandonment of terraces and were mainly affected by soil pH and ammoniacal nitrogen (NH4+-N). Community composition was more similar in drylands and forestlands. Moreover, the abundance of transformation functional genes of carbon (57.01 and 50.80%) and nitrogen (15.25 and 22.36%) in bacterial communities was significantly reduced, and of carbon in the archaeal communities decreased sharply (28.10 and 46.50%), in drylands and forestlands. These findings indicate that short-term abandonment of ancient rice terraces reduces soil carbon and nitrogen contents, which may be closely related to the decline of prokaryotic functional groups. The prevalence of short-term abandonment of rice terraces in the hilly areas of China may pose adverse ecological risks.

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Soil microbial community dynamics in response to Tamarix ramosissima afforestation in desert lands: Metagenomic insights

Zhang,

Cong,

Zhao

et al. 2024

Land Degrad Dev

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Understanding the influence of afforestation on soil microorganisms, the major drivers of soil processes, is essential for maintaining soil health and sustainability. However, in a desert‐oasis ecotone, variations in the microbial community along shrub afforestation years remain unclear. We conducted a metagenomic analysis to study the temporal changes in microbial community structure in 0–100 cm soil following 3‐, 7‐, and 10‐year afforestation of Tamarix ramosissima Ledeb. on the southern edge of the Taklimakan Desert. Compared to the unreclaimed desert land, in 3‐year or 7‐year stands, soil organic carbon (SOC), nitrate nitrogen, available phosphorus and potassium (AK) contents significantly increased on average by 60%, 852%, 72%, and 299%, respectively. Soil archaeal and bacterial community composition were significantly affected by afforestation; their α‐diversity increased on average by 5.9% and 11.1%, respectively, after afforestation, showing a unimodal pattern along afforestation years. In contrast, fungal α‐diversity and community composition did not show significant variation over the afforestation period. The influence of AK outweighed that of SOC and other nutrients on soil microbial community composition. These findings suggest that T. ramosissima afforestation in the desert‐oasis ecotone has significant impacts on the community composition and α‐diversity of archaea and bacteria, but not fungi, by modifying soil physicochemical properties. This research provides valuable implications for soil management and microbial processes related to the afforestation of salt‐secreting shrubs.

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Potential complementary functions among bacteria, fungi, and archaea involved in carbon cycle during reversal of desertification

Cited by 13 publications

References 46 publications

Microbial function regulates the effect of vegetation restoration on the contribution of biocrusts to soil respiration in drylands

Microbial function regulates the effect of vegetation restoration on the contribution of biocrusts to soil respiration in drylands

Reshaping of soil carbon and nitrogen contents in quincentenary ancient rice terraces: The role of both short-term abandonment and prokaryotic functional groups

Soil microbial community dynamics in response to Tamarix ramosissima afforestation in desert lands: Metagenomic insights

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