(Received for publication, September 20, 1996, and in revised form, January 3, 1997)
From the Department of Biochemistry, The Ohio State University, Columbus, Ohio 43210-1292
Deoxyadenosine kinase (dAK) forms a heterodimer with either deoxyguanosine kinase (dGK) or deoxycytidine kinase (dCK), and is heterotropically activated 3-5 times by dGuo or dCyd. Expressed alone, dAK is inactive and exhibits no response to dGuo or dCyd; activity and heterotropic response are fully restored upon reassociation with dGK or dCK. However, turnover of independently expressed dGK or dCK is nearly maximal, being further activated only 50-100% upon reassociation with dAK. In neither case is the heterotropic activation due to ligand-induced heterodimer formation.
A proline/alanine substitution within a dAK segment homologous to loop G2 of Ras proteins yielded a heterodimer with dAK permanently cis-activated 2-fold, with a corresponding reduction in heterotropic activation by dGuo. A chimeric dAK, with 25% of its C terminus substituted by the homologous sequence from dGK, was inactive alone, and its characteristics were unchanged in the reconstituted heterodimer. Superimposing the Pro/Ala substitution on this chimera also reduced heterotropic activation by half. Cross-linking the dimer by 1,5-difluoro-2,4-dinitrobenzene was inhibited by ATP, dATP, dGTP, and dAdo, suggesting the proximity of the active site(s) to the interface. These data suggest that dAK depends on dGK or dCK in a manner resembling the reliance of Ras upon GTPase activating protein.
Subunit interaction is the basis for a wide spectrum of regulatory mechanisms controlling and coordinating chemical events in vivo (1, 2), and the stereochemical nature of these allosteric interactions in several protein systems has been elucidated in great detail over the past 60 years (3). Lactobacillus acidophilus R-26, lacking the ribonucleotide reductase of the deoxynucleotide de novo pathway, possesses all four deoxynucleoside kinases by which it generates building blocks of DNA through salvage pathways (4). While thymidine kinase is readily separated from the other three kinase activities (4), dAdo kinase (dAK)1 exists as a heterodimer with either dGuo kinase (dGK) or dCyd kinase (dCK) subunit (5-8). The turnover at the dAK active site of either heterodimer is only one-seventh to one-tenth of that of dGK or dCK, but is heterotropically activated 3-5-fold to its full activity potential by dGuo or dCyd, respectively, in contrast with the minimal effect (20%, at most) of dAdo on dGK or dCK, which are almost fully active (7, 9). Therefore, the combined output of these two heterotropically-regulated dimers provides the nearly equal quantities of dAMP, dCMP, and dGMP needed for DNA precursor synthesis (7). While dGK and dCK are kinetically and structurally parallel in a relaxed conformation2 (6, 7, 10), dAK is in a constrained conformational state which is relaxed only through subunit-subunit interaction in the presence of heterotropic activators. The constrained state of dAK has been inferred from experiments involving chemical modification (5), limited proteolysis, activation by chaotropic salts, and affinity labeling (10). The largely unidirectional heterotropic activation of dAK by dGuo or dCyd has not been correlated in detail with the unique conformational states of dAK, and a detailed structural mechanism of this heterotropic activation is yet to be described.
The tandem dak/dgk structural genes of L. acidophilus R-26 have been cloned; the DNA insert consists of a common endogenous promoter, the dak gene preceded by its Shine-Dalgarno sequence, a 21-base pair spacer containing the Shine-Dalgarno sequence for dGK expression, the dgk gene, and a transcription termination loop (11). The derived amino acid sequences of dAK and dGK are more than 60% identical. The remaining sequence divergences must therefore account for any differences in conformation and specificity of the two polypeptides. The sequences of dGK and dCK, on the other hand, are identical except at their extreme N termini, and these polypeptides are now believed to be alternative processing products of the dgk gene (12). Hereafter, as a first approximation, the conformations of dGK and dCK will be considered to be essentially identical within their respective heterodimers.
