315 research outputs found
Biochemical, Physiological, and Molecular Aspects of Ornamental Plants Adaptation to Deficit Irrigation
There is increasing concern regarding global warming and its severe impact on the farming
sector and food security. Incidences of extreme weather conditions are becoming more and more
frequent, posing plants to stressful conditions, such as flooding, drought, heat, or frost etc. Especially
for arid lands, there is a tug-of-war between keeping high crop yields and increasing water use
efficiency of limited water resources. This difficult task can be achieved through the selection of
tolerant water stress species or by increasing the tolerance of sensitive species. In this scenario, it is
important to understand the response of plants to water stress. So far, the response of staple foods
and vegetable crops to deficit irrigation is well studied. However, there is lack of literature regarding
the responses of ornamental plants to water stress conditions. Considering the importance of this
ever-growing sector for the agricultural sector, this review aims to reveal the defense mechanisms
and the involved morpho-physiological, biochemical, and molecular changes in ornamental plant’s
responses to deficit irrigation
Focal Epilepsy Associated with Glioneuronal Tumors
Glioneuronal tumors are an increasingly recognized cause of partial seizures that occur primarily in children and young adults. Focal epilepsy associated with glioneuronal tumors is often resistant to pharmacological treatment. The cellular mechanisms underlying the epileptogenicity of glioneuronal tumors remain largely unknown. The involved mechanisms are certain to be multifactorial and depend on specific tumor histology, integrity of the blood-brain barrier, characteristics of the peritumoral environment, circuit abnormalities, or cellular and molecular defects. Glioneuronal tumors presenting with epilepsy were observed to have relatively benign biological behavior. The completeness of the tumor resection is of paramount importance in avoiding tumor progression and malignant transformation, which are rare in cases of epileptogenic glioneuronal tumors.
An evolving understanding of the various mechanisms of tumor-related epileptogenicity may also lead to a more defined surgical objective and effective therapeutic strategies, including antiepileptogenic treatments, to prevent epilepsy in at-risk patients
Changes in Morpho-Anatomical and Eco-Physiological Responses of Viburnum tinus L. var lucidum as Modulated by Sodium Chloride and Calcium Chloride Salinization
Salinity in water and soil is among the major constraints to the cultivation of ornamental
crops since it can affect their growth and aesthetic value. A greenhouse experiment was carried out to
assess whether the application of two different salts (80mM NaCl or 53.3mM CaCl2, with a final ionic
concentration of 160 mM) could differently modulate the anatomical and physiological acclimation
of an important ornamental species such as Viburnum tinus L. var. lucidum. Eco-physiological
analyses (e.g., leaf gas exchange and chlorophyll a fluorescence emission) were performed and
leaves were subjected to light microscopy analysis to quantify functional anatomical traits through
digital image analysis. Results showed that the two iso-osmotic solutions induced different structuremediated
physiological alterations in V. tinus plants. Photosynthesis was lowered by CaCl2 treatments
(-58%) more than by NaCl (-37%), also due to the occurrence of photodamage apart from stomatal
limitations. Neither Na+ nor Cl- exhibited toxic effects in leaf lamina structure which was reflected
in the limited reduction in dry matter accumulation. Overall data were interpreted focusing on the
coordination among leaf structural and functional traits suggesting that the fine control of functional
anatomical traits contributes to physiological acclimation to both stressful condition
Ameliorating a Complex Urban Ecosystem Through Instrumental Use of Softscape Buffers: Proposal for a Green Infrastructure Network in the Metropolitan Area of Naples
Green Infrastructure (GI) definition, deriving from the United States green infrastructure
for hydro-geological rebalancing through imitating the nature stormwater management,
was consolidated in Europe by GI Planning Guide. Nowadays GI can be considered
a valid and meaningful approach for ameliorating urban complex ecosystems, and
could also be considered as mitigation action of land consumption, according to the
guidelines on the soil sealing of the European Commission (2012). The metropolitan
area of Naples located in south Italy is characterized by an unauthorized and chaotic
urban development. The land-use map reported an average of 30% of urbanization in
the metropolitan area, rising up to 50–60% and as high as 98% in the north core area of
the city. This high level of urbanization is directly related to the habitat fragmentation. The
National Biodiversity Conservation Strategy defines several challenges and targets to
counteract the biodiversity loss in Italy, identifying urban areas as places exposed to the
