Gene expression and molecular characterization of a chaperone protein HtpG from Bacillus licheniformis.

Heat shock protein 90 (Hsp90/HtpG) is a highly abundant and ubiquitous ATP-dependent molecular chaperone consisting of three flexibly linked regions, an N-terminal nucleotide-binding domain, middle domain, and a C-terminal domain. Here the putative htpG gene of Bacillus licheniformis was cloned and heterologously expressed in Escherichia coli M15 cells. Native-gel electrophoresis, size exclusion chromatography, and cross-linking analysis revealed that the recombinant protein probably exists as a mixture of monomer, dimer and other oligomers in solution. The optimal conditions for the ATPase activity of B. licheniformis HtpG (BlHtpG) were 45°C and pH 7.0 in the presence of 0.5mM Mg(2+) ions. The molecular architecture of this protein was stable at higher temperatures with a transition point (Tm) of 45°C at neutral pH, whereas the Tm value was reduced to 40.8°C at pH 10.5. Acrylamide quenching experiment further indicated that the dynamic quenching constant (Ksv) of BlHtpG became larger at higher pH values. BlHtpG also experienced a significant change in the protein conformation upon the addition of ATP and organic solvents. Collectively, our experiment data may provide insights into the molecular properties of BlHtpG and identify the alteration of protein structure to forfeit the ATPase activity at alkaline conditions.

Residues Phe103 and Phe149 are critical for the co-chaperone activity of Bacillus licheniformis GrpE.

A tryptophan-free Bacillus licheniformis nucleotide exchange factor (BlGrpE) and its Trp mutants (F70W, F103W, F149W, F70/103W, F70/149W, F103/149W and F70/103/149W) were over-expressed and purified to near homogeneity. Simultaneous addition of B. licheniformis DnaJ, NR-peptide and individual variants synergistically stimulated the ATPase activity of a recombinant DnaK (BlDnaK) from the same bacterium by 3.1-14.7-fold, which are significantly lower than the synergistic stimulation (18.9-fold) of BlGrpE. Protein-protein interaction analysis revealed that Trp mutants relevant to amino acid positions 103 and 149 lost the ability to bind BlDnaK. Circular dichroism measurements indicate that F70W displayed a comparable level of secondary structure to that of BlGrpE, and the wild-type protein and the Trp mutants as well all experienced a reversible behavior of thermal denaturation. Guanidine hydrochloride (GdnHCl)-induced unfolding transition for BlGrpE was calculated to be 1.25 M corresponding to ΔG(N-U) of 4.29 kcal/mol, whereas the unfolding transitions of mutant proteins were in the range of 0.77-1.31 M equivalent to ΔG(N-U) of 2.41-4.14 kcal/mol. Taken together, the introduction of tryptophan residue, especially at positions 103 and 149, into the primary structure of BlGrpE has been proven to be detrimental to structural integrity and proper function of the protein.

Introduction of a unique tryptophan residue into various positions of Bacillus licheniformis DnaK.

Site-directed mutagenesis together with biochemical and biophysical techniques were used to probe effects of single-tryptophan-incorporated mutations on a bacterial molecular chaperone, Bacillus licheniformis DnaK (BlDnaK). Specifically, five phenylalanine residues (Phe(120), Phe(174), Phe(186), Phe(378) and Phe(396)) of BlDnaK were individually replaced by single tryptophans, thus creating site-specific probes for the fluorescence analysis of the protein. The steady-state ATPase activity for BlDnaK, F120W, F174W, F186W, F378W, and F396W was determined to be 76.01, 52.82, 25.32, 53.31, 58.84, and 47.53 nmol Pi/min/mg, respectively. Complementation test revealed that the single mutation at codons 120, 186, and 378 of the dnaK gene still allowed an Escherichia coli dnaK756-Ts strain to grow at a stringent temperature of 44°C. Simultaneous addition of co-chaperones and NR-peptide did not synergistically stimulate the ATPase activity of F174W and F396W, and these two proteins were unable to assist the refolding of GdnHCl-denatured luciferase. The heat-induced denaturation of all variants could be fitted adequately to a three-state model, in agreement with the observation for the wild-type protein. By CD spectral analysis, GdnHCl-induced unfolding transition for BlDnaK was 1.51 M corresponding to ΔG(N-U) of 1.69 kcal/mol; however, the transitions for mutant proteins were 1.07-1.55 M equivalent to ΔG(N-U) of 0.94-2.93 kcal/mol. The emission maximum of single-tryptophan-incorporated variants was in the range of 333.2-335.8 nm. Acrylamide quenching analysis showed that the mutant proteins had a dynamic quenching constant of 3.0-4.2 M(-1). Taken together, these results suggest that the molecular properties of BlDnaK have been significantly changed upon the individual replacement of selected phenylalanine residues by tryptophan.

Involvement of residues Asp8, Asn13, Glu145, Asp168, and Thr173 in the chaperone activity of a recombinant DnaK from Bacillus licheniformis.

Based on the sequence homology, we have modeled the three-dimensional structure of Bacillus licheniformis DnaK (BlDnaK), a counterpart of Hsp70, and identified five different amino acids that might be responsible for maintaining ADP-Mg(2+)-Pi in the correct configuration at the ATP-binding cleft of the protein. As compared with wild-type BlDnaK, site-directed mutant proteins D8A, N13D, E145A, D168A, and T173A had a dramatic reduction in their chaperone activities. Complementation test revealed that the mutant proteins lost completely the ability to rescue the temperature-sensitive growth defect of Escherichia colidnaK756-ts. Wild-type BlDnak assisted the refolding of denatured firefly luciferase, whereas a significant decrease in this ability was observed for the mutant proteins. Simultaneous addition of B. licheniformis DnaJ, BlGrpE, and NR-peptide, did not synergistically stimulate the ATPase activity of D8A, E145A, D168A and T173A. Circular dichroism spectra were nearly identical for wild-type and mutant proteins, and they, except D8A, also exhibited a similar sensitivity towards temperature-induced denaturation. These results suggest that the selected residues are critical for the proper function of BlDnaK.

Site-saturation mutagenesis of leucine 134 of Bacillus licheniformis nucleotide exchange factor GrpE reveals the importance of this residue to the co-chaperone activity.

To elucidate the role of leucine 134 of Bacillus licheniformis nucleotide exchange factor (BlGrpE), site-saturation mutagenesis was employed to generate all possible replacements for this residue. Wild-type and mutant proteins were purified by nickel-chelated chromatography and had a molecular mass of approximately 34.5 kDa. As compared with wild-type BlGrpE, the nucleotide exchange factor (NEF) activity of L134H, L134K, L134R, L134D, L134E, L134N, L134Q, L134S, L134G and L134P was reduced by more than 96%. In vitro binding assay revealed that wild-type BlGrpE and the functional variants mainly interacted with the monomer of BlDnaK, but no such interaction was observed for the remaining mutant proteins. BlGrpE and 9 mutant proteins synergistically stimulated the ATPase activity of B. licheniformis DnaK (BlDnaK), whereas the NEF-defective variants had no synergistic stimulation. Comparative analysis of the far-UV CD spectra showed that the alpha-helical content of the inactive mutant BlGrpEs was reduced significantly with respect to wild-type protein. Moreover, the inactive mutant proteins also exhibited a more sensitivity towards the temperature-induced denaturation. Taken together, these results indicate that Leu134 might play a structural role for the proper function of BlGrpE.