(Received for publication, July 12, 1996, and in revised form, October 24, 1996)
From the Department of Molecular and Cell Biology, University of Connecticut, Storrs, Connecticut 06269-3044
Cytoplasmic Hsc70 is a multifunctional molecular chaperone. It is hypothesized that accessory proteins are used to specify the diverse chaperone activities of Hsc70. A 16-kDa cytosolic protein (p16) co-purified with Hsc70 obtained from a fish hepatocyte cell line, PLHC-1. Hsc70 also co-immunoprecipitated with p16 from PLHC-1 cells and fish liver. p16 was identified as a member of the Nm23/nucleoside diphosphate (NDP) kinase family based on its amino acid sequence similarity, NDP kinase activity, and recognition by anti-human NDP kinase-A antibody. This antibody also co-immunoprecipitated Hsc70 and NDP kinase from human HepG2 cells. p16 monomerized Hsc70 and released Hsc70 from pigeon cytochrome c peptide (Pc) but not from FYQLALT, a peptide specifically designed for high affinity binding. Therefore, p16 may modulate Hsc70 function by maintaining Hsc70 in a monomeric state and by dissociating unfolded proteins from Hsc70 either through protein-protein interactions or by supplying ATP indirectly through phosphate transfer. p16 did not affect basal or unfolded protein-stimulated ATPase activity of bovine brain Hsc70 using in vitro assays. Interestingly, bovine liver NDP kinase did not dissociate the Hsc70·Pc complex. In addition, two nonconservative amino acid subsitutions were found near the amino terminus of p16. Therefore, p16 may be a unique Nm23/NDP kinase that functions as an accessory protein for cytosolic Hsc70 in eukaryotes.
Organisms respond to a variety of chemical and physiological stresses by rapidly synthesizing a group of conserved polypeptides known as heat shock or stress proteins. The induction of these stress proteins is a defense against proteotoxicity, a term used to describe damage to proteins caused by diverse stressors (1). Interestingly, in addition to their function in stressed cells, some members of these stress protein families are normally abundant in nonstressed cells, such as the constitutively expressed 70-kilodalton (kDa) heat shock cognate protein (Hsc70).1 Hsc70 functions as a molecular chaperone to maintain protein homeostasis (protein folding, translocation, assembly, disassembly, and degradation) in cells under normal conditions as well as during stress (reviewed in Refs. 2-4). Hsc70 was originally characterized as an uncoating ATPase that dissociates clathrin triskelions from clathrin-coated vesicles (5-7). It maintains the translocation-competent state of proteins destined for endoplasmic reticula and mitochondria (8-10) and transiently interacts with nascent polypeptides during translation (11, 12). Hsc70 is a crucial component in targeting proteins to lysosomes for degradation (13, 14) and in importing cytoplasmic proteins into the nucleus (15-17). Hsc70 cooperates in TRiC-mediated folding (18) and may be involved in targeting proteins to the ubiquitin/proteasome machinery for degradation (19, 20). In cooperation with Hsp90, Hsc70 is involved in steroid receptor signaling (reviewed in Refs. 21-23). Hsc70 also binds to retinoblastoma protein (24) and to a mutant form of tumor suppressor protein p53 (25). In addition, Hsc70 suppresses protein aggregation (26) and reactivates heat-denatured proteins (27). Hsc70 may also transiently bind to monomeric heat shock transcription factor to keep it in an inactive state. (28, 29).
Hsc70 participates in these diverse cellular processes through the
binding and release of protein substrates at the expense of ATP
hydrolysis. Hsc70 recognizes short extended peptide sequence motifs
enriched in either aromatic/hydrophobic or hydrophobic/basic residues
(30, 31). Flexibility in the Hsc70 peptide binding domains can only
explain part of the diverse functions of Hsc70. Recent research has
suggested that specific accessory proteins may help to determine the
diverse chaperoning activities of Hsc70 (reviewed in Ref. 32). For
example, the accessory proteins DnaJ and GrpE cooperate with DnaK in
Escherichia coli in the replication of phage (33) and P1
plasmid (34), in the negative autoregulation of the heat shock response
(35-37), and in the reactivation of heat-inactivated RNA polymerase
(27) and firefly luciferase (38). These two accessory proteins have
different actions on DnaK. DnaJ can present certain substrates to DnaK
and stimulate the ATPase activity of DnaK while GrpE seems to act as a
nucleotide exchange factor (34, 39).
Although a eukaryotic GrpE homolog has only been found in mitochondria (40-43), a family of DnaJ homologs has been discovered based on the similarity of their N-terminal J-domains (1-70 amino acid residues; see Ref. 44). However, their limited sequence similarity besides the J-domain suggests that the function of each DnaJ homolog may have become specialized (45). For example, in yeast, the cytosolic DnaJ homolog Sis1 binds to Hsc70 during translation while Ydj1, another DnaJ homolog, is thought to target Hsc70 bound substrates to mitochondria and endoplasmic reticula (46, 47). Furthermore, overexpression of Ydj1 cannot rescue Sis1 deletion phenotypes, suggesting that Sis1 has a more specialized function (48). In addition to DnaJ and GrpE homologs, there appear to be a number of other cofactors that are involved in specific Hsc70 chaperone functions. For example, a 100-kDa protein, auxilin, is required for Hsc70 to uncoat clathrin-coated vesicles (49-51). Recently, Hartl and co-workers (52) isolated a 41-kDa Hsc70-interacting protein, Hip, using the yeast two-hybrid system. Hip may modulate the interaction of Hsc70 with different substrates through the stabilization of the ADP-bound state of Hsc70.
