The effects of different cysteine for glycine substitutions within alpha 2(I) chains. Evidence of distinct structural domains within the type I collagen triple helix

Affected individuals from two apparently distinct, mild osteogenesis imperfecta families were heterozygous for a G to T transition in the COL1A2 gene that resulted in cysteine for glycine substitutions at position 646 in the alpha 2(I) chain of type I collagen. A child with a moderately severe form of osteogenesis imperfecta was heterozygous for a G to T transition that resulted in a substitution of cysteine for glycine at position 259 in the COL1A2 gene. Type I collagen molecules containing an alpha 2(I) chain with cysteine at position 259 denaturated at a lower temperature than molecules containing an alpha 2(I) chain with cysteine at position 646. In contrast to cysteine for glycine substitutions in the alpha 1(I) chain, the severity of the osteogenesis imperfecta phenotype is not directly proportional to the distance of the mutation from the amino-terminal end of the triple helix. These findings could be explained if the type I collagen triple helix contains discontinuous domains that differ in their contributions to maintaining helix stability.     

Recombinant collagen studies link the severe conformational changes induced by osteogenesis imperfecta mutations to the disruption of a set of interchain salt bridges

The clinical severity of Osteogenesis Imperfecta (OI), also known as the brittle bone disease, relates to the extent of conformational changes in the collagen triple helix induced by Gly substitution mutations. The lingering question is why Gly substitutions at different locations of collagen cause different disruptions of the triple helix. Here, we describe markedly different conformational changes of the triple helix induced by two Gly substitution mutations placed only 12 residues apart. The effects of the Gly substitutions were characterized using a recombinant collagen fragment modeling the 63-residue segment of the alpha1 chain of type I collagen containing no Hyp (residues 877-939) obtained from Escherichia coli. Two Gly --> Ser substitutions at Gly-901 and Gly-913 associated with, respectively, mild and severe OI variants were introduced by site-directed mutagenesis. Biophysical characterization and limited protease digestion experiments revealed that while the substitution at Gly-901 causes relatively minor destabilization of the triple helix, the substitution at Gly-913 induces large scale unfolding of an unstable region C-terminal to the mutation site. This extensive unfolding is caused by the intrinsic low stability of the C-terminal region of the helix and the mutation induced disruption of a set of salt bridges, which functions to lock this unstable region into the triple helical conformation. The extensive conformational changes associated with the loss of the salt bridges highlight the long range impact of the local interactions of triple helix and suggest a new mechanism by which OI mutations cause severe conformational damages in collagen.     

Type I collagen triplet duplication mutation in lethal osteogenesis imperfecta shifts register of alpha chains throughout the helix and disrupts incorporation of mutant helices into fibrils and extracellular matrix

The majority of collagen mutations causing osteogenesis imperfecta (OI) are glycine substitutions that disrupt formation of the triple helix. A rare type of collagen mutation consists of a duplication or deletion of one or two Gly-X-Y triplets. These mutations shift the register of collagen chains with respect to each other in the helix but do not interrupt the triplet sequence, yet they have severe clinical consequences. We investigated the effect of shifting the register of the collagen helix by a single Gly-X-Y triplet on collagen assembly, stability, and incorporation into fibrils and matrix. These studies utilized a triplet duplication in COL1A1 exon 44 that occurred in the cDNA and gDNA of two siblings with lethal OI. The normal allele encodes three identical Gly-Ala-Hyp triplets at aa 868-876, whereas the mutant allele encodes four. The register shift delays helix formation, causing overmodification. Differential scanning calorimetry yielded a decrease in T(m) of 2 degrees C for helices with one mutant chain and a 6 degrees C decrease in helices with two mutant chains. An in vitro binary co-processing assay of N-proteinase cleavage demonstrated that procollagen with the triplet duplication has slower N-propeptide cleavage than in normal controls or procollagen with proalpha1(I) G832S, G898S, or G997S substitutions, showing that the register shift persists through the entire helix. The register shift disrupts incorporation of mutant collagen into fibrils and matrix. Proband fibrils formed inefficiently in vitro and contained only normal helices and helices with a single mutant chain. Helices with two mutant chains and a significant portion of helices with one mutant chain did not form fibrils. In matrix deposited by proband fibroblasts, mutant chains were abundant in the immaturely cross-linked fraction but constituted a minor fraction of maturely cross-linked chains. The profound effects of shifting the collagen triplet register on chain interactions in the helix and on fibril formation correlate with the severe clinical consequences.     

