Regulation of the reconstituted chloroplast phosphate translocator by an H+ gradient

This report describes the influence of ΔpH on the transport of phosphate, triose phosphate and 3-phosphoglycerate catalyzed by the phosphate translocator in a reconstituted system. The H⁺ gradient across the liposome membrane is adjusted by the addition of external buffer solution and maintained for several minutes. The following results are obtained: (1) An inward directed H⁺ gradient leads to an increase of 3-phosphoglycerate transport and to a decrease of phosphate and triose phosphate transport. (2) An H⁺ gradient in the opposite direction results in a restriction of 3-phosphoglycerate influx whereas the influx of phosphate and triose phosphate is enhanced. (3) The magnitude of the pH effect depends on the internal substrate. Compared to the homoexchange mode, the effect of applied ΔpH is more pronounced in the heteroexchange mode. (4) Transport of phosphate and 3-phosphoglycerate is influenced by ΔpH in a different manner. In the case of phosphate and triose phosphate transport the observed effects are associated with changes in the apparent K_m values whereas in the case of 3-phosphoglycerate transport the application of a pH gradient is linked to a change of V_max. (5) In competition experiments with both substrates in the external medium, ΔpH influences the effect of phosphate as a competitive inhibitor of 3-phosphoglycerate transport whereas the effect of 3-phosphoglycerate on phosphate transport is not affected by a pH gradient. (6) The measured apparent K_m and V_max values under the influence of ΔpH can be used for the calculation of substrate fluxes across the envelope during illumination. It can be demonstrated that the increase of stromal pH in the light gives rise to a considerable change in the ratio of the substrates transported. Under conditions without pH gradient, the species transported out is mainly 3-phosphoglycerate and the species transported in is mainly triose phosphate. These fluxes are reversed when a pH gradient is applied (light conditions).     

The mechanism of the control of carbon fixation by the pH in the chloroplast stroma. Studies with nitrite-mediated proton transfer across the envelope.

1. CO2 fixation of intact spinach chloroplasts is inhibited by nitrite in a pH-dependent mode. At pH 7.3 in the medium 1 mM NaNO2 and at pH 7.9 5 mM NaNO2 were required for 50% inhibition. 2. The addition of nitrite leads to an acidificiation in the stroma. It appears that nitrite renders the envelope permeable for protons resulting in a breakdown of the pH gradient between the external space and the stroma. 3. In view of earlier results on the pH sensitivity of C02 fixation it is concluded that this pH shift in the stroma is responsible for the observed inhibition of CO2 fixation by nitrite. 4. Octanoate and to some extent also high concentrations of bicarbonate and acetate have a similar effect as nitrite in inhibiting CO2 fixation through an acidification in the stroma. 5. The levels of the intermediates of the CO2 fixation cycle were measured. A strong rise of the levels of fructose- and sedoheptulose biphosphates and a concomitant decrease of the corresponding monophosphates was observed during inhibition of CO2 fixation. It appears that the enzymatic steps of the CO2 fixation cycle responsible for the overall inhibition of CO2 fixation caused by lowering of the H+ concentration in the stroma are fructose- and sedopheptulose bisphosphatase. These two enzymes have an important function in the light regulation of CO2 fixation.     

Subcellular volumes and metabolite concentrations in spinach leaves

Cellular and subcellular volumes in mature leaves of spinach (Spinacia oleracea L. US Hybrid 424) were determined stereologically from light and electron micrographs. Forty-nine-day-old leaves of spinach with a total leaf volume of 1177 μL per mg chlorophyll (Chl) were found to be composed of 3% epidermis, 58% mesophyll, 1% vascular tissue, 5% apoplasm and 32% gas space. In the epidermal cells 89% of the volume was occupied by the vacuole. The mesophyll cells consisted, expressed in mg·Chl⁻¹, of 546 μL (79%) vacuole, 66 μL (9.5%) chloroplast stroma, 24 μL (34%) cytosol, 3.7 μL (0.5%) mitochondria and 2.1 μL (0.3%) nucleus. From previous measurements of the subcellular levels of sucrose, of phosphorylated intermediates of carbohydrate metabolism, of malate, oxoglutarate and various amino acids in illuminated leaves, and the above subcellular volumes, the corresponding subcellular metabolite concentrations have been determined. Of the substances measured, only with malate was the concentration higher in the vacuole than in the cytosol. The concentration of sucrose in the cytosol was 5 times, and that of amino acids even 30 times higher than in the vacuole.     

Production and diurnal utilization of assimilates in leaves of spinach (Spinacia oleracea L.) and barley (Hordeum vulgare L.)

