Effects of <i>Hedysarum</i> leguminous plants on soil bacterial communities in the Mu Us Desert, northwest China

Zhou, Ziyuan; Yu, Minghan; Ding, Guodong; Gao, Guanglei; He, Yingying; Wang, Genzhu

doi:10.1002/ece3.6779

Cited by 19 publications

(11 citation statements)

References 78 publications

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“…In turn, plant roots directly affect the soil portion of the rhizosphere by releasing exudates such as sugars and organic acids, which are sources of nutrients and vitamins used by various bacteria and stimulate the development of microbial communities ( 55 ). Similarly, soil properties can affect root traits, resulting in variations in bacterial communities associated with the root system ( 56 , 57 ). Thus, we conclude that changes in root traits and soil nutrient accumulation in drought-stressed sugarcane varieties contribute to distinct bacterial community compositions, suggesting that ZZ6 may exhibit greater drought resistance than ZZ1 in response to these changes.…”

Section: Discussionmentioning

confidence: 99%

Adaptation of rhizosphere bacterial communities of drought-resistant sugarcane varieties under different degrees of drought stress

Dao,

Xing,

Chen

et al. 2023

Microbiol Spectr

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Sugarcane is highly sensitive to changes in moisture, and increased drought severely restricts its growth and productivity. Recent studies have shown that plant growth-promoting microorganisms are essential to reduce the adverse effects of environmental stresses, especially drought. However, our knowledge about the dynamics of rhizosphere microbial community structure in sugarcane under varying degrees of drought stress is limited. We analyzed the effects of different degrees of drought stress on the rhizosphere microbial communities of Zhongzhe 1(ZZ1) and Zhongzhe 6(ZZ6) with differences in drought resistance, by combining soil enzyme activity, nutrient content, and physiological and morphological characteristics of sugarcane roots. The results showed that rhizosphere bacterial community began to change at a field capacity of 50%, enriching the sugarcane rhizosphere with drought-resistant bacteria. The core strains of ZZ1 and ZZ6 rhizosphere enrichment were mainly Streptomycetales , Sphingomonadales , and Rhizobiales . However, compared to ZZ1, the changes in rhizosphere bacterial abundance in ZZ6 were primarily associated with the abundance of Streptomycetales as drought levels increased. Rhizobiales and Streptomycetales , enriched in the rhizosphere of ZZ6 under drought, were positively correlated with root tip number and total root length (TRL), increasing the distribution area of roots and, thus, improving water and nutrient uptake by the roots thereby enhancing the resistance of sugarcane to drought stress. This research enhances our understanding of the composition of the rhizosphere microbial community in sugarcane under different levels of drought stress and its interaction with the roots, thereby providing valuable insights for enhancing drought resistance in sugarcane. IMPORTANCE Drought stress is expected to further increase in intensity, frequency, and duration, causing substantial losses in sugarcane yields. Here, we exposed sugarcane to varying degrees of drought treatment during growth and quantified the eventual composition of the resulting sugarcane rhizosphere bacterial community groups. We found that sugarcane rhizosphere under mild drought began to recruit specific bacterial communities to resist drought stress and used the interactions of root tip number, total root length, and drought-resistant strains to improve sugarcane survival under drought. This research provides a theoretical basis for the rhizosphere microbiome to help sugarcane improve its resistance under different levels of drought stress.

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Section: Discussionmentioning

confidence: 99%

Adaptation of rhizosphere bacterial communities of drought-resistant sugarcane varieties under different degrees of drought stress

Dao,

Xing,

Chen

et al. 2023

Microbiol Spectr

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“…The Bonferroni correction was used for all multiple comparisons. Before statistical analysis, the Kolmogorov–Smirnov test of normality and Levene's test of homogeneity of variance were performed on the data (Yan et al, 2018; Zhou et al, 2020). Through one‐way analysis of variance (ANOVA) and the least significant difference test, the soil properties (SOC, TN, TP, AN, NN, AK, AP, pH, clay, silt, sand, BD, and SWC), the fungal diversity index and the relative abundance of all fungi and functional groups were tested.…”

Section: Methodsmentioning

confidence: 99%

“…To elucidate the co‐occurrence network pattern of fungal communities and assess the structural dissimilarities among fungal communities in each plantation, we performed a Spearman correlation analysis on the species composition of the top 50 most abundant fungal genera. Specifically, we considered data points with a correlation coefficient exceeding 0.7 and a p ‐value <0.05 as significant and employed Gephi software to visualize the resulting network patterns (Zhou et al, 2020). All statistical analyses were performed using SPSS 20.0 (SPSS Inc., Chicago, IL, USA).…”

