Using sequence data to predict the self-assembly of supramolecular collagen structures

Collagen fibrils are the major constituents of the extracellular matrix, which provides structural support to vertebrate connective tissues. It is widely assumed that the superstructure of collagen fibrils is encoded in the primary sequences of the molecular building blocks. However, the interplay between large-scale architecture and small-scale molecular interactions makes the ab initio prediction of collagen structure challenging. Here, we propose a model that allows us to predict the periodic structure of collagen fibers and the axial offset between the molecules, purely on the basis of simple predictive rules for the interaction between amino acid residues. With our model, we identify the sequence-dependent collagen fiber geometries with the lowest free energy and validate the predicted geometries against the available experimental data. We propose a procedure for searching for optimal staggering distances. Finally, we build a classification algorithm and use it to scan 11 data sets of vertebrate fibrillar collagens, and predict the periodicity of the resulting assemblies. We analyzed the experimentally observed variance of the optimal stagger distances across species, and find that these distances, and the resulting fibrillar phenotypes, are evolutionary well preserved. Moreover, we observed that the energy minimum at the optimal stagger distance is broad in all cases, suggesting a further evolutionary adaptation designed to improve the assembly kinetics. Our periodicity predictions are not only in good agreement with the experimental data on collagen molecular staggering for all collagen types analyzed, but also for synthetic peptides. We argue that, with our model, it becomes possible to design tailor-made, periodic collagen structures, thereby enabling the design of novel biomimetic materials based on collagen-mimetic trimers.     

The staining pattern of collagen fibrils. Improved correlation with sequence data.

The periodic banding pattern of stained collagen fibrils observed in the electron microscopic can be correlated with the charge distribution deduced from the amino acid sequence. Earlier work used alpha 1 chain sequence data only. The present study incorporates alpha 2 as well as alpha 1 sequence data, so that the complete distribution of charged residues is used. Correlation is improved if it is supposed that the extrahelical terminal regions are contracted. The optimal value of the periodicity, D, (previously 232.3 +/- 0.5 residues using alpha 1 data only), is now 234.2 +/- 0.5 residues, assuming uniform spacing of residues in the helical body of the molecule. This value agrees better with values obtained by others from analyses of interactions between molecules, using sequence data alone. Using the improved value of D, the relative axial locations of the charged residues in the fibril are displayed. In this way, the charged residues contributing to each band in the fibril staining pattern can be identified.     

Information contained in the amino acid sequence of theα1(I)-chain of collagen and its consequences upon the formation of the triple helix,of fibrils and crosslinks

The molecule of type I collagen from skin consists of two alpha1(I)-chains and one alpha2-chain. The sequence of the entire alpha1-chain comprising 1052 residues is summarily presented and discussed. Apart from the 279 residues of alpha1(I)-CB8 whose sequence has been established for rat skin collagen, all sequences have been determined for calf skin collagen. In order to facilitate sequence analysis, the alpha1-chain was cleaved into defined fragments by cyanogen bromide or hydroxylamine or limited collagenase digestion. Most of the sequence was established by automated stepwise Edman degradation. The alpha1-chain contains two basically different types of sequences: the triple helical region of 1011 amino acid residues in which every third position is occupied by glycine and the N- and C-terminal regions not displaying this type of regularity. Both of these non-triple helical regions carry oxidizable lysine or hydroxylysine residues as functional sites for the intermolecular crosslink formation. Implications of the amino acid sequence for the stability of the triple helix and the fibril as well as for formation of crosslinks are discussed. Evaluation of the sequence in connection with electron microscopical investigations yielded the parameters of the axial arrangement of the molecules within the fibrils. Axial stagger of the molecules by a distance D = 670 angstrom = 233 amino acid residues results in maximal interaction of polar sequence regions of adjacent molecules and similarly of regions of hydrophobic residues. Ordered aggregation of molecules into fibrils is, therefore, regulated by electrostatic and electrophobic forces. Possible loci of intermolecular crosslinks between the alpha1-chains of adjacent molecules may be deduced from the dimensions of the axial aggregation of molecules.     

