Protons and how they are transported by proton pumps.

The very high mobility of protons in aqueous solutions demands special features of membrane proton transporters to sustain efficient yet regulated proton transport across biological membranes. By the use of the chemical energy of ATP, plasma-membrane-embedded ATPases extrude protons from cells of plants and fungi to generate electrochemical proton gradients. The recently published crystal structure of a plasma membrane H(+)-ATPase contributes to our knowledge about the mechanism of these essential enzymes. Taking the biochemical and structural data together, we are now able to describe the basic molecular components that allow the plasma membrane proton H(+)-ATPase to carry out proton transport against large membrane potentials. When divergent proton pumps such as the plasma membrane H(+)-ATPase, bacteriorhodopsin, and F(O)F(1) ATP synthase are compared, unifying mechanistic premises for biological proton pumps emerge. Most notably, the minimal pumping apparatus of all pumps consists of a central proton acceptor/donor, a positively charged residue to control pK(a) changes of the proton acceptor/donor, and bound water molecules to facilitate rapid proton transport along proton wires.

Immunohistochemical localisation of ubiquitin and the proteasome in sunflower (Helianthus annuus cv. Giganteus).

This study provides an immunohistochemical demonstration of the involvement of the ubiquitin- and proteasome-dependent pathway during differentiation and organogenesis in plants. The localisation of ubiquitin and the proteasome was studied in meristems, leaves, stems and roots of sunflower (Helianthus annuus L. cv. Giganteus). By using a new technique that enhances very low antigen signals, we obtained information on the structural distribution of the ubiquitin- and proteasome-dependent pathway, and of the importance of this pathway during organogenesis and plant development. Ubiquitin and the proteasome showed overall similarities in their cellular localisation. The highest antigenic signal was observed in the root and shoot apical meristems, in leaf primordia and vascular tissue. The cambium showed less expression than the apical meristems. During adventitious root formation in cuttings, no sign of increased expression was observed within dedifferentiating tissue, but as organogenesis progressed, the antigenic signal of ubiquitin and the proteasome gradually increased in the developing roots. Comparison of immunochemical results and Western blots demonstrated that important changes in the cellular antigen signal could only be detected by immunochemistry.

Conjugation of ubiquitin to proteins from green plant tissues.

Conjugation of the polypeptide ubiquitin to endogenous proteins was studied in oat (Avena sativa L.) plants, and particularly in green tissues. Conjugating activity in leaf extracts was different from that in root extracts, and in both was less than in etiolated tissue. The conjugates were identified by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), and their formation was both time- and ATP-dependent and had a pH optimum of about 8.2. The assay had a high affinity for ATP with a probable K(m) of less than 50 micromolar. The ubiquitin conjugating system was also shown to be present in isolated chloroplasts, and ubiquitin could be conjugated to endogenous proteins of lyzed chloroplasts in which the ATP concentrations were reduced by preincubation or desalting. SDS-PAGE analysis led to the suggestion that the large and small subunits of ribulose-1,5-bisphosphate carboxylase (RuBPCase) may be able to be ubiquitinated, and we have shown that ubiquitin can stimulate the in vitro breakdown of (125)I-labeled RuBPCase. These results invite the speculation that ubiquitin may be involved in the regulation of protein turnover in green plants.

Regulation of Carbon Partitioning in Source and Sink Leaf Parts in Sweet Pepper (Capsicum annuum L.) Plants : Role of Fructose 2,6-Bisphosphate.

Area expansion rate, partitioning of photosynthetically fixed carbon, and levels of fructose 2,6-bisphosphate (fru-2,6-P(2)) were determined in individual parts of developing leaves of sweet pepper (Capsicum annuum L.). The base was rapidly expanding and allocated less carbon to sucrose synthesis in comparison to the leaf tip, where expansion had almost stopped. The change in leaf expansion rate and carbon partitioning happened gradually. During day time levels of fru-2,6-P(2) were consistently higher in the leaf base than in the leaf tip. Leaf expansion rate and carbon partitioning were closely related to day time levels of fru-2,6-P(2), suggesting that fru-2,6-P(2) is an important factor in adjustment of metabolism during sink-to-source transition of leaf tissue. The levels of fru-2,6-P(2) changed markedly after a dark-to-light transition in the leaf base, but not in the leaf tip, suggesting that regulatory systems based on fru-2,6-P(2) are different in sink and source leaf tissue. During the period upon dark-to-light transition the variations in level of fru-2,6-P(2) did not show a close correlation to changes in the carbon partitioning, until the metabolism had reached a steady state.

Changes in carbohydrate composition in wheat and pea seedlings induced by calcium deficiency.

Wheat (Triticum aestivum L. cv Jubilar) seedlings were grown for 10 days in hydroponics with or without calcium. In the leaves, Ca deficiency caused the level of ethanol soluble carbohydrate to increase between 2-and 10-fold, enhanced dark respiration and decreased CO(2) fixation capacity. Sucrose was the major carbohydrate to accumulate in wheat roots.

Metabolism of Oat Leaves during Senescence : VIII. The Role of L-Serine in Modifying Senescence.

The mechanism whereby l-serine specifically promotes the dark senescence of detached oat (Avena) leaves has been examined. The fact that this promotion is strong in darkness but very weak in white light has been explained, at least in part, by the finding that added serine is partly converted to reducing sugars in light. Labeled serine gives rise to (14)C-sugars and (14)CO(2). In the absence of CO(2), serine does cause chlorophyll loss in light and undergoes a decreased conversion to sugar.As to the large promotion of protease activity which accompanies senescence in the dark, reported earlier, careful purification of the proteases shows that the l-[(14)C]serine is not incorporated into these enzymes, although it is incorporated into the total protein. Cycloheximide decreases the overall synthesis both of protease and of total protein, but again [(14)C]serine does not impart radioactivity to the purified acid proteases. Even when serine is simply added to the protease assay the proteolysis is significantly increased. It is concluded that serine promotes the protease activity by synergizing with the enzyme, or by activating an apoenzyme.