Section: Methodsmentioning

confidence: 99%

Effects of afforestation on soil fungi in rocky mountain areas of North China

Zhang,

Li,

2023

Land Degrad Dev

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Afforestation has a substantial influence on soil fungal communities by introducing ecological variations within forest ecosystems via the inclusion of distinct tree species (coniferous and broadleaf) and afforestation patterns (pure forests and mixed forests). However, the specific effects of these variations on soil fungal communities require further investigation. Soil samples from birch (B: Betula platyphylla Suk.), larch (L: Larix gmelinii (Rupr.) Kuzen.), and mixed birch and larch (B–L) forests were used in this study, and a shrub–grassland field (S–G) was used as a reference. The abundance, diversity, and community composition of fungi in the soil of the monoculture forest (B and L), mixed forest (B–L), and S–G were studied by high‐throughput sequencing. The results showed that Basidiomycota was the dominant fungus in B and B–L, and the dominant genera were Inocybe and Amanita, respectively. Ascomycota was the dominant fungus in L and S–G, and the dominant genus was Mortierella. Afforestation reduced the richness and diversity of soil fungi. Larch forests were richer in soil fungi than B and B–L forests. Soil organic carbon was the main soil factor affecting the soil fungal community structure. Soil fungal community network changed less after planting L than after planting B and B–L, and the soil fungal community structure was more complex and stable in L than in B and B–L. For soil fungal community composition and function, mixed forests did not show outstanding advantages. Planting monoculture forests may be a more effective afforestation strategy in the rocky mountain areas of North China.

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“…It is well known that soil P availability affects and influences the microbial community in roots and soil (Ren et al, 2021). Some reports have shown that soil AP is significantly relevant to the bacterial community of S. davidii, indicating that AP may be an important factor affecting the diversity and composition of the bacterial community in the rhizosphere (Pande et al, 2017;Zhou et al, 2020). It has been found that soil microorganisms can transform the combined phosphorus in soil into water-soluble phosphorus, thus promoting the absorption of phosphorus by plants (He and Zhu, 1998) and shifting the rhizosphere bacterial microbiome (Lennon and Jones, 2011).…”

Section: Important Abiotic Factors Affecting Microbial Community Stru...mentioning

confidence: 99%

Environmental filtering drives the establishment of the distinctive rhizosphere, bulk, and root nodule bacterial communities of Sophora davidii in hilly and gully regions of the Loess Plateau of China

Liu

et al. 2022

Front. Microbiol.

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In addition to the rhizobia, other non-rhizobial endophytes (NREs) have been simultaneously isolated from the root nodules. The existence of NREs in leguminous root nodules is a universal phenomenon, and they have the potential to enhance legume survival, especially under conditions of environmental stress. However, the diversity and biogeographic patterns of microbial communities inhabiting root nodules are not well studied or understood. Here, we explored and characterized the diversity of NRE bacteria by using 16S rRNA gene high-throughput amplicon sequencing. Additionally, we compared the biogeography and co-occurrence patterns in review of the bacterial microbiota inhabiting the rhizosphere, the bulk soil and the root nodule bacterial communities associated with Sophora davidii, a native N-fixing wild leguminous shrub in hilly and gully regions of the Loess Plateau of China. The results showed the presence of a large diversity of bacteria belonging to 81 phyla, 154 classes, 333 orders, 463 families, and 732 genera inside the nodules. Proteobacteria were dominant in the nodule and rhizosphere soil samples, and Actinomycetes were dominant in the bulk soil samples. Mesorhizobium was the dominant genus in the nodules, accounting for between 60.15 and 83.74% of the bacteria. The microbial community composition of the NRE in the root nodules differed from that in the rhizosphere soil and the bulk soil of S. davidii. Moreover, we found that the biogeographic patterns and assembly process of the rhizobia and non-rhizobia communities differed in the root nodule, the rhizosphere soil and the bulk soil. Furthermore, the correlation analysis between the soil’s physical and chemical properties and the bacteria showed that available phosphorus was the predominant factor affecting the bacterial diversity within the rhizosphere soil. Finally, our results revealed that the microbial network diagram of co-occurrence patterns showed more complexes in the soil than in the root nodules. This indicates that only specific microorganisms could colonize and thrive in the rhizosphere through the selection and filtering effects of roots. In conclusion, there are significant differences in bacterial community composition in the nodules, rhizosphere and bulk soil in the hilly and gully region of the Loess Plateau, which is the result of environmental filtration. Our study improves the understanding of the biogeographic patterns and diversity of bacterial microbiota inhabiting root nodules and can help quantify and define the root nodule assemblage process of S. davidii.

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Effects of Hedysarum leguminous plants on soil bacterial communities in the Mu Us Desert, northwest China

Cited by 19 publications

References 78 publications

Adaptation of rhizosphere bacterial communities of drought-resistant sugarcane varieties under different degrees of drought stress

Adaptation of rhizosphere bacterial communities of drought-resistant sugarcane varieties under different degrees of drought stress

Effects of afforestation on soil fungi in rocky mountain areas of North China

Environmental filtering drives the establishment of the distinctive rhizosphere, bulk, and root nodule bacterial communities of Sophora davidii in hilly and gully regions of the Loess Plateau of China

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