Real time kinetics of the DnaK/DnaJ/GrpE molecular chaperone machine action

Applying stopped-flow fluorescence spectroscopy for measuring conformational changes of the DnaK molecular chaperone (bacterial Hsp70 homologue) and its binding to target peptide, we found that after ATP hydrolysis, DnaK is converted to the DnaK*(ADP) conformation, which possesses limited affinity for peptide substrates and the GrpE cochaperone but efficiently binds the DnaJ chaperone. In the presence of DnaJ (bacterial Hsp40 homologue), the DnaK*(ADP) form is converted back to the DnaK conformation, and the resulting DnaJ-DnaK(ADP) complex binds to peptide substrates more tightly. Formation of the DnaJ(substrate-DnaK(ADP)) complex is a rate-limiting reaction. The presence of GrpE and ATP hydrolysis promotes the fast release of the peptide substrate from the chaperone complex and converts DnaK to the DnaK*(ADP) conformation. We conclude that in the presence of DnaJ and GrpE, the binding-release cycle of DnaK is stoichiometrically coupled to the adenosine triphosphatase activity of DnaK.     

The ATP hydrolysis-dependent reaction cycle of the Escherichia coli Hsp70 system DnaK, DnaJ, and GrpE

Molecular chaperones of the Hsp70 class bind unfolded polypeptide chains and are thought to be involved in the cellular folding pathway of many proteins. DnaK, the Hsp70 protein of Escherichia coli, is regulated by the chaperone protein DnaJ and the cofactor GrpE. To gain a biologically relevant understanding of the mechanism of Hsp70 action, we have analyzed a model reaction in which DnaK, DnaJ, and GrpE mediate the folding of denatured firefly luciferase. The binding and release of substrate protein for folding involves the following ATP hydrolysis-dependent cycle: (i) unfolded luciferase binds initially to DnaJ; (ii) upon interaction with luciferase-DnaJ, DnaK hydrolyzes its bound ATP, resulting in the formation of a stable luciferase-DnaK-DnaJ complex; (iii) GrpE releases ADP from DnaK; and (iv) ATP binding to DnaK triggers the release of substrate protein, thus completing the reaction cycle. A single cycle of binding and release leads to folding of only a fraction of luciferase molecules. Several rounds of ATP-dependent interaction with DnaK and DnaJ are required for fully efficient folding.     

Mutations in the DnaK chaperone affecting interaction with the DnaJ cochaperone

Hsp70 chaperones assist protein folding by ATP-controlled cycles of substrate binding and release. ATP hydrolysis is the rate-limiting step of the ATPase cycle that causes locking in of substrates into the substrate-binding cavity of Hsp70. This key step is strongly stimulated by DnaJ cochaperones. We show for the Escherichia coli Hsp70 homolog, DnaK, that stimulation by DnaJ requires the linked ATPase and substrate-binding domains of DnaK. Functional interaction with DnaJ is affected by mutations in an exposed channel located in the ATPase domain of DnaK. It is proposed that binding to this channel, possibly involving the J-domain, allows DnaJ to couple substrate binding with ATP hydrolysis by DnaK. Evolutionary conservation of the channel and the J-domain suggests conservation of the mechanism of action of DnaJ proteins.     

Interaction of the Hsp70 molecular chaperone, DnaK, with its cochaperone DnaJ

Chaperones of the Hsp70 family bind to unfolded or partially folded polypeptides to facilitate many cellular processes. ATP hydrolysis and substrate binding, the two key molecular activities of this chaperone, are modulated by the cochaperone DnaJ. By using both genetic and biochemical approaches, we provide evidence that DnaJ binds to at least two sites on the Escherichia coli Hsp70 family member DnaK: under the ATPase domain in a cleft between its two subdomains and at or near the pocket of substrate binding. The lower cleft of the ATPase domain is defined as a binding pocket for the J-domain because (i) a DnaK mutation located in this cleft (R167H) is an allele-specific suppressor of the binding defect of the DnaJ mutation, D35N and (ii) alanine substitution of two residues close to R167 in the crystal structure, N170A and T173A, significantly decrease DnaJ binding. A second binding determinant is likely to be in the substrate-binding domain because some DnaK mutations in the vicinity of the substrate-binding pocket are defective in either the affinity (G400D, G539D) or rate (D526N) of both peptide and DnaJ binding to DnaK. Binding of DnaJ may propagate conformational changes to the nearby ATPase catalytic center and substrate-binding sites as well as facilitate communication between these two domains to alter the molecular properties of Hsp70.     

