Initiation of phage infection by partial unfolding and prolyl isomerization.

Infection of Escherichia coli by the filamentous phage fd starts with the binding of the N2 domain of the phage gene-3-protein to an F pilus. This interaction triggers partial unfolding of the gene-3-protein, cis → trans isomerization at Pro-213, and domain disassembly, thereby exposing its binding site for the ultimate receptor TolA. The trans-proline sets a molecular timer to maintain the binding-active state long enough for the phage to interact with TolA. We elucidated the changes in structure and local stability that lead to partial unfolding and thus to the activation of the gene-3-protein for phage infection. Protein folding and TolA binding experiments were combined with real-time NMR spectroscopy, amide hydrogen exchange measurements, and phage infectivity assays. In combination, the results provide a molecular picture of how a local unfolding reaction couples with prolyl isomerization not only to generate the activated state of a protein but also to maintain it for an extended time.

Yersinia enterocolitica and Photorhabdus asymbiotica ß-lactamases BlaA are exported by the twin-arginine translocation pathway.

In general, ß-lactamases of medically important Gram-negative bacteria are Sec-dependently translocated into the periplasm. In contrast, ß-lactamases of Mycobacteria spp. (BlaC, BlaS) and the Gram-negative environmental bacteria Stenotrophomonas maltophilia (L2) and Xanthomonas campestris (Bla(XCC-1)) have been reported to be secreted by the twin-arginine translocation (Tat) system. Yersinia enterocolitica carries 2 distinct ß-lactamase genes (blaA and blaB) encoding BlaA(Ye) and the AmpC-like ß-lactamase BlaB, respectively. By using the software PRED-TAT for prediction and discrimination of Sec from Tat signal peptides, we identified a functional Tat signal sequence for Yersinia BlaA(Ye). The Tat-dependent translocation of BlaA(Ye) could be clearly demonstrated by using a Y. enterocolitica tatC-mutant and cell fractionation. Moreover, we could demonstrate a unique unusual temperature-dependent activity profile of BlaA(Ye) ranging from 15 to 60 °C and a high 'melting temperature' (T(M)=44.3°) in comparison to the related Sec-dependent ß-lactamase TEM-1 (20-50°C, T(M)=34.9 °C). Strikingly, the blaA gene of Y. enterocolitica is present in diverse environmental Yersinia spp. and a blaA homolog gene could be identified in the closely related Photorhabdus asymbiotica (BlaA(Pa); 69% identity to BlaA(Ye)). For BlaA(Pa) of P. asymbiotica, we could also demonstrate Tat-dependent secretion. These results suggest that Yersinia BlaA-related ß-lactamases may be the prototype of a large Tat-dependent ß-lactamase family, which originated from environmental bacteria.

A kinetic approach to determining the conformational stability of a protein that dimerizes after folding.

A strongly stabilized form of the ß1 domain of the streptococcal protein G, termed Gß1-M2, was previously obtained by an in vitro selection method for stabilized protein variants. It contains four substitutions, but how they contribute to the Gibbs free energy of denaturation (ΔG(D)) could not be determined, because, unlike the wild-type protein, Gß1-M2 dimerizes in a spectroscopically silent reaction. Here we determined the ΔG(D) of the folded Gß1-M2 monomer by using a kinetic approach that uncouples the folding of the monomer from dimerization. The conformational equilibration of the monomer is faster than dimer formation, and therefore, its stability constant could be determined from the ratio of the rate constants for monomer unfolding and refolding. In this approach, double-mixing experiments were essential for uncovering the unfolding kinetics of the transient Gß1-M2 monomer and the association of the monomers after their folding. The analysis revealed that the selected substitutions stabilize the Gß1-M2 monomer by 15 kJ mol(-1) in an additive fashion. The combination of single- and double-mixing kinetic experiments thus allowed us to determine the thermodynamic stability of a transient species that is inaccessible in equilibrium experiments. It can be applied for proteins in which monomer folding and oligomerization are kinetically uncoupled.

Energetic communication between functional sites of the gene-3-protein during infection by phage fd.

To initiate infection of Escherichia coli, phage fd uses its gene-3-protein (G3P) to bind first to an F pilus and then to the TolA protein at the cell surface. G3P is normally auto-inhibited because a tight interaction between the two N-terminal domains N1 and N2 buries the TolA binding site. Binding of N2 to the pilus activates G3P by initiating long-range conformational changes that are relayed to the domain interface and to a proline timer. We discovered that the 23-28 loop of the N1 domain is critical for propagating these conformational signals. The analysis of the stability and the folding dynamics of G3P variants with a shortened loop combined with TolA interaction studies and phage infection experiments reveal how the contact between the N2 domain and the 23-28 loop of N1 is energetically linked with the interdomain region and the proline timer and how it affects phage infectivity. Our results illustrate how conformational transitions and prolyl cis/trans isomerization can be coupled energetically and how conformational signals to and from prolines can be propagated over long distances in proteins.

Dimer formation of a stabilized Gbeta1 variant: a structural and energetic analysis.

In previous work, a strongly stabilized variant of the beta1 domain of streptococcal protein G (Gbeta1) was obtained by an in vitro selection method. This variant, termed Gbeta1-M2, contains the four substitutions E15V, T16L, T18I, and N37L. Here we elucidated the molecular basis of the observed strong stabilizations. The contributions of these four residues were analyzed individually and in various combinations, additional selections with focused Gbeta1 gene libraries were performed, and the crystal structure of Gbeta1-M2 was determined. All single substitutions (E15V, T16L, T18I, and N37L) stabilize wild-type Gbeta1 by contributions of between 1.6 and 6.0 kJ mol(-1) (at 70 degrees C). Hydrophobic residues at positions 16 and 37 provide the major contribution to stabilization by enlarging the hydrophobic core of Gbeta1. They also increase the tendency to form dimers, as shown by dependence on the concentration of apparent molecular mass in analytical ultracentrifugation, by concentration-dependent stability, and by a strongly increased van't Hoff enthalpy of unfolding. The 0.88-A crystal structure of Gbeta1-M2 and NMR measurements in solution provide the explanation for the observed dimer formation. It involves a head-to-head arrangement of two Gbeta1-M2 molecules via six intermolecular hydrogen bonds between the two beta strands 2 and 2' and an adjacent self-complementary hydrophobic surface area, which is created by the T16L and N37L substitutions and a large 120 degrees rotation of the Tyr33 side chain. This removal of hydrophilic groups and the malleability of the created hydrophobic surface provide the basis for the dimer formation of stabilized Gbeta1 variants.