Search Results (432)

Hydrochar has emerged as a promising carbonaceous amendment to enhance soil quality, yet its short-term effects on soil carbon (C) and nitrogen (N) dynamics and microbial functioning remain poorly understood. Here, a 77-day greenhouse pot experiment was conducted using a Cambisol cultivated with sunflower (Helianthus annuus L.) under two irrigation regimes simulating well-irrigated (WI) and water-deficit (WD) scenarios. Two doses of chicken-manure-derived hydrochar (3.25 and 6.5 t ha⁻¹, corresponding to 2.35 and 4.69 g kg⁻¹ of dry soil, respectively) and mineral fertilizer (MF) treatments providing equivalent N inputs were evaluated. Hydrochar promoted microbial growth and enhanced enzymatic and respiratory activities despite its low apparent C and nutrient input. After 77 days under WI, the addition of 6.5 t ha⁻¹ hydrochar enhanced the activity of phenol oxidase (POA) and acid phosphomonesterase (AcPA). Concomitantly, the availability of soluble C and N increased, whereas total organic C (TOC) and N decreased relative to the initial values. These responses may suggest enhanced mineralization potentially related to early-stage priming processes. The increase in POA relative to β-glucosidase is in line with a functional shift from a predominant degradation of labile compounds towards an increased oxidation of more complex structures. This interpretation is supported by solid-state ¹³C NMR data, revealing a higher degradation index of the soil organic matter. Under WD, the overall effects of hydrochar were attenuated or suppressed, particularly those related to C and N dynamics, emphasizing the interactive influence of moisture and amendment dose. Overall, our results show that hydrochar can modulate short-term soil biochemical processes, partly through enhanced microbial responses. Full article

Plants adapt to abiotic stresses by a variety of physiological and molecular mechanisms, among which the root plays important roles via responding to underground and soilborne signals. Fructan is a polysaccharide involved in energy metabolism and stress adaptation. Orobanche cumana is a holo-parasitic plant that mainly attaches to the root of the host sunflower (Helianthus annuus). Oc6-FEH, a fructan 6-exohydrolase from O. cumana, is involved in both fructan metabolism and flooding responses. Expression of Oc6-FEH is induced by flooding and indole-3-acetic acid (IAA). Oc6-FEH possesses fructan catabolism activity and is associated with fructose release. Overexpression of Oc6-FEH in the host sunflower reduces malondialdehyde (MDA) and hydrogen peroxide (H₂O₂) accumulation, boosts the activities of antioxidant enzymes, including peroxidase (POD) and superoxide dismutase (SOD), and enhances photosynthetic performance. The expression level of Oc6-FEH was found to be positively associated with the flooding tolerance of invading O. cumana, which is connected to the host root. Furthermore, IAA treatment also improved the flooding tolerance of O. cumana. In summary, the metabolism of fructan and the activity of Oc6-FEH were demonstrated to ameliorate waterlogging stress. Oc6-FEH provides a promising genetic target for the improvement of flooding tolerance in crops. Full article

Shoot branching, as an important architectural trait, influences the number of flower heads and the pattern of flowering in sunflowers (Helianthus annuus L.). However, the main genetic factors leading to extensive branching throughout the plant were not clearly understood. In this study, we analyzed branching inheritance and identified a significant locus using an F₂ population (n = 660) from a cross between the non-branched line 150A and the highly branched line PT326. The branching phenotypes varied from having no branches to complete plant branching, with segregation fitting a 3:1 ratio (χ² = 2.916, p > 0.05), suggesting that a single major gene controls this trait, with the non-branched phenotype being dominant. Using bulked segregant analysis (BSA) and whole-genome resequencing, a strong and consistent signal was identified on chromosome 10 across three separate statistical analyses, pinpointing a primary candidate interval of approximately 3.40 Mb, named qBr10. Through the use of 10 developed Kompetitive Allele-Specific PCR (KASP) markers and recombinant screening, qBr10 was restricted to a 388.5 kb (Chr10:13,422,378–13,780,875). Analysis of this interval identified 21 genes, among which WRKY21 and MTB3 were prioritized as candidate genes for further functional validation. Our findings identified qBr10 as a strong candidate for cloning and offer closely associated markers to aid in marker-assisted improvement of branching and capitulum number in sunflower breeding. Full article

