Search Results (322)

Global warming poses serious threats to plant reproduction and agricultural productivity by affecting the timing of flowering, a critical developmental transition. Although transcriptional regulation of flowering pathways has been extensively studied, posttranslational and protein-level regulatory mechanisms are gaining increasing attention as important thermosensory switches enabling rapid and reversible responses to temperature fluctuations. These mechanisms include temperature-dependent protein degradation, ubiquitination, liquid–liquid phase separation of intrinsically disordered proteins, protein sequestration, and dynamic protein–protein interactions. This review summarizes current understanding of posttranslational flowering time regulation under high-temperature conditions, focusing on the major interconnected thermosensory modules, such as the temperature-dependent proteostasis of floral repressors and the emergence of temperature-responsive liquid–liquid phase separation (LLPS) of intrinsically disordered proteins (IDPs). Recent discoveries indicate that temperature-responsive flowering relies not only on transcriptional networks but also on dynamic protein-level regulatory mechanisms, including ubiquitination, proteasomal degradation, and liquid–liquid phase separation. However, the fact that these mechanisms have not been validated in crop species leaves their translational potential an open question. Full article

Alternative splicing (AS) is a major post-transcriptional regulatory mechanism that greatly expands transcriptomic and proteomic diversity in plants. Recent studies have demonstrated that AS dynamically regulates gene expression during plant development and under diverse environmental conditions through isoform-specific modulation of transcript stability, translation efficiency, protein localization, and signaling pathways. In this review, we summarize recent advances in understanding the roles of AS in plant development and abiotic stress responses. Mechanistically, splice site selection is regulated through coordinated interactions among cis-regulatory elements, RNA-binding proteins, RNA secondary structures, transcriptional kinetics, chromatin organization, and spliceosomal dynamics. AS plays critical roles in various developmental processes, including seed germination, vegetative growth, flowering transition, and senescence, while also contributing to plant adaptation to abiotic stresses such as osmotic, temperature, and oxidative stresses. Particular emphasis is placed on the diverse regulatory outcomes of AS, including isoform-specific protein functions, AS-coupled nonsense-mediated decay, transcript stability control, and context-dependent isoform switching. We further discuss the varying levels of experimental evidence supporting reported AS events, ranging from transcriptome-wide observations to genetically and biochemically validated isoform functions. Moreover, recent advances in long-read sequencing, single-cell transcriptomics, proteogenomics, and genome-engineering technologies are accelerating the functional characterization of splice isoforms and uncovering the complexity of AS-mediated regulatory networks. Collectively, these advances highlight AS as a central mechanism coordinating plant developmental plasticity and environmental adaptation. Full article

The dormancy of lilies is an important physiological process involving vernalisation and the differentiation and maturation of flower buds. We have cloned an aquaporin, SbP1P1;2, from the Lilium ‘Siberia’. Subcellular localisation analysis indicates that it is a protein that is localised to the plasma membrane in Nicotiana benthamiana. VIGS-mediated transient silencing revealed that silencing the SbPIP1;2 gene inhibited the development of lily flower buds, while those in the control group differentiated earlier to the anther primordia stage. Notably, the ABA levels in the control group had dropped significantly by day 63, suggesting that dormancy ended earlier than in the treatment group. The test plants’ phenotype is characterised primarily by the fact that silencing the SbPIP1;2 gene inhibits both flower bud development and root growth. The dormancy-to-sleep transition phase (PS vs. TS) was also the period during which the largest number of differentially expressed genes was observed. KEGG enrichment analysis indicates that starch and sucrose metabolic pathways are most active from the onset to the completion of dormancy release and that significant differences occur in several key genes within these pathways. These include alpha-trehalose-phosphate synthase (TPS), sucrose phosphate synthase (SPS), trehalase (TREH), fructokinase-1 (E2.7.1.1), beta-glucosidase (bglB), glycogen synthase (glgA), glucose-6-phosphate isomerase (GPI), and ectonucleotide pyrophosphatase/phosphodiesterase family members 1 and 3 (ENPP1/3). The discovery that aquaporins promote dormancy breaking in lilies is a highly successful case study for aquaporin research in flowers. Full article

