Plant Tolerance Research Articles

Contamination characteristics of heavy metals and enrichment capacity of native plants in soils around typical coal mining areas in Gansu, China

Exploitation of mineral resources is a vital backbone of a country’s socio-economic development. However, the coal exploration would cause ecological and environmental problems such as pollutions of water, soils and atmosphere. Especially, the pollution of heavy metals of soil has become increasingly severity. Plant enrichment and tolerance to heavy metals are crucial for the phytoremediation of coal gangue mountain. In phytoremediation, phytostabilization which can reduce the metal contamination of soil by uptake and burn-off of heavy metals with highly accumulating plants, is one of the most effective techniques of eco-remediation treatment. In present work, heavy metals contamination of soil and plants in the Yaojie mining which located in arid and semi-arid area of northwest China were investigated through field investigation. To identify the suitable plants for the remediation and ecological reclamation of heavy metal contaminated soil in typical mining area, the contamination characteristics of heavy metals in the above-ground parts of 27 native plants and their surrounding non-rhizosphere soils were analyzed. After eliminated by wet digestion and high-pressure closed digestion, the mass fractions of Zinc (Zn), cadmium (Cd), chromium (Cr) and copper (Cu) were determined with inductively coupled plasma emission spectrometer, and the contents of Hydrargyrum (Hg) and Arsenic (As) were analyzed with atomic fluorescence spectrophotometer. The Nemerow pollution index showed that in the surrounding soil, the pollution index of heavy metal was 6.32, which reached the extreme severe pollution level. Among the 6 heavy metals, the most severe contamination being Hg (Pi = 8.50) and had particularly strong Coefficient of variation (CV = 105.8%), which is more likely to be caused by anthropogenic activities. In the aboveground parts of 27 plants, except for Zn, other metals exceeded the standard level, and the exceedance rates in descending order were As, Hg, Cr, Cd, and Cu. The most severe exceedance of As was found in C. virgata, which was as high as 19.20, and the average exceedance rate of As in all plants was 2.79. Bioconcentration Factor (BCF) was utilized as an indicator of the enrichments of various metals in 27 plants. The maximum value of BCF for As and Hg in C. virgata were 1.52 and 2.50, Cr and Cu in X. sibiricum were 0.72 and 2.32, Cd and Zn in S. glauca were 3.33 and 1.82. As revealed, except Cr, all the BCF of other metals are greater than 1, indicating that the three plants exhibited a strong accumulation capacity of heavy metal and are potential candidate pioneer species for the removal of heavy metals from the contaminated soil in the Yaojie mining area. This study provides a basis for plant selection for ecological restoration of contaminated soils in arid and semi-arid regions.

AmTPS6 promotes trehalose biosynthesis to enhance the Cd tolerance in mangrove Avicennia marina

Cadmium (Cd) pollution poses a significant ecological risk to mangrove ecosystems. Trehalose has excellent potential to mitigate the adverse effects of heavy metals. Unfortunately, the mechanisms related to trehalose-mediated heavy metal tolerance in plants remain elusive. In the present study, we firstly found that Cd induced the accumulation of trehalose and the differential expression of trehalose biosynthesis genes in the roots of mangrove plant Avicennia marina. Then, we found that the application of exogenous trehalose could alleviate the negative effects of Cd on A. marina by phenotypic observation. In addition, photosynthetic parameters and cellular ultrastructure analyses demonstrated that exogenous trehalose could improve the photosynthesis and stabilize the chloroplast and nuclear structure of the leaves of A. marina. Besides, exogenous trehalose could inhibit the Cd2+ influx from the root to reduce the Cd2+ content in A. marina. Subsequently, substrate sensitivity assay combined with ion uptake analysis using yeast cells showed that several trehalose biosynthesis genes may have a regulatory function for Cd2+ transport. Finally, we further identified a positive regulatory factor, AmTPS6, which enhances the Cd tolerance in transgenic Arabidopsis thaliana. Taken together, these findings provide new understanding to the mechanism of Cd tolerance in mangrove A. marina at trehalose aspect and a theoretical basis for the conservation of mangroves in coastal wetlands.

