Your search keyword '"Chen, Zhenjiang"' showing total 5 results

1. Fungal Endophyte Improves Survival of Lolium perenne in Low Fertility Soils by Increasing Root Growth, Metabolic Activity and Absorption of Nutrients

Author

Chen, Zhenjiang, Jin, Yuanyuan, Yao, Xiang, Chen, Taixiang, Wei, Xuekai, Li, Chunjie, White, James F., and Nan, Zhibiao

Published

2020

2. Soil fungal and bacterial communities are altered by the incorporation of leaf litter containing a fungal endophyte.

Author

Jin, Yuanyuan, Wei, Xuekai, White, James F., Chen, Taixiang, Li, Xiuzhang, Chen, Zhenjiang, and Li, Chunjie

Subjects

FUNGAL communities, BACTERIAL communities, BACTERIAL diversity, FOREST litter, PLANT litter decomposition, SOILS, SOIL microbiology, LOLIUM perenne

Abstract

Litter decomposition plays a key role in nutrient cycling across ecosystems. The presence of Epichloë endophytes in grass plants affects litter decomposition. The overall effects of leaf litter containing Epichloë endophytes on the chemical and biological properties in non‐rhizosphere soils have not previously been examined. The current study is aimed to understand the effect of direct incorporation of leaf litter from Epichloë endophyte‐infected perennial ryegrass (Lolium perenne) on soil chemical characteristics, and fungal and bacterial biodiversity. Firstly, fresh leaf litter of the endophyte Epichloë festucae var. lolii‐infected (E+) and endophyte‐free (E−) L. perenne were incorporated into the soil, and then samples were collected from E+ and E− litter incorporated soil at T0, T1, T2 and T3 (0, 120, 240 and 360 days) for chemical and sequencing analyses. The Epichloë‐containing leaf litter incorporation changed the soil microbial environment by enhancing the soil organic carbon (SOC), total nitrogen (TN), total phosphorus, NH4+–N and NO3−–N contents, and acidifying soil pH. The endophyte had stronger effects on soil bacteria than soil fungi when the litter was determined with and without the endophyte. Litter containing the Epichloë endophyte significantly increased the absolute abundance of the 16S rRNA gene and relative abundances of the Actinobacteria, Nitrospirae and Gemmatimonadetes, while significantly decreasing the relative abundances of the Planctomycetes and Rokubacteria and the diversity in soil bacteria community. There was no significant effect of endophyte‐containing leaf litter incorporation on the absolute abundance and diversity of the soil fungal community except the increment in the relative abundance of Rozellomycota. Soil pH and the SOC‐to‐TN ratio (C:N) were the main factors influencing the soil bacterial community, and the presence of E. festucae var. lolii was directly and positively related to the soil bacterial diversity. The current study established that Epichloë endophyte‐infection altered the abundance and diversity of the soil bacterial community by affecting leaf litter quality and increasing soil chemical properties after litter incorporation. Highlights: Soil microbial habitat was changed by leaf litter with Epichloë endophyte incorporation.Litter containing endophytes increased the absolute abundance of the 16S rRNA gene.Epichloë endophytes altered the diversity of bacteria during litter incorporation.The response of soil bacteria to a litter containing endophytes was greater than that of soil fungi. [ABSTRACT FROM AUTHOR]

Published

2022

3. Segregation of Lolium perenne into a subpopulation with high infection by endophyte Epichloë festucae var. lolii results in improved agronomic performance.

