Your search keyword '"Shen, Qirong"' showing total 32 results

1. Inoculation of soil by Bacillus subtilis Y-IVI improves plant growth and colonization of the rhizosphere and interior tissues of muskmelon ( Cucumis melo L.).

Author

Zhao, Qingyun, Shen, Qirong, Ran, Wei, Xiao, Tongjian, Xu, Dabing, and Xu, Yangchun

Subjects

*BACILLUS subtilis, *RHIZOSPHERE, *SOIL microbiology, *MUSKMELON, *PLANT growth, *GREEN fluorescent protein

Abstract

Laboratory tests and greenhouse experiments were carried out to investigate the abilities of Bacillus subtilis Y-IVI to promote plant growth and to colonize the rhizosphere and interior tissues of muskmelon. Laboratory tests showed that B. subtilis Y-IVI can produce indole acetic acid, siderophores, and ammonia. The inoculation of soil with green fluorescent protein-tagged Y-IVI (GY-IVI) significantly increased plant shoot and root dry weights as compared with the non-inoculated soils. The inoculation of soil with B. subtilis GY-IVI maintained approximately 10 colony-forming units (cfu) of GY-IVI per gram of dry rhizosphere soil for 1 month. The GY-IVI recovered from the interior of crowns and roots in the inoculated soil were 10 and 10 cfu g dry weight, respectively, suggesting that GY-IVI acted as an endophyte. In the present study, we combined the two important growth promotion ingredients, colonization ability and growth promotion metabolites produced by biological agents, to investigate B. subtilis Y-IVI's promotion effects on muskmelon growth. [ABSTRACT FROM AUTHOR]

Published

2011

2. Harnessing key bacteria from suppressive soil to mitigate banana Panama disease.

Author

Lv, Nana, Ravanbakhsh, Mohammadhossein, Ling, Shuqin, Ou, Yannan, Tao, Chengyuan, Liu, Hongjun, Li, Rong, Shen, Zongzhuan, and Shen, Qirong

Abstract

Soil microbiomes play a pivotal role in shaping plant health and their ability to suppress the pathogens. However, the specific microbial features that confer disease suppression in agricultural soils have remained unknown. In this study, we aim to elucidate the mechanistic roles of soil key bacteria contributing to disease suppression in banana Panama disease by using a comprehensive soil survey focusing on suppressive, and conducive soils. Through an initial field survey across twelve paired locations, we identified five fields with significantly lower pathogen abundances compared to their co-located counterparts. Subsequent greenhouse experiments validated the disease-suppressive nature of soils collected from Jianfeng (JF) and Lingao (LG), both exhibiting low pathogen densities. Furthermore, four OTUs classified as Massilia (OTU44), Flavisolibacter (OTU396), Brevundimonas (OTU632) and Pseudomonas (OTU731), respectively, were identified as key players in suppressing pathogen invasion as they were significantly enriched in suppresive groups and pathogen inoculated treatments. The present results might suggest a vital link between these soil bacteria and pathogen inhibition in banana rhizosphere via a greenhouse experiment. The abundance of nonribosomal peptide synthetase (NRPS) genes, which was responsible for antibiotic synthesis and significantly enriched in the banana rhizosphere after beneficial microorganism inoculation, displayed a significant and negative correlation with pathogen abundance while a positive correlation with relative abundance of Pseudomonas. This result suggests that the up-regulation of NRPS genes may play a key role in bolstering banana plant immunity. These findings not only provide promising biocontrol strategies but also offer valuable insights into the dynamic relationship between soil microbiomes and plant physiology, paving the way for sustainable agriculture and disease management. [ABSTRACT FROM AUTHOR]

Published

2024

3. Potassium phosphite enhanced the suppressive capacity of the soil microbiome against the tomato pathogen Ralstonia solanacearum.

Author

Su, Lv, Feng, Haichao, Mo, Xingxia, Sun, Juan, Qiu, Pengfei, Liu, Yunpeng, Zhang, Ruifu, Kuramae, Eiko E., Shen, Biao, and Shen, Qirong

Subjects

*GRAM-negative bacteria, *RALSTONIA solanacearum, *SOILS, *FERTILIZER application, *POTASSIUM, *PATHOGENIC microorganisms

Abstract

High-throughput sequencing, culture-dependent workflows, and microbiome transfer experiments reveal whether potassium phosphite (KP), an environmentally acceptable agricultural chemical, could specifically enrich the antagonistic bacterial community that inhibited the growth of the pathogen Ralstonia solanacearum. The application of KP enriched the potential antagonistic bacteria Paenibacillus and Streptomyces in soil, but depleted most dominant genera belonging to gram negative bacteria, such as Pseudomonas, Massilia, and Flavobacterium on day 7. Moreover, the KP-modulated soil microbiome suppressed R. solanacearum growth in soil. The predicted functions related to the synthesis of antagonistic substances, such as streptomycin, and the predicted functions related to tellurite resistance and nickel transport system were significantly enriched, but the synthesis of lipopolysaccharide (distinct component lipopolysaccharide in gram negative bacteria) were significantly depleted in the KP-treated soils. In addition, the copy numbers of specific sequences for Streptomyces coelicoflavus and Paenibacillus favisporus were significantly increased in the soil amended with KP, inhibited the growth of R. solanacearum, and had a higher tolerance of KP than R. solanacearum. Our study linked the application of fertilizers to the enrichment of antagonistic bacteria, which could support future work that aims to precisely regulate the soil microbiome to protect the host from infection by soil-borne pathogens. [ABSTRACT FROM AUTHOR]

Published

2022

4. Chimeric plants favor asynchrony of conditionally rare bacterial species facilitating functional complementarity in rhizosphere.

Author

Ruan, Yang, Wang, Tingting, Guo, Shiwei, Huang, Qiwei, Shen, Qirong, and Ling, Ning

Subjects

*ENDANGERED species, *RHIZOSPHERE, *PLANT development, *DETERMINISTIC processes, *WATERMELONS

Abstract

Rare bacteria in rhizospheres from natural watermelon vs chimeric watermelon were investigated to understand the rare rhizobacteria assembling processes along with plant development and effects of rare species on functional stability. Over 80% of the total OTUs were defined as rare taxa (i.e., transient, permanent, and conditionally rare) in the rhizosphere. Among these three rarities, transient rare taxa possessed the highest richness, while the conditionally rarity displayed the largest variations along growth stages and exhibited the greatest deterministic process for assembling. Pairs of conditionally rare taxa with high asynchrony and similar functional potentials were identified in the rhizobacterial communities. This suggests the functional stability of the rhizosphere through functional redundancy. The number of pairs within the rhizosphere of chimeric plant was ~ two fold higher than that of natural watermelon, which illustrated that chimeric plants can stabilize rhizospheric functions. [ABSTRACT FROM AUTHOR]

Published

2022

5. Promoting soil microbial-mediated suppressiveness against Fusarium wilt disease by the enrichment of specific fungal taxa via crop rotation.

