Conformational stability of type I collagen triple helix: evidence for temporary and local relaxation of the protein conformation using a proteolytic probe

Native collagen polypeptides exist in a unique triple helical conformation resistant to most proteinases. In this study, the stability of type I collagen triple helix, employing a mixture of trypsin and alpha-chymotrypsin as a proteolytic probe, was examined. The degradation of type I [3H]collagen was monitored as 3H-labeled peptides soluble in trichloroacetic acid (TCA) or by sodium dodecyl sulfate (SDS)-polyacrylamide slab gel electrophoresis. In one set of experiments, collagen substrates were preincubated at various temperatures for up to 8 h, followed by a 15-min proteolytic treatment at the same temperature. At 43 degrees C, most of the collagen was degraded, while the fraction of the substrate degraded at 40, 38, and 35 degrees C was 53, 41 and 19%, respectively. This fraction was independent of the preincubation time which varied from 10 to 480 min. Thus, at any given temperature, a constant fraction of the collagen substrate was susceptible to proteolysis. Measurement of the midpoint temperature (Tm) of the helix to coil transformation for type I collagen, at neutral pH employing an increasing temperature gradient and brief proteolysis at the individual temperatures, indicated a value of 38.8 degrees C. However, determination of the Tm by employing proteolytic digestions at a constant temperature (30 degrees C) using conditions under which the nonhelical peptides are readily digested to TCA-soluble peptides while native collagen resists such proteolysis, indicated a value of 42.7 degrees C. In further studies, collagen was subjected to continuous proteolysis for up to 24 h. A large fraction of collagen was digested at 30 or 34 degrees C, temperatures well below the Tm of the helix to coil transformation. SDS-polyacrylamide gel electrophoresis of the degradation products obtained at these temperatures revealed multiple cleavage fragments. Finally, temperature double-jump experiments indicated that the destabilization of the triple helix is reversible provided that the Tm of the substrate is not exceeded. The results provide evidence for reversible and local relaxation of the collagen triple helix.     

Structural properties of a collagenous heterotrimer that mimics the collagenase cleavage site of collagen type I

Collagens contain sequence- and conformation-dependent epitopes responsible for their digestion by collagenases at specific loci. A synthetic heterotrimer construct containing the collagenase cleavage site of collagen type I was found to mimic perfectly native collagen in terms of selectivity and mode of enzymatic degradation. The NMR conformational analysis of this molecule clearly revealed the presence of two structural domains, i.e. a triple helix spanning the Gly-Pro-Hyp repeats and a less ordered portion corresponding to the collagenase cleavage site where the three chains are aligned in extended conformation with loose interchain contacts. These structural properties allow for additional insights into the very particular mechanism of collagen digestion by collagenases.     

Identification ofClostridium histolyticum collagenase hyperreactive sites in type I,II, and III collagens: Lack of correlation with local triple helical stability

The class I and IIClostridium histolyticum collagenases (CHC) have been used to identify hyperreactive sites in rat type I, bovine type II, and human type III collagens. The class I CHC attack both collagens at loci concentrated in the N-terminal half of these collagens starting with the site closest to the N-terminus. The class II CHC initiate collagenolysis by attacking both collagens in the interior to produce a mixture of C-terminal 62,000 and a N-terminal 36,000 fragments. Both fragments are next shortened by removal of a 3000 fragment. These results are very similar to those reported earlier for the hydrolysis of rat type I collagen by these CHC, indicating that the three collagens share many hyperreactive sites. Similar reactions carried out with the respective gelatins show that they are cleaved at many sites at approximately the same rate. Thus, the hyperreactivity of the sites identified must be attributed to their environment in the native collagens. N-terminal sequencing of the fragments produced in these reactions has allowed the identification of 16 cleavage sites in the α1(I), α2(I), α1(II), and α1(III) collagen chains. An analysis of the triple helical stabilities of these cleavage site regions as reflected by their imino acid contents fails to yield a correlation between reactivity and triple helical stability. The existence of these hyperreactive CHC cleavage sites suggests that type I, II, and III collagens contain regions that have specific nontriple helical conformations. The sequence of these sites presented here now makes it possible to investigate these conformations by computational and peptide mimetic techniques.     

