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Crystal structure of the collagen triple helix model [(Pro-Pro-Gly)₁₀]₃

¹ Centro di Studio di Biocristallografia, CNR, I-80134 Napoli, Italy
² Dipartimento di Chimica, Università degli Studi di Napoli "Federico II", I-80126, Napoli, Italy
³ Dipartimento di Chimica Biologica, Università degli Studi di Napoli "Federico II", I-80134, Napoli, Italy
⁴ CEINGE, Biotecnologie avanzate Scarl, Napoli, Italy.

Reprint requests to: Prof. Adriana Zagari, Centro di Studio di Biocristallografia, CNR, Via Mezzocannone 6, I-80134, Napoli, Italy; e-mail: zagari{at}chemistry.unina.it; fax: (39) 081-2536-603.

(RECEIVED August 9, 2001; FINAL REVISION October 19, 2001; ACCEPTED October 31, 2001)

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.32602

	Abstract

TOP Abstract Introduction Results and Discussion Conclusions Materials and methods References

 
The first report of the full-length structure of the collagen-like polypeptide [(Pro-Pro-Gly)₁₀]₃ is given. This structure was obtained from crystals grown in a microgravity environment, which diffracted up to 1.3 Å, using synchrotron radiation. The final model, which was refined to an R_factor of 0.18, is the highest-resolution description of a collagen triple helix reported to date. This structure provides clues regarding a series of aspects related to collagen triple helix structure and assembly. The strict dependence of proline puckering on the position inside the Pro-Pro-Gly triplets and the correlation between backbone and side chain dihedral angles support the propensity-based mechanism of triple helix stabilization/destabilization induced by hydroxyproline. Furthermore, the analysis of [(Pro-Pro-Gly)₁₀]₃ packing, which is governed by electrostatic interactions, suggests that charges may act as locking features in the axial organization of triple helices in the collagen fibrils.

Keywords: Collagen; protein structure stability; X-ray structure; triple helix; proline

Abbreviations: PPG, average model of [(Pro-Pro-Gly)10]3 determined in the subcell approximation • GlyAla, polypeptide with sequence (Pro-Hyp-Gly)4-Pro-Hyp-Ala-(Pro-Hyp-Gly)5

	Introduction

TOP Abstract Introduction Results and Discussion Conclusions Materials and methods References

 
In structural studies of collagen model compounds, the (Pro-Pro-Gly)n sequence is certainly the first and most widely investigated, since the X and Y positions of the collagen consensus X-Y-Gly sequence are frequently occupied by imino acids. A first structural analysis of the polypeptide poly(Pro-Pro-Gly) was reported by Yonath and Traub (1969). The poly(Pro-Pro-Gly) fiber diffraction pattern was clearly reminiscent of that observed for collagen, though showing a significantly higher definition. The model obtained exhibited the basic characteristics of the previously proposed collagen II model (Rich and Crick 1961), and for several years it was considered the best available model for the collagen triple helix. As for natural collagen, a model consisted of three left-handed polyproline II-like chains wrapped around a common axis. Gly residues are required at every third residue (X-Y-Gly) as the close packing of the chains near the central axis does not leave room for larger residues. Furthermore, backbone N atoms of Gly residues are involved in interchain hydrogen bonds with the carbonyl groups of residues located in the X positions.

Fiber diffraction studies were followed by a long series of theoretical works on both the Pro-Pro-Gly (Miller and Scheraga 1976; Némethy et al. 1992) and Pro-Hyp-Gly models (Miller et al. 1980). Additional structural information was provided by a low-resolution single-crystal X-ray study on the polypeptide model (Pro-Pro-Gly)₁₀ (Okuyama et al. 1981). In particular, this polypeptide exhibited significant differences in the triple helical parameters from the Rich and Crick model of real collagen (Rich and Crick 1961). These differences, which led to a 7₂ as opposed to 10₃ triple helical symmetry (Rich and Crick 1961), initiated a debate regarding the actual symmetry of natural collagen (Okuyama et al. 1977; Kramer et al. 1999; Okuyama et al. 1999). Over the years, (Pro-Pro-Gly)₁₀ has been regarded as the reference structure for the study of the influence of pyrrolidine ring substituents on triple helix stability and structure. For example, it has been observed that hydroxylation of prolines in the Y position leads to a stabilization of the triple helix, whereas in the X position it strongly destabilizes (Fields and Prockop 1996; Inouye et al. 1982).

