Your search keyword '"Juke S. Lolkema"' showing total 4 results

1. Improved Acid Stress Survival of Lactococcus lactis Expressing the Histidine Decarboxylation Pathway of Streptococcus thermophilus CHCC1524

Author

Niels L. Mulder, Juke S. Lolkema, Hein Trip, Molecular Microbiology, Molecular Genetics, and Groningen Biomolecular Sciences and Biotechnology

Subjects

MECHANISM, Streptococcus thermophilus, Amino Acid Transport Systems, Decarboxylation, Carboxylic Acids, Bioenergetics, BIOGENIC-AMINES, Biochemistry, Amine transport, 03 medical and health sciences, TRANSCRIPTIONAL ANALYSIS, Bacterial Proteins, Stress, Physiological, OPERON, Histidine, Electrochemical gradient, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, ARGININE, 030306 microbiology, Lactococcus lactis, Cell Biology, respiratory system, Hydrogen-Ion Concentration, biology.organism_classification, Amino acid, LACTOBACILLUS-BUCHNERI, PROTON-MOTIVE FORCE, Glucose, chemistry, ESCHERICHIA-COLI, Multigene Family, Biocatalysis, Protons, Genetic Engineering, Flux (metabolism), human activities, Glycolysis, RESISTANCE, Histamine, GENERATION

Abstract

Degradative amino acid decarboxylation pathways in bacteria generate secondary metabolic energy and provide resistance against acid stress. The histidine decarboxylation pathway of Streptococcus thermophilus CHCC1524 was functionally expressed in the heterologous host Lactococcus lactis NZ9000, and the benefits of the newly acquired pathway for the host were analyzed. During growth in M17 medium in the pH range of 5–6.5, a small positive effect was observed on the biomass yield in batch culture, whereas no growth rate enhancement was evident. In contrast, a strong benefit for the engineered L. lactis strain was observed in acid stress survival. In the presence of histidine, the pathway enabled cells to survive at pH values as low as 3 for at least 2 h, conditions under which the host cells were rapidly dying. The flux through the histidine decarboxylation pathway in cells grown at physiological pH was under strict control of the electrochemical proton gradient (pmf) across the membrane. Ionophores that dissipated the membrane potential (ΔΨ) and/or the pH gradient (ΔpH) strongly increased the flux, whereas the presence of glucose almost completely inhibited the flux. Control of the pmf over the flux was exerted by both ΔΨ and ΔpH and was distributed over the transporter HdcP and the decarboxylase HdcA. The control allowed for a synergistic effect between the histidine decarboxylation and glycolytic pathways in acid stress survival. In a narrow pH range around 2.5 the synergism resulted in a 10-fold higher survival rate.

Published

2012

2. Cysteine-scanning mutagenesis reveals a highly amphipathic, pore-lining membrane-spanning helix in the glutamate transporter GltT

Author

Juke S. Lolkema, Wil N. Konings, Dirk Jan Slotboom, Groningen Biomolecular Sciences and Biotechnology, Enzymology, and Molecular Microbiology

Subjects

Protein Folding, Stereochemistry, PROTEINS, Amino Acid Transport System X-AG, Mutant, SUBSTRATE-BINDING, RAT-BRAIN, Biochemistry, ACCESSIBILITY, Geobacillus stearothermophilus, Cell membrane, HIGH-AFFINITY, REENTRANT LOOP, Bacterial Proteins, medicine, TOPOLOGY, Cysteine, Molecular Biology, Chemistry, Cell Membrane, Mutagenesis, Glutamate binding, Cell Biology, FAMILY, Transmembrane domain, medicine.anatomical_structure, SELECTIVITY, Helix, Mutagenesis, Site-Directed, ATP-Binding Cassette Transporters, Protein folding, BACILLUS-STEAROTHERMOPHILUS

Abstract

The carboxyl terminal membrane-spanning segment 8 of the glutamate transporter GltT of Bacillus stearothermophilus was studied by cysteine-scanning mutagenesis. 21 single cysteine mutants were constructed in a stretch ranging from Gly-574 to Gln-404, Two mutants were not expressed, four were inactive, and two showed severely reduced glutamate transport activity. Cysteine mutations at the other positions were well tolerated. Only the two most amino- and carboxyl-terminal mutants (G374C, I375C, S399C, and Q404C) could be labeled with the large thiol reagent fluorescein maleimide, indicating unrestricted access and a location in a loop structure outside the membrane. The labeling pattern of these mutants using membrane- permeable and -impermeable thiol reagents showed that the N and C termini of the mutated stretch are located extra- and intracellularly, respectively. Thus, the location of the membrane-spanning segment was confined to a stretch of 23 residues between Gly-374 and Ser-399. Cysteine residues in three mutants in the central part of the segment (M381C, V388C, and N391C) could be labeled with the small and flexible reagent a-aminoethyl methanethiosulfonate hydrobromide only, suggesting accessibility via a narrow aqueous pore. When the region was modeled as an cu-helix, all positions at which cysteine mutations lead to inactive or severely impaired transporters cluster on one face of this helix, The inactive mutants showed neither proton motive force-driven uptake activity nor exchange activity nor glutamate binding. The results indicate that transmembrane segment 8 forms an amphipathic alpha -helix, The hydrophilic face of the helix lines an aqueous pore and contains many residues that are important for activity.

