Search Results (118)

The espinal agroforestry system is a valuable grazing resource for sheep and cattle in the Mediterranean region of central Chile. It is characterized by a woody stratum dominated by Vachellia caven and an herbaceous grassland stratum that together provide important ecological services. Despite its relevance for extensive livestock production, ongoing land-use change threatens the integrity of the espinal agroforestry system, underscoring the need for sustainable management strategies to enhance productivity. This study assessed the long-term impacts of improved management practices in a representative espinal agroforestry system, including annual fertilization, supplementary cereal crop integration, and progressive increases in stocking rate, on plant diversity and soil carbon storage in Cauquenes, Maule Region, Chile (35°58′ S, 72°17′ W), during 2014–2019. A production system was established on 10 ha of espinal grassland, complemented by 1 ha of supplementary crop rotation (oat–purple vetch intercropping and triticale). Due to the scale of the system, a single experimental unit was used; however, multiple sampling areas were evaluated over time to assess the botanical composition, forage yield, and soil carbon. Grasslands were annually fertilized with phosphorus, potassium, and boron. The forage yield in spring ranged from 2 to 4 t dry matter ha⁻¹ year⁻¹ over six years, with strong interannual variability driven by rainfall. The stocking rate increased progressively from 2 to 8 sheep ha⁻¹ and lamb live weight from 80 to 370 kg ha⁻¹ over six-years. The grassland botanical composition shifted markedly, with increased abundance of annual legumes (Trifolium subterraneum, Medicago polymorpha) and Leontodon leysseri. Supplementary crops yielded between 6.0 and 10.5 t DM ha⁻¹, while soil organic carbon increased from 1.6% to 2.2%. These results demonstrate that sustainable intensification of the espinal system can enhance productivity while maintaining environmental sustainability. Full article

Against the backdrop of urbanization and global warming, reducing carbon emissions and achieving carbon neutrality have emerged as focal points in current urban ecological research. Urban green infrastructure (UGI) serves as the primary natural carbon sink within cities; therefore, investigating and optimizing its carbon sequestration services is a crucial step toward realizing carbon neutrality and fostering sustainable urban development. As the core components of urban ecosystems, urban parks provide essential ecosystem services that play a pivotal role in expanding carbon sinks, facilitating energy conservation and emission reduction, and enhancing urban climate resilience. This paper takes 20 parks in Linyi City’s central urban area as examples, systematically quantifies the carbon sequestration effect of urban parks in the central urban area of Linyi City from 2019 to 2024 using methods such as the Carnegie–Ames–Stanford Approach (CASA) and the gravity model, and quantitatively evaluates the equity of urban residents’ access to these services. The study shows that the overall annual average carbon sequestration rate of urban parks in Linyi City’s central area over nearly six years ranges from 202.02 gC·m⁻²·a⁻¹ to 279.31 gC·m⁻²·a⁻¹, while individual park annual averages range from 171.29 to 332.76 gC·m⁻²·a⁻¹, falling within the normal range for cities at the same latitude; in terms of vegetation carbon sequestration capacity, woody plant communities dominate in this region, with annual average carbon sequestration rates approximately 10% higher than those dominated by herbaceous vegetation. In terms of intrinsic activity performance of carbon sequestration, overall, woody-dominated plant communities exhibit greater stability and resilience under extreme weather conditions, experiencing smaller impacts on ecological functions but longer recovery cycles to peak levels. Regarding equity in the supply and demand of ecosystem services, the Gini coefficient in the study area is 0.59, indicating an extremely imbalanced state; within the same park service range, up to 60% of residents do not benefit from carbon sequestration ecosystem services. The urban supply–demand mismatch reveals that approximately 20% of the population resides in high-demand–low-supply areas, experiencing extreme ecological deprivation; only about 13% of the population falls into the high-demand–high-supply category, this group being the high-benefit recipients who enjoy both spatial convenience and high-quality ecological welfare. The theoretical implications for urban green space planning: according to the results, merely expanding park green space area to increase per capita access is myopic and inadvisable in central urban park planning. Instead, greater emphasis should be placed on enhancing ecological service levels beyond basic area requirements, comprehensively improving vegetation quality and ecosystem service capacity of parks. In old urban areas constrained by land use, the hierarchical structure of vegetation should be strengthened, and micro green spaces should have enhanced ecological service capabilities to improve residents’ access rights through higher service quality. In newly developed urban areas, planning should balance quantity and quality to serve more people and alleviate urban ecological pressures. Overall, by quantitatively assessing the carbon sequestration capacity and the socio-spatial equity of ecosystem services provided by urban parks in Linyi City, this study offers robust empirical evidence and methodological tools for sustainable urban planning, ultimately fostering the sustainable development of urban ecosystems. Full article

