Ganoderma lucidum is a mushroom widely used for its edible and medicinal properties. Primary bioactive constituents of G. lucidum are ganoderic triterpenoids (GTs), which exhibit important pharmacological activity. Abscisic acid (ABA), a plant hormone, is associated with plant growth, development, and stress responses. ABA can also affect the growth, metabolism, and physiological activities of different fungi and participates in the regulation of the tetracyclic triterpenes of some plants. Our findings indicated that ABA treatment promoted GT accumulation by regulating the gene expression levels (squalene synthase (sqs), 3-hydroxy-3-methylglutaryl-CoA reductase (hmgr), and lanosterol synthase (ls)), and also activated cytosolic Ca²⁺ channels. Furthermore, under ABA mediation, exogenous Ca²⁺ donors and inhibitors directly affected the cytosolic Ca²⁺ concentration and related gene expression in Ca²⁺ signaling. Our study also revealed that ABA-mediated cytosolic Ca²⁺ played a crucial regulatory role in GT biosynthesis, accompanied by antioxidant defense modulation with increasing superoxide dismutase (SOD) activity and ascorbate peroxidase (APX) activity, and the resistance ability of O₂^•- and glutathione (GSH) contents.
Reishi/metabolism* ; Triterpenes/metabolism* ; Abscisic Acid/metabolism* ; Antioxidants/metabolism*

Iron (Fe) is an important trace element involved in many important plant physiological and metabolic processes such as photosynthesis, respiration and nitrogen metabolism. Plants maintain iron homeostasis through absorption, transporting, storage and redistribution of iron. Iron metabolism is strictly regulated in plants. Iron regulatory transcription factors and iron transporters constitute the regulatory network of plant iron absorption and transport in plants. Ferritin and iron transporter jointly regulate the response to excess iron in plants. In recent years, important progress has been made in understanding how abscisic acid (ABA) regulates iron metabolism in plants. ABA may be used as a signal to regulate the absorption, transportation and reuse of Fe, or to relieve the symptoms of iron stress by regulating the oxidative stress responses in plants. In order to gain deeper insights into the crosstalk of ABA and iron metabolism in plants, this review summarized the mechanisms of iron absorption and transport and metabolic regulatory network in plants, as well as the mechanisms of ABA in regulating iron metabolism. The relationship between ABA and FER-like iron deficiency-induced transcription factor (FIT), iron-regulated transporter 1 (IRT1), and oxidative stress of iron deficiency were highlighted, and future research directions were prospected.
Abscisic Acid/metabolism* ; Gene Expression Regulation, Plant ; Homeostasis ; Iron/metabolism* ; Plants/metabolism* ; Transcription Factors/metabolism*

Abscisic acid, a plant hormone that inhibits growth, is a key factor in balancing plant endogenous hormones and regulating growth and metabolism. Abscisic acid can improve the drought resistance and salt tolerance of crops, reduce fruit browning, reduce the incidence rate of malaria and stimulate insulin secretion, so it has a broad application potential in agriculture and medicine. Compared with traditional plant extraction and chemical synthesis, abscisic acid synthesis by microorganisms is an economic and sustainable route. At present, a lot of progress has been made in the synthesis of abscisic acid by natural microorganisms such as Botrytis cinerea and Cercospora rosea, while the research on the synthesis of abscisic acid by engineered microorganisms is rarely reported. Saccharomyces cerevisiae, Yarrowia lipolytica and Escherichia coli are common hosts for heterologous synthesis of natural products due to their advantages of clear genetic background, easy operation and friendliness for industrial production. Therefore, the heterologous synthesis of abscisic acid by microorganisms is a more promising production method. The author reviews the research on the heterologous synthesis of abscisic acid by microorganisms from five aspects: selection of chassis cells, screening and expression enhancement of key enzymes, regulation of cofactors, enhancement of precursor supply and promotion of abscisic acid efflux. Finally, the future development direction of this field is prospected.
Abscisic Acid/metabolism* ; Plant Growth Regulators/metabolism* ; Plants/metabolism* ; Yarrowia/metabolism*

Abscisic acid (ABA) plays a key role in many physiological processes of plants, and it was also applied to fields of medicinal plant biotechnology. The article presents a review of some recent application of ABA in enhancing the production of secondary metabolites of medicinal plants, improving the in vitro conservation in medicinal plant tissue culture system.
Abscisic Acid ; metabolism ; Cell Culture Techniques ; Plant Growth Regulators ; metabolism ; Plants, Medicinal ; growth & development ; metabolism

