Attaching human fibroblasts secrete a type I procollagen rich in 3-hydroxyproline.

The predominant collagenous protein secreted during the attachment of freshly trypsinized human foreskin fibroblasts was found to be Type I procollagen. Evidence is presented that both the α₁ and α₂ chains exhibit a 3-hydroxyproline/4-hydroxyproline ratio 4–5 fold higher than that of normal Type I collagen. These findings suggest that caution should be exercised in assigning an observed increase in the 3-hydroxyproline/4-hydroxyproline ratio to the synthesis of a basement membrane type collagen.     

The synthesis of macromolecular 3-hydroxyproline by attaching and confluent cultures of human fibroblasts.

The synthesis of collagen has been studied during the attachment of freshly trypsinized human fibroblasts to culture vessels by measurement of the incorporation of radioactive proline into macromolecular hydroxyproline. Collagenous protein(s) was found to be a component of a substrate-attached material ('microexudate carpet') synthesized rapidly during cell attachment in the absence of serum. The ratio of 3-hydroxyproline/4-hydroxyproline in the collagenous proteins synthesized during cell attachment was found to be 4-5 fold higher than that of normal type I collagen. The synthesis of 3-hydroxyproline by confluent cultures was diminished by serum deprivation, and was shown to require higher concentrations of ascorbate than the synthesis of the 4-hydroxy isomer.     

A novel 3-hydroxyproline (3Hyp)-rich motif marks the triple-helical C terminus of tendon type I collagen

Because of its unique physical and chemical properties, rat tail tendon collagen has long been favored for crystallographic and biochemical studies of fibril structure. In studies of the distribution of 3-hydroxyproline in type I collagen of rat bone, skin, and tail tendon by mass spectrometry, the repeating sequences of Gly-Pro-Pro (GPP) triplets at the C terminus of α1(I) and α2(I) chains were shown to be heavily 3-hydroxylated in tendon but not in skin and bone. By isolating the tryptic peptides and subjecting them to Edman sequence analysis, the presence of repeating 3-hydroxyprolines in consecutive GPP triplets adjacent to 4-hydroxyproline was confirmed as a unique feature of the tendon collagen. A 1960s study by Piez et al. (Piez, K. A., Eigner, E. A., and Lewis, M. S. (1963) Biochemistry 2, 58-66) in which they compared the amino acid compositions of rat skin and tail tendon type I collagen chains indeed showed 3-4 residues of 3Hyp in tendon α1(I) and α2(I) chains but only one 3Hyp residue in skin α1(I) and none in α2(I). The present work therefore confirms this difference and localizes the additional 3Hyp to the GPP repeat at the C terminus of the triple-helix. We speculate on the significance in terms of a potential function in contributing to the unique assembly mechanism and molecular packing in tendon collagen fibrils and on mechanisms that could regulate 3-hydroxylation at this novel substrate site in a tissue-specific manner.     

Glycosylated Threonine but not 4-Hydroxyproline Dominates the Triple Helix Stabilizing Positions in the Sequence of a Hydrothermal Vent Worm Cuticle Collagen

