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k+ + ratio)

Distribution by Scientific Domains

Life Sciences	83%

Selected Abstracts

Preservation of mouse liver tissue during cold storage in experimental solutions assessed by x-ray microanalysis

LIVER TRANSPLANTATION, Issue 3 2003
Inna Kozlova
The increasing use of organs for transplantation necessitates the development of optimal preservation techniques. The goal of this study was to investigate changes in elemental content in mouse liver cells during cold storage by x-ray microanalysis in parallel with morphologic studies. Tissue was stored at 4°C for 4 to 12 hours in normal Krebs-Ringer solution (high sodium/potassium ratio), modified Krebs-Ringer solution (low Na+/K+ ratio), Euro-Collins solution, University of Wisconsin (UW) solution, or seven modified versions of the UW solution. Incubation of liver in normal Krebs-Ringer solution caused a significant increase in sodium and decrease in potassium concentrations in contrast to incubation in other solutions. The concentration of sodium, potassium, and chlorine in the cells closely followed the concentration in the storage solution, indicating that the intracellular concentration of these ions during storage is entirely dependent on diffusion processes. The calcium concentration was independent of the storage solution used. Studies by light and transmission electron microscopy showed good preservation of hepatocytes after storage for 8 and 12 hours in UW solution and its variants, modified Krebs-Ringer solution and Euro-Collins solution, but showed moderate damage to mitochondria and swelling of the endoplasmic reticulum in normal Krebs-Ringer solution. In addition, damage to the sinusoidal endothelial cells was observed after 4 hours in normal Krebs-Ringer solution and after 8 to 12 hours in the other solutions. In conclusion, the only factor determining the intracellular concentration of diffusible ions after cold tissue storage is the ionic composition of the extracellular medium. X-ray microanalysis provides an objective method for assessing whether the intracellular ionic composition of tissue is maintained during storage. [source]

The gene sll0273 of the cyanobacterium Synechocystis sp. strain PCC6803 encodes a protein essential for growth at low Na+/K+ ratios

PLANT CELL & ENVIRONMENT, Issue 6 2000
S. Mikkat
ABSTRACT A mutant of Synechocystis sp. strain PCC6803 was obtained by random cartridge mutagenesis, which could not grow at low sodium concentrations. Genetic analyses revealed that partial deletion of the sll0273 gene, encoding a putative Na+/H+ exchanger, was responsible for this defect. Physiological characterization indicated that the sll0273 mutant exhibited an increased sensitivity towards K+, even at low concentrations, which was compensated for by enhanced concentrations of Na+. This enhanced Na+ demand could also be met by Li+. Furthermore, addition of monensin, an ionophore mediating electroneutral Na+/H+ exchange, supported growth of the mutant at unfavourable Na+/K+ ratios. Measurement of internal Na+ and K+ contents of wild-type and mutant cells revealed a decreased Na+/K+ ratio in mutant cells pre-incubated at a low external Na+/K+ ratio, while it remained at the level of the wild type after pre-incubation at a high external Na+/K+ ratio. We conclude that the Sll0273 protein is required for Na+ influx, especially at low external Na+ concentrations or low Na+/K+ ratios. This system may be part of a sodium cycle and may permit re-entry of Na+ into the cells, if nutrient/Na+ symporters are not functional or operating. [source]

The cyclic nucleotide-gated channel, AtCNGC10, influences salt tolerance in Arabidopsis

PHYSIOLOGIA PLANTARUM, Issue 3 2008
Kun-Mei Guo
Cyclic nucleotide-gated channels (CNGCs) in the plasma membrane transport K+ and other cations; however, their roles in the response and adaptation of plants to environmental salinity are unclear. Growth, cation contents, salt tolerance and K+ fluxes were assessed in wild-type and two AtCNGC10 antisense lines (A2 and A3) of Arabidopsis thaliana (L.) Heynh. Compared with the wild-type, mature plants of both antisense lines had altered K+ and Na+ concentrations in shoots and were more sensitive to salt stress, as assessed by biomass and Chl fluorescence. The shoots of A2 and A3 plants contained higher Na+ concentrations and significantly higher Na+/K+ ratios compared with wild-type, whereas roots contained higher K+ concentrations and lower Na+/K+ ratios. Four-day-old seedlings of both antisense lines exposed to salt stress had smaller Na+/K+ ratios and longer roots than the wild-type. Under sudden salt treatment, the Na+ efflux was higher and the K+ efflux was smaller in the antisense lines, indicating that AtCNGC10 might function as a channel providing Na+ influx and K+ efflux at the root/soil interface. We conclude that the AtCNGC10 channel is involved in Na+ and K+ transport during cation uptake in roots and in long-distance transport, such as phloem loading and/or xylem retrieval. Mature A2 and A3 plants became more salt sensitive than wild-type plants because of impaired photosynthesis induced by a higher Na+ concentration in the leaves. [source]