Author

Yuan, Xianfu, Wang, Beibei, Hong, Shan, Xiong, Wu, Shen, Zongzhuan, Ruan, Yunze, Li, Rong, Shen, Qirong, and Dini-Andreote, Francisco

Subjects

*WILT diseases, *CROP rotation, *FUSARIUM wilt of banana, *SOIL biology, *SOILS, *FUSARIUM oxysporum

Abstract

A pineapple-banana rotation was studied as a model system to investigate the potential emergence of a fungal-mediated disease-suppression in a soil highly infested with the pathogen Fusarium oxysporum causing the banana wilt disease. By using both field and pot experiments, the pineapple-banana rotation system resulted in a significant decrease of the pathogen number and next-stubble banana disease incidence (P < 0.05). This pathogen-suppression phenomenon was linked with detectable shifts in the soil resident fungal taxa tracked in the pineapple season. Most importantly, taxa affiliated with Talaromyces pinophilus and Clonostachys rossmaniae were found to be significantly enriched in the bulk soils due to the pineapple cultivation (P < 0.05). The taxon T. pinophilus was also significantly enriched in the rhizosphere of banana after the rotation (P < 0.05). Later, we used fungal isolation and pot inoculation to validate that both T. pinophilus and C. rossmaniae taxa are able to significantly decrease the pathogen number in the banana rhizosphere soil (P < 0.05), thus confirming their biocontrol effects suppressing the disease. Taken together, this study provides evidence on how crop rotation affects the resident soil microbiome and the development of disease suppressiveness. Besides, this study highlights the importance of understanding the dynamic changes in soil biology mediated by crop rotation and validates the mechanisms underpinning suppression toward promoting practical and directed manipulation of protective microbiomes in agroecosystems. [ABSTRACT FROM AUTHOR]

Published

2021

6. Legacy effects of 8-year nitrogen inputs on bacterial assemblage in wheat rhizosphere.

Author

Liu, Wenbo, Ling, Ning, Guo, Junjie, Ruan, Yang, Zhu, Chen, Shen, Qirong, and Guo, Shiwei

Subjects

*WHEAT, *BACTERIAL communities, *BACTERIAL diversity, *CROP growth, *BIOMASS, *RHIZOSPHERE

Abstract

This study focused on the legacy effects of 8-year application of N (in gradient of 0, 140, 280, 470, and 660 kg N ha−1 year−1) on the bacterial community diversity, interactions, and assembly processes in the wheat rhizosphere. The rhizosphere bacterial α-diversity increased with the rate of historical N input, while it did not change at N addition rates of over 280 kg N ha−1 year−1. Historical N input clearly shifted the rhizosphere bacterial community composition, and soils with more N input were more dissimilar to those without N input. The net relatedness index (NRI) and nearest taxon index (NTI) analysis revealed that the rhizosphere bacterial communities in most samples were phylogenetically clustered, and the treatments with high N (> 470 kg N ha−1 year−1) showed higher levels of clustering than those with low N (< 140 kg N ha−1 year−1), indicating more environmental selection stress in soil with higher historical N input. Increased co-occurrence network size and connectivity were accompanied by increased aboveground biomass of wheat. Overall, with the increase in historical N input, the resulting legacy effects forced the bacterial community in the rhizosphere to undergo higher environmental selection pressure, and indirectly affected the complexity of wheat rhizosphere assemblages during subsequent crop growth. [ABSTRACT FROM AUTHOR]

Published

2020

7. Biofertilizer application triggered microbial assembly in microaggregates associated with tomato bacterial wilt suppression.

Author

Dong, Menghui, Zhao, Mengli, Shen, Zongzhuan, Deng, Xuhui, Ou, Yannan, Tao, Chengyuan, Liu, Hongjun, Li, Rong, and Shen, Qirong

Subjects

*SOIL structure, *DISEASE incidence, *RALSTONIA solanacearum, *TOMATOES, *FERTILIZERS, *BIOFERTILIZERS

Abstract

Soil aggregates support diverse microbes due to heterogeneous micro-environment. A lot of researches have exhibited the difference of microbial composition and activity within different size soil aggregates, but the relative influences of these microbes and the mechanisms underlying their effects on plant health are still poorly understood. This study investigated the microbiomes within four soil aggregate fractions sampled from fields with different incidences of tomato bacterial wilt derived from three fertilization regimes (organic, bio-organic and chemical) and un-fertilized soil to decipher the mechanisms involved in disease suppression. A wet-sieving method was used to separate the aggregate fractions; Illumina MiSeq sequencing was used to characterize the soil microbiomes in field experiment, and real-time qPCR analysis was used in lab cultivation experiment to quantify the number of pathogens. Organic fertilization (OF) and bio-organic fertilization (BF) significantly decreased disease incidences compared with the effects of treatments with chemical fertilizer (CF) and those without fertilizer (CK). The microbial composition was significantly different between fertilizations and aggregate fractions; particularly, the bacterial composition was significantly correlated with disease incidence. Different aggregate fractions contained disparate bacterial taxa correlated with disease incidence. Only in the microaggregate (Mi), the Ralstonia genus' relative abundance showed a significant and positive correlation with disease incidence. The lab cultivation experiment demonstrated that after a spiking of Ralstonia solanacearum, whole soil and the Mi from BF-treated soil showed a significant higher resistance against pathogen invasion than those from CF-treated soil. The correlation between pathogen abundance and disease incidence in the field experiment and the higher resistance of Mi fraction against pathogen indicates that the microaggregates are the key fraction for suppressing tomato bacterial wilt in bio-organic fertilization practice, providing novel insight into the manipulation of the soil microbiome. [ABSTRACT FROM AUTHOR]

Published

2020

8. Effect of LSU and ITS genetic markers and reference databases on analyses of fungal communities.

Author

Xue, Chao, Hao, Yuewen, Pu, Xiaowei, Ryan Penton, C., Wang, Qiong, Zhao, Mengxin, Zhang, Bangzhou, Ran, Wei, Huang, Qiwei, Shen, Qirong, and Tiedje, James M.

Subjects

*SPECIES diversity, *FUNGAL communities, *NUCLEOTIDE sequence, *GENETIC markers, *SWITCHGRASS

Abstract

The effect of genetic markers and reference databases on analyses of fungal communities were estimated using fungal large subunit (LSU) and internal transcribed spacer (ITS) amplicon datasets in consecutive years of rhizosphere samples from three candidate biofuel crops, corn (Zea mays), switchgrass (Panicum virgatum), and miscanthus (Miscanthus × giganteus). These two marker genes were selected to contrast possible differences in biological conclusions. In addition, two ITS schemes based on two ITS reference databases were used to assess differences due to reference database composition. A taxonomy-supervised method was invoked using the Ribosomal Database Project naïve Bayesian classifier that accesses all three databases. The UNITE classification scheme had the highest number of classified taxa in the raw classification result; however, it also had the highest proportion of unknown taxa (sequences that were classified to "unclassified," "unidentified," incertae sedis or, in the case of Warcup, to matches containing two unique names). After removal of these unknown taxa, LSU had the highest classification rate followed by Warcup and UNITE. As expected, the communities resolved using the two ITS databases, based on the same sequences, were relatively more similar than those from the lower-coverage LSU classification scheme. The choice of marker gene or even the same reads with different classification databases revealed different community patterns due to database coverage, e.g., the relative abundance of the most abundant groups changed or were only detected in one or two of the classification schemes, such as for Mortierella, Fusarium, and Phoma. No marked difference in fungal beta-diversity was identified among the three methods. Differentiation between the three biofuel crops and between the drought and normal rainfall years was apparent, regardless of method. Though classification rates, taxonomic conflicts, and coverage differences within the high-abundance fungal groups varied according to classification scheme, there was no overall impact on beta diversity among the three methods. [ABSTRACT FROM AUTHOR]

Published

2019

9. Soil pre-fumigation could effectively improve the disease suppressiveness of biofertilizer to banana Fusarium wilt disease by reshaping the soil microbiome.

