Your search keyword '"Yong, Jean"' showing total 5 results

1. Spatiotemporal, physiological and transcriptomic dynamics of wild jujube seedlings under saline conditions.

Author

He, Aobing, Ma, Zhibo, Li, Yunfei, Huang, Chen, Yong, Jean Wan Hong, and Huang, Jian

Subjects

JUJUBE (Plant), ABSCISIC acid, TRANSCRIPTOMES, SOIL salinity, SALICYLIC acid, SEEDLINGS

Abstract

Soil salinity is a major constraint limiting jujube production in China. Wild jujube (Ziziphus jujuba var. spinosa (Bunge) Hu ex H. F. Chow) is widely used as the rootstock of jujube (Z. jujuba) to overcome the saline conditions. To understand the adaptive mechanism in wild jujube under saline conditions, we combined spatiotemporal and physiological assessments with transcriptomic analysis on wild jujube seedlings undergoing various salt treatments. These salt treatments showed dose and duration effects on biomass, photosynthesis, (K +) and (Na +) accumulation. Salt treatments induced higher levels of salicylic acid in roots and leaves, whereas foliar abscisic acid was also elevated after 8 days. The number of differential expression genes increased with higher doses and also longer exposure of NaCl treatments, with concomitant changes in the enriched Gene Ontology terms that were indicative of altered physiological activities. Gene co-expression network analysis identified the core gene sets associated with salt-induced changes in leaves, stems and roots, respectively. The nitrogen transporters, potassium transporters and a few transcription factors belonging to WRKY/MYB/bHLH families were clustered as the hub genes responding to salt treatments, which were related to elevated nitrogen and K+/Na+. Ectopic overexpression of two WRKY transcription factor genes (ZjWRKY6 and ZjWRKY65) conferred stronger salt-tolerance in Arabidopsis thaliana transformants by enhancing the activities of antioxidant enzymes, decreasing malondialdehyde accumulation and maintaining K+/Na+ homeostasis. This study provided evidence about the spatiotemporal, physiological and transcriptomic dynamics of wild jujube during salt stress and identified potential genes for further research to improve salt tolerance in jujube. [ABSTRACT FROM AUTHOR]

Published

2023

2. Is the NH4+-induced growth inhibition caused by the NH4+ form of the nitrogen source or by soil acidification?

Author

Feng Wang, Qiang Wang, Qiaogang Yu, Jing Ye, Jingwen Gao, Haitian Liu, Yong, Jean W. H., Yijun Yu, Xiaoxia Liu, Haimin Kong, Xinhua He, and Junwei Ma

Subjects

SOIL acidification, NITROGEN in soils, GLUTAMINE synthetase, INHIBITION (Chemistry), CROP growth, BIOFERTILIZERS

Abstract

Soil acidification often occurs when the concentration of ammonium (NH4+) in soil rises, such as that observed in farmland. Both soil acidification and excess NH4+ have serious adverse effects on crop growth and food production. However, we still do not know which of these two inhibitors has a greater impact on the growth of crops, and the degree of their inhibitory effect on crop growth have not been accurately evaluated. 31 wheat cultivars originating in various areas of China were planted under 5 mM sole NH4+ (ammonium nitrogen, AN) or nitrate nitrogen in combined with two pH levels resembling acidified conditions (5.0 and 6.5). The results showed that the shoots and roots biomass were severely reduced by AN in both and these reduction effects were strengthened by a low medium pH. The concentration of free NH4+ and amino acids, the glutamine synthetase activity were significantly higher, but the total soluble sugar content was reduced under NH4+ conditions, and the glutamine synthetase activity was reduced by a low medium pH. Cultivar variance was responsible for the largest proportion of the total variance in plant dry weight, leaf area, nodal root number, total root length and root volume; the nitrogen (N) form explains most of the variation in N and C metabolism; the effects of pH were the greatest for plant height and root average diameter. So, soil acidification and excess NH4+ would cause different degrees of inhibition effects on different plant tissues. The findings are expected to be useful for applying effective strategies for reducing NH4+ stress in the field. [ABSTRACT FROM AUTHOR]

Published

2022

3. Impact of biochar application on nitrogen nutrition of rice, greenhouse-gas emissions and soil organic carbon dynamics in two paddy soils of China.

Author

Xie, Zubin, Xu, Yanping, Liu, Gang, Liu, Qi, Zhu, Jianguo, Tu, Cong, Amonette, James, Cadisch, Georg, Yong, Jean, and Hu, Shuijin

Subjects

BIOCHAR, NITROGEN fertilizers, RICE -- Nutrition, GREENHOUSE gas mitigation, CARBON in soils, INCEPTISOLS, ULTISOLS, EXPERIMENTAL agriculture

