Search Results (170)

M. crystallinum is an edible halophytic succulent plant rich in phenolic compounds with potential pharmaceutical applications. However, it is known that these phytocompounds generally present low absorption, which hinders their direct use in formulations. Therefore, delivery systems, such as phytosomes, can be regarded as a potential strategy to overcome this disadvantage. This study aimed, for the first time, to prepare extracts from the ice plant using different solvents and to incorporate them into phytosomes. Physicochemical characterization of these phytosomes, their antioxidant activity, as well as the quantification and in vitro release profile of their phenolic and flavonoid compounds were studied. Different extraction solvents were assayed, and Ethanol:Acetone (80:20) achieved a strong antioxidant activity (reaching ca. 71.16%), extracting 3200.3 mg of GAE/100 g and 761.7 mg of QE/100 g of phenolic and flavonoid compounds, respectively. The phytosomal formulation exhibited a mean particle size of 233.80 nm, a polydispersity index of 0.23, and a zeta potential of −27.27 mV. Furthermore, a high encapsulation efficiency (96.63%) of the extracts in the phytosomes was obtained. The in vitro release test indicated that the antioxidant activity was retained, reaching a maximum of 42%, accompanied by a release of 51% of the flavonoid content at the end of the 3 h assay, under the experimental conditions. These findings highlight the potential of phytosomes formulated with Mesembryanthemum crystallinum extract as a delivery system for antioxidant phytochemicals. Full article

Halophyte plants constitute vital resources for the advancement of sustainable agricultural practices in soils affected by salinity; however, the precise germination requirements for these species are still inadequately investigated. In this study, we examined how Salicornia europaea aggr., a succulent edible halophyte species, germinates under different genetic, environmental, and hormonal conditions such as gibberellic acid (GA₃), testing the effects of genotype, light exposure, and salinity stress on seed and early seedling development. Two genotypes (GR-1-BBKK-24.6196 and GR-1-BBKK-25.6212) were examined across a range of GA₃ (0, 250, 500 ppm), light intensity (40 and 80 μmol m⁻² s⁻¹), and salt concentrations (0 and 1% NaCl). At the seedling stage, four NaCl concentrations were used (0, 50, 100, 200 mM NaCl). Our data showed that S. europaea seeds do not exhibit dormancy—GA₃ treatment had no effect on germination success. Dark conditions and salt exposure both hindered germination, whereas the highest light intensity (80 μmol m⁻² s⁻¹) improved it considerably. Salt stress progressively slowed seedling growth. Seedling development was enhanced by 200 mM NaCl demonstrating inconsistency of the effect of salinity between the seed and seedling stages. Overall, our work demonstrates that the germination in S. europaea varies substantially between genotypes, with sufficient light and low salt being particularly important for maximizing seed germination, while 200 mM NaCl seems to promote seedling growth. Full article

Plants are frequently exposed to various abiotic stresses during their growth and development. S. portulacastrum possesses inherent tolerance to salinity and heavy metals, yet the underlying molecular mechanisms remain poorly understood. In this study, we performed a comprehensive analysis of S. portulacastrum by integrating full-length transcriptome sequencing and RNA sequencing (RNA-seq) under salt stress conditions. Transcriptome analysis identified 2839 and 1813 DEGs in leaves and 7328 and 754 DEGs in roots at 7 and 14 ds after NaCl treatment, respectively. Pathway enrichment analysis indicated that these DEGs were significantly enriched in pathways associated with Photosynthesis, plant hormone signal transduction, Linoleic acid metabolism, chlorophyll metabolism, and amino acid metabolism. Expression profiling showed that JAZ subfamily genes were significantly upregulated in both leaves and roots under salt and Cd stress. We cloned SpJAZ1, SpJAZ5, and SpJAZ7, and generated their overexpression lines in Arabidopsis. Physiological assays demonstrated that overexpression of SpJAZ1, SpJAZ5, and SpJAZ7 reduced hydrogen peroxide content by 29.07%, 20.62%, and 19.79%, respectively, and lowered the reduction in chlorophyll content (0.12, 0.15, and 0.17 μg/mL vs. 0.22 μg/mL). Meanwhile, proline content was increased in these lines (2.34, 2.08, and 2.05 μg/mL vs. 1.53 μg/mL), alongside enhancements in root length, lateral root number, and water content under salt stress. Importantly, these overexpression lines displayed a similar functional trend under Cd stress. Collectively, our results reveal potential crosstalk between the JA signaling pathway and stress mitigation pathways in S. portulacastrum in response to salt and Cd stresses. Full article

