Ubiquitin carboxy-terminal hydrolase L1 (UCH-L1), also known as PGP9.5, is a protein of 223 amino acids. Although it was originally characterized as a deubiquitinating enzyme, recent studies indicate that it also functions as a ubiquitin (Ub) ligase and a mono-Ub stabilizer. It is highly abundant in brain, constituting up to 2% of total brain proteins. Down-regulation and extensive oxidative modification of UCH-L1 have been observed in the brains of Alzheimer’s disease (AD) and Parkinson’s disease (PD) patients. Mutations in the UCH-L1 gene have been reported to be linked to Parkinson’s disease, in particular, the I93 M variant is associated with a higher susceptibility of PD in contrast to a higher protection against PD for the S18Y variant. Hence, the structure of UCH-L1 and the underlying effects of disease associated mutations on the structure and function of UCH-L1 are of considerable interest. Here, we report the NMR spectral assignments of the S18Y human UCH-L1 mutant with the aim to obtain better understanding about the risk of Parkinson’s disease against structural and dynamical changes induced by this mutation on UCH-L1

C Das

DM Maraganore

DS Wishart

E Leroy

H Osaka

Ho-Sum Tse

Hong-Yu Hu

K Hibi

KD Wilkinson

Kong-Hung Sze

S Naito

Biomolecular NMR Assignments

English

PubMed

Springer - Publisher Connector

Backbone and side-chain 1H, 15N and 13C resonance assignments of S18Y mutant of ubiquitin carboxy-terminal hydrolase L1

