©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Novel Multiubiquitin Chain Linkages Catalyzed by the Conjugating Enzymes E2 and RAD6 Are Recognized by 26 S Proteasome Subunit 5 (*)

(Received for publication, September 25, 1995; and in revised form, November 20, 1995)

Olga V. Baboshina Arthur L. Haas (§)

From the Department of Biochemistry of the Medical College of Wisconsin, Milwaukee, Wisconsin 53226

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

Targeting of substrates for degradation by the ATP, ubiquitin-dependent pathway requires formation of multiubiquitin chains in which the 8.6-kDa polypeptide is linked by isopeptide bonds between carboxyl termini and Lys-48 residues of successive monomers. Binding of Lys-48-linked chains by subunit 5 of the 26 S proteasome regulatory complex commits the attached target protein to degradation with concomitant release of free ubiquitin monomers following disassembly of the chains. Point mutants of ubiquitin (Lys Arg) were used to map the linkage specificity for ubiquitin-conjugating enzymes previously demonstrated to form novel multiubiquitin chains not attached through Lys-48. Recombinant human E2 catalyzed multiubiquitin chain formation exclusively through Lys-11 of ubiquitin while recombinant yeast RAD6 formed chains linked only through Lys-6. Multiubiquitin chains linked through Lys-6, Lys-11, or Lys-48 each bound to subunit 5 of partially purified human 26 S proteasome with comparable affinities. Since chains bearing different linkages are expected to pack into distinct structures, competition between Lys-11 and Lys-48 chains for binding to subunit 5 demonstrates that the latter possesses determinants for recognizing alternatively linked chains and precludes the existence of subunit 5 isoforms recognizing distinct structures. In addition, competition studies provided an estimate of K leq 18 nM for the intrinsic binding of Lys-48-linked chains of linkage number n > 4. This result suggests that the principal mechanistic advantage of multiubiquitin chain formation is to enhance the affinity of the associated substrate for the 26 S complex relative to that of unconjugated target protein. Complementation studies with E1/E2-depleted rabbit reticulocyte extract demonstrated RAD6 supported isopeptide ligase-dependent degradation only through Lys-48-linked chains, while E2 retained the ability to target a model radiolabeled substrate through Lys-11-linked chains. Therefore, the linkage specificity exhibited by these E2 isozymes depends on their catalytic context with respect to isopeptide ligase.


INTRODUCTION

ATP-dependent conjugation of ubiquitin to protein targets is currently recognized to mediate a variety of cellular processes by signaling selective degradation of the latter through the 26 S proteasome pathway, reviewed most recently in (1) and (2) . Among the cellular targets serving as substrates for this unique post-translational modification are various proteins exhibiting either constitutive or conditional short half-lives including cyclins(3, 4, 5, 6, 7, 8) , various oncoproteins(9, 10, 11, 12) , p53(13, 14, 15) , transcriptional factors (16, 17, 18) , and proteins of abnormal structure(19, 20, 21) . In all cases, the signal for ubiquitination probably requires transient exposure of one or more lysines that can serve as sites for recognition and attachment of the polypeptide. For certain targets, enhanced steric accessibility of sensitive lysines arising by minute conformational changes (22, 23, 24) or more global folding transitions (21, 25) may be accompanied by unmasking of specific amino-terminal residues that dispose the protein to recognition by relevant isopeptide ligases (E3) that confer specificity(4, 26, 27, 28, 29, 30) . In the case of cyclins, discrete recognition signals are conserved among related isoforms and within unrelated proteins(6, 31) , although the precise mechanism by which these sequences contribute to substrate recognition by relevant conjugating enzymes has not been well elucidated.

Attachment of single ubiquitin moieties to target proteins effects a modest rate of degradation by the 26 S proteasome(32, 33, 34) ; however, more robust signals for degradative targeting require subsequent formation of multiubiquitin homopolymers by chain elongation from the initial polypeptide conjugate(32, 33, 35) . Considerable recent work has demonstrated that these multiubiquitin chains are formed by a repeating structure in which the carboxyl terminus of each ubiquitin is linked to Lys-48 of the preceding ubiquitin(33, 35) . The crystal structure of the resulting multiubiquitin chain exhibits considerable packing order and symmetry that is thought essential for recognition by the S5 subunit of the regulatory complex capping the 26 S proteasome (36, 37) . This model is supported by mutagenesis studies identifying essential ubiquitin residues required for both multiubiquitin chain binding to S5 and for subsequent degradative targeting(38) .

Ubiquitin-mediated proteolysis has been most extensively studied in yeast and rabbit reticulocytes. Within these systems, the almost quantitative inhibition of ATP-dependent degradation accompanying substitution of rmUb (^1)or UbK48R for wild type polypeptide demonstrates that a significant fraction of degradative flux proceeds through conjugated intermediates bearing Lys-48-linked multiubiquitin chains since neither rmUb nor UbK48R supports chain elongation(33, 35) . However, mounting evidence supports the existence of multiubiquitin chains bearing linkage specificities distinct from Lys-48. Purified recombinant yeast RAD6, a member of the ubiquitin carrier protein (E2) isozyme family, catalyzes multiubiquitin chain formation to core histones in the presence of only ubiquitin activating enzyme (E1) to maintain the E2 active site cysteine charged with ubiquitin thiolester(39) . The linkage specificity for these chains does not require Lys-48 since rmUb but not UbK48R blocks the characteristic ladder of conjugates revealed by SDS-PAGE(39) . Similar results supporting Lys-48-independent chains have more recently been obtained with recombinant E2, an isoform cloned from human keratinocytes using autoantibodies obtained from pemphigous foliaceus patients(64) . Finally, stable Lys-63-linked chains requiring participation of RAD6 (UBC2) have been observed in yeast and proposed to account in part for the DNA repair function of this E2 isoform(40) . Since RAD6 normally supports Lys-48 chain-dependent degradation in yeast within the N-end rule pathway(41, 42) , the latter observation suggests linkage specificity may be context specific and depend on either the target protein or, more likely, the cognate E3 required for conjugation.

