Changes in Soil Biochemical Properties in a Cedar Plantation Invaded by Moso Bamboo

Shiau, Yo‐Jin; Chiu, Chih‐Yu

doi:10.3390/f8070222

Cited by 26 publications

(13 citation statements)

References 32 publications

(55 reference statements)

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“…2015). In addition, recent studies have also reported that moso bamboo invasion affected physical, chemical, and biological soil properties (Lin et al 2014;Fukushima et al 2015;Shinohara and Otsuki 2015;Chang and Chiu 2015;Xu et al 2015;Wang et al 2016b;Song et al 2017;Li et al 2017a;Qin et al 2017;Shiau and Chiu 2017).…”

Section: Introductionmentioning

confidence: 99%

Moso bamboo (Phyllostachys edulis (Carriere) J. Houzeau) invasion affects soil phosphorus dynamics in adjacent coniferous forests in subtropical China

Wang

et al. 2018

Annals of Forest Science

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& Key message The invasion of moso bamboo (Phyllostachys edulis (Carriere) J. Houzeau) into neighboring Cryptomeria japonica (L. f.) D. Don plantations significantly altered soil P status and dynamics. This alteration in phosphorus dynamics must be considered when assessing the ecological consequence of moso bamboo invasion in subtropical China. & Context Moso bamboo is a native species that commonly invades into adjacent forests in Asia. Such invasions may significantly alter soil chemical characteristics because moso bamboo has very different traits compared with the tree species it displaces. However, few studies have investigated the effects of moso bamboo invasion on soil phosphorus (P) dynamics. & Aims The objective of this study was to investigate the effects of moso bamboo invasion on soil P dynamics. Specifically, we quantified soil total P, available P, acid phosphatase activity (APA), and microbial biomass P (MBP) in moso bamboo-invaded coniferous stands and compared them to uninvaded stands and pure moso bamboo stands. & Methods We compared seasonal dynamics of soil P (e.g., total P, available P, APA, and MBP) over a 24-month period among three stand types at Lushan mountain in subtropical China: Cryptomeria japonica plantation (CR), Cryptomeria japonica plantation invaded by Phyllostachys edulis (PH-CR), and Phyllostachys edulis stand (PH). & Results Total soil P concentration was significantly lower in PH-CR than in CR and PH stands, but soil available P concentration was significantly lower in CR and PH stands. Soil APA was significantly higher in PH-CR than in CR and PH stands. Similarly, soil MBP concentration was higher in PH-CR than in CR and PH stands. Also, soil total P, available P, APA, and MBP concentrations displayed seasonal fluctuations in PH-CR, but remained relatively stable in CR and PH stands during the 2 years. & Conclusion The invasion of moso bamboo into adjacent C. japonica stands significantly increased soil available P, acid phosphatase activity, and microbial biomass phosphorus, but decreased soil total P. The implication of these changes to ecosystem composition, structure, and function must be explicitly considered in managing moso bamboo invasion in subtropical China.

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Section: Introductionmentioning

confidence: 99%

Moso bamboo (Phyllostachys edulis (Carriere) J. Houzeau) invasion affects soil phosphorus dynamics in adjacent coniferous forests in subtropical China

Wang

et al. 2018

Annals of Forest Science

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“…Soil soluble N from compounds like NH 4 + KCl , NO 3 − KCl , and TDN KCl was higher in CONIF‐40 than either BROAD‐Nat sites, and this could be linked to the fact that young forests have more young leaves than do old forests. Soil organic C is not polar and therefore dissolves better in HW than under ion exchange (Shiau et al, 2017; Shiau & Chiu, 2017). Therefore, S b OC HW concentrations were higher than those of S b OC KCl at all three studied sites, and S b OC HW is typically considered to reflect the labile portion of soil C better than S b OC KCl (Shiau & Chiu, 2017).…”