Author

Shen, Zongzhuan, Xue, Chao, Taylor, Paul W. J., Ou, Yannan, Wang, Beibei, Zhao, Yan, Ruan, Yunze, Li, Rong, and Shen, Qirong

Subjects

*SOIL fertility, *BIOFERTILIZERS, *FUSARIUM diseases of plants, *BANANA diseases & pests, *SOIL microbiology, *SOIL fumigation

Abstract

Two seasonal pot experiments were conducted to investigate the effect of biofertilizer application after mixture of lime and ammonium bicarbonate (LA) fumigation, on banana Fusarium wilt disease suppression and soil microbial community composition. Biofertilizer application after LA fumigation decreased 80% of disease incidence compared to control of biofertilizer application to non-fumigated soil. Biofertilizer application after fumigation clearly manipulated soil microbial community composition as revealed by non-metric multidimensional scaling and Venn diagram. LA fumigation significantly reduced the abundance of F. oxysporum while biofertilizer application after fumigation could further decrease it. Furthermore, indigenous microbes, e.g., Bacillus, Pseudomonas, and Mortierella, were associated with disease suppression. Biofertilizer application after fumigation significantly (p < 0.05) increased the soil pH and content of soil total C and available P and K, and this probably reshaped soil microbial community as revealed by redundancy analysis and variance partitioning analysis. The observed disease suppression due to biofertilizer application after soil fumigation can be attributed to the reduced abundance of F. oxysporum by general suppression resulting from manipulated soil properties and recovered soil microbiome. [ABSTRACT FROM AUTHOR]

Published

2018

10. Plant growth stages and fertilization regimes drive soil fungal community compositions in a wheat-rice rotation system.

Author

Wang, Jichen, Rhodes, Geoff, Huang, Qiwei, and Shen, Qirong

Subjects

*FUNGAL growth, *NITROGEN fertilizers, *PLANT growth, *FERTILIZERS, *ASCOMYCETES

Abstract

Fungal communities may have different response to fertilization under different conditions. Therefore, it is necessary to reveal the effects of fertilizations on fungal communities considering temporal heterogeneity at different crop stages. To address this, soil samples were collected across eight typical plant growth stages of a wheat-rice rotation system under four fertilization regimes: no nitrogen fertilizer (NNF), chemical fertilizer (CF), organic-inorganic mixed fertilizer (OIMF), and organic fertilizer (OF). Soil temperature and moisture that co-vary with plant growth stages were the strongest predictors of fungal community compositions; meanwhile, fertilization regimes also played important roles. Shannon index and the relative abundance of Ascomycota were consistently increased when compared OF treatment with CF and OIMF treatments, while CF treatment had a higher relative abundance of Zygomycota when compared with NNF and OF treatments. For the functional guilds, application of urea-nitrogen fertilizers (CF and OIMF treatments) significantly decreased the relative abundance of saprotrophs and symbiotrophs, while soil treated with OF had less relative abundance of pathotrophs when compared to inorganic fertilizers. Our study provided a detailed picture of how fungal community composition responded to fertilization regimes across different plant growth stages. [ABSTRACT FROM AUTHOR]

Published

2018

11. Alterations in soil fungal community composition and network assemblage structure by different long-term fertilization regimes are correlated to the soil ionome.

Author

Xue, Chao, Ryan Penton, C., Zhu, Chen, Chen, Huan, Duan, Yinghua, Peng, Chang, Guo, Shiwei, Ling, Ning, and Shen, Qirong

Subjects

*SOIL fungi, *INDUCTIVELY coupled plasma spectrometry, *HYDROGEN-ion concentration, *GEOGRAPHIC network analysis, *SOIL microbiology

Abstract

Agricultural soils with (M+) or without (M−) organic amendment were collected from four long-term field experiments to investigate soil fungal community composition and its relationship to the soil ionome by employing both the sequencing of fungal internal transcription spacer (ITS) fragments and inductively coupled plasma mass spectrometry (ICP-MS). Fungal community composition was primarily impacted by physical location while organic amendment triggered community shifts in the same direction in all four sites. Overall, the fungal community was strongly correlated to soil pH that, conversely, impacted soil ion availability. Fungal community dissimilarity was strongly correlated to soil ionome (ionic profile) variability. Network analysis has been conducted to explore the biotic interactions in soil ecosystem, in which species (nodes) are connected by pairwise interactions (links). The results revealed that organic amendment led to a higher number of correlated nodes to soil ions, links, modules (a group of nodes more densely connected to each other than to nodes outside the group), and positive links within and between modules. Moreover, specific fungal modules were independently correlated with soil ions, suggesting that each module represents a functional guild or collection of similar fungal ecotypes. Module size (number of nodes in a module) exhibited no apparent influence on the scale of these correlations. The increase in cooperative/synergistic interactions with organic amendment suggests that application results in a better-organized and more efficient community with enhanced potential soil fungal interactions mediated by alterations in the soil ionome. Overall, this study indicates that these less commonly measured soil ions play an important role and may be used to reveal previously undetermined drivers of the soil microbial community. [ABSTRACT FROM AUTHOR]

Published

2018

12. Long-term fertilisation regimes affect the composition of the alkaline phosphomonoesterase encoding microbial community of a vertisol and its derivative soil fractions.

Author

Luo, Gongwen, Ling, Ning, Nannipieri, Paolo, Chen, Huan, Raza, Waseem, Wang, Min, Guo, Shiwei, and Shen, Qirong

Subjects

*FERTILIZATION (Biology), *ALKALINE phosphatase, *VERTISOLS, *PARTICLE size determination, *STRUCTURAL equation modeling

Abstract

Alkaline phosphomonoesterase (ALP) mainly originates from soil microbial secretion and plays a crucial role in the turnover of soil phosphorus (P). To examine the response of ALP-encoding microbial communities (analysed for the biomarker of the ALP gene, phoD) of soils and derivative soil fractions to different fertilisation regimes, soil samples were collected from a long-term experimental field (over 35 years). The different organic P (Po) pools of soil fractions and the ALP activity of soil were also determined. Compared with chemical-only fertilised soils, the ALP activity was 232-815% higher in organic-amended soils, and the highest enzyme activity was observed in the organic-only fertilised treatment. The abundance of the phoD gene harbouring in soil fractions, determined by quantitative PCR (qPCR), was affected by different fertilisations. The highest abundance of the phoD gene was generally detected in the 2-63-μm-sized fraction (silt), but most phoD-encoding microbial species were associated to the 0.1-2-μm-sized fraction (clay) in the chemical-only fertilised soil. The contents of labile Po (LPo), moderately labile Po (MLPo) and fulvic acid-associated Po (FAPo) were significantly correlated with the phoD gene abundance, whereas only LPo content was significantly correlated with the ALP activity. The dominant phoD-encoding phylas were Actinobacteria and Proteobacteria, according to a high-throughput sequencing. Bradyrhizobium, a N-fixer identified as a phoD-encoding genus, showed the highest abundance in fertilised soils. The abundance of Bradyrhizobium, Streptomyces, Modestobacter, Lysobacter, Frankia and Burkholderia increased with the organic-only amendment and was significantly correlated with the ALP activity. According to structure equation models (SEM), pH and LPo content significantly and directly affected the ALP activity; the soil organic C (C) content was related to composition and abundances of phoD-harbouring microbial communities; since both microbial properties were correlated to the ALP activity, the C content was indirectly related to the ALP activity. In conclusion, soil management practices can be used to optimise the contents of soil available P and the organic P with regulation of soil ALP activity and the community composition of corresponding microbes. [ABSTRACT FROM AUTHOR]