The currently accepted paradigm for target protein conjugation requires ubiquitin activating enzyme, a ubiquitin carrier protein, and ubiquitin:protein isopeptide ligase. The metabolic significance of E3-independent conjugation by certain members of the E2 family remains uncertain, although conjugates formed in the absence of E3 by yeast RAD6 and CDC34 as well as the rabbit reticulocyte isoform E2 are substrates for 26 S proteasome-mediated degradation(32) . In the present studies, mutagenesis of the lysine residues present on ubiquitin have allowed the assignment of linkage specificity for multiubiquitin chain formation by RAD6 and E2. Other results indicate that these alternatively linked chains are recognized by subunit 5 of the 26 S proteasome, suggesting target proteins marked by such homopolymer structures may be degradative intermediates. Finally, reconstitution experiments with rabbit reticulocyte extracts demonstrate that alternatively linked chains are competent in the overall degradative pathway. These results define a functional role for alternatively linked chains and serve as a basis for future mechanistic studies with the cognate E3 isoforms.


MATERIALS AND METHODS

Inorganic pyrophosphatase (high pressure liquid chromatography purified) was obtained from Sigma. Carrier-free NaI and [2,8-^3H]ATP were purchased from DuPont NEN. Lysine 48-linked diubiquitin generated by recombinant E2(43) was the generous gift of Dr. Cecile Pickart (Johns Hopkins University). The monomer concentration of diubiquitin was determined spectrophotometrically from the extinction coefficient of free polypeptide(44) . Homogeneous wild type, di-, and mutant ubiquitins were radioiodinated by the chloramine-T procedure(45) . Recrystallized BSA was obtained from Pentex and used for the preparation of I-rcmBSA(46) . Rabbit reticulocyte-rich whole blood was generated by phenylhydrazine induction and used to generate fraction II (45) . A portion of fraction II was used to prepare apparently homogeneous E2 and E1/E2-depleted fraction II(39, 47) . Rabbit liver E1 was purified to apparent homogeneity by adapting reported affinity chromatography/fast protein liquid chromatography methods reported previously (47) and quantitated by the stoichiometric formation of ubiquitin [^3H]adenylate(48) . Homogeneous native histone H2B (generous gift of Dr. Vaughn Jackson, Medical College of Wisconsin) and recombinant yeast CDC34 (UBC3) and RAD6 (UBC2) were those reported previously(49) .

Purification of Wild Type Ubiquitin

Bovine erythrocyte ubiquitin was purchased from Sigma as a lyophilized powder. Although previous lots of this polypeptide were sufficiently homogeneous for use without additional purification, recent lots have consistently contained several contaminating proteins that preclude accurate spectrophotometric quantitation of ubiquitin and obviate its direct use following radioiodination. Therefore, commercial preparations were additionally purified by modification of published procedures(44) . Commercial ubiquitin was dissolved in water to a final concentration of 5 mg/ml and then titrated to pH 4.5 (4 °C) with glacial acetic acid. Aliquots were applied to an HR 10/10 Mono S cation exchange fast protein liquid chromatography column (Pharmacia) equilibrated in 25 mM ammonium acetate (pH 4.5). Ubiquitin eluted as a single, symmetric peak at 0.29 M NaCl within a linear gradient of 5 mM/ml (2 ml/min). Ubiquitin-containing fractions were pooled and dialyzed overnight against distilled water using tubing having an exclusion limit of 3.5 kDa. The resulting sample was concentrated by lyophilization and then dissolved in a minimum amount of distilled water. Ubiquitin (>99% pure) was quantitated spectrophotometrically using an empirically determined 280-nm extinction coefficient of 0.16 ml/mgbulletcm(44) . A portion of the homogeneous ubiquitin was used to prepare rmUb as described previously (49) .

Generation and Purification of Ubiquitin Mutants

Single-site mutagenesis of each lysine residue present within ubiquitin was accomplished by the polymerase chain reaction-based overlap extension method of Ho et al.(50) using the pPLhUb mutagenesis/expression plasmid described earlier(51) . Following the final amplification step, the mutant polymerase chain reaction product was restricted with NdeI/SapI then ligated into NdeI/SapI-restricted pPLhUb. Generation of the predicted mutants was confirmed by dideoxy sequencing the complete ubiquitin coding region of the resulting pPLhUb constructs. Mutant ubiquitins were expressed in the Escherichia coli AR58 strain by heat induction and purified to apparent homogeneity without modification(51) . Ubiquitin concentrations were determined spectrophotometrically as for wild type polypeptide. Typical yields were in the range of 10 mg/liter of culture for all mutants except UbK29R, which gave a consistent yield of approximately 0.5 mg/liter of culture. In all subsequent applications, all mutants displayed stabilities comparable to wild type polypeptide. In addition, all mutants exhibited CD spectra between 190 and 260 nm, indistinguishable from that of wild type ubiquitin (not shown).

Ubiquitin-H2B Conjugation Assay

Initial rates of histone H2B monoubiquitination were measured for wild type and mutant ubiquitins as described(51) . Briefly, various concentrations of wild type or mutant radioiodinated ubiquitin (ca. 2-4 times 10^3 cpm/pmol) were incubated at 37 °C in reactions of 25 µl, final volume, containing 50 mM Tris-Cl (pH 8.0), 2 mM ATP, 10 mM MgCl(2), 1 mM dithiothreitol, 10 mM creatine phosphate, 15 µM H2B, 1 IU creatine phosphokinase, 1 IU inorganic pyrophosphatase, 1 nM E1, and 20 nM E2. In addition, all reactions contained 0.5 mg/ml BSA as a carrier protein to prevent adsorption of the enzymes to the reaction tubes. Reactions were quenched by addition of 25 µl of SDS sample buffer containing 3% (v/v) beta-mercaptoethanol and then boiled for 5 min. Following SDS-PAGE resolution, the monoubiquitinated H2B band was excised and associated radioactivity was determined by counting(45) . Data were corrected for radioactivity present in an identical section of a control lane derived from an incubation performed in the absence of E1 and E2. The incubation conditions were chosen to be E1 limiting, indicated by a linear dependence of initial rate on [E1], to kinetically isolate the ubiquitin-dependent activation step.