In further support of the hypothesis that multiple accessory proteins are required for diverse chaperoning functions of Hsc70, we report here the isolation of a new cytosolic accessory protein for eukaryotic Hsc70. This 16-kDa protein (p16) monomerizes Hsc70 and dissociates Hsc70 from peptide substrate; it is a member of Nm23/nucleoside diphosphate kinase family.
Poeciliopsis lucida hepatocellular
carcinoma (PLHC-1) cells were isolated from a
7,12-dimethylbenz[a]anthracene-induced hepatocellular carcinoma of a desert topminnow P. lucida (53, 54). PLHC-1 cells were grown in Eagle's minimal essential medium with Earle's buffer (Life Technologies, Inc.), pH 7.2, supplemented with 10% (v/v)
calf serum (J. R. H. BioSci) and 4 mM
L-glutamine in a 30 °C humidified incubator containing
5% CO2. No antibiotics were used. Cultures were
mycoplasma-free, as determined using a DNA fluorochrome-staining technique (55). Human hepatocellular carcinoma (HepG2 cells, ATCC HB
8065) were grown in CO2-independent medium (Life
Technologies, Inc.) with 5% fetal bovine serum (Hyclone Laboratories)
at 37 °C. Confluent PLHC-1 cells or HepG2 cells were dissociated
with 0.05% (w/v) trypsin and 0.5 mM EDTA in calcium- and
magnesium-free phosphate-buffered saline (CMF-PBS), and the cells were
harvested by centrifugation at 100 × g for 5 min.
Harvested cells were washed once in serum-containing medium to
inactivate the trypsin and then three times in CMF-PBS. Then the cells
were immediately frozen in liquid nitrogen and stored at 70 °C.
Usually four 225-cm2 confluent PLHC-1 cultures yielded
1 g of cells.
Bovine Hsc70 was purified
according to Sadis and Hightower (56). p16 was purified by lysing
PLHC-1 cells in 5 volumes of lysis buffer (11 mM Tris-Cl,
pH 8.8, 100 mM NaCl, 0.5% (w/v) sodium deoxycholate, 1%
(v/v) Triton N-101, 150 mM -mercaptoethanol, 2 mM EDTA, and 1 mM phenylmethylsulfonyl
fluoride) for 10 min. Then the cell lysate was clarified by
ultracentrifugation at 70,000 × g for 1.5 h and
dialyzed overnight against 40-50 volumes of buffer C (20 mM Hepes-KOH, pH 7.0, 25 mM KCl, 10 mM (NH4)2SO4, 2 mM magnesium acetate, 0.1 mM EDTA, 1 mM dithiothreitol) without magnesium acetate. After
dialysis, the cell lysate was adjusted to 2 mM magnesium
acetate and subjected to ATP-agarose chromatography (linked through
C-8, Sigma). The ATP-agarose was washed with 0.5 M KCl to remove nonspecific binding proteins, and then the
bound proteins were eluted with 1 bed volume of 1 mM ATP
(to remove the majority of actin) followed by 3 bed volumes of 5 mM ATP. The pH of the ATP stock solution was adjusted to
7.0 using KOH. p16 enriched fractions, identified by 11.5% SDS-PAGE
and silver staining (56), were pooled and dialyzed overnight against
buffer A (25 mM Tris-HCl, 0.1 mM EDTA, pH 7.0)
plus 1 mM dithiothreitol and then applied to a 1-ml fast
protein liquid chromatography Mono Q anion-exchange column (Pharmacia
Biotech, Inc.). The column was washed with 5 ml of 0.05 M
KCl in buffer A, and then the bound proteins were fractionated with a
30-ml linear gradient of 0.05-0.15 M KCl in buffer A. p16-enriched fractions were dialyzed overnight against buffer C and
then concentrated to 1 mg/ml with a Centricon 3 ultrafiltration unit
(Amicon, Danvers, MA). Protein concentrations were determined using the
Bradford assay (Bio-Rad Laboratories). Approximately 600 µg of p16
were obtained from 20 g of a PLHC-1 cell pellet. The purified
protein was stored at
70 °C in 10% glycerol.