ARTICLE
Backbone and side-chain 1H, 15N and 13C resonance assignments
of S18Y mutant of ubiquitin carboxy-terminal hydrolase L1
Ho-Sum Tse • Hong-Yu Hu • Kong-Hung Sze
Received: 4 December 2010 / Accepted: 7 January 2011 / Published online: 5 February 2011
 The Author(s) 2011. This article is published with open access at Springerlink.com
Abstract Ubiquitin carboxy-terminal hydrolase L1
(UCH-L1), also known as PGP9.5, is a protein of 223
amino acids. Although it was originally characterized as a
deubiquitinating enzyme, recent studies indicate that it also
functions as a ubiquitin (Ub) ligase and a mono-Ub stabi-
lizer. It is highly abundant in brain, constituting up to 2%
of total brain proteins. Down-regulation and extensive
oxidative modification of UCH-L1 have been observed in
the brains of Alzheimer’s disease (AD) and Parkinson’s
disease (PD) patients. Mutations in the UCH-L1 gene have
been reported to be linked to Parkinson’s disease, in par-
ticular, the I93 M variant is associated with a higher sus-
ceptibility of PD in contrast to a higher protection against
PD for the S18Y variant. Hence, the structure of UCH-L1
and the underlying effects of disease associated mutations
on the structure and function of UCH-L1 are of consider-
able interest. Here, we report the NMR spectral assign-
ments of the S18Y human UCH-L1 mutant with the aim to
obtain better understanding about the risk of Parkinson’s
disease against structural and dynamical changes induced
by this mutation on UCH-L1.
Keywords Ubiquitin carboxy-terminal hydrolase L1 
Parkinson’s disease  Ubiquitin  NMR spectroscopy 
Resonance assignment
Biological context
The mechanism of protein metabolism in living cells through
the proteasome system, ubiquitination, and deubiquitination
is an important biological process. In particular, deubiqui-
tination is considered essential for negative regulation of
proteolysis and for recycling of ubiquitin from polyubiquitin
chains. Ubiquitin C-terminal hydrolase (UCH-L1), a multi-
functional 24.8 kDa protein, is one of the most abundant
proteins in the brain (1–2% of the total soluble protein)
(Wilkinson et al. 1989). Mutations in the UCH-L1 gene have
been reported to be linked to susceptibility to and protection
from Parkinson’s disease (PD) (Leroy et al. 1998; Maraga-
nore et al. 1999). Furthermore, abnormal overexpression of
UCH-L1 has been shown to correlate with several forms of
cancer (Hibi et al. 1998). The I93 M UCH-L1 mutant linked
to higher susceptibility to PD was found to cause the accu-
mulation of a-synuclein in cultured cells, which is an effect
that cannot be explained by its originally recognized de-
ubiquitinating hydrolase activity. Subsequently, UCH-L1
was shown to exhibit an unexpected concentration depen-
dent ubiquitin ligase activity (Liu et al. 2002) and a mono-
ubiquitin stabilizer activity (Osaka et al. 2003). On the
contrary, a polymorphic variant of UCH-L1, S18Y, that is
associated with decreased PD risk has been shown to have a
reduced ligase activity but comparable hydrolase activity as
the wild-type enzyme. Thus, the ligase activity as well as the
hydrolase activity of UCH-L1 may play a role in proteasomal
protein degradation in the brain, which is a critical process
for neuronal health.
H.-S. Tse  K.-H. Sze (&)
Department of Chemistry and Open Laboratory of Chemical
Biology of the Institute of Molecular Technology for Drug
Discovery and Synthesis, The University of Hong Kong,
Pokfulam Road, Hong Kong SAR, People’s Republic of China
e-mail: khsze@hku.hk
H.-S. Tse
e-mail: tsehosum@hku.hk
H.-Y. Hu
State Key Laboratory of Molecular Biology, Institute
of Biochemistry and Cell Biology, Shanghai Institutes
for Biological Sciences, Chinese Academy of Sciences,
200031 Shanghai, People’s Republic of China
e-mail: hyhu@sibs.ac.cn
123
Biomol NMR Assign (2011) 5:165–168
DOI 10.1007/s12104-011-9292-7
The amino acid sequence of UCH-L1 is similar to that
of other ubiquitin C-terminal hydrolases, including the
ubiquitously expressed UCH-L3, which shares the con-
served catalytic residues and 51% sequence identity with