Sunflower (Helianthus annuus L.) production is severely hindered by continuous cropping obstacles, leading to soil degradation and significant yield declines. This study compared soybean–sunflower (G-H) and maize–sunflower (Z-H) rotations against sunflower monoculture (H-H) to elucidate the mechanisms of soil health restoration associated with crop rotation. Our results demonstrated that Z-H and G-H rotations led to a profound yield increase of 103.19% and 82.35%, respectively, with Z-H improving the 100-grain weight by 52.63%. Soil biological revitalization was evidenced by a 98.29% increase in sucrase activity and a 28.92% rise in alkaline phosphatase activity. Metagenomic analysis revealed that the rotation sequences increased bacterial Chao1 richness by 35.29% and fungal Shannon diversity by 20.17%. Specifically, the rotation treatments proactively recruited beneficial taxa such as Pontibacter (Log₂FC > 3.0) and Panaeolus (Log₂FC = 6.88), while effectively suppressing pathogens such as Ceratobasidiaceae. Co-occurrence network analysis identified a complex bacterial scaffold (199 nodes, 53 modules) that provided greater structural robustness than the fungal network (27 nodes). It is concluded that diversified rotations effectively mitigate continuous cropping obstacles by reactivating nutrient cycling and restructuring the rhizosphere into a stable, modular microbial interactome. This study provides a quantitative framework for utilizing biological strategies to restore soil health in degraded agroecosystems. Full article

This study aims to develop and characterize novel dermatocosmetic formulations designed to hydrate the skin, improve its appearance, reduce wrinkles, and provide antioxidant, anti-ageing, antimicrobial, and anti-inflammatory benefits, along with potential protection against UVA and UVB radiation. The formulations contain the following ingredients: xanthan gum (0.5%), Calendula officinalis oil (5%), Argania spinosa oil (5%), Helianthus annuus oil (5%), liposomes containing a hydroalcoholic extract of pomace from local red or white grapes (2%), an olive oil-based emulsifier (6%), vitamin E (0.5%), cetearyl alcohol (3%), propylene glycol (8%), and purified water (up to 100%). The natural ingredients used in these formulations, i.e., the red or white grape pomace extract from the aforementioned Romanian varieties, the oils of Calendula officinalis, Argania spinosa, and Helianthus annuus, xanthan gum, and the olive oil-based emulsifier (Olliva), promote the concept of ‘green cosmetics’. The use of liposomes to deliver bioactive substances from hydroalcoholic extracts allows the gradual release of active ingredients into the skin. An alternative for incorporating grape pomace extract into a cream-type matrix involves the use of liposomes. Liposomes loaded with red or white grape pomace extract were prepared using the thin-film hydration technique, followed by ultrasonication and extrusion. The obtained formulations were characterized using bio-physico-chemical analysis procedures in terms of consistency, colour, homogeneity, aroma, pH, stretch, texture, stability, and antioxidant activity/free radical scavenging capacity, as well as in vitro polyphenol release behaviour. These newly developed dermatocosmetic formulations were the subject of a patent application in Romania. Full article

Poultry manure is a valuable nutrient source, but insufficient stabilisation may cause phytotoxic effects during early plant development. This study evaluated the phytotoxicity of fresh and composted poultry manure using seed germination and root elongation bioassays. Elutriates of aerated and static compost mixtures, poultry manure composts, and fresh manure were tested on sunflower (Helianthus annuus L.), mungbean (Vigna radiata L.), and white mustard (Sinapis alba L.). Germination and relative root growth indices were calculated. Aerated compost mixtures showed minimal phytotoxicity, whereas fresh and partially composted manure strongly inhibited seedling development. Mungbean was the most sensitive species. Root elongation was more sensitive than germination, confirming bioassays as reliable tools for assessing compost maturity and fertiliser safety. Full article

