Your search keyword '"Sijbrandi, R."' showing total 20 results

1. Het brigade diepe gevecht

Author

Sijbrandi, R. and Sijbrandi, R.

Published

2017

2. Channel properties of the translocator domain of the autotransporter Hbp of Escherichia coli

Author

Roussel-Jazédé, V.M.C., van Gelder, P., Sijbrandi, R., Rutten, L., Otto, B.R., Luirink, J., Gros, P., Tommassen, J.P.M., van Ulsen, J.P., Biomolecular Imaging, Crystal and Structural Chemistry, Molecular Microbiology, Sub Molecular Microbiology, Dep Scheikunde, Sub Biomolecular Imaging, Sub Crystal and Structural Chemistry, Molecular Microbiology, AIMMS, LaserLaB - Analytical Chemistry and Spectroscopy, Biomolecular Imaging, Crystal and Structural Chemistry, Sub Molecular Microbiology, Dep Scheikunde, Sub Biomolecular Imaging, and Sub Crystal and Structural Chemistry

Subjects

Signal peptide, Protein Folding, medicine.medical_treatment, Biology, Neisseria meningitidis, medicine.disease_cause, Inclusion bodies, Endopeptidases, medicine, Escherichia coli, Denaturation (biochemistry), Molecular Biology, Protease, Circular Dichroism, Serine Endopeptidases, Cell Biology, SDG 10 - Reduced Inequalities, Protein Structure, Tertiary, N-terminus, Spectrometry, Fluorescence, Biochemistry, International (English), Liposomes, Biophysics, Electrophoresis, Polyacrylamide Gel, Bacterial outer membrane, Autotransporters

Abstract

Autotransporters produced by Gram-negative bacteria consist of an N-terminal signal sequence, a C-terminal translocator domain (TD), and a passenger domain in between. The TD facilitates the secretion of the passenger across the outer membrane. It generally consists of a channel-forming β-barrel that can be plugged by an α-helix that is formed by a polypeptide fragment immediately N-terminal to the barrel domain in the sequence. In this work, we characterized the TD of the hemoglobin protease Hbp of Escherichia coli by comparing its properties with the TDs of NalP of Neisseria meningitidis and IgA protease of Neisseria gonorrhoeae. All TDs were produced in inclusion bodies and folded in vitro. In the case of the TD of Hbp, this procedure resulted in autocatalytic intramolecular processing, which mimicked the in vivo processing. Liposome-swelling assays and planar lipid bilayer experiments revealed that the pore of the Hbp TD was largely obstructed. In contrast, an Hbp TD variant that lacked only one amino-acid residue from the N terminus showed the opening and closing of a channel comparable to what was reported for the TD of NalP. Additionally, the naturally processed helix contributed to the stability of the TD, as shown by chemical denaturation monitored by tryptophan fluorescence. Overall these results show that Hbp is processed by an autocatalytic intramolecular mechanism resulting in the stable docking of the α-helix in the barrel. In addition, we could show that the α-helix contributes to the stability of TDs. © 2011 Informa UK, Ltd.

Published

2011

3. Ingezonden reactie op het artikel 'Geografische controlemaatregelen bij het verdedigend gevecht.'

Author

Sijbrandi, R. and Sijbrandi, R.

Published

2014

4. Transmembrane transport of peptidoglycan precursors across model and bacterial membranes

Author

van Dam, V., Sijbrandi, R., Kol, M.A., Swiezewska, E., de Kruijff, B., Breukink, E.J., Biochemie van Membranen, Membraan enzymologie, Dep Scheikunde, Sub Membrane Enzymology begr. 01-06-12, and Sub Algemeen Scheikunde

Subjects

lipids (amino acids, peptides, and proteins)

Abstract

Translocation of the peptidoglycan precursor Lipid II across the cytoplasmic membrane is a key step in bacterial cell wall synthesis, but hardly understood. Using NBD-labelled Lipid II, we showed by fluorescence and TLC assays that Lipid II transport does not occur spontaneously and is not induced by the presence of single spanning helical transmembrane peptides that facilitate transbilayer movement of membrane phospholipids. MurG catalysed synthesis of Lipid II from Lipid I in lipid vesicles also did not result in membrane translocation of Lipid II. These findings demonstrate that a specialized protein machinery is needed for transmembrane movement of Lipid II. In line with this, we could demonstrate Lipid II translocation in isolated Escherichia coli inner membrane vesicles and this transport could be uncoupled from the synthesis of Lipid II at low temperatures. The transport process appeared to be independent from an energy source (ATP or proton motive force). Additionally, our studies indicate that translocation of Lipid II is coupled to transglycosylation activity on the periplasmic side of the inner membrane.