Abstract

Aims: Two field microcosm experiments and N labeling techniques were used to investigate the effects of biochar addition on rice N nutrition and GHG emissions in an Inceptisol and an Ultisol. Methods: Biochar N bioavailability and effect of biochar on fertilizer nitrogen-use efficiency (NUE) were studied by N-enriched wheat biochar (7.8803 atom% N) and fertilizer urea (5.0026 atom% N) (Experiment I). Corn biochar and corn stalks were applied at 12 Mg ha to study their effects on GHG emissions (Experiment II). Results: Biochar had no significant impact on rice production and less than 2 % of the biochar N was available to plants in the first season. Biochar addition increased soil C and N contents and decreased urea NUE. Seasonal cumulative CH emissions with biochar were similar to the controls, but significantly lower than the local practice of straw amendment. NO emissions with biochar were similar to the control in the acidic Ultisol, but significantly higher in the slightly alkaline Inceptisol. Carbon-balance calculations found no major losses of biochar-C. Conclusion: Low bio-availability of biochar N did not make a significantly impact on rice production or N nutrition during the first year. Replacement of straw amendments with biochar could decrease CH emissions and increase SOC stocks. [ABSTRACT FROM AUTHOR]

Published

2013

4. Enhanced allelopathy and competitive ability of invasive plant Solidago canadensis in its introduced range.

Author

Yuan, Yongge, Wang, Bing, Zhang, Shanshan, Tang, Jianjun, Tu, Cong, Hu, Shuijin, Yong, Jean W. H., and Chen, Xin

Subjects

ALLELOPATHY, PLANT competition, INVASIVE plants, PLANT growing media

Abstract

Aims Why invasive plants are more competitive in their introduced range than native range is still an unanswered question in plant invasion ecology. Here, we used the model invasive plant Solidago canadensis to test a hypothesis that enhanced production of allelopathic compounds results in greater competitive ability of invasive plants in the invaded range rather than in the native range. We also examined the degree to which the allelopathy contributes increased competitive ability of S. canadensis in the invaded range. Methods We compared allelochemical production by S. canadensis growing in its native area (the USA) and invaded area (China) and also by populations that were collected from the two countries and grown together in a ‘common garden’ greenhouse experiment. We also tested the allelopathic effects of S. canadensis collected from either the USA or China on the germination of Kummerowia striata (a native plant in China). Finally, we conducted a common garden, greenhouse experiment in which K. striata was grown in monoculture or with S. canadensis from the USA or China to test the effects of allelopathy on plant–plant competition with suitable controls such as adding activated carbon to the soil to absorb the allelochemicals and thereby eliminating any corresponding allopathic effects. Important findings Allelochemical contents (total phenolics, total flavones and total saponins) and allelopathic effects were greater in S. canadensis sampled from China than those from the USA as demonstrated in a field survey and a common garden experiment. Inhibition of K. striata germination using S. canadensis extracts or previously grown in soil was greater using samples from China than from the USA. The competitive ability of S. canadensis against K. striata was also greater for plants originating from China than those from the USA. Allelopathy could explain about 46% of the difference. These findings demonstrated that S. canadensis has evolved to be more allelopathic and competitive in the introduced range and that allelopathy significantly contributes to increased competitiveness for this invasive species. [ABSTRACT FROM AUTHOR]

Published

2013

5. An invasive plant promotes its arbuscular mycorrhizal symbioses and competitiveness through its secondary metabolites: indirect evidence from activated carbon.

Author

Yuan Y, Tang J, Leng D, Hu S, Yong JW, and Chen X

Subjects

Absorption, Physicochemical, Base Sequence, Charcoal, China, Computational Biology, Fabaceae growth & development, Fabaceae microbiology, Molecular Sequence Data, Sequence Analysis, DNA, Solidago growth & development, Species Specificity, Introduced Species, Mycorrhizae physiology, Secondary Metabolism physiology, Soil Microbiology, Solidago metabolism, Solidago microbiology, Symbiosis

Abstract

Secondary metabolites released by invasive plants can increase their competitive ability by affecting native plants, herbivores, and pathogens at the invaded land. Whether these secondary metabolites affect the invasive plant itself, directly or indirectly through microorganisms, however, has not been well documented. Here we tested whether activated carbon (AC), a well-known absorbent for secondary metabolites, affect arbuscular mycorrhizal (AM) symbioses and competitive ability in an invasive plant. We conducted three experiments (experiments 1-3) with the invasive forb Solidago canadensis and the native Kummerowia striata. Experiment 1 determined whether AC altered soil properties, levels of the main secondary metabolites in the soil, plant growth, and AMF communities associated with S. canadensis and K. striata. Experiment 2 determined whether AC affected colonization of S. canadensis by five AMF, which were added to sterilized soil. Experiment 3 determined the competitive ability of S. canadensis in the presence and absence of AMF and AC. In experiment 1, AC greatly decreased the concentrations of the main secondary metabolites in soil, and the changes in concentrations were closely related with the changes of AMF in S. canadensis roots. In experiment 2, AC inhibited the AMF Glomus versiforme and G. geosporum but promoted G. mosseae and G. diaphanum in the soil and also in S. canadensis roots. In experiment 3, AC reduced S. canadensis competitive ability in the presence but not in the absence of AMF. Our results provided indirect evidence that the secondary metabolites (which can be absorbed by AC) of the invasive plant S. canadensis may promote S. canadensis competitiveness by enhancing its own AMF symbionts.

Published

2014