Explore the vast range of titles available.

Salinity substantially affects plant growth and crop productivity worldwide. Plants adopt several biochemical mechanisms including regulation of antioxidant biosynthesis to protect themselves against the toxic effects induced by the stress. One-year-old pistachio rootstock exhibiting different degrees of salinity tolerance were subjected to sodium chloride induced stress to identify genetic diversity among cultivated pistachio rootstock for their antioxidant responses, and to determine the correlation of these enzymes to salinity stress. Leaves and roots were harvested following NaCl-induced stress. The results showed that a higher concentration of NaCl treatment induced oxidative stress in the leaf tissue and to a lesser extent in the roots. Both tissues showed an increase in ascorbate peroxidase, superoxide dismutase, catalase, glutathione reductase, peroxidase, and malondialdehyde. Responses of antioxidant enzymes were cultivar dependent, as well as temporal and dependent on the salinity level. Linear and quadratic regression model analysis revealed significant correlation of enzyme activities to salinity treatment in both tissues. The variation in salinity tolerance reflected their capabilities in orchestrating antioxidant enzymes at the roots and harmonized across the cell membranes of the leaves. This study provides a better understanding of root and leaf coordination in regulating the antioxidant enzymes to NaCl induced oxidative stress.

Seagrass meadows provide important ecosystem services and are critical for the survival of the associated invertebrate community. However, they are threatened worldwide by human-driven environmental change. Understanding the seagrasses’ potential for adaptation is critical to assess not only their ability to persist under future global change scenarios, but also to assess the persistence of the associated communities. Here we screened a wild population of Posidonia oceanica, an endemic long-lived seagrass in the Mediterranean Sea, for genes that may be target of environmental selection, using an outlier and a genome-wide transcriptome analysis. We identified loci where polymorphism or differential expression was associated with either a latitudinal or a bathymetric gradient, as well as with both gradients in an effort to identify loci associated with temperature and light. We found the candidate genes underlying growth and immunity to be divergent between populations adapted to different latitudes and/or depths, providing evidence for local adaptation. Furthermore, we found evidence of reduced gene flow among populations including adjacent populations. Reduced gene flow, combined with low sexual recombination, small effective population size, and long generation time of P. oceanica raises concerns for the long-term persistence of this species, especially in the face of rapid environmental change driven by human activities.

The purification of phycocyanin (PC) from Spirulina generally involves a combination of different techniques. Here, we report the results on PC yields from a combined aqueous extraction-ultrafiltration (UF) process of a strain of Arthrospira maxima cultivated in a farm devoted to producing PC with food-grade purity. Samples optimized from different biomass/solvent ratios were purified by using a polyethersulphone (PES) membrane with a molecular weight cut-off (MWCO) of 20 kDa. The UF system was operated at 2.0 ± 0.1 bar and at 24 ± 2 °C up to a volume concentration factor (VCF) of 5. A diafiltration (DF) process was conducted after UF in order to increase the PC recovery in the retentate. Samples were collected during both UF and DF processes in order to evaluate membrane productivity and PC purity. The average permeate fluxes of about 14.4 L/m2h were measured in the selected operating conditions and more than 96% of PC was rejected by the UF membrane independently ofthe extraction yields and times. The concentration of PC in the final retentate was 1.17 mg/mL; this confirmed the observed rejection and the final VCF of the process (about 5-fold when compared to the concentration of PC in the crude extract). In addition, the combination of UF and diafiltration allowed the removal of about 91.7% of the DNA from the crude extract, thereby improving the purity of the phycocyanin in the retentate fraction.

