Search Results (967)

Growth Regulating Factors (GRFs) are plant-specific transcription factors that play crucial roles in regulating growth and development throughout the plant life cycle. A total of 34 Gossypium hirsutum GRF family genes were identified at the genome-wide level, which were unevenly distributed on 19 chromosomes, and were predicted to be mainly localized in the nucleus and plasma membrane. The number of GRF family genes varied greatly among different species, and they were categorized into four subfamilies (I–IV) according to their phylogenetic relationships. The G. hirsutum GRF genes possessed specific highly conserved structural domains, Trp-Arg-Cys motif (WRC) and Gln, Leu, Gln motif (QLQ), and structural analysis of the genes revealed that they contained 1–23 exons, and most of them contained UTRs. Intraspecies covariance analysis revealed that the GRF genes expanded in G. hirsutum by segmental duplication. The promoter region of the G. hirsutum GRF gene contained a large number of adversity stress response elements, as well as a small number of hormone response elements and growth and development-related response elements. Transcriptome data showed that the expression of G. hirsutum GRF genes was significantly higher in leaves than in other tissues, and some GRF genes responded to a variety of abiotic stresses. Additionally, transcriptomic sequencing revealed significantly higher expression levels of GhGRFs (e.g., GhGRF13/14/18) in embryonic callus (EC) compared to non-embryonic callus (NEC). This differential expression was validated by RT-qPCR, which confirmed that GhGRF13/14/16/20 were significantly upregulated in EC relative to NEC. These findings provide valuable candidate genes and molecular insights for improving G. hirsutum regeneration efficiency and yield-related traits through genetic manipulation, thereby accelerating the molecular breeding of elite G. hirsutum varieties. Full article

As both an energy source and a signaling cue, light quality regulates graft healing by modulating endogenous phytohormone homeostasis, callus formation, and vascular reconnection. To elucidate the regulatory roles of red/blue (R/B) light ratios and green light supplementation on healing and seedling quality of grafted tomato (Solanum lycopersicum L.), a controlled-environment experiment was conducted in a plant factory using ‘Zhongza 105’ as the scion and ‘Zhezhen No. 1’ as the rootstock. LED lighting treatments were established with different R/B ratios (1.0, 2.5, 4.0, 5.5 and 7.0) with or without supplemental green light. The results show that moderate R/B ratios (4.0–5.5) significantly increased scion elongation, the stem diameter of both scion and rootstock, the mechanical strength of the graft union, and sap flow, while also enhancing leaf chlorophyll content, photosynthetic rate, and root activity. Under optimal R/B conditions, indole-3-acetic acid (IAA) and gibberellin (GA) levels were elevated, whereas abscisic acid (ABA) was reduced, favoring callus proliferation and vascular reconnection. Green light supplementation under moderate R/B further promoted stem thickening, leaf area expansion, water transport across the graft union, and total biomass accumulation. Overall, an R/B ratio of 4.0–5.5 combined with appropriate green light supplementation optimized the morphology, structure, and physiological performance of grafted tomato seedlings during the healing stage. The results aim to provide a scientific basis for optimizing light environments in a controlled environment, thus enhancing the stability and quality of grafted tomato seedlings. Full article

Callogenesis is a fundamental step in plant biotechnology and tissue culture, providing the basis for multiple scientific and practical applications. In this study, the impact on callogenesis of different plant growth regulators was studied on Cannabis sativa L. (a non-commercial genotype of hemp), with the objective of identifying the most suitable combination for the establishment of vigorously growing, friable calli. Forty-nine media combinations were evaluated using four PGRs: two auxins (2,4-dichlorophenoxyacetic acid, naphthaleneacetic acid) and two cytokinins (6-benzylaminopurine, kinetin). Parameters such as percentage of callus induction, proliferation, colour, texture, and growth area were assessed. Three media were identified for further spectrophotometric assays and targeted gene expression analysis: the first containing 2,4-dichlorophenoxyacetic acid 1.5 µM and benzylaminopurine 1.5 µM, the second with 2,4-dichlorophenoxyacetic acid 1.5 µM and kinetin 1.5 µM and the third supplemented with 2,4-dichlorophenoxyacetic acid 4.5 µM and kinetin 1.5 µM. The last medium proved to be superior in terms of vigour, friability and phenolic content and showed increased expression of genes involved in the early steps of the phenylpropanoid pathway. These findings highlight the central role of auxin–cytokinin interactions in regulating both callus formation and secondary metabolism. The optimised medium opens the way to subsequent biotechnological applications relying on the cultivation of plant cell suspension cultures. Full article

