Search Results (5,021)

Dehydration response element binding proteins (DREBs) have been identified as major regulators of cold acclimatization in many angiosperms. Cold stress is one of the primary abiotic stresses affecting kiwifruit growth and development. However, kiwifruit is currently one of the most widely consumed fruits worldwide because of its high nutritional value. 5-Aminolevulinic acid (5-ALA) is a nonprotein amino acid known for its distinct promotional effects on plant resistance, growth, and development. However, studies on the function of the kiwifruit DREB gene in alleviating low-temperature stress in its seedlings via exogenous 5-ALA have not been reported. Therefore, in this study, we performed a genome-wide identification of DREB gene family members in kiwifruit and analyzed the regulatory effects of exogenous 5-ALA on kiwifruit DREB genes under low-temperature stress. A total of 193 DREB genes were identified on 29 chromosomes. Phylogenetic analysis classified these genes into six subfamilies. Although there were some differences in cis-elements among subfamilies, all of them contained more biotic or abiotic stresses and hormone-related cis-acting elements. GO and KEGG enrichment analyses revealed that AcDREB plays an essential role in hormone signaling, metabolic processes, and the response to adverse stress. Under low-temperature stress, the application of exogenous 5-ALA inhibited the accumulation of APX and DHAR, promoted an increase in chlorophyll, and increased the accumulation of enzymes and substances such as 5-ALA, MDHAR, GR, ASA, GAH, and GSSH, thereby accelerating ROS scavenging and increasing the cold hardiness of kiwifruits. Functional analysis revealed that 46 differentially expressed DREB genes, especially those encoding AcDREB69, AcDREB92, and AcDREB148, which are involved in ethylene signaling and defense signaling, and, after the transcription of downstream target genes is activated, are involved in the regulation of low-temperature-stressed kiwifruits by exogenous 5-ALA, thus improving the cold tolerance of kiwifruits. Notably, AcDREB69, AcDREB92, and AcDREB148 could serve as key genes for cold tolerance. This study is the first to investigate the function of AcDREB genes involved in the role of exogenous 5-ALA in regulating low-temperature stress, revealing the regulatory mechanism by which DREB is involved in the ability of exogenous 5-ALA to alleviate low-temperature stress. Full article

Pinus yunnanensis is an essential tree species in southwest China. However, its genetic degeneration problem urgently needs to be addressed. Decapitation promotes seedling propagation primarily by disrupting apical dominance, triggering hormonal changes that stimulate lateral bud growth. To investigate the response of hormones and photosynthetic pigments in P. yunnanensis to decapitation at different seedling ages, seedlings aged 6, 10, 14, 18, and 30 months were used as materials to carry out unified decapitation treatment, and the dynamics of photosynthetic pigments, changes in endogenous hormones, and their relationship with tillering ability were analyzed. The results showed that the photosynthetic pigments were higher in younger decapitated seedlings than in older ones, and carotenoids showed an upward trend with time. Additionally, decapitation significantly altered the balance of endogenous hormones, including the contents of GAs, ABA, SA, JA, JA-Ile, and ACC. The GA₃ and ABA contents in the middle-aged decapitated seedlings of P. yunnanensis were higher. The seedlings with older decapitation ages showed higher contents of IAA, SA, and JA. Overall, seedlings with different decapitation ages exhibit significant differences in their responses to decapitation, as indicated by variations in photosynthetic pigments and hormones. This research elucidated the optimal decapitation age for P. yunnanensis, providing a theoretical foundation for establishing efficient decapitation nurseries and promoting near-natural propagation. Full article

Steroid hormones play critical roles in the development and progression of NSCLC through both genomic and non-genomic pathways. This review summarizes the expression profiles and molecular functions of estrogen, progesterone, androgen, and glucocorticoid receptors in NSCLC. Estrogen and progesterone receptors exhibit gender-specific prognostic significance, while glucocorticoid receptors influence tumor growth and immune responses. Emerging evidence supports the use of anti-estrogen therapies and glucocorticoids as adjuncts to existing treatment strategies, including immunotherapy. The crosstalk between hormone signaling and oncogenic pathways such as EGFR or immune checkpoints offers opportunities for novel combination therapies. However, challenges remain in biomarker development, drug resistance, and managing the dual effects of glucocorticoids. A deeper understanding of hormone–tumor–immune interactions is essential to optimize hormone-targeted interventions in NSCLC. Full article

