Báo cáo khoa học: Crystal structure of a designed tetratricopeptide repeat module in complex with its peptide ligand pot

Here we present the X-ray crystal struc-ture of the designed TPR domain CTPR390 in complex with its peptide ligand – the C-terminal residues of Hsp90 peptide MEEVD.. Here we describe in

module in complex with its peptide ligand

Aitziber L Cortajarena1, Jimin Wang1and Lynne Regan1,2

1 Department of Molecular Biophysics & Biochemistry, Yale University, New Haven, CT, USA

2 Department of Chemistry, Yale University, New Haven, CT, USA

Introduction

The basic tetratricopeptide (TPR) repeat comprises 34

amino acids that adopt a helix–turn–helix structure

[1,2] We refer to the two tandem helices as the A-helix

and B-helix In tandem arrays of TPR repeats, the

helices stack to form superhelical structures that

dis-play two surfaces: a concave binding face, and a

con-vex back face The natural role of TPR proteins is to

mediate protein–protein interactions Modules with

three tandem TPR repeats are by far the most

com-mon in nature, and presumably represent the minimal

functional binding unit [1] The simple modular nature

of TPR proteins makes them ideal scaffolds for protein

design studies

We designed a TPR protein, named CTPR3,

com-posed of three repeats of a consensus TPR sequence,

and solved its crystal structure at 1.6 A˚ resolution [3]

The structural alignment of CTPR3 with natural

3-TPR domains clearly shows that its overall structure

is almost identical, with backbone rmsd values between 1.1 A˚ and 1.6 A˚ for the pairwise alignments [4] CTPR3 is significantly more stable than natural TPR domains [3], and this enabled us to introduce muta-tions onto this framework without compromising its thermodynamic stability

Starting with CTPR3 as a structural scaffold, we created a protein (CTPR390) that incorporates heat shock protein (Hsp)90-binding residues, grafted from natural Hsp90-binding TPR domains, onto the con-cave ligand-binding face of the domain (A-helices) [5]

We showed that CTPR390 binds to the C-terminal peptide of Hsp90 [5] specifically, with moderate affinity (Kdof 200 lm) We also demonstrated that the binding affinity could be modulated, and enhanced, by fine-tuning the long-range electrostatic interactions through modifying the charge on the back face of the protein [6] Finally, by introducing the designed domain into

Keywords

crystal structure; Hsp90; protein design;

repeat proteins; tetratricopeptide repeat

(TPR)

Correspondence

L Regan, Department of Molecular

Biophysics & Biochemistry, Yale University,

New Haven, CT 06520, USA

Fax: +1 203 432 5175

Tel: +1 203 432 9843

E-mail: lynne.regan@yale.edu

Website: http://www.yale.edu/reganlab/

(Received 26 October 2009, revised 25

November 2009, accepted 16 December

2009)

doi:10.1111/j.1742-4658.2009.07549.x

Tetratricopeptide repeats (TPRs) are protein domains that mediate key protein–protein interactions in cells Several TPR domains bind the C-ter-mini of the chaperones heat shock protein (Hsp)90 and⁄ or Hsp70, and exchange of such binding partners is key for the heat shock response We have previously described the design of a TPR protein that binds tightly and specifically to the C-terminus of Hsp90, and in doing so, is able to inhibit chaperone function in vivo Here we present the X-ray crystal struc-ture of the designed TPR domain (CTPR390) in complex with its peptide ligand – the C-terminal residues of Hsp90 (peptide MEEVD) This struc-ture reveals two interesting aspects of the TPR modules First, a new pack-ing arrangement of 3-TPR modules is observed The TPR units stack against each other in an unusual fashion to form infinite superhelices in the crystal Second, the structure provides insights into the molecular basis of TPR–ligand recognition

Abbreviations

ASU, asymmetric unit; Hsp, heat shock protein; TPR, tetratricopeptide repeat.

mammalian cells, we showed that it inhibited Hsp90

function, presumably by preventing Hsp90 from

form-ing a complex with the TPR2A domain of

Hsp-organizing protein (HOP) [6]