GhLCYε-3 characterized as a lycopene cyclase gene responding to drought stress in cotton

Drought stress significantly affects crop productivity. Carotenoids are essential photosynthetic pigment for plants, bacteria, and algae, with signaling and antioxidant functions. Lutein is a crucial branch product in the carotenoid synthesis pathway, which effectively improves the stress tolerance of higher plants. lycopene cyclase, a central enzyme for lutein synthesis, holds great significance in regulating lutein production. This research establishes a correlation between lutein content and stress resistance by measuring the drought resistance and lutein content of various cotton materials. To identify which crucial genes are associated with lutein, the lycopene cyclase family (LCYs) was analyzed. The research found that LCYs form a highly conserved family divided into two subfamilies, LCY-ε (lycopene ε-cyclase) and LCY-β (lycopene β-cyclase). Most members of the LCY family contain photoresponsive elements and abscisic acid elements. qRT-PCR demonstrates showed that most genes responded positively to drought stress, and GhLCYε-3 was expressed significantly differently under drought stress. Virus-induced gene silencing (VIGS) assay showed that the content of GhLCYε-3 was significantly increased with MDA and PRO, and the contents of chlorophyll and lutein were significantly decreased in pYL156 plants. The decrease in GhLCYε-3 expression is speculated to lead to reduced lutein content in vivo, resulting in the accumulation of reactive oxygen species (ROS) and decreased drought tolerance. This research enriched the understanding of LCY gene family and lutein function, and provided a new reference for cotton planting in arid areas. SynopsisLycopene cyclase plays an important role in enhancing the ability of scavenging ROS and drought resistance of plants.

Genome-wide identification of HIPP and mechanism of SlHIPP4/7/9/21/26/32 mediated phytohormones response to Cd, osmotic, and salt stresses in tomato

Heavy-metal-associated isoprenylated plant proteins (HIPPs) contributed to abiotic tolerance in vascular plants. Up to now, the HIPP gene family of tomato (Solanum lycopersicum L.) had not been thoroughly understood. In the present study, 34 SlHIPP genes were identified from the tomato genome using the Hidden Markov Model (HMM). The phylogenetic analysis revealed that the evolution of SlHIPPs was highly conserved. The cis-acting element analysis indicated that SlHIPP genes might be involved in phytohormones and abiotic stresses. We constructed venn diagram with 17 genes containing stress-related motifs as well as 15 genes and 19 genes expressing in leaves and roots in RNA-seq data, suggesting that SlHIPP4/7/9/21/26/32 were selected as candidate genes for study. The quantitative real-time PCR (qRT-PCR) analysis showed that 6 candidate genes were indicated to be involved in osmotic and salt stress tolerance and SlHIPP7/21/26/32 responded to cadmium (Cd) tolerance. The virus-induced silencing of 6 candidate genes caused growth inhibition in stress conditions, further illustrating that 6 candidate genes played a positive role in abiotic conditions. Importantly, the phytohormone analysis implied that 6 candidate genes mediated abscisic acid (ABA), salicylic acid (SA), gibberellin (GA3), auxin (IAA), or methyl jasmonate (MeJA) responses to Cd, osmotic, or salt stress tolerance. These findings indicated that SlHIPP4/7/9/21/26/32 were key regulators of abiotic stress responses in tomato seedlings, functioning through multiple phytohormone pathways.

Functional characterization of CaSOC1 at low temperatures and its role in low-temperature escape

Environmental factors such as light and temperature tightly regulate plant flowering time. Under stressful conditions, plants inhibit vegetative growth and accelerate flowering as an emergency response. This adaptive mechanism benefits the survival of species and enhances their reproductive success. This phenomenon is often referred to as stress escape. However, the signaling pathways between low-temperature signals and flowering time are poorly understood. In this study, the MIKC transcription factor, CaSOC1, was isolated from pepper (Capsicum annuum), which showed suppressed expression under low-temperature conditions. Silencing the expression of CaSOC1 in pepper plants resulted in reduced photosynthetic capacity, inhibited vegetative growth, and increased sensitivity to low temperatures. In contrast, overexpression of CaSOC1 increased the biomass of tomato plants under normal growth conditions but suppressed their antioxidant enzyme activity at low temperatures, which negatively regulated their cold tolerance. Furthermore, intermittent low-temperature treatment with CaSOC1 overexpression promoted early flowering in tomato plants. Our findings demonstrate that CaSOC1 reduced the cold tolerance of pepper plants under short term low-temperature conditions, whereas intermittent low-temperature treatment enhanced flower bud differentiation, enabling stress escape and adaptation to long low-temperature environments.