Impatiens walleriana is a widely cultivated ornamental species extensively used in landscaping and garden design, with its vibrant floral colors constituting one of the primary determinants of its ornamental value. We found in preliminary observations that treatment of I. walleriana seeds with colchicine at 60 mg L⁻¹ induced significant flower color variation, with petals changing from purple to pink. Based on this, the present study used the wild-type (purple) and induced mutant plants (pink) of I. walleriana as materials, and systematically elucidated the molecular regulatory mechanism underlying its flower color variation via integrated analysis of targeted metabolomics and transcriptomics. Metabolomic analysis identified 84 anthocyanin-related metabolites. Metabolite composition and accumulation levels differed significantly between Iw-MU and Iw-WT. Pelargonidin, peonidin, and petunidin were markedly elevated in Iw-MU, while procyanidins accumulated to higher levels in Iw-WT. These metabolic differences may serve as the key metabolic basis for the petal color transition to pink. Transcriptomic analysis identified a total of 689 differentially expressed genes, of which 386 were upregulated and 303 were downregulated. Subsequent functional annotation and enrichment analysis revealed that the flavonoid biosynthesis pathway played a key regulatory role in flower color variation. Among these, the significant downregulation of key anthocyanin biosynthetic genes, DFR and ANS, likely suppressed the production of colored anthocyanins. In contrast, the expression levels of ANR and LAR genes were significantly upregulated, which may drive the metabolic flux to shift toward proanthocyanidin biosynthesis. This study elucidated the metabolomic composition characteristics and key regulatory genes associated with the floral color transition from pinkish-purple to light pink in I. walleriana, as well as clarified the core metabolic pathways and molecular regulatory mechanisms underlying this variation. These findings provide a theoretical foundation for the genetic improvement of flower color and the breeding of new cultivars in I. walleriana. Full article

Chang Moi Subdistrict is in Chiang Mai Province, Thailand. It is a subdistrict characterized by cultural heritage and everyday community life. The study pursued three objectives: (1) to explore the tourism context of Chang Moi together with tourist attitudes and behaviors; (2) to develop creative tourism routes and evaluate their carbon implications; and (3) to propose appropriate routes and activities for low-carbon creative tourism development. A mixed-method design was employed, comprising qualitative interviews with key stakeholders, a quantitative tourist survey (n = 408), route development, an LCA-informed greenhouse gas assessment, route testing, and synthesis of findings. Three representative route programs were developed: a one-day walking route for international tourists, a one-day private-car route for Thai tourists, and a two-day mixed route. The carbon-footprint results showed that the one-day routes generated substantially lower greenhouse gas emissions (Program 1 = 10.58 kg CO₂ eq; Program 2 = 10.82 kg CO₂ eq) than the two-day overnight route (Program 3 = 31.52 kg CO₂ eq). Waste management was the largest contributor in the one-day routes, whereas Program 3 showed a more distributed emission profile across waste management, creative activities, food and beverage services, and accommodation. Among the assessed activities, flower arranging generated the highest carbon footprint. Overall, the findings indicate that low-carbon creative tourism development in Chang Moi should emphasize compact and walkable route structures, lower-impact creative activities, sustainability-oriented interpretation, and community-based implementation. The study provides an evidence-based basis for tourism planning in Chang Moi and offers implications for other compact creative districts pursuing low-carbon tourism transition. Full article

To systematically elucidate the molecular regulatory mechanisms underlying leaf development in Moso bamboo, this study conducted transcriptome sequencing and systematic analysis on leaves across three key developmental stages: the division stage, the elongation stage, and the mature stage. A total of 25,256 differentially expressed genes (DEGs) were identified. Functional enrichment analysis revealed the sequential molecular events during leaf development: pathways related to cell division and hormone signal transduction were highly active in the early developmental stages, whereas photosynthesis and secondary metabolism were significantly enriched in the mature stage. This reflects the dynamic transition of leaves from morphogenesis to physiological function. Further analysis screened out 3390 transcription factors, among which the AP2/EREBP and bHLH families exhibited notably dynamic expression patterns. Subsequent transgenic functional validation demonstrated that the overexpression of PheANT led to an increased number of leaves and morphological abnormalities in Arabidopsis, while the overexpression of PhebHLH137 resulted in slender leaves and early flowering. This study systematically maps the transcriptomic landscape of Moso bamboo leaf development and identifies multiple key regulatory genes, providing important theoretical insights and candidate gene resources for revealing the unique leaf development mechanisms in bamboo plants. Full article