Drought stress exerts a considerable effect on growth, physiology and secondary metabolisms of the medicinal plants. It could inhabit the growth of the medicinal plants but promote secretion of secondary metabolites. Other researches indicated that the medicinal plants could depend on the ABA signaling pathway and secreting osmotic substances to resist the drought stress and reduce the damage by it. The article concludes the changes in growth, physiology, secondary metabolisms and response mechanisms of medicinal plants to drought stress that provides a theoretical basis for exploring the relationship between medicinal plants and drought stress.
Abscisic Acid ; metabolism ; Droughts ; Plant Proteins ; genetics ; metabolism ; Plants, Medicinal ; genetics ; growth & development ; metabolism ; Signal Transduction ; Water ; metabolism

To investigate roles of nitric oxide (NO) signal in accumulations of phenolic acids in abscisic.acid (ABA)-induced Salvia miltiorrhiza hairy roots, S. miltiorrhiza hairy roots were treated with different concentrations of sodium nitroprusside (SNP)-an exogenous NO donor, for 6 days, and contents of phenolic acids in the hairy roots are determined. Then with treatment of ABA and NO scavenger (2-(4-carboxy-2-phenyl)-4,4,5,5-tetramethylimidazoline-1- oxyl-3-oxide, c-PTIO) or NO synthase inhibitor (NG-nitro-L-arginine methyl ester, L-NAME), contents of phenolic acids and expression levels of three key genes involved in phenolic acids biosynthesis were detected. Phenolic acids production in S. miltiorrhiza hairy roots was most significantly improved by 100 µmoL/L SNP. Contents of RA and salvianolic acid B increased by 3 and 4 folds. ABA significantly improved transcript levels of PAL (phenylalanine ammonia lyase), TAT (tyrosine aminotransferase) and RAS (rosmarinic acid synthase), and increased phenolic acids accumulations. However, with treatments of ABA+c-PTIO or ABA+L-NAME, accumulations of phenolic acids and expression levels of the three key genes were significantly inhibited. Both NO and ABA can increase accumulations of phenolic acids in S. miltiorrhiza hairy roots. NO signal probably mediates the ABA-induced phenolic acids production.
Abscisic Acid ; pharmacology ; Benzofurans ; metabolism ; Free Radical Scavengers ; pharmacology ; Hydroxybenzoates ; metabolism ; Nitric Oxide ; metabolism ; Phenylalanine Ammonia-Lyase ; metabolism ; Plant Roots ; metabolism ; Salvia miltiorrhiza ; metabolism ; Tyrosine Transaminase ; metabolism

OBJECTIVETo reveal the relation between endogenous hormones and the flower bud differentiation in Schisandga chinensis.

METHODTop buds of extremely short branch and axillary buds of long branch in the same plant of S. chinensis were used as material and the contents of endogenous hormones were measured during different periods of the flower bud differentiation with HPLC.

RESULTThe result showed that flower bud differentiation and the formation of female flower were inhibited by high concentration of GA3 and were promoted by high concentration of ABA or ZT. Low ratio of GA3/ABA has the same result.

CONCLUSIONThere was a correlation between endogenous hormones and the flower bud differentiation of S. chinensis.

Abscisic Acid ; metabolism ; Flowers ; growth & development ; Germination ; Gibberellins ; metabolism ; Plant Growth Regulators ; metabolism ; Plants, Medicinal ; growth & development ; metabolism ; Schisandra ; growth & development ; metabolism ; Zeatin ; metabolism

