Bibliothek

Notizen: Cholera toxin (CT) and the closely related heat-labile enterotoxin of Escherichia coli (LT) are responsible for numerous cases of diarrhea worldwide, leading to considerable morbidity and mortality. The B subunits of these heterohexameric AB5 toxins form a pentameric arrangement which is responsible for binding to the receptor GM1 of the target epithelial cells of the host. Blocking these B pentamer–receptor interactions forms an avenue for therapeutic intervention. Here, the structural characterization of potential receptor-blocking compounds are described based on the previously identified inhibitor m-nitrophenyl-α-D-galactoside (MNPG). The structure of a CTB–MNPG complex confirms that the binding mode of this inhibitor is identical in the two homologous toxins CT and LT and is characterized by a glycosyl linkage geometry that leads to displacement of a well ordered water molecule near the amide group of Gly33 by the O1-substituent of MNPG. This glycosyl geometry is not maintained in the absence of a substituent that can displace this water, as shown by a complex of LTB with p-aminophenyl-α-D-galactoside (PAPG). New compounds were synthesized to investigate the feasibility of maintaining the favorable binding interactions exhibited by MNPG while gaining increased affinity through the addition of hydrophobic substituents complementary to either of two hydrophobic regions of the receptor-binding site. The structural characterization of complexes of LTB with two of these compounds, 3-benzylaminocarbonylphenyl-α-D-galactoside (BAPG) and 2-phenethyl-7-(2,3-dihydrophthalazine-1,4-dione)-α-D-galactoside (PEPG), demonstrates a partial success in this goal. Both compounds exhibit a mixture of binding modes, some of which are presumably influenced by the local packing environment at multiple crystallographically independent binding sites. The terminal phenyl ring of BAPG associates either with the phenyl group of Tyr12 or with the hydrophobic patch formed by Lys34 and Ile58. The latter interaction is also made by the terminal phenyl substituent of PEPG, despite a larger ring system linking the galactose moiety to the terminal phenyl. However, neither BAPG nor PEPG displaces the intended target water molecule. Both of the designed compounds exhibit increased affinity relative to the galactose and to PAPG notwithstanding the failure to displace a bound water, confirming that additional favorable hydrophobic interactions can be gained by extending the starting inhibitor by a hydrophobic tail. The insight gained from these structures should allow the design of additional candidate inhibitors that retain both the glycosyl geometry and water displacement exhibited by MNPG and the favorable hydrophobic interactions exhibited by BAPG and PEPG.

Notizen: The diphtheria toxin repressor (DtxR) from Corynebacterium diphtheriae regulates the expression of the gene on corynebacteriophages that encodes diphtheria toxin (DT). Other genes regulated by DtxR include those that encode proteins involved in siderophore-mediated iron uptake. DtxR requires activation by divalent metals and holo-DtxR is a dimeric regulator with two distinct metal-binding sites per three-domain monomer. At site 1, three side chains and a sulfate or phosphate anion are involved in metal coordination. In the DtxR–DNA complex this anion is replaced by the side chain of Glu170 provided by the third domain of the repressor. At site 2 the metal ion is coordinated exclusively by constituents of the polypeptide chain. In this paper, five crystal structures of three DtxR variants focusing on residues Glu20, Arg80 and Cys102 are reported. The resolution of these structures ranges from 2.3 to 2.8 Å. The side chain of Glu20 provided by the DNA-binding domain forms a salt bridge to Arg80, which in turn interacts with the anion. Replacing either of the salt-bridge partners with an alanine reduces repressor activity substantially and it has been inferred that the salt bridge could possibly control the wedge angle between the DNA-binding domain and the dimerization domain, thereby modulating repressor activity. Cys102 is a key residue of metal site 2 and its substitution into a serine abolishes repressor activity. The crystal structures of Zn-Glu20Ala-DtxR, Zn-Arg80Ala-DtxR, Cd-Cys102Ser-DtxR and apo-Cys102Ser-DtxR in two related space groups reveal that none of these substitutions leads to dramatic rearrangements of the DtxR fold. However, the five crystal structures presented here show significant local changes and a considerable degree of flexibility of the DNA-binding domain with respect to the dimerization domain. Furthermore, all five structures deviate significantly from the structure in the DtxR–DNA complex with respect to overall domain orientation. These results confirm the importance of the hinge motion for repressor activity. Since the third domain has often been invisible in previous crystal structures of DtxR, it is also noteworthy that the SH3-like domain could be traced in four of the five crystal structures.

Notizen: In the quest to develop drugs against traveller's diarrhoea and cholera, the structure of the B pentamer of heat-labile enterotoxin (LT) complexed with a new receptor-binding antagonist, m-carboxyphenyl-α-D-galactopyranoside, has been determined. The high resolution obtained for this structure allowed anisotropic refinement of the model. It was also now possible to confirm at a near-atomic resolution the structural similarity between the B subunits of LT and the closely related cholera toxin (CT), including the similarity in deviations of planarity of the same peptide unit in LT and CT. The structure of the LT complex clearly revealed different conformations for the m-carboxyphenyl moiety of the ligand in the five B subunits of LT, while the binding modes of the well defined galactopyranoside moieties were identical. In two binding sites the m-carboxyphenyl moiety displayed no significant electron density, demonstrating significant flexibility of this moiety. In a third binding site the m-carboxyphenyl moiety could be modelled unambiguously into the density. The two remaining binding sites were involved in crystal packing contacts and the density for the ligands in these two binding sites clearly revealed different binding modes, of which one conformation was identical to and one completely different from the conformation of m-carboxyphenyl-galactopyranoside in the third subunit. The multiple binding modes observed in the crystal may represent the ensemble of conformations of m-carboxyphenyl-α-D-galactopyranoside complexed to LT in solution.

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