Decrease in fungal biodiversity along an available phosphorous gradient in arable Andosol soils in Japan

Bao, Zhihua; Matsushita, Yuko; Morimoto, Sho; Hoshino, Yuko Takada; Suzuki, Carlos Kenichi; Nagaoka, Kazunari; Takenaka, Mikihito; Murakami, Hisashi; Kuroyanagi, Yukiko; Urashima, Yasufumi; Sekiguchi, Hiroyuki; Kushida, Atsuhiko; Toyota, Koki; Saitô, Masanori; Tsushima, Seiya

doi:10.1139/cjm-2012-0612

Cited by 15 publications

(12 citation statements)

References 29 publications

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“…The understanding of fungal community responses to elevated P inputs remains limited (Leff et al, 2015). The effect of P addition on soil fungal community composition depends on ecosystem type, soil properties, and nutrient type and dose (Bao et al, 2013; Beauregard et al, 2010; Li et al, 2015; Liu et al, 2013). Previous studies have demonstrated that experimental P fertilization reduces the species richness of arbuscular mycorrhizal fungi, which could increase soil nutrient capture of their hosts in return for plant C resource (Camenzind et al, 2014; Cheng et al, 2013; Liu et al, 2013).…”

Section: Discussionmentioning

confidence: 99%

Differential mechanisms underlying responses of soil bacterial and fungal communities to nitrogen and phosphorus inputs in a subtropical forest

Tian

Wang

et al. 2019

PeerJ

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Atmospheric nitrogen (N) deposition and phosphorus (P) addition both can change soil bacterial and fungal community structure with a consequent impact on ecosystem functions. However, which factor plays an important role in regulating responses of bacterial and fungal community to N and P enrichments remains unclear. We conducted a manipulative experiment to simulate N and P inputs (10 g N · m−2 · yr−1 NH4NO3 or 10 g P · m−2 · yr−1 NaH2PO4) and compared their effects on soil bacterial and fungal species richness and community composition. The results showed that the addition of N significantly increased NH4+ and Al3+ by 99.6% and 57.4%, respectively, and consequently led to a decline in soil pH from 4.18 to 3.75 after a 5-year treatment. P addition increased Al3+ and available P by 27.0% and 10-fold, respectively, but had no effect on soil pH. N addition significantly decreased bacterial species richness and Shannon index and resulted in a substantial shift of bacterial community composition, whereas P addition did not. Neither N nor P addition changed fungal species richness, Shannon index, and fungal community composition. A structural equation model showed that the shift in bacterial community composition was related to an increase in soil acid cations. The principal component scores of soil nutrients showed a significantly positive relationship with fungal community composition. Our results suggest that N and P additions affect soil bacterial and fungal communities in different ways in subtropical forest. These findings highlight how the diversity of microbial communities of subtropical forest soil will depend on future scenarios of anthropogenic N deposition and P enrichment, with a particular sensitivity of bacterial community to N addition.

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Section: Discussionmentioning

confidence: 99%

Differential mechanisms underlying responses of soil bacterial and fungal communities to nitrogen and phosphorus inputs in a subtropical forest

Tian

Wang

et al. 2019

PeerJ

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“…However, few studies have investigated soil fungi owing to the limited technologies surrounding culture and morphological identification. With the development of high‐throughput sequencing technology over the last few years, soil fungi have received extensive attention, particularly with respect to variations along different spatial scales and environmental gradients, such as temperature (Zhou et al, ), precipitation (Hawkes et al, ; Zumsteg, Bååth, Stierli, Zeyer, & Frey, ), pH (Rousk et al, ), organic phosphorus (Bao et al, ), organic C (Hanson, Allison, Bradford, Wallenstein, & Treseder, ), and anthropogenic disturbances (Sun et al, ; Wang, Song, et al, ). Plant diversity has a strong correlation with soil fungi at local scales (Tedersoo et al, ; Yang, Adams, et al, ) but a weak correlation at global scales (Tedersoo et al, ).…”

Section: Introductionmentioning

confidence: 99%

Broad‐leaved forest types affect soil fungal community structure and soil organic carbon contents