Leaf senescence in perennial species constitutes a highly orchestrated developmental phase that differs fundamentally from the obligate monocarpic senescence of annual plants. While individual organs undergo programmed senescence, prerennial organisms maintain longevity across multiple growing seasons through a sophisticated interplay between endogenous programs and exogenous cues. This review provides a systematic synthesis of the regulatory mechanisms governing leaf senescence in herbaceous perennials (Lolium perenne and Festuca arundinacea) and woody perennials (Populus, Pinus, and Agave). We highlight a multi-layered regulatory landscape, encompassing divergent and conserved pathways in transcriptional orchestration, hormonal crosstalk, metabolic reprogramming, and telomere maintenance. Specific emphasis is placed on how these mechanisms allow for tissue-specific and seasonal adaptation, such as the integration of dormancy signals in woody taxa versus stress-plasticity in perennial grasses. By elucidating these complex frameworks, this review not only advances our fundamental understanding of plant life-span regulation but also provides a theoretical foundation for the molecular breeding of delayed senescence germplasm, offering transformative potential for enhancing agricultural productivity and ecological resilience. Full article

Acmella oleracea (L.) R.K. Jansen is an herbaceous plant cultivated globally as an annual ornamental species. While conventional propagation methods exist, the lack of a standardized in vitro protocol limits research and industrial applications that require genetically and morphologically uniform plant material. In this study, in vitro cultures of A. oleracea were established via seed germination. Well-developed in vitro shoots were dissected into individual nodal segments to serve as explants. Multiple media were evaluated for regeneration and growth, including full-, half, and quarter-strength Murashige and Skoog (MS) media, as well as full- and half-strength McCown Woody Plant media. Two carbohydrate sources, saccharose and glucose, were tested at concentrations of 1%, 2%, and 3% (w/v) in the multiplication medium. Subsequently, the effects of different cytokinins were assessed at concentrations of 4.4 µM and 13.2 µM. The findings demonstrated that 13.2 µM meta-Topolin with 3% saccharose, or 13.2 µM Benzyladenine with 2% glucose was most beneficial for shoot multiplication of A. oleracea. The multiplied shoots were rooted in vitro within 13 days, then potted and acclimatized within 8 days. This protocol facilitates future industrial applications of A. oleracea, particularly in the cosmetics sector, where the use of standardized biomass is essential. Full article

Landfills represent areas of pronounced anthropogenic disturbance, with substantial impacts on local vegetation. The composition and structure of plant communities serve as indicators of eco-system alteration and may function as reservoirs of species with potential utility in ecological restoration. This study provides the first detailed assessment of vegetation structure on a closed MSW landfill in Kokshetau (Akmola Region, northern Kazakhstan; semi-arid steppe/forest-steppe setting) and demonstrates an integrative, restoration-oriented monitoring and target-setting workflow, including a localized phytoremediation screening framework integrating field performance, ecological indicator values, and literature-based functional traits, with a risk/governance filter. A total of 76 vascular plant species were recorded during the field survey, predominantly comprising annual herbaceous taxa adapted to highly disturbed environments. The families Asteraceae and Poaceae were the most species-rich, while Chenopodiaceae and Brassicaceae were also notably represented. Meadow-steppe species constituted the majority (45.5%) of the phytosociological spectrum. Multivariate ecological and statistical analyses revealed that community composition was primarily influenced by the degree of disturbance (p = 0.016), rather than soil pH, with Cannabis sativa and Bassia scoparia emerging as key indicators of less disturbed sectors, contrasting with actively disturbed dumping areas. Consequently, restoration efforts should prioritize mesophytic species adapted to open, sunlit habitats and capable of establishing on slightly alkaline soils, while accounting for site-specific constraints to support long-term vegetation recovery. Notably, Artemisia absinthium and Bassia scoparia were identified as candidate taxa for phytoremediation-oriented restoration, based on their in situ ecological performance and literature-reported traits, albeit with limitations due to allergenic pollen and invasive tendencies, respectively. These findings support phytoremediation strategy design on disturbed landscapes by emphasizing regionally adapted species selection that balances ecological suitability with potential ecological risks. Full article