To examine the largely unidirectional interactions leading to optimal conformations for both subunits of a heterodimer, unmodified dAK and dGK (or dCK) were expressed separately in vivo, enabling us to study the impact of heterodimer reconstitution in vitro on the catalytic competence of these two subunits. Short-range chemical cross-linking was carried out to explore further the interface of the dAK/dGK heterodimer.
dAK and dGK each contain a segment homologous in varying degrees to the G2 loop of p21ras protein, which, in Ras, is responsible for GTP binding and interaction with GTPase activating protein (GAP) (13). The proline residue within this loop is of particular interest, since it is believed to stiffen the loop (14). Knowing that dAK is in a constrained state, a site-directed proline/alanine substitution was made within this loop in an attempt to relax its conformation.
An obvious structural difference between dGK and dAK, and a possible basis for their differing behaviors, is the extra nine amino acid residues at the C terminus of dGK. Therefore, a chimeric dAK was constructed and expressed independently, in which nearly 25% of its C terminus was replaced by the homologous sequence from dGK, either with or without the additional proline/alanine substitution.
One unit of kinase activity is defined as 1 nmol of deoxynucleoside 5-monophosphate formed per minute, assayed in
20 µM deoxynucleoside (Sigma) and 10 mM ATP
(Sigma)-Mg2+ at 20 °C; [3H]dAdo,
[3H]dGuo, or [3H]dCyd (Moravek
Biochemicals) was included to allow the product detection using the
anion exchange disk method (15). Specific activity is expressed as
units per mg of protein. Substrate concentrations were varied for
steady-state kinetics analysis as indicated in each case, but each
reaction mixture contained a constant amount of the radioactive
deoxynucleoside.
As shown in
Fig. 1, the phagemid pBlueScript(+) KS (Stratagene)
construct (11) containing the cloned tandem dak/dgk genes was cleaved at two StyI restriction sites with endonuclease
from Life Technologies Inc., and the residual phagemid was religated following isolation and purification on Qiagen columns.
Independent Subcloning of the dak, dgk, and dck Genes
Plasmids with the separated dgk or engineered
dck genes have recently been prepared and the kinetic
properties of their products described (12). Construction of a
dak clone was achieved by deleting the dgk gene
from the original pBlueScript clone containing the tandem
dak/dgk genes. This mutagenesis was carried out with the
Muta-Gene® phagemid in vitro mutagenesis kit
(version 2) from Bio-Rad, and the primer was synthesized at the Ohio
State University Biotechnology Center. The primer, with its 5 terminus
complementary to the DNA sequence immediately downstream from
dgk's stop codon and its 3
terminus complementary to the
DNA sequence between dak's stop codon and dgk's
Shine-Dalgarno sequence, was annealed to the single-stranded
dak/dgk template. Upon obtaining the putative mutant
colonies, the desired deletion was confirmed by sequencing the plasmid
by the dideoxy method, using the Sequenase version II kit from U. S. Biochemical Corp. The independently subcloned dGK, dCK, and dAK
proteins were expressed in Escherichia coli XL1-Blue strain
(Stratagene) grown overnight in LB medium (components from Difco)
containing ampicillin (100 µg/ml). Ammonium sulfate fractions (70%
saturation) were prepared from all cell extracts. Further purification
of specific preparations was carried out as described.
In general, materials and methods for the mutagenesis were the same as described above. However, in order to specifically mutagenize the dak gene without altering the homologous sequence in dgk, the independent chimeric dak gene served as the template. Upon obtaining the desired mutants, a mutant dak/dgk construct was assembled by resplicing the StyI fragment from normal dak/dgk into the StyI site of the mutant chimeric dak construct (i.e. the tandem gene sequence is restored, except for the mutation within dak, reversing the steps shown in Fig. 1). DNA sequencing and assays for the dGK activity were carried out to identify colonies with the StyI insert.