Impact of homologous overexpression of PR10a gene on improving salt stress tolerance in transgenic Solanum tuberosum

Abiotic stresses severely affected crop productivity and considered to be a major yield limiting factor for crop plant. The tolerance to these stresses is a very complex phenomenon involving a wide array of molecular, biochemical and physiological changes in plant cells. Therefore, it is challenging to understand the molecular basis of abiotic stress tolerance to manipulate it for improving abiotic stress tolerance of major crops. Biotechnological approaches and genetic engineering including homologous gene overexpression can be implemented to understand gene functions under well-defined conditions. The Pathogenesis-related proteins (PR10) such as PR10a play multiple roles in biotic and abiotic stress tolerance and, hence, plant development. A PR10a gene from potato cv. Deseree was introduced into three cultivars of potato (Solanum tuberosum L.) by Agrobacterium tumefaciens-mediated genetic transformation. Transgenic plants were selected on a medium containing 1.0 mg/l phosphinothricin (PPT) and confirmed by polymerase chain reaction (PCR), herbicide (BASTA®) leaf paint assay, and Real-Time- quantitative PCR analyses (qPCR). All of the selected transformants showed completely tolerance to the application of PPT application. Experiments designed for testing salt tolerance revealed that there was enhanced salt tolerance of the transgenic lines in vitro in terms of morphological (plant FW, plant DW and plant height) and antioxidant activates as compared to the non-transgenic control plants. qRT-PCR showed that the expression of PR10a gene in the transgenic potato is higher than that in non-transgenic control under salt stress. The relative PR10a gene-expression patterns in the transgenic plants shed lights into the molecular response of homologues overexpressed PR10a potato to salt-stress conditions. The obtained results provide insights on the fact that PR10a plays a major role regarding salt stress tolerance in potato plants

Mitigating salt stress in “Friariello Napoletano” (Brassica rapa subsp. sylvestris L. Janch. var. esculenta Hort.): The potential of biochar for sustainable agriculture

The agricultural sector is therefore called upon to seek efficient and sustainable strategies to improve plant resilience and tolerance to sub-optimal growth conditions. In many coastal areas of the Mediterranean, saline stress causes serious problems to vegetable crops. In this scenario, the use of upgraded agrochemicals such as plant biostimulants, biochar and plant nutrition regulators could be beneficial. The aim of the study was to evaluate the effects of amending the soil with different concentrations of poplar-derived biochar (0 %, 1 % and 2 % by volume), on the productive and qualitative response of an ecotype of “Friariello Napoletano” (Brassica rapa subsp. sylvestris L. Janch. var. esculenta Hort.) under different levels of saline irrigation (0, 30, 60 and 120 mM NaCl, giving an electrical conductivity values of 0.05, 2.09, 6.09 and 9.70 dS m–1). The experiment was conducted in an unheated greenhouse, using pot plants grown in soil with a randomized complete-block experimental design arranged in a 4 × 3 factorial scheme with three replications. Productive and physiological results (ACO2, gs, E, SPAD index) highlighted a highly glycophytic response of Friariello. Biochar integration, besides increasing total production and glucosinolate content, led to a significant reduction in toxic ion content (Na+and Cl−) under saline conditions compared to control plants. Regardless of salinity effect, the application of biochar resulted in an increase in fresh yield and photosynthetic activity (ACO2) of 12.8 % and 29.3 % respectively. The promising results underscore the potential role of biochar as a sustainable strategy for mitigating salt stress in Friariello Napoletano and potentially other vegetable crops in salt-affected regions. However, it needs to be clarified which adaptive mechanisms triggered by biochar improves production performance even and especially under sub-optimal growing conditions.