Leucas nubica Benth. (Lamiaceae) is an annual herbaceous plant, native to east and northeast tropical Africa. The whole plant is renowned for the treatment of jaundice. The present study aimed at an in-depth phytochemical profiling and evaluation of in vitro antioxidant and enzyme inhibitory potential of methanol–aqueous extract from L. nubica aerial parts. The liquid chromatography–high-resolution mass spectrometry (LC-HRMS) experiment revealed more than 70 secondary metabolites, including carboxylic and phenolic acids, phenylethanoid, iridoid, and lignan glycosides, and flavonoids. The L. nubica extract profile was dominated by the phenylethanoid glycoside verbascoside. All annotated compounds are reported for the first time in the species. The extract actively scavenged DPPH and ABTS radicals (38.8 ± 0.1 and 36.8 ± 0.4 mg TE/g) and showed high CUPRAC (71.1 ± 1.1 mg TE/g) and moderate FRAP (44.9 ± 2.6 mg TE/g) reducing power. The L. nubica extract exhibited high inhibition towards acetylcholinesterase (2.23 ± 0.02 mg GALAE/g), butyrylcholinesterase (2.38 ± 0.04 mg GALAE/g), and tyrosinase (60.7 ± 0.6 mg KAE/g). The obtained results highlight L. nubica extract as a rich source of phenylethanoid glycosides and flavonoids with significant bioactivity and shed light into the phytochemical composition and pharmacological potential of the plant. Full article

Invasions by alien plants are major global drivers of ecosystem changes and loss of biodiversity. Guangxi is an ecological barrier in southern China that is increasingly being affected by invasive alien plant species. We comprehensively reviewed the literature, compiling and analyzing the long-term changes in species composition, native range, life forms, municipal-scale patterns, and correlates of invasive alien plant richness in Guangxi at three time points (1973, 2010, and 2023). Over the 50-year period, the number of invasive alien plant species markedly increased from 31 species in 1973 to 84 in 2010 and 158 in 2023; the number of families, genera, and species increased 2.05-, 3.75-, and 5.10-fold, respectively. Species native to North America consistently dominated the invasive flora, followed by those native to Africa. The number of species native to South America and Asia increased in the records from 2010 to 2023. Annual herbaceous plants accounted for the largest proportion of invasive species throughout the study period and showed the largest absolute increase in species number. However, no substantial temporal shifts in the overall life-form composition were detected. At the municipal scale, the invasive alien plant richness exhibited pronounced spatial heterogeneity. The invasive alien plant richness was highest in Guilin and Baise in 1973, in Guilin in 2023, followed by Nanning and Baise. Correlation analyses based on 2023 data revealed a significant positive association between invasive alien plant richness and tourism intensity, whereas relationships between population size, gross domestic product, and climatic variables were weak or nonsignificant. Overall, our results document the continued expansion and the spatial differentiation of invasive alien plants in Guangxi over the 50-year period of 1973–2023. These patterns primarily reflect the accumulation in the number of recorded invasive species under a consistent classification framework and should be interpreted with caution given the potential variation in survey effort among periods and cities. The results provide a descriptive baseline for the provincial-scale monitoring, risk assessment, and management of invasive alien plants. Full article

