Search Results (524)

Cold-climate cities remain poorly studied, yet their spontaneous flora is strongly shaped by severe winters and short growing seasons. Heilongjiang Province, the northernmost region of China, provides a valuable case study given its rapid urbanization. As an important component of urban biodiversity, the diversity distribution patterns of spontaneous plants and their underlying causes remain underexplored from multi-scale and multi-dimensional perspectives. Therefore, this study aimed to test how climatic subzones and habitat types jointly influence spontaneous plant diversity across urban landscapes in 14 cities of Heilongjiang Province. Based on vegetation surveys, we applied calculations of α- and β-diversity, along with hierarchical clustering, across climatic subzones, cities, and habitat types to elucidate the diversity patterns and their multi-scale driving mechanisms. The results showed the following: (1) A total of 778 spontaneous plant species were recorded, belonging to 98 families and 395 genera. Native plants accounted for 58.7%, and non-native plants accounted for 41.3% (including 77 invasive species). (2) Perennial herbs dominated overall (45.2%), consistent with winter filtering, whereas annual/biennial herbs were more common in warmer subzones such as II B2. (3) Forest gaps (FG) and shrub–grassland gaps (SG) supported the most diverse spontaneous plant communities, highlighting habitat heterogeneity. (4) Species richness peaked in subzone II B2 and was lowest in subzone I A1, while abandoned land (SA) and shrub–grassland gaps (SG) supported the richest communities. (5) β-diversity analyses indicated homogenization under extreme cold in subzone I A1 and greater turnover in warmer subzone II B2, reflecting contrasting climatic filters. The “light patches” in FG habitats and the “disturbance filtering” in LA habitats further shaped the differences in local communities. This study reveals the diversity distribution patterns and adaptation strategies of spontaneous plants in cold cities, emphasizing their integration into urban planning while addressing the dominance of invasive species. Full article

Alzheimer’s disease (AD) is a progressive neurological condition with limited effective pharmaceutical treatments, often accompanied by side effects. This has increased interest in plant-based alternatives. This study examined the cognitive effects of a Natural Polyherbal Extract (NPX) on scopolamine-induced memory deficits in mice. Male C57BL/6 mice (10 weeks old, n = 36) were divided into four groups: control (saline), scopolamine (1 mg/kg, i.p.), tacrine (10 mg/kg, oral), and NPX (1000 mg/kg, oral). NPX and tacrine were administered daily by oral gavage for two weeks. Cognitive function was assessed weekly using the Y-maze task. Brain tissues were collected for biochemical analysis, including AChE activity and immunohistochemical detection of neurodegeneration-related markers. Results: Mice treated with NPX demonstrated improved spontaneous alternation behavior compared to the scopolamine group. NPX also significantly reduced acetylcholinesterase activity. Immunohistochemistry revealed decreased expression of amyloid-beta (Aβ) and caspase-3, with enhanced choline acetyltransferase levels. These outcomes were comparable to those observed in the tacrine-treated group. Conclusions: NPX alleviated scopolamine-induced memory impairment through enhancement of cholinergic signaling and mitigation of neurodegenerative markers. The findings suggest that NPX may serve as a promising plant-derived candidate for managing memory-related disorders, including AD. Full article

Epilepsy manifests as recurrent spontaneous seizures associated with irregular brain activity. Recognizing the limitations of conventional antiepileptic treatments, we explored the therapeutic potential of essential oils (EOs) derived from Greek aromatic plants (Mentha pulegium, Mentha spicata wild, Mentha piperita, Lavandula angustifolia and Origanum Dictamnus). Specifically, we explored their radical scavenging capacity (DPPH), as well as their antioxidant (AOP and MDA levels) and neuroprotective effect in a PTZ-induced epilepsy Balb/c mice model (animals were pretreated with EOs prior to PTZ treatment). Our results indicated that Mentha piperita emerges as the most promising EO, demonstrating strong antioxidant activity and the highest radical scavenging ability (IC₅₀ = 1.9 mg/mL). Mentha pulegium also exhibited considerable antioxidant potential, demonstrating the strongest effect in the AOP assay when administered prior to PTZ treatment. Furthermore, Origanum dictamnus exhibited the strongest potential to attenuate MDA formation in the presence of PTZ. Finally, immunohistochemistry indicated a trend of neuronal preservation in animals pretreated with EOs prior to PTZ, with Mentha piperita demonstrating the most significant effect. Based on these findings, we suggest that certain EOs possess significant antioxidant and neuroprotective properties. Further research is warranted to validate these results and elucidate the active ingredients responsible for the observed properties. Full article