The cuticle collagen of the vestimentiferanRiftia pachyptila, an organism which is endemic to deep-sea hydrothermal vents, has several unusual properties including an extraordinary length (1.5 μm), a high thermal stability (37°C) in spite of a low 4-hydroxyproline content and an atypically high threonine content (20 mol%). We have now purified the constituent chain of cuticle collagen and show that it contains about 40% carbohydrate, which is mainly galactose, indicating that the chain has a molecular mass of approximately 750 kDa. Several large (30 to 150 kDa) fragments, which all contained carbohydrate, could be produced by cleavage with endoproteinase Lys-C, bacterial collagenase and cyanogen bromide (CNBr). Edman degradation of these and several smaller fragments was used to determine about 3000 sequence positions comprising 60% of the total triple-helical sequence. This demonstrated mainly typical Gly-X-Y triplet repeats with a few imperfections and a longer N-terminal non-triplet sequence. Most of the 4-hydroxyproline was found in triplet position X, where it decreases the stability of the triple helix. About 40% of the Y positions could not be identified, which correlated with a low abundance of threonine in the sequence and the demonstration of threonine in these positions after deglycosylation of several peptides by treatment with hydrofluoric acid. Matrix-assisted laser desorption ionisation mass spectrometry of selected peptides indicated that the blocked threonine residues are occupied by chains of one, two or three hexoses (presumably galactose). These glycosylated threonine residues in Y positions are therefore likely to replace 4-hydroxyproline as the major contributor to triple helix stabilization. Studies with a synthetic (Gly-Pro-Thr)₁₀oligopeptide demonstrated a low thermal stability of its triple helix which emphasizes a crucial role of glycosylation for stabilization.     

Evidence for the role of 4-hydroxyproline localized in the third position of the triplet (Gly-X-Y) in adaptational changes of thermostability of a collagen molecule and collagen fibrils

An analysis of the available data on the thermostability and imino acid content of various collagens has shown that the change of the denaturation temperature (t_m) of the collagen triple helix, as well as the temperature of hydrothermic shrinkage (t_s) of collagen fibrils, depends on the number of hydroxyproline residues localized in the third position of the collagen triplet. This change does not depend on the content of proline and 3- and 4-hydroxyproline localized in the second position of the triplet. Empiric equations have been obtained connecting t_m and t_s with the content of 4-hydroxyproline. The results of the analysis are in good agreement with one of the collagen structure models recently proposed by the Ramachandran school.     

Amino-acid sequence and cell-adhesion activity of a fibril-forming collagen from the tube worm Riftia pachyptila living at deep sea hydrothermal vents.

We have determined the amino acid sequence of the alpha chain of a fibril-forming collagen from the body wall of the marine invertebrate Riftia pachyptila (vestimentifera) by Edman degradation. The pepsin-solubilized collagen chain consists of a 1011-residue triple-helical domain and short remnants of N- and C-telopeptides. The triple-helical sequence showed one imperfection of the collagen Gly-Xaa-Yaa triplet repeat structure due to a Gly-->Ala substitution. This imperfection is correlated to a prominent kink in the molecule observed by electron microscopy. No strong sequence similarity was found with the fibril-forming vertebrate collagen types I-III, V and XI except for the invariant Gly residues. However, one of the two consensus cross-linking sequences was well conserved. The Riftia collagen shared with the vertebrate collagens many post-translational modifications. About 50% of the Pro and Lys residues are found in the Yaa position and were extensively hydroxylated to 4-hydroxyproline (4Hyp) and hydroxylysine (Hyl). A few proline residues in Xaa position were partially hydroxylated to either 4Hyp or 3Hyp. Despite the low sequence similarity, Riftia collagen was a potent adhesion substrate for two human cell lines. Cell adhesion could be inhibited by antibodies against the integrin beta 1 subunit but not by RGD peptides. This biological activity is apparently conserved in fibril-forming collagens of distantly related species but does not require the two RGD sequences present in Riftia collagen.     

Separation of prolyl 3-hydroxylase and 4-hydroxylase activities and the 4-hydroxyproline requirement for synthesis of 3-hydroxyproline

Differences between prolyl 3-hydroxylase and prolyl 4-hydroxylase activities were found in their stimulation and inactivation by dithiothreitol and in their affinity to poly-L-proline linked to agarose. The two enzyme activities were separated by gel filtration, the results demonstrating that they are due to separate proteins. Comparison of [¹⁴C]proline-labelled protocollagen and the same protein when fully 4-hydroxylated as substrates indicated dependence of 3-hydroxyproline formation on the presence of 4-hydroxyproline. It is suggested that the main substrate sequence for 3-hydroxyproline synthesis is -Gly-Pro-4Hyp-Gly-.     