The genus Dysosma, a group of perennial herbaceous plants with significant medicinal value and a relatively narrow ecological niche, is potentially at risk due to the combined pressures of habitat degradation and climate change. As their habitats continue to degrade, all species of this genus have been included in the National Key Protected Wild Plants List (Category II). Investigating the impacts of climate change on the distribution of Dysosma resources is vital for their sustainable utilization. In this study, the potential distribution dynamics of seven Dysosma species under current and three future climate scenarios (SSP126, SSP245, SSP585) were quantified using 534 occurrence points and 25 environmental variables in a MaxEnt model, accompanied by the ecological niche overlap index (Schoener’s D), dynamic metrics (relative change rate [RCR], change intensity [CI], stability index [SI], spatial displacement rate [SDR]), and centroid migration analysis. The results indicated that (1) areas of high habitat suitability were consistently concentrated in the mountainous and hilly regions of southwestern Guizhou, Chongqing, and Hubei, with the minimum temperature of the coldest month (Bio6) and the mean diurnal temperature range (Bio2) being identified as the primary driving factors. (2) The future suitable habitat areas remained highly stable overall (SI > 97.89%), though dynamic changes varied across scenarios. Under SSP126, only slight fluctuations were observed, with an average CI of approximately 3.78% and RCR ranging from −0.46% to 1.97%. Under the SSP245 scenario, suitable habitat areas showed a continuous, slight expansion (RCR = 0.45% to 1.54%), whereas under the high-emission SSP585 scenario, a typical “mid-term expansion–late-term contraction” pattern was observed, with RCR shifting from positive (1.32%, 1.44%) to negative (−0.92%). The SI reached its lowest value of 97.89% in the late term, and the spatial displacement rate increased, signaling a reorganization of the distribution pattern. (3) High ecological niche differentiation was observed within the genus, with the highest overlap index being only 0.562, and approximately one-third of species pairs exhibiting completely non-overlapping niches. (4) Dysosma tsayuensis, a niche-specialist species, exhibited a distribution that was highly dependent on the annual mean ultraviolet-B radiation (UVB, contribution rate 52.9%), displaying an adaptation strategy markedly different from that of conservative species. (5) Centroid analysis indicated that, although the overall centroid remained stable in Guizhou, the presence of niche-specialist species under the high-emission SSP585 scenario resulted in migration paths opposite to those observed under other scenarios. The findings reveal the potential vulnerability and differential response patterns of Dysosma species under rapid climate warming, thereby providing a scientific basis for targeted conservation, in situ and ex situ conservation strategies, and population restoration. Full article

Okra (Abelmoschus esculentus L. Moench) is an annual herbaceous plant belonging to the Malvaceae family. Its medicinal properties and edible value have attracted widespread scientific attention, yet its systematic taxonomy, evolution, and photosynthetic mechanisms warrant further investigation. Chloroplasts, specialized semi-autonomous organelles within green plants, possess their own genetic material and serve as an excellent source of genetic information. This study employed Illumina high-throughput sequencing technology to sequence the complete chloroplast genome of the cultivar ‘Gan Kui No. 1’. The complete chloroplast genome was determined to be 163,121 bp in length, with A, C, G, T, and GC nucleotides accounting for 31.24%, 18.71%, 18.02%, 32.02%, and 36.74% of the total, respectively. It exhibits a classic tetrad structure, comprising one large single-copy region (88,071 bp), one small single-copy region (19,032 bp), and one pair of inverted repeat regions (28,009 bp). The entire chloroplast genome contains 132 annotated genes, including 37 tRNA genes, 8 rRNA genes, 87 mRNA genes, and 0 pseudogenes. A phylogenetic tree constructed using 20 species, including Abelmoschus esculentus, revealed a clear phylogenetic relationship between the genus Hibiscus and Abelmoschus esculentus. The complete gene sequences have been uploaded to the NCBI database (accession number PX590535). This study provides insights into understanding the evolutionary relationships of Abelmoschus esculentus and refining its taxonomy, laying a theoretical foundation for subsequent research on the Abelmoschus esculentus chloroplast genome. Full article

