©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
In Vitro Dissociation of BiP-Peptide Complexes Requires a Conformational Change in BiP after ATP Binding but Does Not Require ATP Hydrolysis (*)

(Received for publication, June 20, 1995; and in revised form, September 7, 1995)

Jueyang Wei (1) (2) James R. Gaut (3) Linda M. Hendershot (1) (2)(§)

From the  (1)Department of Tumor Cell Biology, St. Jude Children's Research Hospital, Memphis, Tennessee 38105, the (2)Department of Biochemistry, University of Tennessee, Memphis, Tennessee 38163, and the (3)Institute of Gerontology and Department of Biological Sciences, University of Michigan, Ann Arbor, Michigan 48109

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

In the present study, we produced single point mutations in the ATP binding site of hamster BiP, isolated recombinant proteins, and characterized them in terms of their affinity for ATP and ADP, their ability to undergo a conformational change upon nucleotide binding, and their rate of ATP hydrolysis. These analyses allowed us to classify the mutants into three groups: ATP hydrolysis (T229G), ATP binding (G226D, G227D), and ATP-induced conformation (T37G) mutants, and to test the role of these activities in the in vitro ATP-mediated release of proteins from BiP. All three classes of mutants were still able to bind peptide demonstrating that nucleotide is not involved in this function. Addition of ATP to either wild-type BiP or the T229G mutant caused the in vitro release of bound peptide, confirming that ATP hydrolysis is not required for protein release. ATP did not dissociate G226D, G227D, or T37G mutant BiP-peptide complexes, suggesting that ATP binding to BiP is not sufficient for the release of bound peptides, but that an ATP-induced conformational change in BiP is necessary. The identification of BiP mutants that are defective in each of these steps of ATP hydrolysis will allow the in vivo dissection of the role of nucleotide in BiP's activity.


INTRODUCTION

The heat shock protein 70 (HSP70) (^1)family of chaperones are components of the cellular machinery for folding, assembly, and degradation of proteins(1) . These proteins are thought to undergo cycles of nucleotide-mediated binding and release to unfolded polypeptides. The binding of peptides to HSP70 proteins stimulates their ATPase activity(2) , and bound peptides or proteins are released with ATP but not with non-hydrolyzable analogues(2, 3, 4, 5) . These observations have led to the conclusion that ATP hydrolysis is required for HSP70 activity and that there are functional interactions between the ATP binding and protein binding domains. All HSP70 proteins bind ATP tightly but the ATP hydrolysis rates of purified proteins are so low under physiological conditions, that other co-factors may be required to enhance the rate of ATP hydrolysis. In bacteria two co-factors, dnaJ and grpE, have been identified that together increase the ATPase activity of dnaK (bacterial HSP70 homologue) up to 50-fold (6) . Although dnaJ homologues have been identified in several organelles in various organisms(7) , the only eukaryotic grpE homologues found thus far are mitrochondrial(8, 9) . Alternatively, it is possible that ATP binding rather than ATP hydrolysis is essential for HSP70 function. In support of this hypothesis, investigators have recently demonstrated that peptides are released from both dnaK and hsc70 (mammalian cytosolic homologue) after ATP binding but before ATP hydrolysis occurs(10) . Thus, it is presently unclear whether ATP binding, ATP hydrolysis, or both are important for HSP70 function in vivo.

The ATP binding domain of all HSP70 members resides within a highly conserved NH(2)-terminal 44-kDa fragment that can be generated by proteolysis(11, 12) . The structure of the ATP binding domain of hsc70 has been solved in the presence of ADP (13) and AMPPNP (14) , allowing investigators to identify residues that might participate in either ATP binding or hydrolysis. To date, a number of mutations have been made in the active site of the various HSP70 family members(15, 16, 17) , and these have been characterized to varying degrees.