Here we describe in detail the X-ray crystal structure

of the designed Hsp90-binding TPR module, CTPR390,

in complex with the peptide MEEVD, which

corre-sponds to the five C-terminal residues of Hsp90 We

discuss the unusual superhelical head-to-tail crystal

packing between CTPR390 molecules, and compare it

with the superhelical packing observed for longer TPR

arrays (CTPR8 and CTPR20) [7] Finally, we analyze

the TPR–peptide interaction in detail, thus providing a

structural comparison of natural and designed peptide

recognition by TPR modules This work provides key

insights into the ‘functional grafting’ design strategy,

and also sets the stage for the design of a second

generation of TPR modules with modified binding

properties

Results

Overall crystal structure

The structure of the complex between the C-terminal

Hsp90 peptide and the designed TPR module

CTPR390 was refined to an R-value of 27.1% (free

R-value 28.2%), using all reflections between 30 A˚ and

2.85 A˚ resolution (Tables 1 & 2) The crystallographic

asymmetric unit (ASU) contains five monomeric

CTPR390 molecules with one 5-mer peptide (MEEVD)

bound in the concave cleft of each TPR subunit

(Fig 1A) The stereochemical parameters of the refined

model are good (Table 2), with 98.2% of all

nongly-cine residues located in the ‘most favorable’ region and

the remaining 1.8% nonglycine residues located in the

‘additionally allowed’ regions of the Ramachandran

plot

Crystal packing – head-to-tail packing The parent protein, CTPR3, crystallized as a monomer with two molecules in the ASU It was therefore some-what surprising to find that CTPR390 forms ordered superhelical structures in the crystal (Fig 1B–D)

A superhelical arrangement has been previously observed in the crystal forms of CTPR8 and CTPR20 [7] The packing in CTPR390 crystals, however, is dif-ferent The CTPR390 units stack head to tail and form continuous pseudoinfinite crystalline helical ‘fibers’, which are arranged in a hexagonal symmetry lattice (Fig 2A,B) In the CTPR8 and CTPR20 crystal forms, the ASU was composed of only part of the molecule (two or four repeats), so the ends of the molecules could not be located in the electron density map, and the full-length structures were reconstructed by apply-ing crystal symmetry and unit cell translations [7] By contrast, with CTPR390, we observed five molecules in the ASU, and the discontinuity in the electron density that defines the end of each CTPR390 molecule was clear, allowing us to place the five individual units in the ASU (Fig 1B,D) Each CTPR390 unit is com-posed of three TPR repeats (AB-helix pair) and an additional C-terminal capping helix (Acap) The only way for molecules AB–AB–AB–Acap to arrange on

‘head-to-tail’ packing is if the C-terminal Acap-helix is displaced to allow B3–A1¢ intermolecular packing This effect was observed previously in the CTPR8 and CTPR20 crystal forms [7]

CTPR390 superhelix – comparison with long TPR arrays

The superhelical pitch for the CTPR390 superhelix is approximately 56 A˚, the diameter is 41.4 A˚, and the superhelical twist is 51.4 Seven repeats form an almost complete superhelical turn (Fig 3A,B) CTPR8 and CTPR20 structures displayed similar supehelical conformations, but with eight repeats per superhelical

Table 1 X-ray data collection statistics.

CTPR390–Hsp90

Unit cell dimensions a = b = 100.67 A ˚ , c = 161.57 A˚

Rmerge(%) a 7.5 (39.7)

a Values in parentheses correspond to the highest-resolution bin.

Table 2 Model refinement statistics.

CTPR390–Hsp90

Ramachandran plot (% most favored) 98.2

turn and therefore a twist of 45, with pitch values

varying from 67 A˚ to 72 A˚ and diameter varying from

38 A˚ to 42 A˚ between different crystal forms [7] We

have previously published a detailed comparison of the

superhelices formed by the CTPR proteins and the

superhelix formed by the TPR domain of the enzyme

O-linked GlcNAc transferase [8], showing that the two

superhelices are similar [7] The superhelix in

CTPR390, even though it is similar to that previously

observed in CTPR8 and CTPR20, is more compressed,

and presents a larger curvature, with one fewer repeat

per superhelical turn These differences are clear when

the first three repeats of the CTPR390 superhelix are

superimposed onto the three N-terminal repeats of

CTPR8, as shown in Fig 3C The N-terminal repeats

align well, with an rmsd value of 0.897 A˚, but because

of the differences in the superhelical twist, the two

structures differ more and they do not overlap well towards the C-terminal repeats The fact that 3-TPR units from CTPR390 align well with 3-TPR units of CTPR8 or CTPR20 indicates that, rather than the inter-repeat packing, the intermolecular packing is probably responsible for the pitch and diameter differ-ences between the two structures