Linkage Specificity Assay

The linkage specificity for multiubiquitin chain formation catalyzed by recombinant CDC34, RAD6, and E2 was determined in incubations similar to those for the kinetic assays with the exception that E1 and E2 concentrations were empirically adjusted to be rate-limiting with respect to E2 to kinetically isolate the step of multiubiquitin chain elongation, and histone was present only in the experiment testing RAD6 to serve as a substrate for conjugation(39) . Each incubation was conducted under initial velocity conditions with 5 µM radioiodinated wild type or mutant ubiquitin. Following resolution by 12% SDS-PAGE, the pattern of conjugates was visualized by autoradiography. Correction for slight differences in the specific activities of the radioiodinated proteins was achieved by either normalizing for exposure at constant sample volume (Fig. 1) or adjusting the sample volume at constant exposure (Fig. 2Fig. 3Fig. 4).


Figure 1: Confirmation of CDC34 linkage specificity. The linkage specificity for CDC34-catalyzed autoubiquitination was examined with radiolabeled wild type, reductively methylated, or mutant ubiquitins as described under ``Materials and Methods'' (even-numbered lanes). Incubations were for 30 min in the presence of 80 nm of rabbit liver E1 and 80 nM recombinant CDC34. Odd-numbered lanes were quenched with SDS sample buffer before addition of radiolabeled polypeptide to control for the presence of contaminants in the ubiquitin preparations. Linkage number for multiubiquitin chains is shown to the right.




Figure 2: Determination of E2 linkage specificity. The linkage specificity for E2-catalyzed autoubiquitination was examined in incubations similar to those described in the legend to Fig. 1except that reactions were for 20 min in the presence of 20 nM E1 and 30 nM recombinant E2. Linkage number for multiubiquitin chains is shown to the right.




Figure 3: Determination of RAD6 linkage specificity. The linkage specificity for RAD6-catalyzed ubiquitination of histone H2B was examined in incubations similar to those described in the legend to Fig. 1except that reactions were for 20 min in the presence of 10 nM E1, 20 nM recombinant RAD6, and 12 µM H2B. Linkage number for multiubiquitin chains is shown to the right.




Figure 4: Subunit 5 of the 26 S proteasome binds alternatively linked multiubiquitin chains. Aliquots of partially purified 26 S proteasome (25 µg) were resolved by 10% SDS-PAGE and either stained with Coomassie Blue (left lane) or transferred to nitrocellulose and incubated with radiolabeled chains of the indicated linkage type as described under ``Materials and Methods.'' Positions of subunit 5 and the 100-kDa putative isopeptidase-T bands are indicated to the left. Positions of molecular weight markers are shown to the right.



Proteasome Binding Assay

The 26 S proteasome was partially purified from human erythrocytes by the method of Hough et al.(52) . Proteolytic activity was monitored with the fluorogenic peptide N-succinyl-leucyl-leucyl-valyl-tyrosyl-7-amido-4-methylcoumarin. Fractions exhibiting ATP-dependent hydrolysis of the peptide substrate were pooled and used in the direct conjugate binding assay of Deveraux et al.(37) . Briefly, 25 µg of purified 26 S proteasome per lane was resolved by 10% SDS-PAGE and then electrophoretically transferred to BA83 nitrocellulose (Schleicher and Schuell)(53) . Excess nitrocellulose binding sites were blocked by incubation for 1 h with 50 mM Tris-Cl (pH 7.5) containing 0.15 M NaCl and 5% (w/v) powdered milk. The blots were then incubated for 1.5 h in 50 mM Tris-Cl (pH 7.5) containing 0.15 M NaCl, 25 mg/ml BSA, and 3 times 10^4 cpm/ml multiubiquitin chain prepared using I-ubiquitin and the indicated E2 isozyme. Nonspecifically bound label was removed by four successive 5-min washes in 50 mM Tris-Cl (pH 7.5) containing 0.15 M NaCl, the second and third of which additionally contained 0.05% (v/v) Triton X-100. Specifically bound label was visualized by autoradiography. Binding quantitation was achieved by excising the S5 band and determining associated I label by counting. Radioactivity was corrected for nonspecifically bound label associated with an equally sized portion of the blot not containing the S5 band.

ATP, Ubiquitin-dependent Degradation Assay

The ability of wild type or mutant ubiquitins to support ATP, ubiquitin-dependent degradation of I-rcmBSA in the presence of the three E2 isozymes was assayed using E1/E2-depleted rabbit reticulocyte fraction II(45, 49) . Fraction II was depleted of endogenous E1 and E2 isozymes by passage through an Affi-Gel 10 affinity column containing 5 mg of ubiquitin/ml bed volume (49) . Initial rates of degradation were assayed in triplicate for 1 h at 37 °C in a final volume of 50 µl containing 50 mM Tris-Cl (pH 8.0), 2 mM ATP, 10 mM MgCl(2), 1 mM dithiothreitol, 1 IU creatine phosphokinase, 10 mM creatine phosphate, 300 µg of depleted fraction II, 1 µMI-rcmBSA (3 times 10^5 cpm), 20 µM wild type or mutant ubiquitin, 40 nM E1, and the indicated concentration of E2 isozyme. Depleted fraction II exhibited negligible ubiquitin-dependent degradation of I-rcmBSA in the absence of added affinity-purified E1 and recombinant E2 isozyme. Concentrations of E1 and E2 isozyme in the assays were empirically set to be rate-limiting with respect to E2, as determined by a linear dependence of the initial rate of degradation on [E2].


