Trimming of Ubiquitin Chains by Proteasome-
associated Deubiquitinating Enzymes*
Min Jae Lee, Byung-Hoon Lee, John Hanna, Randall W. King, and Daniel Finley‡

The proteasome generally recognizes substrate via its
multiubiquitin chain followed by ATP-dependent unfolding
and translocation of the substrate from the regulatory
particle into the proteolytic core particle to be degraded.
Substrate-bound ubiquitin groups are for the most part
not delivered to the core particle and broken down to-
gether with substrate but instead recovered as intact free
ubiquitin and ubiquitin chains. Substrate deubiquitination
on the proteasome is mediated by three distinct deubiq-
uitinating enzymes associated with the regulatory parti-
cle: RPN11, UCH37, and USP14. RPN11 cleaves at the
base of the ubiquitin chain where it is linked to the sub-
strate, whereas UCH37 and apparently USP14 mediate a
stepwise removal of ubiquitin from the substrate by dis-
assembling the chain from its distal tip. In contrast to
UCH37 and USP14, RPN11 shows degradation-coupled
activity; RPN11-mediated deubiquitination is apparently
delayed until the proteasome is committed to degrade the
substrate. Accordingly, RPN11-mediated deubiquitination
promotes substrate degradation. In contrast, removal of
ubiquitin prior to commitment could antagonize substrate
degradation by promoting substrate dissociation from the
proteasome. Emerging evidence suggests that USP14
and UCH37 can both suppress substrate degradation in
this way. One line of study has shown that small molecule
USP14 inhibitors can enhance proteasome function in
cells, which is consistent with this model. Enhancing pro-
tein degradation could potentially have therapeutic appli-
cations for diseases involving toxic proteins that are pro-
teasome substrates. However, the responsiveness of
substrates to inhibition of proteasomal deubiquitinating
enzymes may vary substantially. This substrate specificity
and its mechanistic basis should be addressed in future
studies. Molecular & Cellular Proteomics 10: 10.1074/
mcp.R110.003871, 1–5, 2011.

The eukaryotic proteasome is dedicated primarily to the
degradation of proteins tagged by ubiquitin (1). Protea-
somes strongly prefer multiubiquitinated protein substrates.
The successive addition of ubiquitin groups to the substrate
by ubiquitin ligases is usually accomplished through the

formation of ubiquitin chains. The proteasome has much in
common with the simple ATP-dependent proteases of pro-
karyotes and mitochondria (2, 3), although only the protea-
some recognizes the ubiquitin modification. In all cases, the
ATPases form a hexameric ring complex. These rings are
homomeric in the case of the prokaryotic and mitochondrial
proteases, whereas in eukaryotic proteasomes, the ATPase
ring is heteromeric. Proteasomes and the simple ATP-de-
pendent proteases are fundamentally similar in that they all
have an ATPase ring (found within the regulatory particle
[RP]1 in proteasomes, also known as the 19S particle and
PA700) abutting a proteolytic complex (the core particle
[CP] in proteasomes, also known as the 20S particle), al-
though in some cases, the ATPase and protease domains
are present on the same polypeptide chain (Fig. 1). Further-
more, this ancient organization of ATP-dependent pro-
teases involves stacked ring complexes. Substrates are
translocated from one ring to the next via the central pore
within each ring. For most substrates, movement from ring
to ring is driven by ATP hydrolysis. Thus, the substrate is
captured by the ATPase ring of the RP and then translo-
cated into the central cavity of the CP where it is hydrolyzed.

The pathway of translocation contains a series of narrow
constrictions through which folded proteins cannot pass. The
inability of a typical folded protein to pass through these
“filters” defines in part the selectivity of such proteases. How-
ever, the ATPases can exert a pulling force on the substrate
that is strong enough to unfold the protein, which allows for
passage through the series of constrictions. This force is
exerted within the central channel of the ATPase complex.
Thus, translocation and unfolding of the substrate are gener-
ally coupled events (1–3).