Rates of CO₂ fixation during the light period and the rates of CO₂ release during the night period were measured using mature leaves from 39- to 49-d-old spinach (Spinacia oleracea L., US Hybrid 424; grown in 9 h light, 15 h darkness, daily) and mature leaves from 21-d-old barley (Hordeum vulgare L., cv. Apex; grown in 14 h light, 10 h darkness, daily). At certain times during the light and dark periods leaves were harvested for assay of their contents of soluble carbohydrates, starch, malate and the various amino acids. Evaluation of the results of these measurements shows that in spinach and barley leaves 46% and 26%, respectively, of the carbon assimilated during the light period is deposited in the leaves for export during the night period. Taking into account the carbon consumption in the source leaves by dark respiration, it is evaluated that rates of assimilate export during the light period from spinach and barley leaves [38 and 42 atom C · (mg Chl)^–1 · h^–1] are reduced in the dark period to 16 atom C · (mg Chl)^–1 · h^–1 in both species. The calculated C/N ratios of the photoassimilates exported during the dark period were 0.029 and 0.015 for spinach and barley leaves, respectively.This work was supported by the Deutsche Forschungsgemeinschaft. We thank Dr. Dieter Heineke for stimulating discussions and Mrs. Petra Hoferichter and Mrs. Marita Feldkämper for their technical assistance.     

Osmotic regulation of betaine homocysteine-S-methyltransferase expression in H4IIE rat hepatoma cells

Cell hydration changes critically affect liver metabolism and gene expression. In the course of gene expression studies using nylon cDNA-arrays we found that hyperosmolarity (405 mosmol/l) suppressed the betaine-homocysteine methyltransferase (Bhmt) mRNA expression in H4IIE rat hepatoma cells. This was confirmed by Northern blot and real-time quantitative RT-PCR analysis, which in addition unraveled a pronounced induction of Bhmt mRNA expression by hypoosmotic (205 mosmol/l) swelling. Osmotic regulation of Bhmt mRNA expression was largely paralleled at the levels of Bhmt protein and enzymatic activity. Like hyperosmotic NaCl, hyperosmotic raffinose but not hyperosmotic urea suppressed Bhmt mRNA expression, suggesting that cell shrinkage rather than increased ionic strength or hyperosmolarity per se is the trigger. Hypoosmolarity increased the expression of a reporter gene driven by the entire human BHMT promoter, whereas destabilization of BHMT mRNA was observed under hyperosmotic conditions. Osmosensitivity of Bhmt mRNA expression was impaired by inhibitors of tyrosine kinases and cyclic nucleotide-dependent kinases. The osmotic regulation of BHMT may be part of a cell volume-regulatory response and additionally lead to metabolic alterations that depend on the availability of betaine-derived methyl groups.     

The role of pH in the regulation of carbon fixation in the chloroplast stroma. Studies on CO2 fixation in the light and dark.

1. The pH in the stroma and in the thylakoid space has been measured in a number of chloroplast preparations in the dark and in the light at 20 degrees C. Illumination causes a decrease of the pH in the thylakoid space by 1.5 and an increase of the pH in the stroma by almost 1 pH unit. 2. CO2 fixation is shown to be strongly dependent on the pH in the stroma. The pH optimum was 8.1, with almost zero activity below pH 7.3.Phosphoglycerate reduction, which is a partial reaction of CO2 fixation, shows very little pH dependency. 3. Low concentrations of the uncoupler m-chlorocarbonylcyanide phenylhydrazone (CCCP) inhibit CO2 fixation without affecting phosphoglycerate reduction. This inhibition of CO2 fixation appears to be caused by reversal of light induced alkalisation in the stroma by CCCP. 4. Methylamine has a very different effect compared to CCCP. Increasing concentrations of methylamine inhibit CO2 fixation and phosphoglycerate reduction to the same extent. The light induced alkalisation of the stroma appears not to be significantly inhibited by methylamine, but the protons in the thylakoid space are neutralized. The inhibition of CO2 fixation by higher concentrations of methylamine is explained by an inhibition of photophosphorylation. It appears that methylamine does not abolish proton transport. 5. It is shown that intact chloroplasts are able to fix CO2 in the dark, yielding 3-phosphoglycerate. This requires the addition of dihydroxyacetone phosphate as precursor of ribulosemonophosphate and also to supply ATP, and the addition of oxaloacetate for reoxidation of the NADPH in the stroma. 6. Dark CO2 fixation in the presence of dihydroxyacetone phosphate and oxaloacetate has the same pH dependency as CO2 fixation in the light. This demonstrates that CO2 fixation in the dark is not possible, unless the pH in the medium is artificially raised to pH 8.8.     

A multi‐dimensional approach for fractionating proteins using charged membranes

In an effort to increase selectivity among proteins with crossflow ultrafiltration, we offer and demonstrate a comprehensive approach to fractionate proteins of similar molecular weight and relatively close pI values. This multidimensional approach involves optimizing membrane charge type and density together with operating conditions such as precise control of pH, ionic strength, and transmembrane pressure for reduced membrane fouling. Each filtration experiment was performed in cross‐flow configuration for ～20 min, allowing fast screening for optimal separation as determined by maximum selectivity, Ψ, and purity, P. Using our comprehensive approach for fractionating mixtures RNase A–lysozyme and BSA–hemoglobin, we obtained values of Ψ = 9.1, P = 95.7%, and Ψ = 6.5, P = 62.1%, respectively. Biotechnol. Bioeng. 2013; 110: 1704–1713. © 2013 Wiley Periodicals, Inc.