Structure of individual CTPR390 molecules Considering the individual 3-TPR units, the structure

of CTPR390 is almost identical to the structure of the parent protein, CTPR3 [3] CTPR3 is the consensus protein, which contains no binding residues CTPR390 has Hsp90-specific residues ‘grafted’ onto the binding surface of CTPR3 [5] The pairwise backbone align-ment of CTPR3 (Protein Data Bank ID: 1Na0) and

A

B

Fig 2 Crystal packing of CTPR390 (A) R3 crystal lattice in the XY plane The crystal axes (x, y, z) and the positions of the three-fold symmetry operators (black triangles) are indicated The yellow box represents the unit cell The arrows indicate the long axis of the crystalline superhelices (B) Axial view of the crystalline

superhelic-es in hexagonal arrangement For simplicity, only the superhelicsuperhelic-es running in one direction in the crystal are shown to depict the hex-agonal symmetry The crystal axes (x, y, z) are indicated The yellow box represents the unit cell.

C

E

C A

E

A B

D

A

C-termini

N-termini

A

C

D

B

Fig 1 Crystal structure of CTPR390–Hsp90 peptide complex (A)

The ASU is shown in ribbon representation, with each CTPR390

unit colored differently (chain A, green; chain B, cyan; chain C,

magenta; chain D, yellow; chain E, orange) The chains are labeled

in the figure with their identification letters The five Hsp90 peptide

ligands (G, H, I, J, and K) are shown as gray ribbons (B) Ribbon

representation of a superhelix formed by five CTPR390 subunits,

reconstructed by applying crystal symmetry and unit cell

transla-tions The color code for the different CTPR390 chains is the same

as in (A) (C) Axial view of the superhelix in (B) (D) Schematic

rep-resentation of the CTPR390 subunits packing in the infinite

supe-rhelices in the crystal form [same color code as in (A–C)].

CTPR390 has an rmsd value of 0.738 A˚ (Fig 3D).

When we calculate pairwise alignments of CTPR390

molecules within the ASU, we obtain rmsd values in

the range 0.433–0.682 A˚, only slightly smaller than the

values observed for the CTPR390–CTPR3

compari-son The conformation of CTPR390 with the Hsp90

peptide ligand bound is thus very similar to the

ligand-free CTPR3 structure This result lends strong

support to our hypothesis that CTPR3 is a stable

framework onto which we can introduce mutations to

change the binding specificity without affecting the

structure of the protein In addition, this result

con-firms our previous observation that TPR modules

undergo little or no structural change upon ligand

binding [4]

CTPR390–peptide complex CTPR390 binds specifically and with moderate affinity (Kdof 200 lm) to the C-terminal peptide of Hsp90 [5] CTPR390 accommodates the Hsp90 peptide in its con-cave binding groove (Fig 4A) The MEEVD peptide is

in an extended conformation, very similar to that seen

in the cocrystal structure of the TPR2A–MEEVD pep-tide complex (Protein Data Bank ID: 1elr) [9] TPR2A

is a natural Hsp90-binding TPR from Hsp-organizing protein

The resolution of the structure that we present is only 2.85 A˚, and when the structure was refined with

no peptides modeled, electron density in the binding pockets of all five TPR units in the ASU was clearly evident The Hsp90 peptide was built into this density, starting with the peptide from the TPR2A–Hsp90

Fig 3 CTPR390 superhelix (A) Molecular surface representation

of one superhelical turn of CTPR390 (green) and CTPR8 (blue); the

dimensions of the superhelices are shown (B) Molecular surface

representation of the CTPR390 superhelix in axial view The

diame-ter of the superhelix is shown (C) Overlay of CTPR390 (green

rib-bon) and CTPR8 (blue ribrib-bon) superhelices Backbone alignment of

the first three N-terminal repeats of CTPR8 and CTPR390 chain C.