Asymmetry in the triple helix of collagen-like heterotrimers confirms that external bonds stabilize collagen structure

Heating and subsequent cooling mixtures of (Pro-Pro-Gly)(10) and (Pro-Hyp-Gly)(10) peptides leads to formation of model heterotrimeric collagen helices that can be isolated by HPLC. These heterotrimeric collagen peptide helices are shown to be fundamentally unstable as denaturing then renaturing experiments result in heterotrimeric/homotrimeric mixtures.As the proportion of hydroxyproline-containing chains in the trimers increases, differential scanning calorimetry shows that the helix melting temperatures and denaturation enthalpies increasing non-linearly. Three types of Rich-Crick hydrogen bonds observed by NMR allow modelling of heterotrimeric structures based on published homotrimeric X-ray data. This revealed a small axial movement of (Pro-Hyp-Gly)(10) chains towards the C-terminal of the helix, demonstrating heterotrimeric asymmetry.     

Structural heterogeneity of type I collagen triple helix and its role in osteogenesis imperfecta

We investigated regions of different helical stability within human type I collagen and discussed their role in intermolecular interactions and osteogenesis imperfecta (OI). By differential scanning calorimetry and circular dichroism, we measured and mapped changes in the collagen melting temperature (DeltaTm) for 41 different Gly substitutions from 47 OI patients. In contrast to peptides, we found no correlations of DeltaTm with the identity of the substituting residue. Instead, we observed regular variations in DeltaTm with the substitution location in different triple helix regions. To relate the DeltaTm map to peptide-based stability predictions, we extracted the activation energy of local helix unfolding (DeltaG) from the reported peptide data. We constructed the DeltaG map and tested it by measuring the H-D exchange rate for glycine NH residues involved in interchain hydrogen bonds. Based on the DeltaTm and DeltaG maps, we delineated regional variations in the collagen triple helix stability. Two large, flexible regions deduced from the DeltaTm map aligned with the regions important for collagen fibril assembly and ligand binding. One of these regions also aligned with a lethal region for Gly substitutions in the alpha1(I) chain.     

Substitutions for glycine alpha 1-637 and glycine alpha 2-694 of type I procollagen in lethal osteogenesis imperfecta. The conformational strain on the triple helix introduced by a glycine substitution can be transmitted along the helix

Two substitutions for glycine in the triple-helical domain were found in type I procollagen synthesized by skin fibroblasts from two probands with lethal osteogenesis imperfecta. One was a substitution of valine for glycine alpha 1-637, and the other was a substitution of arginine for glycine alpha 2-694. The effects of the mutations on the zipper-like folding of the collagen triple helix were similar, since there was post-translational overmodification of the collagenase A fragments (amino acids 1-775) but not of more COOH-terminal fragments of the protein. The mutations differed markedly, however, on their effects on thermal unfolding of the triple helix. The collagenase A fragment from the collagen containing the arginine alpha 2-694 substitution was cleaved at about amino acid 700 when incubated with trypsin at 30-35 degrees C. Therefore, there was micro-unfolding of the triple helix at a site close to the glycine substitution. Surprisingly, however, the collagenase A fragment with the valine alpha 1-637 substitution was also cleaved at about amino acid 700 under the same conditions. The results, therefore, demonstrated that although most glycine substitutions delay folding of the triple helix in regions that are NH2-terminal to the site of the substitution, the effects on unfolding can be transmitted to regions that are COOH-terminal to the site of the glycine substitution.     

Substitution of serine for alpha 1(I)-glycine 844 in a severe variant of osteogenesis imperfecta minimally destabilizes the triple helix of type I procollagen. The effects of glycine substitutions on thermal stability are either position of amino acid specific