Assays were assembled on ice in a final volume of 10 µl using 2 µg of bovine Hsc70 or 0.5 µg of p16 in buffer C. Incubations were carried out at 37 °C at the indicated times. For p16 and Hsc70 interactions, Hsc70 was incubated with or without p16 for 30 min (p16 by itself as control). For p16, Hsc70, and peptide interactions, either 35 µM of pigeon cytochrome c peptide (Pc, residues 81-104, IFAGIKKKAERADLIAYLKQATAK) or 10 µM of FYQLALT (the minimal peptide concentrations necessary to completely shift 2 µg of Hsc70 in a nondenaturing gel) was used to form Hsc70·peptide complexes for 30 min, and then the complexes were incubated in the presence or absence of p16 for another 30 min (p16 with Hsc70, Pc, or FYQLALT as control). The effect of ATP or NDP kinase purified from bovine liver (Sigma N2635) on the Hsc70·Pc complex was assayed as described above by replacing p16 with either 1 mM ATP or 0.5 µg of NDP kinase (Hsc70 or NDP kinase by itself as control). After incubation, all the samples were immediately placed on ice. Then gel loading buffer was added to the samples to give a final concentration of 50 mM Tris acetate, pH 7.5, 10% glycerol. Half of the protein sample from each assay was analyzed in a 6% (w/v) acrylamide, 0.16% (w/v) bisacrylamide mini-slab gel (nondenaturing gel) that was subjected to electrophoresis for 1.5 h at constant voltage (200 V) in 50 mM Tris acetate buffer, pH 7.5, at 4 °C. Compared to a commonly used basic nondenaturing gel method (31), this neutral nondenaturing gel method not only gives a better separation of Hsc70 and p16, but also allows proteins to be analyzed under conditions closer to their physiological pH. The gels were then fixed in 30% methanol, 10% acetic acid and silver stained.
ATPase Activity1 µg of p16 was added to 2.5 µg of
Hsc70, and its intrinsic and apocytochrome c (apo
c, 200 µg/ml)-stimulated ATPase activity was determined by
measuring the release of radioactive inorganic phosphate
(32Pi) from [-32P]ATP
(57).
Purified p16 was cleaved by endoproteinase-Arg-C to generate peptide fragments for internal amino acid sequencing. Two of the HPLC-purified peptide fragments were sequenced (Protein Structural Laboratory, University of California at Davis). The resulting sequences were used to search for similarity in the GenBank and SwissProt data bases.
NDP Kinase Activity of p16NDP kinase activity of purified p16 was determined by thin layer chromatography (TLC) as follows. 1 µg of purified p16 was incubated with 1.8 mM ATP and 1.8 mM GDP in buffer C at 30 °C for 5 min either in the presence or absence of 75 mM EDTA. An aliquot from each reaction was spotted onto a 20 × 20 cm polyethyleneimine-cellulose-F TLC plate (Sigma), and the nucleotides were resolved by capillary action in a saturated tank of 0.75 M KH2PO4, pH 3.6. The TLC plate was then air dried, and the nucleotides were visualized under ultraviolet light at a wavelength of 254 nm.
Immunoblot AnalysisProtein samples were analyzed in 11.5% SDS-PAGE and electroblotted onto a polyvinylidene difluoride membrane (Millipore). The membrane was then dried overnight to maximize protein binding. Nonspecific binding sites on the membrane were blocked using 5% FBS, 3% bovine serum albumin in PBS for 30 min at 37 °C, and then the membrane was incubated with primary antibody. An affinity purified rabbit polyclonal antibody raised against human NDP kinase-A (Oncor, Gaithersburg, MD) was used to identify p16. Hsc70 and Hsp70 were detected by using a monoclonal antibody (clone 3a3) raised against human Hsp70 (Affinity BioReagents, Neshantic Station, NJ). Antibody binding was visualized by a colorimetric method using alkaline phosphatase-conjugated secondary antibody (Sigma) with 5-bromo-4-chloro-3-indolyl phosphate/nitroblue tetrazolium as the substrate. The color development was stopped by adding 20 mM EDTA.
Co-immunoprecipitation of p16 and Hsc70 from PLHC-1 CellsAll procedures were performed at 4 °C. PLHC-1 cells,
HepG2 cells, or P. lucida liver tissue were resuspended in 3 volumes of cold hypotonic buffer (1.5 mM MgCl2,
5 mM KCl, 10 mM Tris-Cl, pH 8.0, 0.1 mM EDTA, 1 mM phenylmethylsulfonyl fluoride)
per gram of cell/tissue for 10 min. PLHC-1 and HepG2 cells were lysed
by passing them through a 27 gauge needle 15-16 times. P. lucida liver tissue was homogenized by a hand-operated glass
homogenizer. Cell lysis was monitored using the vital stain trypan blue
(0.05% (w/v) in CMF-PBS). The cell lysate was then clarified three
times by centrifugation at 13,000 × g for 20 min in a
microcentrifuge, and the final supernatant was adjusted to the
concentration of buffer C. To facilitate the formation of the immune
complex, magnesium acetate was added to a final concentration of 5 mM. To prevent nonspecific binding, buffer C containing 1%
(w/v) ovalbumin was used to coat the tubes and to swell the protein
A-sepharose CL-4B (Sigma). All incubations for
immunoprecipitation were performed in a rotatory shaker to facilitate
mixing. An affinity purified rabbit polyclonal antibody that recognizes
a different protein (transforming growth factor-, R&D Systems Inc.,
Minneapolis, MN) was used as a positive control. Cell lysate (0.5-1
ml) was incubated with anti-NDP kinase-A antibody or control antibody for 2 h, and then protein A-sepharose was added and incubation continued for another 45 min. The captured immune complex was then
recovered by centrifugation at 200 × g for 1 min and
washed 4 times with buffer C containing 0.1% (w/v) ovalbumin and once with buffer C containing 0.1% (v/v) Nonidet P-40. After adding 2 × SDS-PAGE sample buffer and boiling for 5 min, the immune complex was
separated from the Protein A-sepharose by centrifugation at 13,000 × g for 5-10 s in a microcentrifuge. An aliquot from the supernatant was analyzed by 11.5% SDS-PAGE and immunoblotting. The
blot was then cut in half, and the presence of Hsc70 in the top half
and p16 in the bottom half were detected by 3a3 and anti-NDP kinase-A antibodies, respectively.