UCH-L1. But UCH-L3 appears to be unconnected to
neurodegenerative disease. Therefore, the structure of
UCH-L1 and the effects of disease associated mutations on
the structure and function of UCH-L1 are of considerable
interest and importance. Indeed, a recent small-angle
neutron scattering study indicated that the I93 M mutation
promotes ellipsoidal deformation by a decrease of the b-
turn contents whereas the S18Y mutation recovers the
globularity of the protein by an increase of b-turns (Naito
et al. 2006). As a first step to provide detailed structural
information on molecular level and enable greater under-
standing of how the structure of these UCH-L1 mutants
12
12
10
10
8
8
6
6
1H (ppm)
140 140
130 130
120 120
110 110
100 100
15
)
mpp(
N
K4
E7
N9
Y18
G21
A23
G24
R27
F28
V29
L32
G33
E37
S38
G40
S41
V42
C47
A48
L50
L52
F53
L55
T56
A57
K64
K65
E68
K71
G72
V79
Y80
F81
G87
N88
S89
G91
T92
G94
H97
A100
N101
D104
K105
L106
G107
F108
E109
D110
G111
S112
V113
Q116
S119
T121
E122
M124
S125
A130
K135
N136
E137
Q140
Q148
G150
R153
D155
H161 L164F165
N166
N167
D169
G170
E174
L175
D176
G177
R178
F181
N184
H185
G186
D191
T192
L193
A197
K199
V200
T205
R207
E208
G210
R213
S215
A216
V217
C220
K221
A222
H227
H231
K83
Y173
V168
E190
A218
M82
W26 NE-HE
9.0
9.0
8.5
8.5
8.0
8.0
7.5
7.5
1H (ppm)
124 124
122 122
120 120
118 118
116 116
51
)
mpp(
N
Q2
L3
M6
I8
E11
M12
L13
N14
K15
V16
L17
Y18
R19
L20
V22
Q25
W26
D30
V31
L34
E35
E36
S38
L39
A44
A46
A48
L49
L51
L55
A57
Q58
H59
E60
N61
F62
R63
K64
Q66
I67
L70
Q73
E74
V75
S76
K78
T85
I86
N88
C90
I93
L95
I96
A98
V99
N102
Q103
K105
F108
L114
K115
F117
L118
S119
E120
K123
E127
D128
R129
C132
F133
E134
N136
A138
I139 A141
A142
H143
D144
A145
V146
A147
Q148
E149Q151
C152
R153
V154
D155
D156
K157
V158
N159
F160
I163 H171
L172
M179
V183
A187
S188
S189
D191
L194
K195
D196
A198
C201
R202
E206
Q209
E211
V212
F214
S215
L219C220
K221
A223
L224
E225
H226
H228
H231
E69
K131
E203
F204
(a)
(b)
Fig. 1 1H–15N HSQC spectrum
acquired at 298 K on a Bruker
Avance 600 MHz spectrometer
showing the assignments for
UCH-L1-S18Y. The backbone
1H–15N correlations are
sequence-specifically labeled
and the Asn and Gln side-chain
NH2 peaks are linked by
horizontal solid lines. The
central region of the spectrum
a is expanded and shown in
b for clarity
166 H.-S. Tse et al.
123
relates to the etiology of PD, we present here the backbone
and side chain assignments of the S18Y human UCH-L1
mutant.
Methods and experiments
Cloning, expression, and purification
Full-length UCH-L1 was cloned into a pET-22b vector by
using standard cloning protocols. The resulting C-terminal
(His)6-tagged protein was expressed in Escherichia coli
strain BL21(DE3) (Novagen) using M9 minimal media
supplemented with 2.0 g/l [U-13C] glucose and 1.0 g/l
15NH4Cl (Cambridge Isotopes Laboratory) as the sole
nitrogen and carbon sources. Bacterial cultures were grown
at 37C to an optical density of 0.6–0.7. After 0.2 mM
IPTG induction at 22C for 16 h, the protein was then
purified with a nickel-nitrilotriacetic acid column (Qiagen)
following the manufacturer’s recommendations. The pro-
tein was further purified by size exclusion chromatography
on a HiLoad 16/60 Superdex 75 prep grade column
(Amersham Pharmacia). The purity of the (His)6-tagged
protein was estimated to be over 95% by SDS–PAGE.
NMR experiments
The samples were prepared in a buffer containing 20 mM
sodium phosphate, pH 6.5; 100 mM NaCl; 2 mM DTT and
1 mM PMSF in 90% H2O/10% D2O. All NMR experiments
were conducted at 298 K on a Bruker Advance 600 MHz
NMR spectrometer equipped with a TCI cryoprobe. A 2D
{15N,1H}-HSQC and a series of triple resonance experi-
ments including 3D HNCACB, 3D CBCA(CO)NH,
3D HNCO, 3D HNCACO, 3D HNCA, 3D HNCOCA, 3D
HBHA(CO)NH as well as 3D HCCH-TOCSY and 3D
HCCH-COSY experiments have been carried out to allow
sequence specific backbone and side-chains resonance
assignments of the protein. Trimethylsilyl propanoate (TSP)
was used as a chemical shift reference for 1H while 13C
and 15N chemical shifts were referenced indirectly, using
the gyromagnetic ratios of 15N, 13C and 1H (15N/1H =