Although not departing from this paradigm, the eukaryotic
proteasome interacts with substrate in a more complex man-
ner as a result of interactions involving the ubiquitin tag. Thus,
many of the 13 subunits that were added to the evolutionarily
ancient ATPase complex to form the RP in the eukaryotic
lineage participate in recognition and processing of the ubiq-
uitin tag (1). For example, the yeast proteasome has five and
probably more distinct ubiquitin receptors, two that are inte-

From the Department of Cell Biology, Harvard Medical School,
Boston, Massachusetts 02115

Received, August 2, 2010, and in revised form, September 5, 2010
Published, MCP Papers in Press, September 7, 2010, DOI

10.1074/mcp.R110.003871

1 The abbreviations used are: RP, regulatory particle; CP, core
particle; DUB, deubiquitinating enzyme; USP, ubiquitin-specific pro-
tease; UCH, ubiquitin C-terminal hydrolase; Ub, ubiquitin; AMC, 7-
amino-4-methylcoumarin; JAMM, JAB1/MPN/Mov34 metalloenzyme.

Review
© 2011 by The American Society for Biochemistry and Molecular Biology, Inc.
This paper is available on line at http://www.mcponline.org

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gral subunits and three that are reversibly proteasome-asso-
ciated (4). In addition, proteasomes of mammals have three
distinct deubiquitinating enzymes (DUBs). The multiplicity of
DUBs points to a surprisingly complex role of deubiquitination
in proteasome function.

PROTEASOMAL DEUBIQUITINATING ENZYMES

Why do proteasomes deubiquitinate substrate? The native
state of ubiquitin is exceptionally stable: its single globular
domain remains properly folded under extremes of tempera-
ture and pH (5). This tight structure may antagonize ubiquitin
unfolding by the proteasome, thus obstructing translocation
of the attached substrate; the extent to which attached ubiq-
uitin impedes substrate translocation may vary from substrate
to substrate. A second problem is that, if not cleaved from the
substrate, some ubiquitin can be translocated into the CP
along with substrate and degraded (6, 7). In the absence of
wild-type DUB activity on the proteasome, particularly that of
Ubp6 (the Saccharomyces cerevisiae ortholog of USP14),
cells can become pleiotropically stress-sensitive due to ubiq-
uitin deficiency (6). Thus, DUBs can minimize this collateral
degradation of ubiquitin (6).

Because of these imperatives to remove ubiquitin from
substrate, one might expect that proteasomes remove ubiq-

uitin aggressively. However, unregulated deubiquitination has
the potential to prevent degradation of not only ubiquitin but
substrate as well because substrate is docked at the protea-
some primarily through attached ubiquitin groups. Indeed,
modulation by DUBs could potentially provide sensitive con-
trol over degradation rates of both ubiquitin and substrate.

The DUBs are a diverse family of enzymes, which fall into
five distinct classes (8): the USP family (over 50 members in
humans), the JAMM family (at least four members, one work-
ing on the ubiquitin-like protein Nedd8), the ovarian tumor
(OTU) family (14 members), the Josephin family (four mem-
bers), and the UCH family (four members). DUBs are thiol
proteases with the exception of the metalloenzyme JAMM
family. DUBs vary in their preference for cleaving ubiquitin
chains of different linkages types, their preference for sub-
strate-bound ubiquitin chains as opposed to unanchored
(free) ubiquitin chains, and their cellular localization (8). Some
DUBs appear to function with high specificity toward one or a
few substrates, although only a few examples of this are
known as yet. The functional specialization of DUBs often
reflects their residence in specific protein complexes, and a
remarkable example of this is the proteasomal DUBs.

In humans, the three proteasomal DUBs are RPN11 (also
known as POH1), USP14, and UCH37 (also known as UCH-
L5). This set of proteasomal DUBs is well conserved evolu-
tionarily with the exception of the lack of a recognizable
UCH37 ortholog in S. cerevisiae. The proteasomal DUBs each
belong to a different DUB family and are thus anciently di-
verged in evolution: RPN11, USP14, and UCH37 belong to the
JAMM, USP, and UCH families, respectively.