The N-termini and C-termini of the superhelices are labeled The

A-helix and B-helix of the first repeat are also labeled (D) Pairwise

alignment of the CTPR390 structure (chain C in magenta) and the

CTPR3 structure (Protein Data Bank ID: 1Na0 in blue) The

N-ter-mini and C-terN-ter-mini of the proteins and the A-helices and B-helices

of the three repeats are labeled.

Fig 4 X-ray crystal structure of CTPR390 in complex with the C-terminal peptide of Hsp90 (A) CTPR390–Hsp90 complex (protein chain C and peptide chain I) The backbone of CTPR390 is shown

as a ribbon representation, and the side chains of the TPR residues, which directly interact with the peptide, are displayed as yellow sticks The C-terminal Hsp90 peptide is shown as sticks in purple (B) 2Fo– Foelectron density maps for two of the peptide chains in the ASU: peptide chain I (C) Overlay of the five peptide chains (G, H, I, J and K chains) The peptide backbones are aligned, giving

an rmsd value of 0.298 A ˚ (D) Overlay of two peptide chains (I in magenta, and J in yellow) bound to two CTPR390 molecules in the ASU (C and D, respectively) The two views are related by 90 rota-tion about a vertical (y) axis Only the protein chain backbones, and not the peptide chains, were overlayed, giving an rmsd value of 0.441 A ˚

plex [9] The 2Fo– Fc electron density map for one

peptide in the asymmetric unit (Fig 4B, peptide I)

shows that the peptide is well defined in the complex

Positional noncrystallographic symmetry constraints

between the five peptide chains in the ASU were used

during the refinement In the final stages of the

refine-ment, the noncrystallographic symmetry constraints

were released, and the five peptide chains in the ASU

adopted slightly different locations relative to the TPR

domains When the backbones of the peptides are

aligned, the five peptide molecules show almost

identi-cal conformations, giving an rmsd value of 0.298 A˚

(Fig 4C) On the other hand, when the backbones of

their corresponding TPR protein chains are overlayed,

the average rmsd value of the pairwise peptide chains

is 3.172 A˚ Figure 4D shows two views, related by 90

rotation, of the overlay of peptide chains I and J, and

illustrates the conformational variability between the

different peptide chains relative to the TPR domains

This result implies that the peptide chains can reorient

as rigid bodies in the binding pocket The average

B-factor for atoms in the peptides is higher than the

average B-factor for atoms in the protein (Table 2),

which again may be a reflection of the mobility of the

peptide chain in the binding pocket This

conforma-tional variability could exist because not all of the

TPR–peptide interactions that are seen in the TPR2A–

peptide complex are reproduced in the CTPR3–peptide

complex Such interactions are discussed in detail in

the next section [5]

Atomic details of the CTPR390–Hsp90 interaction

Analysis of the detailed interactions in the CTPR390–

Hsp90 complex is presented for one of the complexes

in the ASU: chains C (TPR) and I (peptide) (Fig 4A),

for which the electron density for the peptide is the

clearest, and the confidence in the conformation of the

peptide within the complex is the highest

The dissociation constant for the

CTPR390–MEE-VD interaction is  200 lm [5], whereas the

dissocia-tion constant of the TPR2A–MEEVD interacdissocia-tion

 11 lm [9] A comparison of the cocrystal structures

of TPR2A and CTPR390 in complex with the

MEE-VD peptide provides an explanation for the lower

affinity of the designed protein

The backbone overlay of CTPR390 and TPR2A

protein chains gives an rmsd value of 1.632 A˚, and

shows that there are no large differences in the

arrangement of the conserved peptide-binding residues

Rather, the major differences in the complexes are in

the location of the peptide chains relative to the

pro-tein (Fig 5A) The Hsp90 peptide is located in the

CTPR390 concave cleft further away from the protein than it is in the TPR2A domain Accordingly, in the TPR2A–Hsp90 complex, there are more extensive and closer interactions between the protein side chains and the peptide, which probably contribute to the tighter binding affinity

We analyzed in detail the interactions present in the designed complex, in which we introduced Hsp90-specific binding residues, mimicking the TPR2A binding interface Consequently, we expected to find in the CTPR390 protein interactions comparable to those present in the naturally occurring Hsp90-binding TPR domains