Confluent PLHC-1 cells were exposed to 0, 0.5, 5.0, and 7.5 mg/liter heavy metal cadmium ions (CdCl2) for 72 h to maximize protein accumulation, and then the cells were solubilized in 200 µl of SDS-PAGE sample buffer. Actin was used as an internal control for equal amounts of protein loading on SDS-PAGE. The changes in Hsc70 and Hsp70 combined (Hsp70s) and p16 protein levels were detected by SDS-PAGE and immunoblotting using 3a3 and anti-NDP kinase-A antibody, respectively.
Our initial goal was to
isolate Hsc70 from PLHC-1 cells using conventional chromatography.
However, a 16-kDa protein, as determined by Tricine-SDS-PAGE (data not
shown), co-purified with Hsc70 using three different types of
chromatography, ATP-agarose, anion exchange, and gel filtration
chromatography (Fig. 1). p16 and actin (identified by
molecular mass and binding to DNA-Sepharose) were co-eluted with Hsc70
from the ATP-agarose column (Fig. 1A) using 5 mM
ATP. When the Hsc70-enriched fractions (8-21) from the ATP-agarose were pooled, dialyzed, and then fractionated by Mono Q anion exchange chromatography (Fig. 1B), actin (fractions 19-21) now was
well separated from the majority of Hsc70 (fractions 14-16) while p16 (fractions 13-14) still overlapped with the leading edge of Hsc70. Because of the differences in their polypeptide molecular weights, we
attempted to separate Hsc70 and p16 using Superose-12 gel filtration chromatography (Fig. 1C). Fractions 11-12 represented the
protein peak of Hsc70 monomer, determined using molecular weight
standards. Interestingly, p16 (fractions 12-14) still partially
overlapped with Hsc70 monomer. Because this small protein co-purified
with Hsc70, we decided to investigate the possibility that p16 is an Hsc70-associated protein. To purify p16, a narrow salt gradient (0.05-0.15 M KCl) was used to separate a portion of p16
from Hsc70 in the Mono Q column. These fractions containing only p16
were used for assays.
Effect of p16 on Bovine Hsc70, Its Peptide Complexes and ATPase Activity in Vitro
If the co-purification of p16 and Hsc70 is not a coincidence, then p16 could either be an accessory protein or protein substrate of Hsc70. Since protein substrates form complexes with Hsc70 and stimulate Hsc70 intrinsic ATPase activity and since accessory proteins, such as DnaJ and GrpE, modulate Hsc70 peptide/protein substrate binding and ATPase activity, functional assays were used to address whether p16 can affect 1) nondenaturing gel mobility, 2) peptide substrate binding, and 3) ATPase activity of Hsc70.
In the presence of p16, the relative amount of Hsc70 dimers and trimers
decreased and the amount of Hsc70 monomer increased (Fig.
2, lanes 1 and 2). The monomeric,
dimeric, and trimeric Hsc70 protein bands in nondenaturing gel were
estimated to be 70-, 140-, and 210-kDa proteins, respectively, using
Superose-12 gel filtration (data not shown). In addition, the p16
protein band was more intensely stained by silver after incubation with Hsc70 (Fig. 2, lanes 2 and 3). There are two
possible explanations for this effect. First, p16 may exist as high
molecular weight oligomers that cannot migrate into the gel. In the
presence of Hsc70, these oligomers may break down allowing more p16 to
migrate into the gel. Second, p16 may undergo a conformational change in the presence of Hsc70 resulting in more intense silver staining.
Next we used synthetic peptides to investigate whether p16 can affect
Hsc70-substrate interaction. Both Pc and FYQLALT (30, 31,
58) bind strongly to Hsc70 and stimulate Hsc70 ATPase activity. The
Hsc70·Pc complex migrated slower than the Hsc70 monomer
(Fig. 3, lane 2) in the nondenaturing gel.
The migration of Hsc70·Pc complex in nondenaturing gel was
identified by the presence of radioactivity using tritium-labeled
Pc as a substrate (data not shown). In the presence of p16,
Hsc70 was dissociated from Pc (Fig. 3, lane 3).