Both the Escherichia coli chaperone systems, GroEL/GroES and DnaK/DnaJ/GrpE, can reactivate heat-treated RNA polymerase. Different mechanisms for the same activity

In this work we show that the GroEL (Hsp60 equivalent) chaperone protein can protected purified Escherichia coli RNA polymerase (RNAP) holoenzyme from heat inactivation better than the DnaK (Hsp70 equivalent) chaperone can. In this protection reaction, the GroES protein is not essential, but its presence reduces the amount of GroEL required. GroEL and GroES can also reactivate heat-inactivated RNAP in the presence of ATP. The mutant GroEL673 protein, with or without GroES, is incapable of reactivating heat-inactivated RNAP. GroEL673 can only protect RNAP, and this protecting ability is not stimulated by GroES. The mechanism by which the DnaJ and GrpE heat shock proteins contribute to DnaK's ability to reactivate heat-inactivated RNAP GroEL673 has also been investigated. We found that the DnaJ protein substantially reduces the levels of DnaK protein needed in this reactivation assay. However, the observed lag in reactivation is diminished only in the additional presence of the GrpE protein. Hence, DnaJ and GrpE are involved in both steps of this reactivation reaction (recognition of substrate and release of chaperone from the substrate-chaperone complex) while, in the case of the GroEL-dependent reaction, GroES is involved only during the release of chaperone from the substrate-chaperone complex.     

Peptide-induced conformational changes in the molecular chaperone DnaK

DnaK, the 70 kDa molecular chaperone of Escherichia coli, adopts a high-affinity state in the presence of ADP that tightly binds its target peptide, whereas replacement of ADP by ATP induces a structural switch to a low-affinity chaperone state that weakly binds its target. An approximately 15% decrease in tryptophan fluorescence of DnaK occurs in concert with this switch from the high- to low-affinity state. The reversibility of this structural transition in DnaK was investigated using rapid mixing and equilibrium fluorescence methods. The Cro peptide (MQERITLKDYAM) was used to mimic an unfolded substrate. When the Cro peptide is rapidly mixed with preformed low-affinity DnaK complexes (DnaK-ATP), a rapid increase (kobs = 3-30 s-1) in the tryptophan fluorescence of DnaK occurs. We suggest that the Cro peptide induces the transition of the low-affinity state of DnaK back to the high-affinity state, without ATP hydrolysis. The combined results in this report are consistent with the minimal mechanism ATP + EP if ATP-EP if ATP-E + P, where ATP binding (K1) induces a conformational change and concerted peptide release (koff), and peptide binding (kon) to the low-affinity state (ATP-E) induces the transition back to ATP-EP, a high-affinity state. At 25 degreesC, in the presence of the Cro peptide, values for K1, koff, and kon are 22 microM, 3.3 s-1, and 2. 4 x 10(4) M-1 s-1, respectively. Evidence for an equilibrium between closed and open forms of DnaK in the absence of ATP and peptide is also presented.     

Kinetic evidence for peptide-induced oligomerization of the molecular chaperone DnaK at heat shock temperatures

The pre-steady-state kinetics of the binding of a fluorescent peptide (dansyl-KLIGVLSSLFRPK, fVSV13) to the Escherichia coli molecular chaperone DnaK were investigated over a range of temperatures (25-42 degrees C). At 42 degrees C, over a wide range of peptide concentrations, the fVSV13 peptide bound to DnaK with biphasic kinetics: a rapid burst in the DnaK-fVSV13 signal in the first 5 s was followed by a gradual reduction in the signal over the next 100 s. The descending portion of each biphasic trace followed the equation F(t) = DeltaF exp(-kdt) + Finfinity, where DeltaF, kd, and Finfinity are the amplitude, the apparent first-order rate constant, and the fluorescence end point, respectively. Both DeltaF and kd increased with increasing concentrations of DnaK, which suggests that the loss of the DnaK-fVSV13 signal is caused by a bimolecular reaction. We propose that (i) the fVSV13 peptide binds to and induces a conformational change in the DnaK monomer [E + P right harpoon over left harpoon (EP)*]; and (ii) the conformational change promotes the formation of oligomeric DnaK-peptide complexes [En + (EP)* right harpoon over left harpoon En-EP]. The term (EP)* denotes a monomeric DnaK-peptide complex in which the bound peptide is fluorescent; En-EP denotes an oligomeric DnaK-peptide complex in which the fluorescence of the bound peptide is quenched. Numerical fitting of the stopped-flow data to reactions (i) and (ii) yielded values for the four rate constants. When the proposed kinetic model was tested by conducting experiments in the presence of excess peptide or excess ATP&sbd;conditions which inhibit oligomerization&sbd;DnaK-fVSV13 complex formation proceeded to stable asymptotes, with no reduction in the DnaK-fVSV13 signal at long times.     

