Elke Brosens

The fimbrial adhesin F17‐G of enterotoxigenic Escherichia coli has an immunoglobulin‐like lectin domain that binds N‐acetylglucosamine

The F17‐G adhesin at the tip of flexible F17 fimbriae of enterotoxigenic Escherichia coli mediates binding to N‐acetyl‐β‐d‐glucosamine‐presenting receptors on the microvilli of the intestinal epithelium of ruminants. We report the 1.7 Å resolution crystal structure of the lectin domain of F17‐G, both free and in complex with N‐acetylglucosamine. The monosaccharide is bound on the side of the ellipsoid‐shaped protein in a conserved site around which all natural variations of F17‐G are clustered. A model is proposed for the interaction between F17‐fimbriated E. coli and microvilli with enhanced affinity compared with the binding constant we determined for F17‐G binding to N‐acetylglucosamine (0.85 mM−1). Unexpectedly, the F17‐G structure reveals that the lectin domains of the F17‐G, PapGII and FimH fimbrial adhesins all share the immunoglobulin‐like fold of the structural components (pilins) of their fimbriae, despite lack of any sequence identity. Fold comparisons with pilin and chaperone structures of the chaperone/usher pathway highlight the central role of the C‐terminal β‐strand G of the immunoglobulin‐like fold and provides new insights into pilus assembly, function and adhesion.

The oxidase DsbA folds a protein with a nonconsecutive disulfide

One of the last unsolved problems of molecular biology is how the sequential amino acid information leads to a functional protein. Correct disulfide formation within a protein is hereby essential. We present periplasmic ribonuclease I (RNase I) from Escherichia coli as a new endogenous substrate for the study of oxidative protein folding. One of its four disulfides is between nonconsecutive cysteines. In general view, the folding of proteins with nonconsecutive disulfides requires the protein disulfide isomerase DsbC. In contrast, our study with RNase I shows that DsbA is a sufficient catalyst for correct disulfide formation in vivo and in vitro. DsbA is therefore more specific than generally assumed. Further, we show that the redox potential of the periplasm depends on the presence of glutathione and the Dsb proteins to maintain it at–165 mV. We determined the influence of this redox potential on the folding of RNase I. Under the more oxidizing conditions of dsb– strains, DsbC becomes necessary to correct non-native disulfides, but it cannot substitute for DsbA. Altogether, DsbA folds a protein with a nonconsecutive disulfide as long as no incorrect disulfides are formed.

All intermediates of the arsenate reductase mechanism, including an intramolecular dynamic disulfide cascade

The mechanism of pI258 arsenate reductase (ArsC) catalyzed arsenate reduction, involving its P-loop structural motif and three redox active cysteines, has been unraveled. All essential intermediates are visualized with x-ray crystallography, and NMR is used to map dynamic regions in a key disulfide intermediate. Steady-state kinetics of ArsC mutants gives a view of the crucial residues for catalysis. ArsC combines a phosphatase-like nucleophilic displacement reaction with a unique intramolecular disulfide bond cascade. Within this cascade, the formation of a disulfide bond triggers a reversible “conformational switch” that transfers the oxidative equivalents to the surface of the protein, while releasing the reduced substrate.

The Activation of Electrophile, Nucleophile and Leaving Group during the Reaction Catalysed by pI258 Arsenate Reductase

The reduction of arsenate to arsenite by pI258 arsenate reductase (ArsC) combines a nucleophilic displacement reaction with a unique intramolecular disulfide cascade. Within this reaction mechanism, the oxidative equivalents are translocated from the active site to the surface of ArsC. The first reaction step in the reduction of arsenate by pI258 ArsC consists of a nucleophilic displacement reaction carried out by Cys10 on dianionic arsenate. The second step involves the nucleophilic attack of Cys82 on the Cys10–arseno intermediate formed during the first reaction step. The onset of the second step is studied here by using quantum chemical calculations in a density functional theory context. The optimised geometry of the Cys10–arseno adduct in the ArsC catalytic site (sequence motif: Cys10–Thr11–Gly12–Asn13–Ser14–Cys15–Arg16–Ser17) forms the starting point for all subsequent calculations. Thermodynamic data and a hard and soft acids and bases (HSAB) reactivity analysis show a preferential nucleophilic attack on a monoanionic Cys10–arseno adduct, which is stabilised by Ser17. The P‐loop active site of pI258 ArsC activates first a hydroxy group and subsequently arsenite as the leaving group, as is clear from an increase in the calculated nucleofugality of these groups upon going from the gas phase to the solvent phase to the enzymatic environment. Furthermore, the enzymatic environment stabilises the thiolate form of the nucleophile Cys82 by 3.3 pH units through the presence of the eight‐residue α helix flanked by Cys82 and Cys89 (redox helix) and through a hydrogen bond with Thr11. The importance of Thr11 in the pKa regulation of Cys82 was confirmed by the observed decrease in the kcat value of the Thr11Ala mutant as compared to that of wild‐type ArsC. During the final reaction step, Cys89 is activated as a nucleophile by structural alterations of the redox helix that functions as a pKa control switch for Cys89; this final step is necessary to expose a Cys82–Cys89 disulfide.

