Microbial and metabolic profiling reveal strong influence of water table and land-use patterns on classification of degraded tropical peatlands

Mishra, Shailendra; Lee, W. A.; Hooijer, A.; Reuben, Sheela; Sudiana, I Made; Idris, Aswandi; Swarup, Sanjay

doi:10.5194/bg-11-1727-2014

Cited by 30 publications

(16 citation statements)

References 90 publications

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“…Environmental conditions strongly impact the structure of microbial communities (Bahram et al, 2018). The effects of water table and total nitrogen content on bacterial communities in SP samples (Table 3) matches well with previous studies in different types of peatlands (Mishra et al, 2014;Urbanová and Bárta, 2016;Zhong et al, 2017). Interestingly we further found that RT and CART also responded to water table and total nitrogen content.…”

Section: Environmental Factors Shaping Bacterial Communitiessupporting

confidence: 86%

Rare Species Shift the Structure of Bacterial Communities Across Sphagnum Compartments in a Subalpine Peatland

Xiao

Evers

et al. 2020

Front. Microbiol.

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Sphagnum-associated microbiomes are crucial to Sphagnum growth and peatland ecological functions. However, roles of rare species in bacterial communities across Sphagnum compartments are poorly understood. Here the structures of rare taxa (RT) and conditionally abundant and rare taxa (CART) from Sphagnum palustre peat (SP), S. palustre ectosphere (Ecto) and S. palustre endosphere (Endo) were investigated in the Dajiuhu Peatland, central China. Our results showed that plant compartment effects significantly altered the diversities and structures of bacterial communities. The Observed species and Simpson indices of RT and CART in alpha diversity significantly increased from Endo to SP, with those of Ecto in-between. The variations of community dissimilarities of RT and CART among compartments were consistent with those of whole bacterial communities (WBC). Network analysis indicated a nonrandom co-occurrence pattern of WBC and all keystone species are affiliated with RT and CART, indicating their important role in sustaining the WBC. Furthermore, the community structures of RT and CART in SP were significantly shaped by water table and total nitrogen content, which coincided with the correlations between WBC and environmental factors. Collectively, our results for the first time confirm the importance of rare species to bacterial communities through structural and predicted functional analyses, which expands our understanding of rare species in Sphagnum-associated microbial communities in subalpine peatlands.

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Section: Environmental Factors Shaping Bacterial Communitiessupporting

confidence: 86%

Rare Species Shift the Structure of Bacterial Communities Across Sphagnum Compartments in a Subalpine Peatland

Xiao

Evers

et al. 2020

Front. Microbiol.

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“…Anthropogenic disturbances, in particular settlements and logging (secondary forest), led to higher diversity indices (Fig .6). On the contrary, sites surrounded by oil palm plantations displayed the lowest diversity indices, supporting results by Mishra et al (2014) who found similar results in peatlands. Furthermore, the OTU overlapping of major anthropogenic activities (i.e settlements and oil palm plantations) in Supp.…”

Section: Possible Pathogenic Bacteria And/or Anthropogenic Influence supporting

confidence: 84%

“…2005; Kolmakova et al, 2014;Lemke et al, 2009;Newton et al, 2011;Read et al, 2015;Staley et al, 2013). While there are studies related to the freshwater-marine gradients of rivers such as studies by Crump and Hobbie (2005) and Fortunato et al (2013)and tropical peatlands (Kanokratana et al, 2011;Mishra et al, 2014;Yule et al, 2016;Too et al, 2018), to the author's knowledge, this is the first study which links both freshwater-marine gradients as well as tropical peatlands as a cohesive component (i.e tropical peat-draining river to coastal ecosystem). Due to the high diversity and fast generation time, the first responders to environmental changes (both natural and anthropogenic events such as storms, upwelling and pollutants) are microbial communities (Hunt and Ward, 2015).…”

Section: Introductionmentioning

confidence: 94%

Biogeographical distribution of Microbial Communities along the Rajang River-South China Sea Continuum