Published

2017

13. Pathogen invasion indirectly changes the composition of soil microbiome via shifts in root exudation profile.

Author

Gu, Yian, Wei, Zhong, Wang, Xueqi, Friman, Ville-Petri, Huang, Jianfeng, Wang, Xiaofang, Mei, Xinlan, Xu, Yangchun, Shen, Qirong, and Jousset, Alexandre

Subjects

*SOIL microbiology, *EXUDATION (Botany), *BACTERIAL communities, *RALSTONIA solanacearum, *CAFFEIC acid

Abstract

Plant-derived root exudates modulate plant-microbe interactions and may play an important role in pathogen suppression. Root exudates may, for instance, directly inhibit pathogens or alter microbiome composition. Here, we tested if plants modulate their root exudation in the presence of a pathogen and if these shifts alter the rhizosphere microbiome composition. We added exudates from healthy and Ralstonia solanacearum-infected tomato plants to an unplanted soil and followed changes in bacterial community composition. The presence of pathogen changed the exudation of phenolic compounds and increased the release of caffeic acid. The amendment of soils with exudates from the infected plants led to a development of distinct and less diverse soil microbiome communities. Crucially, we could reproduce similar shift in microbiome composition by adding pure caffeic acid into the soil. Caffeic acid further suppressed R. solanacearum growth in vitro. We conclude that pathogen-induced changes in root exudation profile may serve to control pathogen both by direct inhibition and by indirectly shifting the composition of rhizosphere microbiome. [ABSTRACT FROM AUTHOR]

Published

2016

14. Microbial communities of an arable soil treated for 8 years with organic and inorganic fertilizers.

Author

Chen, Chen, Zhang, Jianan, Lu, Min, Qin, Chun, Chen, Yahua, Yang, Li, Huang, Qiwei, Wang, Jichen, Shen, Zhenguo, and Shen, Qirong

Subjects

*SOIL microbiology, *ARABLE land, *FERTILIZER application, *RIBOSOMAL RNA, *BACTERIAL communities, *FUNGAL communities

Abstract

The use of organic compost combined with inorganic fertilizer can enable balanced fertilization under intensive farming conditions, but little is known about how these fertilization practices affect the composition of microbial in arable soils. In this study, a field trial of a rice-wheat cropping system was established to examine the effects of 8 years of fertilization with inorganic fertilizers (IFs) and the organic manure-inorganic fertilizers (OMIFs) on composition of microbial communities. The fungal 18S and bacterial 16S rRNA gene fragments were amplified from each soil sample and sequenced. Significantly lower fungal richness and higher bacterial richness were observed for the OMIF treatment compared to the other treatments. No obvious changes in fungal diversity were observed among the treatments, with a decrease bacterial diversity detected in the IF treatment. Variations in relative abundance were observed in the fungal phyla Glomeromycota, Blastocladiomycota, and Schizoplasmodiida and in the bacterial phyla Acidobacteria, Gemmatimonadetes, and Cyanobacteria, most of which were significantly correlated with soil organic matter (OM) and/or nitrate N (NO-N) contents. Additionally, the fungal abundance-based coverage estimator (ACE) showed a significant negative correlation with the soil NO-N/OM content, while the correlation was positive for the bacterial ACE estimate. This study suggests that the fungal and bacterial communities respond differently to the long-term organic-inorganic fertilization, which may result from different effects of NO-N/OM content of soil on the composition of fungal and bacterial communities. [ABSTRACT FROM AUTHOR]

Published

2016

15. Bacillus amyloliquefaciens T-5 may prevent Ralstonia solanacearum infection through competitive exclusion.

Author

Tan, Shiyong, Gu, Yian, Yang, Chunlan, Dong, Yue, Mei, Xinlan, Shen, Qirong, and Xu, Yangchun

Subjects

*BACILLUS amyloliquefaciens, *RALSTONIA solanacearum, *BIOLOGICAL control of plant diseases, *FLUORESCENT proteins, *COMPETITIVE exclusion (Microbiology)

Abstract

Investigation of the properties and mechanisms of the interactions of root-colonizing biocontrol bacteria and plant pathogens is necessary to optimize the biocontrol strategies. In the present study, the interaction of a biocontrol strain Bacillus amyloliquefaciens T-5 tagged with a green fluorescent protein marker and a bacterial wilt pathogen Ralstonia solanacearum QL- Rs1115 tagged with red fluorescent protein marker was studied on tomato roots using different inoculation methods. The results showed that in the co-culture experiment, the population of pathogen QL-RFP was decreased by increasing the initial inoculum concentration of biocontrol strain. In the greenhouse experiment, both strains T-5-GFP and QL-RFP colonized tomato roots (root tips, root hairs, primary roots, and root junctions) and formed a biofilm on the root surfaces as determined by dilution plating and confocal laser scanning microscopy (CLSM) techniques. However, the root colonization of pathogen strain QL-RFP was almost completely suppressed in the presence of biocontrol strain T-5-GFP when both soil and plant seedlings were treated with T-5-GFP. The results of this study revealed the effectiveness of strain B. amyloliquefaciens T-5 as a biocontrol agent against tomato wilt pathogen and the significance of inoculation method used to inoculate biocontrol strain. [ABSTRACT FROM AUTHOR]

Published

2016

16. Rhizosphere microbial community manipulated by 2 years of consecutive biofertilizer application associated with banana Fusarium wilt disease suppression.

Author

Shen, Zongzhuan, Ruan, Yunze, Chao, Xue, Zhang, Jian, Li, Rong, and Shen, Qirong

Subjects

*RHIZOSPHERE microbiology, *BIOFERTILIZERS, *FUSARIUM wilt of banana, *BACILLUS amyloliquefaciens, *RIBOSOMAL RNA, *BACTERIAL diversity

Abstract

In our previous work, applying biofertilizer containing Bacillus amyloliquefaciens strain NJN-6 to a banana orchard infected by a serious Fusarium wilt disease over two consecutive years effectively controlled this soil-borne disease. In this study, deep pyrosequencing of 16S ribosomal RNA (rRNA) genes and internal transcribed spacer (ITS) sequences was performed to investigate how the composition of rhizosphere microbial community responded to the application of biofertilizer (BIO), pig manure compost (PM), and chemical fertilizer (CF) and to explore the potential correlation between the microbial community composition and the Fusarium wilt disease. A total of 104,201 bacterial 16S rRNA genes and 154,953 fungal ITS sequence reads were obtained after basic quality control, and Acidobacteria, Actinobacteria, Bacteroidetes, Firmicutes, Proteobacteria, and Ascomycota were the most abundant bacterial and fungal phyla across all samples. Compared with the PM and CF control, the alpha diversity of bacteria significantly ( P < 0.05) increased, whereas the value of the fungi was significantly ( P < 0.05) reduced following two consecutive years of biofertilizer application. Moreover, the abundance of Acidobacteria ( Gp1 and Gp3), Firmicutes, Leptosphaeria, and Phaeosphaeriopsis was significantly ( P < 0.05) increased, while the abundance of Proteobacteria and Ascomycota was significantly ( P < 0.05) decreased in the BIO treatment. Furthermore, the abundance of Fusarium, a causal pathogen for Fusarium wilt disease, was significantly ( P < 0.05) reduced in the BIO treatment compared with the CF control and was slightly reduced (not significant) compared with the PM control. Interestingly, the disease incidence was negatively correlated with the enriched taxa of Acidobacteria ( Gp1 and Gp3) and Firmicutes, Leptosphaeria, and Phaeosphaeriopsis but positively correlated with abundance of Proteobacteria, Ascomycota, Fusarium, Cylindrocarpon, Gymnascella, Monographella, Pochonia, and Sakaguchia taxa. The results from this study suggest that 2 years of biofertilizer application manipulated the composition of rhizosphere microbial community and induced the Fusarium suppression by increasing bacterial diversity and potentially stimulating microbial consortia taxa, such as Acidobacteria ( Gp1 and Gp3), Firmicutes, Leptosphaeria, and Phaeosphaeriopsis. [ABSTRACT FROM AUTHOR]

Published

2015

17. Contribution of indole-3-acetic acid in the plant growth promotion by the rhizospheric strain Bacillus amyloliquefaciens SQR9.

