Search Results (1,009)

Domestication has profoundly shaped the phenotypic differentiation and genetic architecture of Perilla. However, analyses of the morphological difference between its cultivated and weedy forms across its varieties remains incomplete. This study analyzed morphological variation, genetic diversity, population structure, and marker–trait associations of 45 accessions representing the cultivated and weedy forms of two Perilla varieties (P. frutescens var. frutescens and var. crispa) collected from South Korea and Japan. Analyses of ten qualitative and quantitative agronomic traits revealed clear domestication-related differentiation. Cultivated var. frutescens showed larger and heavier seeds, whereas cultivated var. crispa and the weedy accessions were characterized by longer inflorescences and higher floret numbers but smaller seeds. Strong positive correlations were observed among seed-related traits, particularly between seed size and seed weight (r = 0.932), indicating coordinated selection of seed traits. Genetic diversity analysis using 70 SSR markers identified 330 alleles consistent with domestication bottlenecks in cultivated forms while higher diversity was generally retained in the weedy accessions. Population structure, UPGMA clustering, and principal coordinate analyses broadly differentiated the cultivated and weedy accessions, although partial admixture indicated shared ancestry and historical gene flow. Association mapping using Q-based GLM and Q + K MLM models identified 23 significant marker–trait associations involving 16 SSR markers consistently detected across both models. Several markers were associated with multiple traits, implying pleiotropy or tight genetic linkage. Notably, five SSR markers (KNUPF192, KNUPF202, KNUPF207, KNUPF230, and KNUPF238) may represent potential candidate loci for marker-assisted selection to improve seed-related traits in var. frutescens and leaf-related traits in var. crispa. Full article

Hordeum brevisubulatum ‘Mengnong No. 2’ is a new forage variety developed using traditional group selection breeding techniques. It features notable advantages in plant height, tillering capacity, and overall biomass yield. However, key molecular breeding techniques such as molecular marker identification and genetic manipulation have yet to be established for this variety, limiting improvements in important traits. Consequently, we assessed the biomass of ‘Mengnong No. 2’ against ‘Mengnong No. 1’, the most widely cultivated variety in the central and western regions of Inner Mongolia, China. We report that fresh forage, dry forage, and seed yields of ‘Mengnong No. 2’ increased by 20.6%, 31.78%, and 34.35%, respectively, compared with the control variety, indicating broad prospects for its application and promotion. To enable rapid identification of ‘Mengnong No. 2’ during its promotion and to prevent production losses caused by variety admixture, we used three screened SSR primer pairs (GST25, GST37, GST127) to construct a DNA fingerprint for five H. brevisubulatum varieties, including ‘Mengnong No. 2’. With the percentage of polymorphic bands exceeding 95%, these profiles enabled precise identification of the ‘Mengnong No. 2’ variety. Furthermore, callus regeneration in H. brevisubulatum represents a bottleneck for directed molecular breeding techniques such as genetic transformation and gene editing. Accordingly, we selected the inflorescences of ‘Mengnong No. 2’ as explants and investigated the callus induction and regeneration capacity of inflorescences at different developmental stages. We found that explants at the spikelet primordia differentiation stage exhibited the highest callus induction and regeneration efficiencies, reaching 62.7% and 72.8%, respectively. The resulting embryogenic callus lines can serve as recipients for Agrobacterium-mediated transformation or gene gun bombardment, facilitating the development of subsequent high-efficiency genetic transformation and gene-editing systems. The SSR-based variety identification system and the highly efficient regeneration technology using inflorescence-derived callus established in this study lay a solid foundation for the development of a molecular breeding system for ‘Mengnong No. 2’. Full article

C3H-type zinc finger proteins play essential roles in plant responses to abiotic stresses, as well as in the regulation of growth, development, and signal transduction. Birch (Betula platyphylla Suk.), an ecologically adaptable tree species widely distributed in northern regions, has not yet been systematically characterized for its C3H gene family. In this study, a total of 15 BpC3Hs were identified from a genome-wide analysis of birch. Their physiochemical properties, gene structures, conserved motifs and domains were systematically analyzed. Promoter analysis identified cis-acting elements associated with stress responses, hormone signaling, and developmental regulation. Transcriptome data further showed that most BpC3Hs were responsive to salt, drought, high/low-temperature stresses, and light/dark treatment, and showed differential expression patterns in tension wood and opposite wood. Additionally, they displayed stage-specific expression patterns during male inflorescence development. This study lays a foundation for future functional characterization of the C3H gene family in birch and its application in molecular breeding for stress resistance. Full article