Among the most interesting features of proteasomal DUBs
are their effects on degradation of the substrate. Whereas
RPN11 appears to promote substrate degradation (9, 10),
USP14 and UCH37 appear to antagonize degradation (11–14)
(Fig. 1). It is generally thought that the distinction between
degradation-promoting proteasomal DUBs and degradation-
antagonizing proteasomal DUBs reflects ATP coupling on the
part of RPN11 and the lack of it for USP14 and UCH37 (1).
RPN11 is not itself an ATPase and is part of a larger protea-
some subassembly, the lid, which contains nine subunits,
none of which is thought to be an ATPase. Presumably
RPN11-mediated deubiquitination events are ATP-dependent
because they are contingent on ATP hydrolysis by the ATPase
ring complex, which, as described above, supports substrate
translocation and unfolding. For example, one may speculate
that substrate translocation by the ATPases brings the sub-
strate into the proximity of the active site of RPN11. In this
model, RPN11-mediated deubiquitination events may occur
somewhat “late” in the reaction pathway after the ATPases
have productively engaged the substrate within the central
translocation channel. In contrast, the removal of ubiquitin
from substrate by UCH37 and USP14 is expected to com-
mence upon docking of the substrate to the proteasome.
Although the exact timing of these events has not been di-

FIG. 1. Deubiquitinating enzymes of proteasome. In metazoans,
three DUBs associate with the proteasome as shown. Each is asso-
ciated with the 19-subunit RP. The detailed positioning of these
enzymes on the RP is not known and is represented here schemati-
cally. RPN11 cuts at the base of the chain to release the chain en
bloc. As shown, this is coupled (by an unknown mechanism) to
translocation of the substrate from the RP to the CP to be degraded.
In contrast, the action of USP14 and UCH37 is thought to promote
substrate release from the proteasome rather than degradation. How-
ever, it should be noted that the attack of these enzymes on a
substrate does not guarantee release, especially as their action on the
chain is gradual, proceeding stepwise over time from the distal tip of
the ubiquitin chain. Some substrates may carry more than one ubiq-
uitin chain and thus be processed in a more complex manner. More-
over, more than one DUB might act on a given chain. The proteasome
icon, adapted from Ref. 30 with permission, is based on cryo-EM
imaging.

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rectly probed, the functional distinctions among these en-
zymes are obvious and quite striking.

A second distinction between RPN11 and the other protea-
somal DUBs is that RPN11 appears to cut at the base of the
chain, whereas UCH37 and most likely USP14 cut at the distal
tip of the chain (12, 15) (Fig. 1). The longer a chain is, the
stronger its interaction with the proteasome will be (16). Thus,
attrition of the chain at its distal tip has the potential to finely
regulate the lifetime of the proteasome-substrate interaction.
In one scenario, the longer the substrate remains docked at
the proteasome, the shorter its chain may become and the
more likely it would be to dissociate.

SMALL MOLECULE INHIBITOR OF USP14

In a recent study of USP14, we have assessed several of
these ideas about how deubiquitination may regulate protea-
some function (11). A high throughput assay for the inhibition
of USP14 catalytic activity was developed using ubiquitin-
AMC (Ub-AMC), a fluorogenic substrate of many DUBs.
USP14 is activated �800-fold by proteasomes, so the screen
was done in the presence of proteasomes. Of 63,000 com-
pounds screened, we found 215 true USP14 inhibitors, but of
the strong inhibitors, only three proved specific for USP14 in
comparison with a panel of other DUBs. One of these, IU1,
was characterized in detail. When tested against purified pro-
teasomes, IU1 produced a sharp reduction in the rate of
trimming of ubiquitin chains bound to cyclin B and of other
ubiquitin chains. This effect of IU1 was observed only with
proteasomes containing USP14. Thus, USP14 is a major
chain-trimming DUB of the mammalian proteasome (11).

With these findings in hand, IU1 was used to test whether
chain trimming can provide for regulation of substrate proteo-
lytic rates. Two ubiquitinated substrates of the proteasome,
cyclin B (17) and a tagged form of Sic1 (Sic1PY [18]), were
both degraded by purified proteasomes more rapidly in the
presence of IU1 (11), indicating that the catalytic activity of
USP14 can suppress substrate degradation. In support of this
view, a catalytically inactive form of USP14 (an alanine sub-
stitution of the active site cysteine of this thiol protease) was
largely or completely defective in suppressing degradation.
Moreover, the inactive form of USP14 does not confer sensi-
tivity to IU1.

