Báo cáo khoa học: Solution structure and backbone dynamics of the XPC-binding domain of the human DNA repair protein hHR23B docx

Although the precise functions performed by hHR23A and hHR23B alone in human NER have not yet been determined, Keywords hHR23B; nucleotide excision repair; stress-inducible; structure;

XPC-binding domain of the human DNA repair protein

hHR23B

Byoungkook Kim1,*, Kyoung-Seok Ryu2,*, Hyun-Jin Kim1, Sung-Jae Cho1and Byong-Seok Choi1

1 Department of Chemistry, and National Creative Research Initiative Center for the Repair System of Damaged DNA, Korea Advanced Institute of Science and Technology, South Korea

2 Korea Basic Science Institute, Daejon, South Korea

Nucleotide excision repair (NER) is an important

pathway for the removal of DNA lesions caused by

diverse environmental factors, such as UV irradiation

and chemical modifications [1,2] There are two human

homologs (A and B) of the yeast Rad23 protein

(hHR23A and hHR23B), both of which can form a

complex with the xeroderma pigmentosum group C protein (XPC) [1,3] Recent in vitro and in vivo studies point to a role for the XPC–hHR23B complex as the initiator of global genomic NER [1,4] Although the precise functions performed by hHR23A and hHR23B alone in human NER have not yet been determined,

Keywords

hHR23B; nucleotide excision repair;

stress-inducible; structure; xeroderma

pigmentosum group C protein

Correspondence

B.-S Choi, Department of Chemistry and

National Creative Research Initiative Center

for Repair System of Damaged DNA, Korea

Advanced Institute of Science and

Technology, Yusong-Gu, Gusong-Dong 373-1,

Daejon 305-701, South Korea

Fax: +82 42 869 2810

Tel: +82 42 869 2868

E-mail: byongseok.choi@kaist.ac.kr

*Byoungkook Kim and Kyoung-Seok Ryu

contributed equally to this work

Note

The atomic coordinates of the bundle of 20

conformers have been deposited in the

RCSB Protein Data Bank with entry code

1PVE

(Received 9 November 2004, revised

4 March 2005, accepted 17 March 2005)

doi:10.1111/j.1742-4658.2005.04667.x

Human cells contain two homologs of the yeast RAD23 protein, hHR23A and hHR23B, which participate in the DNA repair process hHR23B hou-ses a domain (residues 277–332, called XPCB) that binds specifically and directly to the xeroderma pigmentosum group C protein (XPC) to initiate nucleotide excision repair (NER) This domain shares sequence homology with a heat shock chaperonin-binding motif that is also found in the stress-inducible yeast phosphoprotein STI1 We determined the solution structure

of a protein fragment containing amino acids 275–342 of hHR23B (termed XPCB–hHR23B) and compared it with the previously reported solution structures of the corresponding domain of hHR23A The periodic position-ing of proline residues in XPCB–hHR23B produced kinked a helices and assisted in the formation of a compact domain Although the overall struc-ture of the XPCB domain was similar in both XPCB–hHR23B and XPCB–hHR23A, the N-terminal part (residues 275–283) of XPCB– hHR23B was more flexible than the corresponding part of hHR23A We tried to infer the characteristics of this flexibility through 15N-relaxation studies The hydrophobic surface of XPCB–hHR23B, which results from the diverse distribution of N-terminal region, might give rise to the func-tional pleiotropy observed in vivo for hHR23B, but not for hHR23A

Abbreviations

hHR23B, human homolog B of yeast Rad23; NER, nucleotide excision repair; RMSD, root mean square deviation; STI1, stress-inducible, heat shock chaperonin-binding motif; UBA, ubiquitin-associated domains; UbL, ubiquitin-like domain; XPC, xeroderma pigmentosum group C protein; XPCB, XPC binding.