In the last decade, a variety of new polypeptide models have been synthesized and characterized, and they have shed light on important features related to collagen structure and stability. The use of specifically designed `host–guest' peptides has provided a reliable scale of triple helical propensities of the various amino acids (Persikov et al. 2000). X-ray studies carried out on the host-guest polypeptide with sequence (Pro-Hyp-Gly)₄-Pro-Hyp-Ala-(Pro-Hyp-Gly)₅, named GlyAla, have shown the structural effects of a disease causative mutation (Bella et al. 1994,1995). Furthermore, the study of fluorinated proline derivatives has indicated that inductive effects may play a role in collagen triple helix stability (Holmgren et al. 1998).

Although a large number of polypeptides have been studied to date, the interest in [(Pro-Pro-Gly)₁₀]₃ is still high, as demonstrated by several recent investigations (Kramer et al. 1998; Nagarajan et al. 1998; Vitagliano et al. 2001a). However, all of the structural models produced were obtained as approximate average structures, by using only a specific class of reflections which characterized a subcell of the [(Pro-Pro-Gly)₁₀]₃ crystals. Herein is the first report of the full-length structure of [(Pro-Pro-Gly)₁₀]₃, which was obtained using synchrotron radiation on crystals grown in microgravity conditions. Several conclusions have been extracted from the analysis of the structure, and their possible biological implications are discussed.

	Results and Discussion

TOP Abstract Introduction Results and Discussion Conclusions Materials and methods References

 
Overall description of the structure
The structure of [(Pro-Pro-Gly)₁₀]₃ was solved and refined at 1.3 Å by combining the use of improved quality crystals, grown in microgravity conditions (Berisio et al. 2000), and synchrotron radiation. The model obtained was refined to an R_factor of 0.181 (0.164 for F > 4) and an R_free of 0.297 (0.261 for F > 4). Unlike previous studies, which described only an average model (Kramer et al. 1998; Nagarajan et al. 1998; Vitagliano et al. 2001a), the first full-length structure of [(Pro-Pro-Gly)₁₀]₃ is here reported. A description of the relationship between the present structure and the average one is given in Figure 1A,B.

View larger version (103K): [in this window] [in a new window]   Fig. 1. (A) Organization of the [(Pro-Pro-Gly)10]3 triple helices in the ac plane. Chains are colored with a ramping code from blue (N-termini) to red (C-termini). The two molecules in the asymmetric unit are the top-center (molecule 1) and the bottom-center (molecule 2) molecules. (B) Average model obtained in the subcell approximation (Vitagliano et al. 2001a) in the ac` plane. The c` corresponds to a ninth of the full-length c axis. (C) Electron density map (2Fo-Fc), extended to the whole unit cell, contoured at 2.0 . (D) Omit map (Fo-Fc) of a representative triplet contoured at 3.5 .

The structure described here is the highest-resolution description of a collagen triple helix to date and, therefore, it provides a good opportunity to review the main architectural elements of collagen-like triple helices. The examination of , , and backbone dihedral angles shows a regular trend of torsion angles along the peptide sequence with small variations at the triple helix terminations. These parameters, averaged over the two molecules in the asymmetric unit, are very similar to those previously reported using the subcell approximation (Table 1) and indicate a 7₂ triple helix symmetry. On the other hand, they are rather different from those derived for the models of natural collagen (Fraser et al. 1979) and poly(Pro-Pro-Gly) (Yonath and Traub 1969), which both exhibit a 10₃ superhelical symmetry.

