Sophora tonkinensis: response and adaptation of physiological characteristics, functional traits, and secondary metabolites to drought stress

How do arbuscular mycorrhizal fungi enhance drought resistance of Leymus chinensis?

BACKGROUND

Leymus chinensis is a vital, dominant grass species in Eurasian temperate grasslands, including the Inner Mongolian steppe. L. chinensis exhibits enhanced drought tolerance through symbiosis with arbuscular mycorrhizal fungi (AMF). The physiological mechanisms behind this drought resistance need to be unraveled. A pot experiment was conducted with four inoculation treatments (inoculation with Funneliformis mosseae, with Claroideoglomus etunicatum, or with both, and no inoculation) and three drought treatments (no drought (75.00% field capacity), mild drought (56.25% field capacity), severe drought (37.50% field capacity)) to analyze how AMF enhance drought resistance of L. chinensis.

RESULTS

The results showed that drought stress inhibited the growth of L. chinensis, depending on its intensity, whereas AMF inoculation significantly improved growth and alleviated the effects of drought stress. Regardless of drought conditions, AMF inoculation significantly enhanced key biochemistry parameters, including soluble sugar concentration and antioxidant enzyme activities, ultimately promoting plant productivity. Structural equation models (SEMs) further showed that the increase in biomass of L. chinensis inoculated with AMF during mild drought was primarily due to reduced catalase activity and increased cytokinin concentration by increased soluble sugar concentration. However, under severe drought, the increase in biomass of L. chinensis inoculated with AMF was associated with increased soluble sugar concentration caused by increased peroxidase activity and reduced cytokinin concentration.

CONCLUSIONS

The mechanisms by which AMF enhance the drought resistance of L. chinensis vary depending on the severity of drought. AMF increase the soluble sugar concentration by enhancing photosynthetic activity to improve drought resistance under mild drought. Under severe drought conditions, AMF enhance the concentration of soluble sugars in L. chinensis by further activating the expression of antioxidant enzyme genes, thereby improving its drought resistance. Additionally, C. etunicatum maintains high ectomycelium by requiring less carbon sources to efficiently absorb the residual soil moisture under severe drought, thus superiorly enhancing the drought resistance of L. chinensis. This study provides a theoretical foundation for the application of AMF fertilizer to improve the productivity of L. chinensis in arid grasslands.

Integrated physiological characterisation and transcriptomics reveals drought tolerance differences between two cultivars of A. sinensis at seedling stage

BACKGROUND

Drought can adversely affect the growth and development of Angelica sinensis (Oliv.) Diels seedlings. M1 and M2 are two cultivars of A. sinensis with distinct phenotypic traits, and they may exhibit different stress resistances. This study compares the growth, physiological characteristics, and transcriptome data of two cultivars of A. sinensis seedlings to explore their differences in drought tolerance and the underlying molecular mechanisms.

METHODS AND RESULTS

We treated seedlings of M1 and M2 using the natural drought method in pots and compared their growth, physiological characteristics, and transcriptomic data. Under drought stress, M2 showed less phenotypic changes and higher RWC of leaves, photosynthetic parameters, and antioxidant enzyme activities. By analyzing RNA-seq data, 13,941 and 9913 DEGs were identified from M1 and M2. These DEGs are enriched in important pathways related to plant responses to drought stress, including photosynthesis (LHC, HEMA, PAO), antioxidant defense (APX, GPX, EBF1/2), and secondary metabolites (PAL, 4CL, CAD). A thorough analysis of the significant DEGs between the two cultivars of A. sinensis revealed that the expression levels of these DEGs were generally consistent with the physiological changes observed under drought stress. In addition, key transcription factors such as WRKY6, PAT1, and SCL13 were screened through WGCNA.

CONCLUSIONS

M2 seedlings showed greater drought tolerance compared to M1. The research results not only provide insights into the molecular mechanisms of A. sinensis in response to drought stress, but also offer a reference for the evaluation of A. sinensis germplasm resources and the selection and breeding of drought-tolerant cultivars.