Visualization of a slow, ATP-induced structural transition in the bacterial molecular chaperone DnaK

Recent reports have shown that the binding of ATP to a 70-kDa molecular chaperone induces a rapid global conformational transition from a "high affinity" state to a "low affinity" state, where these states are defined by tight and weak binding to (poly)peptides, respectively. To complete the activity cycle, a chaperone molecule must ultimately return to the high affinity state. In this report, this return to the high affinity state was studied using a chemical cross-linking assay in conjunction with SDS-polyacrylamide gel electrophoresis. The basis for this assay is that in the absence of nucleotide or in the presence of ADP, conditions that stabilize the high affinity state, cross-linking of the Escherichia coli molecular chaperone DnaK yielded two monomeric forms, with apparent molecular masses of 70 kDa (77%) and 90 kDa (23%), whereas cross-linking yielded only the 70-kDa monomeric form in the presence of ATP. This ATP-dependent difference in cross-linking was used to follow the kinetics of the low affinity to high affinity transition under single turnover conditions. The rate of this transition (kobs = 3.4 (+/-0.6) x 10(-4) s-1 at 25 degrees C) is almost identical to the reported rate of ATP hydrolysis (khy = 2.7 (+/-0.7) x 10(-4) s-1 at 22 degrees C). These results are consistent with a two-step sequential reaction where rate-limiting ATP hydrolysis precedes the conformational change. Models for the formation of two cross-linked DnaK monomers in the absence of ATP are discussed.     

Role of mitochondrial GrpE and phosphate in the ATPase cycle of matrix Hsp70

The yeast mitochondrial GrpE homologue, Mge1, assists matrix Hsp70 in both protein translocation across the mitochondrial membranes and subsequent protein folding. We expressed mtHsp70 and Mge1 in Escherichia coli and analyzed their function in the ATP hydrolysis cycle. Mge1 stimulates ATP hydrolysis by mtHsp70 about twofold. Addition of inorganic phosphate inhibits ATP hydrolysis by preventing ADP release from mtHsp70. Mge1 has no direct effect on gamma-phosphate release from mtHsp70, yet indirectly relieves the phosphate inhibition by stimulating ADP release. We conclude that Mge1 promotes the ATPase cycle of mtHsp70 by increasing the rate of ADP release. ATP then rapidly binds to mtHsp70 such that the total amount of mtHsp70-bound nucleotide is not changed by Mge1.     

Nucleotide-induced conformational changes in the ATPase and substrate binding domains of the DnaK chaperone provide evidence for interdomain communication

Interactions of the DnaK (Hsp70) chaperone from Escherichia coli with substrates are controlled by ATP. Nucleotide-induced changes in DnaK conformation were investigated by monitoring changes in tryptic digestion pattern and tryptophan fluorescence. Using nucleotide-free DnaK preparations, not only the known ATP-induced major changes in kinetics and pattern of proteolysis but also minor ADP-induced changes were detected. Similar ATP-induced conformational changes occurred in the DnaK-T199A mutant protein defective in ATPase activity, demonstrating that they result from binding, not hydrolysis, of ATP. N-terminal sequencing and immunological mapping of tryptic fragments of DnaK identified cleavage sites that, upon ATP addition, appeared within the proposed C-terminal substrate binding region and disappeared in the N-terminal ATPase domain. They hence reflect structural alterations in DnaK correlated to substrate release and indicate ATP-dependent domain interactions. Domain interactions are a prerequisite for efficient tryptic degradation as fragments of DnaK comprising the ATPase and C-terminal domains were highly protease-resistant. Fluorescence analysis of the N-terminally located single tryptophan residue of DnaK revealed that the known ATP-induced alteration of the emission spectrum, proposed to result directly from conformational changes in the ATPase domain, requires the presence of the C-terminal domain and therefore mainly results from altered domain interaction. Analyses of the C-terminally truncated DnaK163 mutant protein revealed that nucleotide-dependent interdomain communication requires a 15-kDa segment assumed to constitute the substrate binding site.     