Cleavage specificity of human skin type IV collagenase (gelatinase). Identification of cleavage sites in type I gelatin, with confirmation using synthetic peptides

Type IV collagenase (gelatinase) readily cleaves denatured collagen into very small peptides. Large cyanogen bromide fragments (25 kDa) of type I collagen are degraded at the same rate as the complete alpha-chain. A number of the gelatinolytic cleavage sites of alpha 1(I)CB7 and alpha 1(I)CB8, representing 50% of the collagen alpha-chain, were determined by sequence analysis of product peptides. In addition to the expected cleavage between glycine and hydrophobic residues, several other cleavage sites were identified. These sites were Gly-Glu, Gly-Asn, and Gly-Ser. Basic residues were found adjacent to the cleavage site in several cases. Hexapeptides containing these unexpected cleavage sites were synthesized, and Km and kcat values were determined. All but one of the Km values were in the submillimolar range, and turnover numbers for the peptides uncharged at the carboxyl terminus were on the order of 10,000/h. Of particular significance was the finding that hydroxyproline occurs 5 residues from the cleavage site in all carboxyl-terminal product peptides and also occurs 5 residues from the cleavage site in seven of nine amino-terminal product peptides. A requirement for hydroxyproline may be of importance in determining the specificity of this enzyme for denatured collagenous substrates.     

Molecular Mechanism of Type I Collagen Homotrimer Resistance to Mammalian Collagenases

Type I collagen cleavage is crucial for tissue remodeling, but its homotrimeric isoform is resistant to all collagenases. The homotrimers occur in fetal tissues, fibrosis, and cancer, where their collagenase resistance may play an important physiological role. To understand the mechanism of this resistance, we studied interactions of α1(I)₃ homotrimers and normal α1(I)₂α2(I) heterotrimers with fibroblast collagenase (MMP-1). Similar MMP-1 binding to the two isoforms and similar cleavage efficiency of unwound α1(I) and α2(I) chains suggested increased stability and less efficient unwinding of the homotrimer triple helix at the collagenase cleavage site. The unwinding, necessary for placing individual chains inside the catalytic cleft of the enzyme, was the rate-limiting cleavage step for both collagen isoforms. Comparative analysis of the homo- and heterotrimer cleavage kinetics revealed that MMP-1 binding promotes stochastic helix unwinding, resolving the controversy between different models of collagenase action.     

Substrate specificity of the collagenolytic serine protease from Uca pugilator: studies with collagenous substrates

The collagenolytic protease from Uca pugilator was studied with respect to its catalytic properties on collagen types I-V. The crab protease degraded all five collagen types, producing multiple cleavages in the triple helix of each native collagen at 25 degrees C. The major early cleavage in the alpha 1 polypeptide chain of collagen types I-III occurred at a 3/4:1/4 locus, resulting in fragments electrophoretically similar to the TCA and TCB products of mammalian collagenase action. Interestingly, a propensity toward this same cleavage was observed even following thermal denaturation of the substrates. The ability of the crab protease to degrade all native collagen types and to catalyze cleavages at multiple loci in the triple helix distinguishes its action from that of mammalian collagenases. The collagenolytic activity of the crab protease was also examined on fibrillar collagen and compared to that of human skin fibroblast collagenase. Enzyme concentrations of fibroblast collagenase which resulted in the saturation of available substrate sites failed to show such an effect in the case of the crab protease. Binding studies of the crab protease to fibrillar collagen likewise indicated substantially reduced levels of enzyme binding in comparison to fibroblast collagenase. These data suggest that the affinity of the crab protease for native collagen is considerably less than the affinity of mammalian collagenase for this substrate.     

Carbamylation differentially alters type I collagen sensitivity to various collagenases.

Carbamylation is a post-translational modification due to nonenzymatic binding of cyanate, a by-product of urea, on free amino groups of proteins. Post-translational modifications are known to induce alterations in structural and functional properties of proteins, thus disturbing protein-protein or cell-protein interactions. We report the impact of carbamylation on type I collagen sensitivity to enzymatic proteolysis. Type I collagen was extracted from rat tail tendons and carbamylated by incubation with 0.1 M potassium cyanate at 37 degrees C for 2, 6 or 24 h. Degradation assays revealed that carbamylated collagen exhibited a greater resistance to collagenases (i.e. bacterial collagenase, matrix metalloproteinase(MMP)-1, MMP-8 and MMP-13), together with an increased sensitivity to MMP-2. Evaluation of collagen triple helix conformation by polarimetry indicated that local destabilizations of triple helix structure related to carbamylation could be responsible for the observed differences in sensitivity. These results confirm the crucial role of triple helix integrity in the degradation of type I collagen by MMPs, and support the deleterious impact of post-translational modifications in vivo by altering the balanced remodeling of collagen within connective tissue.     