A series of dnaK (bacterial HSP70) and Kar2 (yeast endoplasmic reticulum HSP70) mutants have been isolated by genetic screens that have mutations mapping to their ATP binding domain(17, 18) , but most of them have not been characterized biochemically. Mutation of the autophosphorylation site (Thr) of dnaK, yielded mutants that had greatly reduced ATP hydrolysis rates (19) and that were unable to complement dnaK null bacterial strains(20) . Several mutations have been made in the active site of the ATPase domain of bovine hsc70(15, 21) . Biochemical characterization of Thr mutants (corresponding to Thr in dnaK) revealed that the mutation increased the K for ATP(21) , while mutation of four other active site residues (Asp, Asp, Glu, and Asp) decreased the k values. Mutation of two of these (Asp and Glu) resulted in increased K values for ATP(15) . Interestingly, Glu corresponds to one of the residues identified in the dnaK genetic study(17) . No functional data are available on the effects of the various hsc70 mutants. Several point mutations in the ATP binding domain of hamster BiP have been made(16, 22) , including Thr (corresponding to Thr in dnaK and Thr in hsc70) and Glu (corresponding to Glu in dnaK and Glu in hsc70). These mutations affected the ATPase activity of BiP but did not inhibit their ability to bind to ATP-Sepharose or to bind to substrate proteins(16) . Transient expression of the BiP ATPase mutants in mammalian cells causes a disruption of the endoplasmic reticulum (23) and interferes with the folding of a nascent endoplasmic reticulum protein. (^2)A rigorous biochemical characterization of these mutants has not been done.

Thus, there is a growing amount of data to demonstrate that either the ATP binding or hydrolysis properties of HSP70 proteins are important in their in vivo function, but in most cases, ATP binding site mutants have not been characterized in enough detail to determine the role of nucleotide in regulating HSP70 activity. In this study, we have produced a series of single point mutants in the ATP binding site of hamster BiP and purified these recombinant proteins from bacteria. Mutants that retained the structural integrity of wild-type BiP were selected for further characterization in terms of ATPase activity, nucleotide binding affinity, and the ability of nucleotide to induce a conformational change in the mutant protein. Through these characterizations, we were able to classify the ATP binding site mutants into three separate groups: ATP binding mutants, ATP hydrolysis mutants, and conformational change mutants. The mutants were used to determine the requirements for the in vitro release of bound peptides.


MATERIALS AND METHODS

Producing BiP Single Point Mutants

The single site mutants (G226D, G227D, and E201K) were made in a hamster BiP cDNA clone (24) by site-directed mutagenesis using an overlap extension polymerase chain reaction as described(25) . The polymerase chain reaction products were digested with MscI and BstEII, and then inserted back into the BiP cDNA clone in place of the wild-type coding region. The mutations were verified by dideoxy DNA sequencing through the entire region that was ligated back into the BiP cDNA using a Sequenase kit (U. S. Biochemical Corp.). Each of these cDNA clones was inserted into the QE-10 vector (Qiagen, Chatsworth, CA) and expressed in M15 bacteria. Recombinant BiP (rBiP) proteins were purified on Ni-agarose as described(16, 33) . The T37G and T229G mutants were described previously(16, 22) .

Nondenaturing Gel Electrophoresis

2-15% gradient nondenaturing polyacrylamide gels were prepared as described previously (26) . 15 µg of purified rBiP was electrophoresed at 4 °C for 16 h at 150 V. After electrophoresis, the gel was stained with Coomassie Brilliant Blue to detect proteins.

Proteolysis of Recombinant BiP in the Presence of Nucleotide

Recombinant BiP was digested with proteinase K as described by Kassenbrock and Kelly (11) with some modifications. 10 µg of rBiP was incubated with 2 µg of proteinase K in the presence of 100 µM ATP, 100 µM ADP, or with no added nucleotide in 65 µl of the standard ATPase buffer (20 mM HEPES, 25 mM KCl, 2 mM MgCl(2), 0.1 mM EDTA, 0.5 mM dithiothreitol, at pH 7.0). After incubation at 37 °C for 25 min, the reactions were stopped by adding 10 µl of 1 mg/ml phenylmethylsulfonyl fluoride and incubating on ice for 30 min. The digested samples along with an undigested control were analyzed by SDS-PAGE.