A large energetic contribution to the binding of the peptide MEEVD to TPR2A comes from interactions

of the EEVD motif with five conserved ‘carboxylate clamp’ residues on the binding face of the TPR [9] CTPR390 was generated by grafting these residues, and three additional Hsp90-binding specific residues, onto its concave binding face The five residues that form the carboxylate clamp in CTPR390 (Lys13, Asn17, Asn48, Lys78, and Arg82) are equivalent to the residues in TPR2A (Lys229, Asn233, Asn264, Lys301, and Arg305) The overlay of the Ca atoms of these five binding residues gives an rmsd value of 0.565 A˚ (Fig 5A), as compared with the rmsd value of 1.632 A˚ when the entire TPR domains are aligned When the

‘clamp residues’ are aligned, the superposition of the two Hsp90 peptides shows that the C-terminal residues

of the peptides align reasonably well and present the same overall conformation At the N-terminus of the peptide, the alignment diverges more, with the major difference being that the N-terminal Met is signifi-cantly further away from the binding cleft in the CTPR390–MEEVD complex than in the TPR2A– MEEVD complex (Fig 5A)

Figure 5B,C shows detailed schematic diagrams of the TPR–ligand interactions for CTPR390 and TPR2A, respectively, generated using ligplot [10] The electrostatic interactions and hydrogen-bonding inter-actions mediated by the conserved carboxylate clamp residues for the TPR2A–Hsp90 and CTPR390–Hsp90 complexes are tabulated and compared in Table 3 The CTPR390–Hsp90 complex reproduces most of the key interactions present in the TPR2A–Hsp90 complex In the CTPR390–Hsp90 structure, the water molecules cannot be located clearly, so the interactions present in the TPR2A–Hsp90 complex mediated by water molecules could not be placed in the CTPR390– Hsp90 complex (which does not mean that they are not present) Additionally, for most of the interactions, the distances between the interacting atoms are greater

in the CTPR390–Hsp90 complex than in the TPR2A–

Hsp90 complex (Table 3), which could explain the weaker binding affinity relative to the TPR2A–Hsp90 domain

In addition to the electrostatic interactions, hydro-phobic interactions also contribute to the TPR–peptide affinity The total surface area buried upon complex formation between the TPR and the MEEVD peptide was calculated using getarea [11] In the CTPR390– MEEVD complex, 810 A˚2 of surface area is buried upon complex formation, which is slightly smaller than the surface area buried in the TPR2A–Hsp90 complex (930 A˚2) [9]

The hydrophobic residue Val4 of the Hsp90 peptide

is accommodated in a hydrophobic pocket formed by Asn233, Asn264 and Ala267 in TPR2A A comparable hydrophobic pocket is formed by Asn17, Tyr20, Asn48 and Asn51 in CTPR390 (Fig 5B,C) In these two cases, the total surface area buried upon binding of the Val is virtually identical (128 A˚2 versus 137 A˚2) Met1 of the Hsp90 peptide is also engaged in tight hydrophobic interactions with a cavity mainly formed

by the side chains of Tyr236 and Glu271 of TPR2A (Fig 5C) However, in the CTPR390–Hsp90 complex, although an equivalent Tyr is present (Tyr55), there is

a Lys (Lys55) at the Glu271 position that pushes the Met outside of the binding pocket Therefore, Met does not contribute to the binding, resulting in a weaker binding affinity (Fig 5A,B)

A comparison of the average B-factors for the resi-dues in the MEEVD peptide show that the C-terminal Asp has a B-factor of 84, whereas the N-terminal Met has a B-factor of 125 These values provide additional support for the notion that the Met is not engaged in specific interactions with the protein Therefore, the Met probably has more conformational flexibility than

A

B

C

Fig 5 CTPR390–Hsp90 interactions and comparison with the TPR2A–Hsp90 complex (A) Overlay of the five carboxylate clamp residues of the CTPR390–Hsp90 (magenta) and TPR2A–Hsp90 (blue) complexes The side chains of the protein residues and the two Hsp90 peptides are shown in stick representation The identi-ties of the residues in both the CTPR390 (top) and TPR2A (bottom) domains and the N-termini and C-termini of the peptides are indi-cated (B) Schematic 2D diagram of CTPR390–Hsp90 peptide inter-actions (chains C and I) The schematic was generated from the pdb file of the complex with LIGPLOT [10] The interactions shown are those mediated by hydrogen bonds and by hydrophobic con-tacts Hydrogen bonds are indicated by dashed lines between the atoms involved, and hydrophobic contacts are represented by an arc with spokes radiating towards the ligand atoms that they con-tact The contacted atoms are shown with spokes radiating back (C) Schematic representation of TPR2A–Hsp90 peptide interactions generated as in (B) from the pdb file of the complex (Protein Data Bank ID: 1elr) [9].