This comprehensive review paper describes how stressful environmental conditions affect the amounts and types of secondary metabolites synthetized by plants, with particular emphasis on plants that spontaneously grow on post-mining sites. Secondary metabolites are compounds that are not directly necessary for the performance of basic life functions by plants but play an important role in the protection against adverse biotic and abiotic factors. Stress conditions stimulate the synthesis of secondary metabolites. The challenging post-mining sites are spontaneously colonized by many plant species, including medical plants. This observation inspired us to conduct the present review study. Apart from the abiotic conditions, the synthesis of secondary metabolites is also influenced by symbionts such as mycorrhizal fungi. A common effect of abiotic stressors is oxidative damage caused by reactive oxygen species (ROS). Metabolites such as antioxidants maintain the level of ROS at a level safe for the organism. This article presents the current state of knowledge about the impact of habitat conditions on the synthesis of secondary metabolites, which could impact the plant species growing spontaneously in post-mining areas. It considers the possibility of using such post-mining, mineral habitats to enhance these physiological mechanisms for synthesizing secondary metabolites. Full article

Currently, at least one third of greenhouse gas (GHG) emissions come from the agricultural sector, with meat production making a particularly significant contribution. Therefore, alongside the ongoing efforts to transform transport and cut its emissions, it is essential to adopt urgent measures that limit GHG emissions from food production, consumption and distribution. Without them, the Paris Agreement goal of net-zero GHG emissions by 2050 cannot be met, and the most severe impacts of climate change will not be avoided. In principle, lowering emissions from the global food system may appear simple, as no new technology (for example, electric cars or carbon-neutral fuels) is required to decarbonize transport. However, since meat consumption accounts for the majority of food related GHG emissions, it must be coupled with a sharp reduction in the large-scale production and consumption of animal foods. Encouragingly, a growing number of consumers already choose diets that are both healthy and environmentally sustainable. As meat reduction gains popularity in these groups, plant-based products are expanding in the marketplace, mainly in the form of snacks, pasta, pizzas and especially vegan or vegetarian burgers. Thus, almost spontaneously, components of the Westernized diet, rich in ultra-processed foods, salt, sugar and animal protein, are gradually being replaced by plant-derived nutrients that are healthier and more environmentally friendly. To accelerate this trend, legal measures could be introduced to improve the nutritional quality of widely consumed, low-nutrient snacks and to promote agricultural reforms that encourage the production of nutrient-dense legumes and pseudocereals. Full article

A comprehensive floristic study on the vascular flora of the 11 Italian volcanic lake calderas is presented. Despite encompassing one of the Mediterranean’s major freshwater systems, floristic research in these areas has proved fragmented and often outdated. By integrating literature data with original data from new floristic surveys, a total of 1182 spontaneous plant taxa were recorded, including 152 alien plants. Six taxa represent regional novelties and 102 are new for the study area, while 48 taxa reported before 1950 were not confirmed locally. From a conservation perspective, 27 taxa of national interest were reported, including two species classified as Critically Endangered (Isoëtes sabatina, Vicia incisa) and four Endangered (Carex vulpina, Baldellia ranunculoides, Hippuris vulgaris, Hydrocotyle vulgaris) according to IUCN criteria, along with 50 taxa listed on regional red lists. Floristic richness varies notably, from 124 taxa in the caldera of Lake Giulianello to 756 in Lake Bracciano, reflecting differences in caldera size, degree of anthropogenic impact and availability of previous botanical data. These results significantly enrich the floristic knowledge of the calderas of Italian volcanic lakes and may represent a solid reference for future naturalistic research in these areas. Full article