Ostericum palustre (Besser) Besser (synonym Angelica pancicii Vandas ex. Velen.) is a Eurasian species from the Apiaceae family, previously related to the Balkan endemic species A. pancicii. The study aims to provide a thorough profiling of methanol-aqueous extracts from O. palustre leaves, roots, and inflorescences integrated with an evaluation of antioxidant potential and enzyme inhibitory activity towards some therapeutic targets. For the first time, a series of simple coumarins and furanocoumarins alongside phenolic and acylquinic acids, and flavonoids were annotated/dereplicated in the O. palustre of Bulgarian origin by liquid chromatography coupled with quadrupole—Orbitrap high resolution mass spectrometry acquisition platform. According to the discriminant analysis (sPLS-DA) of the biological potential, radical scavenging activity (47.9 mg TE/g in DPPH and 61.8 mg TE/g in ABTS), reducing power (102.2 mg TE/g in CUPRAC and 57.4 mg TE/g in FRAP), and metal-chelating capacity (20.1 mg EDTAE/g) accounted mainly for the stronger antioxidant activity of inflorescences extract than roots and leaves. Root extracts exhibited anti-collagenase, anti-elastase, and anti-hyaluronidase effects with lower IC₅₀ values (IC₅₀ 37.22, 42.47 and 32.09 μg/mL, respectively). Pearson relationship analysis revealed potent antioxidants including furanocoumarins (oxypeucedanin hydrate, xanthotoxol/bergaptol, byakangelicin/isobyakangelicin, ostruthol) and phenolic acids, while a series of angelols alongside feruloylquinic and dicaffeoylquinic acids, and flavonol glycosides hold significance for the neuroprotective activity of the leaves extract. The enzyme inhibitory activity of the root extracts towards collagenase, elastase and hyaluronidase, related to the anti-aging activity, was ascribed to simple hydroxylated/methoxylated coumarins. The study suggests the potential health benefits of O. palustre extracts as antioxidant, anti-aging, and neuroprotective agents. Full article

The identity of oregano used as a medicinal plant and culinary spice remains controversial due to frequent confusion between Origanum vulgare L., native to the spontaneous flora of Romania (mainly subsp. vulgare), and chemically distinct oregano taxa commercially marketed under the generic name “oregano”, often associated with phenolic-rich chemotypes attributed to O. vulgare subsp. hirtum (Link) A.Terracc. The present study aimed to clarify the morphological and chemotaxonomic differences between wild Romanian populations of O. vulgare and commercially available oregano-type plant material, using authenticated O. vulgare subsp. hirtum as a comparative reference. Comparative botanical analysis was performed on wild and cultivated material, followed by thin-layer chromatography (TLC) screening and gas chromatography–mass spectrometry (GC–MS) analysis of essential oils obtained by hydrodistillation. Morphological examination revealed stable differences between wild O. vulgare subsp. vulgare and commercially sourced material in stem habit, leaf morphology, inflorescence structure, corolla coloration, and aroma. TLC screening showed the absence of phenolic derivatives in extracts from wild O. vulgare subsp. vulgare and authenticated O. vulgare subsp. hirtum, while intense thymol-related zones were detected exclusively in plants derived from commercial seeds labeled as O. vulgare. GC–MS analysis confirmed these findings, demonstrating the absence of phenolic monoterpenes in wild populations and their high abundance, particularly thymol and carvacrol, in commercial samples. These results highlight significant discrepancies between authentic wild oregano and commercially marketed plant material, emphasizing the need for rigorous botanical authentication in ethnobotanical, phytochemical, and pharmacological research. Full article

The influence of the autohydrolysis temperature of sunflower stems (SSs) and sunflower inflorescence (SI) on the changes in the composition of the pyrolysis products of their hydrochars (HCs) was investigated. This research was carried out using a TG/FT-IR analytical device, the semi-quantitative ATR technique, the quantitative XRD technique, and the SEM (EDS) technique. It was found that a rise in autohydrolysis temperature alarmingly increases the contribution of undesirable hydrocarbons in the volatile pyrolysis products of HCs calculated with respect to the emitted CO₂ and substantially decreases the yield of pyrolyzed solid products. The rise in autohydrolysis temperature not only changes the content of inorganics in HCs but also influences the migration of inorganics in these samples during pyrolysis: intensifies the migration of Mg and Ca and reduces the migration of K. This affects the secondary reaction between the volatile pyrolysis products. The addition of 2 wt% of paracetamol to pyrolyzed HCs inhibits the migration of Mg and Ca and increases the migration of K with volatile products, which positively influences the reduction in undesirable compounds in the composition of emitted volatile products. The addition of paracetamol decreases the yield of pyrolyzed SSHCs by circa 2% and increases the yield of pyrolyzed SIHC₁₈₀ by almost 5%. Full article