Solving the phase problem for carbohydrate-binding proteins using selenium derivatives of their ligands: a case study involving the bacterial F17-G adhesin.

The Escherichia coli adhesin F17-G is a carbohydrate-binding protein that allows the bacterium to attach to the intestinal epithelium of young ruminants. The structure of the 17 kDa lectin domain of F17-G was determined using the anomalous dispersion signal of a selenium-containing analogue of the monosaccharide ligand N-acetyl-d-glucosamine in which the anomeric oxygen was replaced by an Se atom. A three-wavelength MAD data set yielded good experimental phases to 2.6 A resolution. The structure was refined to 1.75 A resolution and was used to solve the structures of the ligand-free protein and the F17-G-N-acetyl-d-glucosamine complex. This selenium-carbohydrate phasing method could be of general use for determining the structures of carbohydrate-binding proteins.

1H, 13C and 15N backbone resonance assignment of the arsenate reductase from Staphylococcus aureus in its reduced state

In S. aureus, resistance to the metal(III)oxyanions arsenite As(III)O− 2 and antimonite Sb(III)O− 2 is mediated by two proteins, ArsB and ArsR, encoded in the ars operon of plasmid pI258 (Silver, 1999). ArsR acts as the transcription repressor, which is de-repressed in the presence of intracellular oxy(III)anions (Ji and Silver, 1992). ArsB is an integral membrane protein that functions as an ATP-independent transporter selective for arsenite and antimonite (Broer et al., 1993). Resistance against arsenate As(V)O3− 4 involves the intervention of the third and final protein coded in the ars operon, ArsC (Chen et al., 1985). This protein reduces intracellular arsenate As(V)O3− 4 to arsenite As(III)O− 2 , which can subsequently be extruded by ArsB. This more elaborate handling of arsenate is thought to avoid phosphate starvation of the bacterium (Silver, 1998).

Purification of an oxidation-sensitive enzyme, pI258 arsenate reductase from Staphylococcus aureus

Arsenate reductase (ArsC) from Staphylococcus aureus pI258 is extremely sensitive to oxidative inactivation. The presence of oxidized ArsC forms was not that critical for NMR, but kinetics and crystallization required an extra reversed-phase purification to increase sample homogeneity. The salt ions observed in the X-ray electron density of ArsC were investigated. Carbonate was found to have the lowest dissociation constant for activation (K(a)=1.1 mM) and potassium was stabilizing ArsC (DeltaT(m)=+6.2 degrees C). Also due to the use of these salt ions, the final yield of the purification had improved with a factor of four, i.e. 73 mg/l culture.

Combining site-specific mutagenesis and seeding as a strategy to crystallize 'difficult' proteins: the case of Staphylococcus aureus thioredoxin.

The P31T mutant of Staphylococcus aureus thioredoxin crystallizes spontaneously in space group P2(1)2(1)2(1), with unit-cell parameters a = 41.7, b = 49.5, c = 55.6 A. The crystals diffract to 2.2 A resolution. Isomorphous crystals of wild-type thioredoxin as well as of other point mutants only grow when seeded with the P31T mutant. These results suggest seeding as a valuable tool complementing surface engineering for proteins that are hard to crystallize.

Development of a downstream process for the isolation of Staphylococcus aureus arsenate reductase overproduced in Escherichia coli.

Arsenate reductase (ArsC) encoded by Staphylococcus aureus arsenic-resistance plasmid pI258 reduces intracellular As(V) (arsenate) to the more toxic As(III) (arsenite). In order to study the structure of ArsC and to unravel biochemical and physical properties of this redox enzyme, wild type enzyme and a number of cysteine mutants were overproduced soluble in Escherichia coli. In this paper we describe a novel purification method to obtain high production levels of highly pure enzyme. A reversed-phase method was developed to separate and analyze the many different forms of ArsC. The oxidation state and the methionine oxidized forms were determined by mass spectroscopy.