Recent reports have demonstrated that a series of probands with severe osteogenesis imperfecta had single base mutations in one of the two structural genes for type I procollagen that substituted amino acids with bulkier side chains for glycine residues and decreased the melting temperature of the triple helix. Here we demonstrate that the type I procollagen synthesized by cultured fibroblasts from a proband with a severe form of osteogenesis imperfecta consisted of normal molecules and molecules over-modified by post-translational reactions. The thermal stability of the intact type I collagen was normal as assayed by protease digestion under conditions in which a decrease in thermal stability was previously observed with eight other substitutions for glycine in the alpha 1(I) chain. In contrast, the thermal stability of the one-quarter length B fragment generated by digestion with vertebrate collagenase was decreased by 2-3 degrees C under the same conditions. Nucleotide sequencing of cDNAs and genomic DNA established that the proband had a substitution of A for G in one allele of the pro alpha 1(I) gene that converted the codon for alpha 1-glycine 844 to a codon for serine. The results also established that the alpha 1-serine 844 was the only mutation that could account for the decrease in thermal stability of the collagenase B fragment. There are at least two possible explanations for the failure of the alpha 1-serine 844 substitution to decrease the thermal stability of the collagen molecule whereas eight similar mutations decreased the melting temperature. One possibility is that the effects of glycine substitutions are position specific because not all glycine residues make equivalent contributions to cooperative blocks of the triple helix that unfold in the predenaturation range of temperatures. A second possible explanation is that substitutions of glycine by serine have much less effect on the stability of protein than the substitutions by arginine, cysteine, and aspartate previously studied.     

The effect of the L-azetidine-2-carboxylic acid residue on protein conformation. III. Collagen-like poly(tripeptide)s

The chemical and biological properties of collagen are altered by the biosynthetic substitution of the L-azetidine-2-carboxylic acid(Aze) residue in the place of proline. The reasons for this alteration have been studied by means of conformational energy computations on single- and triple-stranded structures formed by poly(Gly-X-Y) poly(tripeptide)s, where X and Y can be Pro or Aze. The most stable triple helix formed by Poly(Gly-Pro-Aze) is collagen-like, but all low-energy triple helices that can be formed by poly(Gly-Aze-Pro) and poly(Gly-Aze-Aze) are very different from collagen. Thus, the regular substitution of Aze for Pro in position X is not compatible with the collagen structure. In the absence of solvent effects, all of these triple helices are stable, relative to the statistical coil, but the substitutions reduce the stability of the collagen-like triple helix, as compared with poly(Gly-Pro-Pro).     

The role of context on alpha-helix stabilization: host-guest analysis in a mixed background peptide model.

The helix content of a series of peptides containing single substitutions of the 20 natural amino acids in a new designed host sequence, succinyl-YSEEEEKAKKAXAEEAEKKKK-NH2, has been determined using CD spectroscopy. This host is related to one previously studied, in which triple amino acid substitutions were introduced into a background of Glu-Lys blocks completely lacking alanine. The resulting free energies show that only Ala and Glu- prove to be helix stabilizing, while all other side chains are neutral or destabilizing. This agrees with results from studies of alanine-rich peptide modela, but not the previous Glu-Lys block oligomers in which Leu and Met also stabilize helix. The helix propensity scale derived from the previous block oligomers correlated well with the frequencies of occurrence of different side chains in helical sequences of proteins, whereas the values from the present series do not. The role of context in determining scales of helix propensity values is discussed, and the ability of algorithms designed to predict helix structure from sequence is compared.     

Helix 8 and helix 10 are involved in substrate recognition in the rat monocarboxylate transporter MCT1.

Transport of lactate, pyruvate, and the ketone bodies, acetoacetate and beta-hydroxybutyrate, is mediated in many mammalian cells by the monocarboxylate transporter MCT1. To be accepted as a substrate, a carboxyl group and an unpolar side chain are necessary. Site-directed mutagenesis of the rat MCT1 was used to identify residues which are involved in substrate recognition. Helices 8 and 10 but not helix 9 were found to contain critical residues for substrate recognition. Mutation of arginine 306 to threonine in helix 8 resulted in strongly reduced transport activity. Concomitantly, saturable transport was transformed into a nonsaturable dependence of transport activity on lactate concentration, suggesting that binding of the substrate was strongly impaired. Furthermore, proton translocation in the mutant was partially uncoupled from monocarboxylate transport. Mutation of phenylalanine 360 to cysteine in helix 10 resulted in an altered substrate side chain recognition. In contrast to the wild-type transporter, monocarboxylates with more bulky and polar side chains were recognized by the mutated MCT1. Mutation of selected residues in helix 9 and helix 11 (C336A, H337Q, and E391Q) did not cause alterations of the transport properties of MCT1. It is suggested that substrate binding occurs in the carboxy-terminal half of MCT1 and that helices 8 and 10 are involved in the recognition of different parts of the substrate.     