Rhizobia are a polyphyletic group of Proteobacteria comprising approximately 700 different species. Despite significant advancements in their taxonomy, evolutionary history, and ecological importance, substantial knowledge gaps remain regarding a detailed understanding of rhizobial biodiversity in a geographical context and the interest in studying and valorizing native rhizobial strains. This bibliometric study used data from the last four decades (1985–2025) to review the taxonomic and functional diversity of the documented novel taxa of rhizobia described from African ecosystems, as well as their valorization status as biofertilizers. It aims to discuss the interest in knowing, preserving, and valorizing native rhizobial resources in the global context of climate change and biodiversity erosion. The study revealed that the first African indigenous novel species of rhizobia was published in 1988, although research on rhizobia dates back to the 1950s in Africa. To date, ~63 species (approximately 9% of the total in the world) and two genera of rhizobia have been described using native isolates from 11 African countries, with substantial discoveries from the Succulent Karoo hotspot of biodiversity in South Africa. Approximately 51% of species are affiliated with Bradyrhizobium and Mesorhizobium, with Vachellia karroo and Senegalia spp. (formerly Acacia spp.) as their primary hosts. Most species-type strains (~89%) were found to be infective on legumes and are good candidates for biofertilizer development. However, there is a limited level of commercial valorization of indigenous isolates as inoculants, mainly because the production of biological intrants is still at the experimental stage in Africa. Interestingly, important breaking point discoveries have been made using native rhizobial strains from Africa, including the pioneering demonstration in 2001 that Burkholderia (beta-rhizobia) is a symbiotic genus with legumes. It also includes the discovery of stem-nodulating rhizobia and Nod factor-independent symbiotic processes in some rhizobia. Together, this review highlights the importance of native African rhizobial strains. This underscores the need to accelerate their agronomic valorization to better support the transition to more resilient and sustainable legume-based farming systems in African countries. Full article

Ruminant herbivores interact dynamically with their food resources, especially in deserts, where plant availability fluctuates sharply across seasons. We evaluated how seasonal food availability and the nutritional traits of preferred plants shape the diet and macronutrient niche of a desert mule deer (Odocoileus hemionus) population in the buffer zone of the Médanos de Samalayuca protected area, northern Mexico. From 2021 to 2022 we quantified seasonal food plant availability and characterized mule deer diet using microhistological fecal analysis and the nutrient content by right-angled mixture triangles. Mule deer diets were consistently low in diversity and dominated by grass, but preferred species shifted seasonally among shrubs, succulents, and grasses. Deer strongly selected some plant species that were scarce in the landscape, particularly during the cold-dry season. Preferred plants generally had high carbohydrate and variable protein contents, with the highest protein proportions in the temperate-dry season. Mixture triangles showed a narrow, carbohydrate-biased macronutrient niche, with the broadest range of nutrient mixtures in the temperate-dry season. Overall, our results support an opportunistic foraging strategy in which mule deer consume what is seasonally available while selectively using key plant species to maintain a relatively constant nutritional balance under limited and variable food resources. Full article