RESULTS

Characterization of the Ubiquitin Mutants

To determine whether introduction of the Lys Arg point mutations into ubiquitin affected their folding or stability, the homogeneous polypeptides were tested for their ability to support the net E1-catalyzed forward reaction of E2-mediated monoubiquitination of histone H2B under E1-limiting conditions(51) . The initial rates for histone monoubiquitination followed hyperbolic kinetics with respect to ubiquitin concentration for each mutant from which values of K(m) and V(max) could be determined by nonlinear least squares fitting using the Enzfitter program. Table 1summarizes values of K(m) and V(max) for wild type ubiquitin and the seven mutants. The value of K(m) for wild type ubiquitin agrees with that determined previously by this kinetic method (51) and the intrinsic K(d) measured under equilibrium conditions(54) . Introduction of the point mutations into ubiquitin had only minor effects on the affinity of E1 for the polypeptides. For UbK11R, UbK48R, and UbK63R, the increase in K(d) was greater than the combined standard error of the measurements. Although the overall effects are small, the results suggest there is weak interaction between the E1 active site and these lysine residues. This is in contrast to the marked effects of Arg Leu mutations on E1-ubiquitin binding(51) . More important, the values of V(max) are identical within experimental error among the eight proteins (Table 1). Under the conditions of the assays, the rates were limiting with respect to E2 at saturating ubiquitin, indicating that V(max) reflects the step of E2-catalyzed histone ubiquitination. Therefore, the point mutants have negligible effect on the E2 conjugation step supported by the isozyme. These results also indicate that the point mutants did not measurably affect the structure of ubiquitin, consistent with their retention of a native CD spectrum (not shown).



Confirmation of the Linkage Specificity For CDC34

The radioiodinated Lys Arg ubiquitin mutants were used to confirm the linkage specificity for multiubiquitin chain formation catalyzed by recombinant CDC34 as described under ``Materials and Methods.'' This approach is based on observations that arginine is incapable of serving as a site for isopeptide bond formation(33, 39) . Reactions were conducted under E2-limiting conditions to kinetically isolate the step of multiubiquitin chain formation. In addition, incubation times were chosen to be within the steady state region of the time course for chain formation to identify potential effects of the mutations on the rates of addition of each ubiquitin moiety.

The autoradiogram of Fig. 1represents the results obtained for CDC34-catalyzed autoubiquitination(55) . In the presence of wild type I-ubiquitin, a ``ladder'' of ubiquitin conjugate bands is observed that corresponds to the successive addition of single ubiquitin molecules based on relative molecular weight. That the pattern of bands represents formation of a multiubiquitin chain is demonstrated by the absence of conjugates above that of CDC34-Ub(2) when I-rmUb is substituted for wild type polypeptide(39) . With the exception of I-UbK48R, the other six arginine mutants exhibit patterns of multiubiquitin chain formation qualitatively similar to that of wild type polypeptide. The absence of chain formation in the presence of I-UbK48R confirms our earlier report that CDC34 catalyzes the specific E3-independent formation of Lys-48-linked multiubiquitin chains (39) and indicates that the other mutations fail substantially to affect this process. The presence of mono- and diubiquitinated forms of CDC34 with I-rmUb and I-UbK48R represent the conjugation of single ubiquitin moieties to distinct lysines present on CDC34(39) . In addition, the minor band migrating with the CDC34-Ub(9) adduct for I-rmUb and I-UbK48R represents the slow rate of CDC34-catalyzed conjugation of E1 present in the incubations.

In Fig. 1, the CDC34-Ub(4) band formed at steady state with wild type I-ubiquitin is under-represented compared to the bands above and below this species. Independent studies have shown this gap to result from a kinetic effect on chain elongation in which the rate of CDC34-Ub(5) formation is faster than than of CDC34-Ub(4), leading to a steady state depletion of the tetramer. (^2)In contrast, for multiubiquitin chains formed with I-UbK6R the tetramer band is present at a steady state level comparable to that of the other bands while the CDC34-Ub(3) adduct is under-represented (Fig. 1). This result indicates that the K6R mutation leads to a change in relative rates of chain elongation at this step, leading to a switch in the steady state levels of the adducts, and suggests Lys-6 represents a specificity determinant for binding of CDC34 to the growing chain during elongation.

Determination of the Linkage Specificity for E2 and RAD6

The ubiquitin mutants were used in a manner similar to that of Fig. 1to determine the linkage specificity for multiubiquitin chain formation catalyzed by recombinant E2 and RAD6. The autoradiogram of Fig. 2illustrates the pattern of conjugates formed during E2-catalyzed autoubiquitination (64) . The pattern of bands is resolved to the E2-Ub(7) adduct, and the low steady state accumulation of the monoubiquitinated species reflects the highly processive nature of E2 autoubiquitination(56) . As with the results of Fig. 1, the absence of a ladder of bands above that of E2-Ub(2) when I-rmUb is substituted for wild type polypeptide confirms that E2 catalyzes multiubiquitin chain formation(56, 64) . Except for I-UbK11R, the other six arginine mutants exhibit patterns of multiubiquitin chain formation identical to that of wild type polypeptide (Fig. 2). The absence of multiubiquitin bands with I-UbK11R identifies this lysine as the exclusive site for chain elongation catalyzed by E2.