Published

2001

3. Membrane topology of the C-terminal half of the neuronal, glial, and bacterial glutamate transporter family

Author

Juke S. Lolkema, Dirk Jan Slotboom, Wil N. Konings, Groningen Biomolecular Sciences and Biotechnology, Enzymology, and Molecular Microbiology

Subjects

DOMAINS, Synaptic cleft, PROTEINS, Amino Acid Transport System X-AG, FUNCTIONAL EXPRESSION, Blotting, Western, Molecular Sequence Data, Biology, medicine.disease_cause, RAT-BRAIN, Biochemistry, SEQUENCE, Fusion gene, Geobacillus stearothermophilus, HIGH-AFFINITY, medicine, Amino Acid Sequence, Molecular Biology, Escherichia coli, Protein secondary structure, Neurons, Glutamate receptor, Transporter, Cell Biology, Alkaline Phosphatase, GLT-1, Transmembrane domain, ESCHERICHIA-COLI, Membrane topology, Biophysics, ATP-Binding Cassette Transporters, Neuroglia

Abstract

Secondary glutamate transporters in neuronal and glial cells in the mammalian central nervous system remove the excitatory neurotransmitter glutamate from the synaptic cleft and prevent the extracellular glutamate concentration to rise above neurotoxic levels. Secondary structure prediction algorithms predict 6 trans membrane helices in the first half of the transporters but fail in the C-terminal half where no clear helix-loop-helix motif is resolved in the hydropathy profile of the primary sequences. A number of previous studies have emphasized the importance of the C-terminal half of the molecules for the function. Here we determine the membrane topology of the C-terminal half of the glutamate transporters by applying the phoA gene fusion technique to the homologous bacterial glutamate transporter of Bacillus stearothermophilus. High sequence conservation and very similar hydropathy profiles in the C-terminal half warrant a similar folding as in the glutamate transporters of the mammalian central nervous system, The C-terminal half contains four putative transmembrane helices. The strong hydrophobic moment and substitution moment of the most C-terminal helix X that point to opposite faces of the helix suggest that the helix faces the lipid environment with its least conserved, hydrophobic face and the interior of the protein with its well conserved, hydrophilic face, Residues that were shown before to be critical for function cluster in helix X and VII.

Published

1996

4. Membrane Potential-generating Transport of Citrate and Malate Catalyzed by CitP of Leuconostoc mesenteroides

Author

Wil N. Konings, Charles Diviès, Philippe Schmitt, Juke S. Lolkema, Claire Marty-Teysset, and Groningen Biomolecular Sciences and Biotechnology

Subjects

Malates, STREPTOCOCCUS-LACTIS, LACTOCOCCUS, Biochemistry, Citric Acid, Membrane Potentials, VESICLES, ENERGY, chemistry.chemical_compound, Bacterial Proteins, Cations, NUCLEOTIDE-SEQUENCE, Citrate synthase, Citrates, Molecular Biology, Membrane potential, Membranes, FERMENTATION, Symporters, biology, Chemiosmosis, Vesicle, Biological Transport, Gene Expression Regulation, Bacterial, Cell Biology, Hydrogen-Ion Concentration, DIACETYLACTIS, biology.organism_classification, Kinetics, PROTON-MOTIVE FORCE, Membrane, chemistry, Leuconostoc mesenteroides, ESCHERICHIA-COLI, Symporter, biology.protein, KLEBSIELLA-PNEUMONIAE, Carrier Proteins, Citric acid, Leuconostoc

Abstract

Citrate uptake in Leuconostoc mesenteroides subsp. mesenteroides 19D is catalyzed by a secondary citrate carrier (CitP). The kinetics and mechanism of CitP were investigated in membrane vesicles of L. mesenteroides. The transporter is induced by the presence of citrate in the medium and transports both citrate and malate. In spite of sequence homology to the Na(+)-dependent citrate carrier of Klebsiella pneumoniae, CitP is not Na(+)-dependent, nor is CitP Mg(2+)-dependent. The pH gradient (delta pH) is a driving force for citrate and malate uptake into the membrane vesicles, whereas the membrane potential (delta psi) counteracts transport. An inverted membrane potential (inside positive) generated by thiocyanide diffusion can drive citrate and malate uptake in membrane vesicles. Analysis of the forces involved showed that a single unit of negative charge is translocated during transport. Kinetic analysis of citrate counterflow at different pH values indicated that CitP transports the dianionic form of citrate (Hcit2-) with an affinity constant of approximately 20 microns. It is concluded that CitP catalyzes Hcit2-/H+ symport. Translocation of negative charge into the cell during citrate metabolism results in the generation of a membrane potential that contributes to the protonmotive force across the cytoplasmic membrane, i.e. citrate metabolism in L. mesenteroides generates metabolic energy. Efficient exchange of citrate and D-lactate, a product of citrate/carbohydrate co-metabolism, is observed, suggesting that under physiological conditions, CitP may function as an electrogenic precursor/product exchanger rather than a symporter. The mechanism and energetic consequences of citrate uptake are similar to malate uptake in lactic acid bacteria.

Published

1995