The Arabidopsis transcription factor LBD15 mediates ABA signaling and tolerance of water-deficit stress by regulating ABI4 expression.

To survive, sessile plants must adapt to grow and develop when facing water-deficit stress. However, the molecular mechanisms underlying fine-tuning of the antagonistic action between stress response and growth remain to be determined. Here, plants overexpressing Lateral Organ Boundaries Domain 15 (LBD15) showed abscisic acid (ABA) hypersensitivity and tolerance of water-deficit stress, whereas the loss-of-function mutant lbd15 presented decreased sensitivity to ABA and increased sensitivity to water-deficit stress.

Establishment and optimization of mRNA in situ hybridization system in turnip ( var).

Background: In situ hybridization (ISH) is a general molecular biological technique used to determine the spatiotemporal expression of genes in many species. In the past few years, numerous ISH protocols have been established in many species. Turnip ( var.

Genome-Wide Identification and Characterization of Transcription Factors in .

The teosinte branched1/cycloidea/proliferating cell factor (TCP) gene family is a plant-specific transcription factor that participates in the control of plant development by regulating cell proliferation. However, no report is currently available about this gene family in turnips (). In this study, a genome-wide analysis of TCP genes was performed in turnips.

Activation of secondary cell wall biosynthesis by miR319-targeted TCP4 transcription factor.

The overexpression of miR319 in plants results in delayed senescence, and high levels of miR319-targeted TCP4 transcription factor cause premature onset of this process. However, the underlying mechanisms of this pathway remain elusive. Here, we found that miR319 overexpression results in a decrease in TCP4 abundance and secondary cell wall formation in the stem.

[Contents and the Correlations of the Total Anthocyanins and Saponins of the Vegetative Organs of Panax notoginseng with Purple and Green Aerial Stems at Different Growth Stages].

Objective: To study the accumulation characteristics of total anthocyanins and saponins in the vegetative organ of Panax notoginseng with purple and green aerial stems at different growth stages.

Methods: The contents of the total anthocyanins and saponins of the leaves, aerial stems, rhizomes and the adventitious roots of one-, two- and three-year-old Panax notoginseng with purple and green aerial stems were determined by spectrophotometry.

Results: From one-year-old to three-year-old Panax notoginseng, the total anthocyanin contents (TACs) of the leaves, aerial stems and all vegetative organs and the percentages of the aerial stems TACs to those of all vegetative organs of purple aerial stemmed Panax notoginseng plants, the percentages of the total saponin contents (TSCs) of the leaves and aerial stems to those of all vegetative organs of the purple and green aerial stemmed plants and the percentages of the leaves TACs to those of vegetative organs of the green aerial stemmed plants all decreased.

Stability-increasing effects of anthocyanin glycosyl acylation.

This review comprehensively summarizes the existing knowledge regarding the chemical implications of anthocyanin glycosyl acylation, the effects of acylation on the stability of acylated anthocyanins and the corresponding mechanisms. Anthocyanin glycosyl acylation commonly refers to the phenomenon in which the hydroxyl groups of anthocyanin glycosyls are esterified by aliphatic or aromatic acids, which is synthetically represented by the acylation sites as well as the types and numbers of acyl groups. Generally, glycosyl acylation increases the in vitro and in vivo chemical stability of acylated anthocyanins, and the mechanisms primarily involve physicochemical, stereochemical, photochemical, biochemical or environmental aspects under specific conditions.