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Structural Basis for Hijacking of Cellular LxxLL Motifs by Papillomavirus E6 Oncoproteins

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Science  08 Feb 2013:
Vol. 339, Issue 6120, pp. 694-698
DOI: 10.1126/science.1229934

Abstract

E6 viral oncoproteins are key players in epithelial tumors induced by papillomaviruses in vertebrates, including cervical cancer in humans. E6 proteins target many host proteins by specifically interacting with acidic LxxLL motifs. We solved the crystal structures of bovine (BPV1) and human (HPV16) papillomavirus E6 proteins bound to LxxLL peptides from the focal adhesion protein paxillin and the ubiquitin ligase E6AP, respectively. In both E6 proteins, two zinc domains and a linker helix form a basic-hydrophobic pocket, which captures helical LxxLL motifs in a way compatible with other interaction modes. Mutational inactivation of the LxxLL binding pocket disrupts the oncogenic activities of both E6 proteins. This work reveals the structural basis of both the multifunctionality and the oncogenicity of E6 proteins.

Papillomaviruses (PV) infect the epithelia of vertebrates. More than 200 PV types have been identified (1), among which a subset is tumorigenic. Cervical cancers are caused by "high-risk" mucosal human PVs (hrm-HPVs), of which HPV16 is the most prevalent and best studied type (2), whereas some skin cancers have been associated with "high-risk" cutaneous HPVs (3). Bovine papillomavirus 1 (BPV1) also induces tumors in its natural host (cattle) and in horses (4).

PV carcinogenesis is primarily linked to two PV oncoproteins, E6 and E7. Hrm-HPV E6 recruits the ubiquitin ligase E6AP (5) and tumor suppressor p53, leading to ubiquitin-mediated degradation of p53 (6). E6 also interacts with many other cellular proteins related to cancer pathways (7, 8). Mucosal and cutaneous HPV E6 oncoproteins recognize some of their target proteins, including E6AP, interferon regulatory factor–3 (IRF-3) (9), and the notch co-activator MAML1 (8, 10, 11) through acidic leucine (L)–rich motifs containing the LxxLL consensus sequence (where x indicates any amino acid) (12, 13). BPV1 E6 recognizes a particular subclass of acidic LxxLL sequences termed LD motifs, which mediate protein-protein interactions regulating cell motility, cell adhesion, and gene expression (14). BPV1 E6 recognizes several LD motifs of the focal adhesion protein paxillin, and this interaction is required for cellular transformation (1517). Despite their small size (about 150 residues), E6 proteins combine multiple interaction sites. For instance, hrm-HPV E6 interacts not only with LxxLL motifs but also with PDZ domains involved in cell polarity and adhesion (18) and possesses a self-association interface required for the p53 degradation activity (19).

Mammalian PV E6 proteins are cysteine-rich proteins consisting of two zinc-binding domains named E6N and E6C. Whereas structures of isolated E6N and E6C domains have been determined (19, 20), full-length E6 proteins undergo self-oligomerization (21), which has precluded structural analysis.

To circumvent this problem, we applied two solubilizing strategies to the BPV1 and the HPV16 E6 proteins (22). For BPV1 E6, we fused a crystallization-prone mutant of the bacterial maltose binding protein (MBP) to an E6-binding LxxLL sequence present in the paxillin LD1 motif that is known to solubilize E6 (23) and then to the BPV1 E6 protein (fig. S1A). The resulting MBP-LxxLL-E6 triple fusion protein was purified as a soluble monomer and yielded crystals that diffracted at a resolution better than 2.3 Å (table S1). For HPV16 E6, we purified the monomeric E6 F47R 4C/4S (24) mutant that combines the F47→R47 (F47R) mutation disrupting E6N dimerization and four mutations at nonconserved cysteines preventing disulfide-mediated aggregation (19). Purified E6 F47R 4C/4S was mixed with equimolar amounts of an MBP-LxxLL fusion containing the E6-binding LxxLL sequence of E6AP (fig. S1B). The complex yielded crystals that diffracted at a resolution better than 2.6 Å (table S1). Both structures were solved by molecular replacement using the known structure of MBP as a template (Fig. 1 and fig. S2).