Glutamate receptor-like (GLR) is an important class of Ca²⁺ channel proteins, playing important roles in plant growth and development as well as in response to biotic and abiotic stresses. In this paper, we performed genome-wide identification of banana GLR gene family based on banana genomic data. Moreover, we analyzed the basic physicochemical properties, gene structure, conserved motifs, promoter cis-acting elements, evolutionary relationships, and used real-time fluorescence quantitative polymerase chain reaction (RT-qPCR) to verify the expression patterns of some GLR family members under low temperature of 4 ℃ and different hormone treatments. The results showed that there were 19 MaGLR family members in Musa acuminata, 16 MbGLR family members in Musa balbisiana and 14 MiGLR family members in Musa itinerans. Most of the members were stable proteins and had signal peptides, all of them had 3-6 transmembrane structures. Prediction of subcellular localization indicated that all of them were localized on the plasma membrane and irregularly distributed on the chromosome. Phylogenetic analysis revealed that banana GLRs could be divided into 3 subclades. The results of promoter cis-acting elements and transcription factor binding site prediction showed that there were multiple hormone- and stress-related response elements and 18 TFBS in banana GLR. RT-qPCR analysis showed that MaGLR1.1 and MaGLR3.5 responded positively to low temperature stress and were significantly expressed in abscisic acid/methyl jasmonate treatments. In conclusion, the results of this study suggest that GLR, a highly conserved family of ion channels, may play an important role in the growth and development process and stress resistance of banana.
Musa/metabolism* ; Phylogeny ; Abscisic Acid/metabolism* ; Temperature ; Stress, Physiological/genetics* ; Hormones/metabolism* ; Gene Expression Regulation, Plant ; Plant Proteins/metabolism* ; Gene Expression Profiling

OBJECTIVETo study the change of endogenous hormone (ABA, IAA, JA, GA3, ZR) in the leaves, petioles, tubers of Pinellia ternate around sprout tumble. It also provided some valuable information to prevent sprout tumble and increase production.

METHODTubers of P. ternata were cultured firstly at (23 +/- 1) degree C for certain days, and then they were coerced under (30 +/- 1 ) degree C stress in the same artificial climate boxes. The endogenous hormones in leaves, petioles and tubers during different stages of high temperature stress were determined with Enzyme-linked Immunosorbent Assays (ELISA).

RESULTAfter under high temperature stress, ABA content in leaves, petioles and tubers increased obviously. Similarly, JA content rose all in the leaves, petioles and tubers. But in the same conditions IAA content declined significantly in the leaves and petioles. In the tubers, IAA content also decreased, but not quickly. With the extension of high temperature coercion, the leaves, petioles, tubers, ZR content were gradually falling off. In the leaves of GA3 content rose markedly at the third day, fell down at the sixth day, but remained higher than before treatment. With the extension of the processing time, GA3 content fell off in the petioles and tubers.

CONCLUSIONABA, JA, ZT and GA3 played an important role in controlling sprout tumble of P. ternata.

Abscisic Acid ; metabolism ; Cyclopentanes ; metabolism ; Enzyme-Linked Immunosorbent Assay ; Gibberellins ; metabolism ; Hot Temperature ; Indoleacetic Acids ; metabolism ; Isopentenyladenosine ; analogs & derivatives ; metabolism ; Oxylipins ; metabolism ; Pinellia ; metabolism ; physiology ; Plant Growth Regulators ; metabolism ; Plant Leaves ; metabolism ; Plant Tubers ; metabolism ; Plants, Medicinal ; metabolism ; physiology

OBJECTIVEThrough analysis of variation and function of 5 main endogenous hormones in the formation of microtuber of Dioscorea opposite in vitro to explore the physiological and biochemical mechanism of microtuber development.

METHODWhen microtubers were induced on MS + 6-BA 1.5 mg x L(-1) + NAA 1.5 mg x L(-1) + sucrose 5% medium, the endogenous hormones were isolated during different formation stages of microtubers, then purified and detected with enzyme-linked immunosorbent assays (ELISA).

RESULTThe results showed that GA3 slightly decreased in initial period, rose suddenly 20 days later, and than decreased. IAA showed a dropping tendency in the total course, ABA and ZR increased in a long period, dropped at last. JA continuously rose and never dropped, GA3 and ABA and the ratio of GA3 and JA varied obviously.

CONCLUSIONIAA, ABA, JA , ZR and GA3 play an important role in controlling formation of microtubers in D. opposite in vitro.

Abscisic Acid ; metabolism ; Cyclopentanes ; metabolism ; Dioscorea ; growth & development ; metabolism ; Gibberellins ; metabolism ; Indoleacetic Acids ; metabolism ; Isopentenyladenosine ; analogs & derivatives ; metabolism ; Oxylipins ; metabolism ; Plant Growth Regulators ; metabolism ; Plant Tubers ; growth & development ; metabolism