Background/Objectives: Plants of the Crassulaceae family have been utilized in traditional medicine because of their medicinal properties. Crassula capitella, an ornamental succulent plant, has not yet received significant attention from physiochemists or pharmacologists. The objective of this study was to investigate the in vitro phytochemical properties and biological activity of methanolic extracts obtained from the leaves (CCLE) and inflorescences (CCIE) of C. capitella. Methods: Phytochemical screening included GC/MS analysis. The in vitro investigation of biological properties includes the assessment of antibacterial activity, utilizing disk diffusion assays and measuring MIC and MBC values for Gram-positive and Gram-negative bacteria. Antioxidant properties were determined through IC50 values in DPPH and ABTS assays. Cytotoxicity properties were evaluated using the MTT assay in MCF-7 and HepG2 cells, along with an analysis of apoptosis gene expression. Additionally, the antidiabetic effects were examined through α-amylase or α-glucosidase inhibition assays. Results: GC/MS analysis revealed distinct differences. CCLE contained more terpenoids such as betulinaldehyde (30.53%) followed by lupeol (19%) and betulin (4.07%), whereas CCIE was rich in fatty acids. The TPC and TFC of CCIE (88.17 mg GAE/g and 57 mg QE/g) were significantly greater than those of CCLE. Compared with CCLE, CCIE exhibited greater antibacterial properties (MIC values of 6.25 µg/mL toward S. aureus), greater antioxidant properties (IC₅₀ values in the DPPH/ABTS assay), antitumor properties (IC₅₀ values of approximately 90–96 µg/mL), and antidiabetic properties (IC₅₀ values of 87–83 µg/mL in the α-amylase/α-glucosidase assay). Both bioactive extracts induced apoptosis in cancer cells by downregulating the expression of the tumorigenesis genes bcl-2 and bcl-xL. Conclusions: The findings provided the first evidence about the evaluated the potential antibacterial, antioxidant, anticancer, and antidiabetic activities of C. capitella, which is attributed to its robust chemical composition and position it as a compelling candidate for further in vivo and sub-clinical applications. Full article

Plantain (Musa paradisiaca L.) is a tropical monocotyledonous, succulent plant of the Musaceae family commonly grown for food in the tropical regions of the African, Asian, and South American continents, where its parts are also sought for ethnomedicinal purposes in the treatment of burns, inflammation, and diabetes, among others. In the present preliminary exploratory study, the ethanol extract of the underutilized Musa paradisiaca peel (MPE) was evaluated for its in vitro inhibitory effects on α-amylase and α-glucosidase, as well as its in vivo hypoglycemic activity and potential biochemical toxicity. MPE (100, 200, 400 mg/kg) was orally administered to normal experimental rats for 30 days, following which the lipid profile, antioxidant status, and serum/tissue indices of hepatic, renal, and cardiac functions were evaluated. MPE produced significant inhibition (p < 0.05) of α-amylase (37%) and α-glucosidase (46%) at 120 µg/mL in vitro. The effect was lower than that of acarbose (IC₅₀ = 44.4 ± 1.14 and 15.60 ± 0.01 µg/mL, respectively). A modest blood glucose-lowering effect of MPE was observed at the highest tested dose (400 mg/kg) following subacute oral administration. During this treatment period, no biochemical alterations of toxicological importance were caused by MPE, as the organ–body weight ratio and serum/tissue indicators of organ function/damage were not adversely altered. In conclusion, MPE demonstrated inhibitory activity against both α-amylase and α-glucosidase, which may contribute to its potential hypoglycemic effects. Additionally, the findings indicate that the peel extract is non-toxic in rats following sub-acute administration at doses up to 400 mg/kg body weight. Further studies involving diabetic models and chronic exposure will substantiate and extend these preliminary observations. Full article