Fig. 1

X-ray structures of E6/LxxLL complexes. (A) The structure of BPV1 E6 bound to residues 1 to 10 of paxillin (left) and that of HPV16 E6 bound to residues 403 to 414 of E6AP (right). Blue indicates E6N; gray, linker helix; gold, E6C; and cyan or green, LxxLL peptides. (B) The hydrophobic pocket (pink) responsible for LxxLL motif recognition in BPV1 E6 (left) and HPV16 E6 (right). These structures show helical LxxLL peptides inserted in a deep pocket formed by the two domains, unlike other cellular domains (FAT, CH, and LBD) interacting through shallow surfaces with the cognate LxxLL peptides (fig. S5B).

The overall structures of the two E6/LxxLL complexes are very similar (fig. S3A) despite low sequence identity (30%), suggesting that crystallization-promoting strategies did not introduce artifacts. Indeed, MBP is differently positioned relative to E6 in the two crystals (fig. S2), and the five solubilizing mutations of E6 F47R 4C/4S are distal from the E6-peptide interface (fig. S3C).

In both LxxLL-bound E6 proteins, the two zinc-binding domains are joined by a linker helix (Fig. 1 and fig. S4). Although the BPV1 and HPV16 E6C domains have a similar fold, the two E6N domains have structurally resolved regions that are essentially superposable but differ in their N-terminal regions (fig. S3B and S4). E6 sequence alignments (fig. S9) show that BPV E6N lacks an N-terminal extension found in HPV E6N. In addition, the first 10 residues of BPV1 E6N are not visible in the electron density map.

The E6-bound LxxLL motifs of both paxillin (M1D2D3L4D5A6L7L8A9D10) and E6AP (E1L2T3L4Q5E6L7L8G9E10E11R12) (24) adopt a α-helical conformation from residues one to eight (Figs. 1 and 2). Both motifs are inserted within a deep pocket formed by the two zinc-binding domains and the linker helix of E6 (Fig. 1, A and B). By contrast, previously solved complexes of cellular FAT, CH, and LBD domains bound to LxxLL motifs (2527) all showed the helical motif interacting with a shallow surface of the domain (fig. S5A).

Fig. 2

Networks of E6/LxxLL peptide interactions. (A) Polar interactions between BPV1 E6 and paxillin. Red spheres, water molecules; black dashed lines, interactions mediated by keystone R89; blue or orange dashed lines, intermolecular interactions mediated by E6N or E6C arginines, respectively; and dotted lines, other polar interactions. (B) All contacts between BPV1 E6 and paxillin. Pink dashed lines, hydrophobic contacts; black lines, polar contacts mediated by side chain (continuous lines) or main chain (dotted lines); and pink or blue boxed residues, E6 hydrophobic or polar contributors, respectively. E6 polar residues displaying favorable van der Waals terms (energy change < –1 kcal/mol, fig. S6A) are included as hydrophobic contributors. (C) Polar interactions between HPV16 E6 and E6AP. (D) All contacts between HPV16 E6 and E6AP. R129-E1 (dashed gray line) is revealed by MD simulations (fig. S7). Note that the polar contacts of E6AP E1 are substituted by hydrophobic contacts for paxillin M1 (fig. S7C).

The three leucine residues (L4, L7, and L8) of the motif are accommodated within a hydrophobic cavity mostly contributed by the E6N domain and linker helix (Figs. 1B and 2, B and D, and fig. S9). Point mutations altering hydrophobic residues of the cavity (i.e., F37S and L58S in BPV1 E6, and L50E in HPV16 E6) decrease both LxxLL peptide binding and E6 transformation (BPV1 E6/paxillin) or p53 degradation (HPV16 E6/E6AP) activities (Fig. 3 and fig. S8A).

Fig. 3

LxxLL binding and functional activities of E6 mutants. (A) Yeast two-hybrid analysis of BPV1 E6 (left) and HPV16 E6 (right) mutants binding to paxillin (full-length or LD1 peptide) and E6AP peptide, respectively. PTPN3 (targeting the PDZ binding motif) is included as control of HPV16 E6 expression. (B) Precipitation assays of BPV1 E6 (left) and HPV16 E6 (right) mutants binding to glutathione S-transferase–fused LxxLL peptides. The data (mean ± SD) were normalized to 100% for the reference protein. Asterisks indicate previously investigated mutants (15, 34, 35). HPV16 E6 mutations were introduced in the E6 4C/4S construct. (C) Oncogenic activities of E6 mutants. The data (mean ± SD) were normalized to 100% for the reference protein. (Left) Transformation phenotypes of BPV1 E6 mutants, quantified by using numbers of anchorage-independent colonies. (Right) p53 degradation activities of HPV16 E6 mutants. See also fig. S8.