ATPase Assay

ATPase assays were performed on purified recombinant protein containing the 6X-His tag as described in the accompanying article(33) . The standard assay contains 20 mM HEPES (pH 7.0), 25 mM KCl, 2 mM MgCl(2), 0.1 mM EDTA, 0.5 mM dithiothreitol, 1.0 mM [-P]ATP, and 2 µM BiP. Reactions were performed at 37 °C in a volume of 100 µl and at appropriate times 20-µl aliquots were removed for P(i) extraction and counted. For characterization of the BiP mutants, 5-6 different recombinant preparations were assayed.

Nucleotide Binding Measurement

The binding affinities of wild-type and mutant rBiP proteins for ATP and ADP were determined as described in the accompanying article (33) using equilibrium dialysis. Briefly, the reaction was carried out in pH 7.0 standard ATPase buffer with rBiP on one side and [^14C]ATP or ADP on the other side of the dialysis membrane. The dialysis chambers were rotated at 4 °C and at equilibrium, an aliquot of 25 µl was taken from both sides of the membrane for scintillation counting. To measure the binding constants of G226D and G227D BiP mutants, we used nucleotide concentrations ranging from 50 to 400 µM with 50 µM rBiP proteins. Nucleotide-free preparations of T37G and T229G mutants were prepared as described for WT BiP(33) . Samples were analyzed by HPLC to ensure that they were free of nucleotide and then the ATP and ADP binding constants were determined.

BiP Binding to Peptide and Release by ATP

Peptide C (2) was coupled to cyanogen bromide-activated Sepharose beads (Pharmacia, Sweden) according to the manufacturer's suggestions. 50 µg of rBiP was incubated with 100 µl of Peptide C beads (1:1 beads:buffer) in 1 ml of ATPase buffer. After rotating at 4 °C for 1 h, the beads were washed three times with ATPase buffer containing 0.2 M NaCl. The beads were then divided equally into two halves and incubated in 1 ml of ATPase buffer either with or without 100 µM ATP for 30 min at room temperature. The beads were re-washed in ATPase buffer containing 0.2 M NaCl, resuspended in SDS sample buffer, heated to 100 °C for 5 min, and analyzed by SDS-PAGE. Proteins were visualized by Coomassie Blue staining and quantitated by scanning densitometry (BioImage, Ann Arbor, MI).


RESULTS

Mutation of Residues in the ATP Binding Site

In order to produce and isolate BiP mutants that were either defective in ATP binding or ATP hydrolysis, our first step was to identify candidate residues to be mutated. Because the ATP binding domains of HSP70 members are highly homologous(1) , we previously took advantage of structural data obtained for the hsc70 ATPase domain and mutated several residues in hamster BiP that could potentially participate in either ATP binding or hydrolysis(16) . These included Thr (Thr in hsc70) and Thr (Thr in hsc70) which lie in close proximity to the -phosphate of ATP in the hsc70 structure (Fig. 1), and Glu (Glu in hsc70) which interacts with the divalent cation required for nucleotide binding. Mutation of these residues to glycine inhibited the ATPase activity of rBiP(16) .


Figure 1: Mutated residues in BiP were located in the ATP binding site of hsc70 to demonstrate their spacial relation to ATP. Presumed positions of the mutated residues in BiP are depicted based on the known position of the homologous residues in hsc70. For each residue, the actual position of the hsc70 side chain is shown with the BiP residue number (i.e. T37 = Thr in hsc70, G226 and G227 = Gly and Gly in hsc70, and T229 = Thr in hsc70). Structural manipulation was performed by using Rasmol program.



Two dominant negative mutations have been identified in Kar2 (yeast BiP homologue) that occur at residues corresponding to Gly and Gly in hamster BiP. (^3)In both cases, the mutation involved a glycine to aspartic acid change. The corresponding residues were identified on the three-dimensional structure of the hsc70 ATPase domain (Fig. 1), and the distances between the alpha carbon of these glycines and the oxygen group of the alpha phosphate of ADP were measured. Gly was 3.66 Å from ADP and Gly was 4.09 Å away, suggesting that the substitution of an amino acid with a large charged side chain at either position might have profound effects on nucleotide binding or hydrolysis. All of these structurally and genetically identified residues (Thr, Thr, Glu, Gly, and Gly in BiP) are completely conserved in Escherichia coli, yeast, and mammalian HSP70 family members.