Sauerkraut (SK) is a fermented food of plant origin recognised for its nutritional properties and health benefits. It is traditionally produced through spontaneous fermentation, carried out by the native microflora of fresh cabbage, which includes Gram-negative bacteria, moulds, yeasts and finally lactic acid bacteria (LAB), responsible for transforming natural sugars into lactic acid. However, spontaneous fermentation can also promote the growth of undesirable microorganisms, leading to risks of sensory or food safety alterations, such as the production of biogenic amines. To prevent these limitations, the use of LAB starter cultures is presented as a promising alternative. This study evaluated the fermentation of cabbage at 18 °C and 25 °C, comparing spontaneous fermentation with controlled fermentations using probiotic cultures (Lactiplantibacillus plantarum 229v and Lacticaseibacillus rhamnosus GG). Due to its nutritional importance, the folate content of different types of SK has been studied. Spontaneous fermentation showed positive results in all studied parameters; however, L. plantarum 229v was the inoculum with the highest and fastest acidifying efficacy, reducing the pH to below 4.0 after 7 days at both temperatures. At 25 °C, L. plantarum 229v achieved LAB counts higher than those of L. rhamnosus GG (7.02 vs. 6.00 log CFU·g⁻¹) and exerted the most effective control over enterobacteria and moulds/yeasts, reaching undetectable values (0 log CFU·g⁻¹) on day 7 under both conditions. Antioxidant activity after 42 days of fermentation was higher at 18 °C with L. rhamnosus GG, which showed the highest values (up to 3.50 mg CE·g⁻¹ FW), followed by L. plantarum 229v and spontaneous fermentation. In terms of total folate content (TFC) retention, spontaneous fermentation was particularly effective at both temperatures after 42 days of fermentation (794.741 µg/100 g TFC at 18 °C and 586.542 µg/100 g TFC at 25 °C). In sensory analysis, spontaneous fermentation, in general acceptance, was rated highest (6.2), followed by L. plantarum 229v (5.5) and L. rhamnosus GG (5.3). Considering all the factors studied, SK fermentation with the probiotic strain L. plantarum 229v has proven to be the most suitable. Full article

This study analyzed the planting characteristics and spatial patterns of public-type private gardens in urban areas. Five gardens in Daejeon and Ulsan were surveyed using quadrats to record tree locations and sizes and were digitized for layout mapping. Planting and analysis units were defined, and spatial patterns were examined using degree centrality. The gardens were classified into one site under mixed artificial–natural management and four sites under artificial management with commercial linkage. The mixed site featured both canopy and shrub layers, with spontaneous vegetation surrounding Pinus thunbergii, Pinus densiflora, and Prunus yedoensis. The commercial sites included either canopy-only or canopy-shrub structures. Lagerstroemia indica, P. densiflora, and Euonymus japonicus. were predominant in the temperate central region, while P. densiflora and Diospyros kaki. dominated in the southern region. This study identified the potential of public-type private gardens as planting models and their capacity to contribute to urban environmental improvement. Full article

The present study showed that it is possible add value to eucalyptus harvest waste, obtained in large quantities, from the cellulose industries, without known economic use, for the production of an activated biochar. The biochar, produced from the impregnation of eucalyptus harvest waste with H₃PO₄, and subsequently pyrolyzed at 600 °C for 1 h, was successfully used as a bioadsorbent in the removal of paracetamol, an emerging pollutant present in wastewater. The biochar showed a high specific surface area with micro- and mesopores and functionalized surface. The optimal conditions for the removal of paracetamol achieve an efficiency around 88–93%. The Langmuir and the pseudo-first-order models best fit the experimental data, with a maximum adsorption capacity of approximately 27.8 mg g⁻¹, at 25 °C. The thermodynamic showed that adsorption occurred spontaneously, endothermally and randomly at the solid–liquid interface. In addition, the bioadsorbent showed excellent reusability and no significant difference in adsorption capacity was observed in more complex aqueous matrices. Thus, the activated biochar produced in this study proved to be an efficient, low-cost and environmentally friendly bioadsorbent, capable of removing paracetamol from contaminated water, with great potential for use in water treatment plants, on a large scale and economically, contributing to the improvement of water quality and minimizing residual biomass in the environment. Full article