Seagrass Cymodocea nodosa was sampled off the Vulcano island, in the vicinity of a submarine volcanic vent. Leaf samples were collected from plants growing in a naturally acidified site, influenced by the long-term exposure to high CO2 emissions, and compared with others collected in a nearby meadow living at normal pCO(2) conditions. The differential accumulated proteins in leaves growing in the two contrasting pCO(2) environments was investigated. Acidified leaf tissues had less total protein content and the semi-quantitative proteomic comparison revealed a strong general depletion of proteins belonging to the carbon metabolism and protein metabolism. A very large accumulation of proteins related to the cell respiration and to light harvesting process was found in acidified leaves in comparison with those growing in the normal pCO(2) site. The metabolic pathways linked to cytoskeleton turnover also seemed affected by the acidified condition, since a strong reduction in the concentration of cytoskeleton structural proteins was found in comparison with the normal pCO(2) leaves. Results coming from the comparative proteomics were validated by the histological and cytological measurements, suggesting that the long lasting exposure and acclimation of C. nodosa to the vents involved phenotypic adjustments that can offer physiological and structural tools to survive the suboptimal conditions at the vents vicinity.

The Spirulina spp. exhibited an ability to tolerate the organophosphates. This study aimed to explore the effects of the herbicide glyphosate on a selected strain of the cyanobacteria Arthrospira maxima cultivated in a company. Experimental cultivations acclimated in aquaria were treated with 0.2 mM glyphosate [N-(phosphonomethyl) glycine]. The culture biomass, the phycocyanin, and the chlorophyll a concentrations were evaluated every week during 42 days of treatment. The differentially expressed proteins in the treated cyanobacteria versus the control cultivations were evaluated weekly during 21 days of treatment. Even if the glyphosate treatment negatively affected the biomass and the photosynthetic pigments, it induced resistance in the survival A. maxima population. Proteins belonging to the response to osmotic stress and methylation pathways were strongly accumulated in treated cultivation; the response to toxic substances and the negative regulation of transcription seemed to have a role in the resistance. The glyphosate-affected enzyme, chorismate synthase, a key enzyme in the shikimic acid pathway, was accumulated during treatment, suggesting that the surviving strain of A. maxima expressed a glyphosate-resistant target enzyme.

Information regarding the physiological and molecular plant responses to the treatment with new biofertilizers is limited. In this study, a fast-composting soil amendment obtained from solid waste by means of a Fenton reaction was assessed to evaluate the effects on the growth of Lactuca sativa L. var. longifolia seedlings. Growth rate, root biomass, chlorophyll concentration, and total soluble proteins of seedlings treated with the 2% fast-composting soil amendment showed significant increases in comparison with the control seedlings. Proteomic analysis revealed that the soil amendment induced the up-regulation of proteins belonging to photosynthesis machinery, carbohydrate metabolism, and promoted energy metabolism. Root proteomics indicated that the fast-composting soil amendment strongly induced the organs morphogenesis and development; root cap development, lateral root formation, and post-embryonic root morphogenesis were the main biological processes enriched by the treatment. Overall, our data suggest that the addition of the fast-composting soil amendment formulation to the base soils might ameliorate plant growth by inducing carbohydrate primary metabolism and the differentiation of a robust root system.

This paper examines how a social threat posed by a deviant behavior affects second-hand forgiveness over time toward ingroup and outgroup transgressors. In Study 1, using real news reports, we investigated intergroup rivalries between soccer fans in order to understand the role of group membership in predicting the intention to forgive transgressors. Results suggested that transgressors were less likely to be forgiven by ingroup members rather than outgroup members, thus showing evidence of the black sheep effect. In Study 2 (using a different sample), we analyzed the same intergroup rivalries one year after the transgression in order to explore changes in intention to forgive over time. Results showed that, after one year, ingroup members were more likely to forgive ingroup than outgroup transgressors, but only when the threat to the group stereotype was not salient. The implications of the results for the subjective group dynamics theory and for the black sheep effect are discussed.