Background/Objectives: Coleus aromaticus (Lamiaceae), also known as Cuban oregano or Indian borage, is a semi-succulent perennial species widely used in traditional medicine for its therapeutic and nutritional properties. While its essential oils and aromatic fraction have been extensively investigated, the characterization of its non-volatile metabolites remains limited. The aim of this study was to explore the chemical composition of fresh leaves with a focus on the non-volatile fraction. Methods: Fresh leaves of C. aromaticus were cryogenically treated with liquid nitrogen, ground, and subjected to three different extraction procedures: hydroalcoholic maceration, ethyl acetate maceration, and liquid–liquid partitioning to obtain a dichloromethane organic phase and a hydroalcoholic phase. Extracts and fractions were analyzed by HPTLC and HPLC for metabolic profiling. In addition, the Bligh–Dyer method was applied to separate polar and non-polar metabolites, which were subsequently characterized using NMR spectroscopy. Results: Chromatographic analyses highlighted the occurrence and distribution of organic acids, polyphenols (notably flavonoids), and proteinogenic amino acids. Spectroscopic data confirmed the presence of diverse polar and non-polar metabolites, providing a more detailed chemical fingerprint of C. aromaticus. This integrated approach broadened the phytochemical profile of the species beyond the well-documented essential oils. Conclusions: The results contribute to a better understanding of the non-volatile metabolites of C. aromaticus, offering novel insights into its chemical diversity. These findings highlight the potential of this plant as a valuable source of bioactive compounds, supporting its future application in nutraceutical and pharmaceutical research. Full article

The genus Kalanchoe (Crassulaceae) comprises approximately 125 species of succulents distributed across Madagascar, Africa, Arabia, Australia, Southeast Asia, and tropical America. Traditionally regarded as “miracle plants”, Kalanchoe species are employed for treating inflammatory, infectious, metabolic, and cardiovascular conditions; this is associated with their abundant content of polyphenols, including phenolic acids and flavonoids such as quercetin, kaempferol, luteolin, rutin, and patuletin. However, robust clinical evidence remains limited. This review integrates pharmacological and bioinformatic perspectives by analyzing more than 70 studies published since 2000 on 15 species, including Bryophyllum. As an in silico complement, the genome of Kalanchoe fedtschenkoi was used to predict genes (AUGUSTUS), perform homology searches against Arabidopsis thaliana, and model three key enzymes: CHS, CYP90, and VEP1. The AlphaFold2/ColabFold models showed conserved catalytic motifs, and molecular docking with representative ligands supported the plausibility of biosynthetic pathways for flavonoids, brassinosteroids, and bufadienolides. The available evidence highlights chemopreventive, antibacterial, anti-inflammatory, antiviral, antioxidant, and cytotoxic activities, primarily associated with flavonoids and bufadienolides. Significant gaps remain, such as the lack of gene–metabolite correlations and the absence of standardized clinical trials. Overall, Kalanchoe represents a promising model that requires multi-omics approaches to enhance its phytopharmaceutical potential. Full article

Herbaceous plant species form the plant synusia of desert ecosystems and play crucial roles in wind-breaking, sand-fixing, and the maintenance of oasis ecosystem stability. This study focused on the leguminous species Medicago sativa and Astragalus laxmannii and the gramineous species Elymus dahuricus, Agropyron desertorum, Agropyron mongolicum and Agropyron cristatum. These are the plants commonly used for ecological restoration in the desertification regions of northwestern China. We conducted a pot experiment with six soil moisture gradients (15% [ck], 12%, 10%, 8%, 6%, and 4%) to simulate drought conditions. We studied how varying degrees of drought stress influenced growth, functional traits and drought resistance, aiming to elucidate the mechanisms by which plants respond to drought. The study indicated that: (1) Drought stress directly and indirectly reduced both the seedling emergence rate and plant height. As soil water content decreased, the seedling emergence rate and plant height declined across all species. (2) The leaves and roots of the plants adopted different strategies to cope with drought stress. As soil water content decreased, leaf water content, leaf succulence, and leaf tissue density increased, while specific leaf area and leaf biomass decreased. Additionally, the root-shoot ratio increased, whereas root biomass, total root length, root surface area, and root volume all decreased. (3) Root system adaptation is the key factor influencing the drought resistance of plants. Drought resistance varied among the six species. Medicago sativa, Elymus dahuricus, and Agropyron cristatum exhibited stronger water retention and more stable growth under drought stress, making them better suited for ecological restoration in arid regions. Our study elucidates differentiation strategies for coping with drought stress and offers essential parameters and theoretical support for species selection and rational assemblage in the ecological restoration of arid regions. Full article