Specific cleavage of human type III collagen by human polymorphonuclear leukocyte elastase

Purified polymorphonuclear leukocyte elastase degraded native human liver type III collagen at 27 degrees C by making a cleavage through the triple helix. The enzyme had no effect on human type I collagen. The reaction was inhibited by phenylmethanesulfonyl fluoride (PhCH2SO2F) but not by EDTA. The collagen reaction products were identical with those generated by human rheumatoid synovial collagenase when analyzed by polyacrylamide gel electrophoresis and gel filtration. NH2-trminal sequence analysis indicated that the enzyme cleaved at an isoleucyl-threonyl bond located 4 residues on the carboxyl side of the established cleavage site for animal collagenases. Therefore, it is likely that in pathologic states, type III collagen can be selectively depleted from the matrix by this enzyme.     

Characterization of the mechanisms by which gelatinase A, neutrophil collagenase, and membrane-type metalloproteinase MMP-14 recognize collagen I and enzymatically process the two alpha-chains

The turnover of native collagen has been ascribed to different members of the matrix metalloproteinase (MMP) family. Here, the mechanisms by which neutrophil collagenase (MMP-8), gelatinase A (MMP-2), and the ectodomain of MT1-MMP (ectMMP-14) degrade fibrillar collagen were examined. In particular, the hydrolysis of type I collagen at 37 degrees C was investigated to identify functional differences in the processing of the two alpha-chain types of fibrillar collagen. Thermodynamic and kinetic parameters were used for a quantitative comparison of the binding, unwinding, and hydrolysis of triple helical collagen. We demonstrate that the MMP family has developed at least two distinct mechanisms for collagen unwinding and cleavage. MMP-8 and ectMMP-14 display a similar mechanism (although with different catalytic parameters), which is characterized by binding (likely through the hemopexin-like domain) and cleavage of alpha-1 and/or alpha-2 chains without distinguishing between them and keeping the gross conformation of the triple helix (at least during the first cleavage step). On the other hand, MMP-2 binds preferentially the alpha-1 chains (likely through the fibronectin-like domain, which is not present in MMP-8 and ectMMP-14), grossly altering the whole triple helical arrangement of the collagen molecule and cleaving preferentially the alpha-2 chain. These distinctive mechanisms underly a drastically different mode of interaction with triple helical fibrillar collagen I, according to which the MMP domain is involved in binding. These findings can be related to the different role exerted by these MMPs on collagen homeostasis in the extracellular matrix.     

Complement component C1r mediated cleavage of the heavy chain of the major histocompatibility class I antigens.

Apart from cleaving C1s, we demonstrate for the first time that: 1) at concentrations found in serum, the activated forms of the complement components C1r in addition to C1s can cleave the heavy chain of MHC class I antigens, 2) the cleavage by C1r and C1s is seemingly dependent upon a native configuration of the MHC class I antigen, since heat denaturation of the HLA antigens reduce the cleavage. The proteolytic fragments following C1 cleavage were characterized by precipitation with Con A-Sepharose, anti-MHC class I and anti-beta 2-microglobulin antibodies. The proteolysis of the alpha-chain of MHC class I was shown to take place between the alpha 2- and alpha 3- domains as estimated by the Con A-Sepharose precipitation pattern on SDS-PAGE. The alpha 1/alpha 2 fragment was still shown to interact with beta 2-microglobulin as shown by immunoprecipitation.     

Changes in thermal stability and microunfolding pattern of collagen helix resulting from the loss of alpha2(I) chain in osteogenesis imperfecta murine

Homozygous mutations resulting in formation of alpha1(I)(3) homotrimers instead of normal type I collagen cause mild to severe osteogenesis imperfecta (OI) in humans and mice. Limited studies of changes in thermal stability of type I homotrimers were reported previously, but the results were not fully consistent. We revisited this question in more detail using purified tendon collagen from wild-type (alpha1(I)(2)alpha2(I) heterotrimers) and oim (alpha1(I)(3)) mice as well as artificial alpha1(I)(3) homotrimers obtained by refolding of rat-tail-tendon collagen. We found that at the same heating rate oim homotrimers completely denature at approximately 2.5deg.C higher temperature than wild-type heterotrimers, as determined by differential scanning calorimetry. At the same, constant temperature, homotrimers denature approximately 100 times slower than heterotrimers, as determined by circular dichroism. Detailed analysis of proteolytic cleavage at different temperatures revealed that microunfolding of oim homotrimers and wild-type heterotrimers occurs at similar rate but within a number of different sites. In particular, the weakest spot on the oim triple helix is located approximately 100 amino acid residues from the C-terminal end within the cyanogen bromide peptide CB6. The same microunfolding site is also present in wild-type collagen, but the weakest spot of the latter is located close to the N-terminal end of CB8. Amino acid analysis and differential gel electrophoresis showed virtually no posttranslational overmodification of oim mouse tendon collagen. Moreover, thermal stability and microunfolding of artificial rat-tail-tendon homotrimers were similar to oim homotrimers. Thus, the observed changes are associated with difference in the amino acid composition of alpha1(I) and alpha2(I) chains rather than posttranslational overmodification.     