Mutant BiP Proteins Retain Overall Structural Integrity

Endogenous BiP (26) and wild-type rBiP (27, 33) exist as monomers, dimers, and some higher order oligomers. Because mutation of residues in BiP's ATP binding cleft could lead to conformational changes resulting in instability or aggregation of the proteins, we first determined the structural integrity of these mutants by analyzing their oligomerization status on nondenaturing gels. We found that most of the mutant rBiP proteins entered the gel and existed as monomers, dimers, and oligomers, a pattern that was indistinguishable from WT BiP (Fig. 2). The E201G and E201K mutants did not resolve into distinct monomers and dimers on nondenaturing gels (not shown) and were therefore excluded from further studies.


Figure 2: Nondenaturing gel analysis of mutant BiP. 15 µg of Ni-agarose purified, recombinant hamster BiP proteins were electrophoresed on 2-15% nondenaturing polyacrylamide gel at 4 °C for 16 h. The proteins were then visualized by Coomassie Blue stain. The positions of monomers, dimers, and higher order oligomers are marked on the left.



Determination of ATPase Activity of Mutant BiP Proteins

The effect of the various mutations on the ATPase activity of BiP was determined. At a concentration of 1.0 mM ATP, the T229G mutant had no detectable ATPase activity, while the other three mutants (G226D, G227D, and T37G) had ATPase activities that were reduced relative to WT BiP (Fig. 3). The actual rates of hydrolysis for the individual mutants varied between different preparations but were reproducible for a single preparation. The variations between preparations are provided for the 30-min time point (Fig. 3). As shown in Table 1, the G226D and G227D BiP mutants had decreased V(max) (1.7 ± 0.2 and 1.5 ± 0.2 pmol/min/µg, respectively) compared to wild-type BiP (V(max) = 5.2 pmol/min/µg), and their K(m) values (97 ± 14 and 93 ± 17 µM) were significantly increased compared to that of WT BiP (K(m) = 1.5 µM). The finding that the G226D and G227D mutants had elevated K(m) values was further supported by the observation that the ATPase activity of these two mutants relative to WT BiP increased as the concentration of ATP was increased from 5 µM to 1 mM (data not shown).


Figure 3: ATPase activity of BiP mutants. The ATPase activity of wild-type and mutant BiP proteins were measured using 2.0 µM protein and 1.0 mM [-P]ATP in the standard ATPase/ATP binding buffer (``Materials and Methods''). The reactions were incubated at 37 °C for the indicated time, and 20 µl were removed for P extraction and counted. Nanomoles of P(i) liberated were calculated based on the specific activity of the [-P]ATP. Bovine serum albumin was assayed in parallel as a negative control. The range of values obtained from various preparations of each mutant is provided for the 30-min time point.





Nucleotide Binding Properties of BiP Mutants

The reduced ATPase activity of the various BiP mutants could result from either a defect in ATP binding or ATP hydrolysis. To distinguish these two possibilities, we measured the binding affinity of our mutants for ATP and ADP using equilibrium dialysis and the results are summarized in Table 1. The T229G and T37G mutants had ATP and ADP binding affinities that were essentially the same as those calculated for wild-type BiP (see (33) ). This demonstrated that the impaired ATPase activity of these two mutants was not due to their inability to bind ATP but to an inability to hydrolyze it. Perhaps this is not surprising since both of the mutations occur at residues that are close to the -phosphate of ATP and involve the substitution of a glycine which should not hinder the binding of nucleotide in this cleft.