Thermostability gradient in the collagen triple helix reveals its multi-domain structure

A triple-helical conformation and stability at physiological temperature are critical for the mechanical and biological functions of the fibril-forming collagens. Here, we characterized the role of consecutive domains of collagen II in stabilizing the triple helix. Analysis of melting temperatures of genetically engineered collagen-like proteins consisting of tandem repeats of the D1, D2, D3 or D4 collagen II periods revealed the presence of a gradient of thermostability along the collagen molecule with thermolabile N-terminal domains and thermostable C-terminal domains. These results imply a multi-domain character of the collagen triple helix. Assays of thermostabilities of the Arg75Cys and Arg789Cys collagen II mutants suggest that, in contrast to the thermostable domains, the thermolabile domains are able to accommodate amino acid substitutions without altering the thermostability of the entire collagen molecule.     

His-391 of beta-galactosidase (Escherichia coli) promotes catalyses by strong interactions with the transition state.

His-391 of beta-galactosidase (Escherichia coli) was substituted by Phe, Glu, and Lys. Homogeneous preparations of the substituted enzymes were essentially inactive unless very rapid purifications were performed, and the assays were done immediately. The inactive enzymes were tetrameric, just like wild-type beta-galactosidase and their fluorescence spectra were identical to the fluorescence spectrum of wild-type enzyme. Analyses of two of the substituted enzymes that were very rapidly purified to homogeneity and rapidly assayed while they were still active (at only a few substrate concentrations so that the data could be rapidly obtained), showed that the kinetic values were very similar to the values obtained with the same enzymes that were only partially purified. This showed that the kinetics were not affected by the degree of purity and allowed kinetic analyses with partially purified enzymes so that large numbers of points could be used for accuracy. The data showed that His-391 is a very important residue. It interacts strongly with the transition state and promotes catalysis by stabilizing the transition state. Activation energy differences (deltadelta G(S) double dagger), as determined by differences in the kcat/Km values, indicated that substitutions for His-391 caused very large destabilizations (22.8-35.9 kJ/mol) of the transition state. The importance of His-391 for transition state stabilization was confirmed by studies that showed that transition state analogs are very poor inhibitors of the substituted enzymes, while inhibition by substrate analogs was only affected in a small way by substituting for His-391. The poor stabilities of the transition states caused significant decreases of the rates of the glycolytic cleavage steps (galactosylation, k2). Degalactosylation (k3) was not decreased to the same extent.     

Production of human type I collagen in yeast reveals unexpected new insights into the molecular assembly of collagen trimers

Substantial evidence supports the role of the procollagen C-propeptide in the initial association of procollagen polypeptides and for triple helix formation. To evaluate the role of the propeptide domains on triple helix formation, human recombinant type I procollagen, pN-collagen (procollagen without the C-propeptides), pC-collagen (procollagen without the N-propeptides), and collagen (minus both propeptide domains) heterotrimers were expressed in Saccharomyces cerevisiae. Deletion of the N- or C-propeptide, or both propeptide domains, from both proalpha-chains resulted in correctly aligned triple helical type I collagen. Protease digestion assays demonstrated folding of the triple helix in the absence of the N- and C-propeptides from both proalpha-chains. This result suggests that sequences required for folding of the triple helix are located in the helical/telopeptide domains of the collagen molecule. Using a strain that does not contain prolyl hydroxylase, the same folding mechanism was shown to be operative in the absence of prolyl hydroxylase. Normal collagen fibrils were generated showing the characteristic banding pattern using this recombinant collagen. This system offers new opportunities for the study of collagen expression and maturation.     

Mechanism of collagen folding propagation studied by Molecular Dynamics simulations

Collagen forms a characteristic triple helical structure and plays a central role for stabilizing the extra-cellular matrix. After a C-terminal nucleus formation folding proceeds to form long triple-helical fibers. The molecular details of triple helix folding process is of central importance for an understanding of several human diseases associated with misfolded or unstable collagen fibrils. However, the folding propagation is too rapid to be studied by experimental high resolution techniques. We employed multiple Molecular Dynamics simulations starting from unfolded peptides with an already formed nucleus to successfully follow the folding propagation in atomic detail. The triple helix folding was found to propagate involving first two chains forming a short transient template. Secondly, three residues of the third chain fold on this template with an overall mean propagation of ~75 ns per unit. The formation of loops with multiples of the repeating unit was found as a characteristic misfolding event especially when starting from an unstable nucleus. Central Gly→Ala or Gly→Thr substitutions resulted in reduced stability and folding rates due to structural deformations interfering with folding propagation.     

