Molecular architecture of E. coli purine nucleoside phosphorylase studied by analytical ultracentrifugation and CD spectroscopy.

Purine nucleoside phosphorylase (PNP) is a key enzyme of the nucleoside salvage pathway and is characterized by complex kinetics. It was suggested that this is due to coexistence of various oligomeric forms that differ in specific activity. In this work, the molecular architecture of Escherichia coli PNP in solution was studied by analytical ultracentrifugation and CD spectroscopy. Sedimentation equilibrium analysis revealed a homohexameric molecule with molecular mass 150+/-10 kDa, regardless of the conditions investigated-protein concentration, 0.18-1.7 mg/mL; presence of up to 10 mM phosphate and up to 100 mM KCl; temperature, 4-20 degrees C. The parameters obtained from the self-associating model also describe the hexameric form. Sedimentation velocity experiments conducted for broad protein concentration range (1 microg/mL-1.3 mg/mL) with boundary (classical) and band (active enzyme) approaches gave s(0)20,w=7.7+/-0.3 and 8.3+/-0.4 S, respectively. The molecular mass of the sedimenting particle (146+/-30 kDa), calculated using the Svedberg equation, corresponds to the mass of the hexamer. Relative values of the CD signal at 220 nm and the catalytic activity of PNP as a function of GdnHCl concentration were found to be correlated. The transition from the native state to the random coil is a single-step process. The sedimentation coefficient determined at 1 M GdnHCl (at which the enzyme is still fully active) is 7.7 S, showing that also under these conditions the hexamer is the only catalytically active form. Hence, in solution similar to the crystal, E. coli PNP is a hexameric molecule and previous suggestions for coexistence of two oligomeric forms are incorrect.

Conserved amino acid residues within the amino-terminal domain of ClpB are essential for the chaperone activity.

ClpB from Escherichia coli is a member of a protein-disaggregating multi-chaperone system that also includes DnaK, DnaJ, and GrpE. The sequence of ClpB contains two ATP-binding domains that are enclosed between the amino-terminal and carboxyl-terminal regions. The N-terminal sequence region does not contain known functional sequence motifs. Here, we performed site-directed mutagenesis of four polar residues within the N-terminal domain of ClpB (Thr7, Ser84, Asp103 and Glu109). These residues are conserved in several ClpB homologs. We found that the mutations, T7A, S84A, D103A, and E109A did not significantly affect the secondary structure and thermal stability of ClpB, nor did they inhibit the self-association of ClpB, its basal ATPase activity, or the enhanced rate of the ATP hydrolysis by ClpB in the presence of poly-L-lysine. We observed, however, that three mutations, T7A, D103A, and E109A, reduced the casein-induced activation of the ClpB ATPase. The same three mutant ClpB variants also showed low chaperone activity in the luciferase reactivation assay. We found, however, that the four ClpB mutants, as well as the wild-type, bound similar amounts of inactivated luciferase. In summary, we have identified three essential amino acid residues within the N-terminal region of ClpB that participate in the coupling between a protein-binding signal and the ATP hydrolysis, and also support the chaperone activity of ClpB.

Nucleotide-induced switch in oligomerization of the AAA+ ATPase ClpB.

ClpB is a member of the bacterial protein-disaggregating chaperone machinery and belongs to the AAA(+) superfamily of ATPases associated with various cellular activities. The mechanism of ClpB-assisted reactivation of strongly aggregated proteins is unknown and the oligomeric state of ClpB has been under discussion. Sedimentation equilibrium and sedimentation velocity show that, under physiological ionic strength in the absence of nucleotides, ClpB from Escherichia coli undergoes reversible self-association that involves protein concentration-dependent populations of monomers, heptamers, and intermediate-size oligomers. Under low ionic strength conditions, a heptamer becomes the predominant form of ClpB. In contrast, ATP gamma S, a nonhydrolyzable ATP analog, as well as ADP stabilize hexameric ClpB. Consistently, electron microscopy reveals that ring-type oligomers of ClpB in the absence of nucleotides are larger than those in the presence of ATP gamma S. Thus, the binding of nucleotides without hydrolysis of ATP produces a significant change in the self-association equilibria of ClpB: from reactions supporting formation of a heptamer to those supporting a hexamer. Our results show how ClpB and possibly other related AAA(+) proteins can translate nucleotide binding into a major structural transformation and help explain why previously published electron micrographs of some AAA(+) ATPases detected both six- and sevenfold particle symmetry.

Domain stability in the AAA+ ATPase ClpB from Escherichia coli.

ClpB is a heat-shock protein that reactivates aggregated proteins in cooperation with the DnaK chaperone system. ClpB belongs to the family of AAA+ ATPases and forms ring-shaped oligomers: heptamers in the absence of nucleotides and hexamers in the presence of nucleotides. We investigated the thermodynamic stability of ClpB in its monomeric and oligomeric forms. ClpB contains six distinct structural domains: the N-terminal domain involved in substrate binding, two AAA+ ATP-binding modules, each consisting of two domains, and a coiled-coil domain inserted between the AAA+ modules. We produced seven variants of ClpB, each containing a single Trp located in each of the ClpB domains and measured the changes in Trp fluorescence during the equilibrium urea-induced unfolding of ClpB. We found that two structural domains: the small domain of the C-terminal AAA+ module and the coiled-coil domain were destabilized in the oligomeric form of ClpB, which indicates that only those domains change their conformation and/or interactions during formation of the ClpB rings.

Structure and function of the middle domain of ClpB from Escherichia coli.

ClpB belongs to the Hsp100/Clp ATPase family. Whereas a homologue of ClpB, ClpA, interacts with and stimulates the peptidase ClpP, ClpB does not associate with peptidases and instead cooperates with DnaK/DnaJ/GrpE in an efficient reactivation of severely aggregated proteins. The major difference between ClpA and ClpB is located in the middle sequence region (MD) that is much longer in ClpB than in ClpA and contains several segments of coiled-coil-like heptad repeats. The function of MD is unknown. We purified the isolated MD fragment of ClpB from Escherichia coli (residues 410-570). Circular dichroism (CD) detected a high population of alpha-helical structure in MD. Temperature-induced changes in CD showed that MD is a thermodynamically stable folding domain. Sedimentation equilibrium showed that MD is monomeric in solution. We produced four truncated variants of ClpB with deletions of the following heptad-repeat-containing regions in MD: 417-455, 456-498, 496-530, and 531-569. We found that the removal of each heptad-repeat region within MD strongly inhibited the oligomerization of ClpB, which produced low ATPase activity of the truncated ClpB variants as well as their low chaperone activity in vivo. Only one ClpB variant (Delta417-455) could partially complement the growth defect of the clpB-null E. coli strain at 50 degrees C. Our results show that heptad repeats in MD play an important role in stabilization of the active oligomeric form of ClpB. The heptad repeats are likely involved in stabilization of an intra-MD helical bundle rather than an intersubunit coiled coil.