The role of RNA polymerase II transcript elongation factors in plant stress responses.

The elongation phase is a dynamic and highly regulated step of the RNA polymerase II (RNAPII) transcription cycle. A variety of transcript elongation factors (TEFs) comprising regulators of RNAPII activity, histone chaperones and modulators of histone modifications assist transcription through chromatin. Thereby TEFs substantially contribute to establish gene expression patterns during plant growth and development. Beyond that, recent research indicates that TEFs and RNAPII transcriptional elongation also play a key role in plant responses to environmental cues. Thus, certain TEFs (i.e. PAF1C, FACT, TFIIS) were found to mediate by different mechanisms transcriptional reprogramming to establish plant tolerance to abiotic conditions such as heat stress and elevated salt concentrations. At this, TEFs govern RNAPII elongation to generate the transcriptional output adequate for distinct environments. It is to be expected that future research in this developing field will reveal that the function of TEFs is involved in a growing number of plant responses to changing environmental conditions.

SORTING NEXIN1 facilitates SALT OVERLY SENSITIVE1 protein accumulation to enhance salt tolerance in Arabidopsis.

The plasma membrane (PM)-localized Na+/H+ antiporter Salt Overly Sensitive1 (SOS1) is essential for plant salt tolerance through facilitating Na+ efflux; however, how SOS1 localization and protein accumulation is regulated in plants remains elusive. Here, we report that Sorting Nexin 1 (SNX1) is required for plant salt stress tolerance through affecting endosomal trafficking of SOS1 in Arabidopsis (Arabidopsis thaliana). Disruption of SNX1 caused salt hypersensitivity with increased Na+ accumulation and decreased Na+ efflux in Arabidopsis when challenged with high salinity stress. SNX1 co-localized and interacted with SOS1 in endosomes, promoting its PM localization and protein stability in plants under saline conditions. SOS1 overexpression promoted salt tolerance in the wild-type, whereas such effect was greatly compromised in the snx1-2 mutant. Pharmaceutical results showed that SOS1 recycling from the cytosol to the PM was largely blocked while its vacuolar degradation was accelerated in the snx1-2 mutant. Furthermore, salt-induced SOS1 phosphorylation enhanced its interaction and co-localization with SNX1, which is required for SOS1 PM localization in plants. Our study elucidates that SNX1 facilitates SOS1 PM localization and protein accumulation through endosomal trafficking, thereby enhancing salt tolerance in plants.

Birch (Betula platyphylla) BES/BZR transcription factor BpBZR1-6 improves salt tolerance in transgenic Arabidopsis thaliana

BackgroundSalt stress is one of the major environmental factors affecting plant growth and productivity. BRI1-EMS suppressor 1/brassinazole-resistant 1 ((BES1/BZR1) plays an important role in responding to abiotic stress in plants. Although the impacts of BES1/BZR1 on plant growth and resistance have been documented, the potential mechanisms are not fully elucidated in Betula platyphylla. This work contributes to the understanding of how BES1/BZR1 promotes stress tolerance in woody plants.ResultsSix BES1/BZR1 family members were identified from Betula platyphylla. Cis-element analysis showed that the promoters of six genes were rich in ABA-responsive element (ABRE), MYB and MBS cis-acting elements, which are reported to be involved in abiotic stress responses. Quantitative real-time polymerase chain reaction (qRT-PCR) analysis indicated that BpBZR1-6 (BPChr10G06000) could be induced by salt stress, ABA and BRs. BpBZR1-6 was localized in the nucleus and had transactivation activity. Ectopic expression of BpBZR1-6 enhanced Arabidopsis tolerance and decreased abscisic acid (ABA) sensitivity under salt treatment. Specifically, the seed germination rate, root length, fresh weight and chlorophyll content were significantly higher in BpBZR1-6-overexpressing (OE) transgenic plants than in wild-type (WT) plants after salt stress (P < 0.05). Additionally, BpBZR1-6 overexpression showed enhanced the reactive oxygen species (ROS) scavenging capability under salt stress, including increasing the activities of antioxidant enzyme, resulting in a decrease in O2− and H2O2 accumulation, and reducing malondialdehyde (MDA) content. Meanwhile, the expression levels of six antioxidant enzyme genes were higher in OE plants than in WT plants after stress.ConclusionBpBZR1-6 overexpression enhanced the salt tolerance of transgenic plants by modulating antioxidant enzyme gene expression and ROS scavenging, which may provide underlying strategy for breeding of salt-tolerant plants.