Campaigns supporting victims of gender harassment and abuse, such as #MeToo, have made and still make significant contributions to achieving the fifth UN Sustainable Development Goal aimed at eliminating “all forms of violence against all women”. In two correlational studies, we examined possible antecedents of people’s willingness to participate in the #MeToo campaign by focusing on the role of ambivalent beliefs toward women and men and the perceived effects of the movement. Men (Study 1) and women (Study 2) were asked to answer questions concerning hostile and benevolent beliefs about women and men, respectively, their perception of the beneficial and detrimental effects of #MeToo, and their intentions to participate in the campaign. Study 1 showed that men’s hostile sexism toward women was associated with fewer intentions to actively support the #MeToo campaign and that the reduced beliefs that the movement had beneficial effects mediated this relation. Study 2 revealed that women’s stronger benevolent beliefs about men were associated with decreased perception that the #MeToo campaign had a beneficial impact. In turn, such a perception was related to lower intentions to participate in supporting the campaign. Moreover, women’s hostility toward men explained the intention to join the #MeToo movement through the mediation of the perception that the campaign was beneficial. The findings suggest that to foster participation in a feminist movement that promotes women’s rights, it is necessary to eradicate traditional gender roles and the related ideologies that legitimate men’s dominant position in society.

Pistachio, one of the important tree nuts, is cultivated in arid and semi-arid regions where salinity is the most common abiotic stress encountered by this tree. However, the mechanisms underlying salinity tolerance in this plant are not well understood. In the present study, five 1-year-old pistachio rootstocks (namely Akbari, Badami, Ghazvini, Kale-Ghouchi, and UCB-1) were treated with four saline water regimes (control, 8, 12, and 16 dS m−1) for 100 days. At high salinity level, all rootstocks showed decreased relative water content (RWC), total chlorophyll content (TCHC), and carotenoids in the leaf, while ascorbic acid (AsA) and total soluble proteins (TSP) were reduced in both leaf and root organs. In addition, the total phenolic compounds (TPC), proline, glycine betaine, total soluble carbohydrate (TSC), and H2O2 content increased under salinity stress in all studied rootstocks. Three different ion exclusion strategies were observed in the studied rootstocks: (i) Na+ exclusion in UCB-1, because most of its Na+ is retained in the roots; (ii) Cl− exclusion in Badami, in which most of its Cl− remained in the roots; and (iii) similar concentrations of Na+ and Cl− were observed in the leaves and roots of Ghazvini, Akbari, and Kale-Ghouchi. Transport capacity (ST value) of K+ over Na+ from the roots to the leaves was more observable in UCB-1 and Ghazvini. Overall, the root system cooperated more effectively in UCB-1 and Badami for retaining and detoxifying an excessive amount of Na+ and Cl−. The results presented here provide important inputs to better understand the salt tolerance mechanism in a tree species for developing more salt-tolerant genotypes. Based on the results obtained here, the studied rootstocks from tolerant to susceptible are arranged as follows: UCB-1 > Badami > Ghazvini > Kale-Ghouchi > Akbari.

Dimethyl sulfoxide (DMSO), produced by various phytoplankton species and macrophytes, is the most abundant biogenic sulfur compounds in the marine environment. It is derived from the oxidation of dimethylsulfide (DMS), a key compound in the marine sulfur cycle and contributing to global climate regulation. Despite its relevance, the specific natural functions of DMSO for producer organisms remain largely unknown. This study investigated the hormetic response of increasing exogenous DMSO concentrations to decipher its role in the marine plant Posidonia oceanica , a keystone species in Mediterranean marine biodiversity and major producer of DMSO. Treatment with 1% DMSO significantly increased elongation of adult (204%) and intermediate (46%) leaves, number of juvenile leaves and boosted chlorophyll a (50%) and b (65%) concentration. Concentrations above or below this threshold had negative effects; specifically, 0.1% DMSO had a negative impact on intermediate leaves elongation (29% decrease) and on chlorophyll b (45% decrease). Proteomic analysis showed that DMSO inhibits primary metabolism while activating secondary metabolic pathways. Photosynthesis, glycolysis, translation were depleted, while vacuolar metabolism enhanced. To cope energy for growth and tolerate the stress, under 1% DMSO concentration the flavonoid biosynthesis was hugely enhanced. Significant accumulation of proteins involved in the glutamine synthesis, assured the nitrogen source for plant growth and development. These findings suggest DMSO modulates leaf meristem activity, regulates cellular osmosis, and protects against oxidative damage. Future work should investigate the molecular mechanisms behind these roles and explore the broader ecological impact of DMSO on marine sulfur cycling and P. oceanica interactions. Graphical Abstract