Author

Chen, Zhenjiang, Li, Chunjie, Nan, Zhibiao, White, James F., Jin, Yuanyuan, and Wei, Xuekai

Subjects

*LOLIUM perenne, *HOST plants, *RYEGRASSES, *INFECTION, *PLANT colonization, *TURFGRASSES

Abstract

Background and aims: Low temperature stress is a common hazard during plant growth. Endophyte infection has been shown to increase cold tolerance in host plants. Many Lolium perenne cultivars contain low to moderate levels of endophyte. This study was done to explore cultivar improvement by segregation of endophyte containing individuals from the original cultivar to create a high endophyte subpopulation. Methods: Endophyte-infected plants were segregated over the first 3 years to produce high-endophyte subpopulation, and field and greenhouse experiments were carried out in the forth and fifth to determine the cold tolerance of the L. perenne subpopulation with high endophyte infection rates (N), the parent (F), the control endophyte-free subpopulation (E) and the control local variety (L). Results: (1) After 3 years of screening, high endophyte infection rates in the tillers and seeds of plants were still observed (96.5%), and agronomic traits (crown width, plant height, panicle number, withering, regreen-up, the growth cycle and the over-wintering rate) was also improved with increased Epichloë colonization of host plant. (2) The subpopulation with high endophyte infection rates and improved agronomic traits had better cold tolerance than the parent, the control endophyte-free subpopulation and the control local variety. The possible mechanisms by which high endophyte infection enhances cold resistance in the field include increased root system, increased the over-wintering rate, reduced regrowth periods with the sowing date being October 15th. (3) The high-endophyte subpopulation significantly increased SOD, POD, CAT, and APX activities at 0, 5, and 10 °C by 11.8%–44.6%, compared with the parent population. Conclusions: The subpopulation had a high endophyte infection rate, improved agronomic traits and higher enzymatic activities. These results indicate that increasing endophyte infection rates by selection, effectively improved agronomic traits and cold tolerance. [ABSTRACT FROM AUTHOR]

Published

2020

4. Soil nutrient dynamics relate to Epichloë endophyte mutualism and nitrogen turnover in a low nitrogen environment.

Author

Chen, Zhenjiang, White, James F., Malik, Kamran, Chen, Hao, Jin, Yuanyuan, Yao, Xiang, Wei, Xuekai, Li, Chunjie, and Nan, Zhibiao

Subjects

*NITROGEN cycle, *NITROGEN fixation, *NUTRIENT uptake, *PLANT biomass, *PLANT nutrients

Abstract

Colonization by foliar fungal endophytes can assist host plants in the acquisition of soil nutrients, however understanding of the effects of Epichloë endophytes on soil nutrient dynamics and their consequences for nitrogen cycling remains fragmentary. Here, we studied the microbial functional genes involved in the soil nitrogen cycle and soil nutrient dynamics along a nitrogen gradient in rhizosphere soil of ryegrass infected by the endophyte Epichloë festucae var. lolii. High-throughput sequencing was used to determine the community of microbial functional genes. Plant nutrients and soil N 2 O flux were measured. The endophyte presence reduced the plant nutrient traits (shoot organic carbon, total nitrogen and total phosphorus, and root total phosphorus) under low nitrogen, while it increased the soil nutrient accumulation and altered the microbial environment. Plants with fungal endophyte showed higher community diversity in the AOB -amoA gene (ammonia-oxidation bacteria), had lower absolute and relative abundances in the nirK gene (nitrite reduction bacteria), and improved relative abundances and community diversity of the nosZ (nitrous oxide reduction bacteria). The nifH gene (N 2 fixing bacteria) showed higher absolute and relative abundances, and diversity in rhizosphere soil of endophyte-infected plants. Changes in plant and soil traits mediated by endophyte infection were closely related to N 2 O fluxes and nifH gene abundance. The changes in CO 2 flux by changing in soil microbial biomass nitrogen mediated by shoot biomass (induced by endophyte infection), which further altered the soil pH and NO 3 − content and lead to an increased in NH 4 + accumulation. The current study demonstrated that the possible mechanism for endophyte-mediated nutrient uptake might promote the NH 4 + accumulation through nitrogen mineralization and NO 3 − isomerization rather than enhancing in the nitrogen fixation process and inhibiting the denitrification process in N limited samples. By underlining the importance of endophyte infection for nutrient accumulation in plant and soil and biomass, these findings suggested that nutrient availability could initiate endophyte infection effects to mitigate the damage of low N stress for the host. • Nutrient availability mitigates low N stress by initiating endophyte effects. • Increased in soil microbial biomass carbon and nitrogen by endophyte infection. • Endophyte-infected plant reduced nitrous oxide (N 2 O) flux and increased CO 2 flux. • Endophyte-mediated nutrient uptake associated with soil NO 3 − dissimilation. [ABSTRACT FROM AUTHOR]