Analysis of the primary structure of collagen for the origins of molecular packing

The amino acid sequence in the triplet region of the α1 chain of collagen was analyzed for complementary relationships that would explain the stagger of multiples of 670 Å between the rod-like molecules in the fibril. The analysis was done by moving the sequence of 1011 amino acids past itself and scoring for complementarity between opposing amino acids allowing a range of ±2 to 3 residues. It was found that interactions between amino acids of opposite charge and between large hydrophobic amino acids in the overlapping region between two chains are maximal when the chains are staggered by 0D, 1D, 2D, 3D and 4D, where D = 234 ± 1 residues. The residue repeat derived from this value is 2.86 ± 0.02 Å. The existence of a D separation between interacting residues was shown to be reflected in the actual distribution of large hydrophobic amino acids. Surprisingly, the distribution approximates the pattern ($\text{2D}\text{11}$)₅($\text{D}\text{11}$) repeated over 4.4D intervals. The regularity may arise from structural constraints imposed by super-coiling. The distribution of charged residues is less regular and does not show a well-defined periodicity. However, positively-charged residues tend to be near negatively-charged residues, allowing intramolecular charge neutralization as well as strong intermolecular charge interactions at 0D.     

The Self-assembly of a Mini-fibril with Axial Periodicity from a Designed Collagen-mimetic Triple Helix

In this work we describe the self-assembly of a collagen-like periodic mini-fibril from a recombinant triple helix. The triple helix, designated Col108, is expressed in Escherichia coli using an artificial gene and consists of a 378-residue triple helix domain organized into three pseudo-repeating sequence units. The peptide forms a stable triple helix with a melting temperature of 41 °C. Upon increases of pH and temperature, Col108 self-assembles in solution into smooth mini-fibrils with the cross-striated banding pattern typical of fibrillar collagens. The banding pattern is characterized by an axially repeating feature of ∼35 nm as observed by transmission electron microscopy and atomic force microscopy. Both the negatively stained and the positively stained transmission electron microscopy patterns of the Col108 mini-fibrils are consistent with a staggered arrangement of triple helices having a staggering value of 123 residues, a value closely connected to the size of one repeat sequence unit. A mechanism is proposed for the mini-fibril formation of Col108 in which the axial periodicity is instigated by the built-in sequence periodicity and stabilized by the optimized interactions between the triple helices in a 1-unit staggered arrangement. Lacking hydroxyproline residues and telopeptides, two factors implicated in the fibrillogenesis of native collagen, the Col108 mini-fibrils demonstrate that sequence features of the triple helical domain alone are sufficient to “code” for axially repeating periodicity of fibrils. To our knowledge, Col108 is the first designed triple helix to self-assemble into periodic fibrils and offers a unique opportunity to unravel the specific molecular interactions of collagen fibrillogenesis.     

Interpretation of the small-angle X-ray diffraction of collagen in view of the primary structure of the alpha1 chain.

The small-angle X-ray diffraction pattern of collagen has been calculated using the sequence of the alpha 1 chain and a Hodge-Petruska scheme for the packing of the collagen molecules. The molecular stagger giving the best fit of calculated-to observed structure factors has been found to be 236 or 237 amino acid residues for three tendon collagens. But this result depends on the appoximation that the molecular conformation is uniform throughout the molecule. A comparison of the observed and calculated electron density profiles in axial projection leads to a corrected model, in which the COOH-terminal telopeptide is contracted in a way suggesting a saddle-shaped electron density distribution near the collagenase site.     

NMR shows hydrophobic interactions replace glycine packing in the triple helix at a natural break in the (Gly-X-Y)n repeat

Little is known about the structural consequences of the more than 20 breaks in the (Gly-X-Y)(n) repeating sequence found in the long triple helix domain of basement membrane type IV collagen. NMR triple resonance studies of doubly labeled residues within a set of collagen model peptides provide distance and dihedral angle restraints that allow determination of model structures of both a standard triple helix and of a triple helix with a break in solution. Although the standard triple helix cannot continue when Gly is not every third residue, the NMR data support rod-like molecules that have standard triple-helical structures on both sides of a well defined and highly localized perturbation. The GAAVM break region may be described as a "pseudo triple helix," because it preserves the standard one-residue stagger of the triple helix but introduces hydrophobic interactions at the position normally occupied by the much smaller and hydrogen-bonded Gly residue of the repeating (Gly-X-Y)(n) sequence. This structure provides a rationale for the consensus presence of hydrophobic residues in breaks of similar length and defines a novel variant of a triple helix that could be involved in recognition.     