Surrounding the hydrophobic cavity, a positively charged surface (fig. S5B), favorable to the acidic moieties of the peptide, includes a number of arginine residues that play specific roles in the architecture of the complex. The side chain of a strictly conserved arginine (R89 in BPV1 and R102 in HPV16) holds together, like a keystone, the E6C domain, the E6N domain and the peptide by interacting with L8 of the peptide and with main chain atoms at the C termini of both E6N α1 helix and the peptide's helix (Fig. 2). Adjacent to R89 and R102, BPV1 R121 and HPV16 R131 provide structurally equivalent contacts to backbone and side-chain moieties of the peptide (Fig. 2). Free-energy decomposition analysis (28) coupled to prior molecular dynamics (MD) simulations of the complexes revealed favorable van der Waals terms for BPV1 E6 R89 and R121 and for HPV16 E6 R102 and R131 (fig. S6) that are consistent with their multiple interactions at the complex interface. Mutagenesis of all these arginine residues markedly decreased peptide binding and biological activities of the two E6 proteins (Fig. 3 and fig. S8).

A number of peripheral E6 arginine side chains selectively clamp acidic and/or polar side chains of the LxxLL peptide (Fig. 2). In BPV1 E6, R42 and R116 interact with D3 and D5, respectively (Fig. 2A). In HPV16 E6, R55 (equivalent to BPV1 R42) interacts with T3 and E6. R129 (equivalent to BPV1 R116) displays conformational disorder in the crystal (fig. S6A), where it is oriented away from the peptide toward MBP (Fig. 2C and fig. S7A). However, upon MD simulation of the E6/E6AP complex devoid of MBP, the side chain of R129 readily reorients to form a direct interaction with residue E1 of the E6AP peptide (fig. S7, B and C). In HPV16 E6, R10 at the N terminus of E6N forms an additional ion bridge with E11 of the C terminus of the target peptide (Fig. 2, C and D). Alanine mutagenesis of these peripheral arginine residues had little or no influence on peptide binding or the tested biological activities, with the exception of BPV1 R116, whose mutation markedly decreased paxillin binding and cellular transformation (Fig. 3 and fig. S8). Indeed, the side chain of R116 is involved in a network of direct or water-mediated polar interactions at the E6C-peptide interface and in cation-π stacking with the aromatic side chain of W65 (Fig. 2A and fig. S7C). This environment appears to strongly stabilize the R116-D5 salt bridge, as confirmed by the high electrostatic free-energy term displayed by both R116 and D5 (fig. S6A).

A salient difference between the two structures concerns the mode of recognition of the N terminus of the bound peptide, which is exclusively hydrophobic for paxillin and purely electrostatic for E6AP (fig. S6). Indeed, in the BPV1 E6/paxillin complex, M1 of paxillin interacts with a hydrophobic patch at the C terminus of the linker helix constituted by W65 and L64 (fig. S7C). In HPV16 E6, E6 residues L64 and W65 are substituted by basic residues R77 and H78, which together with R129 form a favorable electrostatic environment for the interaction with E1 of the E6AP peptide (Fig. 2C and fig. S7C).

Many cellular functions are mediated by short linear interaction motifs (SLIMs), whose simple and redundant sequences constitute an Achille's heel for viral attack (29). Whereas viral proteins very often contain mimics of cellular SLIMs (29), E6 has an original fold that captures cellular acidic LxxLL motifs. In contrast to cellular proteins, which recruit LxxLL motifs on shallow surfaces of globular helical domains (fig. S5), E6 captures these motifs within a binding pocket composed of three structural modules (Fig. 1). LxxLL-contacting residues are located at equivalent positions in BPV1 and HPV16 E6 sequences, and these positions are generally conserved (fig. S9), suggesting that all mammalian PV E6 proteins contain a LxxLL-binding pocket. Furthermore, BPV1 and HPV16 E6 mutants disrupted for LxxLL-motif binding systematically lost transformation and degradation activities (Fig. 3), indicating that the conserved LxxLL-binding pocket is essential for the tumorigenic phenotype of E6 proteins. This pocket thus represents a promising target for therapeutic drugs.

E6 peptide-contacting residues play distinct roles. Hydrophobic pocket residues, as well as the "keystone" arginines R89 and R102, only establish contacts with the invariable leucine side chains of the motif and/or sequence-independent contacts with the peptide backbone. Other E6 residues function as "readers," which discriminate variations of the LxxLL motif through sequence-dependent contacts to variable side chains of the peptide. In particular, the nature of residues located at the C terminus of the E6 linker helix or at the N terminus of E6N domain may influence the selection of residues at the N or C terminus of the peptide, respectively. Conversely, some reader residues may tolerate variations in the position of key acidic residues in the LxxLL motif sequence, because equivalent arginine residues in BPV1 E6 and HPV16 E6 can interact with acidic side chains belonging to different turns of the peptide helix (Fig. 2). Such combinations of discriminative and tolerant reading mechanisms should allow different E6 proteins to capture different panels of host proteins bearing variations of the LxxLL motif.