Gibberellins (GAs) are key endogenous hormones regulating chrysanthemum flowering, and Gibberellin INSENSITIVE DWARF1 (GID1) is the core receptor of the gibberellin (GA) signaling pathway. However, the functional mechanism of CmGID1A remains unelucidated. Here, we constructed CmGID1A-RNAi silencing lines and characterized the biological function of CmGID1A by phenotypic identification, protein interaction assays, qRT-PCR and RNA-seq. The results of RT-qPCR showed that CmGID1A responds to short days and gibberellins. Inhibition of the expression of CmGID1A can significantly promote the transition of chrysanthemum from the vegetative growth stage to the reproductive growth stage and accelerate its flowering process. Bimolecular fluorescence complementation (BiFC) and yeast two-hybrid (Y2H) assays confirmed that CmGID1A interacts with the DELLA protein CmRGL1 in a gibberellin-dependent manner. RNA-seq results revealed that silencing of CmGID1A leads to a significant up-regulation of downstream Ethylene Response Factor 6 (ERF6) expression. Collectively, CmGID1A acts as a GA receptor to mediate GA signal transduction via interacting with CmRGL1, and regulates the expression of CmERF6 and other downstream genes, thereby participating in the regulation of floral transition in chrysanthemum. This study clarifies the core role of CmGID1A in the GA signaling pathway and provides novel experimental data for enriching the molecular regulatory mechanism of GA in floral transition in chrysanthemum. Full article

Magnolia cavaleriei var. platypetala ‘Tanchun’ is a newly registered flower variety in China, known for its characteristic floral aroma that intensifies toward full bloom. However, the composition of the volatiles of this aromatic flower remains uncharacterized. Here, we compared the volatile organic compound composition of Tanchun through gas chromatography–mass spectrometry and comparative transcriptome sequencing analyses of the stamen (S), pistil (P), and petals (T) during flower development, i.e., the bud (S1), semi-opened (S2), and bloom (S3) stages. We present a first comprehensive profile of 1395 metabolites from Tanchun’s floral organs. Terpenoids (26.2%) constituted the largest chemical group, followed by esters (17.52%), nitrogen compounds (9.83%), hydrocarbons (8.11%), alcohols (7.97%), aldehydes (6.53%), and others. We found that volatile organic compound (VOC) accumulation was both spatiotemporal and stage-specific. The S1 and S2 transition was characterized by scent notes of green, herbal, and waxy aromas, while the S2 and S3 shift exhibited a richer profile of fruity, sweet, and creamy notes, primarily in petals. A comparative VOC and transcriptomic analysis revealed that petals activate pathways for structural expansion and precursor mobilization, stamens enhance lipid and terpenoid metabolism, and pistils maintain a conserved profile. Importantly, the S1 and S2 transition in petals establishes the biochemical foundation by activating acyl-CoA, phenylpropanoid, and terpenoid synthesis pathways, which enables the activation of the butanoate metabolism pathway at S3, leading to the production of ester-rich compounds that define the floral scent. The transition to full bloom involves a shift to energy-efficient volatile biosynthesis, supported by carbohydrate restructuring and phytohormonal regulation. Our results provide the first comprehensive volatilome and transcriptome resource for ‘Tanchun’, revealing a highly efficient, multi-stage strategy for floral fragrance biosynthesis. This work lays a molecular foundation for future horticultural improvement and biotechnological applications in the flavor and fragrance industries. Full article

The evolution of connectivity in quantum networks under decoherence and link degradation is a central problem in quantum information, calling for further understanding of the nature of its transition during structural network degradation. By diluting each link with probability $1-\mathit{f}$, we focus on connectivity strength transitions in diluted hierarchical scale-free quantum networks, the $(u,v)$ flowers, which are analytically tractable through two adjustable path-length parameters, $u\le v$. Incorporating quantum concurrence percolation and comparing it with classical percolation, we analyze the transitions of critical thresholds for various values of f and v from analytical, numerical, and simulation perspectives. The results demonstrate that quantum percolation exhibits consistently lower critical thresholds than classical percolation, even under various topologies and dilution levels. Our work implies that quantum multipath entanglement provides an intrinsic compensatory mechanism against structural degradation and that the hierarchical scale-free topology contributes to the failure resistance and robustness of quantum networks with multipath coupling. Full article