The GLABROUS1 Enhancer Binding Protein (GeBP) gene family plays a crucial role in plant growth, development, and stress responses. In this study, 28 GeBP genes were identified in Brassica oleracea using HMMER and validated through multiple conserved domain databases. A phylogenetic tree was constructed based on the GeBP protein sequences from B. oleracea, Arabidopsis thaliana, Brassica rapa, and Brassica napus, dividing them into four evolutionary clades (A–D), which revealed a close evolutionary relationship within the genus Brassica. Conserved motif and gene structure analyses showed clade-specific features, while physicochemical property analysis indicated that most BoGeBP proteins are hydrophilic, nuclear-localized, and structurally diverse. Gene duplication and chromosomal localization analyses suggested that both segmental and tandem duplication events have contributed to the expansion of this gene family. Promoter cis-element analysis revealed a dominance of light-responsive and hormone-responsive elements, implying potential roles in photomorphogenesis and stress signaling pathways. Notably, the protein encoded by BolC01g019630.2J possesses both a transmembrane domain and characteristics of the Major Facilitator Superfamily (MFS) transporter family, and it is predicted to localize to the plasma membrane. This suggests that it may act as a molecular bridge between environmental signal perception and transcriptional regulation, potentially representing a novel signaling mechanism within the GeBP family. This unique feature implies its involvement in transmembrane signal perception and downstream transcriptional regulation under environmental stimuli, providing valuable insights for further investigation of its role in stress responses and metabolic regulation. Overall, this study provides a theoretical foundation for understanding the evolutionary patterns and functional diversity of the GeBP gene family in B. oleracea and lays a basis for future functional validation and breeding applications. Full article

Abscisic acid (ABA) is a central phytohormone that orchestrates plant responses to abiotic stresses, such as drought, salinity, and extreme temperatures, while also influencing growth and development. The regulatory networks underpinning ABA-mediated stress tolerance have been the focus of intensive research, revealing sophisticated mechanisms of biosynthesis, signal transduction, and gene regulation. Recent advances in genetic, genomic, and biochemical approaches have illuminated the complexity of ABA’s interactions with other hormonal and environmental signaling pathways, providing a multidimensional understanding of plant adaptation. This review critically synthesizes current knowledge on ABA’s regulatory frameworks, identifies key gaps in our understanding, and discusses the potential integration of omics and emerging technologies to uncover new insights. By offering a comprehensive synthesis of recent findings, this paper aims to stimulate further research into the interplay of ABA with other signaling pathways, highlighting its translational potential for crop improvement under changing environmental conditions. Full article

Microneedles have emerged as a versatile technology for biosensing across biomedical domains and are increasingly being explored for other applications like agriculture. This review highlights recent advancements in the development of microneedle-based biosensors in novel areas. Biomedical applications include continuous glucose monitoring, multiplexed biomarker detection beyond glucose, and numerous recent works presenting fully integrated systems comprising microneedle arrays alongside miniaturized wearable electronics. Agricultural applications largely focus on the detection of plant growth markers, hormones, and nutrient levels. Despite significant progress, challenges remain in overcoming biofouling and electrode degradation, optimizing electrode longevity for long-term (weeks to months) in situ monitoring, and creating scalable sensor fabrication processes. Additionally, there is a need for standardized mechanical and electrical testing protocols, and guidelines specifying critical performance metrics that should be reported to facilitate accurate literature comparisons. The review concludes by outlining key opportunities for future research to address these persisting challenges. Full article