Shoot tip culture is currently the most widely used method for strawberry virus elimination, yet its efficiency has approached the theoretical limit of 80–85%. While anther culture offers a higher virus-free rate, it faces the technical bottleneck of low callus differentiation rates. To address this issue, this study used ‘Miaoxiang 7’ strawberry anthers as explants and systematically optimized key culture parameters. Different combinations of cytokinins and auxins were tested across various culture stages—including callus induction, adventitious bud differentiation from callus, proliferation, and rooting—to determine the most efficient plant growth regulator (PGR) formulations. This approach enhanced both the callus induction rate and differentiation efficiency. The regenerated plants obtained in this study achieved a virus-free rate of 98.39%. Flow cytometric ploidy analysis revealed that octoploids constituted the highest proportion, reaching 73.64%, among the regenerated plants. SSR molecular marker analysis indicated a genetic similarity coefficient of 0.9778–1.0000 between the regenerated plants and the maternal parent. Virus-free treatment holds potential for enhancing physiological growth indicators and fruit quality, demonstrating advantages in certain key metrics such as leaf area and soluble solids content. This technological system provides a viable approach for obtaining virus-free plants through anther culture, overcoming the technical limitation of low callus differentiation rates in anther culture. It offers reliable technical support for the sustainable development of the strawberry industry. Full article

This study explored, for the first time, the simultaneous dyeing and functionalization of textiles using enzymatically synthesized mixtures of phloridzin and esculin oligomers. Initial screening using multifiber fabric containing diacetate, cotton, polyamide, polyester, polyacrylonitrile, silk, viscose, and wool revealed that the oligomers successfully imparted color and high antioxidant activity to cotton, polyamide, and viscose. These three materials were therefore selected for determination of key process parameters’ influence, including temperature (35 °C and 75 °C), reaction time (6 h and 19 h), and oligomers’ concentration (1.5 and 3.0 mg/mL). Treated fabrics were evaluated for color strength (K/S), antioxidant activity, and prebiotic capacity (in vitro stratum corneum model), with all properties assessed before and after washing. The results showed that several functionalized fabrics retained coloration and functionality after washing, while fabrics functionalized with esculin oligomers’ mixture showed strong prebiotic capacity. Overall, the polyamide that functionalized with 3.0 mg/mL esculin oligomers for 19 h at 35 °C was identified as a promising candidate for reusable colored textiles, including dermatology-oriented garments for sensitive or atopic skin, sportswear, protective workwear, and daily use functional items such as hygienic pads or cloth liners. These findings demonstrate the feasibility of developing textiles with targeted prebiotic functionality. Full article

Plant cell culture represents a sustainable platform for the production of high-value natural products. Although ultraviolet A (UV-A) radiation is established as an inducer of phenylpropanoid metabolism, its precise regulatory role in downstream flavonoid biosynthesis within grape cells remains unclear. Using red and white-type callus derived from Vitis vinifera L. cv. Cabernet Sauvignon berry skins, we investigated the effects of UV-A treatments with two durations (45 min and 90 min) on flavonoid biosynthesis. Metabolite profiling demonstrated that UV-A predominantly promoted proanthocyanidin accumulation in white-type callus, while stimulating the global flavonoid pathway in a dose-dependent manner in red callus. Transcriptional analysis identified structural genes potentially governing flavonoid product channeling in both callus types under UV-A exposure. Weighted Gene Co-expression Network Analysis (WGCNA) constructed light-responsive regulatory modules, uncovering potential mechanisms coordinating flavonoid pathway gene expression in response to UV-A. These findings demonstrate how the interaction of callus-type and UV-A shapes flavonoid metabolic flux, providing insights into the regulation of plant cell culture metabolites. Full article