Huauzontle (Chenopodium berlandieri subsp. nuttalliae) is a pseudocereal native to Mesoamerica, traditionally consumed as a nutrient-rich food and characterized by its adaptability to adverse environmental conditions, including salt stress. This study evaluated the effects of four NaCl concentrations (0, 100, 200, and 300 mM) on plant morphology and nutrient concentrations (N, P, K, Ca, Mg, Fe, Cu, Zn, Mn, and B) and Na in leaves, stems, inflorescences, and seeds of three native huauzontle genotypes. The experiment was conducted using a completely randomized design with a split-plot arrangement and 12 replications. Applications of 200 and 300 mM NaCl delayed harvest and reduced seed weight, while plant height, fresh and dry biomass of stems, leaves, and inflorescences were progressively decreased as NaCl concentrations increased. Orthogonal partial least squares discriminant analysis (OPLS-DA) clearly differentiated genotypes and grouped NaCl treatments into distinct clusters, revealing different nutrient partitioning patterns among plant organs. Nutrient accumulation varied according to organ and salinity level; leaves showed reduced N, K, Ca, Mg, and Fe concentrations, whereas Cu and Mn concentrations increased. Huauzontle exhibited high salinity tolerance, maintaining growth and development at NaCl concentrations up to 300 mM. These findings highlight the potential of huauzontle as a resilient and nutritionally valuable crop for cultivation under saline conditions. Full article

This study evaluated morphological variation in 45 accessions of cultivated Perilla frutescens var. frutescens (PFF) and var. crispa (PFC) collected from South Korea and Japan, together with their weedy counterparts, var. frutescens (WPFF) and var. crispa (WPFC) from South Korea, using ten quantitative and ten qualitative traits. Clear morphological differentiation was observed between cultivated and weedy forms in both varieties, particularly in pigmentation, plant fragrance, and seed-related traits. PFF cultivars were characterized by predominantly green pigmentation, a typical frutescens aroma, and significantly larger and heavier seeds, suggesting stronger phenotypic differentiation in leaf and seed utilization. In contrast, PFC cultivars showed substantial morphological overlap with WPFC and WPFF accessions, indicating comparatively weaker phenotypic differentiation. Principal component analysis showed that the first principal component (PC1) explained 25.7% of the total phenotypic variance and was strongly associated with five quantitative traits (plant height, inflorescence length, floret number, seed size, and 100-seed weight) and five qualitative traits (adaxial and abaxial leaf color, flower color, seed color, and seed hardness). Along PC1, PFF cultivars formed a well-defined cluster, whereas PFC cultivars and the weedy WPFF and WPFC accessions exhibited broader dispersion, reflecting greater morphological variability. These results provide morphological insights into the differentiation between cultivated and weedy Perilla accessions and indicate potential domestication-related patterns. However, these interpretations are based primarily on morphological observations, and further genetic and evolutionary studies will be necessary to clarify the domestication history of these taxa. The identified trait complexes provide a useful phenotypic foundation for marker-assisted breeding, informed cultivar selection, and effective germplasm conservation and management. Full article

Garlic (Allium sativum L.) is an important vegetable with high nutritional and medicinal value. Its reliance on asexual reproduction causes variety degradation and low propagation efficiency, severely limiting the garlic industry. This study established an efficient shoot organogenesis system for the garlic cultivar Gailiangsuan through optimizing tissue culture protocols. Various explants, media, and hormone combinations were tested to determine the optimal conditions for improving in vitro propagation efficiency. The results demonstrated that for garlic inflorescence explants, immature inflorescences protruding 0–5 cm from the leaf sheath or not protruding were the optimal explants, exhibiting the highest shoot number. The Gamborg B5 (B₅) medium supplemented with a hormone combination of zeatin (ZT) 2 mg/L + indole-3-acetic acid (IAA) 0.05–0.2 mg/L at the first stage and ZT 0.2 mg/L + IAA 0.05 mg/L at the second stage was the most effective for improving in vitro propagation efficiency. For in vitro stem disc culture, the B₅ medium containing 6-benzylaminopurine (6–BA) 2 mg/L + 1-naphthaleneacetic acid (NAA) 0.2 mg/L was optimal. Moreover, a sucrose concentration of 7% was identified as optimal for microbulb development, resulting in significantly larger microbulbs than those grown in a medium with 3% sucrose. These results provide a technical basis for large-scale production of high-quality garlic seedlings. Full article