Identification ofClostridium histolyticum collagenase hyperreactive sites in type I, II, and III collagens: Lack of correlation with local triple helical stability

The class I and IIClostridium histolyticum collagenases (CHC) have been used to identify hyperreactive sites in rat type I, bovine type II, and human type III collagens. The class I CHC attack both collagens at loci concentrated in the N-terminal half of these collagens starting with the site closest to the N-terminus. The class II CHC initiate collagenolysis by attacking both collagens in the interior to produce a mixture of C-terminal 62,000 and a N-terminal 36,000 fragments. Both fragments are next shortened by removal of a 3000 fragment. These results are very similar to those reported earlier for the hydrolysis of rat type I collagen by these CHC, indicating that the three collagens share many hyperreactive sites. Similar reactions carried out with the respective gelatins show that they are cleaved at many sites at approximately the same rate. Thus, the hyperreactivity of the sites identified must be attributed to their environment in the native collagens. N-terminal sequencing of the fragments produced in these reactions has allowed the identification of 16 cleavage sites in the 1(I), 2(I), 1(II), and 1(III) collagen chains. An analysis of the triple helical stabilities of these cleavage site regions as reflected by their imino acid contents fails to yield a correlation between reactivity and triple helical stability. The existence of these hyperreactive CHC cleavage sites suggests that type I, II, and III collagens contain regions that have specific nontriple helical conformations. The sequence of these sites presented here now makes it possible to investigate these conformations by computational and peptide mimetic techniques.     

Proteolysis of the heavy chain of major histocompatibility complex class I antigens by complement component C1s.

The major histocompatibility complex (MHC) class I antigens contain a light chain, beta 2-microglobulin, non-covalently associated to the transmembrane heavy alpha-chain carrying the allotypic determinants. Since the C1q complement component is known to associate with beta 2-microglobulin, and we recently found that activated C1s complement was capable of cleaving beta 2-microglobulin, we decided to investigate the proteolytic activity of C1 complement towards the heavy chain of class I antigens. Our results demonstrate that human C1s complement cleaves the heavy chain of human class I antigens into at least two fragments, with apparent molecular weights of 22,000 and 24,000 g/mol on sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE), under both reducing and non-reducing conditions. The cleavage of the heavy chain is inhibited by the presence of C1 esterase inhibitor. The molecular weights of the fragments are in agreement with the cleavage located in the area between the disulphide loops of the alpha 2-and alpha 3-domains of the heavy chain. In addition human C1s complement is able to cleave H-2 antigens from mouse in a similar fashion but not rat MHC class I antigen or mouse MHC class II antigen (I-Ad). Mouse MHC class I antigen-specific determinants could also be detected in supernatant from mouse spleen cells incubated with C1r and C1s. These results indicate the presence in the body fluids of a non-membrane-bound soluble form of the alpha 1-and alpha 2-domains which represent the binding site for antigenic peptides.     

