Search Results (2,362)

The quarantine pathogen Phytophthora ramorum has a high potential for dispersal due to its airborne inoculum, its wide range of hosts, and its ability to spread through the trade of nursery plants. For these reasons, it represents a serious threat to ornamental nursery production and, consequently, to urban, natural and semi-natural ecosystems. This oomycete pathogen (EU1 lineage, A1 mating type) has been detected on Viburnum tinus in a commercial nursery located in the Pistoia nursery district (PND) (Tuscany, central Italy), one of the main nursery areas for the production of ornamentals in Europe. Artificial inoculations were carried out in the laboratory under controlled conditions, following a standard detached-leaf assay protocol, on leaves of 16 ornamental shrub species commonly marketed by the PND. Disease severity was assessed, and susceptibility categories (high, moderate, low, and non-susceptible) were defined based on data collected at 7 and 14 days post-inoculation and validated through statistical analysis. Inoculated species exhibited variable levels of disease severity. The results confirmed the pathogen’s high virulence on Viburnum tinus and Rhododendron hybrid ‘Madame Masson’. The following species were also found to be highly susceptible: Ilex aquifolium, Loropetalum chinense, Magnolia stellata, Osmanthus fragrans, and Trachelospermum jasminoides. Camellia japonica, Nerium oleander, Osmanthus heterophyllus, Prunus laurocerasus, and Rhododendron obtusum showed moderate susceptibility. Arbutus unedo, Laurus nobilis, Photinia fraseri and Syringa vulgaris exhibited low susceptibility. At the end of the trial, no infected species fell into the non-susceptible categories. The oomycete proved particularly aggressive on Ilex aquifolium, the most susceptible host among those tested. This high susceptibility is a new finding that could have significant epidemiological implications. Our findings emphasize the need for rigorous phytosanitary surveillance in nursery systems, based on constant monitoring and the adoption of high-throughput diagnostic protocols, in order to implement effective and rapid control measures. Full article

The genus Tulipa L. is a common group of ornamental plants, characterized by high morphological variability and a complex taxonomy. Despite considerable interest in this group, assessments of its species composition remain inconclusive, as evidenced by discrepancies between contemporary taxonomic sources. The number of recognized taxa varies across major taxonomic databases, including Plants of the World Online, World Flora Online, and Euro+Med PlantBase, reflecting ongoing taxonomic revisions and differences in species concepts. In terms of distribution patterns, 7.6% are widely distributed taxa across transcontinental regions, 28.0% occur across multiple countries within a continent, and 66.9% are range-restricted taxa. The latter group includes 4.2% transnational endemics, 44.1% single-country endemics, 8.5% single-region endemics, and 10.2% single-site endemics. Recent taxonomic and evolutionary studies of Tulipa increasingly rely on molecular approaches, particularly DNA barcoding and chloroplast genome analyses, which have improved phylogenetic resolution and species delimitation in several cases. However, truly comprehensive studies combining morphological, cytogenetic, and molecular datasets remain limited and are typically restricted to individual taxa or species complexes rather than the genus as a whole. Modern molecular genetic studies demonstrate the high informativeness of both nuclear and plastid markers for studying the phylogeny, systematics, and genetic diversity of Tulipa species. Natural populations of Tulipa are under pressure from anthropogenic factors and climate change, resulting in reduced range and habitat degradation. According to the International Union for Conservation of Nature Red List of Threatened Species, among 118 taxa of the genus Tulipa, T. sprengeri Baker is classified as Extinct in the Wild, 5.9% as Critically Endangered, 5.9% as Endangered, 8.5% as Vulnerable, 11.9% as Near Threatened, and 11.0% as Least Concern. The use of exclusively national assessments to determine species extinction risk may be insufficiently objective, whereas global assessments provide a more informative and reliable approach for evaluating conservation status. In this review, we combine investigations of the morphology, taxonomy, and geographic diversity; population genetic structure and molecular diversity; and molecular phylogenetics and plastome-based genomics of the genus Tulipa. Furthermore, the review examines current challenges and future research prospects, emphasizing that studies of the genus Tulipa should integrate morphological, genomic, and ecological approaches to refine taxonomy and conserve genetic resources. Full article