0.101329118, 13C/1H = 0.251449530). All NMR spectra
were processed using XWINNMR software (Bruker
GmbH). The chemical shifts of backbone and side-chain
resonances were assigned manually using SPARKY pro-
gram (Goddard and Kneller 1993).
Assignments and data deposition
A 2D 1H-15N HSQC spectrum of UCH-L1-S18Y, with
assignment indicated, is shown in Fig. 1. The peaks
observed in this spectrum is well-dispersed, indicating that
the protein is well structured. All expected backbone
1H-15N correlations have been assigned, with the exception
of Q84 and F162. The hexa-His tag at the C-terminus is
also unassigned due to considerable signal overlap. In total,
90.5% of all protons and 84.5% of all aliphatic carbons
have been assigned. All 1H, 15N and 13C backbone and
side-chain chemical shift assignments have been deposited
at the BMRB (http://www.bmrb.wisc.edu) and can be
accessed under the accession number 17260. Analysis of
the 1Ha,
13Ca,
13Cb and
13C’ chemical shift using Chemical
Shift Index (Wishart and Sykes 1994) is summarized in
Fig. 2. The predicted secondary structure of UCH-L1-
S18Y is largely consistent with that found in the crystal
structure of wild type UCH-L1 (Das et al. 2006).
Acknowledgments This work was supported by the Research
Grants Council of Hong Kong (GRF 7755/08 M, 7765/09 M)
Open Access This article is distributed under the terms of the
Creative Commons Attribution Noncommercial License which per-
mits any noncommercial use, distribution, and reproduction in any
medium, provided the original author(s) and source are credited.
References
Das C, Hoang QQ, Kreinbring CA, Luchansky SJ, Meray RK, Ray
SS, Lansbury PT, Ringe D, Petsko GA (2006) Structural basis
for conformational plasticity of the Parkinson’s disease-associ-
ated ubiquitin hydrolase UCH-L1. Proc Natl Acad Sci USA
103:4675–4680
Goddard TD, Kneller DG (1993) SPARKY 3. University of
California, San Francisco
Hibi K, Liu Q, Beaudry GA et al (1998) Serial analysis of gene
expression in non-small cell lung cancer. Cancer Res
58:5690–5694
Leroy E, Boyer R, Auburger G, Leube B, Ulm G, Mezey E et al
(1998) The ubiquitin pathway in Parkinson’s disease. Nature
395:451–452
Liu Y, Fallon L, Lashuel HA, Liu Z, Lansbury PT Jr (2002) The
UCH-L1 gene encodes two opposing enzymatic activities that
10 20 30 40 50 60
MQLKPMEINPEMLNKVLYRLGVAGQWRFVDVLGLEEESLGSVPAPACALLLLFPLTAQHE 
70 80 90 100 110 120
NFRKKQIEELKGQEVSPKVYFMKQTIGNSCGTIGLIHAVANNQDKLGFEDGSVLKQFLSE 
130 140 150 160 170 180
TEKMSPEDRAKCFEKNEAIQAAHDAVAQEGQCRVDDKVNFHFILFNNVDGHLYELDGRMP 
190 200 210 220
FPVNHGASSEDTLLKDAAKVCREFTEREQGEVRFSAVALCKAA
Fig. 2 Secondary structure prediction of UCH-L1-S18Y. Indicated
underneath the amino acid sequence of UCH-L1-S18Y are the carton
representation of the positions of the sheets and helical regions
observed in the crystal structure of wild type UCH-L1 (blue) and the
secondary structure prediction of UCH-L1-S18Y by CSI (red).
Arrows represent the helices and waves the sheets
Backbone and side-chain 1H, 15N and 13C 167
123
affect alpha-synuclein degradation and Parkinson’s disease
susceptibility. Cell 111:209–18
Maraganore DM, Farrer MJ, Hardy JA, McDonnell SK, Lincoln SJ,
Rocca WA (1999) Case-control study of the ubiquitin carboxy-
terminal hydrolase L1 gene in Parkinson’s disease. Neurology
53:1858–1860
Naito S, Mochizuki H, Yasuda T et al (2006) Characterization of
multimetric variants of ubiquitin carboxyl-terminal hydrolase L1
in water by small-angle neutron scattering. Biochem Biophys
Res Commun 339:717–725
Osaka H, Wang YL, Takada K et al (2003) Ubiquitin carboxy-
terminal hydrolase L1 binds to and stabilizes monoubiquitin in
neuron. Hum Mol Genet 12:1945–1958
Wilkinson KD, Lee KM, Deshpande S, Duerksen-Hughes P, Boss JM,
Pohl J (1989) The neuron-specific protein PGP 9.5 is a ubiquitin
carboxyl-terminal hydrolase. Science 246:670–673
Wishart DS, Sykes BD (1994) The13C chemical-shift index: a simple
method for the identification of protein secondary structure using
13C chemical-shift data. J Biomol NMR 4:171–180
168 H.-S. Tse et al.
123