Stability, activity and flexibility in alpha-lactalbumin.

alpha-Lactalbumins and the type-c lysozymes are homologues with similar folds that differ in function and stability. To determine if the lower stability of alpha-lactalbumin results from specific substitutions required for its adaptation to a new function, the effects of lysozyme-based and other substitutions on thermal stability were determined. Unblocking the upper cleft in alpha-lactalbumin by replacing Tyr103 with Ala, perturbs stability and structure but Pro, which also generates an open cleft, is compatible with normal structure and activity. These effects appear to reflect alternative enthalpic and entropic forms of structural stabilization by Tyr and Pro. Of 23 mutations, only three, which involve substitutions for residues in flexible substructures adjacent to the functional site, increase stability. Two are lysozyme-based substitutions for Leu110, a component of a region with alternative helix and loop conformations, and one is Asn for Lys114, a residue whose microenvironment changes when alpha-lactalbumin interacts with its target enzyme. While all substitutions for Leu110 perturb activity, a Lys114 to Asn mutation increases T(m) by more than 10 degrees C and reduces activity, but two other destabilizing substitutions do not affect activity. It is proposed that increased stability and reduced activity in Lys114Asn result from reduced flexibility in the functional site of alpha-lactalbumin.     

Deletion of a Gly-Pro-Pro repeat in the proα2(I) chain of procollagen I in a family with dominant osteogenesis imperfecta type IV

We have investigated one member of a family with dominant osteogenesis imperfecta type IV through three generations. In protein-chemical studies of cultured fibroblasts derived from the proband, collagen I was overmodified, with normal processing of procollagen 1, normal thermal stability, and a cyanogen bromide peptide map that suggested a C-terminal location of the structural abnormality in the collagen triple helix. Sequencing of the gene encoding the 2(I) chain of collagen I (COL1A2) indicated a nine base-pair deletion of nucleotides 3418–3426. When a polymerase chain reaction product containing the nucleotides in question was electrophoresed in a 12% polyacrylamide gel, two bands with a difference in size of nine base pairs could be shown. Sequencing of the lower molecular weight band confirmed the deletion of the nine base pairs involving codons 1003–1006 of COL1A2. The deletion introduced aSfiI restriction site that was used for confirmation of the deletion in genomic DNA from the proband. The deletion resulted in the removal of three amino acids (Gly-Pro-Pro), but this did not disrupt the Gly-X-Y sequence of the collagen triple helix, as is often the case in the more common glycine substitutions. We discuss the ways in which this deletion could result in osteogenesis imperfecta.     

Transmembrane segment 3 of the Glut1 glucose transporter is an outer helix

A model has been proposed for the structure of the Glut1 glucose transporter based on the results of mutagenesis studies and homology modeling in which eight transmembrane segments form an inner helical bundle surrounded by four outer helices. The role of transmembrane segment 3 in this structural model was investigated using cysteine-scanning mutagenesis in conjunction with the membrane-impermeant, sulfhydryl-specific reagent, p-chloromercuribenzenesulfonate (pCMBS). Twenty-one Glut1 mutants were created from a fully functional, cysteine-less, parental Glut1 molecule by successively changing each residue along transmembrane helix 3 to a cysteine. The single cysteine mutants were then expressed in Xenopus oocytes, and their expression levels, transport activities, and sensitivities to pCMBS were determined. Cysteine substitution at methionine 96 abolished transport activity, whereas substitutions at the other positions resulted in either modest reductions or no significant effect on transport activity. In striking contrast to all other helices that have been examined to date, only one of the 21 helix 3 single-cysteine mutants was inhibited by pCMBS, suggesting that only a small portion of this helix is exposed to the external solvent. This result is consistent with predictions based on our current structural model, in which helix 3 is one of four outer helices that surround the inner helical bundle that comprises the aqueous substrate-binding cavity. An updated two-dimensional model for the orientation of the 12 transmembrane helices and the conformation of the exofacial glucose-binding site of Glut1 is presented that is consistent with existing experimental data.