many reports suggest that these proteins stabilize the

XPC protein by protecting it from 26S

proteasome-dependent protein degradation [5–7] Another

bio-chemical analysis of the damage-recognition process in

NER revealed that hHR23B is necessary for XPA⁄

replication protein A-mediated displacement of the

XPC–hHR23B complex from damaged DNA [8]

Both hHR23A and hHR23B have four well-defined

functional domains (Fig 1A) These include an

N-ter-minal ubiquitin-like (UbL) domain, the XPC-binding

domain, and two ubiquitin-associated domains (UBA1

and UBA2) [9,10] The UbL domain has a high

bind-ing affinity for polyubiquitin bindbind-ing site 2 of the

human S5a protein, which is supposed to serve as a

shuttle delivering polyubiquitinated, degradable protein

substrates to the proteasome [10] The UBA domains

occur in many enzymes involved in the ubiquitination

pathway and in cell-cycle check points [5,11] It also

has been shown recently that the intramolecular

inter-action between the UbL and UBA domains of

hHR23B may regulate NER by modulating the

pro-teolysis of XPC [12,13]

The XPC-binding domain of hHR23B (residues

277–332, referred to herein as XPCB–hHR23B) houses

an XPC-stimulation activity that functions in a manner

similar to that of full-length hHR23B; this activity

par-ticipates in DNA damage discrimination in vitro and

in the enhancement of cell survival in vivo [9] From

the amino acid sequence, Masutani et al [9] showed

that the XPC-binding domain of hHR23B has a partly

repetitive character [that is, it contains various versions

of the sequence (P)QLLQQ(I)] and a highly

amphi-pathic nature, which is evident when the domain is

represented as a helical wheel [9] XPC-binding

domain-like sequences are also found in protein

linking IAP with cytoskeleton (PLIC), which also has both UbL and UBA domains [14] Consensus motifs from proteins with XPC-binding domain-like sequen-ces are shown in Fig 1B It is interesting that the XPC-binding domain has been classified as a heat shock chaperonin-binding motif, which is also found in the stress-inducible phosphoprotein STI1 [15,16] The presence of sequence similarity between the XPCB domain and STI1 is not surprising, because XPC is also induced by a kind of cellular stress (i.e DNA damage) Studies have also suggested that hHR23B has more diverse in vivo functions than hHR23A For example, only hHR23B was codetected with XPC protein during the affinity fractionation of mammalian crude extract, using an immobilized glutathione-S-transferase (GST)– S5a fusion protein [17] S5a can bind to both polyubi-quitinated proteins and the N-terminal ubqiuitin-like domain of hHR23A⁄ B [18] This might occur because only a small fraction of cellular hHR23A exists in a complex with XPC [7] Experiments with knockout mice that carry a homozygous deficiency in either the mHR23Aor mHR23B gene showed that these two pro-teins are functionally redundant in terms of response

to DNA damage by UV light The XPC protein was not detected in the double knockout cell line, but could be detected after treatment with a proteasome inhibitor It is interesting that only the mHR23B knockout mouse showed defects in postnatal growth, suggesting that mHR23B may have functions beyond those related to XPC and DNA repair [19]

Here, we report the three-dimensional solution struc-ture of the XPCB–hHR23B (275–342) fragment (XPCB–hHR23B), which contains the XPC interaction domain, and compare this with the recently reported structure of XPCB–hHR23A [13,20] Both overall

A

B

Fig 1 Proteins with STI1-homologous domain and the sequence alignment of the XPCB domain with its homologs (A) Domain presenta-tions of the STI1-homologous proteins, showing the UbL (ubiquitin-like), UBA (ubiquitin associated), STI1 (stress inducible) and TPR (tetratrico peptide repeat) domains (B) Multiple sequence alignments of the XPCB domains of hHR23B and hHR23A with other STI1-homologous domains from yeast STI1 and DSK2, and from human PLIC2 were obtained from a simple modular architecture research tool ( SMART ) [16] The Pro residues are indicated in bold.