A 9-base pair deletion in COL1A1 in a lethal variant of osteogenesis imperfecta

A proband with lethal osteogenesis imperfecta has been investigated for the causative defect at the levels of collagen protein, mRNA, and DNA. Analysis of type I collagen synthesized by the proband's fibroblasts showed excessive post-translational modification of alpha 1(I) chains along the entire length of the helix. Oververmodification of alpha chains could be prevented by incubation of the cells at 30 rather than 37 degrees C, and the thermal stability of the triple helix, as determined by protease digestion, was normal. RNase A cleavage of RNA:RNA hybrids formed between the proband's mRNA and antisense RNA derived from normal pro-alpha 1(I) chain cDNA clones was used to locate an abnormality to exon 43 of the proband's pro-alpha 1(I) collagen gene (COL1A1). The nucleotide sequence of the corresponding gene region showed, in one allele, the deletion of 9 base pairs, not present in either parent, within a repeating sequence of exon 43. The mutation causes the loss of one of three consecutive Gly-Ala-Pro triplets at positions 868-876, but does not otherwise disrupt the Gly-X-Y sequence. Procollagen processing in fibroblast cultures and susceptibility of the mutant collagen I to cleavage with vertebrate collagenase were normal, indicating that the slippage of collagen chains by one Gly-X-Y triplet does not abolish amino-propeptidase and collagenase cleavage sites. How the mutation produces the lethal osteogenesis imperfecta phenotype is not entirely clear; the data suggest that the interaction of alpha chains immediately prior to helix formation may be affected.     

The A and B fragments of normal type I procollagen have a similar thermal stability to proteinase digestion but are selectively destabilized by structural mutations

Previous studies demonstrated that the thermal stability of the procollagen triple helix can be assayed by digesting the protein for short periods with high concentrations of trypsin and chymotrypsin. Here we cleaved human type I procollagen or collagen with vertebrate collagenase to generate A fragments from the three-quarter amino termini and B fragments from the one-quarter carboxy termini of the molecules. The thermal stabilities of the fragments were then assayed by rapid trypsin/chymotrypsin digestion. Both fragments were resistant up to 36 degrees C and completely degraded between 37 degrees C and 39 degrees C. In subsequent experiments the same assay was carried out with type I procollagens synthesized by fibroblasts from two patients with lethal variants of osteogenesis imperfecta. With one, the A fragments were selectively destabilized, an observation consistent with previous data indicating that the mutation in the patient produced a deletion of 84 amino acids from the middle of the alpha 1(I) chain. With procollagen synthesized by fibroblasts from the second patient the B fragments were selectively destabilized, an observation consistent with preliminary data indicating a mutation that alters the primary structure of the carboxy-terminal region of the alpha 1(I) chain. Therefore, the procedures described here present a simple and direct method for locating mutations that destabilize the collagen triple helix.     

A short sequence in the N-terminal region is required for the trimerization of type XIII collagen and is conserved in other collagenous transmembrane proteins

The recombinant transmembrane protein type XIII collagen is shown to reside on the plasma membrane of insect cells in a 'type II' orientation. Expressions of deletion constructs showed that sequences important for the association of three alpha1(XIII) chains reside in their N- rather than C-terminal portion. In particular, a deletion of residues 63-83 immediately adjacent to the transmembrane domain abolished the formation of disulfide-bonded trimers. The results imply that nucleation of the type XIII collagen triple helix occurs at the N-terminal region and that triple helix formation proceeds from the N- to the C-terminus, in opposite orientation to that of the fibrillar collagens. Interestingly, a sequence homologous to the deleted residues was found at the same plasma membrane-adjacent location in other collagenous transmembrane proteins, suggesting that it may be a conserved association domain. The type XIII collagen was secreted into insect cell medium in low amounts, but this secretion was markedly enhanced when the cytosolic portion was lacking. The cleavage occurred in the non-collagenous NC1 domain after four arginines and was inhibited by a furin protease inhibitor.     

A targeted mutation at the known collagenase cleavage site in mouse type I collagen impairs tissue remodeling

Degradation of type I collagen, the most abundant collagen, is initiated by collagenase cleavage at a highly conserved site between Gly775 and Ile776 of the alpha 1 (I) chain. Mutations at or around this site render type I collagen resistant to collagenase digestion in vitro. We show here that mice carrying a collagenase-resistant mutant Col1a-1 transgene die late in embryo-genesis, ascribable to overexpression of the transgene, since the same mutation introduced into the endogenous Col1a-1 gene by gene targeting permitted normal development of mutant mice to young adulthood. With increasing age, animals carrying the targeted mutation developed marked fibrosis of the dermis similar to that in human scleroderma. Postpartum involution of the uterus in the mutant mice was also impaired, with persistence of collagenous nodules in the uterine wall. Although type I collagen from the homozygous mutant mice was resistant to cleavage by human or rat fibroblast collagenases at the helical site, only the rat collagenase cleaved collagen trimers at an additional, novel site in the nonhelical N-telopeptide domain. Our results suggest that cleavage by murine collagenase at the N-telopeptide site could account for resorption of type I collagen during embryonic and early adult life. During intense collagen resorption, however, such as in the immediate postpartum uterus and in the dermis later in life, cleavage at the helical site is essential for normal collagen turnover. Thus, type I collagen is degraded by at least two differentially controlled mechanisms involving collagenases with distinct, but overlapping, substrate specificities.     