Estimation of the Approximate Dissociation Constant (Kd) of dAK/dCKThe inactive dAK was partially purified as an ammonium sulfate fraction (~70% saturation), while dCK was further purified by gel filtration chromatography. The latter involves applying a dCK ammonium sulfate fraction (50 mg total protein in 8 ml) to a Sephacryl S-200 HR (Pharmacia) gel permeation column (2.5 cm × 148 cm, 726-ml volume) equilibrated with elution buffer containing 15 mM potassium phosphate (pH 8.0) and 5% glycerol. About 75% of the dCK activity was recovered with the dCK protein peak (about 80% pure, as estimated from SDS-PAGE), with a protein concentration of about 0.08 mg/ml, as determined by the Bradford method (16) using dye reagent from Bio-Rad. The molar concentration of dCK was then calculated from its subunit molecular weight. Various amounts of dCK were mixed with a fixed amount of dAK, incubated on ice for 10 min, and then diluted and incubated at 20 °C for further 5 min. Aliquots (10 µl each) were then taken from each diluted mixture for assay (at 20 °C) of the dAK activity (total assay volume of 40 µl) in the presence of 400 µM dCyd, which both activated the dAK subunit and blocked the secondary dAK activity of the heterodimeric dCK protein. The progress of the dAK and dCK heterodimerization was monitored by this measurement of the dAK activity, since the total catalytic turnover of dAdo within the 30-min assay period is linearly correlated with the amount of heterodimeric dAK/dCK in equilibrium. The data were then fitted to Equation 1, which assumes that dCK used during titration existed as monomers before associating with dAK,
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(Eq. 1) |
Alternatively, the data were fitted into Equation 2, which assumes that dCK may also exist as homodimers before the heterodimer reconstitution,
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(Eq. 2) |
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All three polypeptides were partially purified as ammonium sulfate fractions. Various amounts of dGK or dCK were incubated on ice for 10 min with a fixed amount of dAK, diluted and assayed for the dAK activity in the presence or absence of dGuo or dCyd (400 µM), respectively. Both dGK and dCK active sites have secondary dAK activities (but with much larger Km values for dAdo than for the homologous deoxynucleosides), regardless of whether the dGK or dCK is expressed independently of dAK (12), or is in the form of heterodimer.3 Therefore, these secondary dAK activities should be blocked by saturating dGK and dCK with their more tightly binding primary deoxynucleoside substrates. When the dAK activity was to be assayed without dGuo or dCyd, a control was included in which the secondary dAK activity of free dGK or dCK was assayed. Hence, the dAK activity due solely to dAK in the heterodimer was calculated by subtracting the secondary dAK activity of either the dGK or dCK protein from the total dAK activities of the heterodimer.
Chemical Cross-linkingHeterodimeric dAK/dGK protein was expressed and extracted as described for independent dAK, dGK, or dCK peptides. An ammonium sulfate fraction containing 169 mg of total protein was loaded onto the gel permeation column (as described above), and 5 × 15-ml fractions containing at least 80% of the dAK/dGK activities were collected. Those active fractions were then pooled and further purified on a blue-Sepharose column (2.5 cm × 2.5 cm), as described previously (5), with modifications. Aliquots of dAK/dGK active fractions (in 15 mM potassium phosphate, 5% glycerol, pH 8.0) were adjusted to pH 6.6 by mixing 10 volumes of enzyme fraction with 0.7 volumes of 150 mM monopotassium phosphate, 5% glycerol (pH 2.6). The pH-adjusted fractions were further diluted 2-fold with washing buffer 1 (15 mM potassium phosphate, 5% glycerol, pH 6.6) before application to the blue-Sepharose column at a flow rate of 2 ml/min. At a flow rate of 2.5 ml/min, the column was washed with 90 ml of washing buffer 1, then 250 ml of washing buffer 2 (15 mM potassium phosphate, 15 mM AMP, 5% glycerol, pH 8.0), and 150 ml of washing buffer 3 (15 mM potassium phosphate, 5% glycerol, pH 8.0). The dAK/dGK protein was finally eluted with 100 ml of elution buffer (15 mM potassium phosphate, 10 mM ATP, 5% glycerol, pH 8.0), and the first eight 10-ml fractions were pooled and concentrated to ~1 ml with CentriPlus ultrafiltration units from Amicon, resulting in dAK/dGK protein (80% pure, as estimated from SDS-PAGE) at a concentration of ~1 mg/ml.