Background/Objectives: Hair loss, driven by disrupted hair cycles, age-related hormonal imbalances, and oxidative stress, poses significant psychological challenges, necessitating the development of safe and effective therapies. This research investigates the trichogenic potential and underlying mechanisms of a standardized Ageratum conyzoides extract (ACE) using human follicle dermal papilla cells (HFDPCs) and C57BL/6 mice as models. Methods: HFDPCs were treated with ACE to assess its effects on 5α-reductase activity, estrogen receptor (ERα/ERβ) signaling, and activation of Wnt/β-catenin and MAPK pathways. Reactive oxygen species (ROS) levels and antioxidant enzyme expression were also evaluated. In vivo, C57BL/6 mice were administered ACE orally, and hair regrowth, follicle number and depth, and histological changes were measured. Results: In HFDPCs, ACE inhibited 5α-reductase activity, modulated ERα and ERβ signaling, and activated Wnt/β-catenin and MAPK pathways. ACE treatment at 100 μg/mL significantly increased β-catenin, p-GSK3β, and vascular endothelial growth factor (VEGF) expression (p < 0.01) and decreased Dickkopf-related protein-1 (DKK-)1 expression (p < 0.05). It also upregulated VEGF and other hair-growth-related factors and exhibited substantial antioxidant properties by reducing reactive oxygen species (ROS) and elevating the expression of antioxidant enzymes, notably SOD2 at 100 μg/mL. In C57BL/6 mice, oral administration of ACE significantly increased hair regrowth, with the 50 mg/kg group showing the most prominent effects, including increased hair follicle number and depth compared to the negative control group (p < 0.05). These effects were observed to be dose-dependent and comparable to those of minoxidil. Histological analysis confirmed enhanced anagen-phase follicle development. Conclusions: These findings highlight ACE’s multifaceted biological activity in promoting hair growth through hormonal modulation, pathway activation, and antioxidant protection, positioning it as a promising natural supplement for hair growth and health, although further clinical studies are required to confirm its efficacy in humans. Full article

Fatty acid desaturase (FAD) is a rate-limiting enzyme catalyzing the biosynthesis of unsaturated fatty acids (UFAs) and participates in key physiological processes such as plant growth and development, fruit ripening, and stress responses by regulating membrane lipid composition. Using pear genome data, this study systematically identified FAD gene family members through bioinformatic analysis and characterized their drought-responsive expression patterns. Results revealed that 34 FAD family members were identified in pear, unevenly distributed across 12 chromosomes and classified into six subfamilies. Members within the same subfamily exhibited similar conserved domains and gene structures. Promoter element analysis demonstrated that pear FAD promoters contain cis-acting elements associated with plant growth and development, hormone responses, and abiotic stress responses. qRT-PCR expression profiling showed that PbrFAD23 and PbrFAD30 were significantly upregulated during the early stages of drought stress, followed by suppressed expression levels, suggesting their potential crucial regulatory roles in the initial drought response. Genome-wide identification of 34 PbrFAD family members highlighted that PbrFAD23 and PbrFAD30, with marked upregulation under early drought stress, exhibit prominent drought responsiveness. This study provides valuable resistance gene resources for molecular breeding of stress-tolerant pear varieties and establishes a theoretical foundation for functional characterization of key drought-resistant candidate genes in pear. Full article

Forage sorghum (Sorghum bicolor (L.)) is a cereal native to Africa and belongs to the family Poaceae. It is a forage with a C4 photosynthetic pathway that stands out for its ability to adapt to different environments; it is able to produce even in unfavorable circumstances. The objective of this study was to analyze the attenuating effect of the brassinosteroid hormone in the form of 24-epibrassinolide on forage sorghum plants subjected to water deficit and rehydration. A completely randomized design (CRD) was used in the experiment. A 2 × 3 × 5 factorial arrangement was used, with two water conditions (water deficit and rehydration), three brassinosteroid doses (0 nM, 50 nM, and 100 nM as 24-epibrassinolide), and five replicates. The experiment was conducted in a greenhouse. Sorghum seeds were sown in pots with a capacity of 3 kg of substrate. Analyses were performed on the roots and leaves of sorghum plants at different growth stages. The macronutrients (N, P, K, Ca, and Mg) were analyzed in the soil physics laboratory. As a result, the content of N, P, K, Ca, and Mg decreased under a water deficit and was then restored by the hormone 24-epibrassinolide, which was able to restore these nutrients. The effect of the hormone under rehydration had a positive effect, increasing the levels of nutrients. Given the above, it was possible to conclude that there were no significant divergences between the treatments during the period of irrigation suspension. Among the tested concentrations, 50 nM of 24-epibrassinolide showed the most consistent improvements in nutrient concentrations under water-deficit conditions, suggesting a potential role in mitigating nutritional imbalance during stress. Rehydrated plants maintained nutrient levels similar to the controls regardless of 24-epibrassinolide application. However, it is important to note that nutritional quality indices such as crude protein and total digestible nutrients (TDN) were not evaluated in this study, which limits direct conclusions about the forage nutritional value. Full article