Sunflower is a globally important oilseed crop. Improving its fatty acid composition is crucial for enhancing oil quality and nutritional value. To dissect the genetic basis of quality traits, we performed genome resequencing on 203 sunflower inbred lines and conducted a genome-wide association study (GWAS) for five traits—oil content, stearic acid, palmitic acid, oleic acid, and linoleic acid—across three environments. We identified 103 significant single-nucleotide polymorphisms (SNPs) and 154 candidate genes. Notably, several associated loci were co-localized for multiple traits, suggesting pleiotropic effects or close genetic linkages. Integration with transcriptome data from developing seeds revealed that 66 candidate genes were expressed within 30 days after pollination, of which 12 showed significant differential expression between high- and low-oleic acid varieties. Functional characterization of a selected candidate, the ω-6 fatty acid desaturase gene (LOC110938218, designated HaDES8.11), demonstrated that the HaDES8.11-eGFP fusion protein localizes to the endoplasmic reticulum. Heterologous expression of HaDES8.11 in Arabidopsis thaliana significantly increased seed linoleic acid content while decreasing oleic acid content, confirming its role in fatty acid desaturation. Our study provides novel genetic insights and valuable candidate genes for the molecular breeding of sunflower with optimized oil quality. Full article

Mining and metallurgical activities are among the main sources of heavy metal (HM) contamination of terrestrial ecosystems and the creation of persistent technogenic pollution hotspots. This study aimed to provide a comprehensive assessment of the accumulation of zinc (Zn), cooper (Cu), cadmium (Cd) and lead (Pb) in soils and vegetation under conditions of long-term industrial impact in Ridder, East Kazakhstan Region. A total of 52 soil samples were collected from 0–5 cm and 5–20 cm depths at 26 sites, and 44 species of natural vegetation, as well as three dominant agricultural crops, were examined. Soil concentrations of Zn (4415 mg·kg⁻¹), Cu (1177 mg·kg⁻¹), Cd (179 mg·kg⁻¹), and Pb (1996 mg·kg⁻¹) were classified as extremely high. Cadmium contributed most to the potential ecological risk (Cd > Pb > Zn > Cu). The industrial zone’s vegetation cover was predominantly formed by stress-tolerant and ruderal species, including Artemisia vulgaris, Calamagrostis epigeios, Bunias orientalis, Dactylis glomerata, Convolvulus arvensis, and Urtica dioica. The agricultural crops (Helianthus annuus, Avena sativa, and Triticum aestivum) mainly accumulated HMs in their root systems, with limited translocation to their aboveground organs (TF < 1). This indicates the predominance of phytostabilisation mechanisms, and highlights the potential of locally adapted plants for managing contaminated areas. Full article

Soil salinization is a major constraint on sustainable agriculture worldwide, highlighting the need for stress-tolerant plant growth-promoting rhizobacteria (PGPR) for salt-affected soils. A moderately halophilic and alkali-tolerant bacterium, Staphylococcus succinus NYN-1, was isolated from the rhizosphere soil of the halophyte Suaeda dendroides collected from a highly salinized site in Xinjiang, China. This study aimed to evaluate its salt–alkali tolerance and plant growth-promoting potential through integrated phenotypic characterization, pot experiments, and whole-genome analysis. NYN-1 grew over a broad salinity range [0–15% (w/v)] and pH range (6.0–11.0), and showed plant growth-promoting activities including organic phosphorus mineralization, inorganic phosphate solubilization, potassium solubilization, and NH₄⁺ production. In pot experiments under 300 mM NaCl, inoculation with NYN-1 significantly improved the growth performance of maize (Zea mays L.), cotton (Gossypium hirsutum L.), and sunflower (Helianthus annuus L.). Genome analysis identified multiple Na⁺/H⁺ antiporter-related genes and genes encoding compatible-solute transport systems that are consistent with adaptation to salt–alkali stress. The genome also harbors a broad set of genes related to phosphorus metabolism, as well as other plant growth-promoting functions, including potassium solubilization-related pathways and siderophore biosynthesis. Collectively, these findings identify S. succinus NYN-1 as a promising native halophilic PGPR candidate and a potential microbial resource for developing inoculant strategies in salt-affected agricultural systems. Full article