the Asp, which displays many specific contacts with the

protein (Table 3) The change in surface area associated

with the Met upon binding to CTPR390 (34 A˚2) is

small in comparison with the change upon binding to

TPR2A (142 A˚2), also corroborating the lack of specific

interaction mediated by the Met Indeed, the difference

in surface area buried by the Met between the two

complexes accounts for the total difference in surface

area buried upon peptide binding between CTPR390

and TPR2A It has been reported that deletion of the

Met increases the dissociation constant of the TPR2A–

Hsp90 complex from 11 lm to 90 lm [9] Therefore,

the lack of this interaction in the CTPR390–peptide

complex will partially contribute to the moderately

weak binding affinity of the designed TPR module

Discussion

In this article, we present the cocrystal structure of a

designed TPR domain with its partner peptide

We show that this 3-TPR domain can adopt a

superhelical structure in the crystal similar to those

reported for long TPR arrays [7] This result illustrates

the natural tendency of TPR domains to stack head to

tail and self-assemble into an ordered macrostructure

in crystals We have seen no evidence for such

associa-tion in soluassocia-tion

We previously showed that, by grafting the binding

residues from a given natural TPR domain onto a

con-sensus scaffold, we could incorporate the binding

activity in the newly designed domain This structure

proves that the new domain obtained using this

‘graft-ing’ strategy mimics not only the binding activity [5,6],

but also the interactions at a molecular level between

the protein and the ligand This result confirms the

TPR domains as a stable protein scaffold where, by

grafting the binding residues, one can interchange the binding activities between domains

Additionally, this work allows us to compare the structure of the consensus CTPR3 domain without ligand and the designed CTPR390 (with a total of only

12 mutations relative to the parent CTPR3) with ligand bound These two structures overlap almost per-fectly, supporting our previous observations that TPR domains bind their target peptides without undergoing any major conformational changes [4]

Finally, the detailed understanding of the molecular basis of the CTPR390–Hsp90 recognition opens the door to a second generation of rationally improved CTPR modules For example, it is clear from the structure that Asn51 and Lys55 from CTPR390 are pushing the peptide out of the hydrophobic pocket, and therefore the N-terminal Met of the peptide does not contribute to the binding energy In TPR2A, these residues are Ala267 and Glu271 One would expect that introducing these mutations in the CTPR390 scaf-fold might improve its binding affinity for Hsp90 peptide

Experimental procedures

Protein design CTPR390 incorporates Hsp90-binding residues in the con-cave face of the consensus 3-TPR domain (CTPR3) [3,5] The sequences of the first, second and third A-helices of CTPR390 are as follows: first A-helix, AEAWKNLGNAYYK; second A-helix, ASAWYNLGNAYYK; and third A-helix, AKA-WYRRGNAYYK The B-helix sequence in all of the TPR repeats in CTPR390 is DYQKAIEYYQKALEL, which differs from the negatively charged back sequence of the

Table 3 TPR–peptide electrostatic interactions in the carboxylate clamp For the data for hydrobonding interactions, we have been gen-erous in the constraints in order to show all the possible interactions, and how they differ between the two complexes.

Residue in TPR Residue in peptide Distance (A ˚ ) Residue in TPR Residue in peptide Distance (A ˚ )

CTPR3 scaffold, DYDEAIEYYQKALEL Underlining

indi-cates the solvent-exposed charged residues [5]

Cloning of the CTPR390 gene

The gene encoding CTPR390 was constructed as previously

described and cloned into the pProEx-HTA vector to

incor-porate a cleavable N-terminal His-tag (GibcoBRL,

Gaithersburg, MD, USA) [5,12] The identity of the

construct was verified by DNA sequencing (W.M Keck

Facility, Yale University, New Haven, CT, USA)