The cross-linker stock solution (1,5-difluoro-2,4-dinitrobenzene (DFDNB) (from Pierce) in acetone) was freshly prepared before each use. Each reaction, in a total volume of 100 µl (pH 8.0), contained 15 mM potassium phosphate (or 45 mM potassium phosphate, to maintain pH when dGTP or dATP was introduced), 10% glycerol, 0.1 mg/ml dAK/dGK, and 0.05 mM DFDNB (added last). Whenever the reactions were carried out in parallel, the reaction mixtures contained identical concentrations of potassium phosphate. The reactions were allowed to proceed for 1 h at room temperature (22.5 °C), and were quenched with 50 mM (final concentration) Tris-HCl (pH 8.0). When necessary, the reaction mixtures were passed through Bio-Spin 6 columns (Bio-Rad) to remove possible remaining DFDNB and other salts. Finally, 35 µl of the reaction mixture was analyzed by SDS-PAGE (12% gel), using the Laemmli buffer system (17). The gels were stained with Brilliant Blue R (Sigma) and dried, and the protein bands were quantified by SigmaGelTM densitometry software (Jandel).
With the primer 5-CCA TAT TGG ACC GCA GTT TTG CT_C GTT AAC
TAG TTT AAA TTC CCT-3
, the dgk structural gene was
completely looped out from the original (11) DNA construct employing
the Muta-Gene® phagemid in vitro mutagenesis
kit from Bio-Rad. DNA sequencing confirmed that the dgk gene
was deleted, leaving only the dak structural gene
immediately followed by the transcription terminator of the original
tandem genes. Consequently, the dak gene in this construct
should be transcribed and translated just as it is in the tandem
dak/dgk genes, but without the dgk gene product.
The dAK protein thus expressed was enzymatically inactive until the heterodimeric enzyme form was reconstituted in vitro with
independently expressed dGK or dCK peptides (expressed in E. coli as a heterodimer in vivo, the specific dAK
activity in a comparable ammonium sulfate fraction is usually ~3
units/mg).
The dAK activity of reconstituted dAK/dGK or dAK/dCK heterodimer could be further activated 3-5-fold heterotropically by dGuo or dCyd, respectively (Table I), just as has been observed with the wild type enzymes (7, 9). It should be noted that either dGK or dCK, expressed separately from dAK, has a secondary dAK activity, but the Km(dAdo) is 1-2 orders of magnitude higher than that for the respective primary deoxynucleoside substrate, dGuo or dCyd (12). In the heterodimeric form, dGK or dCK's Km(dAdo) is also estimated to be at least 1,000 µM,3 while the Km for the primary deoxynucleoside is less than 10 µM (12). Therefore, the secondary dAK activity of either heterodimeric dGK or dCK is easily blocked by saturating (e.g. 400 µM) dGuo or dCyd, respectively. In the absence of the heterotropic activator, the secondary dAK activity of free dGK or dCK was determined and subtracted from total dAK activities of the heterodimer obtained from reconstitution. This yields the dAK activity solely from the dAK subunit in the heterodimer before heterotropic activation. Furthermore, for the free dGK or dCK protein, the secondary dAK activity amounts, at most, to 2-7% of the primary dGK or dCK activity when assayed with only 20 µM dAdo (12). Therefore, when the heterotropic activation is observed in wild type enzymes (where dGK or dCK is nearly in equal stoichiometry amount of dAK), this trivial secondary dAK activity of dGK or dCK can be ignored even if it is not blocked. The fact that the calculated heterotropic activation factor (Table I) is the same as that observed in the wild type heterodimers further validates the calculation shown.
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The subcloned independently expressed dGK (data
not shown) or dCK (Fig. 2, A and
B) was already almost fully active, being activated only an
additional 50-100% upon heterodimer reconstitution in
vitro. This activation is purely a Vmax
effect with no significant changes in the Km for
either the deoxynucleoside substrate or for ATP-Mg2+. This
relatively modest dependence of the dGK or dCK activity upon the dAK
subunit is paralleled by the small heterotropic activation (5-20%) of
dGK (Fig. 2, C and D) or dCK (data not shown) in
the heterodimer by dAdo. The heterotropic activation is also a
Vmax effect with no changes of
Km values for either the deoxynucleoside substrate
(7, 9) or ATP-Mg2+, within experimental error (Fig. 2,
C and D). These experimental results can also be
predicted theoretically: since dGuo binding to dGK does not change the
affinity of dAK for dAdo in the presence of saturating ATP (7),
according to the linked-function analysis (1) (Fig. 3),
dAdo binding to dAK should not change dGK's affinity for dGuo, either.