The analytic hierarchy process (AHP) was applied to six agronomic scenarios for durum wheat (Triticum durum Desf.) in the Capitanata plain (Apulia, southern Italy), combining three sowing dates (15 October, 1 November, and 15 November) with two water regimes (rainfed; supplemental irrigation at flowering). Five performance indicators were derived from AquaCrop-GIS simulations coupled with cradle-to-gate life-cycle assessment: grain yield, CO₂-equivalent emissions (CO₂_eq), carbon footprint (CFP), total water consumption (TotW), and water footprint (WFP). Six theoretical decision profiles were defined through a symmetric weight scheme (w = 0.60 for the dominant criterion, w = 0.10 for each of the remaining four; balanced profile with equal weights). The rankings revealed a systematic inversion between absolute and ratio indicators: under absolute-metric profiles, the lowest-yielding scenario paradoxically ranked first because reduced productivity mechanically lowered per-hectare resource consumption, whereas under ratio-metric and balanced profiles, early-November rainfed sowing consistently led the rankings. Switching point analyses quantified the weight thresholds at which leadership transitions occurred, providing a continuous sensitivity assessment of the dominant weight, and the AHP procedure was also applied to the 72 simulation replicates spanning the soil × climatic-cell variability of the 2013–2023 dataset to obtain empirical rank distributions for each scenario under each profile. The results highlight that the choice between absolute and ratio environmental indicators is a substantive methodological decision that directly affects the ranking of agronomic alternatives in multi-criteria evaluation. Full article

Following the passage of the Agriculture Improvement Act of 2018, demand for accurate cannabinoid quantification in hemp flowers has increased to ensure regulatory compliance. Liquid chromatography–tandem mass spectrometry (LC–MS/MS) using a triple-quadrupole mass spectrometer provides high sensitivity and selectivity and is well suited for this purpose; however, a review of the literature indicates that many published LC–MS/MS methods target only a limited number of cannabinoids, and reliable differentiation of structural isomers remains challenging. In this study, an LC–MS/MS method was developed for the simultaneous quantification of eighteen cannabinoids in hemp flowers. Baseline chromatographic separation of structural isomers enabled reliable differentiation of compounds with highly similar fragmentation patterns and allowed the use of the most sensitive multiple reaction monitoring (MRM) transitions for quantification. Both positive and negative ionization modes were employed to achieve optimal sensitivity using dynamic polarity switching within a single analytical run. Following validation in accordance with ISO/IEC 17025, the method was applied to a proficiency test hemp sample and six commercial hemp samples, demonstrating excellent time efficiency (11 min for 18 cannabinoids) and an exceptionally wide calibration range (8–5000 ng/mL, corresponding to 0.032–20% (w/w) for all cannabinoids). Full article

As representatives of early-flowering herbaceous peony types, certain cultivars known as the ‘Coral’ series are highly prized in the global cut flowers market for their unique dynamic color transitions from orange-red (amber) to creamy yellow during the florescence and senescence periods. Despite their strong growth vigor and high commercial value, these cultivars face critical postharvest preservation challenges, most notably rapid petal abscission and short vase life. Previous studies have confirmed that postharvest quality deterioration of these peony cut flowers, including undesired color fading and accelerated senescence of petals, is closely associated with ethylene and ROS accumulation. To address these development impediments, systematic optimization of the entire industrial chain is essential. Proposed countermeasures include preharvest regulation of environmental conditions and cultivation practices to establish a foundation for quality formation, as well as postharvest strategies such as precise harvest timing, anti-ethylene treatments, and full cold-chain logistics. Meanwhile, simplifying the distribution system and optimizing terminal vase preservation techniques are also crucial to maintain postharvest quality. In the long term, promoting sustainable development of the global cut-flower industry will require breeding new germplasm with low ethylene sensitivity from a global perspective, continuously optimizing agronomic practices to overcome year-round supply constraints, and accelerating the application of intelligent technologies such as the Internet of Things (IoT) in full chain quality management. Full article