Background/Objectives: Essential amino acid (EAA) supplementation is often employed in sportive and clinical nutrition due to EAAs’ role in muscle mass maintenance and growth. EAAs are also involved in insulin and glucagone regulation in diabetes management, but only few reports investigate their possible implication as dipeptidyl peptidase-IV (DPP-IV) inhibitors and their effect on the stability and secretion of enteroendocrine hormones. A blend of EAAs (called GAF) available as a food supplement, in a specific qualitative and quantitative ratio, was investigated to address its in vitro bioaccessibility, its hypoglycemic properties in vitro and in situ on cellular models, and its safety on intestinal Caco-2 cells. Methods: GAF was subjected to the INFOGEST static digestion protocol, producing the iGAF sample. iGAf DPP-IV inhibitory properties were investigated both in vitro and in situ on Caco-2 cells. Then, STC-1 enteroendocrine cells were employed alone and in co-culture with Caco-2 cells to evaluate iGAF’s impact on glucagon-like peptide 1 (GLP-1) hormone secretion. Results: The study demonstrates that the present EAAs blend is stable and bioaccessible after simulated gastrointestinal digestion, and it is safe at the intestinal cellular level. It inhibits DPP-IV enzyme both in vitro and in situ and promotes GLP-1 secretion by enteroendocrine cells. Conclusions: The sample demonstrated safety at the intestinal level and showed hypoglycemic properties by acting on a dual synergic mechanism that involves DPP-IV enzyme inhibition and GLP-1 hormone stimulation. Full article

Traditional soil cultivation of lettuce faces challenges; hydroponic technology offers solutions to improve lettuce production. However, the interrelationships among the root phenotype of lettuce, auxin synthesis and signal transduction, and nutrient solution flow, and their effects on hydroponic lettuce growth remain unclear. We investigated the effects of nutrient solution flow state on lettuce’s early growth, transcriptomic changes, and auxin-related gene expression. Growth indicators were measured 2, 4, and 6 days after transplanting. The shoot and root fresh weights, total root length, and root surface area were significantly higher under the flow treatment than under the non-flow condition. The shoot fresh weight increased by 29, 64, and 31%, respectively, at the three growth stages. A clear distinction was observed between the samples from different treatment groups. The Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways that were commonly enriched included “Plant hormone signal transduction (auxin)”. Moreover, the significantly enriched Gene Ontology (GO) terms varied across different time points, which vividly reflected the dynamic characteristics of the plant’s response. Genes related to auxin biosynthesis—such as AL3F1, YUC5, and AMI4G—exhibited higher expression levels under the flow treatment. Overall, these results indicate that nutrient solution flow can promote auxin synthesis and signal transduction in early roots of lettuce. Full article

Light exposure during incubation can influence hatching characteristics, post-hatch growth, and physiological responses in poultry. This study aimed to evaluate the impact of pre-development exposure to different cold-colored light emitting diode (LED) lights on incubation characteristics, growth performance, stress physiology, and myogenic regulatory factors (MRFs) expression level in the slow-growing native Gerze chicken breed. Fertilized eggs were incubated under red, green, white, or dark conditions. The shortest hatch window was observed under red light (42 h), while the dark condition resulted in the longest (84 h) (p < 0.05). White light exposure reduced hatchability compared to the other groups (p < 0.05), whereas green and red lights enhanced both chick weight at hatch and egg-to-chick conversion efficiency (p < 0.001). Chicks incubated under green light exhibited superior body weight during the first four weeks (p < 0.05), but those from the red light group maintained consistently higher weights thereafter (p < 0.05). The highest serotonin levels were detected in chicks from the dark group, while the lowest were associated with green light exposure. Red light exposure was associated with the lowest corticosterone concentrations (p < 0.05). Gene expression analysis revealed no significant differences in MRFs across groups. In conclusion, the spectral level of light during incubation exerts measurable effects on hatch dynamics, post-hatch growth, and hormonal regulation in Gerze chicken. Full article