Protein expression and purification

CTPR390 was overexpressed and purified as previously

described [5] As a final purification step to obtain

high-purity protein for crystallization, the protein was run on a

size exclusion column (HiLoad Superdex HR-75;

Amer-sham Bioscience, Uppsala, Sweden) The protein

concentra-tion was determined by UV absorbance at 280 nm, using

extinction coefficients at 280 nm calculated from amino

acid composition [13]

Protein crystallization and data collection

Purified CTPR390 at 20 mgÆmL)1 protein in 10 mm

Tris⁄ HCl and 50 mm NaCl (pH 7.5) was mixed with the

C-terminal five amino acids of Hsp90 (Ac-MEEVD-COOH

peptide) at a protein⁄ peptide ratio of 1 : 4

Microbatch-under-oil screening at the high-throughput crystallization

laboratory at the Hauptman-Woodward Medical Research

Institute Inc (HWI, Buffalo, NY, USA) [14] identified few

preliminary crystallization conditions We could reproduce

one crystallization condition [0.1 m NaH2PO4, 40% (w⁄ v)

poly(ethylene glycol) 20000, 0.1 m Caps, pH 10.0] in our

laboratory We optimized this condition by the sitting-drop

vapor diffusion method, using two-fold diluted initial

for-mulation as the well solution The final crystallization

condi-tion contained 50 mm NaH2PO4, 20% (w⁄ v) poly(ethylene

glycol) 20000, and 50 mm Caps (pH 10.0) The well solution

was mixed in equal volumes (2 lL) with a protein–peptide

complex solution (1 : 4 molar ratio) at 30 mgÆmL)1protein

concentration Crystals appeared within a week at 20C,

and reached sizes of approximately 80· 80 · 50 lm within

2 weeks Crystals were flash-cooled under a nitrogen gas

stream (100 K) Data were collected to 2.85 A˚ resolution at

the NSLS beamline X12C (Brookhaven National

Labora-tory) The data collection statistics are shown in Table 1

Structure determination and refinement

We used hkl2000 [15] to index, scale and integrate the

data The protein crystallized in space group R3 with unit

cell dimensions of a = b = 100.67 A˚, c = 161.57 A˚, and

a = b = 90, c = 120 The CTPR390 structure was solved by molecular replacement using molrep [16] in the ccp4i suite [17] The structure of the consensus TPR with-out the solvating helix was used as search model [CTPR3 (Protein Data Bank ID: 1NA0] [3] There were five TPR molecules in the ASU The structure was refined with cns [18] and refmac5 [19], with TLS refinement [20] in the late stages of the refinement, to a resolution of 2.85 A˚ Iterative rounds of refinement and manual model adjusting in coot [21] were performed until R-factors converged to a final value of R (Rfree) = 28.4 (29.2) for the structure of the TPR molecules The ligand peptide (MEEVD) was built in the Fo–Fcdifference electron density map First, one peptide chain was built in the CTPR390 molecule in the ASU with strongest positive density, using a backbone conformation for the Hsp90 peptide from the TPR2A–Hsp90 complex as starting model (Protein Data Bank ID: 1elr) [9] The model with one copy of the Hsp90 peptide was refined and the additional four peptide chains were built by symmetry oper-ations of the refined peptide chain in the binding pockets of the other protein chains The complete model was further refined Water molecules were automatically added in coot, and were validated with the electron density maps The final model with one peptide molecule in the binding groove of each of the five TPR molecules in the ASU converged to

R(Rfree) = 27.1 (28.2) The geometry and stereochemical properties of the model were checked with molprobity [22] Crystallographic statistics are shown in Table 2

Coordinates The X-ray structure of the CTPR390–Hsp90 peptide com-plex has been deposited in the Protein Data Bank as 3KD7

Acknowledgements

We thank members of staff at NSLS beamlines X12C and X6A, BNL, where data were collected The high-throughput crystal screening service of the Hauptman-Woodward facility assisted in identifying initial crystallization conditions We thank T Kajander for his advice during the crystallization process and data collection We thank staff members and users of the Yale Center for Structural Biology for valuable insights during the structure-solving and refinement process We thank R Collins, T Grove, R Ilagan, M Jackrel, L Kundrat and G Pimienta-Rosales for valu-able discussions and comments on the manuscript