In this analysis, the assumption was made that if Km
is not changed during heterotropic activation, neither is
Kd, and vice versa.
Heterotropic Activation Is Not Caused by Induced Heterodimer Formation
With the finding that dAK expressed without dGK is
enzymatically inactive until the heterodimer is formed, a question
which naturally arises is: does the deoxynucleoside substrate
strengthen the inter-subunit affinity of the heterodimer, hence driving
the equilibrium further toward heterodimer formation and activating dAK
and dGK? The independent cloning of dAK, dGK, and dCK provided the
means to answer this question. During the in vitro
heterodimer reconstitution, the amount of the dAK protein was fixed
while the dGK or dCK amounts were varied so that, in effect, dAK was being titrated by the formation of heterodimer. However, the extent of
heterotropic activation of dAK by dGuo or dCyd was unaltered regardless
of the progress of titration (Fig. 4), leading to the conclusion that heterotropic activation is not due to the formation of
additional heterodimeric dAK. Therefore, we may exclude the possibility
of a ligand-induced change of the heterodimer association constant as
the mechanism of the heterotropic activation. In fact, it is clear from
Fig. 4 that dGK (or dCK) had the same affinity for dAK both in the
presence and absence of dGuo (or dCyd). Therefore, heterotropic
activation must be due to a conformational fine tuning of structural
element(s) affecting catalytic turnover mediated through the interface
of any existing heterodimeric molecules.
Estimation of the Heterodimer Equilibrium Dissociation Constant
The dissociation constant of dAK/dCK was estimated,
based on the following observations: (i) dAK is inactive by itself
(Table I), (ii) the secondary dAK activity of heterodimeric dCK should be completely blocked by saturating dCyd (as discussed earlier), and
(iii) the affinity between dAK and dGK (or dCK) is unaltered by dGuo
(or dCyd) (Fig. 4). Furthermore, since dAK is active only in the
heterodimeric form, the equilibrium concentration of dAK/dCK should be
directly proportional to the amount of dAdo converted to dAMP during
the 30-min assay period. Therefore, the heterodimer formation was
monitored directly by measuring the dAK activity of the "revived"
and heterotropically activated dAK subunit. The data obtained (Fig.
5) were then fitted into Equation 1, yielding a
Kd of 4 × 108 M. An
identical Kd value was also obtained through
Equation 2, when an assumption was made that the dCK proteins used for the titration were in the homodimeric form before associating with dAK.
Since the heterodimer formation was monitored by measuring the dAK
activity from the dAK subunit in the heterodimer, the Kd value should be regarded as having been obtained
under current assay conditions: 100 mM Tris-HCl, 5%
glycerol at 20 °C. The actual Kd value under the
host's physiological conditions (37 °C) is expected to be somewhat
different, especially since it has been observed that salt
(e.g. NaCl) can affect the association between dAK and dGK
(data not shown). However, that estimated Kd should
be reasonably close to the true value in vivo, because it
has been determined that nearly 100% of the dCK molecules used for the
titration are active.4 In the chemical
cross-linking reactions (described in a later section), where both dAK
and dGK were present at concentrations of about 2 × 10
6 M, nearly 100% of dAK and dGK should be
in the heterodimeric form according to the magnitude of this
Kd.
The Structural Elements Distinguishing dAK from dGK Must be Located between Residues 19 and 171
Since the longer dGK protein has nine additional amino acid residues at the very C terminus that have no counterparts in the highly homologous dAK protein, the different behaviors of these two proteins might be explained in terms of this structural difference. Therefore, a chimeric dAK was constructed, containing residues 1-171 of dAK and residues 172-224 from dGK. However, this replacement of over 20% of the dAK polypeptide apparently did not change the unique conformational state of dAK. The chimeric dAK was still inactive until reconstituted into the heterodimer, and the extent of heterotropic activation of this revived chimera remained essentially the same as in the native heterodimer (data not shown). Apart from the first three amino acid residues at the very N terminus which distinguish the specificities of dGK and dCK (12), wild type dAK and dGK share an identical N-terminal amino acid sequence up to residue 18 (11). Therefore, the unique structural determinants of dAK which differentiate its properties from those of dCK and dGK must reside between residues 19 and 171.