This paper explores how children perceive and use outdoor spaces in their everyday urban environment, and which spatial characteristics encourage engagement, autonomy, and diverse play. This study was conducted using child-led sensory walks—an exploratory qualitative method in which children acted as active research guides—with ten children aged 6 to 11 in residential areas of Zagreb. Verbal comments, movement patterns, and play behaviours were recorded and analysed through thematic analysis. Following the walks, eleven public playgrounds were assessed from a landscape architecture perspective, integrating children’s observations with an expert evaluation of spatial organisation, shade provision, connectivity with surrounding green spaces, and potential for unstructured play. The results reveal a pronounced preference for natural and semi-natural spaces, where children exhibited longer stays, more diverse physical and symbolic play, and a greater sense of autonomy. These findings affirm the relevance of affordance theory and multisensory experience in understanding children’s spatial behaviour and demonstrate the potential of the sensory walk as a transferable research and design tool in landscape architecture practice. At a broader scale, they point to the untapped role that playgrounds—redesigned as genuine green infrastructure nodes—could play in advancing urban climate adaptation goals at the neighbourhood scale. 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

Global climate change profoundly impacts the geographical distribution patterns and evolutionary dynamics of plants. As a vital ornamental and ecological shrub native to the temperate regions of the Northern Hemisphere, the wild germplasm resources of Weigela florida are facing dual threats from habitat fragmentation and climate warming. To elucidate the biogeographical mechanisms underlying the species’ responses to climate change and to formulate scientific conservation strategies, this study simulated the spatiotemporal dynamics of suitable habitats for W. florida across key historical periods spanning the Late Pliocene (~3.3 million years ago), Quaternary (~2.58 million years ago), the current period, and future climate scenarios using an optimized Maximum Entropy ecological niche model, and further tracked the migration trajectories of its spatial centroids. The results indicate that precipitation conditions, dry-season temperatures, and temperature seasonality are the dominant environmental factors limiting the distribution of wild W. florida. During the glacial–interglacial cycles, the area of its suitable habitat fluctuated significantly. Notably, the Korean Peninsula and the southern part of Northeast China maintained high habitat suitability across all geological historical periods, serving as long-term stable Quaternary glacial refugia for the species. Under various future climate scenarios, the total suitable habitat area of W. florida generally exhibits a shrinking trend, with habitat loss primarily concentrated at the western and southern edges of its distribution range. In the future, its spatial centroid shows a significant tendency to migrate towards higher latitudes (northeastward) to track suitable climatic niches. This study clarifies the macroscopic driving mechanisms behind the habitat dynamics of wild W. florida, providing critical spatial planning guidance for the refined evaluation and long-term sustainable utilization of its germplasm resources. Full article

Safflower (Carthamus tinctorius L.) is an important medicinal plant widely used as a source of natural pigments. Flower color is a key trait affecting both ornamental and commercial value; however, the roles of long non-coding RNAs (lncRNAs) in safflower flower coloration remain largely unclear. In this study, strand-specific RNA sequencing was performed on three safflower varieties with distinct flower colors at different floral developmental stages. A total of 4851 lncRNAs were identified, including 940 natural antisense transcript (NAT) pairs. Among them, lncRNA MSTRG.28365 was identified as a natural antisense transcript paired with CtCHS.7, a chalcone synthase-like gene potentially involved in flavonoid biosynthesis. Expression analysis revealed that CtCHS.7 was highly expressed in the red-flowered variety, whereas MSTRG.28365 exhibited an opposite expression pattern, suggesting a potential regulatory association. Co-expression analysis further indicated that CtCHS.7 was associated with genes putatively involved in flavonoid modification, including UDP-glycosyltransferases and cytochrome P450 enzymes. Functional assays showed that the recombinant CtCHS.7 protein could catalyze the production of downstream flavonoid-related metabolites, although the detected product differed from canonical naringenin chalcone. These findings suggest that lncRNAs may participate in flower color variation and flavonoid biosynthesis-related processes in safflower. This study provides candidate regulatory elements for future functional validation of safflower flower coloration mechanisms. Full article