A new rapid method for quantitating radioactive proline, 4-hydroxyproline,and 3-hydroxyproline

A simple and rapid method for separating proline, 4-hydroxyproline and 3-hydroxyproline was developed by the use of high-voltage electrophoresis. An excellent counting efficiency of proline was achieved by a simple extraction of the labeled material from paper; 98–100% recovery of count rates was obtained, equivalent to recoveries from column chromatography. This method can tolerate high concentrations of salt, acid, and protein in the sample. No carrier is required and multiple samples (up to 15) can be separated on a single sheet and analyzed within 2 h. Serial dilution experiments showed excellent linearity. An average recovery rate of 92% was obtained for samples over a wide range of radioactivity and high sensitivity of the method was demonstrated. This analysis is applicable to protein hydrolysates and to determination of the free amino acids in the presence of protein. Thus, proline, 4-hydroxyproline and 3-hydroxyproline can be quantitated simultaneously in any biological sample.     

The peptides acetyl-(Gly-3(S)Hyp-4(R)Hyp)10-NH2 and acetyl-(Gly-Pro-3(S)Hyp)10-NH2 do not form a collagen triple helix

Hydroxylation of proline residues in the Yaa position of the Gly-Xaa-Yaa repeated sequence to 4(R)-hydroxyproline is essential for the formation of the collagen triple helix. A small number of 3(S)-hydroxyproline residues are present in most collagens in the Xaa position. Neither the structural nor a biological role is known for 3(S)-hydroxyproline. To characterize the structural role of 3(S)-hydroxyproline, the peptide Ac-(Gly-3(S)Hyp-4(R)Hyp)10-NH2 was synthesized and analyzed by circular dichroism spectroscopy, analytical ultracentrifugation, and 1H nuclear magnetic resonance spectroscopy. At 4 degrees C in water the circular dichroism spectrum indicates that this peptide was in a polyproline-II-like secondary structure with a positive peak at 225 nm similar to Ac-(Gly-Pro-4(R)Hyp)10-NH2. The positive peak at 225 nm almost linearly decreases with increasing temperature to 95 degrees C without an obvious transition. Although the peptide Ac-(Gly-Pro-4(R)Hyp)10-NH2 forms a trimer at 10 degrees C, sedimentation equilibrium experiments indicate that Ac-(Gly-3(S)Hyp-4(R)Hyp)10-NH2 is a monomer in water at 7 degrees C. To study the role of 3(S)-hydroxyproline in the Yaa position, we synthesized Ac-(Gly-Pro-3(S)Hyp)10-NH2. This peptide also does not form a triple helix in water. 1H Nuclear magnetic resonance spectroscopy data (including line widths and nuclear Overhauser effects) are entirely consistent, with neither Ac-(Gly-3(S)Hyp-4(R)Hyp)10-NH2 nor Ac-(Gly-Pro-3(S)Hyp)10-NH2 forming a triple helix in water. Therefore 3(S)-hydroxyproline destabilizes the collagen triple helix in either position. In contrast, when 3(S)-hydroxyproline is inserted as a guest in the highly stable -Gly-Pro-4(R)Hyperepeated host sequence, Ac-(Gly-Pro-4(R)Hyp)3-Gly-3(S)Hyp-4(R)Hyp-(Gly-Pro-4(R)Hyp)4-Gly-Gly-NH2 forms as stable a trimer (Tm=49.6 degrees C) as Ac-(Gly-Pro-4(R)Hyp)8-Gly-Gly-NH2 (Tm=48.9 degrees C). Given that Ac-(Gly-Pro-4(R)Hyp)3-Gly-4(R)Hyp-Pro-(Gly-Pro-4(R)Hyp)4-Gly-Gly-NH2 forms a triple helix nearly as stable as the above two peptides (Tm=45.0 degrees C) and the knowledge that Ac-(Gly-4(R)Hyp-Pro)10-NH2 does not form a triple helix, we conclude that the host environment dominates the structure of host-guest peptides and that these peptides are not necessarily accurate predictors of triple helical stability.     