Global insights into intermediate metabolites: Signaling, metabolic divergence and stress response modulation in plants

Climate change-induced environmental stresses pose significant challenges to plant survival and agricultural productivity. In response, many plants undergo genetic reprogramming, resulting in profound alterations in metabolic pathways and the production of diverse secondary metabolites. As a critical molecular junction, intermediate metabolites by targeted intensification or suppression of subpathways channel cell resources into a multifaceted array of functions such as cell signals, photosynthesis, energy metabolism, ROS homeostasis, producing defensive and protective molecules, epigenetic regulation and stress memory, phytohormones biosynthesis and cell wall architecture under stress conditions. Unlike the well-established functions of end products, intermediate metabolites are context-dependent and produce enigmatic alternatives during stress. As key components of signal transduction pathways, intermediate metabolites with relay and integration of stress signals ensure responses to stress combinations. Investigating efficient metabolic network pathways and their role in regulating unpredictable paths from upstream to downstream levels can unlock their full potential to shape the future of agriculture and ensure global food security. Here, we summarized the activity of some intermediate metabolites, from the perception step to tolerance responses to stress factors.

Multifaceted insights into the environmental adaptability of Arnebia guttata under drought stress

Introduction

Global warming has led to increased environmental stresses on plants, notably drought. This affects plant distribution and species adaptability, with some medicinal plants showing enhanced drought tolerance and increased medicinal components. In this pioneering study, we delve into the intricate tapestry of Arnebia guttata, a medicinal plant renowned for its resilience in arid environments. By fusing a rich historical narrative with cutting-edge analytical methodologies, this research endeavors to demystify the plant's intricate response to drought stress, illuminating its profound implications for medicinal valorization.

Methods

The methodology includes a comprehensive textual research and resource investigation of A. guttata, regionalization studies, field sample distribution analysis, transcriptome and metabolome profiling, rhizosphere soil microbiome analysis, and drought stress experiments. Advanced computational tools like ArcGIS, MaxEnt, and various bioinformatics software were utilized for data analysis and modeling.

Results

The study identified significant genetic variations among A. guttata samples from different regions, correlating with environmental factors, particularly precipitation during the warmest quarter (BIO18). Metabolomic analysis revealed marked differences in metabolite profiles, including shikonin content, which is crucial for the plant's medicinal properties. Soil microbial community analysis showed variations that could impact plant metabolism and stress response. Drought stress experiments demonstrated A. guttata's resilience and its ability to modulate metabolic pathways to enhance drought tolerance.

Discussion

The findings underscore the complex interplay between genetic makeup, environmental factors, and microbial communities in shaping A. guttata's adaptability and medicinal value. The study provides insights into how drought stress influences the synthesis of active compounds and suggests that moderate stress could enhance the plant's medicinal properties. Predictive modeling indicates future suitable growth areas for A. guttata, aiding in resource management and conservation efforts. The research contributes to the sustainable development of medicinal resources and offers strategies for improving the cultivation of A. guttata.

Effects of Exogenous Abscisic Acid on the Physiological and Biochemical Responses of Camellia oleifera Seedlings under Drought Stress

This study comprehensively investigates the physiological and molecular regulatory mechanisms of Camellia oleifera seedlings under drought stress with a soil moisture content of about 30%, where exogenous abscisic acid (ABA) was applied via foliar spraying at concentrations of 50 µg/L, 100 µg/L, and 200 µg/L. The results demonstrated that appropriate concentrations of ABA treatment can regulate the physiological state of the seedlings through multiple pathways, including photosynthesis, oxidative stress response, and osmotic balance, thereby aiding in the restructuring of their drought response strategy. ABA treatment effectively activated the antioxidant system by reducing stomatal conductance and moderately inhibiting the photosynthetic rate, thus alleviating oxidative damage caused by drought stress. Additionally, ABA treatment promoted the synthesis of osmotic regulators such as proline, maintaining cellular turgor stability and enhancing the plant's drought adaptability. The real-time quantitative PCR results of related genes indicated that ABA treatment enhanced the plant's response to the ABA signaling pathway and improved disease resistance by regulating the expression of related genes, while also enhancing membrane lipid stability. A comprehensive evaluation using a membership function approach suggested that 50 µg/L ABA treatment may be the most-effective in mitigating drought effects in practical applications, followed by 100 µg/L ABA. The application of 50 µg/L ABA for 7 h induced significant changes in various biochemical parameters, compared to a foliar water spray. Notably, superoxide dismutase activity increased by 17.94%, peroxidase activity by 30.27%, glutathione content by 12.41%, and proline levels by 25.76%. The content of soluble sugars and soluble proteins rose by 14.79% and 87.95%, respectively. Additionally, there was a significant decrease of 31.15% in the malondialdehyde levels.