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Water, a necessary component of cell protoplasm, plays an essential role in supporting life on Earth; nevertheless, extreme changes in climatic conditions limit water availability, causing numerous issues, such as the current water-scarce regimes in many regions of the biome. This review aims to collect data from various published studies in the literature to understand and critically analyze plants’ morphological, growth, yield, and physio-biochemical responses to drought stress and their potential to modulate and nullify the damaging effects of drought stress via activating natural physiological and biochemical mechanisms. In addition, the review described current breakthroughs in understanding how plant hormones influence drought stress responses and phytohormonal interaction through signaling under water stress regimes. The information for this review was systematically gathered from different global search engines and the scientific literature databases Science Direct, including Google Scholar, Web of Science, related studies, published books, and articles. Drought stress is a significant obstacle to meeting food demand for the world’s constantly growing population. Plants cope with stress regimes through changes to cellular osmotic potential, water potential, and activation of natural defense systems in the form of antioxidant enzymes and accumulation of osmolytes including proteins, proline, glycine betaine, phenolic compounds, and soluble sugars. Phytohormones modulate developmental processes and signaling networks, which aid in acclimating plants to biotic and abiotic challenges and, consequently, their survival. Significant progress has been made for jasmonates, salicylic acid, and ethylene in identifying important components and understanding their roles in plant responses to abiotic stress. Other plant hormones, such as abscisic acid, auxin, gibberellic acid, brassinosteroids, and peptide hormones, have been linked to plant defense signaling pathways in various ways.

The study is aimed at assessing the influence of the electrohydraulic effect on succulent plant raw materials. Experimental data show that the use of electrohydraulic effect helps to increase the juice yield of raw materials due to the active effect on the protoplasm of cells and increasing their permeability. It has been established that the optimal processing mode using the electrohydraulic method at 7 kV and 1 μF provides maximum juice yield, especially for pulp with a liquid consistency, such as grape pulp. Microscopy results revealed changes in cell structure, confirming the effectiveness of this treatment method. The developed experimental electrohydraulic effect installation takes into account the scientific findings obtained and represents a promising means for processing grape pulp in a stream. Thus, the study confirms the significance and potential of using the electro-hydraulic method to improve the production process in the food industry.

Biomolecular condensates play a key role in organizing cellular reactions by concentrating a specific set of biomolecules. However, whether condensate formation is accompanied by an increase in the total mass concentration within condensates or by the demixing of already highly crowded intracellular components remains elusive. Here, using refractive index imaging, we quantify the mass density of several condensates, including nucleoli, heterochromatin, nuclear speckles, and stress granules. Surprisingly, the latter two condensates exhibit low densities with a total mass concentration similar to the surrounding cyto- or nucleoplasm. Low-density condensates display higher permeability to cellular protein probes. We find that RNA tunes the biomolecular density of condensates. Moreover, intracellular structures such as mitochondria heavily influence the way phase separation proceeds, impacting the localization, morphology, and growth of condensates. These findings favor a model where segregative phase separation driven by non-associative or repulsive molecular interactions together with RNA-mediated selective association of specific components can give rise to low-density condensates in the crowded cellular environment. The cell interior is organized by diverse membrane-less condensates. Here, the authors reveal that the densities of certain condensates are surprisingly low, similar to the surrounding protoplasm and driven by cellular RNA as well as the crowded milieu.

Upstream Contamination is a counter-intuitive phenomena of fluid dynamics, where particles can go against the liquid stream and climb, higher containers. Previous studies have attributed the movement of particles against the flow of water to the Marangoni effect, where surface tension gradients drive fluid movement. However, the effect was not enough to account for the motion of particles. Meanwhile, this study challenges that explanation by documenting the ascent of fine particles of Iron Fillings, through a water jet where the lower container exhibited higher surface tension due to an aqueous calcium chloride (CaCl 2 ) solution. Contrary to the Marangoni effect, which predicts that particles should move from areas of lower to higher surface tension, our observations showed that the particles can move upwards even from a higher surface tension to a lower surface tension region. Afterward, other factors influencing this phenomenon were studied, including the height of the upper container from the lower one, the angle between the channel and the horizontal axis, temperature, and surface tension gradient. Each of them, suggests that factors other than surface tension gradients, such as fluid dynamics and turbulence, play a significant role in particle behavior in these conditions. This study can help us understand how some ‘safe-ecosystems’, cell mechanisms and medicine production can be contaminated in an unthinkable way so that these contaminators can be prevented and a safer ecosystem and medicare development can be ensured and steps to safeguard protoplasm from harmful contaminants can be taken.

The true slime mould, Physarum polycephalum, develops as a vascular network of protoplasm, connecting node-like sources of food in an effort to solve multi-objective transport problems. The organism first establishes a dense and continuous mesh, reinforcing optimal pathways over time through constructive feedbacks of protoplasmic streaming. Resolved vascular morphologies are the result of an evolutionarily-refined mechanism of computation, which can serve as a versatile biological model for network design at the urban scale. Existing digital Physarum models typically use positive reinforcement mechanisms to capture meshing and refinement behaviours simultaneously. While these automations generate accurate descriptions of sensory and constructive feedback, they limit stepwise design control, reducing flexibility and applicability. A model that decouples the two “phases” of Physarum behaviour would enable multistage control over network growth. Here we introduce such a system, first by producing a site-responsive mesh from a population of nutrient-attracted agents, and then by independently calculating from it a flexible, proximity-defined shortest-walk to produce a final network. We develop and map networks within existing urban environments that perform similarly to those biologically grown, establishing a versatile tool for bio-inspired urban network design.