Prolyl hydroxylase of earthworms. Substrate specificity of an enzyme from the subcuticular epithelium.

A relatively crude enzyme preparation derived from the subcuticular epithelium of earthworms catalyzed the formation of 4-hydroxyproline from prolyl residues in unhydroxylated natural collagens and in several synthetic collagen-like polypeptides. The specificity of hydroxylation differed from that of all vertebrate polyl hydroxylases in that (Gly-Pro-Ala)n was a much better substrate than (Gly-Ala-Pro)n. In contrast, however, only the so-called Y position proline (Gly-X-Y) was hydroxylated in Gly-Pro-Pro sequences derived either from natural collagen or from synthetic polypeptides; specificity of hydroxylation for the latter sequence is identical with that of the vertebrate enzymes. Little or no formation of 3-hydroxyproline could be demonstrated in preparations of the enzyme active as a 4-hydroxylase. In contrast with an earlier report from another laboratory, using a crude extract of earthworm body wall, we were unable to demonstrate either significant 3-hydroxyproline formation or efficient 4-hydroxylation of X position prolyl residues in synthetic polypeptides with the internal sequence Gly-Pro-Pro.     

Purification of rheumatoid synovial collagenase and its action on soluble and insoluble collagen.

1. The neutral collagenase released into the culture medium by explants of ehrumatoid synovial tissue has been purified by ultrafiltration and column chromatography, utilising Sephadex G-200, Sephadex QAE A-50 and Sephadex G-100 superfine. 2. The final collagenase preparation had a specific activity against thermally reconstituted collagen fibrils of 312 mug collagen degraded min-1 mg enzyme protein-1, representing more than a 1000-fold increase over that of the active culture medium. 3. Electrophoresis in polyacrylamide disc-gels with and without sodium dodecyl sulphate showed the enzyme to migrate as a single protein band. Elution experiments from polyacrylamide gels and chromatography columns have provided no evidence for the existence of more than one collagenase. 4. The molecular weight of the enzyme, as determined by dodecylsulphate-polyacrylamide gel electrophoresis, was 33000. 5. Data obtained from sutdies with the ion-exchange resin and from gel electrophoresis in acid and alkaline buffer systems suggested a basically charged enzyme. 6. It did not hydrolyse the synthetic collagen peptide Pz-Pro-Leu-Gly-Pro-D-Arg and non-specific protease activity was absent. 7. The collagenase attacked undenatured collagen in solution at 25 degrees C resulting in a 58% loss of viscosity and producing the two characteristic products TCA(3/4) and TCB(1/4). 8. At 37 degrees C and pH 8.0 both reconstituted collagen fibrils and gelatin were degraded to peptides of less than 10000 molecular weight. 9. As judged by the release of soluble hydroxyproline peptides and electron microscopic appearances the enzyme degraded human insoluble collagens derived from tendon and soft juxta-articular tissues although rates of attack were less than with reconstituted fibrils. 10. The data suggests that pure rheumatoid synovial collagenase at 37 degrees C and neutral pH can degrade gelatin, reconstituted fibrils and insoluble collagens without the intervention of non-specific proteases. 11. The different susceptibilities of various collagenous substrates to collagenase attack are discussed.     