Published

2007

5. Molecular insight into the pathogenetic synergy between E. coli and B. fragilis in secondary peritonitis

Author

Sijbrandi, R., Oudega, Bauke, Luirink, Joen, Otto, B.R., and Molecular Microbiology

Published

2006

6. Biosynthesis of K88 fimbriae in Escherichia coli: interaction of tip-subunit FaeC with the periplasmic chaperone FaeE and the outer membrane usher FaeD

Author

Mol, O., Oudhuis, W. C., Oud, R. P. C., Sijbrandi, R., J. Luirink, Harms, N., Oudega, B., and Molecular Microbiology

Published

2001

7. Channel properties of the translocator domain of the autotransporter Hbp of Escherichia coli

Author

Biomolecular Imaging, Crystal and Structural Chemistry, Molecular Microbiology, Sub Molecular Microbiology, Dep Scheikunde, Sub Biomolecular Imaging, Sub Crystal and Structural Chemistry, Roussel-Jazédé, V.M.C., van Gelder, P., Sijbrandi, R., Rutten, L., Otto, B.R., Luirink, J., Gros, P., Tommassen, J.P.M., van Ulsen, J.P., Biomolecular Imaging, Crystal and Structural Chemistry, Molecular Microbiology, Sub Molecular Microbiology, Dep Scheikunde, Sub Biomolecular Imaging, Sub Crystal and Structural Chemistry, Roussel-Jazédé, V.M.C., van Gelder, P., Sijbrandi, R., Rutten, L., Otto, B.R., Luirink, J., Gros, P., Tommassen, J.P.M., and van Ulsen, J.P.

Published

2011

8. Transmembrane transport of peptidoglycan precursors across model and bacterial membranes

Author

Biochemie van Membranen, Membraan enzymologie, Dep Scheikunde, Sub Membrane Enzymology begr. 01-06-12, Sub Algemeen Scheikunde, van Dam, V., Sijbrandi, R., Kol, M.A., Swiezewska, E., de Kruijff, B., Breukink, E.J., Biochemie van Membranen, Membraan enzymologie, Dep Scheikunde, Sub Membrane Enzymology begr. 01-06-12, Sub Algemeen Scheikunde, van Dam, V., Sijbrandi, R., Kol, M.A., Swiezewska, E., de Kruijff, B., and Breukink, E.J.

Published

2007

9. Crystal structure of hemoglobin protease, a heme binding autotransporter protein from pathogenic Escherichia coli

Author

Otto, B.R., Sijbrandi, R., Luirink, S., Oudega, B., Heddle, J.G., Mizutani, K., Park, S.Y., Tame, J.R.H., Otto, B.R., Sijbrandi, R., Luirink, S., Oudega, B., Heddle, J.G., Mizutani, K., Park, S.Y., and Tame, J.R.H.

Abstract

The acquisition of iron is essential for the survival of pathogenic bacteria, which have consequently evolved a wide variety of uptake systems to extract iron and heme from host proteins such as hemoglobin. Hemoglobin protease (Hbp) was discovered as a factor involved in the symbiosis of pathogenic Escherichia coli and Bacteroides fragilis, which cause intra-abdominal abscesses. Released from E. coli, this serine protease autotransporter degrades hemoglobin and delivers heme to both bacterial species. The crystal structure of the complete passenger domain of Hbp (110 kDa) is presented, which is the first structure from this class of serine proteases and the largest parallel β-helical structure yet solved. © 2005 by The American Society for Biochemistry and Molecular Biology, Inc.