Author

Shao, Jiahui, Xu, Zhihui, Zhang, Nan, Shen, Qirong, and Zhang, Ruifu

Subjects

*BACILLUS amyloliquefaciens, *INDOLE, *PLANT growth, *PLANT hormones, *ACETOIN, *CROP yields

Abstract

Bacillus amyloliquefaciens SQR9, isolated from the rhizosphere of cucumber, can control Fusarium wilt of cucumber and directly stimulate plant growth. To evaluate its potential agricultural use, the plant growth promotion of B. amyloliquefaciens SQR9 was evaluated, and the relative mechanisms, especially the production of the phytohormone indole-3-acetic acid (IAA), were investigated. The related plant-growth-promoting factors were genetically and chemically analyzed, and a mutant library was constructed for selecting strains with different IAA production. B. amyloliquefaciens SQR9 showed a growth-promoting activity in greenhouse experiments. Plant-growth-promoting factors like extracellular phytase, volatile components including acetoin, 2,3-butanediol, and phytohormone IAA were detected in B. amyloliquefaciens SQR9 cultures grown under laboratory conditions. Three IAA production mutant strains showed variation in plant-growth-promoting effect. IAA production in B. amyloliquefaciens SQR9 was related to its plant-growth-promoting effect, but IAA alone could not account for the overall observed plant-growth-promoting effect. The promoted plant growth by the rhizospheric strain B. amyloliquefaciens SQR9 can be attributed to multiple factors, including production of phytohormones, volatile compounds, and extracellular enzymes. Therefore, the strain B. amyloliquefaciens SQR9 may be used as a plant-growth-promoting agent to increase crop yield. [ABSTRACT FROM AUTHOR]

Published

2015

18. Response of the bacterial diversity and soil enzyme activity in particle-size fractions of Mollisol after different fertilization in a long-term experiment.

Author

Ling, Ning, Sun, Yuming, Ma, Jinghua, Guo, Junjie, Zhu, Ping, Peng, Chang, Yu, Guanghui, Ran, Wei, Guo, Shiwei, and Shen, Qirong

Subjects

*BACTERIAL diversity, *SOIL enzymology, *FERTILIZERS, *PARTICLE size distribution, *ENZYME kinetics, *MOLLISOLS, *SOIL microbiology

Abstract

Particle-size soils were fractionated for evaluating changes in the composition of bacterial community and enzyme activity in response to 13 years of fertilization. This study focused on Mollisol and its particle-size fractions of 200-2,000 μm (coarse sand sized), 63 to 200 μm (fine sand sized), 2 to 63 μm (silt sized), and 0.1 to 2 to μm (clay-sized). Long-term chemical fertilization lowered the pH of all particle fractions, whereas organic fertilizer application mitigated soil acidification. Nutrient concentrations depended on both fertilizer treatment and particle fractions and enzymes were unevenly active throughout the soil. Generally, the highest enzyme activities were observed in the silt and clay fractions of control soil and the soil treated with chemical fertilizer (N, P, and K (NPK)) and in the sand-sized fraction of soil treated with manure and chemical fertilizer (MNPK). Except for acid phosphomonoesterase, the other tested enzyme activities in coarse-sized fractions of MNPK soil were significantly higher than those of the control and NPK soils. Fertilization and soil fraction interactively ( p < 0.05) affected the enzyme activity. Denaturing gradient gel electrophoresis analysis showed that the bacterial community structure significantly differed in different particle sizes with a higher bacterial diversity in small-sized than in coarse-sized fractions. Dominant bands were excised and sequenced. We have found the following bacterial groups: Actinobacteria, γ-proteobacteria, and Acidobacteria. In addition, enrichment of organic matter in coarser fractions was related to greater bacterial diversity than any other treatment. Principal component analysis showed a smaller variability among fractions of the organic amended treatment. Redundancy analysis showed that the tested properties significantly affected the composition of bacterial community with the exception of C/N and available P. No significant correlation between enzyme activity and bacterial community composition was detected, whereas positive correlations between other soil properties and enzyme activities were observed to various extents. Probably, enzyme activities might be affected by specific functional bacterial communities rather than by the overall bacterial community. We concluded that the long-term application of organic manures contributed to the increase of soil organic matter content of particles higher than 200 mm, with higher bacterial diversity and increases in most of the enzyme activities. [ABSTRACT FROM AUTHOR]

Published

2014

19. Effects of bio-organic fertilizer plus soil amendment on the control of tobacco bacterial wilt and composition of soil bacterial communities.

Author

Wu, Kai, Yuan, Saifei, Wang, Lili, Shi, Junxiong, Zhao, Jun, Shen, Biao, and Shen, Qirong

Subjects

*BIOORGANIC chemistry, *ORGANIC fertilizers, *SOIL microbiology, *SOIL amendments, *TOBACCO, *RALSTONIA solanacearum, *BACTERIAL wilt diseases

Abstract

Tobacco bacterial wilt (TBW) is caused by Ralstonia solanacearum ( R. solanacearum), a severe pathogenic agent with a wide host range. In this study, lime + ammonium bicarbonate (L + AB), organic fertilizer (OF), bio-organic fertilizer (BOF), and integrated treatment (L + AB + BOF) were assessed for the ability to control TBW and to influence the composition of native soil bacterial communities. The results showed that disease incidence of L + AB + BOF for two growth seasons in pot experiment was the lowest, with only 15.56 and 11.11 % at seasons 1 and 2, respectively. The integrated treatment could also significantly suppress TBW in the field, with a disease incidence of only 14.27 % compared with 35.41, 50.03, and 31.32 % in L + AB, OF, and BOF treatments, respectively. With application of the integrated treatment in pot and field experiments, the abundances of R. solanacearum were both significantly lower than those with other treatments. Denaturing gradient gel electrophoresis (DGGE) patterns showed that application of BOF significantly affected composition of bacterial communities of rhizosphere. The analysis of 454 sequencing data showed that application of integrated treatment recruited more beneficial bacteria than other treatments, such as Bacillus, Paenibacillus, Arthrobacter, and Streptomyces, while the abundance of Ralstonia with the integrated treatment was decreased. Overall, these results suggested that application of integrated agricultural management could effectively suppress bacterial wilt by affecting the composition of bacterial community and reducing the population of R. solanacearum. [ABSTRACT FROM AUTHOR]

Published

2014

20. Ammonia volatilization in Chinese double rice-cropping systems: a 3-year field measurement in long-term fertilizer experiments.