The rpoD gene functions as a multicopy suppressor for mutations in the chaperones, CbpA, DnaJ and DnaK, in Escherichia coli

The CbpA protein is an analog of the DnaJ molecular chaperone of Escherichia coli. The dnaJ- cbpA- double-null mutant exhibits severe defects in cell growth, namely, a very narrow temperature range for growth. To gain insight into the functions of CbpA as well as DnaJ, we isolated a multicopy suppressor gene that permits this dnaJ- cbpA- mutant to grow normally at low temperatures. The suppressor gene was identified as rpoD, the gene that encodes the major sigma 70. The biological implications of this finding are examined and discussed.     

Analysis of three DnaK mutant proteins suggests that progression through the ATPase cycle requires conformational changes

DnaK, the bacterial homolog of the eukaryotic hsp70 proteins, is an ATP-dependent chaperone whose basal ATPase is stimulated by synthetic peptides and its cohort heat shock proteins, DnaJ and GrpE. We have used three mutant DnaK proteins, E171K, D201N, and A174T (corresponding to Glu175, Asp206, and Ala179, respectively, in bovine heat stable cognate 70) to probe the ATPase cycle. All of the mutant proteins exhibit some alteration in basal ATP hydrolysis. However, they all exhibit more severe defects in the regulated activities. D201N and E171K are completely defective in all regulated activities of the protein and also in making the conformational change exhibited by the wt protein upon binding ATP. We suggest that the inability of D201N and E171K to achieve the ATP activated conformation prevents both stimulation by all effectors and the ATP-mediated release of GrpE. In contrast, the defect of A174T is much more specific. It exhibits normal binding and release of GrpE and normal stimulation of ATPase activity by DnaJ. However, it is defective in the synergistic activation of its ATPase by DnaJ and GrpE. We suggest that this mutant protein is specifically defective in a DnaJ/GrpE mediated conformational change in DnaK necessary for the synergistic action of DnaJ+GrpE.     

Control of cell cycle progression by fibronectin matrix architecture

Developmental patterning and differentiation, maintenance of parenchymal cell function, and the size, shape, and invasiveness of tumors are all orchestrated by cell interactions with the extracellular matrix. Here we show that the fibrillar structure of fibronectin (FN) matrix encodes essential regulatory cues and controls cell proliferation and signaling through changes in matrix architecture. A matrix assembled from native FN stimulated cell growth. In contrast, a mutant FN (FNDeltaIII1-7) that contains all known cell binding motifs but forms a structurally distinct matrix inhibited progression from G0/G1 into S phase. Furthermore, FNDeltaIII1-7 suppressed the stimulatory capacity of native FN and induced different levels of tyrosine phosphorylation of pp125(FAK). The differential effects on cell growth were ablated by blocking formation of matrix fibrils. Thus, modification of matrix architecture provides a novel approach to control cell proliferation.     

Regulation of Hsp90 ATPase activity by tetratricopeptide repeat (TPR)-domain co-chaperones

The in vivo function of the heat shock protein 90 (Hsp90) molecular chaperone is dependent on the binding and hydrolysis of ATP, and on interactions with a variety of co-chaperones containing tetratricopeptide repeat (TPR) domains. We have now analysed the interaction of the yeast TPR-domain co-chaperones Sti1 and Cpr6 with yeast Hsp90 by isothermal titration calorimetry, circular dichroism spectroscopy and analytical ultracentrifugation, and determined the effect of their binding on the inherent ATPase activity of Hsp90. Sti1 and Cpr6 both bind with sub-micromolar affinity, with Sti1 binding accompanied by a large conformational change. Two co-chaperone molecules bind per Hsp90 dimer, and Sti1 itself is found to be a dimer in free solution. The inherent ATPase activity of Hsp90 is completely inhibited by binding of Sti1, but is not affected by Cpr6, although Cpr6 can reactivate the ATPase activity by displacing Sti1 from Hsp90. Bound Sti1 makes direct contact with, and blocks access to the ATP-binding site in the N-terminal domain of Hsp90. These results reveal an important role for TPR-domain co-chaperones as regulators of the ATPase activity of Hsp90, showing that the ATP-dependent step in Hsp90-mediated protein folding occurs after the binding of the folding client protein, and suggesting that ATP hydrolysis triggers client-protein release.     