Published

2005

10. Signal recognition particle (SRP)- mediated targeting and Sec-dependent translocation of an extracellular E. coli protein.

Author

Sijbrandi, R., Urbanus, M.L., ten Hagen-Jongman ten, C.M., Bernstein, H.D., Oudega, B., Otto, B.R., Luirink, S., Sijbrandi, R., Urbanus, M.L., ten Hagen-Jongman ten, C.M., Bernstein, H.D., Oudega, B., Otto, B.R., and Luirink, S.

Abstract

Hemoglobin protease (Hbp) is a hemoglobin-degrading protein that is secreted by a human pathogenic Escherichia coli strain via the autotransporter mechanism. Little is known about the earliest steps in autotransporter secretion, i.e. the targeting to and translocation across the inner membrane. Here, we present evidence that Hbp interacts with the signal recognition particle (SRP) and the Sec-translocon early during biogenesis. Furthermore, Hbp requires a functional SRP targeting pathway and Sec-translocon for optimal translocation across the inner membrane. SecB is not required for targeting of Hbp but can compensate to some extent for the lack of SRP. Hbp is synthesized with an unusually long signal peptide that is remarkably conserved among a subset of autotransporters. We propose that these autotransporters preferentially use the cotranslational SRP/Sec route to avoid adverse effects of the exposure of their mature domains in the cytoplasm.

Published

2003

11. RNA polymerase II complexes in the very early phase of transcription are not susceptible to TFIIS-induced exonucleolytic cleavage

Author

Sijbrandi, R., primary

Published

2002

12. Censuur.

Author

Sijbrandi, R.

Published

2013

13. Specificity of the transport of lipid II by FtsW in Escherichia coli.

Author

Mohammadi T, Sijbrandi R, Lutters M, Verheul J, Martin NI, den Blaauwen T, de Kruijff B, and Breukink E

Subjects

Amino Acid Sequence, Arginine chemistry, Arginine genetics, Arginine metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Biological Transport, Cell Wall metabolism, Escherichia coli genetics, Genetic Complementation Test, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Lysine chemistry, Lysine genetics, Lysine metabolism, Membrane Proteins chemistry, Membrane Proteins genetics, Microscopy, Fluorescence, Models, Molecular, Molecular Sequence Data, Molecular Structure, Mutation, Protein Structure, Secondary, Proteolipids metabolism, Sequence Homology, Amino Acid, Uridine Diphosphate N-Acetylmuramic Acid chemistry, Uridine Diphosphate N-Acetylmuramic Acid metabolism, Bacterial Proteins metabolism, Escherichia coli metabolism, Membrane Proteins metabolism, Uridine Diphosphate N-Acetylmuramic Acid analogs & derivatives

Abstract

Synthesis of biogenic membranes requires transbilayer movement of lipid-linked sugar molecules. This biological process, which is fundamental in prokaryotic cells, remains as yet not clearly understood. In order to obtain insights into the molecular basis of its mode of action, we analyzed the structure-function relationship between Lipid II, the important building block of the bacterial cell wall, and its inner membrane-localized transporter FtsW. Here, we show that the predicted transmembrane helix 4 of Escherichia coli FtsW (this protein consists of 10 predicted transmembrane segments) is required for the transport activity of the protein. We have identified two charged residues (Arg(145) and Lys(153)) within this segment that are specifically involved in the flipping of Lipid II. Mutating these two amino acids to uncharged ones affected the transport activity of FtsW. This was consistent with loss of in vivo activity of the mutants, as manifested by their inability to complement a temperature-sensitive strain of FtsW. The transport activity of FtsW could be inhibited with a Lipid II variant having an additional size of 420 Da. Reducing the size of this analog by about 274 Da resulted in the resumption of the transport activity of FtsW. This suggests that the integral membrane protein FtsW forms a size-restricted porelike structure, which accommodates Lipid II during transport across the bacterial cytoplasmic membrane., (© 2014 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2014

14. Identification of FtsW as a transporter of lipid-linked cell wall precursors across the membrane.

Author

Mohammadi T, van Dam V, Sijbrandi R, Vernet T, Zapun A, Bouhss A, Diepeveen-de Bruin M, Nguyen-Distèche M, de Kruijff B, and Breukink E