structures are similar, but the N-terminal part (275–

283) of XPCB–hHR23B is more flexible than that of

hHR23A 15N-Heteronuclear relaxation analyses were

performed with XPCB–hHR23B to gain precise

infor-mation concerning the flexibility of the NH vectors

along the peptide chain We analyzed the diverse

hydrophobic surfaces of XPCB–hHR23B, which result

from the flexible N-terminal region, and attempt to

determine the structure of the XPC-binding surface

Results and Discussion

Although the minimal domain of hHR23B (277–332)

binding to the XPC protein (XPCB–hHR23B) has

been reported previously [9], the solubility of this

frag-ment was too low for NMR experifrag-ments (< 0.2 mm,

data not shown) To increase the solubility of XPCB–

hHR23B for NMR analysis, we added two more

N-terminal amino acids, P275 and L276, which were

selected according to the sequence alignment of STI1

homologs (Fig 1); as such, XPCB–hHR23B could be

concentrated up to 1 mm Still, the peak of the

15N-HSQC spectrum was broad, and its intensity was

not uniform with increasing concentrations of protein

(data not shown) The line-broadening observed at

higher protein concentrations seemed to result from

nonspecific hydrophobic interactions between XPCB–

hHR23B subunits, which were due to the higher

con-tent of hydrophobic residues in the XPCB To reduce

these intermolecular interactions, we either included

additional amino acids from the C-terminal part of

XPCB–hHR23B (residues 333–342, QEAGGQGG

GGG) or solubilized the protein fragment in 10 mm

CHAPS buffer The combination of these two

procedures markedly improved the quality of the 15 N-HSQC spectra for XPCB–hHR23B (Supplementary material, Fig S1) The presence of CHAPS had a negligible effect on the chemical shift values in the

15N-HSQC spectra (data not shown)

Although the peak regions of Hb and Hc in the

15N-HSQC spectra were complicated because of the high content of Gln, Leu and Glu, we were able to accomplish complete side-chain assignment with the aid of additional HCCH-COSY spectrum After the automatic NOE assignment and structure calculation using cyana [21], we obtained the 1242 assigned dis-tance restraints from the 1948 NOE cross-peaks For the energy-minimized final structure, we used the amber7 program after pseudo-atom correction for the obtained distance restraints A stereoview of the calcu-lated XPCB–hHR23B structures is shown in Fig 2A, and the statistics of structure calculation are summar-ized in Table 1 XPCB forms a very compact, roughly five-helix bundle: (a) helix 1 consists of residues E277

to L279 or R280 and assumes the geometry of a

310helix; (b) helix 2 consists of residues F285 to I292,

of which the front boundary was slightly variable; (c) helix 3 spans residues P296 to E309, which has a

310helix that contains residues P296 to L298; (d) helix 4 is formed by residues P311 to S318; and (e) helix 5 consists of residues Q321 to L328 The C-terminal Gly-rich region is a flexible random coil, as was predicted by the chemical shift index (Fig 3A) The Pro residues are likely to be the cornerstones for the boundaries of the helices, and their periodical presence made the XPCB domain fold in a compact manner by introducing helical breaks and turns or kinks (Figs 1 and 2A) The N-terminal part of XPCB–hHR23B

Fig 2 NMR structure of the XPCB domain of hHR23B (A) Stereoview of the 12 superimposed structures of XPCB–hHR23B All Pro resi-dues conserved among the STI1 homologs are marked in blue, and the Pro resiresi-dues not conserved among the STI1 homologs are marked

in cyan (B) Ribbon presentation of the XPCB–hHR23B three-dimensional structure (C) Seven structures of XPCB–hHR23B (yellow) and of XPCB–hHR23A (green, from Walters et al [13]) are superimposed The red and blue residues are amino acids that differ between XPCB– hHR23B and XPCB–hHR23A The side chains of residues with orientations that differ between hHR23B and hHR23A are shown Also, b-N and b-C are the N- and C-termini of XPCB–hHR23B; a-N and a-C are the N- and C-termini of hHR23A.