Therefore, these data suggested that p16 indeed has a specific
functional relationship with Hsc70. Interestingly, the effect of p16 on
the Hsc70·FYQLALT complex was very different. Hsc70·FYQLALT
migrated faster than the Hsc70 monomer (Fig. 3, lane 4) and
p16 did not change the mobility of Hsc70·FYQLALT complexes (Fig. 3,
lane 5). However, the mobility of p16 itself was slowed
reproducibly in the presence of both Hsc70 and FYQLALT (Fig. 3,
lane 5) but not with FYQLALT alone (Fig. 3, lane
7). These data suggest that p16 undergoes a shape change in the
presence of Hsc70·FYQLALT complexes. It may be able to bind to
FYQLALT when presented by Hsc70 or p16 may interact differently with
Hsc70 carrying a tightly bound hydrophobic peptide. Therefore, we have
shown that p16 can affect Hsc70 in vitro by monomerizing
Hsc70 and by dissociating Hsc70 from Pc.
Hsc70 possesses intrinsic ATPase activity and an unfolded protein; apo
c stimulates this intrinsic ATPase activity 2-3 fold (57).
Interestingly, p16 did not affect either the intrinsic or apo
c-stimulated ATPase activity of Hsc70, and p16 itself is not
an ATPase (Fig. 4).
p16 Is an NDP Kinase
p16 is an N-terminally blocked protein
(data not shown), and based on amino acid analysis, has 4-5 arginine
residues. Therefore, purified p16 was cleaved using the endoproteinase
Arg-C to generate peptide fragments for internal amino acid sequencing.
Two peptides were sequenced and they were very similar to a known human
protein, Nm23/NDP kinase, with a molecular mass of approximately 17 kDa (59). As shown in Fig. 5, the first peptide fragment
matched 8 out of 10 amino acid residues at position 8-17 of Nm23/NDP
kinase, and the second fragment was 100% identical at amino acid
positions 89-104. Amino acid sequence comparisons demonstrate that NDP
kinase homologues are remarkably conserved from prokaryotes to
eukaryotes; for example, human and E. coli NDP kinases share
43% identity (60). Therefore, the two nonconservative amino acid
subsitutions (glycine to tyrosine and glutamine to serine) in p16
peptide 1 suggests that p16 may be a unique Nm23/NDP kinase.
The amino acid sequence similarity suggests that p16 might be an NDP
kinase; to confirm this, the NDP kinase activity of p16 was determined.
NDP kinases are biochemically defined by their ability to reversibly
transfer the -phosphate from any nucleoside triphosphate to any
other nucleoside diphosphate. Fig. 6, lane 1,
shows that purified p16 was able to transfer
-phosphate from ATP to
GDP forming GTP and ADP. Since magnesium ion is essential for the NDP
kinase activity, incubating p16 with excess EDTA to chelate magnesium
ions completely inactivated the kinase activity (Fig. 6, lane
2). Therefore, we confirmed that p16 has NDP kinase activity.
We then attempted to confirm the identity of p16 as an NDP kinase by
immunoblot analysis using a commercially available anti-NDP kinase
antibody. Fig. 7 shows that PLHC-1 cell lysate
(lanes 2 and 4) and purified p16 (lanes 3 and 5) were analyzed by SDS-PAGE and silver staining
(A) or immunoblot analysis (B). An affinity purified rabbit polyclonal antibody raised against human NDP kinase-A was incubated in both PLHC-1 cell lysate and purified p16. Fig. 7B shows that the antibody bound only to p16. Therefore,
based on its amino acid sequence similarity, NDP kinase activity, and recognition by anti-NDP kinase antibody, we have confirmed that p16 is
an NDP kinase.
Co-immunoprecipitation of p16 and Hsc70 from PLHC-1 Cells
The
polyclonal anti-NDP kinase-A antibody was then used for
co-immunoprecipitation of p16·Hsc70 complexes from PLHC-1 cell lysate. As shown in Fig. 8, lane 1, when
anti-NDP kinase-A antibody was used for immunoprecipitation, Hsc70 was
found associated with the p16-antibody immune complex. In the control
immunoprecipitation, neither p16 nor Hsc70 was found (Fig. 8,
lane 2). Similar results were obtained using P. lucida liver tissue (data not shown). To prove that the
association of p16/NDP kinase and Hsc70 exists in other vertebrate
cells, human hepatocellular carcinoma HepG2 cells were used for
immunoprecipitation. As shown in Fig. 8, bottom panel, lane
3, human NDP kinase A and B, with a molecular mass of
approximately 18 kDa each, were identified using anti-NDP kinase-A antibody, and Hsc70 was associated with NDP kinase-antibody immune complex (Fig. 8, top panel, lane 3). Again, neither NDP
kinase nor Hsc70 was found in the control immunoprecipitation (Fig.