Author

Shang, Qingyin, Gao, Cuimin, Yang, Xiuxia, Wu, Pingping, Ling, Ning, Shen, Qirong, and Guo, Shiwei

Subjects

*AMMONIA, *CROPPING systems, *RICE farming, *NITROGEN fertilizers, *PHOSPHATE fertilizers, *GRAIN yields

Abstract

The impact of long-term fertilizer on ammonia (NH) volatilization in a double rice-cropping system is not well documented. A long-term fertilizer experiment in Chinese double rice-cropping systems initiated in 1990 was used in this study to evaluate the NH volatilization. Six fertilizer treatments were designed, including inorganic fertilizer [nitrogen and phosphorus fertilizer (NP), nitrogen and potassium fertilizer (NK), and balanced mineral fertilizer (NPK)], combined inorganic/organic fertilizers at full and reduced rate (FOM and ROM), and no fertilizer application (served as control). Ammonia volatilization fluxes were measured using a continuous airflow enclosure method during double rice growing seasons from 2007 to 2009. Results showed that the cumulative NH volatilizations in the fertilizer plots ranged from 12.8 to 27.3 kg N ha for the early rice season and from 17.3 to 32.7 kg N ha for the late rice season, which accounted for 9.2-33.6 % and 17.8-32.2 % of the applied N, respectively. The NH concentration in floodwater is a predominant factor to NH losses in the double rice-cropping systems. Compared with the NPK, the cumulative NH volatilizations during double rice growing seasons were respectively increased by 9.7, 50.6, and 37.6 % for the NP, NK, and FOM plots, respectively, while they were decreased by 24.6 % for the ROM plots. Compared with the NPK, N uptakes by rice were decreased by 7.2-49.7 % with imbalanced fertilizer application (NP and NK), while they were increased by 9.6-41.0 % with combined inorganic/organic fertilizers application (ROM and FOM). Grain yields were comparable among the NPK, ROM, and FOM treatments, but they were declined by the treatments with imbalanced fertilizer application. These results suggested that agricultural economic viability and NH volatilization mitigation can be simultaneously achieved by balanced inorganic and organic fertilizers application. [ABSTRACT FROM AUTHOR]

Published

2014

21. Bio-organic fertilizer application significantly reduces the Fusarium oxysporum population and alters the composition of fungi communities of watermelon Fusarium wilt rhizosphere soil.

Author

Zhao, Shuang, Liu, Dongyang, Ling, Ning, Chen, Fadi, Fang, Weimin, and Shen, Qirong

Subjects

*WATERMELONS, *ORGANIC fertilizers, *FUSARIUM oxysporum, *RHIZOSPHERE, *POLYMERASE chain reaction, *PLANT genes, *PAENIBACILLUS

Abstract

Watermelon Fusarium wilt is one of the most severe soil-borne diseases caused by Fusarium oxysporum f. sp. niveum. In this study, the population of F. oxysporum was quickly monitored by real-time PCR and DNA array in watermelon Fusarium wilt infected soils treated with Paenibacillus polymyxa SQR21 enhanced bio-organic fertilizer (BIO) at the beginning of nursery growth and/or at the beginning of transplanting. The fungal community composition was investigated by molecular cloning and DGGE techniques. The real-time PCR results showed the F. oxysporum population in the rhizosphere soil decreased from 8.56 × 10 colony-forming units (cfu) g rhizosphere soil to 9.41 × 10 cfu g rhizosphere soil after BIO application and the DNA array detection signals of F. oxysporum population weakened. The difference between F. oxysporum abundance of BIO amended and not amended bulk soils was lower than 10 cfu g soil. DGGE profile indicated that BIO application changed the fungal community structure in the rhizosphere soils; the molecular cloning data revealed that consecutive applications of BIO at nursery and transplanting stages not only decreased Ascomycota and increased Basidiomycota abundance in the rhizosphere soil but also caused the apperance of unique fungal group which were not found in the control. The beneficial fungi Chaetomium sp. Aspergillus penicillioides were found in the BIO amended treatment, while some harmful fungi such as F. oxysporum, Rhizoctonia solani, and Fusarium solani were only detected in the control. Data from this study indicated that BIO application can control watermelon Fusarium wilt by suppressing the population of F. oxysporum and changing the fungal community structure in the rhizosphere soils. [ABSTRACT FROM AUTHOR]

Published

2014

22. De-coupling of root-microbiome associations followed by antagonist inoculation improves rhizosphere soil suppressiveness.

Author

Qiu, Meihua, Li, Shuqing, Zhou, Xuan, Cui, Xiaoshuang, Vivanco, Jorge, Zhang, Nan, Shen, Qirong, and Zhang, Ruifu

Subjects

*SOIL microbiology, *PLANT roots, *MATHEMATICAL decoupling, *RHIZOSPHERE microbiology, *ECOLOGICAL niche, *FUNGICIDES

Abstract

It was hypothesized that disruption of the root-microbiome association creates empty rhizosphere niches that could be filled by both soilborne pathogens and beneficial microbes. The effect of de-coupling root-microbiome associations related to improve soil suppressiveness was investigated in cucumber using the pathogen Fusarium oxysporum f. sp. Cucumerinum (FOC) and its antagonist Bacillus amyloliquefaciens SQR9 (SQR9) system. The root-soil microbiome association of cucumber was disrupted by applying the fungicide carbendazim to the soil, and then FOC or/and its antagonist SQR9 were inoculated in the rhizosphere. In the fungicide treatment, the FOC wilt disease incidence was significantly increased by 13.3 % on average compared to the FOC treatment without fungicide. However, when the fungicide treatment was applied to the soil with SQR9 and FOC, the SQR9 effectively reduced the disease incidence, and improved cucumber plant growth compared to a no fungicide control. These results indicate that de-coupling of root-microbiome associations followed by antagonist inoculation can improve rhizosphere soil suppressiveness, which may help to develop strategies for efficient application of rhizosphere beneficial microbes in agriculture. [ABSTRACT FROM AUTHOR]

Published

2014

23. Tobacco bacterial wilt can be biologically controlled by the application of antagonistic strains in combination with organic fertilizer.

Author

Liu, Yanxia, Shi, Junxiong, Feng, Yonggang, Yang, Xingming, Li, Xiang, and Shen, Qirong

Subjects

*RALSTONIA solanacearum, *TOBACCO diseases & pests, *SOILBORNE plant diseases, *PHYSIOLOGICAL control systems, *ORGANIC fertilizers

Abstract

Bacterial wilt caused by Ralstonia solanacearum is one of the most serious tobacco diseases worldwide. Brevibacillus brevis (L-25) and Streptomyces rochei (L-9) with strong inhibitory effects on R. solanacearum in vitro were isolated from the rhizosphere of a healthy tobacco plant in a severely wilt-diseased field. Pot and field experiments were conducted to evaluate the biocontrol effect of the isolated antagonists alone and in combination with organic fertilizer. In pot experiment, the control efficacy was 92.3-100 % in the treatments applied with L-25 and L-9 alone or together with organic fertilizers. When bioorganic fertilizer containing L-9 and L-25 was applied to the soil in field condition, the control efficacies were 95.4 and 30.0 in the Anhui and Guizhou field plots, respectively. The counts of bacteria and actinomycetes in rhizosphere soil were significantly increased ( p ≤ 0.05) under all antagonist applications compared with CK (P). In contrast, fungal and R. solanacearum densities in the rhizosphere soil applied with antagonists were much lower than the CK (P) rhizosphere. Combined application of the two antagonists had better effect than single antagonist treatments. The antagonists were more effective when they were combined with organic fertilizer as compared with the antagonistic strains only. These results allow us to conclude that a combination of the biocontrol agents, L-25 and L-9, together with organic fertilizers can effectively control bacterial wilt by affecting soil microbial structure. [ABSTRACT FROM AUTHOR]

Published

2013

24. Effects of novel bioorganic fertilizer produced by Bacillus amyloliquefaciens W19 on antagonism of Fusarium wilt of banana.