Induction of callus is an important step to produce high-quality seedlings, to promote the large-scale production of seedings, and to establish stable transgenic methods. To establish an efficient callus-based regeneration system for lily, in this study, we used the scales of Lilium regale as explants and employed plant tissue thin-layer culture to induce callus tissues. To examine the effects of different types and concentrations of plant growth regulators (PGRs) on the induction of lily callus tissues and plant regeneration, we designed orthogonal experiments using three PGRs: 6-BA, NAA, and PIC, with each regulator at three concentration levels. The results indicated that a suitable medium for inducing callus under the experimental conditions was 1.00 mg/L 6-BA + 0.05 mg/L NAA + 2.00 mg/L PIC, pH = 5.8 because in this medium, callus tissue showed a good balance of induction and contamination rate, as well as very low redifferentiation into bulbs. Under the experimental conditions, a suitable medium for callus expansion was 1 mg/L 6-BA + 0.5 mg/L NAA, pH = 5.8. We also showed that the induced callus tissues could develop into seedlings. These findings provide important references for optimizing in vitro culture systems of Lilium regale and offer supports for tissue culture studies of other lily species. Full article

Adventitious shoot regeneration is an essential prerequisite for the application of biotechnological tools such as CRISPR-Cas in woody fruit crops. Nonetheless, many Prunus species exhibit strong recalcitrance to in vitro regeneration. Light quality has emerged as an important environmental factor influencing morphogenic responses under in vitro conditions. In this study, the effect of different LED light spectra on adventitious shoot regeneration was evaluated in three peach-related genotypes: the commercial peach cultivar ‘Siroco 5’ (Prunus persica L.) and the hybrid rootstocks ‘GF677’ and ‘Garnem’ (P. persica × P. dulcis). Callus explants derived from the basal region of in vitro proliferation cultures were exposed for 30 days to five LED light treatments: white (control), blue, red + far-red, mixed (red + far-red + blue), and sequential LED light. Regeneration efficiency was assessed through the frequency of organogenic callus formation (FOC), the number of regenerated shoots per explant, the organogenic rate, and the fresh weight of the regenerated explants. While FOC was consistently high across genotypes and light treatments, shoot regeneration was significantly influenced by both genotype and light spectrum. The hybrid rootstocks exhibited a higher regeneration capacity than the commercial cultivar under most conditions. Red + far-red LED light promoted the highest regeneration efficiency across all of the genotypes, particularly enhancing shoot regeneration and fresh weight in ‘Siroco 5’. These results demonstrate that LED light spectrum modulation, especially red + far-red, is an effective strategy to optimize adventitious shoot regeneration in peach cultivar and hybrid rootstock genotypes, providing a robust basis for future applications in micropropagation and genetic improvement programs. Full article

The remarkable plasticity of plants is best exemplified by the capacity of their somatic cells to regenerate entire organs or the organism itself. The molecular and cellular events underlying this ability are complex and multifaceted. The initial phase leading to cell cycle reactivation is often called dedifferentiation. This process is triggered either by wounding or exogenous hormone application. In this opinion paper, I propose that the dedifferentiation of mature somatic cells is a two-step process. It involves a transition into a transient senescence-like state induced by stress and/or signals emanating from dying cells. This state entails the loss of genetic information required for cell differentiation, resulting in a critical cellular condition. In the absence of subsequent proliferative signals, dedifferentiating (senescing) cells become committed to programmed cell death. Exogenous and/or endogenous plant hormones, such as auxin and cytokinin, might override this pathway. This rescue step, in most cases, activates cell divisions to replace lost cells/tissues. If cell division is maintained, it may result in callus formation. A callus is not an undifferentiated, homogeneous mass of cells. It is an unorganised tissue with at least some cells having ground-tissue-like molecular identity and high developmental potential. A callus might also form from pre-existing competent cell populations, e.g., pericycle cells, with no senescence-like intermitting state. It is discussed whether this “one-step” callus-formation pathway can be considered dedifferentiation. Full article