Hydroxylation-induced stabilization of the collagen triple helix. Further characterization of peptides with 4(R)-hydroxyproline in the Xaa position

4(R)-Hydroxyproline in the Yaa position of the -Gly-Xaa-Yaa-repeated sequence of collagen plays a crucial role in the stability of the triple helix. Since the peptide (4(R)-Hyp-Pro-Gly)10 does not form a triple helix, it was generally believed that polypeptides with a -Gly-4(R)-Hyp-Yaa-repeated sequence do not form a triple helix. Recently, we found that acetyl-(Gly-4(R)-Hyp-Thr)10-NH2 forms a triple helix in aqueous solutions. To further study the role of 4(R)-hydroxyproline in the Xaa position, we made a series of acetyl-(Gly-4(R)-Hyp-Yaa)10-NH2 peptides where Yaa was alanine, serine, valine, and allo-threonine. We previously hypothesized that the hydroxyl group of threonine might form a hydrogen bond to the hydroxyl group of 4(R)hydroxyproline. In water, only the threonine- and the valine-containing peptides were triple helical. The remaining peptides did not form a triple helix in water. In 1,2- and in 1,3-propanediol at 4 degrees C, all the soluble peptides were triple helical. From the transition temperature of the triple helices, it was found that among the examined residues, threonine was the most stable residue in the acetyl-(Gly-4(R)-Hyp-Yaa)10-NH2 peptide. The transition temperatures of the valine- and allo-threonine-containing peptides were 10 degrees lower than those of the threonine peptide. Surprisingly, the serine-containing peptide was the least stable. These results indicate that the stability of these peptides depends on the presence of a methyl group as well as the hydroxyl group and that the stereo configuration of the two groups is essential for the stability. In the threonine peptide, we hypothesize that the methyl group shields the interchain hydrogen bond between the glycine and the Xaa residue from water and that the hydroxyl groups of threonine and 4(R)hydroxyproline can form direct or water-mediated hydrogen bonds.     

The occurrence of two types of collagen proalpha-chain in the abalone Haliotis discus muscle.

Acid-soluble collagens were prepared from connective tissues in the abalone Haliotis discus foot and adductor muscles with limited proteolysis using pepsin. Collagen preparation solubilized with 1% pepsin contained two types of alpha-chains which were different in their N-terminal amino acid sequences. Accordingly, two types of full-length cDNAs coding for collagen proalpha-chains were isolated from the foot muscle of the same animal and these proteins were named Hdcols (Haliotis discus collagens) 1alpha and 2alpha. The two N-terminal amino acid sequences of the abalone pepsin-solubilized collagen preparation corresponded to either of the two sequences deduced from the cDNA clones. In addition, several tryptic peptides prepared from the pepsin-solubilized collagen and fractionated by HPLC showed N-terminal amino acid sequences identical to those deduced from the two cDNA clones. Hdcols 1alpha and 2alpha consisted of 1378 and 1439 amino acids, respectively, showing the primary structure typical to those of fibril-forming collagens. The N-terminal propeptides of the two collagen proalpha-chains contained cysteine-rich globular domains. It is of note that Hdcol 1alpha completely lacked a short Gly-X-Y triplet repeat sequence in its propeptide. An unusual structure such as this has never before been reported for any fibril-forming collagen. The main triple-helical domains for both chains consisted of 1014 amino acids, where a supposed glycine residue in the triplet at the 598th position from the N-terminus was replaced by alanine in Hdcol 1alpha and by serine in Hdcol 2alpha. Both proalpha-chains of abalone collagens contained six cysteine residues in the carboxyl-terminal propeptide, lacking two cysteine residues usually found in vertebrate collagens. Northern blot analysis demonstrated that the mRNA levels of Hdcols 1alpha and 2alpha in various tissues including muscles were similar to each other.     

Collagen cross-linking. Isolation of cross-linked peptides from collagen of chicken bone