The effect of sunflower extract on the germination and development of weeds is investigated. However, knowledge about the effects of extracts on target plants is equally important. Investigations into the allelopathic relationship between sunflowers and cereals, which often make up 50–70% of crop rotations, still have many unanswered questions. This experiment aimed to investigate the allelopathic impact of sunflower (Helianthus annuus L.) as a donor plant for spring barley (Hordeum vulgare L.) and spring wheat (Triticum aestivum L.) through their germination and morphological parameters. The following three factors were studied: factor A—two growth stages of the donor plant; factor B—three parts of the donor plant; factor C—five concentrations (0%, 25%, 50%, 75% and 100%) of aqueous extracts of the plant donor. The extract concentration was the strongest factor influencing the germination of spring barley and spring wheat compared to the other two factors. The flowering sunflower extract inhibited the germination of the spring barley and spring wheat by 33–44% and 33–41%, respectively, more strongly than the ripe sunflower extract. According to the SE values, the allelopathic impact of extracts of sunflower parts on spring barley and spring wheat was as follows: L + S < R ˂ H and L + S < H ˂ R, respectively. The inhibitory effect of increasing concentration was determined on the SG, root/shoot length ratio, and SPAD values of both receptor plants. Full article

The aim of this study was to evaluate the effects of protein-based (zein) and polysaccharide-based (carboxymethylcellulose, CMC) edible coatings and citric acid (CA) applied prior to freeze-drying on the quality parameters of Jerusalem artichoke (Helianthus tuberosus L.) slices from ‘Albik’ and ‘Rubik’ cultivars. Freeze-drying increased inulin extraction efficiency (57–61 g 100 g⁻¹ vs. 44–45 g 100 g⁻¹ in fresh samples). In the ‘Albik’ cv., CMC and CA coatings significantly minimized L-ascorbic acid losses, with a 10–20% reduction vs. control. For the same cultivar, enhanced polyphenol retention was observed (up to 13%) when CA coating was applied, while the use of zein reduced vitamin C content in both cultivars. Sensory analysis (PCA, 92.4% variance) revealed that CMC improved appearance, texture, and overall acceptability, while zein imparted an off-taste, odor, and fragility. Image texture analysis showed elevated parameters (e.g., HMean) post freeze-drying, with CA inducing the greatest structural changes and zein yielding samples most similar to raw material. Machine learning classification (quadratic/linear SVM, 10-fold CV) achieved 91.5% (‘Albik’) and 81.9% (‘Rubik’) accuracy, perfectly distinguishing raw slices (100%). These findings demonstrate that CMC and CA coatings optimize bioactive retention, sensory quality, and textural differentiation in freeze-dried Jerusalem artichoke, supporting their application in functional food production. Full article

The widespread application of road deicing salts in northern regions has led to elevated salinity in roadside soils and adjacent watersheds. Phytoremediation offers a cost-effective and sustainable approach for mitigating salt contamination, but its success depends on utilizing plant species that can both tolerate and remove salt under roadside conditions. To systematically identify high-potential candidates from the large inventory of salt-tolerant plants in North America, we developed a quantitative decision matrix incorporating criteria related to ecological safety, establishment potential on disturbed soils, aboveground biomass production, biomass use-value, and salt uptake capacity. Thirteen of the highest-ranked species were subsequently evaluated for sodium (Na⁺) and chloride (Cl⁻) uptake in a controlled greenhouse study under saline and non-saline conditions. The greatest total salt uptake was observed in common sunflower (Helianthus annuus) (35.6 mg Na⁺ and 100.2 mg Cl⁻ plant⁻¹) and pitseed goosefoot (Chenopodium berlandieri) (18.6 mg Na⁺ and 76.0 mg Cl⁻ plant⁻¹), while perennial species including tall fescue turfgrass (Lolium arundinaceum), showy goldenrod (Solidago speciosa), and weeping alkaligrass (Puccinellia distans) also demonstrated substantial uptake combined with greater long-term suitability for roadside management. Overall, this study presents a quantitative framework for phytoremediation species selection and provides experimental evidence supporting both annual and perennial species for mitigating deicing salt contamination through environmentally sustainable, low-input roadside management strategies. Full article