Similar studies on the G226D and G227D mutants revealed that, although both mutants retained some ATPase activity (K(m) 100 µM), we were unable to measure nucleotide binding by equilibrium dialysis using nucleotide concentrations ranging from 50 to 400 µM with 50 µM of mutant protein. These binding data were further supported by HPLC analyses of the nucleotide content of these mutants after they were purified from bacteria. Unlike WT BiP and the T229G mutant, which both contained bound ADP that was resistant to dialysis, the G226D and G227D mutants had no detectable nucleotide bound to them (data not shown).

Thus, we were concerned that the ATPase activity observed with G226D and G227D could be due to a trace contamination by a stronger ATP hydrolyzing protein. To rule out the possibility of contamination, we first rebound the recombinant protein to Ni-agarose and washed the column with 1 M salt to remove any BiP-associated proteins, and second, we chose several new bacteria colonies expressing each of the mutants. Both the salt-extracted and the new isolates were analyzed for ATPase activity and nucleotide binding. Identical results were obtained: the G226D and G227D mutants still had some ATPase activity but no detectable nucleotide binding capability. Photoaffinity labeling of the G227D mutant with 100 µM radioactive azido-ATP demonstrated that this mutant could indeed bind ATP (data not shown), further ruling out the possibility that the ATPase activity came from a contaminating protein. Thus, these two mutants evidently bind ATP, but their affinity for ATP is decreased to such an extent that the binding assay used here is unable to detect this binding.

Protease Digestion of BiP Mutants in the Presence of Nucleotide

BiP and other HSP70 members produce characteristic proteolytic patterns when digested with protease in the presence of ATP versus ADP(11, 12) . An NH(2)-terminal 44-kDa fragment that comprises the nucleotide binding domain of HSP70 proteins is protected from proteolysis when ADP is present in this cleft. Upon ATP binding, a conformational change occurs in the HSP70 protein resulting in the protection of a 60-kDa fragment that includes both the protein binding domain and the ATP binding domain(11) . We wished to use this assay to determine if the two BiP mutants with wild-type ATP binding affinity underwent a proper conformational change upon ATP binding and to verify that the ATP binding mutants were unable to protect the 60-kDa fragment. WT and mutant BiP proteins were digested with proteinase K, a nonspecific serine protease, in the presence of ADP, ATP, or no added nucleotide (Fig. 4). In the accompanying paper(33) , we demonstrated that WT rBiP exhibited the same proteolytic patterns as native BiP isolated from dog pancreas (i.e. ATP protected both a 60- and 44-kDa fragment, while ADP protected a 44-kDa fragment). Proteolytic digestion of the T229G mutant generated a pattern identical to that observed with WT BiP (Fig. 4). This is consistent with the observation that the T229G mutant binds ATP with the same affinity as WT BiP. Furthermore, it suggests that ATP induced a similar conformational change in this mutant.


Figure 4: Protease digestion of BiP mutants. 10 µg of purified wild-type and mutant BiP were either digested with 2.0 µg of proteinase K for 25 min in the presence of 0.1 mM ATP, 0.1 mM ADP, or no added nucleotide or left undigested. Proteinase K was inactivated by adding phenylmethylsulfonyl fluoride. The samples were analyzed by SDS-PAGE and detected by Coomassie Blue staining. Positions and sizes of the major proteolytic fragments are marked at the right.



ATP did not protect a 60-kDa fragment in either the G226D or G227D mutant, which is in agreement with our inability to demonstrate stable binding of ATP to these mutants. However, the 44-kDa fragment was still protected in the absence of any added nucleotide. HPLC analyses revealed that these mutants did not contain ATP or ADP (data not shown), suggesting that the NH(2)-terminal ATP binding domain folds compactly even in the absence of nucleotide and is in keeping with data obtained for nucleotide-free WT BiP that was also analyzed (33) . Surprisingly, ATP did not protect a 60-kDa fragment in the T37G mutant, even though its ATP binding affinity was normal. This suggests that T37G is unable to undergo the appropriate conformational change upon binding to ATP that leads to changes in the protein binding domain.