Functional Diversity of A-Type RING Ligases (ATL) Genes: Insights into the Crucial Roles of E3 Ubiquitin Ligases in Plant Biology

AbstractE3 ubiquitin ligases are vital components of the ubiquitin–proteasome system (UPS), responsible for maintaining protein balance and controlling cellular functions. E3 ligases target specific proteins for degradation or modify their activities through ubiquitin attachment. One prominent E3 ligase family is the ATL family, which comprises 100 members in Arabidopsis thaliana and has significantly expanded in plant genomes. All ATLs share a common domain architecture, featuring a transmembrane domain at the amino-terminal region, a distinct RING-H2 finger domain, and the GLD motif. The RING domain facilitates interactions between E3 ligases, E2-conjugating enzymes, and target proteins, enabling the transfer of ubiquitin molecules. The amino-terminal and carboxy-terminal regions introduce sequence diversity and potentially mediate interactions with other components that assist in UPS function or target recognition. ATLs had been classified within groups, each group encompasses specific ATLs with defined roles in various biological processes. For example, group C-ATLs are implicated in drought tolerance, flower development, phosphate homeostasis, and immune signaling. G-ATLs are associated with carbon/nitrogen stress, immune signaling, salt stress, ABA responses, cadmium tolerance, and sugar-mediated plant growth. A-ATLs participate in early elicitor-response, salt and drought responses, and flowering time regulation. Lastly, D-ATLs are involved in the regulation of programmed cell death. This review let perceive ATLs as a cohesive group of E3 ligases, shedding light on their functional diversifity and redundancy, specifically examining their participation in diverse biological processes, explore their evolutionary history shaped by gene duplication events, and appraise their interactions with key proteins and targets of ubiquitination. This comprehensive overview aims to offer insights into the role of ATLs in plant adaptation, defense mechanisms, and stress tolerance, while also underlying molecular and evolutionary mechanisms and regulatory networks that govern these processes.

DNA Hypomethylation Is One of the Epigenetic Mechanisms Involved in Salt-Stress Priming in Soybean Seedlings.

Salt-stress priming enhances the tolerance of plants against subsequent exposure to a similar stress. Priming-induced transcriptomic reprogramming is mediated by multiple epigenetic mechanisms, the best known of which is histone modifications. However, not much is known about other epigenetic responses. In this study, salt-stress priming resulted in global DNA hypomethylation in the leaves of soybean seedlings. The DNA methyltransferase activities in primed seedlings were reduced, contributing to the overall DNA hypomethylation. Genes associated with the hypomethylated DNA regions in primed seedlings also showed a higher mean level of the active histone mark, histone 3 lysine 4 trimethylation (H3K4me3), and a lower mean level of the repressive histone mark, H3K4me2. Transcriptomic analyses supported that DNA hypomethylation played a role in fine-tuning the chromatin status in primed seedlings to potentiate gene expressions. Motif and transcriptional network analyses revealed that DNA hypomethylation may facilitate the responses mediated by key transcription factors in the abscisic acid (ABA)-dependent pathway. A pre-treatment using a DNA methyltransferase inhibitor, 5-azacytidine, could enhance salt tolerance in non-primed soybean seedlings, similar to the priming effect, suggesting the role of DNA hypomethylation in salt-stress priming. Overall, this research furthers our understanding of the epigenetic mechanisms involved in salt-stress priming in soybean.