(amino acids 275–283) was not well converged,

sug-gesting that this part of the molecule was more flexible

than the rest of the polypeptide Indeed, the relatively

negligible long-range NOE cross-peaks in this segment

fit well with this hypothesis (data not shown) For the

rest of XPCB–hHR23B (amino acids 284–332), the

backbone regions were well converged, and the root

mean square deviation (RMSD) was 0.63 A˚ (Table 1)

Although, the overall three-dimensional structure of

XPCB–hHR23B was very similar to that of XPCB–

hHR23A (Fig 2C), it was difficult to identify the

flexi-bility in the N-terminal region of the two previously

reported NMR structures of XPCB–hHR23A [13,20]

The sequence homology between the XPCB regions of

hHR23A and hHR23B is very high (88%), and the

nine amino acids that differ [namely, N281(A) to D237

(B), Q287 (A) to N243 (B), I291 (A) to V247 (B), S297

(A) to A253 (B), I306 (A) to L262 (B), R308(A) to

Q264 (B), Q319 (A) to R275 (B), H323 (A) to Q279

(B) and V332(A) to P288 (B)], simply increased the

flexibility of the backbone segment, including helix 1

(Fig 2C) Although our overall structure for

XPCB–hHR23B was more similar to the structure of XPCB–hHR23A determined by Waters et al (RMSD,

2.12 A˚) [13] than that by Kamionka and Feigon (RMSD,
3.43 A˚) [20], this trend is reversed when

Table 1 Statistics of structure calculation RMSD, root mean

square deviation.

Total NOE distance restraints (#) 717

Long-range NOE (|i – j| > 4) 1242

/ (TALOS + experimental 3 JHNHa) 42

20-structures from AMBER(kCalÆmol)1)

AMBER FF99 force field

20-structures PROCHECK analysis (%)

a

Summation of energies defined by AMBER force field.

A

B

C

D

E

F

G

H

Fig 3 Relaxation studies of XPCB–hHR23B at 500 MHz field (A) The chemical shift index (CSI) clearly shows the well-defined five helical regions R1 (B), R2 (C), and 15 N- 1 H heteronuclear NOE (D) values were used to obtain the ordered parameters (E), the internal correlation times (F), the exchange rates (G), and the model types (H) from the TENSOR 2 analysis The values marked by asterisks (*)

in (C) and (G) are 24.0 ± 0.94 (s)1) and 14.8 ± 1.62 (s)1), respect-ively.