Conformational Mutant Is Defective in Peptide Stimulated ATPase

We tested the possibility that the T37G mutant was impaired in its ability to transduce a signal from the ATP binding domain to the protein binding domain by examining the effect of peptide on the ATPase activity of both WT BiP and the T37G mutant (Fig. 5). As expected, we found that the ATPase activity of WT BiP could be stimulated about 2-3-fold by peptide. However, the ATPase activity of T37G was not stimulated by peptide, further suggesting that T37G does not undergo the proper conformational changes required to transduce information from one domain of BiP to the other. Thus, based on comparisons of ATPase activity, ATP binding affinity, and proteolytic protection analyses, our mutants were grouped into three classes: 1) ATP hydrolysis mutants (T229G), those that bind ATP, undergo a conformational change, but cannot hydrolyze it; 2) conformational change mutants (T37G), those that bind ATP but do not undergo an ATP-induced conformational change; and 3) ATP binding mutants (G226D and G227D), those that are extremely impaired in their ability to bind nucleotide.


Figure 5: Peptide effect on the ATPase activity of T37G and WT BiP. ATPase activity was assayed as described in the legend to Fig. 3. Peptide I or peptide C (500 µM) was included for assaying peptide-stimulated ATPase activity. All the reactions were incubated at 37 °C for 30 min. Relative units of ATPase activity were calculated.



Release of Bound Peptides from BiP Mutants

It has been shown that HSP70 proteins bind unfolded proteins or peptides and release them upon ATP addition in vitro(2, 4, 5, 10, 28) . To further understand the mechanism of this process, we used our three groups of mutants to determine what is required for the release of proteins in vitro. All three classes of mutants bound to peptide C-coupled Sepharose beads similar to WT BiP (Fig. 6). Upon ATP addition, both WT BiP and the ATP hydrolysis mutant, T229G, were released from the peptide beads (Fig. 6). There was no evidence that the inability to hydrolyze ATP affected the rate of release, since both wild-type and T229G mutant BiP were released from the peptide beads with the same kinetics (data not shown). As anticipated, the ATP binding mutants, G226D and G227D, were not released from the peptide-conjugated beads with ATP. Most interestingly, we found that the T37G mutant that bound ATP but was unable to undergo the appropriate conformational change was as impaired in its ability to be released from peptide as the mutants that did not bind ATP. These results demonstrate that ATP hydrolysis is not required for the release of peptide form BiP. Additionally, they establish that ATP binding is not sufficient, but that an ATP-induced conformational change in BiP is essential for its release from peptide.


Figure 6: Peptide binding to WT and mutant BiP and release by ATP. Upper panel, rBiP proteins were incubated with peptide C-coupled beads at 4 °C for 1 h, washed, and then either incubated with ATP (+) or without ATP(-) for 30 min at room temperature. Beads were washed and bound proteins were analyzed by SDS-PAGE. Bottom panel, the density of the protein bands in the upper panel were quantitated by scanning densitometry. The amount of bound protein without ATP represented 100% binding and the amount remaining after ATP treatment was calculated as a percent of the ATP(-) bands.




DISCUSSION

Our identification of three classes of BiP ATPase mutants further delineates the events in ATP hydrolysis and allows us to separate each event to determine its functional significance. Since the residues we mutated in BiP are absolutely conserved in the highly homologous ATP binding domain of all HSP70 members, we anticipate that similar changes in other members would produce similar classes of mutants.

Two dominant negative mutants have been identified in Kar2 (yeast BiP) that resulted from the mutation of Gly and Gly to aspartic acid.^3 Although these mutants have not been characterized biochemically, examination of side chain coordinate data revealed that in hsc70 the corresponding residues (Gly and Gly) are only 3.66 and 4.09 Å, respectively, from the alpha phosphate of ATP. It is easy to imagine that substitution of a large, negatively charged side chain at this site would interfere with the binding of both ADP and ATP. Indeed, we found that mutation of the corresponding residues in hamster BiP (G226D and G227D) yielded ATP and ADP binding mutants. Although the K(d) values for these two mutants could not be directly obtained, their binding affinities for ATP were significantly lowered as estimated from their K(m). Because these mutants still have partial ATPase activity and can be labeled with azido-ATP, we suspect that the decreased affinity is most probably due to an increased off-rate. This correlates well with our protease digestion data demonstrating that there was no protection of the 60-kDa fragment that is characteristic of stable ATP binding.