Morus alba L., a member of the Moraceae family, is known for its positive effects on human health, linked to the presence of different classes of secondary metabolites, including flavonoids, stilbenoids, and alkaloids, found in different parts of the plant. Stilbenoids, in particular, are mainly present at the root cortex level and, owing to their valuable activities, have attracted scientific interest in recent years. Since roots are a non-renewable source, in this study, M. alba in vitro callus cultures were established. The biomass with the appropriate growth and texture was selected for juice extraction, and the total phenol, flavonoid, and proanthocyanidin contents, along with the antioxidant activity, were estimated in the juices. The analyses throughout the callus growth cycle revealed the juice of 14-day-old calli to be the richest, resulting in the most active. In this juice, the LC-MS/MS-DAD analysis unveiled the presence of seventeen stilbenoids. Together with the data obtained by the nutritional analysis, the results showed that M. alba cell cultures have the potential to be utilised for producing innovative healthy food materials, bridging the gap between the ever-increasing natural-based-product demand and the need for more environmental, social, and economic development. Full article

P. peruviana is a species of agronomic and biotechnological interest; however, the relationship between in vitro regeneration and phenolic compound production remains poorly explored. This study evaluated the combined effects of thidiazuron (TDZ), explant type (cotyledon and hypocotyl), auxin type (naphthaleneacetic acid, NAA, or indole-3-butyric acid, IBA), and auxin concentration on shoot organogenesis, photosynthetic pigment content, and phenolic accumulation. An initial screening identified 4.54 µM TDZ as the optimal concentration for shoot induction. Subsequent experiments showed that morphogenic and physiological responses were strongly dependent on the interaction among explant type, auxin type, and auxin dose. Cotyledon explants consistently exhibited higher shoot regeneration, vigor, biomass accumulation, and photosynthetic pigment content than hypocotyl explants, which showed reduced physiological performance and a higher tendency for callus formation. NAA-based treatments primarily enhanced morphogenic traits, whereas IBA-based treatments were associated with increased photosynthetic pigment content and phenolic accumulation. Multivariate analysis integrating morphogenic, physiological, and biochemical variables identified cotyledon explants cultured with 0.5 µM IBA in the presence of 4.54 µM TDZ as the treatment achieving the most favorable balance between shoot regeneration, physiological stability, and controlled phenolic accumulation. These findings provide a robust basis for optimizing in vitro culture systems of P. peruviana that balance growth, physiological integrity, and secondary metabolism. Full article

Plant-derived polynucleotides (PNs) have emerged as promising regenerative biomolecules; however, their mechanisms remain less defined than those of salmon-derived polydeoxyribonucleotides (S-PDRNs). Here, we extracted polynucleotides from Paeonia lactiflora callus (PL-PN) and evaluated their biological effects on human dermal fibroblasts. PL-PN treatment increased cell viability and pro-collagen I α1 secretion. PL-PN enhanced adenosine A2A receptor expression and activated the cyclic adenosine monophosphate (cAMP)/protein kinase A (PKA)/cAMP response element-binding protein (CREB) pathway, accompanied by increased Cyclin D1 levels, retinoblastoma protein (Rb) phosphorylation, and nuclear proliferating cell nuclear antigen (PCNA) levels, indicating an accelerated G1/S transition. PL-PN also significantly reduced nuclear NF-κB localization and downregulated MMP1, MMP3, MMP9, and MMP13, suggesting attenuation of inflammatory and catabolic signaling. Furthermore, PL-PN increased TGF-β maturation, Smad2/3 phosphorylation, and the transcription of COL1A1, COL3A1, and elastin, resulting in enhanced collagen and elastin deposition. These effects are comparable to those of S-PDRN. Although the pathway specificity and in vivo relevance require further studies, our findings provide evidence that PL-PN promotes extracellular matrix regeneration via coordinated proliferative, anabolic, and anti-inflammatory actions. Thus, PL-PN represents a potential sustainable plant-based alternative to S-PDRN for dermatological regeneration. Full article