considering the local structure For example, the

struc-ture of hHR23B I306 differed significant from that of

the corresponding residue (L262) of hHR23A I306

was well ordered and was part of a hydrophobic core,

whereas L262 is somewhat flexible and extrudes out

from the molecule core (Fig 2C) However, the

confi-guration of L262 from the XPCB–hHR23A structure

of Kamionka and Feigon shows solvent exposure

sim-ilar to that of I306 in XPCB–hHR23B (Fig 5) The

C-terminus of XPCB–hHR23B extends in a different

direction than those of both XPCB–hHR23As This

may result from the altered amino acid sequence

(P331–V332 in hHR23B vs P287–P288 in hHR23A),

because the consecutive prolines of XPCB–hHR23A

restrict the direction of the C-terminus in a different

way to the Pro–Val sequence in hHR23B

We next performed 15N-relaxation experiments and

tensor2 analysis [22] to examine in more detail the

flexible characteristics of the 275–284 segment of

hHR23B Because of the high quality of our

15N-HSQC spectra, 54 of the 58 protonated backbone

nitrogen atoms were available for relaxation

measure-ments The values of 15N R1, R2 and 15N-1H

hetero-nuclear NOEs are shown in Fig 3 The results

obtained for residues 336–342 (GGQGGGG) were

omitted from Fig 3, as the NOE values of these

resi-dues were in the far negative and their chemical shift

index values were assigned to 0, indicating that this

region is very flexible (Fig 3A) Excepting the

C-ter-minal segment from E330 to G342, the heteronuclear

NOE and R2 measurements showed a uniform

distri-bution over most of the amino acid sequence,

demon-strating values typical for a globular protein The

molecular size of XPCB–hHR23B (275–342) is

8.14 kDa, and the initial R2⁄ R1 ratio values obtained

from 600 and 500 MHz NMR machines corresponded

to an overall correlation times (sinit

c ) of 5.7 and 6.9 ns, respectively The higher correlation time at 500 MHz

may be caused by slight experimental differences,

including a slight difference in buffer conditions and

the lower temperature used for the experiment at

500 MHz (25 instead of 27
C), which gives better

HSQC spectra Because of the known dependence of

the overall correlation time scon the molecular size of

various proteins [23], both sc values of the XPCB are

well matched to those of spherical molecules of similar

size with a smooth surface moving in an ideal liquid

By increasing the error ranges from the fitting to

sin-gle exponential decay (1.75 and 2.0 times for the

relax-ation data at 500 and 600 MHz, respectively), it was

possible to find a proper diffusion tensor model

Fol-lowing the determination and assignment of

appropri-ate spectral density function models for each residue,

the overall correlation time was again optimized using tensor2 Residue-specific models were selected to minimize the overall v2with respect to sc The analyzed results of both relaxation data at 600 and 500 MHz were quite similar (Supplementary Fig S2; and Fig 3), but the values of the order parameters at

600 MHz were low at the residues 278, 281, 322 and

323 Inspection of (S2, si) parametric space for these residues (assigned to model type 2, 4, and 5) showed a very diverse distribution in the Monte Carlo simula-tion using tensor2 Similar inspecsimula-tion of the residues

278 and 281 in the 500 MHz data showed less diverse distribution in the (S2, si) parametric space and the residues, 322 and 323 were assigned to model type 1

It is possible that the quality of relaxation data at

500 MHz is better than at 600 MHz or that the field-dependent motion results in a different model type for the specific residues With respect to the regions of the XPC-binding domain that have well-defined secondary structure (Fig 3A), the order parameter (S2) was higher than 0.85, whereas smaller values were usually obtained for the less ordered C-terminal part of XPCB–hHR23B (Fig 3E) Although a model-free ana-lysis of is not based on the exact physical motions of the molecule, it can provide important information regarding the dimensionless characteristics of the mole-cule’s backbone Most residues are well fitted to model type 1–4, which can be described by the combination

of three terms; an order parameter (S2), an internal correlation time (si), and a conformational exchange term (Rex) From the relaxation studies, we identified that N-terminal segment of XPCB–hHR23B (275–283) has a distinctive exchange process (Fig 3) Interest-ingly, the heteronuclear NOE values of this segment were almost similar to other well-refined regions, in spite of the presence of internal motion (si) and a remarkable exchange process (Rex) The NOE values combined with the presence of internal motion and the exchange terms in N-terminal segment show that the N-H vectors of each residue of this region are correla-ted in motion on the axis of helix 1 (i.e this segment

is not independently flexible)

The XPC–hHR23B complex was reported to be sta-ble even in 0.3 m salt, and the binding mode is driven mainly by hydrophobic interactions [9] Our results show that XPCB–hHR23B has a more diverse hydro-phobic surface than the XPCB–hHR23A, because of the heterogeneous distribution of N-terminal segment (Fig 4) Two major hydrophobic trails (HTs) (HT1 and HT2) were identified in XPCB–hHR23B, one between helix 2 and helix 3, and one between helix 3 and helix 4–5 These two trails were linked by a hydro-phobic linker patch between helix 2 and helix 3 (P296,