Yeast RAD6 is not subject to autoubiquitination but does catalyze facile conjugation to core histones when used as model substrates(39) . The autoradiogram of Fig. 3represents the pattern of conjugates formed to histone H2B for each of the radioiodinated ubiquitin polypeptides. With wild type I-ubiquitin, a clear pattern of H2B conjugates is observed extending to the Ub(7) adduct. The absence of discrete bands above that of the diubiquitin species in the presence of I-rmUb confirms our earlier report that RAD6 is also capable of multiubiquitin chain formation(39) . That these higher order bands are absent in the I-UbK6R lane confirms that multiubiquitin chain formation by RAD6 exhibits an exclusive linkage specificity requiring isopeptide bond formation through this residue (Fig. 3). This conclusion is supported by observation that the other arginine mutants support multiubiquitin chain formation indistinguishable from that of wild type polypeptide. These results confirm our earlier observations that multiubiquitin chain formation catalyzed by RAD6 does not require linkage through Lys-48(39) .

The S5 Subunit of the 26 S Proteasome Binds Differentially Linked Multiubiquitin Chains

The ability of Lys-48-linked multiubiquitin chains to direct degradation of their attached target protein is thought to be mediated through their binding to subunit 5 of the 19 S regulatory complex present on the 26 S proteasome(37) . Fig. 4demonstrates that subunit 5 also binds multiubiquitin chains linked through Lys-6, catalyzed by RAD6, and those linked through Lys-11, catalyzed by E2.

The 26 S proteasome was partially purified from human erythrocytes (52) and then resolved by SDS-PAGE. The left lane in Fig. 4displays a pattern of Coomassie-stained bands typical of this complex; that is, a family of bands in the molecular weight range of 14-30 kDa representing the 20 S core degradative complex and a series of higher molecular weight bands localized to the 19 S regulatory complex that confers both ATP and ubiquitin conjugate dependence on degradation (52) . Parallel lanes were transferred to nitrocellulose and incubated with multiubiquitin chains formed from radioiodinated polypeptide in chemically defined reactions as described under ``Materials and Methods.''

Multiubiquitin chains linked through Lys-48, formed in the autoubiquitination of CDC34 (Fig. 1) and having an average linkage number n > 7 specifically bound to a band of 50 kDa relative molecular mass (Fig. 4), previously identified as subunit 5 (37) . At equivalent monomer concentrations, I-diubiquitin but not I-ubiquitin also bound to the same band (not shown), consistent with the binding specificity of subunit 5 in recognizing multiubiquitin chains(37) . However, I-diubiquitin bound to subunit 5 only at monomer concentrations substantially greater than that of the CDC34 multiubiquitin chains, again in agreement with the increased affinity exhibited by this proteasome subunit for binding chains of n geq 4(37) . Similarly, Lys-6-linked multiubiquitin chains formed to histone H2B in the reaction catalyzed by RAD6 (Fig. 3) and possessing an average linkage number n > 7 bound to a band having the same relative mobility (Fig. 4). Multiubiquitin chains linked through Lys-11 formed in the autoubiquitination of E2 (Fig. 2) and having an average linkage number n > 7 were also found to bind to the same subunit as those possessing Lys-48 and Lys-6 linkages (Fig. 4). In control studies (not shown), neither histone H2B nor E2 at an equivalent concentration had any effect on the binding of radiolabeled Lys-6- and Lys-11-linked chains, respectively, indicating that these conjugates did not bind to S5 through the target protein moiety to which they were conjugated.

During these studies, we consistently observed multiubiquitin chains possessing all three linkage specificities to associate with an additional protein band having a relative molecular mass of ca. 100 kDa (Fig. 4). This molecular weight is consistent with that of isopeptidase T, a ubiquitin-specific protease believed responsible for the disassembly of multiubiquitin chains and the subsequent reutilization of monomeric polypeptide during the degradative cycle of the 26 S proteasome(57) . This observation suggests isopeptidase T may possess a broad specificity for multiubiquitin chain disassembling. Studies are currently in progress to test this hypothesis with purified isopeptidase.

Differentially Linked Multiubiquitin Chains Compete For Binding to Subunit 5

The results of Fig. 4suggest that subunit 5 is capable of binding multiubiquitin chains possessing different linkage specificities. However, the results do not preclude the alternative interpretation that the apparently homogeneous subunit 5 consists of mixed isoforms, each possessing specificity for binding chains containing different linkages. To test these alternative models, the ability of unlabeled diubiquitin and CDC34-bound Lys-48-linked chains to compete with radiolabeled Lys-48- and Lys-11-linked chains (n > 7) formed during the autoubiquitination of CDC34 and E2, respectively, was examined. Binding of radiolabeled chains was assessed by quantitating bound radioactivity within the S5 band by counting after correction for nonspecifically bound label contained on an equivalently sized portion of nitrocellulose from a parallel control lane containing no sample. The monomer concentration and weighted average linkage number for unlabeled Lys-48-linked chains to CDC34 were estimated from a parallel reaction in which I-ubiquitin was substituted for free polypeptide.

Fig. 5shows that a 10^4-fold excess of diubiquitin results in only a 25% inhibition in binding of I-labeled Lys-48- or Lys-11-linked chains. This result confirms observations of Deveraux et al.(37) that subunit 5 exhibits a significantly diminished affinity for diubiquitin compared to Lys-48-linked chains of higher linkage number. In contrast, a 10^2-fold excess of unlabeled Lys-48-linked chains (n > 7) results in a 60-65% inhibition of both Lys-48- and Lys-11-linked radioiodinated chains. In parallel control studies, neither free CDC34 nor E2 at similar concentrations was capable of competing with its respective radiolabeled auto-multiubiquitin chains (not shown), ruling out the possibility that the apparent competition results from direct binding of the E2 isoforms to S5. Competition between unlabeled Lys-48-linked chains and labeled Lys-48- or Lys-11-linked chains suggests that a single subunit 5 species recognizes chains of alternate linkage specificity. In addition, subunit 5 must possess comparable affinities for Lys-48- and Lys-11-linked chains since unlabeled diubiquitin and Lys-48-linked chains result in similar degrees of inhibition for both homopolymer structures.