Author

Wang, Beibei, Yuan, Jun, Zhang, Jian, Shen, Zongzhuan, Zhang, Maoxing, Li, Rong, Ruan, Yunze, and Shen, Qirong

Subjects

*FUSARIUM wilt of banana, *BACILLUS amyloliquefaciens, *FERTILIZERS, *BOTANICAL fungicides, *PLANT diseases, *ORGANIC fertilizers

Abstract

Banana production has been severely hindered by the long-term practice of monoculture agriculture. Fusarium wilt, caused by the Fusarium oxysporum f. sp. cubense (FOC), is one of the most destructive diseases that can afflict banana plants. It is both necessary and urgent to find an efficient method for protecting banana production worldwide. In this study, 57 antagonistic bacterial strains were isolated from the rhizospheres of healthy banana plants grown in a heavily wilt-diseased field; of the 57 strains, six strains with the best survival abilities were chosen for further study. Compared with the control and the other strains in the greenhouse experiment, W19 strain was found to observably decrease the incidence of Fusarium wilt and promote the growth of banana plants when combined with the organic fertilizer (OF). This strain was identified as Bacillus amyloliquefaciens based on its morphological, physiological, and biochemical properties, as well as 16S rRNA analysis. Two kinds of antifungal lipopeptides (iturin and bacillomycin D) produced by W19 strain were detected and identified using HPLC-ESI-MS. Another lipopeptide, called surfactin, was also produced by the thick biological film forming W19 strain. In addition to lipopeptides, 18 volatile antifungal compounds with significant antagonistic effect against F. oxysporum were detected and identified using gas chromatography-mass spectrometer (GC-MS). The work described herein not only highlights how the bioorganic fertilizer with B. amyloliquefaciens can be used to control Fusarium wilt of banana but also examines some of the potential mechanisms involved in the biocontrol of Fusarium wilt. [ABSTRACT FROM AUTHOR]

Published

2013

25. Antagonist Bacillus subtilis HJ5 controls Verticillium wilt of cotton by root colonization and biofilm formation.

Author

Li, Shuqing, Zhang, Nan, Zhang, Zhenhua, Luo, Jia, Shen, Biao, Zhang, Ruifu, and Shen, Qirong

Subjects

*VERTICILLIUM wilt diseases, *BACILLUS subtilis, *GREEN fluorescent protein, *CULTIVARS, *BIOLOGICAL pest control agents, *PLANT diseases

Abstract

Cotton plants that are continuously subjected to monoculture suffer greatly from Verticillium wilt disease. The application of a novel bioorganic fertilizer (BOF) consisting of organic fertilizer combined with the antagonistic Bacillus subtilis strain HJ5 significantly suppressed Verticillium wilt of cotton. The disease incidence rates in soils that were treated with BOF (1 %, w/ w) in the nursery stage, in the transplanted soil stage or in both stages, decreased by 42.9 %, 57.1 %, and 88.0 %, respectively, compared with controls. B. subtilis HJ5 was tagged with a plasmid-borne gfp gene encoding the green fluorescent protein to investigate its colonization behavior on cotton root surfaces. The results indicated that B. subtilis HJ5 predominantly colonizes the elongation and differentiation zones of the roots and forms micro-colonies in hydroponic and soil systems. The population of B. subtilis HJ5 in the rhizosphere and on cotton roots was also monitored. The number of B. subtilis HJ5 cells on the root surface reached a peak value of approximately 10 cfu per gram of roots 3 days after exposure of the cotton seedlings to the bacteria. Probably the colonization of B. subtilis HJ5 on cotton roots is one of the mechanisms involved in protecting cotton plants from fungal infection. [ABSTRACT FROM AUTHOR]

Published

2013

26. Role of arbuscular mycorrhizal network in carbon and phosphorus transfer between plants.

Author

Ren, Lixuan, Lou, Yunsheng, Zhang, Ning, Zhu, Xudong, Hao, Wenya, Sun, Shubin, Shen, Qirong, and Xu, Guohua

Subjects

*VESICULAR-arbuscular mycorrhizas, *CARBON, *PHOSPHORUS, *WATERMELONS, *RICE

Abstract

Intercropping with aerobic rice or arbuscular mycorrhizal fungi (AMF) colonization alleviated watermelon wilt disease, which is likely attributed to rice root exudates or AMF depressing watermelon wilt pathogen. However, it is unclear whether rice root exudates transfers to watermelon rhizosphere soil and whether AMF affects the transfer of rice root exudates to watermelon rhizosphere soil. A rhizobox experiment, with aerobic rice under CO, was conducted to investigate the effect of AMF colonization on carbon (C) transfer from rice to watermelon and on phosphorus (P) uptake by both watermelon and rice. The rhizobox was separated into labelling side (L side) and sampling side (S side) by inserting nylon mesh in the middle of the box. The L side was planted with aerobic rice, and the S side was aerobic rice (monocropping) or watermelon (intercropping). When CO was added to rice canopy at the L side, C activities of rice roots and rhizosphere soils in the L side were increased by intercropping with watermelon or AMF colonization. The C was detected in roots and rhizosphere soils of rice and watermelon in the S side, but no differences were found among different treatments. C activities in leaves were improved by AMF inoculation in the S side, regardless of rice or watermelon. Mycorrhizal colonization stimulated P absorption and translocation to rice in intercropping system. These findings suggest that AMF colonization could increase C transfer from rice to watermelon while intercropping with watermelon could promote AMF colonization and P uptake by rice. [ABSTRACT FROM AUTHOR]

Published

2013

27. Application of bio-organic fertilizer can control Fusarium wilt of cucumber plants by regulating microbial community of rhizosphere soil.

Author

Qiu, Meihua, Zhang, Ruifu, Xue, Chao, Zhang, Shusheng, Li, Shuqing, Zhang, Nan, and Shen, Qirong

Subjects

*RHIZOSPHERE, *FUSARIUM oxysporum, *CUCUMBER research, *ORGANIC fertilizers, *SOIL amendments

Abstract

Fusarium wilt, caused by Fusarium oxysporum f. sp. cucumerinum J. H. Owen, results in considerable yield losses for cucumber plants. A bio-organic fertilizer (BIO), which was a combination of manure composts with antagonistic microorganisms, and an organic fertilizer (OF) were evaluated for their efficiencies in controlling Fusarium wilt. Application of the BIO suppressed the disease incidence by 83% and reduced yield losses threefold compared with the application of OF. Analysis of microbial communities in rhizosphere soils by high-throughput pyrosequencing showed that more complex community structures were present in BIO than in OF treated soils. The dominant taxonomic phyla found in both samples were Proteobacteria, Firmicutes, Actinobacteria and Acidobacteria among bacteria and Ascomycota among fungi. Abundance of beneficial bacteria or fungi, such as Trichoderma, Hypoxylon, Tritirachium, Paenibacillus, Bacillus, Haliangium and Streptomyces, increased compared to the OF treatment, whereas the soil-borne pathogen, Fusarium, was markedly decreased. Overall, the results of this study demonstrate that the application of the BIO was a useful and effective approach to suppress Fusarium wilt and that the high-throughput 454 pyrosequencing was a suitable method for the characterization of microbial communities of rhizosphere soil of cucumber. [ABSTRACT FROM AUTHOR]

Published

2012

28. Biological control of tobacco black shank and colonization of tobacco roots by a Paenibacillus polymyxa strain C5.

Author

Ren, Xiaoli, Zhang, Nan, Cao, Minghui, Wu, Kai, Shen, Qirong, and Huang, Qiwei

Subjects

*PHYSIOLOGICAL control systems, *TOBACCO, *PATHOGENIC microorganisms, *PAENIBACILLUS, *SOIL microbiology