Interpretation of the low-angle meridional neutron diffraction patterns from collagen fibres in terms of the amino acid sequence

Measurement of fully corrected, low angle meridional neutron diffraction intensities from native collagen fibres, in a full range of H₂O/D₂O contrasts, is described. The observed contrast dependence of the intensities of the first 12 orders of 670 A (D) axial periodicity is fitted to a general quadratic theory of contrast variation. The observed first order contrast dependence is compared to predictions based on the amino acid sequence, assuming different extents of chemical H/D exchange, and found to be consistent with complete non-carbon linked H/D exchange except for 1 to 1.6 hydrogen atoms per gly-X-Ytriplet involved in H-bonding. Both X-ray and neutron diffraction data in a variety of contrasts are consistent with a unique model for the axially projected structure of native collagen fibrils based on the amino acid sequence. This model if characterized by average axial residua translations in the NH₂ and COOH terminal, non-triple helical telopeptides, expressed as multiples of the triple helical residue translation, of 0.85 ± 0.05 and 0.7 ± 01 respectively, with D = 235 ± 1 residues.     

Transition metal ions induce cell growth in NRK cells synchronized in G1 by picolinic acid.

Analyses of the way in which the amino acid sequence of the α1 chain of a collagen molecule can specify the Hodge-Petruska staggered fibrilstructure have been unable to show how this sequence can specify the direction as well as the magnitude of stagger between neighbouring molecules. We propose that the role of the α2 chain in non-tissue-specific collagens is to introduce a heterogeneity into the interactions between molecules that enables this direction to be specified. Our proposal is supported by a simple one-dimensional theoretical treatment. We predict that fibrils made up of collagen molecules with three identical chains will not have regular three-dimensional lattices.     

Staggered molecular packing in crystals of a collagen-like peptide with a single charged pair

The crystal structure of the triple-helical peptide, (Pro-Hyp-Gly)(4)-Glu-Lys-Gly-(Pro-Hyp-Gly)(5) has been determined to 1.75 A resolution. This peptide was designed to examine the effect of a pair of adjacent, oppositely charged residues on collagen triple-helical conformation and intermolecular interactions. The molecular conformation (a 7(5) triple helix) and hydrogen bonding schemes are similar to those previously reported for collagen triple helices and provides a second instance of water mediated N--H . . . O==C interchain hydrogen bonds for the amide group of the residue following Gly. Although stereochemically capable of forming intramolecular or intermolecular ion pairs, the lysine and glutamic acid side-chains instead display direct interactions with carbonyl groups and hydroxyproline hydroxyl groups or interactions mediated by water molecules. Solution studies on the EKG peptide indicate stabilization at neutral pH values, where both Glu and Lys are ionized, but suggest that this occurs because of the effects of ionization on the individual residues, rather than ion pair formation. The EKG structure suggests a molecular mechanism for such stabilization through indirect hydrogen bonding. The molecular packing in the crystal includes an axial stagger between molecules, reminiscent of that observed in D-periodic collagen fibrils. The presence of a Glu-Lys-Gly triplet in the middle of the sequence appears to mediate this staggered molecular packing through its indirect water-mediated interactions with backbone C==O groups and side chains.     

Hierarchical assembly and the onset of banding in fibrous long spacing collagen revealed by atomic force microscopy.

The mechanism of formation of fibrillar collagen with a banding periodicity much greater than the 67 nm of native collagen, i.e. the so-called fibrous long spacing (FLS) collagen, has been speculated upon, but has not been previously studied experimentally from a detailed structural perspective. In vitro, such fibrils, with banding periodicity of approximately 270 nm, may be produced by dialysis of an acidic solution of type I collagen and alpha(1)-acid glycoprotein against deionized water. FLS collagen assembly was investigated by visualization of assembly intermediates that were formed during the course of dialysis using atomic force microscopy. Below pH 4, thin, curly nonbanded fibrils were formed. When the dialysis solution reached approximately pH 4, thin, filamentous structures that showed protrusions spaced at approximately 270 nm were seen. As the pH increased, these protofibrils appeared to associate loosely into larger fibrils with clear approximately 270 nm banding which increased in diameter and compactness, such that by approximately pH 4.6, mature FLS collagen fibrils begin to be observed with increasing frequency. These results suggest that there are aspects of a stepwise process in the formation of FLS collagen, and that the banding pattern arises quite early and very specifically in this process. It is proposed that typical 4D-period staggered microfibril subunits assemble laterally with minimal stagger between adjacent fibrils. alpha(1)-Acid glycoprotein presumably promotes this otherwise abnormal lateral assembly over native-type self-assembly. Cocoon-like fibrils, which are hundreds of nanometers in diameter and 10-20 microm in length, were found to coexist with mature FLS fibrils.     