NtSAP9 confers freezing tolerance in Nicotiana tabacum plants

Abiotic stresses, such as extreme temperatures, drought, and salinity, significantly affect plant growth and productivity. Among these, cold stress is particularly detrimental, impairing cellular processes and leading to reduced crop yields. In recent years, stress-associated proteins (SAPs) containing A20 and AN1 zinc-finger domains have emerged as crucial regulators in plant stress responses. However, the functions of SAPs in tobacco plants remain unclear. Here, we isolated Nicotiana tabacum SAP9 (NtSAP9), whose expression was induced by cold treatment, based on RNA-sequences data. Knock down of NtSAP9 expression reduced freezing tolerance, while overexpression conferred freezing tolerance in transgenic tobacco plants, as indicated by relative electrolytic leakage and photosystem II photochemical efficiency. Untargeted metabolomics via liquid chromatography-tandem mass spectrometry revealed distinct metabolic profiles between WT and NtSAP9-overexpressing tobacco plants under normal and low temperature conditions. Upregulation of amino acids like D-Glutamine, DL-Glutamine, and O-Acetyl-L-serine suggests NtSAP9 enhances cold tolerance. Further expression analysis by quantitative real-time PCR indicated that NtSAP9 participates in cold stress response possibly through amino acid synthesis-related genes expression, such as glutamine synthetase and glutamate dehydrogenase. These findings improve our understanding of SAP proteins in tobacco's response to cold stress.

Acetoin Promotes Plant Growth and Alleviates Saline Stress by Activating Metabolic Pathways in Lettuce Seedlings

Acetoin is a volatile organic compound, which is a class of metabolites produced by plant growth-promoting rhizobacteria. The mechanisms underlying plant growth promotion by acetoin and its potential to induce saline stress tolerance in plants are poorly understood. Lettuce (Lactuca sativa L. var. ramosa Hort.) seedlings in hydronics and pots under non-saline or saline conditions were foliar-sprayed with 10 mL of 0 or 1 mg·mL−1 acetoin at 7 and 14 d after transplantation and harvested 7 d after the second spray. Shoots and roots of hydroponic lettuce seedlings were harvested at 6 and 24 h after treatment for RNA sequencing. Seedlings sprayed with acetoin showed more vigorous growth, with higher shoot and root biomass than those of the controls, in both hydronic and pot modes. The transcriptomic analysis revealed acetoin application resulted in 177 differentially expressed genes (39 upregulated and 138 downregulated) in shoots and 397 differentially expressed genes (112 upregulated and 285 downregulated) in roots. These DEGs, mainly involved in plant hormone signal transduction and the mitogen-activated protein kinase, have the potential to trigger plants’ responses to various environmental stimuli, including stress and developmental signals. Under saline conditions, acetoin-treated plants showed increased net leaf photosynthesis and activities of several defense enzymes, indicating that acetoin enhances both fundamental growth and the plant’s stress defenses, especially against salinity. In summary, acetoin appears to act through a complex interplay of genetic and biochemical mechanisms, influencing key signaling pathways and physiological processes that lead to improved growth and stress tolerance in lettuce seedlings.

Exogenous Calcium Enhances Castor Tolerance to Saline–Alkaline Stress by Regulating Antioxidant Enzyme Activity and Activating Ca2+ and ROS Signaling Crosstalk

Saline–alkaline stress is a major factor limiting agricultural development, with calcium (Ca2+) playing a role in regulating plant tolerance through multiple signaling pathways. However, the specific mechanisms by which Ca2+ mediates saline–alkaline stress tolerance at the molecular level remain incompletely understood. This study investigates the effects of exogenous Ca2+ application on enhancing plant tolerance to saline–alkaline stress, focusing on its impact on the antioxidant system and Ca2+ and reactive oxygen species (ROS) signaling pathways. Through physiological assays and transcriptomic analyses, we evaluated oxidative damage markers, antioxidant enzyme activities, and the expression of key Ca2+ and ROS signaling genes. The results showed that saline–alkaline stress significantly elevated ROS levels, which led to increased membrane lipid peroxidation and induced upregulation of antioxidant response elements in castor roots. Exogenous calcium treatment reduced ROS accumulation by increasing superoxide dismutase (SOD), peroxidase (POD), and catalase (CAT) activities and decreasing malondialdehyde (MDA) levels, demonstrating a marked improvement in the antioxidant system. Transcriptomic analysis identified CAT2 (LOC107261240) as the primary target gene associated with increased CAT activity in response to exogenous calcium. Additionally, the upregulation of specific Ca2+ channels, Ca2+ sensors, ROS receptors, and antioxidant-related genes with calcium treatment highlights the critical role of Ca2+–ROS signaling crosstalk in enhancing stress tolerance. Protein–protein interaction analysis identified APX3 and other hub genes involved in Ca2+–ROS signaling transduction and the regulation of antioxidant activity. These findings enhance our understanding of calcium’s complex regulatory roles in plant abiotic stress responses, offering new theoretical insights for improving crop resilience in agriculture.