Sugars play a pivotal regulatory role in floral bud dormancy release in Prunus mume, a process that critically determines subsequent flowering time. However, the precise molecular mechanisms linking sugar metabolism to this developmental transition remain poorly understood. To address this gap, we integrated physiological profiling and transcriptomic sequencing using two cultivars with contrasting flowering phenologies: the early-flowering ‘Chaotang Gongfen’ (CTGF) and the late-flowering ‘Shichu Jin’ (SCJ). Exogenous sugar treatments were applied separately to floral buds of the cultivar ‘Yilian’ to evaluate the effect of sugars on dormancy release. During dormancy release, glucose and sucrose contents increased progressively and showed significant positive correlations with bud break rates in both CTGF and SCJ (r > 0.75). Consistently, exogenous application of glucose and sucrose significantly accelerated bud break in ‘Yilian’, whereas mannose exhibited an inhibitory effect. Transcriptome analysis of CTGF and SCJ revealed significant enrichment of starch and sucrose metabolism, hormone signal transduction, and stress-responsive pathways. Key metabolic genes, notably the α-amylase gene PmAMY1-2 and the cell wall invertase genes PmCWINV1/4, were upregulated during this transition. Weighted gene co-expression network analysis (WGCNA) further identified PmFRK4, PmSUS6, and the aforementioned invertases as candidate genes within a sugar-associated regulatory module. Collectively, these findings support a model in which glucose and sucrose accumulation promotes endodormancy release via the transcriptional activation of starch and sucrose catabolic pathways. This study provides a theoretical framework for deciphering dormancy regulation in woody perennials and offers potential targets for the precise manipulation of flowering time. Full article

Black pepper (Piper nigrum L.) faces challenges related to irregular flowering, which compromises crop productivity. Gibberellic acid (GA₃) is a plant growth regulator known for its role in inducing reproductive processes, although its effects on this species are not yet fully understood. This study aimed to evaluate the influence of different GA₃ doses on flowering and vegetative growth in black pepper plants. The experiment was conducted with black pepper seedlings of the Bragantina cultivar in a randomized block design, with four doses of GA₃ (0, 10, 20, and 30 mg L⁻¹) and six replications, using eight-month-old plants grown in pots under full sun. GA₃ applications were performed in two floral induction cycles. Variables related to flowering, chlorophyll a fluorescence, vegetative growth, biomass allocation, and carbohydrate distribution were evaluated. The data were subjected to analysis of variance, regression analysis, mean grouping tests, and principal component analysis. The results showed that intermediate doses (10 and 20 mg L⁻¹) significantly stimulated flowering at early developmental stages, whereas the 30 mg L⁻¹ dose enhanced vegetative growth while reducing floral induction. Additionally, GA₃ affected physiological parameters by increasing photosynthetic efficiency and altering carbohydrate balance, with higher accumulation of soluble sugars in leaves and reduced starch content in roots. It is concluded that GA₃ application is a promising strategy to modulate reproductive transition in black pepper, with 10 to 20 mg L⁻¹ doses recommended to promote flowering without compromising plant development. Full article

The development of high-performance electrode materials with controlled morphology remains a key challenge for advancing supercapacitor technologies. In this study, polyethylene glycol (PEG)-assisted hydrothermal synthesis was employed to engineer NiCo₂S₄ nanostructures with controlled morphology for enhanced supercapacitor performance. The influence of PEG concentration on nucleation behavior, structural evolution, and electrochemical characteristics was systematically investigated. The optimized NiCo₂S₄ electrode synthesized with 0.2% PEG (NiCoS-P2) exhibited a hierarchical flower-like nanosheet architecture with reduced agglomeration and improved electrochemically accessible surface area. As a result, the electrode delivered a high areal capacitance of 13.689 F/cm² (specific capacitance of 6845 F/g) at 5 mA/cm², along with excellent rate capability and superior cycling stability, retaining 84.16% capacitance after 12,000 cycles. Electrochemical analysis revealed that the charge storage process is predominantly diffusion-controlled with enhanced ion transport kinetics. Furthermore, an asymmetric supercapacitor device assembled using NiCoS-P2 as the positive electrode and activated carbon as the negative electrode demonstrated a wide operating voltage of 1.5 V, delivering an areal capacitance of 0.409 F/cm² (specific capacitance of 204.5 F/g), an energy density of 0.128 mWh/cm², and a power density of 2.99 mW/cm². The device also exhibited excellent long-term stability with 85.3% capacitance retention after 7000 cycles. This work highlights the effectiveness of polymer-assisted structural engineering in optimizing transition metal sulfide electrodes for advanced energy storage applications.: Full article