Localization of cysteine residues in the alpha-chain of histidine decarboxylase from Micrococcus sp. n

It was shown that the alpha-chain of histidine decarboxylase of Micrococcus sp. n. is split off by 2-nitro-5-thiocyanobenzoic acid at only one of the two cysteine residues. Determination of the C-terminal sequences, amino acid composition, molecular weight of the fragments obtained demonstrated that these fragments constitute a complete alpha-chain whose cleavage occurs at the cysteine residue which is readily modified by SH-reagents. the Ile-Cys peptide bond appeared to be resistant to cleavage under these conditions. This cleavage permitted to identify the amino acid environment of the cysteine residue active center and its localization in the alpha-chain of histidine decarboxylase.     

Pivotal molecular determinants of peptidic and collagen triple helicase activities reside in the S3' subsite of matrix metalloproteinase 8 (MMP-8): the role of hydrogen bonding potential of ASN188 and TYR189 and the connecting cis bond

The mechanism of triple helical collagen unwinding and cleavage by collagenases in the matrix metalloproteinase (MMP) family is complex and remains enigmatic. Recent reports show that triple helicase activity is initiated by the hemopexin C domain of membrane type 1-MMP, whereas catalytically inactive full-length interstitial collagenase (MMP-1) exhibits full triple helicase functionality pointing to active site determinants that are needed to complete the triple helicase mechanism. In MMP-8, the neutrophil collagenase, a conserved Gly at the S(3)' substrate specificity subsite is replaced by Asn(188) that forms a highly unusual cis bond with Tyr(189), a conserved active site residue in the collagenases. Only in MMP-1 is the S(3)' Gly also replaced, and there too a cis configured Glu-Tyr occurs. Thus, this high energy peptide bond coupled to the canonical Tyr may be important in the collagenolytic process. In a systematic mutagenesis investigation of the MMP-8 S(3)' subsite we found that introducing an S(3)' Gly(188) into MMP-8 reduced collagenolytic efficiency by approximately 30% with a corresponding reduction in cleavage of a synthetic peptide fluorescence resonance energy transfer substrate analogue of the alpha2(I) collagen chain cleavage site. The substitution of Asn(188) to Leu, a hydrophobic residue of similar size to the highly polar Asn and designed to retain the cis bond, revealed the importance of hydrogen bonding to bound substrate with both collagenolytic and peptidic activities reduced approximately 3-fold. In contrast, the specificity for type I collagen of the mutant Y189F dropped 3-fold without any significant alteration in general peptidase activity. Therefore, S(3)' and in particular the hydrogen bonding potential of Tyr(189) is a specific molecular determinant for MMP-8 triple helicase activity. The cis bond connection to Asn(188) juxtaposes these two side chains for closely spaced hydrogen bonding with substrate that improves collagenolytic and general catalytic efficiency that could be exploited for new collagenase-specific inhibitor drugs.     

Sequence dependence of renucleation after a Gly mutation in model collagen peptides

Missense mutations in the collagen triple helix that replace one Gly residue in the (Gly-X-Y)(n) repeating pattern by a larger amino acid have been shown to delay triple helix folding. One hypothesis is that such mutations interfere with the C- to N-terminal directional propagation and that the identity of the residues immediately N-terminal to the mutation site may determine the delay time and the degree of clinical severity. Model peptides are designed to clarify the role of tripeptide sequences N-terminal to the mutation site, with respect to length, stability, and nucleation propensity, to complete triple helix folding. Two sets of peptides with different N-terminal sequences, one with the natural sequence alpha1(I) 886-900, which is just adjacent to the Gly(901) mutation, and one with a GPO(GAO)(3) sequence, which occurs at alpha1(I) 865-879, are studied by CD and NMR. Placement of the five tripeptides of the natural alpha1(I) collagen sequence N-terminal to the Gly to Ala mutation site results in a peptide that is folded only C-terminal to the mutation site. In contrast, the presence of the Hyp-rich sequence GPO(GAO)(3) N-terminal to the mutation allows complete refolding in the presence of the mutation. The completely folded peptide contains an ordered central region with unusual hydrogen bonding while maintaining standard triple helix structure at the N- and C-terminal ends. These peptide results suggest that the location and sequences of downstream regions favorable for renucleation could be the key factor in the completion of a triple helix N-terminal to a mutation.