These in vitro data were largely reproduced in cultured cells
using different substrates. Proteins such as tau, TDP-43, and
ataxin-3, which have been linked to various neurodegenera-
tive diseases, showed reduced levels upon IU1 treatment (11).
Mouse embryonic fibroblast cells were used for these studies
because of the availability of Usp14-null mouse embryonic
fibroblast cells, a critical specificity control. However, be-
cause this is not a neuronal cell type and because these
transfection-based studies do not reproduce physiological
expression levels, it remains uncertain whether USP14 con-
trols the degradation rates of these particular proteins in a
physiological setting. Nonetheless, these data indicate that

USP14 can control proteasome activity in a cell-based assay.
Another open question is whether accelerated degradation of
such proteins such as tau and TDP-43 can ameliorate their
associated toxicities. However, one indication that acceler-
ated proteasome-mediated degradation can mitigate toxicity
related to misfolded proteins has been seen under conditions
of oxidative damage. Damage to the genome has traditionally
been viewed as the most harmful aspect of oxidative damage,
although it has become increasingly clear that oxidized pro-
teins play a significant role in toxicity (19). The ability of cells
to survive exposure to oxidizing agents was strongly in-
creased by concurrent treatment with IU1 (11), and further-
more, this increased survival correlated with increased clear-
ance of oxidatively damaged proteins. Thus, under conditions
of general proteotoxic stress, the enhancement of protea-
some activity can have a beneficial effect on cell viability.

It appears that a specific subset of substrates is responsive
to catalytic inactivation of USP14 (11). RPN11 and UCH37
have been found to discriminate strongly among different
types of chain linkages (14, 20), and this may be true of
USP14 as well. Experiments to resolve this are in progress.
Chain length may be equally critical (see below). A third sub-
strate feature that may determine USP14 susceptibility is the
amenability of the substrate to proteasome-directed unfold-
ing. Substrates that cannot be readily unfolded and translo-
cated into the CP may bind to the proteasome for longer
periods, thus allowing more time for trimming to proceed. The
persistence of the proteasome-substrate interaction may also
be controlled by USP14 itself in a noncatalytic function of the
protein. Studies carried out originally in yeast (15) and recently
extended to mammalian cells (11) have shown that USP14
has a second mode of proteasome inhibition that does not
involve chain trimming. However, if slowing substrate degra-
dation allows a longer exposure of the substrate to the trim-
ming activity, the two mechanisms may be related. Finally,
USP14 can regulate the opening of the substrate transloca-
tion channel in the CP, providing yet another avenue by which
this intricate DUB influences the interaction between protea-
somes and ubiquitin conjugates (21). We have as yet essen-
tially no understanding of how these three modes of protea-
some regulation by USP14 are related; this is a major
challenge for future work.

USP14 AND UCH37: HOW DO THEY COMPARE?

An important early study (in 1997) on chain trimming by the
proteasome focused on an activity that was unidentified at the
time (12) but now understood to be UCH37 (22). Inhibition by
ubiquitin aldehyde resulted in enhanced degradation of ubiq-
uitinated globin polypeptides. Interestingly, this enhancement
was strongly dependent on chain length: a strong, nearly
4-fold rate enhancement was observed for monoubiquitinated
globin, but this effect was quite weak for species bearing two
or more ubiquitins (12). Thus, the effect observed by Lam et al.
(12) seems to differ markedly from that seen with USP14 in

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that USP14 can suppress the degradation of substrates bear-
ing long chains or many ubiquitin groups. A second difference
is that USP14 is able to suppress degradation over a very brief
time scale. The globin degradation assays were 1-h assays
(12), whereas in the USP14 assays using Sic1PY, for example,
the suppressive effect of USP14 was clear after only 2.5 min
(11). It will be interesting to test whether these differences
would be sustained if the behavior of these enzymes were
examined on a wider variety of substrates.