Background: A significant concern today is the dependence on low-quality water sources, such as saline water, in hydroponic systems, especially due to the scarcity of freshwater. Halophytes and salt-tolerant species have emerged as viable candidates for cultivation in saline hydroponics. However, their agronomic performance and physiological responses within hydroponic systems require further investigation. Objectives: This research aims to explore the potential of edible halophytes grown in saline nutrient solutions within hydroponic systems within salt-tolerant ranges, focusing on their metabolic profiles and mineral accumulation. Methods: Plantago coronopus (L.), Portulaca oleracea (L.), and Salsola komarovii (Iljin) were grown in walk-in controlled environment chambers in deep water culture hydroponic systems, at 0, 50, 100, 150, and 200 mM·L⁻¹ NaCl salinity; 16h, 250 µmol m⁻² s⁻¹, and wide LED spectrum lighting was maintained. Results: A significant decrease in organic acids, and fresh and dry weight under high saltinity was observed in Plantago coronopus and Portulaca oleracea, but not in Salsola komarovii. An increase in hexoses, particularly glucose, violaxanthin and β-carotene, P⁺ and Zn²⁺, along with a decrease in lutein, K⁺ and Ca²⁺ levels across salinity levels from 0 to 200 mM NaCl was observed in all treated halophytes. Increased salinity did not significantly affect total protein accumulation. Conclusions: These findings reveal that different shifts in osmolytes, mineral elements, and biomass accumulation in tested halophytes indicate species-dependent osmotic adjustment to increased salinity and may be attributed to the morphological differences among halophytic grasses, dicot halophytes, and those with succulent leaves or stems. The PCA score scatterplot results excluded the response of Plantago coronopus from other tested halophytes; also, it demonstrated that Portulaca oleracea was more sensitive to the hydroponic solution salinity compared to Salsola komarovii and Plantago coronopus. Full article

Cacti of the genera Opuntia and Nopalea exhibit morphophysiological and biochemical characteristics that favor their adaptation to semiarid environments, such as crassulacean acid metabolism (CAM) and cladode succulence. These strategies reduce water loss and allow the maintenance of photosynthesis under stress conditions. In this study, we evaluated the seasonal variation in the physiological and photochemical responses of forage cactus clones grown in semiarid environments, considering the rainy, dry, and transition seasons. The net photosynthetic rate (P_n) and chlorophyll fluorescence parameters varied significantly as a function of water availability and microclimatic conditions. We found higher CO₂ assimilation rates during the rainy season, while the dry season resulted in a strong impairment of photosynthetic activity, with reductions of 65% in stomatal conductance, 37% in transpiration, 20% in maximum quantum efficiency of photosystem II, and 19% in the electron transport rate. Furthermore, during these periods, we observed an increase in initial fluorescence and non-photochemical dissipation, demonstrating the activation of photoprotective mechanisms against excess light energy. During the transition seasons, the cacti exhibited rapid adjustments in gas exchange and energy dissipation, indicating the adaptive plasticity of CAM pathway. The MIU (Nopalea cochenillifera (L.) Salm-Dyck), OEM (Opuntia stricta (Haw.) Haw.), and IPA (Nopalea cochenillifera (L.) Salm-Dyck) clones demonstrated greater resilience, maintaining greater stability in P_n, instantaneous water use efficiency, and photochemical parameters during the drought. In contrast, the OEA (Opuntia undulata Griffiths) clone showed high sensitivity to water and heat stress, with marked reductions in physiological and photochemical performance. In summary, the photosynthetic efficiency and chlorophyll fluorescence of CAM plants result from the interaction between water availability, air temperature, radiation, and genotypic traits. This study provides a new scientific basis for exploring the effects of environmental conditions on the carbon and biochemical metabolism of cacti grown in a semiarid environment. Full article