Crossref

Ubiquitin carboxy-terminal hydrolase L1 (UCH-L1), also known as PGP9.5, is a protein of 223 amino acids. Although it was originally characterized as a deubiquitinating enzyme, recent studies indicate that it also functions as a ubiquitin (Ub) ligase and a mono-Ub stabilizer. It is highly abundant in brain, constituting up to 2% of total brain proteins. Down-regulation and extensive oxidative modification of UCH-L1 have been observed in the brains of Alzheimer's disease (AD) and Parkinson's disease (PD) patients. Mutations in the UCH-L1 gene have been reported to be linked to Parkinson's disease, in particular, the I93 M variant is associated with a higher susceptibility of PD in contrast to a higher protection against PD for the S18Y variant. Hence, the structure of UCH-L1 and the underlying effects of disease associated mutations on the structure and function of UCH-L1 are of considerable interest. Here, we report the NMR spectral assignments of the S18Y human UCH-L1 mutant with the aim to obtain better understanding about the risk of Parkinson's disease against structural and dynamical changes induced by this mutation on UCH-L1. © 2011 The Author(s).published_or_final_versionSpringer Open Choice, 21 Feb 201

Sze, KH

Hu, HY

Tse, HS

HKU Scholars Hub

TitleBackbone and side-chain 1H, 15N and 13C resonanceassignments of S18Y mutant of ubiquitin carboxy-terminalhydrolase L1Author(s) Tse, HS; Hu, HY; Sze, KHCitation Biomolecular Nmr Assignments, 2011, v. 5 n. 2, p. 165-168Issued Date 2011URL http://hdl.handle.net/10722/144868Rights The Author(s)ARTICLEBackbone and side-chain 1H, 15N and 13C resonance assignmentsof S18Y mutant of ubiquitin carboxy-terminal hydrolase L1Ho-Sum Tse • Hong-Yu Hu • Kong-Hung SzeReceived: 4 December 2010 / Accepted: 7 January 2011 / Published online: 5 February 2011 The Author(s) 2011. This article is published with open access at Springerlink.comAbstract Ubiquitin carboxy-terminal hydrolase L1(UCH-L1), also known as PGP9.5, is a protein of 223amino acids. Although it was originally characterized as adeubiquitinating enzyme, recent studies indicate that it alsofunctions as a ubiquitin (Ub) ligase and a mono-Ub stabi-lizer. It is highly abundant in brain, constituting up to 2%of total brain proteins. Down-regulation and extensiveoxidative modification of UCH-L1 have been observed inthe brains of Alzheimer’s disease (AD) and Parkinson’sdisease (PD) patients. Mutations in the UCH-L1 gene havebeen reported to be linked to Parkinson’s disease, in par-ticular, the I93 M variant is associated with a higher sus-ceptibility of PD in contrast to a higher protection againstPD for the S18Y variant. Hence, the structure of UCH-L1and the underlying effects of disease associated mutationson the structure and function of UCH-L1 are of consider-able interest. Here, we report the NMR spectral assign-ments of the S18Y human UCH-L1 mutant with the aim toobtain better understanding about the risk of Parkinson’sdisease against structural and dynamical changes inducedby this mutation on UCH-L1.Keywords Ubiquitin carboxy-terminal hydrolase L1 Parkinson’s disease  Ubiquitin  NMR spectroscopy Resonance assignmentBiological contextThe mechanism of protein metabolism in living cells throughthe proteasome system, ubiquitination, and deubiquitinationis an important biological process. In particular, deubiqui-tination is considered essential for negative regulation ofproteolysis and for recycling of ubiquitin from polyubiquitinchains. Ubiquitin C-terminal hydrolase (UCH-L1), a multi-functional 24.8 kDa protein, is one of the most abundantproteins in the brain (1–2% of the total soluble protein)(Wilkinson et al. 1989). Mutations in the UCH-L1 gene havebeen reported to be linked to susceptibility to and protectionfrom Parkinson’s disease (PD) (Leroy et al. 1998; Maraga-nore et al. 1999). Furthermore, abnormal overexpression ofUCH-L1 has been shown to correlate with several forms ofcancer (Hibi et al. 1998). The I93 M UCH-L1 mutant linkedto higher susceptibility to PD was found to cause the accu-mulation of a-synuclein in cultured cells, which is an effectthat cannot be explained by its originally recognized de-ubiquitinating hydrolase activity. Subsequently, UCH-L1was shown to exhibit an unexpected concentration depen-dent ubiquitin ligase activity (Liu et al. 2002) and a mono-ubiquitin stabilizer activity (Osaka et al. 2003). On thecontrary, a polymorphic variant of UCH-L1, S18Y, that isassociated with decreased PD risk has been shown to have areduced ligase activity but comparable hydrolase activity asthe wild-type enzyme. Thus, the ligase activity as well as thehydrolase activity of UCH-L1 may play a role in proteasomalprotein degradation in the brain, which is a critical processfor neuronal health.H.