Proline angles of [(Pro-Pro-Gly)₁₀]₃ are reported as a function of ₁ in Figure 2. Together with the experimental data derived from the [(Pro-Pro-Gly)₁₀]₃ structure, the figure reports the results of a statistical analysis (Vitagliano et al. 2001b) carried out on all trans proline residues from nonredundant protein chains, belonging to structures refined at a resolution better than 2.0 Å and an R_factor lower than 0.23 (Fig. 2). In accordance with our previous results (Vitagliano et al. 2001a), proline residues from [(Pro-Pro-Gly)₁₀]₃ are allocated in triple helices without significant strain, since backbone angles correlate well with those intrinsically adopted by proline residues in globular proteins. Furthermore, proline rings in the Y positions systematically adopt an up puckering, whereas those in the X position adopt a down puckering. These findings provide statistical support for the `propensity-based' mechanism for the stabilization of the collagen triple helix induced by the presence of Hyp in the Y position and its destabilization when Hyp is in the X position (Vitagliano et al. 2001a,b). Such a model, which is based on both the strict correlation between main and side chain dihedral angles in imino acids and on the observation that the hydroxyl group of Hyp induces an up puckering, has also been very recently confirmed by theoretical calculations (Improta et al. 2001).

View larger version (46K): [in this window] [in a new window]   Fig. 2. Values of versus 1 for proline rings in X (•) and Y () positions in [(Pro-Pro-Gly)10]3 and derived from a statistical survey on trans proline rings in protein structures () (Vitagliano et al. 2001b).

View larger version (44K): [in this window] [in a new window]   Fig. 3. Distribution of water molecules as a function of their distance from the nearest protein atom.

Solvent accessibility of Pro residues in the Pro-Pro-Gly triplets was evaluated by averaging side chain accessibility over all proline rings in the X and Y positions. Results show that the side chain accessibility per atom is similar in the X and Y positions, with average values of 22.1 ± 7.5 Ų and 25.2 ± 9.7 Ų, respectively. However, each of the atom types of the proline side chains exhibits significantly different accessibility in the X and Y positions. In particular, the C^ß atoms are much more exposed in the X positions. This finding is in accordance with the previous studies showing that the X position is generally more exposed for residues different than Pro (Jones and Miller 1991) and that mutations of nonimino acidic residues in the X position have relatively little effect on triple helix stability (Ramshaw et al. 1998). On the other hand, both C and C atoms are more accessible in Y positions (Fig. 4A,B). Indeed, C and C atoms of the down Pro rings in the X positions are partially buried by the up Pro rings in the Y positions belonging to the neighboring staggered single chain. It is worth noting that the occurrence of down and up puckerings, in X and Y positions respectively, maximizes the hydrophobic interactions between proline residues in adjacent chains.

View larger version (88K): [in this window] [in a new window]   Fig. 4. Solvent accessibility, averaged over the two molecules in the asymmetric unit, of the Pro side chain atoms in X positions(A) and Y positions (B).

The charged layers through the crystal are characterized by a scattered electrostatic potential surface (Fig. 5A). Each of the triple helices is five-coordinated and surrounded by one parallel and four antiparallel helices. Alternatively, each couple of helices is surrounded by four couples with opposite-sign electrostatic potential. Packing of layers on top of each other generates a three-dimensional lattice of charges.

View larger version (267K): [in this window] [in a new window]   Fig. 5. Lateral packing: (A) Electrostatic potential surface of a charged layer. The color code is blue for positive and red for negative electrostatic potential. (B) Pseudotetragonal packing of the triple helices. The triple helices shown in red are directed upward from the paper, whereas those shown in blue are directed downward from the paper.

The structural findings found in the full-length [(Pro-Pro-Gly)₁₀]₃ structure led us to a series of considerations regarding triple helix assembly. The structure here presented, together with that of GlyAla (Bella et al. 1994), is charged at the terminal ends. We recently crystallized and solved the X-ray structure of the collagen model [(Pro-Hyp-Gly)₁₀]₃ (R. Berisio, L. Vitagliano, L. Mazzarella, and A. Zagari, unpubl.), which is also charged. It is worth noting that all of these three structures form double layers of charges, generated by the triple helix ends. Furthermore, in the case of the polypeptide with sequence (Pro-Hyp-Gly)₄-Glu-Lys-Gly-(Pro-Hyp-Gly)₅, which has also charged residues in the center, triple helices are not in the axial register (Kramer et al. 2000). However, their axial stagger occurs in correspondence with the charged Lys and Glu residues. Therefore, in all of these cases, charges act as locking features in the triple helix axial stagger.