Cross-linked peptides were isolated from chicken bone collagen that had been digested with CNBr or with bacterial collagenase. Analyses of (3)H radioactivity in disc electrophoretic profiles of the CNBr peptides from bone collagens that had been treated with NaB(3)H indicated that a major site of intermolecular cross-linking in chicken bone collagen is located between the carboxy-terminal region of an alpha1 chain and a small CNBr peptide, probably situated near the amino-terminus of an alpha1 or alpha2 chain in an adjacent collagen molecule. A small amount of this cross-linked CNBr peptide was isolated from a CNBr digest of chicken bone collagen by column chromatography. Amino acid analysis showed that the CNBr peptide, alpha1CB6B, the carboxy-terminal peptide of the alpha1 chain, was the major CNBr peptide in the preparation, and the reduced cross-linking components were identified as hydroxylysinohydroxynorleucine (HylOHNle), with a smaller amount of hydroxylysinonorleucine (HylNle). However, the composition and the low recovery of the cross-linking amino acids suggested that the preparation was a mixture of CNBr peptides alpha1CB6B and alpha1CB6B cross-linked to a small CNBr peptide whose identity could not be determined. A small cross-linked peptide was isolated from chicken bone collagen that had been reduced with NaB(3)H(4) and digested with bacterial collagenase. This peptide was the major cross-linked peptide in the digest and contained a stoicheiometric amount of the reduced cross-linking compounds. A peptide which had the same amino acid composition, but contained the cross-linking compounds in their reducible forms, was isolated from a collagenase digest of chicken bone collagen that had not been treated with NaBH(4). The absence of the reduced cross-links from this peptide indicates that, at least for the cross-linking site from which the peptide derives, natural reduction is not a significant pathway for biosynthesis of stable cross-links. However, most of the reducible cross-linking component in the peptide appeared to stabilize in the bone collagen by rearrangement from aldimine to ketoamine form.     

Studies on the intracellular degradation of newly synthesized collagen in 3-methylcholanthrene induced fibrosarcoma cells.

The intracellular degradation of newly synthesized collagen was studied in both normal fibroblast and 3-methylcholanthrene induced fibrosarcoma cells. The degradation of newly synthesized collagen was examined using pulse-chase experiments and radioactive labelling techniques with [3H]-proline. The percentage of intracellular proteolysis of newly synthesized collagen was determined by measuring the formation of [3H]-hydroxyproline containing fragments in alcohol-soluble and insoluble fractions of normal cells and fibrosarcoma cells in the culture. The rate of degradation of newly formed collagen was then followed by estimating the radioactivity of [3H]-hydroxyproline at different intervals, during the chase period. The results clearly demonstrated that the percent of intracellular degradation of newly synthesized collagen was approximately three fold higher in fibrosarcoma cells than in normal fibroblast cells. The increased intracellular degradation of newly formed collagen was followed by an increase in the activity of cathepsin B and L in fibrosarcoma cells. The pulse-chase experiments indicated that the rate of degradation of newly synthesized collagen in fibrosarcoma cells is relatively greater than in normal fibroblast cells. In addition, as the labelling time increased, the formation of [3H]-hydroxyproline containing peptides in the ethanol-soluble fraction were found to be increased in both normal cells and fibrosarcoma cells, but the extent of formation was higher in fibrosarcoma cells compared to normal fibroblast cells. The results of this investigation collectively suggest that the intracellular degradation of newly synthesized collagen is enhanced in fibrosarcoma cells.     

Simplified procedure for the analysis of 3- and 4-hydroxyproline

A column chromatographic analysis of 3-hydroxyproline (3-Hyp), 4-hydroxyproline (4-Hyp), and γ-carboxyglutamic acid (Gla) is described. The analyses of urine and plasma were performed with a JLC-6AH amino acid analyzer. A 0.15 M sodium citrate buffer, pH 2.1, was used for elution. Urinary Gla, 3-Hyp, and 4-Hyp were among the seventeen peaks eluted before asparti acid. Hyp, Gla, glutamine, and asparagine in plasma were separated by elution with 0.2 M sodium citrate buffer, pH 3.25, containing 10% methanol. This single-column procedure achieves the sequential separation and quantitation of Gla, 3-Hyp, and 4-Hyp in urine as well as plasma, and is applicable to the diagnosis of collager, metabolism disorders.     

The differentiation of teratocarcinoma stem cells is marked by the types of collagen which are synthesized.

