Arterial receptors for adrenal steroids and transport of electrolytes in vascular smooth muscle

The role of arterial receptors to mineralocorticoids (MC) and glucocorticoids (GC) in the induction by MC and GC of changes in transmembrane transport of sodium (Na+) and water was investigated. Implantation of Silastic rubber strips impregnated with 11-desoxycorticosterone acetate (DOCA) in rabbits was followed by a marked increase in vascular smooth muscle cell membrane permeability to Na+ and hypertension. Both of these effects were preventable with progesterone, an anti-MC at the steroid-receptor level, implanted in relative excess simultaneously with DOCA, in approximately 50% of the implanted animals. The other 50% were hydroxylating in vivo progesterone to 11-desoxycorticosterone (DOC) efficiently enough not to yield the necessary ratio of progesterone to DOC for the sufficient MC receptor blockage. In vascular smooth muscle cell culture, grown in the presence of steroids, GC but not MC increased intracellular water space. This increase was preventable by a potent synthetic anti-GC,RU 38486, a steroid with high affinity for GC receptors, added to culture medium along with GC. These results provide evidence that both the in vivo effect of MC on Na+ permeability and the induction of hypertension, and the in vitro effect of GC on water transport in cultured vascular smooth muscle cells are elicited through the receptor-mediated molecular mechanism(s) for action of these steroids in the arterial wall.     

Phosphorus deficiency induced by nitrogen input in Douglas fir in the Netherlands

Summary A re-examination of earlier NPK fertilization experiments in Douglas fir stands on sandy soils shows the effects of high nitrogen input by air pollution during the last 10–15 years on plant nutrition at these sites. In 1960, experimental plots showed a positive growth reaction to nitrogen, phosphorus, and potassium fertilization. All suffered from severe phosphorus deficiency in 1984, low phosphorus in the needles was invariably accompanied by a high nitrogen content, with all N/P ratios between 20 and 30. The same conclusion emerges from an independent investigation of nutrient status of a selection of Douglas fir stands. Hence, if stand productivity and a balanced nutrient status of the trees is to be maintained, the increase in atmospheric input of nitrogen calls for supplementary fertilization. Given the current N/P ratios in the needles, a positive growth response to phosphorus fertilization is to be expected.     

Siderophores and outer membrane proteins of antagonistic, plant-growth-stimulating, root-colonizing Pseudomonas spp

As an approach to understanding the molecular basis of the reduction in plant yield depression by root-colonizing Pseudomonas spp. and especially of the role of the bacterial cell surfaces in this process, we characterized 30 plant-root-colonizing Pseudomonas spp. with respect to siderophore production, antagonistic activity, plasmid content, and sodium dodecyl sulphate-polyacrylamide gel electrophoresis patterns of their cell envelope proteins. The results showed that all strains produce hydroxamate-type siderophores which, because of the correlation with Fe3+ limitation, are thought to be the major factor responsible for antagonistic activity. Siderophore-negative mutants of two strains had a strongly decreased antagonistic activity. Five strains maintained their antagonistic activity under conditions of iron excess. Analysis of cell envelope protein patterns of cells grown in excess Fe3+ showed that most strains differed from each other, although two classes of similar or identical strains were found. In one case such a class was subdivided on the basis of the patterns of proteins derepressed by iron limitation. Small plasmids were not detected in any of the strains, and only one of the four tested strains contained a large plasmid. Therefore, it is unlikely that the Fe3+ uptake system of the antagonistic strains is usually plasmid encoded.     

Resistance of citrus fruit to mass transport of water vapor and other gases

The resistance of oranges (Citrus sinensis L. Osbeck) and grapefruit (Citrus paradisi Macf.) to ethylene, O₂, CO₂, and H₂O mass transport was investigated anatomically with scanning electron microscope and physiologically by gas exchange measurements at steady state. The resistance of untreated fruit to water vapor is far less than to ethylene, CO₂ and O₂. Waxing partially or completely plugs stomatal pores and forms an intermittent cracked layer over the surface of fruit, restricting transport of ethylene, O₂, and CO₂, but not of water; whereas individual sealing of fruit with high density polyethylene films reduces water transport by 90% without substantially inhibiting gas exchange.

Stomata of harvested citrus fruits are essentially closed. However, ethylene, O₂ and CO₂ still diffuse mainly through the residual stomatal opening where the relative transport resistance (approximately 6,000 seconds per centimeter) depends on the relative diffusivity of each gas in air. Water moves preferentially by a different pathway, probably through a liquid aqueous phase in the cuticle where water conductance is 60-fold greater. Other gases are constrained from using this pathway because their diffusivity in liquid water is 10⁴-fold less than in air.

     

Osmotic regulation of aldose reductase protein synthesis in renal medullary cells

Renal medullary cells are normally exposed to high extracellular NaCl as part of the urinary concentrating mechanism. They react to this stress by accumulating sorbitol and other organic osmolytes. PAP-HT25, a line of epithelial cells derived from rabbit renal inner medulla, expresses this response. In hypertonic medium, these cells accumulate large amounts of sorbitol. There is a large increase in the amount of aldose reductase, which catalyzes production of sorbitol from glucose. The purpose of the present study was to investigate whether the aldose reductase protein increases because of faster synthesis or slower degradation. We measured the rate of synthesis and degradation of aldose reductase protein by pulse-chase with [35S]methionine, followed by immunoprecipitation with specific antiserum and autoradiography. The protein synthesis rate was 6 times greater in cells grown in hypertonic (500 mosmol/kg) medium, than in those grown in normal (300 mosmol/kg) medium. When control cells were switched to hypertonic medium, the synthesis rate increased 15-fold by 24 h, then decreased to 11-fold after 48 h. In contrast, synthesis rate continued to increase past 24 h when accumulation of sorbitol was prevented by inhibiting aldose reductase activity with Tolrestat. Thus, there is a feedback mechanism by which cellular sorbitol accumulation inhibits aldose reductase protein synthesis. Degradation of aldose reductase protein was slow (only about 25% in 3 days) and was not affected by osmolality. Thus, the osmoregulatory increase in aldose reductase protein is due to an increase in its synthesis rate and not to any change in its degradation.     

Combining industrial ecology tools to assess potential greenhouse gas reductions of a circular economy: Method development and application to Switzerland

Industrial ecology (IE) methodologies, such as input/output or material flow analysis and life cycle assessment (LCA), are often used for the environmental evaluation of circular economy strategies. Up to now, an approach that utilizes these methods in a systematic, integrated framework for a holistic assessment of a geographic region's sustainable circular economy potential has been lacking. The approach developed in this study (IE4CE approach) combines IE methodologies to determine the environmental impact mitigation potential of circular economy strategies for a defined geographic region. The approach foresees five steps. First, input/output analysis helps identify sectors with high environmental impacts. Second, a refined analysis is conducted using material flow and LCA. In step 3, circular strategies are used for scenario design and evaluated in step 4. In step 5, the assessment results are compiled and compared across sectors. The approach was applied to a case study of Switzerland, analyzing 8 sectors and more than 30 scenarios in depth. Carbon capture and storage (CCS) from waste incineration, biogas and cement production, food waste prevention in households, hospitality and production, and the increased recycling of plastics had the highest mitigation potential. Most of the scenarios do not influence each other. One exception is the CCS scenarios: waste avoidance scenarios decrease the reduction potential of CCS. A combination of scenarios from different sectors, including their impact on the CCS scenario potential, led to an environmental impact mitigation potential of 11.9 Mt CO₂-eq for 2050, which equals 14% of Switzerland's current consumption-based impacts.