Urbanization profoundly transforms ecosystems, often resulting in habitat loss and biodiversity decline. Urban spontaneous plants, which are established naturally without human intervention, play a critical role in urban ecosystems by providing habitats, mitigating urban heat islands, and acting as indicators of environmental changes. Multidimensional urbanization, encompassing vertical and horizontal scale, exerts a significant influence on the biodiversity of green space. While previous studies have extensively examined the effects of horizontal spatial scales (such as land use and population density), the impacts of vertical spatial scales remain understudied. To elucidate the spatial patterns and driving factors of spontaneous plant diversity under multidimensional urbanization, we conducted a comprehensive survey of spontaneous plants across Changchun, a rapidly urbanizing city in northeast China. We established 1147 herbaceous plots within 245 urban green space patches across 38 sites and analyzed the effects of multidimensional urbanization metrics on spontaneous plant diversity. A total of 408 species of spontaneous plants were recorded, with herbs as the dominant life-form (89.2%), 322 are native species (78.9%), and 21.1% non-native species (of which 65.1% are invasive), primarily dispersed by autochory. Significant differences in plant diversity indices were observed across various urban green spaces and habitat types in Changchun, with native plant diversity generally highest in square green spaces and scrub gaps, while non-native plant diversity was most prominent in brownfield sites and showed no significant variation among habitat types. Regression analyses revealed that, in addition to patch characteristic factors (including patch area, perimeter–area ratio, and landscape shape index), the richness of total, native, and autochorous spontaneous plants was primarily influenced by vertical urbanization (as indicated by building volume), with building volume positively associated with species richness. In contrast, the richness of non-native and anemochorous plants was also significantly affected by horizontal urbanization factors, such as the proportion of impervious surface within a 100 m buffer zone and distance from patch to city center. The results reveal distinct spatial patterns of spontaneous plant diversity driven by both urbanization of horizontal spatial scales and vertical spatial scales. Our study provides new insights into the interplay between multidimensional urbanization and biodiversity, offering a theoretical foundation for integrating biodiversity conservation into sustainable urban planning and ecosystem management. Full article

Mining and metallurgical activities negatively impact ecosystems due to the release of potentially toxic elements (PTEs). This study assesses PTE pollution and accumulation in native plant species that have spontaneously colonized a historical mining site (Michaly, site A) and a nearby metallurgical smelter site (Varvara, site B) on the Lavreotiki Peninsula, Attika, Greece. Soils were analyzed for As, Cd, Co, Cr, Cu, Fe, Mn, Ni, Pb, Sb, and Zn. A total of 89 native plant taxa across 28 families were identified. The aerial parts from dominant species were analyzed for PTE concentrations, and bioconcentration factors (BCFs) were calculated. One-way ANOVA and principal component analysis (PCA) using R were used for statistical evaluation. Soils at both sites showed elevated As, Cd, Cr, Cu, Ni, Pb, Sb, and Zn; Mn was high only at site B, while Co and Fe remained at background levels. Several plant species, especially at Michaly, had elevated concentrations of As, Cd, Co, Cr, Fe, Pb, Sb, and Zn in their aerial parts. BCFs indicated general PTE exclusion from aerial parts, particularly at site B. Native vegetation on these contaminated sites shows resilience and PTE exclusion, highlighting their potential for phytoremediation, especially phytostabilization, and ecological restoration in similarly polluted Mediterranean environments. Full article

Background: Purple loosestrife (Lythrum salicaria L.) is a medicinal plant native to the spontaneous Romanian flora. The aim of this study was to investigate the phenolic profile, total phenolic content (TPC), and antioxidant capacity (AC) of two L. salicaria L. extracts, a hydro-methanolic extract (LSmet-1) and a hydro-ethanolic extract (LSeth-2), and their putative toxicity, as well as the effect on eye pigment content in the case of Drosophila melanogaster of an extract derived from LSmet-1 (LSmet-3). To the best of our knowledge, this is the first study to evaluate the influence of L. salicaria L. extracts on cytotoxicity and the expression of genes as determined by eye pigment levels, using a D. melanogaster-based model system. Methods: High-performance liquid chromatography was carried out to investigate the chemical composition of the extracts. Spectrophotometric methods were used to estimate their TPC and AC. Cytotoxicity was evaluated using an in vivo D. melanogaster diet-dependent viability assay and eye pigments of w^m4h males, suitable for position-effect variegation studies, which were quantified by a spectrophotometric method. Results: The results indicated that the main phenolic compounds were gallic acid, resveratrol, and rutin in LSmet-1, whereas in LSeth-2, gallic acid and quercetin were the most relevant. LSmet-1 had a higher TPC compared to LSeth-2. Both extracts exhibited notable efficacy in the applied in vitro antioxidant tests. The viability of flies on normal media increased in a concentration-dependent manner at lower concentrations, with the extract being toxic at higher concentrations. On a high-sugar diet, even lower concentrations were toxic. All tested concentrations influenced the eye pigment content. Conclusions: Our study brings new findings on L. salicaria L. extracts, suggesting the need for further investigation before introducing them in therapy. Full article