Figure 5: Lys-48- and Lys-11-linked multiubiquitin chains competitively bind to subunit 5. Partially purified 26 S proteasome was resolved by 10% SDS-PAGE and then transferred to nitrocellulose as described in the legend to Fig. 4. Regions corresponding to subunit 5 were excised and incubated with Tris-saline-powdered milk to block excess nitrocellulose binding sites (see ``Materials and Methods''). Nitrocellulose sections were then incubated with 1.4 nMI-ubiquitin present as Lys-48-linked CDC34 multiubiquitin chains of n > 7 (Lys-48 linkage) and either 15 µM unlabeled diubiquitin (+Ub(2)) or 0.2 µM unlabeled Lys-48-linked CDC34 multiubiquitin chains of n > 7 (+Ub). Parallel nitrocellulose sections were incubated with 0.6 nMI-ubiquitin present as Lys-11-linked E2 multiubiquitin chains of n > 7 (Lys-11 linkage) and 15 µM unlabeled diubiquitin (+Ub(2)) or 0.2 µM unlabeled Lys-48-linked CDC34 multiubiquitin chains of n > 7 (+Ub). Data are expressed as percent of label bound in the absence of competing unlabeled chain (None). Chain concentrations are expressed in terms of monomer ubiquitin.



Effect of the Ubiquitin Mutants on Protein Degradation

The previous results indicate that RAD6 and E2 are capable of catalyzing E3-independent multiubiquitination via linkages distinct from that of Lys-48 and that these alternate linkages are able to bind to the recognition subunit of the 26 S proteasome. Therefore, we were interested in examining whether these properties were reflected in the abilities of the E2 isoforms to support ubiquitin-dependent degradation. Prior work has shown that rabbit reticulocyte fraction II can be quantitatively depleted of endogenous E1 and E2 isoforms by passing the extract through a ubiquitin-linked affinity column(39, 64) . Ubiquitin-dependent protein degradation can be reconstituted in the resulting depleted fraction II by supplementing with exogenous E1 and selected E2 isoforms(39, 64) . Depleted fraction II was prepared as described under ``Materials and Methods'' and used to measure the initial rates of degradation of I-rcmBSA by the generation of trichloroacetic acid-soluble radioactivity(45) . Preliminary experiments indicated that unsupplemented depleted fraction II exhibited no net ubiquitin-dependent degradation of the radiolabeled substrate in the presence of ATP nor was the rate of proteolysis increased when only E1 was added to the incubations (not shown), consistent with previous findings(39, 64) . In addition, depleted fraction II was unable to form conjugates with I-ubiquitin unless supplemented with E1 and an E2 isozyme (not shown).

Fig. 6(panel A) illustrates rates of net ATP-dependent degradation observed with intact fraction II when supplemented with wild type or variant forms of ubiquitin. A significant decrease in degradative capacity is observed when rmUb is substituted for wild type polypeptide, indicating that the majority of proteolysis proceeds through degradative intermediates bearing multiubiquitin chains(33) . That these chains predominantly contain Lys-48 linkages is demonstrated by the similar inhibition found with UbK48R(33) . A 50% inhibition was consistently observed when incubations were supplemented with UbK11R. Inhibition by UbK11R within this context probably does not indicate formation of chains containing Lys-11 linkages within intact fraction II since complete inhibition is observed only with UbK48R; however, the data do not rule out the potential for chains bearing mixed linkages. More likely, inhibition by UbK11R reflects an effect of this mutant on either the rate of Lys-48-linked multiubiquitin chain elongation within the E3-dependent reaction or a diminished binding of Lys-48-linked UbK11R chains to subunit 5.


Figure 6: RAD6 and E2 support ATP, ubiquitin-dependent protein degradation. Initial rates of I-rcmBSA degradation were measured for complete reticulocyte fraction II (panel A) or E1/E2-depleted fraction II supplemented with rabbit liver E1 (40 nM) and 50 nM recombinant E2 (panel B), 120 nM recombinant RAD6 (panel C), or 80 nM recombinant E2 (panel D). Incubations also contained 20 µM of wild type (Ub), reductively methylated (rm), or mutant ubiquitins. Data are expressed as net ATP, ubiquitin-dependent degradation (panel A) or net ATP, ubiquitin- and E2-dependent degradation (panels B-D) for the mean of triplicate determinations ± S.D.



Profiles of net E2-dependent degradation obtained with depleted fraction II supplemented with recombinant E2, the cognate isozyme for E3-dependent proteolysis within reticulocyte extracts, are qualitatively similar to those observed with intact extract (Fig. 6, panel B). That E2 supplementation of depleted fraction II is capable of quantitatively reconstituting the level of degradation observed with intact extract demonstrates that the bulk of ATP, ubiquitin-dependent proteolysis proceeds through an E2-mediated pathway of conjugation. Panel C illustrates that RAD6 is competent to support protein degradation in depleted fraction II when supplemented with wild type ubiquitin, although the absolute rate of degradation is considerably attenuated(39) . That RAD6 can complement degradation in fraction II is expected since this isoform is considered the yeast homolog of E2 for N-end rule-dependent degradation(58, 59) . The relative efficacy of RAD6 in complementing degradation varied with different preparations of fraction II from which depleted extract was prepared (not shown), suggesting that additional component(s) required for this pathway also show preparation-dependent variability. Notable in the data of panel C is that degradation via a RAD6-dependent pathway requires formation of Lys-48-linked multiubiquitin chains rather than those linked by Lys-6 since degradation is inhibited to base-line values when the reactions are supplemented with either rmUb or UbK48R but not UbK6R. Therefore, RAD6 displays a change in multiubiquitin linkage specificity for E3-dependent conjugation compared to earlier results obtained in the absence of ligase (Fig. 3).