PHOTOSYNTHESIS ACTIVITIES OF MELON CULTIVARS UNDER FLOODING ENVIRONMENT

Flooding is such a stress factor leading to reduction in both the yield and quality of crops. One practical solution lowering yield and quality performances of crops in areas with flooding risks is to practice of tolerant plant cultivars. The major purpose of the present work was to identify the most suitable cultivars within 11 different Kırkağaç melon cultivars in accordance of photosynthesis activities. In such pot experiment, all treatments were irrigated with same amount of water during stages of seed sowing-initial of stress applications, and 10-day stress was applied to treatments having the flooding stress in time with plants having four-five leaves. In plants, harvested just after stress application, leaf temperature, stomata conductivity, quantum yield of photosynthesis, and photochemical yield of photosystem II were examined. In results, flooding stress had no significant effects on leaf temperature and stomata conductance but resulted important reductions in quantum yield of photosynthesis, and photochemical yield of photosystem II. There were observed changes among cultivars, and Sürmeli F1 (V-5), Kırkağaç local cultivar (V-10) and Kyrgyzstan local cultivar (V-11) performed maximum photosynthesis activity.

Enhanced salt stress tolerance in plants without growth penalty through increased photosynthesis activity by plastocyanin from Antarctic moss.

Salinity poses a significant challenge to plant growth and crop productivity by adversely affecting crucial processes, including photosynthesis. Efforts to enhance abiotic stress tolerance in crops have been hindered by the trade-off effect, where increased stress resistance is accompanied by growth reduction. In this study, we identified and characterized a plastocyanin gene (PaPC) from the Antarctic moss Polytrichastrum alpinum, which enhanced photosynthesis and salt stress tolerance in Arabidopsis thaliana without compromising growth. While there were no differences in growth and salt tolerance between the wild type and Arabidopsis plastocyanin genes (AtPC1 and AtPC2)-overexpressing plants, PaPC-overexpressing plants demonstrated superior photosynthetic efficiency, increased biomass, and enhanced salt tolerance. Similarly, PaPC-overexpressing rice plants exhibited improved yield potential and photosynthetic efficiency under both normal and salt stress conditions. Key amino acid residues in PaPC responsible for this enhanced functionality were identified, and their substitution into AtPC2 conferred improved photosynthetic performance and stress tolerance in Arabidopsis, tobacco, and tomato. These findings not only highlight the potential of extremophiles as valuable genetic resources but also suggest a photosynthesis-based strategy for developing stress-resilient crops without a growth penalty.

Ectopic expression of HvbHLH132 from hulless barley reduces cold tolerance in transgenic Arabidopsis thaliana.

Overexpression of HvbHLH132 from hulless barley impairs in chilling and freezing tolerance at the seedlings stage in Arabidopsis thaliana The basic helix-loop-helix (bHLH) transcription factors (TF) are ubiquitously existed in eukaryote and play crucial roles in numerous biological processes. However, the characterization of their members and functions in hulless barley remains limited. Here, we conducted a genome-wide identification of the HvbHLH gene family and assessed the role of HvbHLH132 in cold stress tolerance. We identified 141 HvbHLH genes, which were categorized into twelve subfamilies. Subcellular localization predictions indicated that the majority of HvbHLH proteins were localized in the nucleus. cis-Acting element analysis revealed that the promoter regions of the HvbHLH family contain diverse elements associated with various biological processes. Expression profiling of the 141 HvbHLH genes in two extreme varieties revealed that HvbHLH132 was significantly induced and exhibited substantial differential expression under cold stress. Analyses of subcellular localization and transactivation activity confirmed that HvbHLH132 specifically localized in the nucleus and contributed to transcriptional activation. Furthermore, overexpression of HvbHLH132 in Arabidopsis resulted in impaired chilling and freezing tolerance at the seedling stage, leading to biochemical changes unfavorable for freezing stress. Additionally, the expression of some cold-responsive genes (COR) genes was significantly less induced compared to wild type under freezing stress. This study provides comprehensive insight into the HvbHLH gene family and reveals a critical role of HvbHLH132 in regulating cold tolerance in plants.