L298, L299, and P300) and thus form a U-shaped

hydrophobic surface (Fig 4A,B) The boundary and

size of the hydrophobic linker patch and HT2 were

well conserved in all calculated structures, because

these hydrophobic surfaces were formed by the

well-converged parts of XPCB–hHR23B However, because

of secondary effects from the divergent positioning of

the flexible N-terminal region (275–283), the boundary

and size of HT1 were variable; in contrast, this

vari-ability of the HT1 region was not detected for XPCB–

hHR23A in the Kamionka and Feigon study [20]

Moreover, the HT1 region was not observed in an

ear-lier structure of XPCB–hHR23A reported by Waters

et al [13] The effect of the motion of the N-terminal

region on the hydrophobic surface area is more

obvi-ous in Fig 4C The hydrophobic interior appeared to

be relatively well covered by helix 1 in Structures 1

and 2, but its larger part was exposed to the outside in Structure 3, because of reduced shielding by helix 1

We calculated the solvent-accessible areas of XPCB– hHR23A and XPCB–hHR23B for each residue It is clearly shown that the variation in the solvent-access-ible area of the N-terminal part of XPCB–hHR23B is markedly higher than that of XPCB–hHR23A (Fig 5) The total surface area of all these structures is very similar; XPCB–hHR23B,
41 nm2, XPCB–hHR23As from Waters et al and Kamionka and Feigon,
41 and
43 nm2, respectively The diverse hydrophobic surface, which resulted from the heterogeneous distri-bution of the N-terminal segment of XPCB–hHR23B, was not observed in XPCB–hHR23A and could explain the inferior solubility of XPCB–hHR23B com-pared with that of XPCB–hHR23A [20]

We tried to express the entire hHR23B-binding domain of human XPC (amino acids, 496–734) in Escherichia coli so as to identify the precise XPC con-tact sites in the XPCB–hHR23B However, this domain was expressed in an insoluble form with var-ious expression vectors (N- and C-terminal His-tag, GST-tag, and thioredoxin-tag) and in a number of

E coli strains It is possible that, if we expressed por-tions of the hHR23B-binding domain of human XPC, the peptide segments we selected would be more amen-able to purification in a soluble form Therefore, we

Fig 4 Surface presentations of the three representative structures

of XPCB–hHR23B The hydrophobic surface is presented in yellow,

and the polar and charged surfaces are shown in white HT1 and

HT2 are hydrophobic trail 1 and 2, respectively HL denotes the

hydrophobic linker patch Some structures from the AMBER 7

calcula-tion showed a short distance between the side chains of Q284 and

E309 (marked by the asterisk) This is an artifact from the

electro-static force field of AMBER 7, because no NOE cross-peak between

these side chains was observed.

Fig 5 Solvent-accessible surface areas of XPCB–hHR23A and B The solvent-accessible surface areas and their deviations for each residue are shown for two XPCB–hHR23A structures; Waters et al [13] (A1), Kamionka and Feigon [20] (A2), and XPCB–hHR23B (B).

sought to determine which XPC peptide segments

within the hHR23B-binding domain were relevant to

the domain’s function It was reported that a segment

of the human Stch (hStch) protein can bind to the

STI1-homologous domain (Fig 1B) of the Chap1

(hPLIC-1) protein [24] Therefore, we performed

sequence alignment with the hHR23B-binding domain

of XPC and hStch (because the XPCB domain is

sus-pected to shares sequence similarity with STI1), and

selected two segments with the highest degree of

simi-larity, although their values are low We then

construc-ted two GST-tagged expression vectors that contained

DNA sequences that corresponded to the two selected

segments (which encoded amino acids 566–608 and

613–661 of the hHR23B-binding domain of XPC)