Subjects

Biological Transport, Recombinant Proteins metabolism, Bacterial Proteins metabolism, Cell Membrane metabolism, Cell Wall metabolism, Escherichia coli metabolism, Membrane Lipids metabolism, Membrane Proteins metabolism, Peptidoglycan metabolism

Abstract

Bacterial cell growth necessitates synthesis of peptidoglycan. Assembly of this major constituent of the bacterial cell wall is a multistep process starting in the cytoplasm and ending in the exterior cell surface. The intracellular part of the pathway results in the production of the membrane-anchored cell wall precursor, Lipid II. After synthesis this lipid intermediate is translocated across the cell membrane. The translocation (flipping) step of Lipid II was demonstrated to require a specific protein (flippase). Here, we show that the integral membrane protein FtsW, an essential protein of the bacterial division machinery, is a transporter of the lipid-linked peptidoglycan precursors across the cytoplasmic membrane. Using Escherichia coli membrane vesicles we found that transport of Lipid II requires the presence of FtsW, and purified FtsW induced the transbilayer movement of Lipid II in model membranes. This study provides the first biochemical evidence for the involvement of an essential protein in the transport of lipid-linked cell wall precursors across biogenic membranes.

Published

2011

15. Pbp, a cell-surface exposed plasminogen binding protein of Bacteroides fragilis.

Author

Sijbrandi R, Stork M, Luirink J, and Otto BR

Subjects

Amino Acid Sequence, Bacterial Outer Membrane Proteins genetics, Bacterial Outer Membrane Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Blotting, Western, Carrier Proteins genetics, Carrier Proteins metabolism, Cloning, Molecular, Databases, Protein, Escherichia coli metabolism, Gene Expression, Genes, Bacterial, Genetic Vectors, Humans, Plasmids, Plasminogen metabolism, Bacterial Outer Membrane Proteins isolation & purification, Bacterial Proteins isolation & purification, Bacteroides fragilis genetics, Bacteroides fragilis metabolism, Carrier Proteins isolation & purification

Abstract

The Gram-negative anaerobic bacterium B. fragilis is a member of the commensal flora of the human intestine, but is also frequently found in severe intra-abdominal infections. Several B. fragilis virulence factors have been implicated in the development of these infections. A B. fragilis protein of circa 60-kDa was identified as a putative plasminogen binding protein (Pbp). The corresponding gene was located, cloned, sequenced and the subcellular localization of the protein was investigated. Pbp was both determined in the outer membrane of B. fragilis and of E. coli that expressed the cloned protein. Protease accessibility studies showed that the protein is expressed at the cell surface. Importantly, we demonstrated that Pbp is sufficient and required for plasminogen binding to whole cells in both E. coli and B. fragilis. Pbp-like proteins were also detected in some other Bacteroides subspecies. The role of this potential B. fragilis virulence factor in pathogenicity is discussed.

Published

2008

16. Transmembrane transport of peptidoglycan precursors across model and bacterial membranes.

Author

van Dam V, Sijbrandi R, Kol M, Swiezewska E, de Kruijff B, and Breukink E

Subjects

Azoles pharmacology, Chromatography, Thin Layer, Cold Temperature, Fluorescent Dyes pharmacology, Nitrobenzenes pharmacology, Peptidoglycan Glycosyltransferase metabolism, Staining and Labeling, Uridine Diphosphate N-Acetylmuramic Acid metabolism, Cell Membrane metabolism, Cell Wall metabolism, Escherichia coli metabolism, Membrane Transport Proteins metabolism, Uridine Diphosphate N-Acetylmuramic Acid analogs & derivatives

Abstract

Translocation of the peptidoglycan precursor Lipid II across the cytoplasmic membrane is a key step in bacterial cell wall synthesis, but hardly understood. Using NBD-labelled Lipid II, we showed by fluorescence and TLC assays that Lipid II transport does not occur spontaneously and is not induced by the presence of single spanning helical transmembrane peptides that facilitate transbilayer movement of membrane phospholipids. MurG catalysed synthesis of Lipid II from Lipid I in lipid vesicles also did not result in membrane translocation of Lipid II. These findings demonstrate that a specialized protein machinery is needed for transmembrane movement of Lipid II. In line with this, we could demonstrate Lipid II translocation in isolated Escherichia coli inner membrane vesicles and this transport could be uncoupled from the synthesis of Lipid II at low temperatures. The transport process appeared to be independent from an energy source (ATP or proton motive force). Additionally, our studies indicate that translocation of Lipid II is coupled to transglycosylation activity on the periplasmic side of the inner membrane.