Adventitious shoot regeneration in woody species is regulated by interactions between plant growth regulators, endogenous hormone metabolism, and environmental cues such as light quality. Here, we investigated the effects of thidiazuron (TDZ) and the cytokinin oxidase/dehydrogenase (CKX) inhibitors INCYDE and phenyladenine (PA), in combination with different light spectra, on morphogenesis in Melia volkensii leaf explants. TDZ induced the highest frequencies of callus formation and adventitious shoot regeneration, particularly under white light. INCYDE promoted localized regeneration responses, including activation of dormant meristematic regions in secondary leaf axils, whereas PA showed limited regeneration efficiency. Light quality significantly influenced morphogenesis, with white and blue light favoring organized shoot development, while red and far-red light suppressed shoot regeneration and promoted callus formation. Cytokinin profiling revealed treatment-dependent shifts in endogenous cytokinin composition, most notably in isopentenyladenine (iP)-type cytokinins, which is consistent with altered cytokinin degradation dynamics. Cis-zeatin-type cytokinins were abundant across treatments, likely reflecting regulation associated with in vitro culture conditions. These findings indicate that cytokinin metabolism and light quality jointly influence organogenic competence in Melia volkensii Gürke, providing a physiological basis for optimizing regeneration strategies in woody plants. This study provides the first integrated analysis of cytokinin-modulating compounds and light spectra on adventitious shoot regeneration in Melia volkensii. The findings establish a physiological basis for improving regeneration protocols in recalcitrant woody species and support future biotechnological applications, including genetic improvement and advanced propagation strategies. Full article

Background/Objectives: Nonunion bone healing results from a critical size defect that fails to bridge a bone injury to produce bony union. Novel approaches are critical for refining therapy in clinically challenging bone injuries, but the complex and coordinated nature of fracture callus tissue development requires study outside of the simple closed murine fracture model. Methods: We have utilized a three-dimensional printing approach to develop a scaffold construct with layers designed to sequentially release small molecule therapy within the tissues of a murine endochondral segmental defect to augment different mechanisms of fracture repair during critical stages of nonunion bone healing. Initially, a sonic hedgehog (SHH) agonist is released from a fibrin layer to promote chondrogenesis. A prolyl-hydroxylase domain (PHD)2 inhibitor is subsequently released from a β-tricalcium phosphate (β-TCP) layer to promote hypoxia-inducible factor (HIF)-1α regulation of angiogenesis. This sequential approach to therapy delivery is assisted by the inclusion of bone marrow stromal cells (BMSCs) to increase the cell substrate available for the small molecule therapy. Results: Immunohistochemistry of fracture callus tissue revealed increased expression of PTCH1 and HIF1α, targets of hedgehog and hypoxia signaling pathways, respectively, in the SAG21k/IOX2-treated mice compared to vehicle control. MicroCT and histology analyses showed increased bone in the fracture callus of mice that received therapy compared to control vehicle scaffolds. Conclusions: While our findings establish feasibility for the use of BMSCs and small molecules in the fibrin gel/β-TCP scaffolds to promote new bone formation for segmental defect healing, further optimization of these approaches is required to develop a fracture callus capable of completing bony union in a large defect. Full article

Background/objectives: Cannabidiol (CBD) is a non-psychoactive constituent of Cannabis sativa, which has potential skeletal benefits through modulation of bone cell function and inflammatory signalling. However, evidence of its effects and mechanisms in bone health remains fragmented. This scoping review summarised the current findings on the impact of CBD on bone outcomes and its mechanisms of action. Methods: A systematic search of PubMed, Scopus, and Web of Science was conducted in October 2025 for original studies published in English, with the primary objective of examining the effects of CBD on bone health, regardless of study design. After applying inclusion and exclusion criteria, 24 primary studies were included. Data on model design, CBD formulation, treatment parameters, bone-related outcomes, and proposed mechanisms were extracted and analysed descriptively. Results: Among the studies included, eleven demonstrated beneficial effects of CBD on bone formation, mineralisation, callus quality, or strength; eleven showed mixed outcomes; and two demonstrated no apparent benefit. Previous studies have shown that CBD suppresses bone resorption by reducing osteoclast differentiation and activity while promoting osteoblast proliferation and matrix deposition. Mechanistically, CBD’s effects involve activation of cannabinoid receptor 2, modulation of the receptor activator of nuclear factor-κB ligand/osteoprotegerin pathway, and regulation of osteoblastogenic and osteoclastogenic signalling through bone morphogenetic protein, Wnt, mitogen-activated protein kinase, nuclear factor-κB, and peroxisome proliferator-activated receptor signalling. The anti-inflammatory and antioxidant actions of CBD further contribute to a favourable bone microenvironment. Conclusions: Preclinical evidence suggests that CBD has a bone-protective role through multifaceted pathways that enhance osteoblast function and suppress osteoclast activity. Nevertheless, robust human trials are necessary to confirm its efficacy, determine its optimal dosing, and clarify its long-term safety. Full article