Abstract

Tobacco black shank, caused by a soil-borne pathogen, Phytophthora parasitica var . nicotianae, is one of the most serious diseases which reduce tobacco production worldwide. In this study, P. parasitica var . nicotianae was successfully controlled in vitro and in vivo by a newly isolated strain, Paenibacillus polymyxa C5, which is a plant-growth-promoting rhizobacteria and an effective biocontrol agent. Pot experiments were carried out to evaluate the effect of a novel bio-organic fertilizer (BIO), produced by the solid fermentation of organic fertilizer amended P. polymyxa C5, on the control of tobacco black shank. In comparison with the control, the disease incidence was significantly ( P < 0.05) reduced by 50% with the application of BIO. P. polymyxa C5 was tagged with a plasmid-borne gfp gene to investigate its colonization behavior on tobacco roots in a natural soil system. As determined by confocal laser scanning microscopy, P. polymyxa C5 formed a biofilm on the tobacco roots growing in soil, both on the root tip and elongation zone but not inside the roots. It is speculated that the colonization of tobacco roots by P. polymyxa C5 is one of the mechanisms for the protection of tobacco plants from fungal infection. [ABSTRACT FROM AUTHOR]

Published

2012

29. Control of cotton Verticillium wilt and fungal diversity of rhizosphere soils by bio-organic fertilizer.

Author

Lang, Jiaojiao, Hu, Jiang, Ran, Wei, Xu, Yangchun, and Shen, Qirong

Subjects

*VERTICILLIUM wilt of cotton, *SOILBORNE plant diseases, *ORGANIC fertilizers, *RHIZOSPHERE, *POLYMERASE chain reaction

Abstract

Cotton Verticillium wilt is a destructive soil-borne disease affecting cotton production. In this study, application of bio-organic fertilizer (BIO) at the beginning of nursery growth and/or at the beginning of transplanting was evaluated for its ability to control Verticillium dahliae Kleb. The most efficient control of cotton Verticillium wilt was achieved when the nursery application of BIO was combined with a second application in transplanted soil, resulting in a wilt disease incidence of only 4.4%, compared with 90.0% in the control. Denaturing gradient gel electrophoresis patterns showed that the consecutive applications of BIO at nursery and transplanting stage resulted in the presence of a unique group of fungi not found in any other treatments. Humicola sp., Metarhizium anisopliae, and Chaetomium sp., which were considered to be beneficial fungi, were found in the BIO treatment, whereas some harmful fungi, such as Alternaria alternate, Coniochaeta velutina, and Chaetothyriales sp. were detected in the control. After the consecutive applications of BIO at nursery and transplanting stage, the V. dahliae population in the rhizosphere soil in the budding period, flowering and boll-forming stage, boll-opening stage, and at harvest time were 8.5 × 10, 3.1 × 10, 4.6 × 10, and 1.7 × 10 colony-forming units per gram of soil (cfu g), respectively, which were significantly lower than in the control (6.1 × 10, 3.4 × 10, 5.2 × 10, and 7.0 × 10 cfu g, respectively). These results indicate that the suggested application mode of BIO could effectively control cotton Verticillium wilt by significantly changing the fungal community structure and reducing the V. dahliae population in the rhizosphere soil. [ABSTRACT FROM AUTHOR]

Published

2012

30. Bacillus subtilis SQR 9 can control Fusarium wilt in cucumber by colonizing plant roots.

Author

Cao, Yun, Zhang, Zhenhua, Ling, Ning, Yuan, Yujuan, Zheng, Xinyan, Shen, Biao, and Shen, Qirong

Subjects

*BACILLUS subtilis, *FUSARIUM diseases of plants, *CUCUMBER diseases & pests, *FERTILIZERS, *PLANT roots

Abstract

Fusarium wilt is one of the major constraints on cucumber production worldwide. Several strategies have been used to control the causative pathogen, Fusarium oxysporum f. sp. cucumerinum J. H. Owen, including soil solarization, fungicide seed treatment and biological control. In this study, F. oxysporum f. sp. cucumerinum was successfully controlled by a newly isolated strain, Bacillus subtilis SQR 9, in vitro and in vivo. Greenhouse experiments were carried out to evaluate the effect of inoculation and solid fermentation of organic fertilizer with B. subtilis SQR 9, hereby defined as bio-organic fertilizer (BIO), on the control of Fusarium wilt. In comparison with the control, the wilt incidence was significantly reduced (49-61% reduction) by application of BIO. The rhizosphere population of F. oxysporum f. sp. cucumerinum, as detected both by selective plating and realtime PCR, was significantly lower in BIO-treated plants than the control. The localization of bacterial cells, pattern of colonization and survival of B. subtilis SQR 9 in the rhizsosphere of cucumber, was examined by fluorescent microscopy and explored following recovery of the green fluorescent protein ( gfp)-labeled SQR 9 with the new gfp-marked shuttle vector pHAPII through selective plating. The preferential sites of the labeled strain were the differentiation and elongation zone, root hair and the lateral root junctions. The population of the strain was 10 cfu/g root in rhizoplane. These results indicate that the strain was able to survive well in the rhizosphere of cucumber, suppressed growth of F. oxysporum in the rhizosphere of cucumber and protected the host from the pathogen. [ABSTRACT FROM AUTHOR]

Published

2011

31. Long-term agronomic practices alter the composition of asymbiotic diazotrophic bacterial community and their nitrogen fixation genes in an acidic red soil.

Author

Xun, Weibing, Li, Wei, Huang, Ting, Ren, Yi, Xiong, Wu, Miao, Youzhi, Ran, Wei, Li, Dongchu, Shen, Qirong, and Zhang, Ruifu

Abstract

The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria.The asymbiotic diazotrophic bacteria are important for nitrogen (N) input to soil. Here, we investigated asymbiotic diazotrophic bacteria in an acidic red soil from functional, phylogenetic, and ecological perspectives. We firstly confirmed that phosphorus (P) availability determines the overall asymbiotic N fixation potential in the red soil. Then, we analyzed the soil bacterial community and N fixing (nifH) gene composition. Long-term different fertilizations significantly affected the composition of soil bacterial community. In addition, long-term organic cultivations increased most of the asymbiotic diazotrophic bacteria and the corresponding nifH gene abundances. Few asymbiotic diazotrophic bacteria, belonging to Chloroflexaceae, Methylocystaceae, Enterobacteriaceae, and Pseudomonadaceae, and their corresponding nifH genes were more abundant in N and P co-limited than in not co-limited soils, suggesting that some bacterial taxa from these families might be activated under nutrient limited conditions. Our findings provided new information for the distribution of asymbiotic diazotrophic bacteria in red soil and gave insights into the ecology of diazotrophic bacteria. [ABSTRACT FROM AUTHOR]

Published

2018

32. Erratum to: Contribution of indole-3-acetic acid in the plant growth promotion by the rhizospheric strain Bacillus amyloliquefaciens SQR9.

Author

Shao, Jiahui, Xu, Zhihui, Zhang, Nan, Shen, Qirong, and Zhang, Ruifu

Subjects

*INDOLE, *PLANT growth, *BACILLUS amyloliquefaciens

Abstract

A correction to the article "Contribution of indole-3-acetic acid in the plant growth promotion by the rhizospheric strain Bacillus amyloliquefaciens SQR9," by Jiahui Shao and colleagues that was published in the 2015 issue is presented.

Published

2015