Rice bran protein (RBP) is an important plant protein, but its functional properties are reduced due to the presence of disulfide bonds in the structure. Polyphenol modification is an effective strategy to improve protein functional properties. However, the interactions between quercetin (Que) and RBP have not been well-studied. In this study, we explored the mechanism of non-covalent interactions between RBP and Que and systematically evaluated the improvement of functional properties of the RBP–Que complex. The results revealed that the addition of Que can significantly affect the particle size, ζ-potential and protein flexibility of the RBP–Que complex, and the non-covalent interactions significantly altered the secondary structure (α-helix content decreased to 20.28%, β-sheet decreased to 22.02%, β-turn increased to 29.30% and random coil increased to 28.40%) and the tertiary conformation of RBP. Spectroscopic data showed that static quenching occurred. Thermodynamic parameters showed that ΔG, ΔH, and ΔS were negative, revealing that the binding process was spontaneous and exothermic and the main reactive bonds were the hydrogen bond and the van der Waals force. When the Que concentration was 120 μmol/g, the emulsifying and foaming properties were improved by 57.72% and 71.88% compared with the RBP, respectively. The study will expand the application of RBP in the food and beverage processing industry. Full article

Pinus taeda plantations have been facing declining productivity in South America, especially due to competition for natural resources such as light, water, and nutrients. Competition with spontaneous vegetation in the early years is one of the main constraints on growth and biomass allocation in trees. However, the best method and timing for weed control and its impact on the productivity of Pinus taeda plantations are unknown. This study aims to evaluate whether weed control increases the growth and above-ground biomass production of Pinus taeda plantations in southern Brazil. This study was conducted at two sites with five-year-old Pinus taeda plantations in southern Brazil, with each being submitted to different weed control methods. This study was conducted in randomized blocks, with nine treatments: (i) NC—no weed control, i.e., weeds always present; (ii) PC—physical weed control; (iii) CC–T—chemical weed control in the total area; (iv) CC–R—chemical weed control in rows (1.2 m wide); (v) C6m, (vi) C12m, (vii) C18m, and (viii) C24m—weed control up to 6, 12, 18, and 24 months after planting; and (ix) COC—company operational weed control. The following parameters were evaluated: the floristic composition and weed biomass, height, diameter, stem volume, needle biomass, branches, bark, and stemwood of Pinus taeda. Control of the weed competition, especially by physical means (PC), and chemical control over the entire area (CC–T) promoted significant gains in the growth and above–ground biomass production of Pinus taeda at five years of age, particularly at the Caçador site. The results reinforce the importance of using appropriate strategies for managing weed control to maximize productivity, especially before canopy closure. In addition, the strong correlation between growth variables and the total biomass and stemwood indicates the possibility of obtaining indirect estimates through dendrometric measurements. The results contribute to the improvement of silvicultural management in subtropical regions of southern Brazil. Full article

Green spaces are essential for urban environments, but urban expansion often results in fragmented patches and narrow pavements unsuitable for tree growth. Consequently, there is a pressing need for alternative vegetation in urban landscapes where tree planting is impractical. Urban spontaneous vegetation (USV)—plants that establish naturally without cultivation—shows promise for urban landscaping, and yet has been underexplored in urban ecology. This study was the first systematic survey to examine the composition of USV in Chiang Mai, Thailand, across seven urban locations. The survey was conducted along 13 sidewalk routes (totaling 33.24 km), documenting all non-tree vascular plant species. A total of 63 USV species from 24 families were recorded, predominantly colonizing pavement gaps, cracks, and curbside cracks. The most diverse family was Poaceae, with 15 species. Among the 61 identified species, 32 species (52%) were non-native. Seven species were found in all surveyed locations, highlighting their adaptability to challenging urban conditions. Fifty USV species are medicinal plants. Many species exhibit characteristics that are ideal for sustainable landscaping, such as drought tolerance, low maintenance requirements, and ornamental value. This study highlights USV as a key component of green infrastructure and provides new insights for urban sustainable landscaping. Full article