Objectives: Plant extracellular vesicles (EVs) mediate intercellular communication and carry tissue-specific metabolites, yet tissue-resolved EV metabolomics in non-model medicinal plants remains poorly explored. Hibiscus syriacus is a valuable medicinal and ornamental species rich in bioactive compounds, but the metabolic profiles of flower- and leaf-derived EVs are unknown. This study aimed to characterize tissue-specific EV metabolomes of H. syriacus and reveal their functional implications. Methods: EVs were isolated from flowers (MJH) and leaves (MJY) of H. syriacus and verified by TEM and DLS. Untargeted LC-MS/MS metabolomics was applied to profile EV metabolites. Multivariate statistics (PCA, OPLS-DA), differential metabolite screening (VIP > 1, p < 0.05), and KEGG pathway enrichment were performed. Results: MJH- and MJY-EVs exhibited typical EV morphology and high purity. In total, 3338 metabolites were identified, dominated by lipids (29.43%). Clear metabolic separation was observed between MJH- and MJY-EVs. Thirty-nine differential metabolites were identified: 31 upregulated in MJH-EVs (lipids, pentadecanoic acid) and eight in MJY-EVs (nucleotides, secondary metabolites). Glycerophospholipid metabolism was the most enriched pathway in MJH-EVs, while MJY-EVs were linked to energy and defensive metabolism. Conclusions: H. syriacus EVs display strong tissue-specific metabolic signatures. Leaf EVs prioritize lipid metabolism for photosynthetic function and stress tolerance, while flower EVs accumulate secondary and energy-related metabolites for reproduction and defense. These findings advance plant EV biology and support potential applications of H. syriacus EVs in cosmetics and agriculture. Full article

Yellow bells (Tecoma stans) is a popular ornamental flowering plant used in public spaces. Its flowers are considered a medicinal herb rich in bioactive compounds. This study aimed to investigate the effect of using dried yellow bells flower (YB) as a dietary supplement for Nile tilapia (Oreochromis niloticus). Nile tilapia (0.74 ± 0.01 g body weight) were divided into six groups for an eight-week feeding trial, during which their diets were supplemented with 5 different levels by weight of YB: 2, 4, 6, 8, and 10%. The control group received a non-supplemented diet. Parameters related to growth, feed utilization, skin and fillet coloration, gut functionality, fillet quality, blood parameters, and whole-body composition were observed. Survival, feed utilization, and skin and fillet coloration were unaffected by YB supplementation, and growth performance was generally maintained up to 8% dietary inclusion. However, at 4 to 6% YB intestinal cellulase activity and gastrointestinal radical-scavenging activities were significantly increased, while amylase and protease activities, and the amylase/trypsin ratio, were maintained. Fillet quality was improved at 4% YB, with higher myosin and total myofibrillar protein contents but without changes in RNA, total protein, or RNA/protein ratio. At moderate YB inclusion levels, white blood cell counts were lower and packed cell volume and hemoglobin levels were higher, indicating improved physiological status. Whole-body crude protein and ash were increased at higher YB levels, whereas moisture and lipid were unchanged. Overall, dietary inclusion of around 4% YB was associated with favorable improvements in gut functionality, fillet quality, blood parameters, and whole-body composition in Nile tilapia. Full article

This study explored the effects of one mineral fertilizer and two microbial inoculants and their combined applications on soil physicochemical properties, bacterial community structure, and plant growth of Cymbidium faberi under potted cultivation, aiming to provide theoretical and technical support for the sustainable cultivation of ornamental orchids. A single-factor randomized block experiment was designed with eight treatments: control (CK), mineral sulfosulfuric acid potassium (HF), Bacillus subtilis (KC), Trichoderma harzianum (HC), mineral sulfosulfuric acid potassium + Bacillus subtilis (HK), mineral sulfosulfuric acid potassium + Trichoderma harzianum (HH), Bacillus subtilis + Trichoderma harzianum (KH), and mineral sulfosulfuric acid potassium + Bacillus subtilis + Trichoderma harzianum (HKH). Plant growth traits, soil properties, and soil bacterial community characteristics were measured. The effects of inoculant agents on Cymbidium faberi growth, soil environment, and bacterial community, as well as their interaction relationships, were systematically analyzed. The combination of three inoculants significantly promoted plant height and leaf thickness in Cymbidium faberi. Compared with CK, the relative abundance of Pseudomonadota and Bacteroidota in HH treatment increased by 6.0% and 11.0%, respectively, while the relative abundance of Acidobacteriota and Verrucomicrobiota decreased by 6.0% and 12.0%, respectively. Venn diagram analysis revealed 146 ASVs shared among all treatments. KC, HC, and HF had more unique ASVs, whereas HK and HKH had the fewest. Principal component analysis (PCA) was used to visualize differences in bacterial community structure. Significant differences among treatments were confirmed using ANOSIM. Ecological network analysis indicated predominantly positive (cooperative) associations among bacterial taxa, with HKH showing the highest proportion of positive edges, suggesting stronger bacterial cooperation. Correlation analysis showed that Patesibacteria, Acidobacterita, and Planctomycetota were significantly negatively correlated with pH and TP, while Bacteroidota, Actinomycetota, and Methylomirabilota were significantly positively correlated with pH. The Mantel analysis revealed a significant positive correlation between bacterial community composition and richness and pH. Further analysis using the structural equation model revealed that soil nutrients and bacterial communities were the main factors affecting plant growth. This study clarifies the response rules of plant growth, soil physicochemical properties and rhizosphere bacterial communities to different mineral fertilizer and microbial inoculant combinations, and provides a practical basis for the rational screening of functional inoculants and the construction of healthy rhizosphere microecosystems in Cymbidium faberi pot cultivation. Full article