However, we not able to detect binding of either

XPCB–hHR23B or the complete hHR23B protein in

GST pull-down assays using these two constructs (data

not shown) This inability to detect XPCB–hHR23B

binding in these pull-down assays suggests that either

XPCB–hHR23B recognizes XPC regions not present in

the two selected segments or binding of the two

pro-teins requires specifically folded motifs not present in

the protein fragments The latter hypothesis is more

likely, because the hydrophobic surface of XPCB is

delocalized in two ways, and hHR23B has been

repor-ted to stabilize XPC from heat denaturation [25] The

slight variability of the hydrophobic surface of XPCB–

hHR23B resulting from its innate flexibility could be

another advantage of adapting to the larger binding

counter part

The difference in flexibility of the N-terminal regions

of XPCB–hHR23B and XPCB–hHR23A may be one

way to explain why these domains, which share high

sequence homology, have such different solubilities,

even though they have similarly folded structures The

presence of the divergent hydrophobic surface, which

results from the more flexible N-terminal part of

XPCB–hHR23B compared with hHR23A, may explain

why the former has more diverse in vivo functions

[7,18,19] In order to further our knowledge with

respect to the mechanisms of action of these proteins,

it is crucial that we define the precise boundaries of

the STI1-homologous domain and compare the

struc-tures of these domains from various proteins Such

analysis should help to determine the minimal unit for

proper folding to yield a functional domain A number

of other cellular proteins exist that, like hHR23B,

con-tain the STI1, UBL and UBA domains connected by

relatively flexible linkers It is likely that the STI1

domains of these proteins have evolved to specify and

modulate target proteins through a common

mechan-ism related to proteolysis

Experimental procedures

Cloning and purification of the XPCB–hHR23B domain

The cDNAs encoding the hHR23B were generously provi-ded by F Hanaoka (Osaka, Japan) [9] A cDNA fragment containing the XPC-binding motif of hHR23B (277–332), plus two extra N-terminal residues (Pro and Leu) and 10 more C-terminal residues (333–342), was subcloned into the pET15b vector at the NdeI and BamHI sites (Novagen, Madison, WI, USA) The protein was expressed in the

E coli BL21 (DE3) pLysS strain by using isopropyl thio-b-d-galactoside induction at 37
C The N-terminal His-tagged form of the XPCB–hHR23B protein was purified by using a Ni-NTA column (Qiagen, Valencia, CA, USA), and the terminal His-tag was removed by the thrombin diges-tion An additional purification step of gel permeation chromatography was performed on a Superdex 75 column (Amersham Biosciences) Uniformly 15N-labeled and

13C,15N-labeled XPCB–hHR23B (275–342) were obtained

by growing the bacteria in M9 minimal medium supplemen-ted by [15N]ammonium chloride and [13C]glucose

Acquisition and processing of NMR data NMR samples were prepared in buffers (pH 7.0, 40 mm sodium phosphate and 160 mm sodium chloride) with or without 10 mm Chaps All NMR spectra were recorded

at 27
C using a 600 MHz, Varian INOVA spectrometer (Varian Associates Inc., Palo Alto, CA, USA) For the backbone and side-chain assignments of XPCB–hHR23B,

we used the following general triple-resonance experiments: HNCACB [26], CBCA(CO)NH [27], HNCO [28],

HCCH-TOCSY [30], HCCH-COSY [30], and TOCSY-N15-HSQC (mixing time, 100 ms) For structure determin-ation, we extracted the NOE-distance restraints from NOESY-N15-HSQC (mixing times, 80 ms and 150 ms) and NOESY-C13-HSQC (mixing time, 100 ms)

R1 (1⁄ T1) values of 15N were measured from spectra recorded with nine different delays of T¼ 10, 50, 100, 200,

400, 600, 800, 1000, and 1200 ms with relaxation delays of 1.5 s R2(1⁄ T2) values were determined from spectra recor-ded with duration delays of 10, 30, 50, 70, 130, 190, and