Studies of the local conformational properties of the cell-adhesion domain of collagen type IV in synthetic heterotrimeric peptides

Collagen type IV is a specialized form of collagen that is found only in basement membranes. It is involved in integrin-mediated cell-adhesion processes, and the responsible binding sites for the alpha1beta1 integrin cell receptor have been identified as Asp461 of the two alpha1 chains and Arg461 of the alpha2 chain. In the most plausible stagger of native collagen type IV the alpha2 chain is the tailing one. This has recently been confirmed by the differentiated binding affinities of synthetic heterotrimeric collagen peptides in which the chains were staggered in this native register as well as in the less plausible alpha1alpha2alpha1' register with an artificial cystine knot. In the present work, two heterotrimeric collagen peptides with chain registers identical to the previous ones were synthesized for fluorescence resonance energy transfer and emission anisotropy measurements, exploiting the native Phe464 in the alpha2 chain as donor and an Ile467Tyr mutation in the alpha1' chain as acceptor fluorophore. This fluorophore pair allowed extraction of more detailed information on the conformational properties of the cell-adhesion epitope incorporated into the central part of the trimeric collagen model peptides. A comparison of the experimentally derived values of the interfluorophore distance and of the orientation factor kappa(2) with the values extracted from the molecular model of the trimer in the native stagger confirmed a triple-helical structure of the adhesion-site portion at low temperature. The thermal unfolding of this central domain was specifically monitored by emission anisotropy, allowing unambiguous assignment of the three structural domains of the trimeric collagen molecules detected by microcalorimetry, with the integrin binding site as the portion of weakest triple-helical stability flanked by two more stable triple-helical regions. The results are consistent with the picture of a conformational microheterogeneity as the responsible property for selective recognition of collagens by interacting proteins.     

The role of aromatic residues in the hydrophobic core of the villin headpiece subdomain

Small autonomously folding proteins are of interest as model systems to study protein folding, as the same molecule can be used for both experimental and computational approaches. The question remains as to how well these minimized peptide model systems represent larger native proteins. For example, is the core of a minimized protein tolerant to mutation like larger proteins are? Also, do minimized proteins use special strategies for specifying and stabilizing their folded structure? Here we examine these questions in the 35‐residue autonomously folding villin headpiece subdomain (VHP subdomain). Specifically, we focus on a cluster of three conserved phenylalanine (F) residues F47, F51, and F58, that form most of the hydrophobic core. These three residues are oriented such that they may provide stabilizing aromatic–aromatic interactions that could be critical for specifying the fold. Circular dichroism and 1D‐NMR spectroscopy show that point mutations that individually replace any of these three residues with leucine were destabilized, but retained the native VHP subdomain fold. In pair‐wise replacements, the double mutant that retains F58 can adopt the native fold, while the two double mutants that lack F58 cannot. The folding of the double mutant that retains F58 demonstrates that aromatic–aromatic interactions within the aromatic cluster are not essential for specifying the VHP subdomain fold. The ability of the VHP subdomain to tolerate mutations within its hydrophobic core indicates that the information specifying the three dimensional structure is distributed throughout the sequence, as observed in larger proteins. Thus, the VHP subdomain is a legitimate model for larger, native proteins.     

Synthesis of heterotrimeric collagen peptides containing the alpha1beta1 integrin recognition site of collagen type IV.

Collagen type IV provides a biomechanically stable scaffold into which the other constituents of basement membranes are incorporated, but it also plays an important role in cell adhesion. This occurs with collagen type IV mainly via the alpha1beta1 integrin, and the proposed epitope involved in this type of collagen/integrin interaction corresponds to a non-sequential R/Xaa/D motif, where the arginine and aspartate residues are provided by the alpha2 and alpha1 chains of the collagen molecule, respectively. Since the stagger of the three alpha chains in native collagen type IV is still unknown and different alignments of the chains lead to different spatial epitopes, two heterotrimeric collagen peptides containing the natural 457-469 sequences of the cell adhesion site were synthesized in which the single chains were assembled via disulfide bonds into the two most plausible alpha1alpha2alpha1' and alpha2alpha1alpha1' registers. The differentiated triple-helical stabilities of the two heterotrimers suggest a significant structural role of the chain register in collagen, although the binding to alpha1beta1 integrin is apparently less affected as indicated by preliminary experiments.     