greatest pressures on ecosystems. Therefore, the integration of different policies limiting
habitat fragmentation, heat island effect and natural soil hydro-geological degradation
into spatial planning, especially through green corridors and ecosystem enhancement
in urban areas is an urgent need for the society. Spatial planning has to be renewed
in metropolitan areas, where threats and weaknesses to biodiversity conservation are
stronger than in any other place, according to the Law n. 56/2014, (Gazzetta Ufficiale
della Repubblica Italiana, 2014) committing metropolitan cities to the enactment of
General Territorial Plan. In the current paper, we aim at designing an ecological network
for the metropolitan area of Naples one of the biggest city of southern Italy. The analyses
include the adopted methodological procedure, i.e., ecological network analysis and
design, and the introductory elements of a spatial analysis on a pilot ecological network
of several patches. Finally, the paper illustrates the network analysis conceived as a
monitoring system and also in future perspective, as a planning support system
Anthocyanins are Key Regulators of Drought Stress Tolerance in Tobacco
Abiotic stresses will be one of the major challenges for worldwide food supply in the near future. Therefore, it is important to understand the physiological mechanisms that mediate plant responses to abiotic stresses. When subjected to UV, salinity or drought stress, plants accumulate specialized metabolites that are often correlated with their ability to cope with the stress. Among them, anthocyanins are the most studied intermediates of the phenylpropanoid pathway. However, their role in plant response to abiotic stresses is still under discussion. To better understand the effects of anthocyanins on plant physiology and morphogenesis, and their implications on drought stress tolerance, we used transgenic tobacco plants (AN1), which over-accumulated anthocyanins in all tissues. AN1 plants showed an altered phenotype in terms of leaf gas exchanges, leaf morphology, anatomy and metabolic profile, which conferred them with a higher drought tolerance compared to the wild-type plants. These results provide important insights for understanding the functional reason for anthocyanin accumulation in plants under stress
How Leaf Vein and Stomata Traits Are Related with Photosynthetic Efficiency in Falanghina Grapevine in Different Pedoclimatic Conditions
The increase in severe drought events due to climate change in the areas traditionally suitable for viticulture is enhancing the need to understand how grapevines regulate their photosynthetic metabolism in order to forecast specific cultivar adaptive responses to the changing environment. This study aims at evaluating the association between leaf anatomical traits and eco-physiological adjustments of the 'Falanghina' grapevine under different microclimatic conditions at four sites in southern Italy. Sites were characterized by different pedoclimatic conditions but, as much as possible, were similar for plant material and cultivation management. Microscopy analyses on leaves were performed to quantify stomata and vein traits, while eco-physiological analyses were conducted on vines to assess plant physiological adaptation capability. At the two sites with relatively low moisture, photosynthetic rate, stomatal conductance, photosystem electron transfer rate, and quantum yield of PSII, linear electron transport was lower compared to the other two sites. Stomata size was higher at the site characterized by the highest precipitation. However, stomatal density and most vein traits tended to be relatively stable among sites. The number of free vein endings per unit leaf area was lower in the two vineyards with low precipitation. We suggest that site-specific stomata and vein traits modulation in Falanghina grapevine are an acclimation strategy that may influence photosynthetic performance. Overall in-depth knowledge of the structure/function relations in Falanghina vines might be useful to evaluate the plasticity of this cultivar towards site-specific management of vineyards in the direction of precision viticulture
Counteracting the negative effects of copper limitations through the biostimulatory action of a tropical plant extract in grapevine under pedo-climatic constraints
In southern Mediterranean areas, vineyards are facing the combination of increasing air temperature, drought and frequency of extreme events (e.g., heat waves) due to climate change. Since most of the berry growth and ripening phases occur during the aridity period, such environmental constraints are responsible for limitations in yield and berry quality. Within this scenario, to achieve vineyard sustainability, renewed approaches in vineyard management have been proposed and the use of plant biostimulants seems a prominent and environmental friendly practice. The aim of this study was to test four combinations of a tropical plant extract and conventional chemicals for disease control on morpho-anatomical, physiological, biochemical and berry quality in Vitis vinifera L. subsp. vinifera “Aglianico.” In particular, we aimed to evaluate the possibility to