8, lane 4). Therefore, Hsc70 indeed bound to p16/NDP kinase
and co-immunoprecipitated from PLHC-1 and HepG2 cell lysate as well as
P. lucida liver cells lysate with the anti-NDP kinase-A
antibody. Also, p16 appears to be a cytoplasmic protein rather than a
membrane-bound protein since it can be easily released from cells using
hypotonic lysis. Next, we used glutaraldehyde to cross-link purified
Hsc70 and p16 and then identified the cross-linked product by SDS-PAGE
and immunoblotting using 3a3 and anti-NDP kinase antibody. When a mixture of Hsc70 and p16 was treated with glutaraldehyde, the pattern
of cross-linked proteins was altered when compared with their
individual self cross-linking patterns. A new high molecular weight
cross-linked protein band was identified by anti-NDP kinase antibody
(data not shown). However, the interpretation of this new protein band
as a potential Hsc70·p16 cross-linked product was complicated by the
extensive self cross-linking of Hsc70 in the same high molecular weight
region (data not shown).
ATP, but Not Bovine NDP Kinase Dissociated Hsc70 from Pc
Since ATP can monomerize Hsc70 (61, 62) and ATP binding causes
substrate release from both Hsc70 and DnaK in the presence of potassium
ions (63), p16 may affect Hsc70 functions by providing ATP through its
NDP kinase activity. We first examined the effect of ATP on the
Hsc70·Pc complex. As expected, ATP effectively released Hsc70 from Pc (Fig. 9, lane 1).
Then we investigated whether mammalian NDP kinases can interact with
Hsc70. The commercially available NDP kinase purified from bovine liver
contained two polypeptides with approximate molecular masses of 18 and
19 kDa, respectively (data not shown); and it was able to transfer
-phosphate from ATP to GTP (data not shown). However, bovine NDP
kinase not only did not dissociate Hsc70 from Pc (Fig. 9,
lane 2), but it also migrated much slower than p16 during
nondenaturing gel electrophoresis (Fig. 9, lane 3). Since
the known oligomeric structures of NDP kinases (64) are either hexamers
(human, Drosophila, and Dictyostelium) or
tetramers (rat, yeast, and Myxococcus), it is possible that p16 and
bovine NDP kinase migrated as tetramer and hexamer, respectively.
p16 Is a Stress-inducible Protein
The protein levels of p16
increased with increasing concentrations of cadmium ions (Fig.
10 bottom panel, lanes 1-4), a
stressor that can induce cellular stress responses. Therefore, p16 is a stress-inducible protein. In addition, p16 showed cellular stress response to cadmium ions at lower concentrations with maximal protein
accumulation at 5.0 mg CdCl2/liter (Fig. 10, bottom
panel, lane 3) compared with that of Hsc70/Hsp70 at 7.5 mg CdCl2/liter (Fig. 10, top panel, lane
4).
Hsc70 Is Not Phosphorylated by p16
Next, we used
phosphorylation assay and nondenaturing gel electrophoresis to
investigate whether p16 can phosphorylate Hsc70 by transferring
32Pi label to bound ADP. We took advantage of
the fact that Hsc70 is a weak ATPase that hydrolyzes approximately one
molecule of ATP every 13 min (the turnover number,
kcat, was 0.075 molecule of ATP/min/Hsc70
monomer) (57). Therefore, if p16 transfers the terminal phosphate from
[-32P]ATP to Hsc70 bound ADP, at least some of the
Hsc70 should be radiolabeled, which can then be detected by
nondenaturing gel electrophoresis and autoradiography. Therefore, 1 µg of Hsc70 was incubated at 37 °C with or without 0.5 µg of p16
in buffer C containing 1.5 µCi of [
-32P]ATP. After
10 min, the samples were immediately placed on ice and analyzed using a
6% nondenaturing gel. After electrophoresis, the gel was dried under
vacuum at room temperature for 3 h. The dried gel was exposed to
x-ray film using intensifying screens at
70 °C. However, we did
not observe any phosphorylation of Hsc70 by p16 (data not shown).
The results reported here support the hypothesis that p16 is a new accessory protein for eukaryotic Hsc70. The partial co-purification of p16 and Hsc70 by ATP-agarose and gel filtration chromatography can be explained by the properties of NDP kinase (nucleotide binding and its native oligomeric state) and may have been fortuitous. However, subsequent analyses taken together make a strong case that p16 and Hsc70 interact: 1) Hsc70 co-immunoprecipitates with p16 from PLHC-1 cells, 2) p16 monomerizes Hsc70, and 3) p16 dissociates Hsc70 from Pc. Since unfolded or denatured proteins can bind to and stimulate intrinsic ATPase activity of Hsc70, the association between p16 and Hsc70 could result from the denaturation of p16 during purification. However, our data exclude this possibility because p16, like Hip, does not stimulate Hsc70 ATPase activity; and purified p16 has NDP kinase activity, i.e. it is an enzymatically active protein. Therefore, p16 appears to be an accessory protein that can modulate the oligomeric state of Hsc70 and dissociate unfolded proteins from Hsc70 in the absence of exogenous ATP. In further support of this hypothesis, our data show that p16 is a stress-inducible protein; it is possible that this association may assist Hsc70 and/or Hsp70 in protecting cells from stress-induced damage.