-S. Tse  K.-H. Sze (&)Department of Chemistry and Open Laboratory of ChemicalBiology of the Institute of Molecular Technology for DrugDiscovery and Synthesis, The University of Hong Kong,Pokfulam Road, Hong Kong SAR, People’s Republic of Chinae-mail: khsze@hku.hkH.-S. Tsee-mail: tsehosum@hku.hkH.-Y. HuState Key Laboratory of Molecular Biology, Instituteof Biochemistry and Cell Biology, Shanghai Institutesfor Biological Sciences, Chinese Academy of Sciences,200031 Shanghai, People’s Republic of Chinae-mail: hyhu@sibs.ac.cn123Biomol NMR Assign (2011) 5:165–168DOI 10.1007/s12104-011-9292-7The amino acid sequence of UCH-L1 is similar to thatof other ubiquitin C-terminal hydrolases, including theubiquitously expressed UCH-L3, which shares the con-served catalytic residues and 51% sequence identity withUCH-L1. But UCH-L3 appears to be unconnected toneurodegenerative disease. Therefore, the structure ofUCH-L1 and the effects of disease associated mutations onthe structure and function of UCH-L1 are of considerableinterest and importance. Indeed, a recent small-angleneutron scattering study indicated that the I93 M mutationpromotes ellipsoidal deformation by a decrease of the b-turn contents whereas the S18Y mutation recovers theglobularity of the protein by an increase of b-turns (Naitoet al. 2006). As a first step to provide detailed structuralinformation on molecular level and enable greater under-standing of how the structure of these UCH-L1 mutants1212101088661H (ppm)140 140130 130120 120110 110100 10015)mpp(NK4E7N9Y18G21A23G24R27F28V29L32G33E37S38G40S41V42C47A48L50L52F53L55T56A57K64K65E68K71G72V79Y80F81G87N88S89G91T92G94H97A100N101D104K105L106G107F108E109D110G111S112V113Q116S119T121E122M124S125A130K135N136E137Q140Q148G150R153D155H161 L164F165N166N167D169G170E174L175D176G177R178F181N184H185G186D191T192L193A197K199V200T205R207E208G210R213S215A216V217C220K221A222H227H231K83Y173V168E190A218M82W26 NE-HE9.09.08.58.58.08.07.57.51H (ppm)124 124122 122120 120118 118116 11651)mpp(NQ2L3M6I8E11M12L13N14K15V16L17Y18R19L20V22Q25W26D30V31L34E35E36S38L39A44A46A48L49L51L55A57Q58H59E60N61F62R63K64Q66I67L70Q73E74V75S76K78T85I86N88C90I93L95I96A98V99N102Q103K105F108L114K115F117L118S119E120K123E127D128R129C132F133E134N136A138I139 A141A142H143D144A145V146A147Q148E149Q151C152R153V154D155D156K157V158N159F160I163 H171L172M179V183A187S188S189D191L194K195D196A198C201R202E206Q209E211V212F214S215L219C220K221A223L224E225H226H228H231E69K131E203F204(a)(b)Fig. 1 1H–15N HSQC spectrumacquired at 298 K on a BrukerAvance 600 MHz spectrometershowing the assignments forUCH-L1-S18Y. The backbone1H–15N correlations aresequence-specifically labeledand the Asn and Gln side-chainNH2 peaks are linked byhorizontal solid lines. Thecentral region of the spectruma is expanded and shown inb for clarity166 H.-S. Tse et al.123relates to the etiology of PD, we present here the backboneand side chain assignments of the S18Y human UCH-L1mutant.Methods and experimentsCloning, expression, and purificationFull-length UCH-L1 was cloned into a pET-22b vector byusing standard cloning protocols. The resulting C-terminal(His)6-tagged protein was expressed in Escherichia colistrain BL21(DE3) (Novagen) using M9 minimal mediasupplemented with 2.0 g/l [U-13C] glucose and 1.0 g/l15NH4Cl (Cambridge Isotopes Laboratory) as the solenitrogen and carbon sources. Bacterial cultures were grownat 37C to an optical density of 0.6–0.7. After 0.2 mMIPTG induction at 22C for 16 h, the protein was thenpurified with a nickel-nitrilotriacetic acid column (Qiagen)following the manufacturer’s recommendations. The pro-tein was further purified by size exclusion chromatographyon a HiLoad 16/60 Superdex 75 prep grade column(Amersham Pharmacia). The purity of the (His)6-taggedprotein was estimated to be over 95% by SDS–PAGE.NMR experimentsThe samples were prepared in a buffer containing 20 mMsodium phosphate, pH 6.5; 100 mM NaCl; 2 mM DTT and1 mM PMSF in 90% H2O/10% D2O. All NMR experimentswere