Although direct comparisons of chain trimming by USP14
and UCH37 remain to be done, the present data raise the
possibility that, at least for the few substrates examined to
date, USP14 catalyzes chain trimming more rapidly to the
extent that it may be dominant over UCH37. This would be
surprising because several studies based on Ub-AMC assays
have reported that UCH37 activity strongly predominates over
that of USP14 (13, 14). However, the Ub-AMC assay may not
be strongly predictive of the relative strengths of these activ-
ities against true ubiquitin-protein conjugates. For example,
UCH-type DUBs may dominate over USP-type DUB for sub-
strates with small leaving groups, such as Ub-AMC (23). It
should be noted that, in the Lee et al. (11) study of 2010,
whereas UCH37 was inhibited by Ub-vinyl sulfone (a deriva-
tive of ubiquitin in which the vinyl sulfone moiety is placed at
the C terminus of ubiquitin; Ub-vinyl sulfone is an irreversible
modifier of catalytic cysteine of thiol protease DUBs) to es-
tablish a high throughput assay of Ub-AMC hydrolysis for
proteasome-bound USP14, UCH37 was not subjected to in-
hibition when the trimming of true ubiquitin chains or effects
on protein degradation were examined (11). Thus, the obser-
vation of strong effects of USP14 on these processes was not
achieved by silencing a competing deubiquitinating activity.
Procedures used for purification in the Lam et al. (12) study of
1997 would have removed USP14 (13), the existence of which
was not recognized at that time, raising the possibility that a
stronger effect on the trimming of ubiquitin from globin might
have been seen otherwise. Chain-trimming globin isopepti-
dase activity has been observed in reticulocyte extracts as
well, and its inhibition by ubiquitin aldehyde also stimulates
globin degradation (24). This is congruent with the studies
using purified proteasomes, but whether the globin-directed
chain trimming activity in the extracts is in fact UCH37, rather
than USP14, which is also inhibited by ubiquitin aldehyde, is
unclear.

We do not know why UCH37 and USP14 are functionally
distinct, but one interesting scenario is that UCH37 acts pref-
erentially on a subset of ubiquitin conjugates that dock at the
proteasome via subunit RPN13. RPN13 has the remarkable
property of being a receptor for both UCH37 and ubiquitin
itself (4, 25). RPN13 is also an activator of UCH37 (22). If
UCH37 acts quickly enough, chains bound to RPN13 might
be released not only through simple dissociation but by
UCH37-dependent chain disassembly as well. Alternatively,
UCH37 might cleave RPN13-bound chains but not in such a

way as to promote their release from RPN13. Several studies,
performed both in vivo and in vitro, have suggested that
UCH37 can suppress protein degradation (12–14). In contrast,
a recent study has suggested that UCH37 may instead pro-
mote the degradation of specific proteasome substrates, thus
working similarly to RPN11 (26). We know too little to resolve
these seeming contradictions. It is possible that UCH37 sup-
presses the degradation of some substrates while promoting
the degradation of others.

DIRECTIONS FOR FUTURE STUDIES

In summary, recent studies have highlighted the complexity
and functional importance of proteasome-associated deubiq-
uitination reactions. With growing interest in this problem, a
much clearer picture should be available soon. Many basic
issues that should be addressed are described above. In
addition, it will be important to determine whether protea-
somal DUBs are constitutive or regulated. One study in yeast
has shown that Ubp6, the ortholog of USP14, is controlled by
ubiquitin levels in a feedback regulatory pathway (27). The
sensitive control over protein degradation rates that can be
achieved via deubiquitination makes it an attractive means to
modulate proteasome activity. In addition to endogenous
mechanisms to regulate proteasome function, small mole-
cules that selectively inhibit these enzymes might in principle
have therapeutic applications in diseases involving toxic, mu-
tationally defective, or otherwise harmful proteins that are also
proteasome substrates. Reducing the levels of such harmful
proteins through accelerated degradation might be beneficial.
Proteasome substrates have been found among proteins in-
volved in neurodegeneration and cancer (11). Enhancement of
proteasome activity, by inhibition of chain trimming, could
have detrimental effects as well. For example, Usp14-null
mutations are lethal in mice (28). However, proteasome func-
tion is essential in many and possibly all mammalian cell
types, yet partial proteasome inhibition has had a major im-
pact in the treatment of multiple myeloma (29). It is possible
that modest proteasome activation may similarly have bene-
ficial effects in specific disease contexts.

* This work was supported, in whole or in part, by National Insti-
tutes of Health Grants DK082906 and GM65592.

‡ To whom correspondence should be addressed: Dept. of Cell
Biology, Harvard Medical School, 240 Longwood Ave., Boston, MA
02115. Tel.: 617-432-3492; Fax: 617-432-1144; E-mail: daniel_finley@
hms.harvard.edu.

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