Agave guiengola Gentry is a microendemic ornamental species native to Oaxaca, México, with restricted distribution and threatened by human activities, placing it at risk of extinction. Two culture media were evaluated: Murashige and Skoog (MS) medium and modified MS medium, together with medium consistency (semisolid and liquid) and plant growth regulators (PGRs): 6-benzylaminopurine (BA) (5.0 mg L⁻¹) for MS media and a combination of kinetin (KIN) and 3-indoleacetic acid (IAA) (5.0–9.0 and 0.1–1.0 mg L⁻¹ respectively) for modified media. Shoot clusters were grown in two consecutive 30-day phases, with transfer to opposite consistency after the first month of cultivation (first phase). Growth, hyperhydricity, rooting and callus formation were evaluated. Treatments using modified formulation + KIN + IAA under both consistencies had the greatest growth (5.5 and 5.0 cm²). Hyperhydricity was more frequent in liquid MS media (up to 100%), while adjusted MS medium had lower incidence with or without PGRs (0.0% and 6.6%). Transfer from liquid-to-semisolid medium reduced hyperhydricity (10.47%) compared with the reverse (31.35%). Rooting occurred frequently with modified formulation media. Callogenesis occurred mainly using MS + BA media (up to 93.2%), associated with adventitious shoot formation. A synergistic biphasic effect is proposed using semisolid MS + BA followed by modified MS liquid + KIN + IAA, optimizing in vitro growth for conservation. Full article

Water hyacinth (Pontederia crassipes Mart.) is native to the Amazon basin. It has spread to freshwater ecosystems in over 80 countries in tropical, subtropical, and warm temperate regions. Due to its invasive nature, water hyacinth is listed among the world’s 100 worst invasive alien species. Infestations of water hyacinth affect the abiotic components of these ecosystems, including water evaporation, flow, and quality; oxygen and nitrogen levels; sunlight transmission; and greenhouse gases. These changes reduce the abundance and diversity of primary producers in the food web, including phytoplankton and aquatic plants. Consequently, these alterations affect consumers in the food web, including zooplankton, invertebrates, fish, and birds. A negative correlation has often been observed between water hyacinth infestations and the abundance and diversity of these organisms, particularly native species. However, the abundance of some introduced species among these consumers has increased due to water hyacinth infestations. These changes alter the structure and function of natural ecosystems compared to what they were before infestations occurred. Infestations also negatively impact daily human activities and livelihoods, harming local communities and increasing disease transmission. Global warming and the eutrophication of freshwater ecosystems allow water hyacinth to spread into additional non-native areas in high latitudes, thereby increasing the threat it poses. Water hyacinth also contributes to global warming by increasing methane emissions. Over the past century, management strategies have shifted toward restoring the structure and function of ecosystems by progressively integrating various sectors. The infestation of water hyacinth is a complicated, site-specific process influenced by time, climate, existing biotic and abiotic factors, and ecosystem resilience. Therefore, long-term monitoring of environmental outcomes is essential for developing sustainable, site-specific strategies. Robust evaluation systems are necessary to track the efficacy of interventions and to understand the broader ecological ramifications of management strategies. Water hyacinth is still sold in some local markets for ornamental purposes. Raising public awareness of its invasive characteristics is necessary. Full article

Methyl jasmonate (MeJA) is a key regulator of plant defense and abiotic stress responses, while terpenoids are important secondary metabolites. However, the effects of MeJA on floral volatiles in Lagerstroemia indica and the underlying mechanisms remain unclear. In L. indica ‘Whit III’, MeJA treatment rapidly increased the emission of monoterpenes (e.g., citronellol) and sesquiterpenes (e.g., trans-farnesol) and advanced the peak emission time. We identified 34 LiTPS and 22 LiMYC genes in the genome, with promoter regions enriched in JA-responsive cis-elements. Expression analysis showed that LiMYC genes encoding putative JA repressors were transiently upregulated, whereas LiTPS genes located in a chromosome 11 cluster and LiTPS13 (7.33-fold induction) were strongly activated. These results suggest that MeJA may promote an early scent production through the coordinated activation of specific LiMYC and LiTPS gene sets, pointing to a potential mechanism by which jasmonate signaling modulates floral volatile emission. Full article