250 ms with relaxation delays of 1 s Steady-state 15N-1H NOEs were measured following the method described in Farrow et al [31] using proton saturation periods of 3 and

5 s, and then the average15N-1H NOE was obtained Addi-tional R1 values (20, 40, 80, 140, 240, 400, 800, and

1200 ms with a delay of 3 s) and R2 values (16.8, 33.5, 50.3, 67.0, 100.5, 134.0, 184.3, and 234.6 ms with a delay of

1 s) and two independent set heteronuclear NOEs (satura-tion period of 3 s) were obtained using a cryoprobe-installed 500 MHz, Bruker Avance at the Korea Basic

Science Institute (Daejon, South Korea) The buffer

condi-tion was slightly different to that used in the 600 MHz

NMR machine (pH 7.2, 50 mm Hepes and 200 mm NaCl),

because the presence of highly charged and small ion, such

as phosphate, increases the 90 degree pulse length in the

cryoprobe All NMR data were processed using nmrpipe

[32] and analyzed using sparky [33] The errors of R1 and

R2were estimated from the errors in the single exponential

decay fitting, and those of the15N-1H NOEs were obtained

from the difference of two independent experiments The

values of error were adjusted for the proper tensor2

analy-sis, by increasing of the errors from the fitting (1.75 and 2.0

times for the relaxation data of 500 and 600 MHz,

respect-ively), in which the maximum and minimum errors were

fixed to 7.5 and 3.0%, respectively Spectral density

func-tions assuming an isotropic rotational diffusion tensor were

calculated in 1000-step Monte Carlo simulations using the

tensor2 program [22]

Structure calculation and analysis

In total, 28 sets of dihedral angle restraints (/, u) with

good prediction scores were gathered from TALOS

chem-ical shift analysis [34], and an additional 14 angles

restraints (/) were obtained from the intensity-modulated

15N-HSQC experiment [35] The automatic NOE

assign-ment and structure calculations were performed using the

cyanaprogram [21] and the 1948 NOE cross-peaks (1165

from 13C-NOESY-HSQC and 783 from 15

N-NOESY-HSQC) The 50 conformers with the lowest final target

function values with pseudo-atom correction were the input

for structure refinement with the amber7 program using an

Amber FF99 force field [36] The 50 conformers were

simu-lated, annealed, and energy-minimized for 15 ps During

this calculation, the generalized Born model was applied

for a better simulation of an electrostatic interaction in a

vacuum We deleted a few distance restraints that were

con-sistently violated during the structure calculation and

increased the upper boundary of some distance restraints

slightly by comparing with the NOESY spectra However,

we tried to retain the original values obtained from the

auto-assignment and the structure calculation using cyana

when the distance violations were relatively small Among

the 30 structures with the lowest total energies, we selected

20 structures with the lowest NMR restraint violations for

further analysis There were no angle restraint violations

for the final 20 structures and there were 33–50 distance

restraint violations (0.11 ± 0.04 A˚) among 1242 total

dis-tance restraints for each structure The quality of the

struc-tures was assessed using the refined energy terms and the

procheck program [37] The surface electrostatic potential

distribution of the best overall model of XPCB–hHR23B

was calculated with delphi [38] The solvent-accessible

surface area for XPCB domains were calculated using

gromacs (v3.2.1) [39] and chimera [40] was used to

analyze the structures and to prepare drawings of the struc-tures

Acknowledgements

Financial support was obtained from the National Creative Research Initiatives of the Korean Ministry

of Science and Technology Molecular graphics images were produced using the Chimera package from the Computer Graphics Laboratory of the University of California, San Francisco (supported by NIH P41 RR-01081)

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Supplementary material

The following material is available from http://www blackwellpublishing.com/products/journals/suppmat/EJB/ EJB4667/EJB4667sm.htm

Fig S1 15N-HSQC spectrum of XPCB–hHR23B Fig S2 Relaxation studies of XPCB–hHR23B at 600 MHz field