In contrast, depleted fraction II supplemented with recombinant E2 displays a dependence on formation of Lys-11-linked chains similar to that found in the E3-independent reactions of Fig. 2(Fig. 6, panel D). The absolute ability of E2 to support degradation was considerably less than that found with intact extract (panel A) and varied with different preparations of fraction II (not shown). That E2-catalyzed degradation requires Lys-11-linked multiubiquitin chain formation is demonstrated by the complete inhibition of proteolysis observed with rmUb and UbK11R but not UbK48R. Therefore, unlike the results with RAD6, E2 retains its Lys-11 linkage specificity within the context of E3-dependent protein degradation.


DISCUSSION

Pickart and Rose first resolved the E2 isoforms of reticulocytes and demonstrated their ability to catalyzed E3-independent ligation of ubiquitin to a narrow range of model protein substrates(60) . Subsequent studies have emphasized similarities in sequence of the core catalytic domains among members of the E2 family and distinctions in their participation in a variety of the regulatory phenotypes characteristic of ubiquitin-mediated protein degradation, their ability to conjugate ubiquitin to various test proteins, and their catalysis of multiubiquitin chain formation bearing discrete linkage specificities (39, 61) . In the present studies, we have utilized Lys Arg point mutants of ubiquitin to map the linkage specificities for multiubiquitin chain formation catalyzed by two members of the E2 family previously demonstrated to form Lys-48-independent chains and have characterized interactions between these structures and downstream components of the degradative pathway.

The autoradiogram of Fig. 2demonstrates that recombinant human E2 forms multiubiquitin chains exclusively through Lys-11 of the polypeptide since none of the other six lysine mutants significantly effects the pattern of radiolabeled conjugates resolved by SDS-PAGE. This is distinct from the absolute Lys-48 linkage specificity previously characterized for the analogous autoubiquitination reaction of CDC34 (Fig. 1). In contrast, RAD6 exclusively forms Lys-6 linkages during chain elongation from the initial ubiquitin conjugated to histone H2B (Fig. 3). The distinct linkage specificities catalyzed by the three E2 isozymes probably arise in part from core domain sequence differences since the peptide insertion within the core catalytic domain of CDC34 that has been proposed to account for its Lys-48 linkage specificity is absent in both E2 and RAD6(55) . Available evidence suggests the carboxyl-terminal extension domains present on RAD6 and CDC34 are not required for multiubiquitination since their deletion has little effect on the ability to support degradation or conjugation(29, 59) . However, these observations may be a function of the cognate E3 isozymes examined. Conjugation of the initial ubiquitin moiety during CDC34-catalyzed autoubiquitination occurs intramolecularly between subunits of a transient homodimer(63) ; in contrast, the first ubiquitin ligated upon E2 autoubiquitination is within the monomeric polypeptide(62) . The kinetic order for chain elongation is presently unknown for CDC34 and E2, although steric constraints imposed by the growing multiubiquitin chain suggests this step is intermolecular.

Multiubiquitin chains linked through Lys-48 yield a highly symmetric structure stabilized by defined packing interactions between the monomeric units(36) . Multiubiquitin chains possessing novel linkages through Lys-6 or Lys-11 probably yield related but distinct symmetric structures stabilized by packing interactions unique from those found in Lys-48-linked chains. Retention of a defined linkage specificity during elongation of such novel structures must arise from complementary interactions between groups present on the growing multiubiquitin chain and the respective E2 isozyme. Moreover, fidelity in linkage specificity accompanying chain elongation probably requires the E2 to bind across more than a single ubiquitin unit and thus recognize a unique pattern of interaction sites. Such a model posits that each unique linkage specificity should be characterized by a distinct constellation of ubiquitin residues specifying these interactions. For CDC34 chain elongation, the minimum recognition unit requires three ubiquitin units in correct Lys-48 linkage.^2 The hypothesis of discrete sites on ubiquitin directing linkage specificity is supported by our recent observations that mutation of ubiquitin residues directing the specificity for Lys-48 linkages during CDC34- and E2-catalyzed chain elongation have no effect on multiubiquitin chain formation by RAD6 and E2.^2 Alteration in the kinetics of CDC34-catalyzed Lys-48 chain elongation revealed by the shift in steady state formation of CDC34-Ub(3)versus CDC34-Ub(4) intermediates (Fig. 1) suggests that Lys-6 contributes to define this linkage specificity either by direct interaction with the E2 or by stabilizing the incipient structure. The accumulated observations do not rule out an alternative interpretation that conjugation of the second ubiquitin in correct linkage during chain elongation directs formation of subsequent linkages by sterically blocking other available lysine residues present on the polypeptide. This interpretation appears unlikely since in the Lys-48 tetraubiquitin structure all lysine residues remain solvent exposed(36) .

Because chains bearing different linkage specificities are expected to pack into unique structures, we were surprised to find that polymers of similar length linked through Lys-6, Lys-11, or Lys-48 bound with comparable apparent affinity to the S5 subunit of the 26 S proteasome (Fig. 4). Moreover, both Lys-48 and Lys-11 chains bound competitively to S5 (Fig. 5), precluding the existence of distinct isoforms of S5 able to discriminate between alternative structures. (^3)Either the unique structures expected for chains of different linkage pack to present the same ubiquitin surface residues for interaction with S5 or, more likely, the proteasome subunit contains subsets of interacting sites recognizing differentially linked chains. In either case, recognition of the alternatively linked chains by S5 must be of high affinity based on the nanomolar concentrations of these species used in Fig. 4. The competition experiments of Fig. 5allow us to estimate the K(d) for binding of Lys-48 chains to S5. If one reasonably assumes that labeled and unlabeled Lys-48-linked chains bind with equal affinity, then the 60% inhibition found for competition of 200 nM unlabeled chains with the 1.4 nM labeled chains present in the incubation predicts a K(d) of 130 nM, expressed as monomer ubiquitin concentration. A linkage number n approx 7 for both labeled and unlabeled chains requires an intrinsic K(d) leq 18 nM for chain binding. Similar calculations reveal that the 25% inhibition of Lys-48 chain binding by 15 µM diubiquitin requires an intrinsic K(d) of 23 µM for the latter having a linkage number of n = 2.