A new twist in the collagen story--the type VI segmented supercoil

Collagen occurs in two major forms: fibrillar and non-fibrillar. Non-fibrillar collagens are structurally more variable and relatively ill-understood. In this work we analysed the amino acid sequence of type VI collagen, a non-fibrillar collagen that forms antiparallel dimers. A sequence motif was discovered that gives rise to systematic molecular coiling. There is a common periodicity ( approximately 23 or 2 x 23 residues) in the charged amino acids, in the prolines and in the discontinuities in the Gly-X-Y triplets. In addition, there is a different periodicity ( approximately 21 amino acids) in the apolar groups. The two repeats mean that the only way to simultaneously maximize both the hydrophobic and polar interactions during dimer formation is with the molecules antiparallel, overlapped by 75 nm as observed, and supercoiled. The alternating proline-rich and charge-rich patches, often together with discontinuities in the Gly-X-Y sequences, coincide with each half-turn of the supercoil, thus breaking it into segments. We have termed this structure the collagen segmented supercoil. The segmented supercoil and variants may be common aggregation motifs for the non-fibrillar collagens.     

The spatial orientation of the essential amino acid residues arginine and aspartate within the alpha1beta1 integrin recognition site of collagen IV has been resolved using fluorescence resonance energy transfer

The interaction of collagen IV with cells is mediated mainly by the integrin alpha1beta1. The recognition site has been located to a segment of the triple-helical domain 100 nm away from the N terminus of the collagen molecule. The three essential amino acid residues of the alpha1beta1 binding site, arginine alpha2(IV)461 and the two aspartate residues alpha1(IV)461, are all located on different chains. Since the spatial array of the three residues depends on the stagger of the chains within the triple helix, the stagger has been elucidated using fluorescence resonance energy transfer with phenylalanine alpha1(IV)473 and tryptophan alpha2(IV)479 as the fluorescent donor/acceptor pair. The distance R between phenylalanine and tryptophan was determined by analysis of the energy transfer efficiency, E, and the orientation factor, kappa(2). In parallel, distance R and orientation factor, kappa(2 )were also calculated from the coordinates of the triple helix. Comparison of the calculated and empirically determined values unequivocally showed the stagger to be alpha1'alpha1alpha2. This arrangement of the three alpha chains describes the conformation of the alpha1beta1 integrin recognition site, that is the distinct orientation of the side-chains of the essential residues aspartate and arginine in respect to the helix axis.     

Molecular interactions in myosin assembly. Role of the 28-residue charge repeat in the rod.

We have used internal deletions of multiples of seven residues to change the phase of the 28-residue charge repeat in a light meromyosin cDNA construct expressed in Escherichia coli. The solubility behaviour of these mutants was similar to that of the wild-type material, but the molecular packing in the aggregates formed at low ionic strength was different. Whereas wild-type material formed paracrystals in which molecules were in close contact over most of their length, molecules in the paracrystals formed by the mutants were in close contact for only a short distance, which was just short enough to exclude the deletion from the overlap. These data indicate that, although the 28-residue charge periodicity is important in myosin molecular interactions, it is probably not the major driving force for myosin assembly and instead influences the detailed axial stagger of the interacting molecules.     

Common interruptions in the repeating tripeptide sequence of non-fibrillar collagens: sequence analysis and structural studies on triple-helix peptide models

Interruptions in the repeating (Gly-X1-X2)_n amino acid sequence pattern are found in the triple-helix domains of all non-fibrillar collagens, and perturbations to the triple-helix at such sites are likely to play a role in collagen higher-order structure and function. This study defines the sequence features and structural consequences of the most common interruption, where one residue is missing from the tripeptide pattern, Gly-X1-X2-Gly-AA₁-Gly-X1-X2, designated G1G interruptions. Residues found within G1G interruptions are predominantly hydrophobic (70%), followed by a significant amount of charged residues (16%), and the Gly-X1-X2 triplets flanking the interruption are atypical. Studies on peptide models indicate the degree of destabilization is much greater when Pro is in the interruption, GP, than when hydrophobic residues (GF, GY) are present, and a rigid Gly-Pro-Hyp tripeptide adjacent to the interruption leads to greater destabilization than a flexible Gly-Ala-Ala sequence. Modeling based on NMR data indicates the Phe residue within a GF interruption is located on the outside of the triple helix. The G1G interruptions resemble a previously studied collagen interruption GPOGAAVMGPO, designated G4G-type, in that both are destabilizing, but allow continuation of rod-like triple helices and maintenance of the single residue stagger throughout the imperfection, with a loss of axial register of the superhelix on both sides. Both kinds of interruptions result in a highly localized perturbation in hydrogen bonding and dihedral angles, but the hydrophobic residue of a G4G interruption packs near the central axis of the superhelix, while the hydrophobic residue of a G1G interruption is located on the triple-helix surface. The different structural consequences of G1G and G4G interruptions in the repeating tripeptide sequence pattern suggest a physical basis for their differential susceptibility to matrix metalloproteinases in type X collagen.     

