Your search keyword '"W.N Konings"' showing total 2 results

1. Ion permeability of the cytoplasmic membrane limits the maximum growth temperature of bacteria and archaea

Author

Trees Ubbink-Kok, W.N Konings, Arnold J. M. Driessen, M. G. L. Elferink, J.L C M van de Vossenberg, GBB Microbiology Cluster, Molecular Microbiology, and Groningen Biomolecular Sciences and Biotechnology

Subjects

Cytoplasm, Cell Membrane Permeability, Sodium, chemistry.chemical_element, Microbiology, Ion, Membrane Lipids, LIPID BILAYERS, Lipid bilayer, Molecular Biology, PROTON CONDUCTANCE, CLOSTRIDIUM-FERVIDUS, Ion Transport, Bacteria, biology, Thermophile, Temperature, Biological membrane, BIOLOGICAL-MEMBRANES, biology.organism_classification, Archaea, TRANSPORT, THERMAL ADAPTATION, Membrane, chemistry, Biochemistry, Permeability (electromagnetism), Liposomes, ACID, Biophysics, SP-NOV, BACILLUS-STEAROTHERMOPHILUS, Protons, PHOSPHOLIPID-BILAYERS

Abstract

Protons and sodium ions are the most commonly used coupling ions in energy transduction in bacteria and archaea. At their growth temperature, the permeability of the cytoplasmic membrane of thermophilic bacteria to protons is high compared with that of sodium ions. In some thermophiles, sodium is the sole energy-coupling ion. To test whether sodium is the preferred coupling ion at high temperatures, the proton- and sodium permeability was determined in liposomes prepared from lipids isolated from various bacterial and archaeal species that differ in their optimal growth temperature. The proton permeability increased with the temperature and was comparable for most species at their respective growth temperatures. Liposomes of thermophilic bacteria are an exception in the sense that the proton permeability is already high at the growth temperature. In all liposomes, the sodium permeability was lower than the proton permeability and increased with the temperature. The results suggest that the proton permeability of the cytoplasmic membrane is an important parameter in determining the maximum growth temperature.

Published

1995

2. Expression of the gltP gene of Escherichia coli in a glutamate transport-deficient mutant of Rhodobacter sphaeroides restores chemotaxis to glutamate

Author

W.N Konings, Berend Tolner, Mariken H. J. Jacobs, T. van der Heide, and Arnold J. M. Driessen

Subjects

chemistry.chemical_classification, biology, Binding protein, Mutant, Protein-glutamate O-methyltransferase, Glutamate receptor, Chemotaxis, biology.organism_classification, Microbiology, Amino acid, Glutamine, Rhodobacter sphaeroides, chemistry, Biochemistry, Molecular Biology

Abstract

Rhodobacter sphaeroides is chemotactic to glutamate and most other amino acids. In Escherichia coli, chemotaxis involves a membrane-bound sensor that either binds the amino acid directly or interacts with the binding protein loaded with the amino acid. In R. sphaeroides, chemotaxis is thought to require both the uptake and the metabolism of the amino acid. Glutamate is accumulated by the cells via a binding protein-dependent system. To determine the role of the binding protein and transport in glutamate taxis, mutants were created by Tn5 insertion mutagenesis and selected for growth in the presence of the toxic glutamine analogue gamma-glutamyl-hydrazide. One of the mutants, R. sphaeroides MJ7, was defective in glutamate uptake but showed wild-type levels of binding protein. The mutant showed no chemotactic response to glutamate. Both glutamate uptake and chemotaxis were recovered when the gltP gene, coding for the H+-linked glutamate carrier of E. coli, was expressed in R. sphaeroides MJ7. It is concluded that the chemotactic response to glutamate strictly requires uptake of glutamate, supporting the view that intracellular metabolism is needed for chemotaxis in R. sphaeroides.

Published

1995