How might p16 modulate Hsc70 chaperone functions? p16 may be involved
in maintaining the active monomeric pool of Hsc70 inside cells. It has
been shown that purified Hsc70 exists as monomers, dimers, and trimers
(5, 61, 65). A current model suggests that the oligomers are the
storage/sequestration forms of Hsc70 that convert to active monomers in
the presence of ATP or protein/peptide substrates. In the presence of
ATP, Hsc70 oligomers are dissociated to monomers (61, 62), and a
similar result was obtained with Grp78 oligomers, a member of the
70-kDa heat shock protein family found in endoplasmic reticulum (66).
In addition, incubation of purified Hsc70 with
[-32P]ATP revealed that ATP is bound only to monomers
(62). Although both monomers and dimers have uncoating activity
in vitro (5), only the monomeric Hsc70 is associated with
(67), or binds strongly to, clathrin (68). When cells are under glucose
starvation, the oligomeric forms of BiP are converted to monomers,
presumably for binding the accumulated underglycosylated proteins (69). Both the oligomeric and monomeric forms of BiP can bind peptide substrates; however, the binding causes conversion of the oligomers to
monomers (70). In prokaryotes, the accessory protein GrpE has limited
capacity to bind the oligomeric DnaK (71). Taken together, these
observations strongly suggest that converting Hsc70 oligomers to active
monomers may regulate Hsc70 activity and that p16 plays a very
important role in this process.
If this is a viable regulatory mechanism in cells, then the oligomers must be stabilized or sequestered such that cytoplasmic ATP cannot immediately dissociate them. In fact, we see a lag in the stimulation of intrinsic ATPase activity in the presence of ATP that is eliminated by p16 (Fig. 4), suggesting that p16 may initially activate Hsc70 ATPase activity. To further support this model, DnaJ and GrpE modulate the oligomeric state of Hsc70/DnaK. Greene and colleagues showed that in the presence of ATP, Ydj1, a DnaJ homolog isolated from yeast, can induce oligomerization of bovine Hsc70 and yeast cytosolic Hsc70 homolog, Ssa1 (72). These data strongly suggest that besides regulating Hsc70 ATPase and substrate binding activities, accessory proteins also play a very important role in modulating the oligomeric states of Hsc70. By maintaining a monomeric pool of Hsc70, p16 may allow Poeciliopsis to adapt to rapid temperature fluctuations in the desert environment; these fish commonly experience substantial temperature extremes (4-40 °C) and can be exposed to a 22 °C temperature differential in the course of a single day (73, 74). It is possible that p16 may need to release Hsc70 from substrate to allow thermal inactivation of Hsc70 during cooling and to monomerize oligomers rapidly during heating to activate Hsc70.
p16 also helps dissociate Hsc70 from Pc but not from FYQLALT, suggesting that p16 may modulate specific Hsc70 chaperoning activities. What chaperoning functions of Hsc70 may involve accessory proteins like p16? For example, the Hsc70·clathrin complex has been reported to lock into a stable complex after release from a coated vesicle (58), and therefore, it is possible that accessory proteins like p16 help dissociate Hsc70 from clathrin to recycle both proteins. The efficient dissociation of the Hip·Hsc70-substrate complex may also require p16-like proteins rather than exchange of ADP for ATP (52). In yeast, Ssa2 (cytosolic Hsc70 homolog) and Ydj1 form a stable complex with denatured rhodanese to prevent aggregation (26); accessory proteins like p16 may then help release the denatured rhodanese from Ssa2 and Ydj1 for refolding or degradation. It is also possible that p16-like proteins can function as the cytosolic factors that dissociate Hsc70 from presecretory proteins (75) or mitochondrial precursor-Hsc70 complexes (10). Since the dissociation of Hsc70·Pc complex by p16 did not require exogenous ATP, it supports the idea that Hsc70 does not always require ATP for substrate release. For example, the refolding of heat-denatured topoisomerase I by purified Hsc70 in vitro does not require exogenous ATP (76), and the Hsc70-dependent pathway for mitochondrial import does not require exogenous ATP (77). Therefore, p16 may be a specific regulator for certain Hsc70 chaperone functions that require dissociation of stable Hsc70-substrate complexes at the right time or right place.
Although GrpE can monomerize DnaK (71), our data did not suggest that p16 is a GrpE homolog. First, p16 does not stimulate the nucleotide exchange of Hsc70 (data not shown). Second, GrpE by itself does not release substrate from DnaK without added nucleotides. Finally, unlike GrpE (78), p16 does not appear to form a stable complex with Hsc70 in our nondenaturing gel assay conditions. This transient interaction may explain why p16 was not identified before in Hsc70 complexes. When compared with eDnaJ, p16 appears to have opposite effects on Hsc70 functions. eDnaJ induces oligomerization of Hsc70, presents some substrates to Hsc70 or dissociates some substrates from Hsc70 in the presence of ATP, and stimulates Hsc70 ATPase activity. However, p16 monomerizes Hsc70, dissociates Hsc70 from certain substrates in the absence of ATP, and does not stimulate Hsc70 ATPase activity. Therefore, p16 appears to be a unique accessory protein that may counter the actions of eDnaJ on Hsc70.