	Conclusions

TOP Abstract Introduction Results and Discussion Conclusions Materials and methods References

 
[(Pro-Pro-Gly)₁₀]₃ has been the object of pioneering studies on collagen-like systems, as it was the first to be synthesized and crystallized. Since then, several X-ray determinations of its structure have been performed over the past nearly 30 years. However, only an approximate X-ray structure, obtained using only the reflections characterizing a subcell with a 20 Å repeat along the c axis, has thus far been reported. Indeed, most of the other reflections were very weak and could hardly be recorded. The difficulty in registering the weak reflections was attributed to a fiberlike disorder of the crystals, due to the high level of symmetry of the triple helix. Such difficulty led to an incorrect determination of the unit cell parameters and, consequently, did not allow the determination of the full-length structure. Therefore, the structure presented here is the first crystallographic view of a regular collagen-like model system.

Analysis of the proline puckering supports the `propensity-based' model for collagen triple helix stabilization by Hyp (Vitagliano et al. 2001a). Indeed, such a model suggests that, due to inductive effects generated by the hydroxyl group (Holmgren et al. 1999; Vitagliano et al. 2001a), Hyp has main chain dihedral angles which are suitable only for the Y position in the triple helix. As such, imino acid propensities also allow the explanation of the destabilization induced by Hyp in the X position (Vitagliano et al. 2001a). Furthermore, they account for the observed shift of the cis/trans equilibrium observed in Hyp, compared to Pro (Bretscher et al. 2001; Vitagliano et al. 2001b). The present high-resolution structure confirms that triple helices are highly hydrated in the crystal state (Bella et al. 1995; Kramer et al. 1998; Berisio et al. 2001), although the role of water molecules in the stabilization of the collagen triple helix has been questioned (Holmgren et al. 1999; Nagarajan et al. 1999).

The comparison of crystal packing of [(Pro-Pro-Gly)₁₀]₃ with that of the other known collagen-like polypeptide structures has highlighted the importance of charges in the axial registration of collagen-like triple helices. This finding may be extended to natural collagen and supports the idea (Kramer et al. 2000) that charges may play a fundamental role in axial registration of triple helices in the collagen fibrils. It should also be mentioned that all Hyp-containing structures known to date form direct hydrogen bonding interactions between Hyp hydroxyl groups of adjacent triple helices (Kramer et al. 2000,2001; Berisio et al. 2001), except for the structure of GlyAla (Bella et al. 1994). In this case, the lack of direct intermolecular hydrogen bonding interactions may be attributed to the loss of the axial triple helix repetition, which is due to the existence of a bulge in the center of the molecule (Bella et al. 1994). These findings suggest that Hyp–Hyp interactions may play a role in lateral assembly of triple helices in the fibrils. It may be concluded that charge–charge and Hyp–Hyp interactions can be regarded as two codes for three-dimensional aggregation of triple helices in collagen fibrils.

	Materials and methods

TOP Abstract Introduction Results and Discussion Conclusions Materials and methods References

 
Crystallization and data collection
Crystals of [(Pro-Pro-Gly)₁₀]₃ were grown in microgravity conditions, using the dialysis technique, with a final polypeptide concentration of 5.0 mg mL^-1 in 0.05 M acetic acid, 0.22 M sodium acetate, and 10%(v/v) PEG 400 (Berisio et al. 2000). Such crystals, which belong to the P2₁2₁2₁ space group, were significantly better diffracting than those grown on Earth (Berisio et al. 2000). Diffraction data were collected at 1.3 Å using synchrotron radiation at Elettra, Trieste, Italy. The diffraction pattern was characterized by very strong and very weak reflections. Indexing of only the strongest reflections was consistent with a subcell with axes a` = 26.9, b` = 26.3, c` = 20.3 Å, in accordance with previous results (Okuyama et al. 1981; Kramer et al. 1998; Nagarajan et al. 1998). Furthermore, the whole diffraction pattern was characterized by unit cell parameters a = 26.9, b = 26.4, c = 182.5 Å, with a much larger c axis than previously believed. Indeed, in all previous studies, conducted on crystals obtained under similar conditions, only a small fraction of weak reflections was measured. These reflections were tentatively indexed with a c axis of about 100 Å (Okuyama et al. 1981; Kramer et al. 1998; Nagarajan et al. 1998).