Safflower (Carthamus tinctorius L.) is a traditional economic crop in China valued for its medicinal petals and high-quality seed oil. Despite the importance of floret number and capitulum architecture for petal yield in safflower, the molecular regulators linking auxin signaling to inflorescence development in this species remain poorly understood. Auxin response factors (ARFs) are key transcriptional regulators mediating auxin-responsive gene expression and developmental processes, yet their functions in safflower inflorescence development have not been systematically investigated. In this study, we identified 25 CtARF genes from the safflower genome and classified them into five phylogenetic subfamilies. Cis-regulatory analysis predicted the presence of hormone- and development-related elements in CtARF-associated promoter regions. Expression profiling revealed that CtARF4, a member of the CtARF III subfamily, exhibits preferential expression during flower development. CtARF4 was localized to the nucleus and shown to interact with the CtMADS24 promoter and the Aux/IAA protein CtIAA9 in heterologous systems. Transient overexpression of CtARF4 increased floret number and length and promoted flowering, whereas virus-induced gene silencing resulted in opposite phenotypes. In addition, CtARF4 perturbation was associated with a reduction in IAA content as measured by a kit-based assay. Collectively, these findings suggest that CtARF4 functions as an auxin-responsive transcriptional regulator contributing to inflorescence development in safflower. Full article

Tomato (Solanum lycopersicum L.) is a globally important vegetable crop and a key model species for studying reproductive development in other Solanaceae members with edible fleshy fruits, such as eggplant, sweet and hot peppers, and Physalis spp. The morphogenesis and patterning of tomato floral organs fundamentally determine fruit yield and quality. Recent advances in high-throughput sequencing and gene editing have significantly deepened our understanding of the molecular network regulating tomato reproductive development. This process, from the transition of vegetative shoot apical meristem to the inflorescence meristem, forming floral meristems with primordia of sepals, petals, stamens, carpels, and fruits, is precisely coordinated by a genetic network involving homeobox and other types of transcription factors, along with signaling pathways. This review systematically outlines the core regulatory network, with an emphasis on the MADS-domain transcription factor family and its associated ABCDE model. Integrating insights from hormone signaling and mutant phenotypes, we summarize the maintenance of inflorescence meristem identity, the specification of floral meristems, and the morphogenetic patterns and core gene regulatory mechanisms for each floral whorl in tomato. We further extend this framework to the flower–fruit continuum, examining how carpel development, floral meristem termination, and ovule differentiation influence fruit morphology, locule number, pericarp structure, and metabolic traits. Finally, we discuss the integration of floral organ development with molecular design breeding and formulate a forward-looking research agenda that translates floral regulatory mechanisms to breeding strategies for yield, uniformity, and fruit quality. This synthesis provides a theoretical foundation and genetic resources for the genetic improvement of tomato flower architecture and its underlying regulatory mechanisms. Full article

Taraxacum kok-saghyz (TK), the rubber dandelion, is an emerging crop offering potential for sustainable natural rubber production independent of tropical climates. Successful domestication of TK requires a mechanistic understanding of its reproductive biology, yet floral anatomy, sporogenesis, and gametogenesis remain poorly characterized. We hypothesized that TK’s reproductive development follows the general patterns of sexually reproducing diploid Taraxacum species and other Asteraceae, distinguishable from the irregular meiosis reported in apomictic taxa. Here, using light and scanning electron microscopy across multiple developmental stages, we describe the floral and inflorescence anatomy, as well as sporogenesis and gametogenesis in TK. Anther development in TK predominantly follows the simultaneous microsporogenesis pattern, typical of eudicots, producing regular tetrahedral tetrads. Notably, we also observed occasional successive-type events resulting in dyads and tetragonal tetrads, indicating a previously unreported developmental variation within the species, culminating in mature tricellular pollen. We detail key reproductive structures, including anther wall layers, ovary mesophyll differentiation, and the presence of a micropylar obturator. The meiotic behavior and gametophyte development observed in TK are consistent with those of diploid, sexually reproducing Taraxacum species and other members of the Asteraceae, in contrast to the irregular meiosis reported in Taraxacum apomictic taxa. These newly described morphoanatomical details on reproductive aspects will inform breeding strategies and advance our understanding of pollination, fertilization, and seed development in TK. Full article