In the absence of target peptide, E6 is likely to adopt a different overall structure, because the few interactions connecting the E6N, linker helix, and E6C modules (fig. S10) are likely to be insufficient to maintain the E6 architecture observed in the complex structures. The propensity for self-association (21) and the strong affinity for target motifs (23, 30, 31) suggest that most E6 molecules preferentially exist as target-bound complexes in infected cells.

The data suggest that different modes of interaction can coexist in one single molecule of E6. The LxxLL binding region, the PDZ domain–binding motif at the extreme C terminus of E6 (32, 33), and the E6N self-association interface required for p53 degradation (19) do not overlap when they are mapped onto the structure of HPV16 E6 (Fig. 4). Solvent-accessible surfaces not involved in these three interactions represent candidate E6 regions for p53 binding. Structural studies of E6 in complex with multiple partners are now required to decipher the mechanisms of E6 oncogenic activities such as the degradation of host target proteins.

Fig. 4

Mapping HPV16 E6 functional regions. The different binding sites of HPV16 E6 map to distinct regions of the protein's solvent-accessible surface. LxxLL binding and E6 self-association residues are colored green and blue, respectively. The position of the second E6 molecule shown in the ribbon representation was modeled on the basis of the geometry of the E6N homodimer interface (2LJY.pdb). The C-terminal PDZ binding motif (pink) is disordered in the nuclear magnetic resonance structure of the isolated HPV16 E6C domain and adopts a β-strand conformation upon binding to the PDZ1 of Magi I (red) (2KPL.pdb). The relative orientation of E6 and the PDZ domain shown is arbitrary. Surfaces colored white are potentially available for binding to p53. See also fig. S9.

Supplementary Materials

www.sciencemag.org/cgi/content/full/339/6120/694/DC1

Materials and Methods

Figs. S1 to S10

Table S1

References (3657)

References and Notes

  1. Materials and methods are available as supplementary materials on Science Online.
  2. Single-letter abbreviations for the amino acid residues are as follows: A, Ala; C, Cys; D, Asp; E, Glu; F, Phe; G, Gly; H, His; I, Ile; K, Lys; L, Leu; M, Met; N, Asn; P, Pro; Q, Gln; R, Arg; S, Ser; T, Thr; V, Val; W, Trp; and Y, Tyr.
  3. Acknowledgments: This work was supported by institutional support from CNRS, Université de Strasbourg, INSERM, the European Commission SPINE2-Complexes project (contract no. LSHG-CT-2006-031220) and grants from Association pour la Recherche contre le Cancer (ARC) (no. 3171), Agence Nationale de la Recherche (ANR-MIME-2007 EPI-HPV-3D), and NIH (grant R01CA134737). S.C. was supported by ANR, A.o.M.o.S. by ARC, and K.o.B. by College Doctoral Européen. S.V.P., N.B., and T.A. were supported by NIH grants (CA120352, CA134737 and CA08093) to S.V.P. and institutional support from the University of Virginia. S.C., K.o.B., and M.G.F. were supported by NIH grant CA134737. MD calculations were performed at the Mèso-Centre of the University of Strasbourg. The authors thank members of the European Synchrotron Radiation Facility–European Molecular Biology Laboratory joint Structural Biology groups for the use of beamline facilities and for help during data collection; members of the IGBMC common services for assistance; and B. Kieffer, A. Dejaegere, and all members of the Oncoproteins team for helpful discussions and advice. Coordinates and structure factors have been deposited at the Protein Data Bank with accession codes 3PY7 and 4GIZ. K.Z., S.C., N.B., A.o.M.o.S., T.A., K.o.B., I.M., A.G.McE., P.P.-c., V.C., and S.V.P. performed experiments; M.G.F. and R.H.S. performed computational analysis; and J.C. and A.G.McE. performed structure determination. S.C., K.Z., J.C., S.V.P., and G.T. analyzed the data. G.T., K.Z., S.C., S.V.P., J.C., and R.S. prepared the manuscript. G.T., S.V.P., J.C., and R.S. supervised the work.
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