With the new cell axes, the strong reflections defining the subcell correspond to the reflections with indexes l = 9n, with n integer. As we showed previously (Berisio et al. 2000), reflections have markedly different intensities depending on the l index: besides those with l = 9n, reflections with l = 9n + 2 are the strongest, followed by those with l = 9n + 4 and l = 9n + 7. The presence of these sharp spots made the indexing unambiguous (Berisio et al. 2000). Statistics of data processing, carried out using the HKL package (Otwinowsky and Minor 1997), are shown in Table 2. A full report of the crystallization procedure and data quality has been published (Berisio et al. 2000).

The model obtained from ARP/wARP contained only Ser and Gly residues. As indicated by the electron density maps, Ser residues were mutated to Pro using the program O (Jones et al. 1991). The resulting model, which consisted of 153 residues, was refined using SHELX-L in a restrained mode (Sheldrick and Schneider 1997). R_free, calculated on 5% of the total number of reflections, was used throughout the refinement procedure. Potential water sites were identified using an automated water divining procedure, implemented in SHELX-L. Modeling of these sites was carried out after inspection of omit (Fo-Fc) electron density maps and was monitored using R_free. All of the missing terminal residues except the C-terminal glycines were built by alternating omit map calculations and manual building to SHELX-L refinement cycles. Although displaying higher atomic displacement factors, N-terminal Pro residues were substantially ordered. In contrast, for each of the two molecules in the asymmetric unit, C-terminal glycine residues display electron density only at the N atom of the two chains involved in interchain hydrogen bonds. On the other hand, no electron density is visible for the C-terminal glycines of the two most staggered chains (see inset in Fig. 6), for which interchain hydrogen bonds cannot be formed. Once the main features of the structure were modeled, an anisotropic treatment of the atomic displacement parameters was adopted. Introduction of anisotropy resulted in a decrease in R_factor and R_free of 0.05 and 0.03, respectively. During the anisotropic refinement, weak similarity restraints were applied to the corresponding U_ij components of atoms which were close in space (Table 2). The solvent water molecules were restrained to be approximately isotropic. All of the weights used for the restraints were monitored using R_free. The refinement converged with R_factor, calculated for all 21,970 positive reflections of 0.181 and R_free of 0.297. These values of R_factor and R_free are higher than normally observed at this resolution. This is most likely determined by the large proportion of weak reflections (41.6% of the whole set of reflections with I/(I) < 2), which is due to the extensive noncrystallographic symmetry. Since the diffraction pattern was characterized by very bright and very weak reflections, an R_factor for each of the nine reflection classes with a different l index was calculated (Table 3). The values of R_factor confirm the correctness of the final model. Indeed, among the reflections which were not used in the subcell approximation (reflection index l 9n), the classes with l = 9n + 2 and l = 9n + 4 have an R_factor comparable with that having l = 9n. Namely, as expected for well refined structures, R_factor depends mainly on reflection intensities rather than on the specific class to which the reflections belong. Indeed, higher R_factor values correspond to reflections characterized by lower intensities (Table 3).

View larger version (49K): [in this window] [in a new window]   Fig. 6. Average main chain e.s.d. values versus residue number for the three chains of molecule 1 (A) and molecule 2 (B) in the asymmetric unit. The insets show the stagger of the three chains in each triple helix.

View this table: [in this window] [in a new window]   Table 3. Distribution of <I/(I)> and Rfactor in the nine reflection classes

The pictures were generated using the programs MOLSCRIPT (Kraulis 1991), BOBSCRIPT (Esnouf 1999), O (Jones et al. 1991), GRASP (Nicholls et al. 1991), and RASTER3D (Merritt and Bacon 1997). Coordinates were deposited with the Protein Data Bank (Berman et al. 2000), code 1k6f.

	Acknowledgments

 
We acknowledge EMBL/DESY, Sincrotrone Trieste Spa/Elettra, and CNR/Elettra for beam time and support. We thank Mr. Luca De Luca and Mr. Giosué Sorrentino for technical assistance, Dr. L. Carotenuto (MARS) for discussions, and Dr. Antonello Mastrangelo for his help with the computations. This work was financially supported by the Agenzia Spaziale Italiana (ASI).

The publication costs of this article were defrayed in part by payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 USC section 1734 solely to indicate this fact.

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