Published

2022

5. Gene analysis reveals that leaf litter from Epichloë endophyte-infected perennial ryegrass alters diversity and abundance of soil microbes involved in nitrification and denitrification.

Author

Chen, Zhenjiang, Jin, Yuanyuan, Yao, Xiang, Wei, Xuekai, Li, Xiuzhang, Li, Chunjie, White, James F., and Nan, Zhibiao

Subjects

*AMMONIA-oxidizing bacteria, *NITRIFICATION, *DENITRIFICATION, *RYEGRASSES, *GENES, *SOILS, *FOREST litter, *GRASSLAND soils

Abstract

Although Epichloë endophytes are present only in aboveground tissues of grasses they indirectly influence soil biological characteristics through increased litter incorporation and root exudation. Epichloë endophytes have been reported to affect the decomposition rates of litter by altering litter quality and microbial decomposers to affect soil characteristics. However, it is not well-studied that underlying effects on functional genes involved in nitrification and denitrification after incorporation of litter containing Epichloë endophytes into soil. We collected soil samples at S 0 (first litter incorporation), S 1 (second litter incorporation), S 2 (third litter incorporation) and S 3 (120 days after the third litter incorporation) times after incorporation of litter that was either infected with the fungal endophyte Epichloë festucae var. Lolii or free of Epichloë endophyte, respectively.. We sampled the soil fororganic carbon (OC), total nitrogen (TN), total phosphorus (TP), ammonium nitrogen (NH 4 +-N: AN), nitrate nitrogen (NO 3 −-N: NN), soil microbial biomass carbon (MBC), nitrogen (MBN), ammonia-oxidizing bacteria (AOB- amoA) and ammonia-oxidizing archaea (AOA- amoA) functional genes for nitrification, nitrite reduction (nirS and nirK) and nitrous oxide reduction (nosZ) functional genes for denitrification. We found that Epichloë -infected plant increased the soil properties (OC, TN, AN, NN) and microbial biomass C in S 1 to S 3 times, and microbial biomass N in S 2 and S 3 times, but reduced soil pH in S 1 times and the C_N ratio in S 2 and S 3 times by litter incorporation. The absolute abundance of the AOB- amoA functional gene at S 1 and S 3 times and relative abundances of Planctomycetes, Methylobacterium, Nitosomonas, Gemmata, Geodermatophilus and Sinorhizobium in the nirK functional gene community were significantly higher in soil with Epichloë -infected litter compared to soil with Epichloë -free litter at S 1 and S 3 times. While the absolute abundance at S 1 and S 3 times and diversity at S 3 times of the nirK functional gene, and the absolute abundance at S 1 to S 3 times and diversity at S 1 times of the nosZ functional gene, and relative abundance of Proteobacteria in the AOB- amoA functional gene were significantly lower in soil with litter containing Epichloë endophyte than that of soil with litter without the endophyte. The soil moisture, and the contents of TP, OC, AN and MBN were the best explanatory variables for the altered microbial community. Our results provide a new understanding of the responses of soil nitrification and denitrification genes through incorporation of litter containing Epichloë endophytes into soil. • Soil microbial habitat environment was changed by litter incorporation. • We observed an increase in the absolute abundance of AOB- amoA in EI compared to EF soil. • The composition of nirK functional gene communities differed in EI and EF soil. • Endophyte reduced the diversity of nosZ functional gene following litter incorporation. • Soil properties were explained best the difference in functional genes. [ABSTRACT FROM AUTHOR]

Published

2021