Protein folding activity of Hsp70 is modified differentially by the hsp40 co-chaperones Sis1 and Ydj1

Specification of Hsp70 action in cellular protein metabolism may occur through the formation of specialized Hsp70:Hsp40 pairs. To test this model, we compared the ability of purified Sis1 and Ydj1 to regulate the ATPase and protein-folding activity of Hsp70 Ssa1 and Ssb1/2 proteins. Ydj1 and Sis1 could both functionally interact with Ssa1, but not the Ssb1/2 proteins, to refold luciferase. Interestingly, Ydj1:Ssa1 could promote up to four times more luciferase folding than Sis1:Ssa1. This functional difference was explored and could not be accounted for by differences in the ability of Sis1 and Ydj1 to regulate Ssa1 ATPase activity. Instead, differences in the chaperone function of Ydj1 and Sis1 were observed. Ydj1 was dramatically more effective than Sis1 at suppressing the thermally induced aggregation of luciferase. Paradoxically, Sis1 and Ydj1 could bind similar quantities of chemically denatured luciferase. The polypeptide binding domain of Sis1 was found to lie between residues 171-352 and correspond to its conserved carboxyl terminus. The conserved carboxyl terminus of Ydj1 is also known to participate in the binding of nonnative polypeptides. Thus, Ydj1 appears more efficient at assisting Ssa1 in folding luciferase because its contains a zinc finger-like region that is absent from Sis1. Ydj1 and Sis1 are structurally and functionally distinct Hsp40 proteins that can specify Ssa1 action by generating Hsp70:Hsp40 pairs that exhibit different chaperone activities.     

Control of tissue progastrin concentrations in the rat

An acidic capsular and an O-specific polysaccharide were isolated from the marine microorganism Alteromonas haloplanktis KMM 156. Both polysaccharides have the identical structure and are built up of tetrasaccharide repeating units, containing two residues of L-rhamnose as well as a 2-acetamido-2-deoxy-D-glucose and a 3-O-[(R)-1-carboxyethyl]-D-glucose (Glc3Lac) residue. On the basis of methylation studies, 1H- and 13C-NMR-spectroscopy including nuclear Overhauser effect and two-dimensional heteronuclear 13C/1H correlation spectroscopy, the following structure was suggested for the polysaccharide repeating unit: [formula: see text]     

Structure-function analysis of the Escherichia coli GrpE heat shock protein

We have isolated various missense mutations in the essential grpE gene of Escherichia coli based on the inability to propagate bacteriophage lambda. To better understand the biochemical mechanisms of GrpE action in various biological processes, six mutant proteins were overexpressed and purified. All of them, GrpE103, GrpE66, GrpE2/280, GrpE17, GrpE13a and GrpE25, have single amino acid substitutions located in highly conserved regions throughout the GrpE sequence. The biochemical defects of each mutant GrpE protein were identified by examining their abilities to: (i) support in vitro lambda DNA replication; (ii) stimulate the weak ATPase activity of DnaK; (iii) dimerize and oligomerize, as judged by glutaraldehyde crosslinking and HPLC size chromatography; (iv) interact with wild-type DnaK protein using either an ELISA assay, glutaraldehyde crosslinking or HPLC size chromatography. Our results suggest that GrpE can exist in a dimeric or oligomeric form, depending on its relative concentration, and that it dimerizes/oligomerizes through its N-terminal region, most likely through a computer predicted coiled-coil region. Analysis of several mutant GrpE proteins indicates that an oligomer of GrpE is the most active form that interacts stably with DnaK and that the interaction is vital for GrpE biological function. Our results also demonstrate that both the N-terminal and C-terminal regions are important for GrpE function in lambda DNA replication and its co-chaperone activity with DnaK.     

Plasma LH progesterone concentrations in the turkey hen during the ovulatory cycle

Progesterone and luteinizing hormone (LH) were measuured in the plasma of Large White turkey hens at frequent intervals during the ovulatory cycle and during the periods when ovulations did not occur. The hormones were quantitated at the beginning and the end of the reproductive season to follow the change in patterns and concentrations of these hormones. Radioimmunoassay procedures were used to assay both hormones. Both progesterone and LH reached a peak amount at about 8 to 2 hours before ovulation. At no time did the progesterone peak precede that of LH. On the other hand, the peak of progesterone was observed to last somewhat longer than the LH peak. Progesterone and LH concentrations demonstrated no peak during the non-ovulatory periods. The patterns of both hormones at the end of the reproductive season was about the same as at the beginning of the season, but with lower concentrations.