Analysis of periodic patterns in amino acid sequences: Collagen

Methods are given for analyzing regularly spaced patterns of amino acids in proteins and applied to the α₁ chain of collagen. Fourier methods use the transform of the sequence either embedded in a very long array or folded onto a fundamental base period. Filtering through a moveable “window” of definite width is used to display almost regular features at any chosen frequency. A pattern detection method is described for patterns of general shape. Collagen has statistically significant periodicities at fractions of the stagger distance D = 670 Å. Hydrophobic groups show strong orders of 5, 6, 11; proline 5; charged groups 6, 18, 21. Charged residues mostly occur as neutral pairs. Their distribution has strong 6th and 21st orders which also appear in the changes which are paired at multiples of D. Charge pairs separated by (D + 3) residues show a strong 5D/89 pattern and may form a system of salt bridges across the fibril. There is no sign of any regular pattern of amino acids over the triple helix with a period close to its natural pitch of 30 residues. Supercoiled models with six relative turns of the contact edge between paired triple-helical strands are examined.     

Cell adhesion promoting peptide GVKGDKGNPGWPGAP from the collagen type IV triple helix: cis/trans proline-induced multiple 1H NMR conformations and evidence for a KG/PG multiple turn repeat motif in the all-trans proline state

Peptide GVKGDKGNPGWPGAPY (called peptide IV-H1), derived from the protein sequence of human collagen type IV, triple-helix domain residues 1263-1277, represents an RGD-independent, cell-specific, adhesion, spreading, and motility promoting domain in type IV collagen. In this study, peptide IV-H1 has been investigated by 1H NMR (500 MHz) spectroscopy. Cis-trans proline isomerization at each of the three proline residues gives rise to a number of slowly exchanging (500-MHz NMR time scale) conformation states. At least five such states are observed, for example, for the well-resolved A14 beta H3 group, and K3, which is six residues sequentially removed from the nearest proline, i.e., P9, shows two sets. The presence of more than two sets of resonances for residues sequentially proximal to a proline, e.g., A14-cis-P15 and A14-trans-P15, and more than one set for a residue sequentially well-removed from a proline, e.g., K3, indicates long range conformation interactions and the presence of preferred structure in this short linear peptide. Many resonances belonging to these multiple species have been assigned by using mono-proline-substituted analogues. Conformational (isomer) state-specific 2D 1H NMR assignments for the combination of cis and trans proline states have been made via analysis of COSY-type, HOHAHA, and NOESY spectra. Peptide IV-H1 in the all-trans proline state ttt exists in relatively well-defined conformation populations showing numerous short- and long-range NOEs and long-lived backbone amide protons and reduced backbone NH temperature coefficients, suggesting hydrogen-bonding, and structurally informative 3J alpha N coupling constants. The NMR data indicate significant beta-turn populations centered at K3-G4, K5-G6, P9-G10, and P12-G13, and a C-terminal gamma-turn within the A14-P15-Y16 sequence. These NMR data are supported by circular dichroic studies which indicate the presence of 52% beta-turn, 10% helix, and 38% random coil structural populations. Since equally spaced KG and PG residues are found on both sides of peptide IV-H1 in the native collagen type IV sequence, this multiple turn repeat motif may continue through a longer segment of the protein. Synthetic peptide IV-H1 overlapping sequence "walk throughs" indicate that the primary biological activity is localized in the GNPGWPGAP double beta-turn domain, which contains the backbone constraining proline residues. This proline-domain conformation may suggest a collagen type IV receptor-specific, metastatic cell adhesion promoting binding domain.