counteract the negative effects of the reductions in copper distribution, by applying the tropical plant extract enriched with: micronutrients, enzymes involved in the activation of natural defense, aminoacids, and vitamins. The halved dose of Cu in combination with the tropical plant extract allowed maintaining a reduced vegetative vigor. In the second year of treatment, the addition of the plant extract significantly improved leaf gas exchanges and photochemistry as well as the synthesis of photosynthetic pigments. At berry level, the plant extract induced an increase in phenolics accompanied by a decrease in soluble sugars. The overall results showed that the expected differences in growth performance and productivity in vines are linked to different eco-physiological and structural properties induced by the various treatments. The tropical plant extract also primed plant defenses at the leaf and fruit levels, mainly due to modifications of some structural and biochemical traits, respectively
Protein Hydrolysates from Animal or Vegetal Sources Affect Morpho-Physiological Traits, Ornamental Quality, Mineral Composition, and Shelf-Life of Chrysanthemum in a Distinctive Manner
Protein hydrolysates (PHs) are a prominent category of plant biostimulants, mainly constituted of amino acids, oligopeptides and polypeptides, obtained by partial hydrolysis of animal or plant protein sources. Despite scientific evidence supporting the biostimulant action of PHs on vegetables, the morphological, physiological, and shelf-life performances underlying the PH action on cut flowers are still poorly explored. Accordingly, the aim of this research is to assess the effects of three commercial biostimulants, one animal PH (PH A, Hicure®) and two plant PHs (PH V1, Trainer® and PH V2, Vegamin©), on two chrysanthemum (Chrysanthemum morifolium) cultivars (Pinacolada and Radost). In both cultivars, only the plant-derived PH (V1 and V2) treatments recorded significantly higher fresh plant biomass than the control (on average +18%, in both cultivars). The foliar application of the vegetal-derived PHs but not the animal one, particularly in Pinacolada, improved the status of plants, stimulating stem elongation and the apical flower diameter. In Pinacolada, applications with PH V1 resulted in a significant increase in nitrate and P concentration in leaves and Ca content in flowers compared with the control (+43%, +27%, and +28% for nitrate, P, and Ca, respectively). In Radost, PH A and PH V2 applications caused a significant reduction in nitrate concentration in both leaves and flowers compared with the control. One week after harvest, in both cultivars, PH A applications caused flower stems to wilt faster than the control. In contrast, plants treated with PH V1 revealed significantly slower flower stem senescence compared to the control. Flower wilting during vase life was correlated to a decrease in the K-to-Na ratio in flowers due to an inability to transport K to the flowers from the leaves rather than an increase in Na in the flowers themselves
Protein Hydrolysates from Animal or Vegetal Sources Affect Morpho-Physiological Traits, Ornamental Quality, Mineral Composition, and Shelf-Life of Chrysanthemum in a Distinctive Manner
Protein hydrolysates (PHs) are a prominent category of plant biostimulants, mainly constituted of amino acids, oligopeptides and polypeptides, obtained by partial hydrolysis of animal or plant protein sources. Despite scientific evidence supporting the biostimulant action of PHs on vegetables, the morphological, physiological, and shelf-life performances underlying the PH action on cut flowers are still poorly explored. Accordingly, the aim of this research is to assess the effects of three commercial biostimulants, one animal PH (PH A, Hicure®) and two plant PHs (PH V1, Trainer®and PH V2, Vegamin©), on two chrysanthemum (Chrysanthemum morifolium) cultivars (Pinacolada and Radost). In both cultivars, only the plant-derived PH (V1 and V2) treatments recorded significantly higher fresh plant biomass than the control (on average +18%, in both cultivars). The foliar application of the vegetal-derived PHs but not the animal one, particularly in Pinacolada, improved the status of plants, stimulating stem elongation and the apical flower diameter. In Pinacolada, applications with PH V1 resulted in a significant increase in nitrate and P concentration in leaves and Ca content in flowers compared with the control (+43%, +27%, and +28% for nitrate, P, and Ca, respectively). In Radost, PH A and PH V2 applications caused a significant reduction in nitrate concentration in both leaves and flowers compared with the control. One week after harvest, in both cultivars, PH A applications caused flower stems to wilt faster than the control. In contrast, plants treated with PH V1 revealed significantly slower flower stem senescence compared to the control. Flower wilting during vase life was correlated to a decrease in the K-to-Na ratio in flowers due to an inability to transport K to the flowers from the leaves rather than an increase in Na in the flowers themselves
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