Peculiarities of Plant Mineral Composition in Semi-Desert Conditions

Plant–soil interactions in semi-desert conditions elicit the development of plant-specific adaptation strategies, including selective accumulation of macro- and microelements. Using an ICP-MS analysis of 12 plant species belonging to Asteraceae, Fabaceae, Poaceae, Ephedraceae, Amarantaceae, and Lamiaceae families of the Baskunchak Nature Reserve, remarkable species differences in accumulation of 22 macro- and microelements were recorded. The most common Artemisia species and Poaceae representatives belong to two different groups of plants with high content of Na, K, Zn, Cu, V and high antioxidant status and low Si typical for the former group and the opposite characteristics for the latter one. The mentioned phenomenon indicates two diverse powerful adaptation mechanisms based on the antioxidant defense and Si protection, respectively. The high frequency of remarkable levels of Se in plants with BCF exceeding 1 (Glycyrrhiza aspera, Phlomis pungens, Tanacetum nullifolium, Helichrysum nogaicum, and Jurinea ewersmannii), Zn in all species except Poa angustifolia, and Cu in the Asteraceae plants Phlomis pungens and Krascheninnikovia ceratoides suggests the significance of these elements in plant tolerance to environmental stresses. Plant–soil positive correlations were recorded for Sr (r = 0.866; p &lt; 0.001); plant Sr, Fe, Co, Pb levels and soil salinity (r = 0.763, p &lt; 0.001; r = 0.606, p &lt; 0.03; r = 0.627, p &lt; 0.02; r = 0.548, p &lt; 0.05, respectively); and Cr only for Asteraceae species (r = 0.986, p &lt; 0.001). The results obtained in this research may be used in plant adaptability evaluation in conditions of environmental stress.

Two genes encoding a bacterial-type ABC transporter function in aluminum tolerance in soybean.

GmABCI5 and GmABCI13 enhance Al tolerance through regulating the composition of root cell wall, and in this process, GmABCI5 and GmABCI13 may act in the form of a complex. Aluminum (Al) toxicity is a major factor limiting plant growth in acidic soils. ATP-binding cassette (ABC) transporters are involved in plant tolerance to various environmental stresses. However, there are few reports on the ABC transporters implicated in soybean tolerance to Al toxicity. Here, we reported that two genes, GmABCI5 and GmABCI13, were involved in Al tolerance in soybean (Glycine max). GmABCI5 and GmABCI13 encode a nucleotide-binding domain and a transmembrane domain of a bacterial-type ABC transporter, respectively. The expression of both GmABCI5 and GmABCI13 was mainly induced by Al in the roots. GmABCI5 was localized at the plasma membrane and also in the cytoplasm and nucleus, while GmABCI13 was only localized at the plasma membrane. Furthermore, GmABCI5 could physically interact with GmABCI13. Overexpression of GmABCI5 or GmABCI13 in Arabidopsis reduced Al accumulation in roots and enhanced Al tolerance. However, expression of GmABCI5 and/or GmABCI13 in yeast cells did not affect Al uptake. Under Al stress, transgenic Arabidopsis lines expressing GmABCI5 or GmABCI13 had lower Al content in root cell walls than wild-type plants. Further analysis showed that Al content in cell wall fractions (pectin and hemicellulose 1) of transgenic lines was significantly lower than that of wild-type plants, which was coincident with the changes of pectin and hemicellulose 1 content under Al stress. These results indicate that GmABCI5 and GmABCI13 form an ABC transporter complex to regulate Al tolerance by affecting the modification of cell wall.