p16 may mimic the effect of ATP by providing ATP to Hsc70 indirectly
through phosphate transfer. However, our preliminary data suggested no
direct phosphorylation of Hsc70-bound ADP by p16 using
[-32P]ATP (see "Results"). Also, p16 did not
stimulate Hsc70 ATPase activity, arguing against this mechanism. Since
the active site for phosphate transfer on all NDP kinases involves a
histidine residue (64), use of site-directed mutagenesis to replace the active site histidine residue on p16 may answer whether the action of
p16 on Hsc70 is through its NDP kinase activity. Interestingly, NDP
kinases have been implicated in Drosophila embryo
development (79, 80), binding to the promoter region of
c-myc oncogene (81), and inhibition of myeloid leukemic
cells differentiation (82). In human tumors, reductions in Nm23 gene
expression, another NDP kinase family member, have been associated with
increased metastatic potential of a variety of carcinomas (reviewed in
Ref. 83). However, none of these functions involve their NDP kinase activity. Recently, NDP kinase has been shown to function as a protein
kinase that phosphorylates a serine residue on histone 2b or casein
(84), and a histidine residue on ATP-citrate lyase (85). However, we
did not observe any protein phosphorylation of Hsc70 by p16 in
vitro (see "Results"). Therefore, the effect of p16 on Hsc70
is most likely based upon a protein-protein interaction resulting in a
conformational change in both Hsc70 and p16.
NDP kinase is generally considered to be one of the "housekeeping" enzymes necessary for maintaining the nucleotide pools of the cell. One of the remarkable features of this enzyme seems to be its association with proteins that require guanine nucleotides for their functions. These proteins include initiation factor eIF2 (86), and GTP binding (G) proteins (87, 88). The ability of NDP kinase to convert GDP to GTP has led to the proposal that NDP kinase plays a role in the activation of G proteins in signal transduction by directly or indirectly providing GTP (89-91). Interestingly, plant NDP kinases have been proposed as a part of the signal transduction pathway during stress (92). NDP kinase from cultured sugarcane cells exhibits heat shock-stimulated autophosphorylation activity (93), and in tomato plant, its mRNA level is up-regulated in response to wounding (94). Since one of the most common signal transduction events during heat shock is protein phosphorylation, the up-regulated NDP kinase activity and protein levels may allow the plant to perceive and transduce signals related to high temperature stress (92). Since the protein levels of p16 increased when PLHC-1 cells were exposed to cadmium ions, it is possible that p16, like the plant NDP kinases, may also play a role in signal transduction pathways during stress. Furthermore, the direct association between p16 and Hsc70, combined with similar dose-dependent increases in both p16 and Hsc70/Hsp70 levels in response to cadmium ions reported here, demonstrate for the first time a direct link between NDP kinase and the stress response in animal cells.
The relationship between NDP kinase and the stress response is further demonstrated by the identification of NDP kinase as a plant flavonoid cromoglycate binding protein (95). Cromoglycate is a widely used antiasthmatic drug that is structurally related to quercetin, a potent NDP kinase inhibitor in vitro (IC50 is 28.6 mM; see Ref. 96). More importantly, quercetin down-regulates the heat shock response in human HeLa cells by reducing both HSF1 phosphorylation and protein levels. As a result, HSF1-heat shock element complex declines (97).
The discovery of p16 as a new cytoplasmic accessory protein for Hsc70
supports the hypothesis that a variety of accessory proteins (eDnaJ,
auxilin, Hip, and p16/Nm23/NDP kinase) are required to support the
diverse chaperoning functions of Hsc70. These diverse accessory
protein-chaperone interactions may allow the cells to regulate
different chaperoning functions of Hsc70 more efficiently by
controlling the individual accessory proteins. Roles for p16 in the
Hsc70 reaction cycle are proposed in Fig. 11. In this
model, Hsc70 initiates interaction with substrates in its ATP-bound
state, which has a high on rate for substrate. In contrast, the
ADP-bound Hsc70 has a low on rate for substrate and, therefore, plays a less important role in initiation of substrate binding. After binding
to a substrate, the ATP-bound Hsc70 undergoes a conformational change.
Since the ATP-bound Hsc70 is characterized by rapid substrate association and dissociation kinetics, a stable Hsc70-substrate complex
will form only after ATP hydrolysis. After nucleotide exchange, Hsc70
returns to its ATP-bound form, and the substrate is subsequently
released. Accessory proteins modulate different steps in the reaction
cycle. DnaJ-like protein modulates the binding of substrates as well as
stimulates ATP hydrolysis, while Hip stabilizes the
Hsc70·ADP-substrate complex. Since ATP/ADP exchange is slow and no
GrpE homologs have been found in the cytoplasm, some substrates would
be released very slowly without help from accessory proteins. However,
in the presence of p16, substrate can also be released from
Hsc70·ADP, and the subsequent ATP/ADP exchange then converts Hsc70 to
the form most accessible for substrate binding. p16 also monomerizes
Hsc70 oligomers and may counter the actions of Ydj1 on Hsc70.
We benefited from the use of the Cell Culture Facility of the University of Connecticut Biotechnology Center.