Section: Discussionmentioning

confidence: 99%

“…Research has shown that soil KCl‐ and hot water (HW)‐extractable C and N contents reflect the nutrients that can be readily metabolized by soil microorganisms, while acid‐hydrolyzable C is considered to be bioreactive C in soil (Xu et al, 1997). Extraction methods, such as KCl and HW, have been widely used to study various forest ecosystems and have proven that KCl‐ and HW‐extracted C and N contents are directly linked to microbial biomass (Huang et al, 2014; Shiau et al, 2017; Shiau & Chiu, 2017). In addition, acid‐hydrolyzable and recalcitrant C have been used to evaluate soil C quality under different types of plant cover (Wang, Chou, et al, 2016; Wang, Tian, et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Improvements in Soil C and N Compositions After 40 and 80 Years of Reforestation in Subtropical Low Mountain Forests

et al. 2020

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Reforestation is an important step toward recovering soil quality and wildlife habitats that are degraded due to deforestation. However, little is known about how soil C and N compositions in subtropical forests evolve after decades of reforestation. This study comprehensively evaluated the differences in soil C and N fractions in 40-and 80-year-old secondary (reforested) coniferous forests and a natural broadleaf forest. Although reforestation with coniferous plants appeared to increase soil organic matter and labile C levels, the ratio of soil labile C to total organic C was lower in the reforested coniferous forests than the natural broadleaf one. The trend in the labile N to total N ratio as coniferous reforestation progresses follows that of C. Furthermore, the percentage of recalcitrant C as total soil organic C was higher in the reforested coniferous forests than the natural broadleaf one. This feature of C composition in reforested coniferous forest causes environmental stress to microbes (as indicated by a high metabolic quotient) in the forest, even several decades after reforestation of a former broadleaf forest site. Results from this study demonstrate that it takes a very long time for reforestation with coniferous vegetation to restore the soil chemical properties of the previous natural forest.

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“…Soil total organic C (TOC) and total N (TN) were evaluated by the combustion method with an elemental analyzer (Fisons NA1500, ThermoQuest Italia, Milan, Italy). Soil labile C and N (soluble organic C: S b OC; soluble organic N: S b ON; ammonium: NH 4 + ; nitrate: NO 3 − ; total dissolved N: TDN) were extracted using a 2 M KCl extraction method [ 28 , 29 ]. Briefly, extracts were filtered from 5 g of soil and soaked with 50 mL KCl for an hour at 150 rpm.…”

Section: Methodsmentioning

confidence: 99%

“…were extracted using a 2 M KCl extraction method [28,29]. Briefly, extracts were filtered from 5 g of soil and soaked with 50 mL KCl for an hour at 150 rpm.…”

Section: Aerobic Ch4 Oxidation Experiments and Dna-sip Gradient Fractimentioning

confidence: 99%

Niche Differentiation of Active Methane-Oxidizing Bacteria in Estuarine Mangrove Forest Soils in Taiwan

et al. 2020

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Mangrove forests are one of the important ecosystems in tropical coasts because of their high primary production, which they sustain by sequestering a substantial amount of CO2 into plant biomass. These forests often experience various levels of inundation and play an important role in CH4 emissions, but the taxonomy of methanotrophs in these systems remains poorly understood. In this study, DNA-based stable isotope probing showed significant niche differentiation in active aerobic methanotrophs in response to niche differentiation in upstream and downstream mangrove soils of the Tamsui estuary in northwestern Taiwan, in which salinity levels differ between winter and summer. Methylobacter and Methylomicrobium-like Type I methanotrophs dominated methane-oxidizing communities in the field conditions and were significantly 13C-labeled in both upstream and downstream sites, while Methylobacter were well adapted to high salinity and low temperature. The Type II methanotroph Methylocystis comprised only 10–15% of all the methane oxidizers in the upstream site but less than 5% at the downstream site under field conditions. 13C-DNA levels in Methylocystis were significantly lower than those in Type I methanotrophs, while phylogenetic analysis further revealed the presence of novel methane oxidizers that are phylogenetically distantly related to Type Ia in fresh and incubated soils at a downstream site. These results suggest that Type I methanotrophs display niche differentiation associated with environmental differences between upstream and downstream mangrove soils.

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Changes in Soil Biochemical Properties in a Cedar Plantation Invaded by Moso Bamboo

Cited by 26 publications

References 32 publications

Moso bamboo (Phyllostachys edulis (Carriere) J. Houzeau) invasion affects soil phosphorus dynamics in adjacent coniferous forests in subtropical China

Moso bamboo (Phyllostachys edulis (Carriere) J. Houzeau) invasion affects soil phosphorus dynamics in adjacent coniferous forests in subtropical China

Improvements in Soil C and N Compositions After 40 and 80 Years of Reforestation in Subtropical Low Mountain Forests

Niche Differentiation of Active Methane-Oxidizing Bacteria in Estuarine Mangrove Forest Soils in Taiwan

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