This estimate probably represents a lower limit to the actual affinity since it is unlikely that the S5 subunit retains absolute native conformation following SDS-PAGE resolution, electrophoretic transfer, and binding to the nitrocellulose membrane. However, the magnitude of this estimated K(d) suggests that the principal mechanistic effect of multiubiquitin chain formation is in increasing the affinity of the proteasome for target substrates over that of the unconjugated protein. This argument is consistent with the significant increase in rate of degradation for model substrates bearing multiubiquitin chains compared to those containing only single ubiquitin moieties(32) . Enhanced affinity of the 26 S proteasome to bind multiubiquitin chain-linked substrates together with the marked ability of the ligation pathway to recognize minute conformational changes arising by denaturation or exposure of discrete signals provides a formidable targeting mechanism for selective protein degradation within the cell.

We have previously shown that RAD6 and E2 support ATP, ubiquitin-dependent degradation in E1/E2-depleted reticulocyte fraction II extracts when supplemented with exogenous activating enzyme (39, 64) and that RAD6 functions in the E3-independent targeting of I-labeled histone H3 for degradation by purified human erythrocyte 26 S proteasome(32) . The complementation studies of Fig. 6confirm our earlier observations that RAD6 and E2 support degradation and confirm in both cases that degradation proceeding through multiubiquitinated intermediates is significantly attenuated in the presence of rmUb. Although RAD6 exhibits Lys-6 linkage specificity in E3-independent chain formation (Fig. 3), within depleted fraction II degradation proceeds exclusively through Lys-48 chains (Fig. 6, panel C). Conversely, E2 retains the Lys-11 linkage specificity in both E3-independent chain formation (Fig. 2) and when added to depleted fraction II (Fig. 6, panel D). Therefore, the linkage specificity of these E2 isozymes is determined in part by the catalytic contribution of E3. Two lines of evidence suggest RAD6- and E2-dependent degradation within depleted fraction II proceeds through E3-catalyzed chain formation. First, both RAD6 and E2 support formation of a heterogeneous distribution of I-ubiquitin conjugates to endogenous proteins when added to E1-supplemented depleted fraction II that is similar to that observed for intact and E2-supplemented extract (not shown). Second, both RAD6 and E2 exhibit extremely restricted substrate specificities for conjugation of exogenous substrates in the absence of E3 (39, 64) and are unable to catalyze a significant rate of rcmBSA ligation (not shown). Therefore, these observations support and extend earlier observations that the multiubiquitin chain linkage formed with RAD6 is context specific with respect to the identity of the E3 involved.

At present, only Lys-48- and Lys-63-linked chains have been observed in vivo(35, 40) . Formation of Lys-63-linked chains within yeast do not challenge the conclusion that Lys-48 chains represent the principal mechanism of degradative targeting since the former appear to serve a regulatory rather than proteolytic function(40) . Moreover, the present observations indicate that detection of alternatively linked chains requires expression of the responsible E2/E3 pair. In the case of E2, this isozyme is abundant in only a limited number of cell types other than keratinocytes. (^4)We are currently screening these cell lines for the presence of Lys-11-linked multiubiquitin chains. The functional significance of alternative chains is obscure at present, particularly since both Lys-11- and Lys-48-linked chains appear equally competent to target degradation. Steady state concentrations of ubiquitin conjugates and therefore their rate of subsequent degradation by the 26 S proteasome depend on the relative rates of conjugation versus disassembly(47, 53) . If chains of different linkage form or undergo disassembly at differential rates, then the presence of alternative structures may represent modulation of proteolysis for specific substrates or substrate subpopulations.

The present data provide additional evidence for the formation of multiubiquitin chains bearing linkage specificities distinct from that of Lys-48. In addition, these alternatively linked chains bind to the 26 S proteasome and, in the case of Lys-11- and Lys-48-linked chains, direct degradation by the complex. The results provide a framework for studies in progress assessing the role of various E2 isozymes in E3-dependent conjugation during the targeting of substrates for degradation by the 26 S proteasome.


FOOTNOTES

*
This work was supported by United States Public Health Service Grant GM34009 (to A. L. H.). 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 Biochemistry, Medical College of Wisconsin, 8701 Watertown Plank Rd., Milwaukee, WI 53226. Tel.: 414-456-8768; Fax: 414-266-8497; :arthaas{at}post.its.mcw.edu.

(^1)
The abbreviations used are: rmUb, reductively methylated ubiquitin; BSA, bovine serum albumin; E1, ubiquitin activating enzyme; E2, ubiquitin carrier protein (subscript denotes relative molecular weight or isozyme); E3, ubiquitin:protein isopeptide ligase; rcmBSA, reduced carboxymethylated BSA; PAGE, polyacrylamide gel electrophoresis; Ub, ubiquitin.

(^2)
D. J. Katzung and A. L. Haas, manuscript in preparation.

(^3)
We did not examine competition between Lys-6- and Lys-48-linked chains because of the technical problems associated with generating structures of the former linkage having a sufficiently high linkage number to make the experiment meaningful. This problem arises from the modest processivity of RAD6-catalyzed chain elongation (O. V. Baboshina and A. L. Haas, unpublished observation).

(^4)
C. A. Conrad and A. L. Haas, unpublished observations.


ACKNOWLEDGEMENTS

-We are indebted to Vaughn Jackson and Cecile Pickart for providing purified histone H2B and Lys-48-linked diubiquitin, respectively, and to Olivija Boskovic for expert technical assistance.


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