The Effect of Site-directed Substitution, P155A or S156T, on dAK of Heterodimeric dAK/dGKResidues Pro-155 and Ser-156, just upstream
from residue 171, fall within a sequence which is homologous with the
G2 loop of Ras (13), but which is heretofore unknown in any of the
deoxynucleoside kinases. To assess the importance of this motif (the
sequence comparisons are discussed in detail under "Discussion"),
the mutagenesis of two likely functional residues was carried out using
the primers 5-CTTTTAAACTTG
ATCGGTTG-3 and
5
-GTAATCTTTTAAA
TTGGATCGGTTG-3
to produce mutant strains
expressing dAK(P155A) and dAK(S156T), respectively. Upon confirming the
desired mutagenesis by DNA sequencing, the unaltered dAK/dGK strain,
the dAK(P155A)/dGK strain, and the dAK(S156T)/dGK strain were cultured
and harvested in parallel, the kinases were partially purified through
ammonium sulfate precipitation, and dAK and dGK activities analyzed
under the assay conditions indicated under "Experimental
Procedures." The dGK activities from all three strains appeared to be
the same (~30 units/mg), whereas the dAK activity of dAK(P155A)/dGK
was elevated 2-3-fold compared either with the wild type or with
dAK(S156T)/dGK. Table II shows the effects of
mutagenesis on heterotropic activation. For dAK(P155A)/dGK, the dAK
activity was permanently activated 2-fold, with the heterotropic
activation effect of dGuo accordingly reduced 2-fold. In other words,
both the wild type and the mutant dAK activities had the same maximal
turnover potential when heterotropically activated, while there was
only a 10% difference in the Km(dAdo) between wild
type and dAK(P155A) (Table III). Interestingly, the above chimeric dAK, with the additional P155A mutation superimposed, was still inactive unless in the heterodimeric form. Upon
reconstitution, its heterotropic activation factor was also reduced
~2-fold (data not shown), in parallel with the previous example.
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In an attempt to identify
interfacial domains, DFDNB, with an arm-length of 3 Å, was used to
cross-link dAK and dGK subunits in the normal heterodimer. The
experimental conditions were such that the activities of dAK and dGK
remained stable for 2 h in the absence of cross-linker (Fig.
6), but upon the addition of DFDNB (0.05 mM), dGK lost its activity more quickly than dAK did; within 1 h, more than 80% of the dGK activity was lost while only 50% was lost from dAK. This difference between dAK and dGK parallels their relative rates of inactivation by rose bengal-induced
photooxidation (5), or trypsin proteolysis, and is also reflected in
the opposite responses of their activities to dilute chaotropic salts
(10). DFDNB is a bifunctional reagent with a preference for amino and phenolic groups but is also capable of reacting with sulfhydryls (not
present in either dAK or dGK) and imidazole groups (18). Therefore, it
can be envisioned that dAK and dGK differ in their conformations in
such a way that critical reactive groups are exposed to different
extent. Although the fluoro groups of DFDNB are symmetrically situated,
their reactivities are not the same; therefore, DFDNB is expected to be
both a monofunctional and bifunctional reagent (18, 19). This explains
why the cross-linking efficiency (20%) was considerably less than the
maximal loss of activity (>80% for dGK). Most of DFDNB reacted with
the protein only once, thus inactivating the activity without
cross-linking the heterodimer. Unfortunately, other reagents which were
tried gave even lower cross-linking efficiencies.
Cross-linking by DFDNB is inhibited by substrates such as ATP and dAdo, and by two end-product inhibitors, dATP and dGTP (Table IV). dATP and dGTP are each postulated to bind to the homologous deoxynucleoside-binding site, with the triphosphate group overlapping ATP's triphosphate site (20). However, dGuo, in contrast with dAdo, had no effect on the cross-linking efficiency (Table IV). But, the comparable behavior of dGuo and dGTP in the heterotropic activation of dAK indicates that dGuo and dGTP induce similar conformational changes. Thus, the inability of dGuo to inhibit the cross-linking strongly suggests that the inhibition is due to the direct steric shielding of the cross-linking sites rather than being due to an indirect positional switching caused by a conformational change. Therefore, the triphosphate-binding site, hence the dGuo site, of dGK should be close to the interface. The effect of dAdo on cross-linking also suggests that the dAdo site of dAK, and hence its ATP site as well, is in close proximity to the interface. It should be noted that, since both subunits have an ATP site, it is not clear if the effect of ATP on cross-linking is a function of both active sites or if it is mediated through a single subunit.
