Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, China

Abstract Background The broad-leaved Korean pine mixed forest is an important and typical component of a global temperate forest. Soil microbes are the main driver of biogeochemical cycling in this forest ecosystem and have complex interactions with carbon (C) and nitrogen (N) components in the soil...

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Main Authors: Minghui Liu, Xin Sui, Yanbo Hu, Fujuan Feng
Format: Article
Language:English
Published: BMC 2019-09-01
Series:BMC Microbiology
Subjects:
Online Access:http://link.springer.com/article/10.1186/s12866-019-1584-6
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spelling doaj-544db89dc8124cf196f1c812df5ee8db2020-11-25T03:33:33ZengBMCBMC Microbiology1471-21802019-09-0119111410.1186/s12866-019-1584-6Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, ChinaMinghui Liu0Xin Sui1Yanbo Hu2Fujuan Feng3College of Life Science, Northeast Forestry UniversityCollege of Life Science, Heilongjiang UniversityNortheast Forestry UniversityCollege of Life Science, Northeast Forestry UniversityAbstract Background The broad-leaved Korean pine mixed forest is an important and typical component of a global temperate forest. Soil microbes are the main driver of biogeochemical cycling in this forest ecosystem and have complex interactions with carbon (C) and nitrogen (N) components in the soil. Results We investigated the vertical soil microbial community structure in a primary Korean pine-broadleaved mixed forest in Changbai Mountain (from 699 to 1177 m) and analyzed the relationship between the microbial community and both C and N components in the soil. The results showed that the total phospholipid fatty acid (PLFA) of soil microbes and Gram-negative bacteria (G-), Gram-positive bacteria (G+), fungi (F), arbuscular mycorrhizal fungi (AMF), and Actinomycetes varied significantly (p < 0.05) at different sites (elevations). The ratio of fungal PLFAs to bacterial PLFAs (F/B) was higher at site H1, and H2. The relationship between microbial community composition and geographic distance did not show a distance-decay pattern. The coefficients of variation for bacteria were maximum among different sites (elevations). Total soil organic carbon (TOC), total nitrogen (TN), soil water content (W), and the ratio of breast-height basal area of coniferous trees to that of broad-leaved tree species (RBA) were the main contributors to the variation observed in each subgroup of microbial PLFAs. The structure equation model showed that TOC had a significant direct effect on bacterial biomass and an indirect effect upon bacterial and fungal biomass via soil readily oxidized organic carbon (ROC). No significant relationship was observed between soil N fraction and the biomass of fungi and bacteria. Conclusion The total PLFAs (tPLFA) and PLFAs of soil microbes, including G-, G+, F, AMF, and Actinomycetes, were significantly affected by elevation. Bacteria were more sensitive to changes in elevation than other microbes. Environmental heterogeneity was the main factor affecting the geographical distribution pattern of microbial community structure. TOC, TN, W and RBA were the main driving factors for the change in soil microbial biomass. C fraction was the main factor affecting the biomass of fungi and bacteria and ROC was one of the main sources of the microbial-derived C pool.http://link.springer.com/article/10.1186/s12866-019-1584-6Original Korean pine forestSoil microbial communityBiogeographic distributionDistance-decay relationshipSoil carbon and nitrogenStructural equation model
collection DOAJ
language English
format Article
sources DOAJ
author Minghui Liu
Xin Sui
Yanbo Hu
Fujuan Feng
spellingShingle Minghui Liu
Xin Sui
Yanbo Hu
Fujuan Feng
Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, China
BMC Microbiology
Original Korean pine forest
Soil microbial community
Biogeographic distribution
Distance-decay relationship
Soil carbon and nitrogen
Structural equation model
author_facet Minghui Liu
Xin Sui
Yanbo Hu
Fujuan Feng
author_sort Minghui Liu
title Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, China
title_short Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, China
title_full Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, China
title_fullStr Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, China
title_full_unstemmed Microbial community structure and the relationship with soil carbon and nitrogen in an original Korean pine forest of Changbai Mountain, China
title_sort microbial community structure and the relationship with soil carbon and nitrogen in an original korean pine forest of changbai mountain, china
publisher BMC
series BMC Microbiology
issn 1471-2180
publishDate 2019-09-01
description Abstract Background The broad-leaved Korean pine mixed forest is an important and typical component of a global temperate forest. Soil microbes are the main driver of biogeochemical cycling in this forest ecosystem and have complex interactions with carbon (C) and nitrogen (N) components in the soil. Results We investigated the vertical soil microbial community structure in a primary Korean pine-broadleaved mixed forest in Changbai Mountain (from 699 to 1177 m) and analyzed the relationship between the microbial community and both C and N components in the soil. The results showed that the total phospholipid fatty acid (PLFA) of soil microbes and Gram-negative bacteria (G-), Gram-positive bacteria (G+), fungi (F), arbuscular mycorrhizal fungi (AMF), and Actinomycetes varied significantly (p < 0.05) at different sites (elevations). The ratio of fungal PLFAs to bacterial PLFAs (F/B) was higher at site H1, and H2. The relationship between microbial community composition and geographic distance did not show a distance-decay pattern. The coefficients of variation for bacteria were maximum among different sites (elevations). Total soil organic carbon (TOC), total nitrogen (TN), soil water content (W), and the ratio of breast-height basal area of coniferous trees to that of broad-leaved tree species (RBA) were the main contributors to the variation observed in each subgroup of microbial PLFAs. The structure equation model showed that TOC had a significant direct effect on bacterial biomass and an indirect effect upon bacterial and fungal biomass via soil readily oxidized organic carbon (ROC). No significant relationship was observed between soil N fraction and the biomass of fungi and bacteria. Conclusion The total PLFAs (tPLFA) and PLFAs of soil microbes, including G-, G+, F, AMF, and Actinomycetes, were significantly affected by elevation. Bacteria were more sensitive to changes in elevation than other microbes. Environmental heterogeneity was the main factor affecting the geographical distribution pattern of microbial community structure. TOC, TN, W and RBA were the main driving factors for the change in soil microbial biomass. C fraction was the main factor affecting the biomass of fungi and bacteria and ROC was one of the main sources of the microbial-derived C pool.
topic Original Korean pine forest
Soil microbial community
Biogeographic distribution
Distance-decay relationship
Soil carbon and nitrogen
Structural equation model
url http://link.springer.com/article/10.1186/s12866-019-1584-6
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AT yanbohu microbialcommunitystructureandtherelationshipwithsoilcarbonandnitrogeninanoriginalkoreanpineforestofchangbaimountainchina
AT fujuanfeng microbialcommunitystructureandtherelationshipwithsoilcarbonandnitrogeninanoriginalkoreanpineforestofchangbaimountainchina
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