Containerized ornamental plant production requires efficient irrigation strategies to balance plant quality with water and nutrient conservation. This study evaluated four leaching fraction (LF) levels (0%, 20%, 40%, and 60%) in a completely randomized design with three replications, each consisting of three pots, to determine their effects on plant growth, ornamental quality, gas exchange, water use efficiency (WUE), and macronutrient leaching in off-season potted Curcuma cv. ‘Jasmine Pink’. Irrigation volumes were determined using crop coefficient (Kc)-based estimates derived from evaporation pan measurements. The results showed that the highest LF level (60%) significantly improved several ornamental quality traits, including flower number per cluster, leaf greenness, specific leaf area, and compactness index, while also increasing aerial dry weight and improving gas exchange parameters during the flowering stage. These improvements were associated with reduced substrate electrical conductivity, indicating lower soluble salt accumulation in the root zone under higher LF treatments and more favorable conditions for plant growth. Leaching fraction is commonly used in containerized crop production to prevent excessive salt accumulation in the root zone by allowing excess irrigation water to drain from the substrate. However, increasing LF also resulted in greater irrigation water consumption and higher macronutrient losses through leachate, particularly potassium. In contrast, lower LF treatments (0–20%) improved water use efficiency and reduced nutrient losses but were associated with higher substrate electrical conductivity, suggesting greater soluble salt accumulation in the root zone. Overall, the results indicate that a higher LF (60%) provided the greatest improvement in plant growth and ornamental quality under the conditions of the present study for off-season potted Curcuma alismatifolia production, although integrated strategies may be required to reduce water and nutrient losses. These findings provide practical insights for optimizing irrigation management in container-grown ornamental crops. Full article

Iris sanguinea features upright, stiff leaves, making it an excellent cut-foliage material, with its tall leaf architecture greatly enhancing ornamental value in landscaping. However, during the leaf expansion phase, plants frequently exhibit loose foliage arrangement, excessive spreading, and compromised mechanical strength, culminating in lodging and a concomitant decline in ornamental quality. Plant height in I. sanguinea is strongly regulated by phytohormones. This study showed that exogenous GA at concentrations of 50 mg·L⁻¹, 100 mg·L⁻¹, and 200 mg·L⁻¹ increased seedling height by 5.7%, 8.8%, and 12.7%, respectively, through foliar spraying on I. sanguinea seedlings grown ex vitro in a greenhouse; conversely, PAC treatment at equivalent concentrations suppressed growth by 19.3%, 21.0%, and 22.2%, respectively. Two pivotal GA signaling components, GAI and GID1a, were isolated from I. sanguinea. Subcellular localization confirmed that both IsGAI and IsGID1a proteins localize to the nucleus. Overexpression vectors pCAMBIA1300-IsGAI-GFP and pCAMBIA1300-IsGID1a-GFP were constructed and expressed in Arabidopsis thaliana. Transgenic lines overexpressing IsGAI showed significantly reduced plant height, hypocotyl elongation, and bolting, whereas IsGID1a overexpression promoted these traits. Exogenous GA application partially reversed the dwarf phenotype induced by IsGAI overexpression and further potentiated the height enhancement observed in IsGID1a-overexpressing lines. This study identifies two key genes controlling plant height and provides a theoretical basis and genetic resources for precisely engineering plant architecture in I. sanguinea. This is especially important for developing dwarf varieties with enhanced ornamental and agronomic traits, offering significant potential in the landscaping and cut flower industries. Full article

The genus Myricaria is one of the four genera within the Tamaricaceae family. It comprises 13 species distributed across Eurasia. Phytochemical studies carried out on Myricaria plants revealed the presence of flavonoids (including rare, sulfated derivatives), tannins, phenolic acid derivatives, triterpenoids, steroids, and alkanediols. Studies on the extracts and compounds isolated from the described to date have demonstrated various biological activities, including antioxidant, anti-inflammatory, cytotoxic, antimicrobial, analgesic, antinociceptive, cholinergic, and glucose absorption reducing properties. This work provides a comprehensive overview of the botanical and detailed phytochemical characteristics, ornamental value, pharmacological properties, and traditional uses of the Myricaria genus representatives. The article fills a longstanding gap in the literature as no other integrative description is currently available. Full article