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In order to discern the role of dGK in affecting the
conformation and activity of dAK, the dAK and dGK polypeptides were
independently expressed. The fact that dAK, by itself, has no
discernable dAK activity therefore parallels the situation with Ras of
the GTPase superfamily. In the interaction between Ras proteins and
GAP, GAP directly activates GTPase activity of Ras ~100,000-fold
(21-23), possibly by supplying one or more critical positive charges
important for efficient catalysis (24-26). Furthermore, in G proteins
of the GTPase superfamily, when both the G GTP-binding core domain (R-2) and a GAP-like G
insert domain (G-2) are separately expressed as recombinant proteins, G-2 stimulates the GTPase activity of R-2
under conditions where neither alone hydrolyzes GTP (23). In another
GTPase family, which includes proteins involved in protein
translocation across membranes, a G2 loop-containing FtsY again has no
measurable GTPase activity alone unless combined with Ffh-4.5S
ribonucleoprotein (27).
Analysis of the amino acid sequences derived from the tandem
dak/dgk genes reveals that dAK and dGK both contain a
segment (residues 153-161 at site iv) which is homologous,
to varying degrees, with the G2 sequence of Ras proteins (Fig.
7) of the GTPase superfamily (11). While within each
GTPase family the amino acid sequence corresponding to the G2 region is
highly conserved, some of the residues vary between families of the
superfamily. But an invariant element in all the GTPase families is a
threonine residue within each putative G2 sequence (13, 28). It is
interesting to note that this site iv of dAK, with its
G2-like sequence, is only 6 residues away from the arginine-rich
site iii (residues 140-146). While absent from Ras, this
arginine-rich region is highly conserved among all the other
deoxynucleoside kinases sequenced so far, as well as in other kinases
such as porcine adenylate kinase (pAK) (29, 30). Since the Arg-138
residue of pAK (or, the Arg-156 of E. coli adenylate kinase)
was shown to interact with the transferred phosphoryl group at the
transition state (31, 32), it is reasonable to assume that an arginine
residue in site iii of dAK or dGK has a similar function
(11). In equivalent manner, this stabilizing function is also carried
out by an arginine residue within the G2 sequence among the
-subunits (e.g.
s (33)) of G proteins (13, 28, 34,
35). However, this catalytically important Arg is missing from the
corresponding G2 sequence of Ras (13, 28, 36), and is thought to be
provided to Ras in trans by Arg-903 of its GAP (25). While
required for activity, this Arg is not necessary for the association of
GAP with Ras (26). The association with GAP, and the binding of
GTP-Mg2+, as well, is a function of the Ras G2 sequence
(13, 37). In G1, the N-terminal Ras sequence resembles the conserved
P-loop of many nucleotide-binding proteins and recent model studies on Ras-catalyzed hydrolysis of GTP suggest that Gly-13 and Lys-16 also
contribute significantly to transition state stabilization. Again, this
GTPase superfamily's G1 sequence is also conserved in dAK and dGK as
site i (see Fig. 7).
The interaction between dAK and dGK (or dCK) subunits is viewed as occurring in two stages. The first stage occurs immediately after protein synthesis as the subunits associate into heterodimers, each subunit reciprocally affecting the other's catalytic efficiency, but to greatly different extents. Reflecting in their contrasting conformations (10), dGK (or dCK) turnover is elevated 1.5-2-fold, while that of dAK is raised from practically 0 to about one-seventh of its partner's activity. In a second fine-tuning stage, dAK is brought into its fully active conformation heterotropically: the binding of dGuo (or dCyd) at the dGK (or dCK) active site presumably causes a conformational change which is transmitted to the neighboring dAK subunit. This is an example of the unusual V-type activation, the Km values for substrates of dAK being unchanged (7, 9). In the opposite direction, dAdo produces only a very minor (5-20%) affect on the turnover of its partner. It is also important to note that the heterotropic activation is not caused by additional heterodimer formation.