Published

2007

17. Crystal structure of hemoglobin protease, a heme binding autotransporter protein from pathogenic Escherichia coli.

Author

Otto BR, Sijbrandi R, Luirink J, Oudega B, Heddle JG, Mizutani K, Park SY, and Tame JR

Subjects

Amino Acid Sequence, Animals, Bacterial Proteins chemistry, Biological Transport, Catalytic Domain, Cattle, Cloning, Molecular, Crystallography, X-Ray, Electrons, Endopeptidases metabolism, Escherichia coli metabolism, Hemoglobins chemistry, Models, Molecular, Molecular Sequence Data, Plasmids metabolism, Polymerase Chain Reaction, Protein Binding, Protein Conformation, Protein Structure, Secondary, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Serine Endopeptidases chemistry, Endopeptidases chemistry, Heme chemistry

Abstract

The acquisition of iron is essential for the survival of pathogenic bacteria, which have consequently evolved a wide variety of uptake systems to extract iron and heme from host proteins such as hemoglobin. Hemoglobin protease (Hbp) was discovered as a factor involved in the symbiosis of pathogenic Escherichia coli and Bacteroides fragilis, which cause intra-abdominal abscesses. Released from E. coli, this serine protease autotransporter degrades hemoglobin and delivers heme to both bacterial species. The crystal structure of the complete passenger domain of Hbp (110 kDa) is presented, which is the first structure from this class of serine proteases and the largest parallel beta-helical structure yet solved.

Published

2005

18. Characterization of an iron-regulated alpha-enolase of Bacteroides fragilis.

Author

Sijbrandi R, Den Blaauwen T, Tame JR, Oudega B, Luirink J, and Otto BR

Subjects

Bacterial Outer Membrane Proteins, Bacterial Proteins analysis, Bacterial Proteins physiology, Bacteroides fragilis enzymology, Bacteroides fragilis genetics, Base Sequence, Carrier Proteins analysis, Cloning, Molecular, Cytoplasm metabolism, Electrophoresis, Polyacrylamide Gel, Intracellular Membranes metabolism, Iron Deficiencies, Iron-Binding Proteins, Molecular Sequence Data, Molecular Weight, Periplasmic Binding Proteins, Phosphopyruvate Hydratase chemistry, Phosphopyruvate Hydratase metabolism, Up-Regulation, Bacteroides fragilis physiology, Phosphopyruvate Hydratase physiology

Abstract

This study describes the identification, cloning and molecular characterization of the alpha-enolase P46 of Bacteroides fragilis. The gram-negative anaerobic bacterium B. fragilis is a member of the commensal flora of the human intestine but is also frequently found in severe intra-abdominal infections. Several virulence factors have been described that may be involved in the development of these infections. Many of these virulence factors are upregulated under conditions of iron- or heme-starvation. We found a major protein of 46 kDa (P46) that is upregulated under iron-depleted conditions. This protein was identified as an alpha-enolase. Alpha-enolases in several gram-positive bacteria and eukaryotic cells are located at the cell surface and function as plasminogen-binding proteins. Localization studies demonstrated that P46 is mainly located in the cytoplasm and partly associated with the inner membrane (IM). Under iron-restricted conditions, however, P46 is localized primarily in the IM fraction. Plasminogen-binding to B. fragilis cells did occur but was not P46 dependent. A 60-kDa protein was identified as a putative plasminogen-binding protein in B. fragilis.

Published

2005

19. Signal recognition particle (SRP)-mediated targeting and Sec-dependent translocation of an extracellular Escherichia coli protein.