However, our inability to detect nucleotide binding for the G226D and G227D mutants remains a concern. We checked to see if this could be a result of aggregate formation at the high protein concentrations used for this assay. However, we found that the proteins were completely soluble after equilibrium dialysis and existed as both dimers (60%) and monomers (40%). Interestingly, the mutant dimers could not be shifted to monomers by the addition of 200 µM ATP, whereas the WT BiP dimers were readily converted to monomers. Therefore, under the nucleotide binding conditions, the WT BiP was monomeric while these two mutants were largely dimeric (data not shown). This difference in molecular forms could further contribute to our inability to measure stable nucleotide binding for the G226D and G227D mutants since BiP dimers may have a lower affinity for ATP(29) . In summary, we have been as rigorous as possible in an attempt to resolve the discrepancy between the K(m) measured for these mutants and our inability to detect stable nucleotide binding and can find no obvious technical reason for it. Despite this, all of our assays demonstrate that both mutants are impaired in their ability to bind to nucleotide.

The T229G mutant was described previously as a BiP ATPase mutant(16) . The characterization presented here demonstrates that the defect leading to reduced ATPase activity is not due to an inability of this mutant to bind ATP or to undergo a conformational change after binding ATP, but is due to its inability to hydrolyze ATP. The importance of T229 in ATP hydrolysis was anticipated by structural predictions(13, 14) . This threonine has been mutated in both dnaK (Thr) and hsc70 (Thr). Characterization of the dnaK Thr mutants revealed that substitution of an alanine, valine, or aspartic acid at this site greatly reduced the ATPase activity of the mutants (0.6, 3, and 7%, respectively) compared to that measured for WT dnaK(19) . These mutants still bind ATP-agarose (19) , and the T199A mutant undergoes a conformational change upon ATP binding resulting in the release of substrate protein(10) , which is entirely consistent with our characterization of the BiP T229G mutant. Unlike the data obtained for dnaK and BiP, mutation of the corresponding threonine (Thr) in hsc70 results in an increase of both k and K(m)(21) .

HSP70 proteins bind nucleotide in the NH(2)-terminal domain and polypeptide in the C-terminal domain. ATP causes the release of bound polypeptides and peptide binding can activate the ATPase activity, suggesting that communication between the two domains is important for the functions of HSP70 proteins. The protection of a 60-kDa fragment with ATP versus a 44-kDa fragment with ADP in the presence of proteases (11, 12) implies that a conformational change takes place in HSP70 proteins upon ATP binding that affects the protein binding region residing between the 44- and 60-kDa cleavage sites(30) . The T37G mutant binds ATP and ADP with normal affinity, but a 60-kDa fragment was not protected during proteolysis in the presence of ATP, suggesting that the ATP-induced conformational change does not occur in the T37G mutant. This uncoupling was further confirmed by the finding that its ATPase activity was not stimulated by peptide. The fact that the K(d) for ATP and ADP were not altered in this mutant suggests that the conformational change in the protein binding domain does not act to stabilize ATP in the pocket, but to transduce a signal from the ATPase domain to the protein binding domain for substrate release. A dnaK transducing mutant was recently described that resulted from the mutation of Glu (Glu in BiP) to alanine, leucine, or lysine (31) suggesting that there may be several ways to uncouple the ATP-mediated release of proteins from HSP70 members.

