Activation of MAPK signaling pathway during nitrogen-deficiency responses in Ulva Prolifera

Background: Ulva prolifera is one of the main seaweeds (or macroalgae) species that causes “green tides”. This alga inhabits the estuarine areas that exhibit changes in nutrient contents, which include changes in nitrogen (N) levels, while the mechanisms through which these microalgae resist N deficiency remains unclear. Results: We amplified the full-length sequences and quantified expression of genes involved in the nitrogen metabolism process, the data indicated that nitrate reductase, nitrite reductase, and glutamine synthase increased after nitrogen deprivation in Ulva prolifera. Hence, although the ratio of cell-wall regeneration did not change, the apoptosis rates of protoplasts of Ulva prolifera increased after this deficiency. Furthermore, a decreased in N supplies triggered the activation of MAPK signaling, and SB239063, a p38 MAPKα/β inhibitor, enhanced the effects of N deficiency on the mortality of protoplasts and decreased the capacity for cell-wall regeneration. Conclusions: All the data provided evidence that MAPK signaling had functional roles in helping U. prolifera adapt to fluctuations in N availability within a short time. Hence, the application of biochemical reagents on cell-wall regeneration on the surface of protoplasts provided a new perspective in the genetic breeding of Ulva prolifera.

Dynamics of structural polysaccharides deposition on the plasma-membrane surface of plant protoplasts during cell wall regeneration

In this study, dynamic changes in structural polysaccharide deposition on the plasma membrane and cortical microtubules (CMTs) behavior were monitored in protoplasts isolated from white birch callus using confocal laser scanning microscopy and atomic force microscopy. We focused on the influence of an environmental stimulus on cell wall regeneration in protoplasts by employing an acidic culture medium containing a high concentration of Ca2+ (the stress condition). Under the non-stress condition, cellulose microfibrils and callose were initially synthesized, and thereafter deposited on the plasma membrane as “primary cell wall material”. Under the stress condition, callose micro-sized fibers were secreted without cell wall regeneration. Behavior of CMTs labeled with mammalian microtubule-associated protein 4 with green fluorescent protein in transgenic protoplasts was monitored by time-lapse video analysis. Under the non-stress condition, CMTs behavior showed a linear arrangement at a fixed position, whereas unfixed manner of CMTs behavior was observed under the stress condition. These findings indicate that excessive Ca2+ affects cellulose synthesis and CMTs dynamics in plant protoplasts. Current study first demonstrated dynamics of cell wall regeneration and CMTs in woody protoplast, which provides novel insight to aid in understanding early stages of primary cell wall formation in plants.

THE ROLE OF POTASSIUM AND CALSIUM IN IMPROVING THE QUALITY AND SHELF LIFE OF TOMATO (Lycopersicum esculentum var. servo)

Tomato has the characteristics natural to damage. Damage fruits are caused by destitute of fruit quality and sensory attributes. The loss of tomato production on harvest in developing countries reached 50% due to the long duration of tomato distribution. Servo varieties of tomatoes are in demand by farmers because of their genetic advantages, high productivity, and abundant fruit weights. The shortage of servo varieties of tomatoes is the short shelf life of fruit, which is seven days after harvest. Short shelf life is influenced by fruit thickness and fruit hardness. In improving the quality and shelf life of tomatoes, potassium (K) nutrition plays a role in photosynthetic translocation, strengthens the cell wall, and involved in the lignification process of sclerenchyma tissue. Tomatoes, as climacteric fruits have a high respiration rate influenced by ethylene. Ethylene production can be inhibited by calcium chloride (CaCl2) application by strengthening the cell wall mechanism, cross-link with pectin, and increase the cell wall regeneration can change the texture of the fruit become harder, and it reduces sensitivity to physiological damage. Based on the treatment of this research, the quality and shelf life of servo varieties of tomato is increased.

Studies on cell wall regeneration in protoplast culture of legumes – the effect of organic medium additives on cell wall components

The cell wall regeneration in mesophyll protoplasts of yellow lupin and grass pea was studied. The occurrence of cell wall components: cellulose, callose and arabinogalactan proteins was analysed during 15 days of culture. Protoplasts were cultured in different media to test the effect of culture environment on the cell wall regeneration. Medium supplementation with 2 mg/l chitosan resulted in prolonged viability, more balanced cellulose resynthesis, increased callose formation and induction of mitotic divisions in protoplast-derived cells of both examined legumes. In chitosan-enriched medium arabinogalactan proteins were detected in cell plates of divided cells. Medium rich in additional organic compounds, i.e. free amino acids, organic acids and monosaccharides, was inferior to media of simpler composition. In both species the relatively quick cellulose resynthesis negatively affected the viability of protoplast-derived cells. In grass pea cellulose appeared during 24 h of culture. In yellow lupin the process started significantly later and after 10 days the frequency of walled cells did not exceed 50%. Callose was detected in cultures of both species and its pattern suggested that the synthesis was unlikely to be a result of protoplast wounding. Arabinogalactan proteins were localized in cell walls of different types of cells: dividing, elongating, but predominantly in degenerating ones. Occurrence and organization of the cell wall components studied were discussed in relation to recalcitrance of grass pea and yellow lupin protoplasts.