Sunflower (Helianthus annuus L.) is a crop with ornamental and energetic potential, but its propagation is challenged by abiotic stresses such as salinity and water deficit. Ensuring high-quality propagation materials is crucial for healthy plant development. Nanotechnology offers innovative tools to enhance seed performance, stress tolerance, and production efficiency. Among these, carbon nanotubes, a strong, conductive, and thermally resistant material, have shown promise in improving seed quality. This study aimed to evaluate the effects of nanopriming with multi-walled carbon nanotubes (MWCNTs) on the physiological and biochemical performance of sunflower seeds under accelerated aging and stress conditions. Seeds were treated with 100, 200, or 400 mg·L⁻¹ MWCNTs, and parameters such as germination percentage, seedling growth, pigment profile, and oxidative stress indicators were analyzed. The 200 mg·L⁻¹ concentration enhanced germination, root and shoot development, and antioxidant enzyme modulation, while the 400 mg·L⁻¹ dose increased reactive oxygen species, indicating toxicity. Under saline and drought-like conditions, nanopriming with 100–200 mg·L⁻¹ mitigated oxidative damage more effectively than hydropriming. MWCNTs also influenced pigment synthesis, affecting chlorophyll and carotenoid levels. These findings support the potential of carbon nanotube-based nanopriming to improve seed vigor and stress tolerance in sunflower cultivation, though further environmental safety assessments are required. Full article

Helianthus tuberosus L. tubers are the primary part utilized by humans for bioenergy and bioproduct production. Therefore, achieving high tuber yield is a core issue in Jerusalem artichoke cultivation and management. In this study, red-skinned Jerusalem artichoke was used as an experimental material. Under field conditions from 2022 to 2023, different root-cutting treatments were established to investigate their effects on Jerusalem artichoke biomass, photosynthetic characteristics, and rhizosphere (non-rhizosphere) soil nutrient content, aiming to provide a theoretical basis for high-yield cultivation of Jerusalem artichoke. During the vegetative growth stage (70–75 days after planting), a “vertical cutting method” was applied; centered on the plant, vertical cuts were made through the horizontal root system at radii of 20 cm, 30 cm, 40 cm, and 50 cm to implement root-cutting treatments. The total biomass, underground biomass, tuber yield and root/shoot ratio of Jerusalem artichoke increased by 11.59–25.97%, 15.77–46.33%, 7.69–49.09% and 11.72–62.69%, respectively. The tuber yield was greatest under D1 (20 cm) (0.94 kg·plant⁻¹ and 0.98 kg·plant⁻¹). On the 7th and 15th days after root breakage, the photosynthetic characteristics and transpiration rate of the Jerusalem artichoke gradually increased with increasing root-cutting radius and were lower than those of the control. On the 21st day after the root-cutting treatment, the photosynthetic characteristics and transpiration rate of the Jerusalem artichoke plants gradually decreased with increasing root-cutting radius and were greater than those of the control plants. The water use efficiency of Jerusalem artichoke increased with increasing root-cutting radius. The contents of C, N, P, available phosphorus, alkali-hydrolyzed nitrogen, nitrate nitrogen showed that proper root-cutting can increase tuber yield of Jerusalem artichoke and improve rhizosphere soil nutrients. Full article

Soil salinization severely constrains agricultural productivity, while root-associated microbiota contribute to plant adaptation to saline–alkali stress. However, developmental assembly dynamics of rhizosphere and root endosphere bacterial communities remain insufficiently characterized in irrigation-driven saline–alkali agroecosystems such as the Hetao Plain of northern China. Here, Helianthus annuus plants were sampled at seedling, squaring, and flowering stages, and rhizosphere and root microbiota were analyzed using high-throughput amplicon sequencing integrated with soil physicochemical measurements, beta nearest taxon index–based community assembly inference, and co-occurrence network analysis. The rhizosphere maintained higher diversity, broader taxonomic heterogeneity, and persistently complex interaction networks, whereas the root endosphere exhibited progressive diversity reduction and compositional convergence during plant development. Developmental progression drove contrasting successional trajectories, with increasing rhizosphere complexity and endophytic convergence toward a Proteobacteria-dominated core, particularly Pseudomonas. Beta nearest taxon index analysis indicated mixed stochastic and dispersal-related processes in the rhizosphere but drift-dominated assembly in late-stage roots. Functional predictions revealed enhanced nitrogen-related metabolic potential during flowering, coinciding with enrichment and network centrality of Pseudomonas. These findings demonstrate stage-dependent spatial reorganization of sunflower root microbiomes under saline–alkali stress and provide a framework for identifying functionally relevant microbial groups for targeted microbiome-based agricultural management. Full article