Sheng

Cong

et al. 2019

MicrobiologyOpen

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Evergreen broad‐leaved (EBF) and deciduous broad‐leaved (DBF) forests are two important vegetation types in terrestrial ecosystems that play key roles in sustainable biodiversity and global carbon (C) cycling. However, little is known about their associated soil fungal community and the potential metabolic activities involved in biogeochemical processes. In this study, soil samples were collected from EBF and DBF in Shennongjia Mountain, China, and soil fungal community structure and functional gene diversity analyzed based on combined Illumina MiSeq sequencing with GeoChip technologies. The results showed that soil fungal species richness (p = 0.079) and fungal functional gene diversity (p < 0.01) were higher in DBF than EBF. Zygomycota was the most dominant phylum in both broad‐leaved forests, and the most dominant genera found in each forest varied (Umbelopsis dominated in DBF, whereas Mortierella dominated in EBF). A total of 4, 439 soil fungi associated functional gene probes involved in C and nitrogen (N) cycling were detected. Interestingly, the relative abundance of functional genes related to labile C degradation (e.g., starch, pectin, hemicellulose, and cellulose) was significantly higher (p < 0.05) in DBF than EBF, and the functional gene relative abundance involved in C cycling was significantly negatively correlated with soil labile organic C (r = −0.720, p = 0.002). In conclusion, the soil fungal community structure and potential metabolic activity showed marked divergence in different broad‐leaved forest types, and the higher relative abundance of functional genes involved in C cycling in DBF may be caused by release of loss of organic C in the soil.

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“…The increases and decreases in the number of populations observed in some gel lines may indicate, as with the results from the primers for the 16S rDNA, that fungal populations were influenced by the presence of rock dust or by the plant, showing negative or positive selection patterns. A negative interaction between plants and microbial communities was also observed by Bao et al (2013). A greater number of fungus populations were detected among plants with the maximum growth in height and higher biomass production.…”

Section: Dgge Analysis Dendrograms and Dna Sequencingmentioning

confidence: 77%

Effects of phosphate-solubilizing bacteria, native microorganisms, and rock dust on Jatropha curcas L. growth

2016

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Microorganisms with the ability to release nutrients to the soil from insoluble sources may be useful for plant cultivation. We evaluated the growth-promoting effect on Jatropha curcas L. of phosphate-solubilizing bacteria (PSB) and the native microbiota in soil with or without rock dust. J. curcas L. is important for biodiesel production. The experiments were performed in a greenhouse under a random-statistical design with 14 replicates. The soil received increasing dosages of rock dust. The presence of resident microorganisms and PSB inoculum was correlated with plant height, biomass production, and phosphorus content in plants for 120 days. Native soil microorganisms were detected and identified using denaturing gradient gel electrophoresis and DNA sequence analysis. Several bacterial populations belonged to the genus Bacillus. Populations associated with the phyla Chytridiomycota and Ascomycota were detected among the fungi. The best results for the variable plant height were correlated with the presence of resident microbiota and rock dust until the end of the experiment. The largest biomass production and the highest content of phosphorus occurred in the presence of soil-resident microbiota only up to 120 days. No significant effects were observed for biomass production with the use of PSB combined with rock dust. J. curcas L. under the influence of only resident microbiota showed the best plant growth results. Future research will focus on the specificity of resident microbiota activity in plant growth promotion and the isolation of these microorganisms to produce a new inoculum to be tested in various plants.

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Decrease in fungal biodiversity along an available phosphorous gradient in arable Andosol soils in Japan

Cited by 15 publications

References 29 publications

Differential mechanisms underlying responses of soil bacterial and fungal communities to nitrogen and phosphorus inputs in a subtropical forest

Differential mechanisms underlying responses of soil bacterial and fungal communities to nitrogen and phosphorus inputs in a subtropical forest

Broad‐leaved forest types affect soil fungal community structure and soil organic carbon contents

Effects of phosphate-solubilizing bacteria, native microorganisms, and rock dust on Jatropha curcas L. growth

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