This study evaluated activities of crude extracts from different parts of the tree of heaven (Ailanthus altissima (Mill.) Swingle) collected in Slovenia and Hungary, using effect-directed analyses based on hyphenation of high-performance thin-layer chromatography (HPTLC) and nine in vitro assays performed in situ on chromatographic plates after the separation. HPTLC separation combined with a set of four antibacterial assays, two antifungal assays, and three enzyme inhibitor assays to evaluate the extracts of 15 plant parts: young shoots, young leaves, mature leaves, yellow leaves, petioles of leaves, petioles of male inflorescences, petioles of fruits, female inflorescences, young fruits, male inflorescences, mature male inflorescences, bark of 1–2-year branches, bark of 2-year branches, bark of tree trunk, and bark of roots. Antibacterial activities against Gram-positive bacteria (Bacillus subtilis, Rhodococcus fascians) and Gram-negative bacteria (Aliivibrio fischeri, Pseudomonas syringae pv. maculicola (Psm)), as well as inhibition of enzymes α-glucosidase, lipase, and acetylcholinesterase, were observed for all extracts. Extracts differed in their antifungal activities. Extracts of young shoots, mature leaves, petioles of leaves, and bark of roots showed antifungal activity against plant pathogens Fusarium avenaceum and Bipolaris sorokiniana. Extracts of yellow leaves, male inflorescences, bark of 1–2-year branches, and bark of tree trunks were only active against F. avenaceum, whereas extracts of young leaves were only active against B. sorokiniana. This study is the first to report that A. altissima extracts exhibit (1) antifungal activity against F. avenaceum and B. sorokiniana; (2) antibacterial activity against A. fischeri, Psm, R. fascians, and B. subtilis (except leaves, bark of branches and bark of tree trunks); and (3) inhibitory activity toward lipase, α-glucosidase (except bark of tree trunks), and acetylcholinesterase (except bark of tree trunks). Full article

Industrial hemp (Cannabis sativa L.) harvesting for grain represents a critical technological bottleneck in the modern supply chain, driven by a fundamental conflict between the plant’s resilient morphology and standard agricultural machinery. This review provides an analytical synthesis of harvesting methodologies, evaluating their performance against specific biological constraints such as extreme plant height (up to 4.5 m), high tensile fiber strength, and indeterminate ripening. Data synthesis reveals that hemp cutting is approximately 80 times more energy-intensive than for traditional forage crops, requiring an average maximum force of 243 N per stem. Comparative analysis demonstrates that while conventional whole-plant harvesting faces seed losses ranging from 26% to 46%, selective systems like specialized panicle mowers reduce these losses to nearly 2 kg·ha⁻¹ by targeting only the mature inflorescences. To ensure seed integrity and operational stability, the review identifies concrete technological priorities: the use of abrasion-resistant alloys for cutting edges, the implementation of non-binding shaft shielding (e.g., ABS piping), and a 40–50% reduction in threshing cylinder speeds compared to cereal settings. Future advancements must focus on specialized, high-clearance selective machinery and adaptive control systems to reconcile hemp’s unique physiology with industrial-scale efficiency. Full article

Plant-derived materials previously regarded as low-value by-products are increasingly investigated as sources of bioactive compounds, yet hemp (Cannabis sativa L.) leaves remain underutilized despite their rich phytochemical profile. This study aimed to evaluate and compare the in vitro antioxidant capacity and total phenolic content of methanolic extracts obtained from the leaves and inflorescences of four hemp cultivars (Finola, Futura 75, Dioica, and Kompolti). Antioxidant capacity (AC) was assessed using ABTS, DPPH, and FRAP assays, while total phenolic content was determined spectrophotometrically. Inflorescences exhibited significantly higher total phenolic content than leaves, with the highest values observed in the Finola cultivar. In contrast, leaf extracts showed greater radical-scavenging capacity in the ABTS and DPPH assays, whereas inflorescences demonstrated higher ferric ion–reducing power in the FRAP assay. Both cultivar and plant part had a significant effect on all evaluated parameters. Overall, hemp leaves and inflorescences displayed distinct and complementary antioxidant profiles in vitro, with Kompolti and Finola leaves characterized by strong radical-scavenging activity and Finola inflorescences showing the highest reducing capacity. These findings provide a comparative characterization of hemp morphological parts with respect to phenolic content and antioxidant behavior, highlighting the potential value of leaves as a source of bioactive compounds. Full article