A recent report demonstrated that the rate of peptide release from dnaK and hsc70 after ATP binding was faster than the rate of ATP hydrolysis (10) , implying that ATP binding, not hydrolysis, triggered the release of peptide. The dnaK T199A mutant is impaired in its ability to hydrolyze ATP, but it is able to release denatured proteins with ATP in the presence of KCl(10) . The ability of our ATP hydrolysis mutant, T229G, to be released from peptide with ATP supports this data. The ATP binding-mediated release they described requires KCl and does not occur with NaCl(10) . We previously reported that the T229G mutant was defective in peptide release using a NaCl containing buffer(16) , but this mutant is released as readily as wild-type BiP when KCl is present in the buffer. This suggests that KCl is required for the ATP-induced conformational change in HSP70 proteins. The same group (10) found that ATP analogues were unable to release bound polypeptides from dnaK or hsc70 which is in agreement with earlier reports(2, 3, 4, 5) . However, they showed that this was not because ATP hydrolysis is necessary for the release but was because the ATP analogues do not induce a conformational change in the HSP70 proteins(10) . Our characterization of the three classes of ATPase mutants allowed us to re-examine this question and to confirm their findings in several different ways. First, the ATP hydrolysis mutant (T229G), that binds ATP with wild-type affinity but does not hydrolyze it, released peptide upon ATP addition with the same apparent kinetics as wild-type protein. Second, the ATP binding mutants (G226D and G227D) were not capable of releasing bound peptide. Finally, we were able to determine that ATP binding per se is not sufficient for peptide release, but that a concurrent conformational change induced by ATP binding is also required.

Most current models on HSP70 protein binding and release portray the ADP-HSP70 complex as peptide binding competent and ATP-HSP70 as incompetent for peptide binding. In vivo these may be the only two forms of HSP70, since the binding affinity of both ATP and ADP are very high. However, our in vitro data on the two nucleotide binding mutants demonstrate that ADP binding is not a requirement for making BiP receptive to peptides. This is further supported by the fact that the protein binding domain of hsc70 (32) and BiP(23) , expressed without the ATP binding domain, are able to bind polypeptides.

In vitro systems have provided sophisticated and essential information on nucleotide binding, nucleotide-induced changes, and nucleotide hydrolysis by HSP70 proteins and delineated the requirements for in vitro release of bound proteins. These data have been instrumental in allowing investigators to produce models of how the ATP binding/hydrolysis activities of HSP70 proteins regulate their function in vivo. However, it has not been possible to directly test these models because separating these events in vivo is not feasible. Our identification of BiP ATPase mutants that are defective in the various steps in ATP hydrolysis, coupled with an in vivo expression system and a species-specific antisera to recognize the transfected mutants (23) will allow for the first time the direct testing of the various HSP70 functional models in vivo.


FOOTNOTES

*
This work was supported by National Institutes of Health Grant GM 43576, Cancer Center Support CORE Grant CA 21765, and the American Lebanese Syrian Associated Charities of St. Jude Children's Research Hospital. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed: Dept. of Tumor Cell Biology, St. Jude Children's Research Hospital, 332 N. Lauderdale, Memphis, TN 38105. Tel.: 901-495-2475; Fax: 901-495-2381.

(^1)
The abbreviations used are: HSP70, 70-kDa heat shock protein; BiP, immunoglobulin binding protein; HPLC, high performance liquid chromatography; AMPPNP, 5`-adenylyl imidodiphosphate.

(^2)
L. M. Hendershot, J. Wei, J. R. Gaut, J. Melnick, S. Aviel, and Y. Argon, manuscript submitted.

(^3)
J. Vogel and M. Rose, personal communication.


ACKNOWLEDGEMENTS

We are grateful to Dr. D. B. McKay (Stanford University, Stanford, CA) for sending the side chain coordinate data for the hsc70 ATPase domain, Drs. J. P. Vogel and M. D. Rose (Princeton University, Princeton, NJ) for sharing their preliminary characterization of dominant negative Kar2 mutants, and Dr. A. S. Lee (University of California, Los Angeles, CA) for providing us with the hamster Grp78/BiP cDNA clone. Thanks also go to Dr. G. M. Carlson (University of Tennessee), J. B. Easton (St. Jude Children's Research Hospital, Memphis, TN), and B. C. Gao (National Institutes of Health) for helpful discussions. Oligonucleotides were synthesized by the Center for Biotechnology at St. Jude Children's Research Hospital.


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