This investigation focuses on urban ornamental greenery, a field of research that is still relatively unexplored in Italy but is becoming increasingly important both from a botanical point of view and in relation to sustainable land management and planning. A checklist of the ornamental vascular flora of Basilicata (Southern Italy) is reported here. A total of 281 taxa were recorded, including trees, shrubs, herbaceous plants, and succulents cultivated in parks, gardens, and street trees. Such taxa (including 265 species s. str., 6 varieties, 5 subspecies, and 11 forms) belong to 201 genera, included in 94 families, among which the most represented are Rosaceae, Oleaceae, Asteraceae, Pinaceae, Cupressaceae, and Fabaceae. Phanerophytes represent the dominant growth form, and the chorological spectrum is composed mainly of Asian and American taxa. Taxa from subtropical and tropical biomes also showed a significant presence. This study highlighted the clear prevalence in the Basilicata ornamental flora of alien taxa (approximately 80%, of which 21% are naturalized aliens) compared to native ones, which is a phenomenon that is unfortunately widespread and observed worldwide. Full article

As freshwater resources become increasingly scarce, seawater and brackish water represent alternative sources for crop irrigation, particularly in systems such as saltwater aquaponics. Red orache (Atriplex hortensis var. rubra) is a halophyte with high antioxidant content but also accumulates antinutrients like nitrate (NO₃⁻) and oxalate. Oxalate helps plants cope with salinity stress but can cause health issues in humans. This study examined the growth of red orache baby greens in saline and nitrogen-limited hydroponic solutions to assess its adaptability and nutritional quality, focusing on the impact of salinity and reduced nitrogen on antinutrient levels. Four nutrient solutions differing in NaCl (0 or 428 mM) and NO₃⁻ (10 or 1 mM) were tested. Salinity significantly reduced red orache yield (by 75.5%), pigment levels, antioxidants, and nutrient uptake, while increasing leaf Na and oxalate concentration, ethylene production, and succulence. Salinity decreased NO₃⁻ concentration and oxalate oxidase (OxO) activity but boosted total ascorbic acid and oxalate accumulation. Low NO₃⁻ mildly reduced yield (by 25.7%), leaf area, and NO₃⁻ concentration in leaves, but had no effect on leaf moisture content, succulence, antioxidant capacity, and the concentration of antioxidants, pigments, and total oxalate. In addition, low NO₃⁻ increased OxO activity, only under non-saline conditions. The high salinity typical of aquaculture effluents strongly reduced red orache baby greens yield and quality to a greater extent than low NO₃⁻ levels. Both salinity and low NO₃⁻ reduced NO₃⁻ concentration in leaves, while salinity increased oxalate concentration, probably due to the reduced activity of OxO. Full article

Kalanchoe pinnata, commonly known as the “miracle plant” or “life plant”, is a succulent species traditionally used for various health conditions. Recent research investigations have intensified interest in this species due to its diverse repertoire of bioactive constituents, including flavonoids, alkaloids, triterpenes, and glycosides. These compounds have been associated with multiple therapeutic effects, notably antioxidant, anti-inflammatory, and antidiabetic activities. Although several studies have highlighted the positive effects of the extracts of K. pinnata on key factors contributing to the pathophysiology and complications of diabetes mellitus, a systematic overview focusing on the use of these extracts and their bioactive constituents in the management of the disease is lacking. This literature review summarizes the phytochemical composition, traditional uses, and recent scientific data supporting the antidiabetic potential of K. pinnata, with a particular focus on its effects on glycemic control, as well as inflammatory and oxidative homeostasis, toxicity, safety, and potential clinical implications. The phytochemical constituents discussed include quercetin, kaempferol, apigenin, epigallocatechin gallate (EGCG), avicularin, and bufadienolides, along with a presentation of representative structures. The review also covers the potential mechanisms of action in diabetes mellitus. The survey of available literature highlights the effects of K. pinnata on indices of diabetes mellitus, including enhancing insulin sensitivity, mitigating oxidative stress and inflammation, lowering blood glucose levels, and the potential adverse effects. These results point to the promising prospect for K. pinnata use in the management of diabetes mellitus and its associated complications, while underscoring the need for more rigorous investigations, including well-controlled clinical trials. Full article