References

1 D’Andrea L & Regan L (2003) TPR proteins: the versa-tile helix Trends Biochem Sci 28, 655–662

2 Blatch GL & Lassle M (1999) The tetratricopeptide

repeat: a structural motif mediating protein–protein

interactions Bioessays 21, 932–939

3 Main ERG, Xiong Y, Cocco MJ, D’Andrea L & Regan

L (2003) Design of stable alpha-helical arrays from an

idealized TPR motif Structure 11, 497–508

4 Cortajarena AL & Regan L (2006) Ligand binding by

TPR domains Prot Sci 15, 1193–1198

5 Cortajarena AL, Kajander T, Pan W, Cocco MJ &

Regan L (2004) Protein design to understand peptide

ligand recognition by tetratricopeptide repeat proteins

Protein Eng Des Sel 17, 399–409

6 Cortajarena AL, Yi F & Regan L (2008) Designed TPR

modules as novel anticancer agents ACS Chem Biol 3,

161–166

7 Kajander T, Cortajarena AL, Mochrie SG & Regan L

(2007) Structure and stability of a consensus TPR

superhelix Acta Crystallogr D 63, 800–811

8 Jinek M, Rehwinkel J, Lazarus BD, Izaurralde E,

Hanover JA & Conti E (2004) The superhelical

TPR-repeat domain of O-linked GlcNAc transferase exhibits

structural similarities to importin alpha Nat Struct Mol

Biol 11, 1001–1007

9 Scheufler C, Brinker A, Bourenkov G, Pegoraro S,

Mo-roder L, Bartunik H, Hartl FU & Moarefi I (2000)

Structure of TPR domain–peptide complexes: critical

elements in the assembly of the Hsp70–Hsp90

multi-chaperone machine Cell 101, 199–210

10 Wallace AC, Laskowski RA & Thornton JM (1995)

LIGPLOT: a program to generate schematic diagrams

of protein–ligand interactions Protein Eng 8, 127–134

11 Fraczkiewicz R & Braun W (1998) Exact and efficient

analytical calculation of the accessible surface area and

their gradient for macromolecules J Comput Chem 19,

319–333

12 Kajander T, Cortajarena AL & Regan L (2006)

Consensus design as a tool for engineering repeat

proteins Methods Mol Biol 340, 151–170

13 Pace CN, Vajdos F, Fee L, Grimsley G & Gray T (1995) How to measure and predict the molar absorp-tion coefficient of a protein Prot Sci 4, 2411–2423

14 Luft JR, Collins RJ, Fehrman NA, Lauricella AM, Veatch CK & DeTitta GT (2003) A deliberate approach to screening for initial crystallization condi-tions of biological macromolecules J Struct Biol 142, 170–179

15 Otwinowski Z & Minor W (1997) Processing of X-ray diffraction data collected in oscillation mode Methods Enzymol 276, 307–326

16 Vagin AA & Teplyakov A (1997) MOLREP: an auto-mated program for molecular replacement J Appl Crys-tallogr 30, 1022–1025

17 Collaborative Computational Project, Number 4 (1994) The CCP4 suite: programs for protein crystal-lography Acta Crystallogr D 50, 760–763

18 Bru¨nger AT, Adams PD, Clore GM, DeLano WL, Gros P, Grosse-Kunstleve RW, Jiang JS, Kuszewski J, Nilges M, Pannu NS et al (1998) Crystallography & NMR system: a new software suite for macromolecular structure determination Acta Crystallogr D 54, 905–921

19 Murshudov G, Vagin A & Dodson E (1997) Refinement

of macromolecular structures by the maximum-likeli-hood method Acta Crystallogr D 53, 240–255

20 Winn M, Isupov M & Murshudov GN (2001) Use of TLS parameters to model anisotropic displacements in macromolecular refinement Acta Crystallogr D 57, 122–133

21 Emsley P & Cowtan K (2004) Coot: model-building tools for molecular graphics Acta Crystallogr D 60, 2126–2132

22 Lovell SC, Davis IW, Arendall WBI, de Bakker PIW, Word JM, Prisant MG, Richardson JS & Richardson

DC (2003) Structure validation by C-alpha geometry: phi, psi, and C-beta deviation Protein Struct Funct Genet 50, 437–450