Efforts were therefore initiated to probe the structural elements determining the contrasting conformations and activities of dAK and dGK, which occur despite highly homologous primary structures overall. Upon substituting about 25% of dAK's C terminus with dGK's homologous sequence, the character of dAK remains unchanged. The chimeric dAK is still inactive until re-associated with dGK, and subsequent heterotropic activation is of normal magnitude. This result clearly indicates that elements contributing to dAK's unique conformational properties (i.e. dAK's total dependence on dGK for its activity and the large heterotropic activation of dAK by dGuo or dGTP), as well as its specificity, are further upstream.
Just several residues upstream of the site selected for chimeric replacement, dAK has a Ras G2-like loop, but which differs slightly from that of dGK. Within this loop, among other differences, dAK has a serine residue while dGK has a threonine at position 156. However, the lack of an effect of the S156T mutation on dAK indicates that this particular amino acid replacement is not sufficient to convert dAK to dGK in any apparent way. However, since the conformation of the equivalent Ras loop changes during Ras-GAP interaction, alteration of its conformation in dAK may be expected to affect subunit interaction and substrate turnover if dAK-dGK interaction parallels that of Ras-GAP. Accordingly, a P155A substitution on dAK of the dAK/dGK heterodimer resulted in a dAK, permanently cis-activated half-way toward its maximal turnover potential, correspondingly reducing the heterotropic activation effect of dGuo. Presumably, this mutation increases loop flexibility, altering dAK's interaction with dGK in a way that partially mimics the impact on dAK when dGuo binds to dGK. This effect of the mutation on dAK is not surprising in the light of mutagenic studies on other allosteric proteins such as dimeric glutathione reductase from E. coli (38) and tetrameric pyruvate kinase of yeast (39), where point mutations of subunit interface regions are capable of altering protein conformation, intersubunit communication, and hence, allosteric behavior and catalysis. Nevertheless, the chimeric dAK, even with the addition of the proline/alanine mutation, is still inactive by itself, indicating that the alteration of the loop conformation in this way only partially mimics the process occurring during the second stage of subunit-subunit interaction.
Chemical cross-linking with a 3-Å linker offers an opportunity to study the interface of the heterodimeric dAK/dGK. By analogy with Ras-GAP, the dGK subunit contacts the dAK subunit at dAK's active site which catalyzes the transfer of the phosphoryl group. This is evidenced by the fact that ATP, dATP, and dAdo all partially block the cross-linking reaction. Therefore, it is likely that both elements of dAK's active site are at the interface. dGTP can also reduce the cross-linking efficiency, suggesting that the ATP triphosphate-binding site of dGK, which dGTP is believed to partially overlap, is also close to the interface, and opposite the dAdo site. It is unfortunate that extensive apparently random monovalent addition of this reagent makes peptide mapping analysis impractical. The cross-linking event, on the other hand, is specific and useful, even if it does not afford analysis of the specific residues involved.
In conclusion, all the data up to this point are consistent with the hypothesis that dGK acts, in some way, like a "GAP" for dAK. It is obvious that the exact functional mechanisms in which the G2-sequence participates are different between dAK (as a kinase) and Ras (as a GTPase), reflecting nature's versatility in utilizing a similar structural element in different three-dimensional environments. While the heterotropic activation of dAK Vmax does not fall into the category of complex signal transduction in the conventional sense, but it does reflect the ability of protein/enzyme to regulate the downstream events in response to substrate conditions, as seen in many other systems (2). Finally, it is worth noticing that the Ras G2-like sequence conserved in the heterodimeric dAK/dGK and dAK/dCK expands the repertoire of this loop's functions to prokaryotes, and may provide a useful model for further study. In a parallel case, many of the energetic and conformational features required for chemomechanical energy transducing assemblies have also been observed in the less-complex allosteric enzymes, leading to the suggestion that structural and energetic data obtained by study of allosteric proteins can help to understand the more complicated mechanisms occurring in such eukaryotic macromolecular assemblies (40).
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U01881[GenBank].