Summer savory (Satureja hortensis L.) is an annual herbaceous plant belonging to the Lamiaceae family and widely used as a culinary spice. The present research aimed to investigate the physicochemical characteristics, phenolic profile, antioxidant potential, and antimicrobial activity of ten summer savory samples (dried leaves and flowers) grown in different regions of Bulgaria. The physicochemical analyses of the dried plant material demonstrated that the ash content varied from 19.51 to 26.92%, proteins from 16.25 to 22.78%, and carbohydrates from 5.37 to 10.01%. The values of the total phenolic content (TPC) ranged from 1.10 to 4.83 mg GAE/g dw (aqueous savory extracts—ASE) and from 3.98 to 9.54 mg GAE/g dw (methanolic savory extracts—MSE). The values of the total flavonoid content (TFC) were from 0.08 to 0.29 mg QE/g dw (ASE) and from 0.73 to 1.23 mg QE/g dw (MSE). The investigated samples exhibited significant antioxidant activity, with values determined by the DPPH method varying between 35.01 and 59.93 mM TE/g dw (ASE) and between 51.75 and 91.85 mM TE/g dw (MSE). The values by the FRAP method ranged from 74.49 to 134.85 µmol Fe²⁺/g dw (ASE) and from 108.20 to 215.48 µmol Fe²⁺/g dw (MSE). The high-performance liquid chromatography (HPLC) analysis showed that rosmarinic acid was predominant in all tested samples (3.54–5.90 mg/g dw), whereas ferulic, caffeic and p-coumaric acids were detected in trace amounts. The HPLC analysis of organic acids revealed that ascorbic acid was present in higher concentration in all samples (0.35–0.98 mg/g dw) compared to malic acid, which was found in trace amounts. The antimicrobial activity test demonstrated that methanolic savory extracts showed moderate to high inhibitory activity against most of the microorganisms used (most pronounced against Staphylococcus aureus 6538P, with diameters of the inhibition zones from 20 to 30 mm), while aqueous savory extracts exhibited antifungal rather than antibacterial activity. Based on the results obtained, we can conclude that savory is a plant with potential for use in the pharmaceutical and agricultural sectors, in addition to its culinary applications. Full article

Pepper (Capsicum annuum L.), an annual herbaceous plant in the Solanaceae family, possesses significant edible and medicinal value. Studies have shown that there are significant differences in the plant chemical constituents and antioxidant activity among different colored peppers, but there have been fewer studies on the relationship between pigment content, plant chemical constituents and antioxidant activity in peppers. Therefore, this study divided twenty pepper accessions of pepper materials into four categories based on color changes and measured the bioactive compounds, pigment content and antioxidant activity of these four types of peppers at different maturity stages and conducted correlation analysis and principal component analysis (PCA). The results showed that yellow pepper cultivars had higher levels of vitamin C (Vc), and Class IV (purple-to-red transitioning pepper cultivars) had higher total phenolic content (TPC), total flavonoid content (TFC), and anthocyanin content in the early fruit stage. Correlation analysis showed that Class IV (purple-to-red transitioning pepper cultivars) had higher levels of bioactive compounds and antioxidant capacity. The antioxidant content in immature fruits was high, but decreased as the fruits matured. This study focuses on pepper-derived bioactive compounds and their antioxidant activity, providing a scientific basis for developing natural antioxidant products, expanding pepper resource utilization, and guiding pepper variety selection and cultivation management. Full article

Ongoing urbanization, biodiversity decline, and intensifying climate change increasingly challenge the sustainability of urban green spaces (UGS) dominated by conventional, intensively maintained lawns. Although widespread across cities worldwide, lawns are criticised for their low biodiversity value and high resource demands. This paper explores nature-based solutions (NBS) as viable alternatives for enhancing resilience and multifunctionality of urban lawns. It conceptualizes lawns as intertwined ecological, design, and socio-cultural systems, and evaluates strategies for their transformation. Building on case studies from ten Eurasian cities, a narrative literature review, and the authors’ inter- and transdisciplinary research experience, this study develops a typology of NBS alternatives, including urban species-rich meadows, semi-natural grasslands, naturalistic herbaceous perennial plantings, mixed-vegetation groundcovers, edible lawns, pictorial (annual) meadows, and rewilded lawns. Key interventions involve reduced mowing, multifunctional green spaces, adaptive management, and community engagement. Findings demonstrate that these approaches enhance biodiversity, ecosystem services, and climate resilience, but their success depends on local ecological conditions, landscape design, and public perceptions of urban nature. Alternative lawn designs and maintenance practices should employ native, drought- and trampling-resistant plants and context-sensitive design configurations while respecting cultural traditions of urban greening and fostering social acceptance. The paper suggests practical recommendations and directions for future research. Full article