Passiflora edulis propagation relies extensively on grafting, yet the optimization of pruning strategies for scion quality remains empirically guided. This study elucidates the physiological and molecular mechanisms underlying scion quality across five leaf retention treatments (0%, 25%, 50%, 75%, and unpruned control). The 50% partial leaf retention (50% PLR) treatment optimally promoted axillary bud development in passion fruit through coordinated physiological and molecular adaptations. This treatment significantly outperformed other treatments in terms of both bud sprouting rate and growth parameters (including length and diameter). Physiological analyses demonstrated transient auxin accumulation coupled with synchronized antioxidant system activation, maintaining redox homeostasis. Transcriptomic profiling identified upregulation of genes in the auxin signaling pathway and cytokinin activators, while dormancy-related genes were suppressed. These findings establish 50% PLR as an optimal threshold that balances photosynthetic capacity with hormonal regulation, providing a science-based strategy to standardize grafted seedling production, while enhancing scion quality for grafting efficiency. Full article

Pregnancy induces substantial anatomical, hormonal, and biomechanical changes in the spine and pelvis to accommodate fetal growth and maintain postural adaptation. This narrative review synthesizes peer-reviewed evidence regarding pregnancy-related spinal biomechanics, with a particular focus on low back pain, spinopelvic alignment, sacroiliac joint dysfunction, and potential contributions to degenerative spinal conditions. A systematic search of PubMed, Embase, and Google Scholar was conducted using Boolean operators and relevant terms, yielding 1050 unique records, with 53 peer-reviewed articles ultimately cited. The review reveals that increased lumbar lordosis, ligamentous laxity, altered gait mechanics, and muscular deconditioning elevate mechanical load on the lumbar spine, predisposing up to 56% of pregnant individuals to low back pain. These changes are often associated with sacroiliac joint laxity, anterior pelvic tilt, and multiparity. Long-term risks may include degenerative disc disease and spondylolisthesis. Conservative interventions such as pelvic floor muscle training, prenatal exercise, and surface topography monitoring offer symptom relief and support early rehabilitation, although standardized protocols and longitudinal outcome data remain limited. Pregnancy-related spinal changes are multifactorial and clinically relevant; an interdisciplinary approach involving spinal biomechanics, physical therapy, and obstetric care is critical for optimizing maternal musculoskeletal health. Full article

Endometriosis, a chronic estrogen-dependent disorder defined by ectopic endometrial-like tissue growth, causes pelvic pain and infertility in reproductive-age women. Despite its prevalence, the underlying mechanisms driving lesion persistence and reproductive impairment remain unclear. This review synthesizes recent pathophysiological advances, highlighting how hormonal dysregulation, immune dysfunction, epigenetic alterations, and oxidative stress collectively foster lesion persistence and treatment resistance. Critically, these molecular disturbances disrupt critical reproductive functions—including oocyte quality, endometrial receptivity, and embryo implantation. We further explore emerging non-hormonal therapeutic strategies, including MAPK and PI3K/AKT inhibitors as well as epigenetic agents targeting HOXA10 methylation and microRNA modulation, which offer fertility-sparing alternatives to conventional hormonal suppression. To enhance clinical translation, we propose a multi-level prevention framework—encompassing at the primary level, risk reduction; at the secondary level, biomarker-guided intervention; and at the tertiary level, fertility preservation—to anticipate disease progression and personalize reproductive care. By delineating shared pathways between endometriosis and infertility, this work advances precision medicine approaches for affected patients. Full article