Some natural structures show three-dimensional morphologies on the micro- and nano-scale, characterized by levels of symmetry and complexity well far beyond those fabricated by best technologies available. This is the case of diatoms, unicellular microalgae, whose protoplasm is enclosed in a nanoporous microshell, made of hydrogenated amorphous silica, called frustule. We have studied the optical properties of Arachnoidiscus sp. single valves both in visible and ultraviolet range. We found photonic effects due to diffraction by ordered pattern of pores and slits, accordingly to an elaborated theoretical model. For the first time, we experimentally revealed spatial separation of focused light in different spots, which could be the basis of a micro-bio-spectrometer. Characterization of such intricate structures can be of great inspiration for photonic devices of next generation.

Stoichiometry of leaf macronutrients can provide insight into the tradeoffs between leaf structural and metabolic investments. Structural carbon (C) in cell walls is contained in lignin and polysaccharides (cellulose, hemicellulose, and pectins). Much of leaf calcium (Ca) and a fraction of magnesium (Mg) were further bounded with cell wall pectins. The macronutrients phosphorus (P), potassium (K), and nitrogen (N) are primarily involved in cell metabolic functions. There is limited information on the functional interrelations among leaf C and macronutrients, and the functional dimensions characterizing the leaf structural and metabolic tradeoffs are not widely appreciated. We investigated the relationships between leaf C and macronutrient (N, P, K, Ca, Mg) concentrations in two widespread broad-leaved deciduous woody species Quercus wutaishanica (90 individuals) and Betula platyphylla (47 individuals), and further tested the generality of the observed relationships in 222 woody eudicots from 15 forest ecosystems. In a subsample of 20 broad-leaved species, we also analyzed the relationships among C, Ca, lignin, and pectin concentrations in leaf cell walls. We found a significant leaf C–Ca tradeoff operating within and across species and across ecosystems. This basic relationship was explained by variations in the share of cell wall lignin and pectin investments at the cell scale. The C–Ca tradeoffs were mainly driven by soil pH and mean annual temperature and precipitation, suggesting that leaves were more economically built with less C and more Ca as soil pH increased and at lower temperature and lower precipitation. However, we did not detect consistent patterns among C–N, and C–Mg at different levels of biological organization, suggesting substantial plasticity in N and Mg distribution among cell organelles and cell protoplast and cell wall. We observed two major axes of macronutrient differentiation: the cell-wall structural axis consisting of protein-free C and Ca and the protoplasm metabolic axis consisting of P and K, underscoring the decoupling of structural and metabolic elements inherently linked with cell wall from protoplasm investment strategies. We conclude that the tradeoffs between leaf C and Ca highlight how carbon is allocated to leaf structural function and suggest that this might indicate biogeochemical niche differentiation of species.

In this article was applied a comprehensive research method which made it possible to quite fully investigate the mechanism of the effect of electrical impulses on the protoplasm of cells and determine the optimal parameters of such effect on plant raw materials, ensuring high efficiency of their use to increase the juice yield. The complex research method made it possible to obtain the necessary data for the implementation of the electrical method for intensifying the process of extracting juice from plant materials. Due to the fact that the issues related to the use of electrical impulses for the processing of plant materials have been little studied and there is no sufficiently clear understanding of the mechanism of such an effect on living cells, we made an attempt to investigate the mechanism of this process. A technique has been developed for studying the dynamics of the action of electric current on plant tissue cells. We expressed the yield of juice from raw materials as a percentage of the weight of the pulp, which was processed and pressed. Thus, a comparison of the results of individual experiments showed an absolute increase in juice yield as a percentage.

Heavy metal contamination in aquatic environments poses a significant threat to microbial communities, yet the subcellular responses of phytoplankton to metal stress remain poorly understood. In particular, the effects of heavy metal exposure on the structural and physiological properties of diatoms require further investigation. Here, we analyze the impact of cadmium (Cd) and copper (Cu) exposure on the subcellular structures of the diatom Skeletonema pseudocostatum using holographic tomography. This imaging technique enables detailed visualization and quantitative analysis of diatom subcomponents, including frustules, protoplasm, vacuoles, and chloroplasts, under varying metal concentrations. The study aims to understand the changes in the mean refractive index (RI) and concentration (e.g., the ratio among cell dry mass and its biovolume) as indicators of cellular response to metal stress and to infer if such diatom can be used as sentinel species of heavy metal pollution. Findings indicate that diatoms exhibit significant variations in RI and internal cell density when exposed to different metal concentrations. Lower RI values observed at higher metal concentrations, can be considered as a sign of stress due to cytoplasm extrusion and/or vacuolization. The results highlight the potential of using S. pseudocostatum as a bioindicator for monitoring water metal pollution. Moreover, the results show that holographic tomography as useful tool for non-invasive, high-resolution cellular imaging of phytoplankton in environmental studies.

This article presents the results of experimental studies to determine the effect of electrical impulse processing parameters on the output of juice from the pulp. It is based on the effect of pulse energy and voltage on apple juice. The influence of an electrical impulse on the production of juice before pressing fruit pulps has been studied. It is based on the optimal parameters of the grinding rate of the raw material, which affects the efficiency of processing with electric pulses. An additional large amount of juice was detected after the pulp was treated with electrical impulses. Based on the voltage dependence of the juice obtained from the raw material and the direct interaction of the field with the electrically charged system of the cell protoplasm.