Much focus is being dedicated to the development of innovative technologies for producing biodegradable polymers from plant biomass. It is proposed that annual and perennial herbaceous plants, such as miscanthus, be used as promising sources of cellulose. The component composition of miscanthus allows us to consider it as a raw material for obtaining cellulose. This paper proposes methods for cooking miscanthus lignocellulose raw materials, which allow sulfate cellulose to be obtained with a high yield (up to 52%). In the process of obtaining chemical–thermomechanical pulp, the product yield is 71%. The possibility of replacing unbleached sulfate pulp with a semi-finished product from miscanthus for paper production is considered. For all types of raw materials obtained, acceptable paper-forming properties are observed. The best strength and deformation properties are obtained for sulfate cellulose. The addition of this cellulose to the composition of waste paper fluting significantly increases the sheet density, elasticity, and energy capacity without losing tensile strength. Using miscanthus raw materials along with waste paper of grade MS 5B makes it possible to make a composite product. The resulting products have optimal mechanical properties for creating the middle layer of corrugated cardboard. Miscanthus cellulose can be considered a promising raw material for enhancing waste paper fluting. Altering the system composition utilizing miscanthus and waste paper enables a broad modification of the mechanical and optical qualities of the resultant paper. The recommended concentration of miscanthus fraction in waste paper fluting is 30%. Full article

Broccoli (Brassica oleracea L. var. italica) is a biennial or annual herbaceous plant belonging to the species Brassica oleracea in the genus Brassica of the Cruciferae family. The green flower curd serves as the primary edible organ, with its development and preservation critically determining broccoli yield and quality. Given that these processes are regulated by flowering time, understanding the mechanisms underlying floral transition is essential for enhancing broccoli yield and quality. This study aimed to identify the MADS-box family in broccoli and to investigate the function of the BoAGL8 gene in floral induction. We identified a total of 176 MADS-box genes, of which 54 genes were up-regulated and 50 genes were down-regulated under low-temperature treatment. Notably, the expression of BoAGL8 was up-regulated by 6.70-fold under low-temperature induction, prompting us to select and clone this gene for further analysis. Tissue-specific expression profiling further revealed that BoAGL8 is expressed at relatively high level in both mature and young leaves. After 15 days of low-temperature treatment, BoAGL8 expression in shoot tip was significantly upregulated compared to untreated controls. Subcellular localization analysis showed that BoAGL8 protein was located to the nucleus. Ectopic over-expression of BoAGL8 in Arabidopsis exhibited accelerated bolting and flowering, reduced rosette leaf number, and increased seed yield per plant compared to wild-type plants. Furthermore, compared to wild-type controls, transgenic lines exhibited upregulated expression of AtFT, AtAP1 and AtSEP3, alongside downregulation of SVP expression. The above results indicate that BoAGL8 may play a key regulatory role in the process of floral organ development in broccoli, providing an important theoretical basis for future research on flowering time regulation and breeding in broccoli. Full article

The content and stoichiometric ratios of plant biogenic elements are key indicators for understanding plants’ ecological traits and their responses to environmental changes. However, it remains unclear how wetland herbaceous plants allocate these biogenic elements and how they relate to soil conditions. This study examines the variations in carbon (C), nitrogen (N), and phosphorus (P) stoichiometry across different organs and life forms, and their response to soil factors in Yellow River Delta wetlands. We analyzed the stoichiometric characteristics of 44 herbaceous species (17 annuals and 27 perennials) and their organs (leaves and stems). The results showed that annual plants show higher N and P but lower C content compared to perennials, indicating distinct life history strategies. In plant organs, leaves exhibited higher C, N, and P concentrations than stems, reflecting functional adaptation. Notably, random forest analysis identified stem C content as a key indicator for life history strategy differentiation. Furthermore, soil factors directly influenced organ-level stoichiometry but showed limited effects across life forms. The plants demonstrated P limitation with high sensitivity to soil P availability. This study provides new insights into organ-specific nutrient allocation strategies in wetland plants and offers valuable guidance for coastal wetland conservation. Full article