Author

Sijbrandi R, Urbanus ML, ten Hagen-Jongman CM, Bernstein HD, Oudega B, Otto BR, and Luirink J

Subjects

Adenosine Triphosphatases metabolism, Amino Acid Sequence, Carrier Proteins genetics, Carrier Proteins metabolism, Endopeptidases genetics, Escherichia coli genetics, Escherichia coli Proteins metabolism, Membrane Transport Proteins metabolism, Molecular Sequence Data, Protein Transport genetics, SEC Translocation Channels, SecA Proteins, Signal Recognition Particle genetics, Signal Transduction genetics, Bacterial Proteins, Endopeptidases metabolism, Escherichia coli metabolism, Signal Recognition Particle metabolism

Abstract

Hemoglobin protease (Hbp) is a hemoglobin-degrading protein that is secreted by a human pathogenic Escherichia coli strain via the autotransporter mechanism. Little is known about the earliest steps in autotransporter secretion, i.e. the targeting to and translocation across the inner membrane. Here, we present evidence that Hbp interacts with the signal recognition particle (SRP) and the Sec-translocon early during biogenesis. Furthermore, Hbp requires a functional SRP targeting pathway and Sec-translocon for optimal translocation across the inner membrane. SecB is not required for targeting of Hbp but can compensate to some extent for the lack of SRP. Hbp is synthesized with an unusually long signal peptide that is remarkably conserved among a subset of autotransporters. We propose that these autotransporters preferentially use the co-translational SRP/Sec route to avoid adverse effects of the exposure of their mature domains in the cytoplasm.

Published

2003

20. Biosynthesis of K88 fimbriae in Escherichia coli: interaction of tip-subunit FaeC with the periplasmic chaperone FaeE and the outer membrane usher FaeD.

Author

Mol O, Oudhuis WC, Oud RP, Sijbrandi R, Luirink J, Harms N, and Oudega B

Subjects

Amino Acid Sequence, Cloning, Molecular, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Molecular Sequence Data, Periplasm, Antigens, Bacterial, Antigens, Surface biosynthesis, Bacterial Outer Membrane Proteins metabolism, Bacterial Proteins metabolism, Escherichia coli Proteins, Fimbriae Proteins, Molecular Chaperones metabolism

Abstract

K88 fimbriae are ordered polymeric protein structures at the surface of enterotoxigenic Escherichia coli cells. Their production and assembly requires a molecular chaperone located in the periplasm (FaeE) and a molecular usher located in the outer membrane (FaeD). FaeC is the tip component of the K88 fimbriae. We studied the expression of the subcloned faeC gene, the subcellular localization of FaeC and its interaction with the chaperone and the outer membrane usher. In the absence of the chaperone or the usher, FaeC could not be detected in E. coli cells harbouring the faeC gene and its ribosome binding site under contol of the IPTG inducible lpp/lac promoter/operator. The expression of FaeC was detectable in the presence of chaperone FaeE, but a direct interaction between the chaperone and FaeC was not found. The expression of FaeC was also detectable in cells co-expressing the outer membrane usher FaeD. Overexpression of FaeC after changing the faeC ribosome binding site appeared to induce lethality. Expression of subcloned FaeC in the absence of FaeE or FaeD could be detected when faeC was cloned under the tight control of the ara promoter/operator and when lethality induction was avoided. The direct interaction of FaeC with outer membranes containing the usher FaeD was studied by cell fractionation, isopycnic sucrose density gradient centrifugation, SDS-PAGE and immunoblotting. FaeC was found to bind to outer membranes containing FaeD or a FaeD-PhoA hybrid construct containing 215 amino-terminal residues of FaeD. This binding was not observed when control outer membranes without FaeD were used. No other K88 specific proteins were required for this interaction. The direct interaction between FaeC and FaeD in the outer membranes was shown by affinity blotting experiments. FaeE was not required for this interaction. Together these data indicate that the minor fimbrial subunit FaeC, unlike FaeG, H and F, does not have a strong interaction with the chaperone FaeE in the E. coli periplasm, but directly binds to the outer membrane molecular usher FaeD.

Published

2001