Sia¹,

Zhu²,

Zhang³

et al. 2019

Preprint

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Abstract. Microbial community composition and diversity in freshwater habitats, especially in lotic environments, are much less studied compared to marine and soil communities. The Rajang River is the main drainage system for central Sarawak in Malaysian Borneo and passes through peat domes whereby peat-rich material is being fed into the system and eventually into the southern South China Sea. Microbial communities found within peat-rich systems are important biogeochemical cyclers in terms of methane and carbon dioxide sequestration. To address the critical lack of knowledge about microbial communities in tropical (peat-draining) rivers, this study represents the first seasonal assessment targeted at establishing a foundational understanding of the microbial communities of the Rajang River-South China Sea continuum. This was carried out utilizing 16S rRNA gene amplicon sequencing via Illumina MiSeq in size-fractionated samples (0.2 and 3.0 μm GF/C filter membranes) covering different biogeographical features/sources from headwaters to coastal waters. The microbial communities found along the Rajang river exhibited taxa common to rivers (i.e. the predominance of β-Proteobacteria) while estuarine and marine regions exhibited taxa that were common to the aforementioned regions as well (i.e. predominance of α- and γ-Proteobacteria). This is in agreement with studies from other rivers which observed similar changes along the salinity gradients. In terms of particulate versus free-living bacteria, nonmetric multi-dimensional scaling (NMDS) results showed similarly distributed microbial communities with varying separation between seasons. Distinct patterns were observed based on linear models as a result of the changes in salinity along with variation of other biogeochemical parameters. Alpha diversity indices indicated that microbial communities were higher in diversity upstream compared to the marine and estuarine regions whereas anthropogenic perturbations led to increased richness but less diversity. Despite the observed changes in bacterial community composition and diversity that occur along the Rajang River to sea continuum, the PICRUST predictions showed minor variations. The results provide essential context for future studies such as further analyses on the ecosystem health in response to anthropogenic land-use practices and probable development of biomarkers to improve the monitoring of water quality in this region.

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“…This was particularly apparent in Sebungan, where the canopy was closed and temperatures were lower. Sebungan had a lower mean WTD than the RSPO recommendations at the time of measurement and thus fresh peat may have been exposed to heterotrophic bacteria, increasing the rate of R h from Sebungan (Lim et al, 2012;Mishra et al, 2014;Carlson et al, 2015).…”

Section: Mitigation Optionsmentioning

confidence: 99%

“…Modifying peatlands for agricultural management can alter the biogeochemistry and trace gas fluxes from these systems due to the introduction of artificial drainage ditches that lower the water table and create an aerated zone for root growth, raising the soil redox potential (Hirano et al, 2012;Mishra et al, 2014;Tonks et al, 2017). In these more oxic conditions, methanogenesis is inhibited and aerobic degradation pathways predominate, namely peat oxidation from heterotrophic respiration (R h ; Hooijer et al, 2012;Miettinen et al, 2017;Warren et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Carbon Emissions From Oil Palm Plantations on Peat Soil

Manning

Kho

Hill

et al. 2019

Front. For. Glob. Change

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Southeast Asian peatlands have undergone recent land use change with an increase in industrial agricultural plantations, including oil palm. Cultivating peatlands requires creating drainage ditches and other surface microforms (i.e., harvest paths, frond piles, cover plants, and next to the palm). However, it is currently unclear how these management actions affect rates of carbon losses from the peat. Here we report carbon fluxes from each of the different surface microforms measured monthly (soil CO 2 [total soil respiration-R tot ] and stem CH 4) and bimonthly (soil CH 4 , drain CO 2 and drain CH 4). We calculated annual carbon fluxes and partitioned heterotrophic (R h) and root-rhizosphere respiration by sampling rhizosphere and root-free soil. Linear mixed effect models were used to determine which environmental factors best-predicted carbon fluxes, and to develop recommendations for management solutions that could reduce carbon losses. Carbon fluxes varied significantly between the different microforms; the greatest CO 2 fluxes were measured next to the palm and the greatest CH 4 fluxes were measured from the drainage ditches. Annual estimates of R tot , R h and drain CO 2 were 22.08 ± 0.50, 17.75 ± 1.54, and 1.5 ± 0.10 Mg CO 2-C ha −1 yr −1 , respectively. R h varied between the two plantations: Sebungan averaged 11.43 ± 1.37 Mg CO 2-C ha −1 yr −1 and Sabaju averaged 24.08 ± 1.42 Mg CO 2-C ha −1 yr −1. Net ecosystem CH 4 fluxes averaged 61.02 ± 17.78 kg CH 4-C ha −1 yr −1-similar to unmanaged swamp forests. The two plantations did not vary in overall CH 4 flux, but did vary in transport pathway. CH 4 fluxes from the soil, drains and stems followed a ratio of 50:50:0 from Sabaju (water table depth [WTD]: −0.49 ± 0.004 m) and 11:98:0 from Sebungan (WTD: −0.77 ± 0.007 m). R h dominated the peat carbon losses. WTD controlled variation in R h from Sebungan where the WTD was deeper. Air and soil temperature controlled variation in Sabaju, with greater fluxes from the harvest path, attributed to the absence of shade. These results suggest that shading the soil (e.g., through addition of frond piles) and raising the water table may be the most effective ways to reduce peat carbon loss from drained peat soils.

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Microbial and metabolic profiling reveal strong influence of water table and land-use patterns on classification of degraded tropical peatlands

Cited by 30 publications

References 90 publications

Rare Species Shift the Structure of Bacterial Communities Across Sphagnum Compartments in a Subalpine Peatland

Rare Species Shift the Structure of Bacterial Communities Across Sphagnum Compartments in a Subalpine Peatland

Biogeographical distribution of Microbial Communities along the Rajang River-South China Sea Continuum

Carbon Emissions From Oil Palm Plantations on Peat Soil

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