conducted at 298 K on a Bruker Advance 600 MHzNMR spectrometer equipped with a TCI cryoprobe. A 2D{15N,1H}-HSQC and a series of triple resonance experi-ments including 3D HNCACB, 3D CBCA(CO)NH,3D HNCO, 3D HNCACO, 3D HNCA, 3D HNCOCA, 3DHBHA(CO)NH as well as 3D HCCH-TOCSY and 3DHCCH-COSY experiments have been carried out to allowsequence specific backbone and side-chains resonanceassignments of the protein. Trimethylsilyl propanoate (TSP)was used as a chemical shift reference for 1H while 13Cand 15N chemical shifts were referenced indirectly, usingthe gyromagnetic ratios of 15N, 13C and 1H (15N/1H =0.101329118, 13C/1H = 0.251449530). All NMR spectrawere processed using XWINNMR software (BrukerGmbH). The chemical shifts of backbone and side-chainresonances were assigned manually using SPARKY pro-gram (Goddard and Kneller 1993).Assignments and data depositionA 2D 1H-15N HSQC spectrum of UCH-L1-S18Y, withassignment indicated, is shown in Fig. 1. The peaksobserved in this spectrum is well-dispersed, indicating thatthe protein is well structured. All expected backbone1H-15N correlations have been assigned, with the exceptionof Q84 and F162. The hexa-His tag at the C-terminus isalso unassigned due to considerable signal overlap. In total,90.5% of all protons and 84.5% of all aliphatic carbonshave been assigned. All 1H, 15N and 13C backbone andside-chain chemical shift assignments have been depositedat the BMRB (http://www.bmrb.wisc.edu) and can beaccessed under the accession number 17260. Analysis ofthe 1Ha,13Ca,13Cb and13C’ chemical shift using ChemicalShift Index (Wishart and Sykes 1994) is summarized inFig. 2. The predicted secondary structure of UCH-L1-S18Y is largely consistent with that found in the crystalstructure of wild type UCH-L1 (Das et al. 2006).Acknowledgments This work was supported by the ResearchGrants Council of Hong Kong (GRF 7755/08 M, 7765/09 M)Open Access This article is distributed under the terms of theCreative Commons Attribution Noncommercial License which per-mits any noncommercial use, distribution, and reproduction in anymedium, provided the original author(s) and source are credited.ReferencesDas C, Hoang QQ, Kreinbring CA, Luchansky SJ, Meray RK, RaySS, Lansbury PT, Ringe D, Petsko GA (2006) Structural basisfor conformational plasticity of the Parkinson’s disease-associ-ated ubiquitin hydrolase UCH-L1. Proc Natl Acad Sci USA103:4675–4680Goddard TD, Kneller DG (1993) SPARKY 3. University ofCalifornia, San FranciscoHibi K, Liu Q, Beaudry GA et al (1998) Serial analysis of geneexpression in non-small cell lung cancer. 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Indicatedunderneath the amino acid sequence of UCH-L1-S18Y are the cartonrepresentation of the positions of the sheets and helical regionsobserved in the crystal structure of wild type UCH-L1 (blue) and thesecondary structure prediction of UCH-L1-S18Y by CSI (red).Arrows represent the helices and waves the sheetsBackbone and side-chain 1H, 15N and 13C 167123affect alpha-synuclein degradation and Parkinson’s diseasesusceptibility. Cell 111:209–18Maraganore DM, Farrer MJ, Hardy JA, McDonnell SK, Lincoln SJ,Rocca WA (1999) Case-control study of the ubiquitin carboxy-terminal hydrolase L1 gene in Parkinson’s disease. Neurology53:1858–1860Naito S, Mochizuki H, Yasuda T et al (2006) Characterization ofmultimetric variants of ubiquitin carboxyl-terminal hydrolase L1in water by small-angle neutron scattering. Biochem BiophysRes Commun 339:717–725Osaka H, Wang YL, Takada K et al (2003) Ubiquitin carboxy-terminal hydrolase L1 binds to and stabilizes monoubiquitin inneuron. Hum Mol Genet 12:1945–1958Wilkinson KD, Lee KM, Deshpande S, Duerksen-Hughes P, Boss JM,Pohl J (1989) The neuron-specific protein PGP 9.5 is a ubiquitincarboxyl-terminal hydrolase. Science 246:670–673Wishart DS, Sykes BD (1994) The13C chemical-shift index: a simplemethod for the identification of protein secondary structure using13C chemical-shift data. J Biomol NMR 4:171–180168 H.-S. Tse et al.123

Petsko GA

SPARKY 3.

The ubiquitin pathway in Parkinson’s disease.

The UCH-L1 gene encodes two opposing enzymatic activities that

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Backbone and side-chain 1H, 15N and 13C resonance assignments of S18Y mutant of ubiquitin carboxy-terminal hydrolase L1

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