A cloned line of undifferentiated teratocarcinoma cells (OC15S1) was either maintained as a homogeneous embryonal carcinoma (EC) cell population or was cultured under conditions where the cells differentiated into endoderm-like (END) cells. In this study we examine the synthesis of collagen in both EC and END cells. Cell cultures were incubated with tritiated proline and lysine, and the radioactive collagen secreted into the medium was extracted and purified or immunoprecipitated by antibodies to type IV collagen (Adamson and Ayers, 1979). Radioactive collagens were identified by electrophoretic mobility, by sensitivity to collagenase and to reduction, by insensitivity to pepsin, by cyanogen bromide peptides, and by aminoacid analyses of 3-hydroxyproline, 4-hydroxyproline and proline. OC15S1 EC cells were found to synthesize several collagenous polypeptides, of which 60–70% of the radioactivity was like that of basement membrane (type IV) collagen. Type I-like collagen was the main collagenous product of END cells, but a minor product of EC cells. We concluded that type IV collagen synthesis was suppressed during the differentiation of EC cells to END, while type I-like synthesis was increased. Similarly, other EC cell lines produced mainly type IV-like collagen polypeptides (PC13, F9, PSA1), and following the formation of END cells, two lines produced mainly type I-like collagen polypeptides (PC13, C145b). The type of endoderm formed on embryoid bodies, however, presents an alternate route of differentiation, since immunoperoxidase tests showed that it was synthesizing significant amounts of type IV collagen. We discuss the significance of these findings in relation to a similar change which occurs during normal development.     

Sequence dependence of the folding of collagen-like peptides. Single amino acids affect the rate of triple-helix nucleation

The refolding of thermally denatured model collagen-like peptides was studied for a set of 21 guest triplets embedded in a common host framework: acetyl-(Gly-Pro-Hyp)3-Gly-Xaa-Yaa-(Gly-Pro-Hyp)4-Gly-Gly-amide. The results show a strong dependence of the folding rate on the identity of the guest Gly-Xaa-Yaa triplet, with the half-times for refolding varying from 6 to 110 min (concentration = 1 mg/ml). All triplets of the form Gly-Xaa-Hyp promoted rapid folding, with the rate only marginally dependent on the residue in the Xaa position. In contrast, triplets of the form Gly-Pro-Yaa and Gly-Xaa-Yaa were slower and showed a wide range of half-times, varying with the identity of the residues in the triplet. At low concentrations, the folding can be described by third-order kinetics, suggesting nucleation is rate-limiting. Data on the relative nucleation ability of different Gly-Xaa-Yaa triplets support the favorable nature of imino acids, the importance of hydroxyproline, the varying effects of the same residue in the Xaa position versus the Yaa position, and the difficulties encountered when leucine or aspartic acid are in the Yaa position. Information on the relative propensities of different tripeptide sequences to promote nucleation of the triple-helix in peptides will aid in identification of nucleation sites in collagen sequences.     

Characterization of recombinant human prolyl 3-hydroxylase isoenzyme 2, an enzyme modifying the basement membrane collagen IV

The single 3-hydroxyproline residue in the collagen I polypeptides is essential for proper fibril formation and bone development as its deficiency leads to recessive osteogenesis imperfecta. The vertebrate prolyl 3-hydroxylase (P3H) family consists of three members, P3H1 being responsible for the hydroxylation of collagen I. We expressed human P3H2 as an active recombinant protein in insect cells. Most of the recombinant polypeptide was insoluble, but small amounts were also present in the soluble fraction. P3H1 forms a complex with the cartilage-associated protein (CRTAP) that is required for prolyl 3-hydroxylation of fibrillar collagens. However, coexpression with CRTAP did not enhance the solubility or activity of the recombinant P3H2. A novel assay for P3H activity was developed based on that used for collagen prolyl 4-hydroxylases (C-P4H) and lysyl hydroxylases (LH). A large amount of P3H activity was found in the P3H2 samples with (Gly-Pro-4Hyp)5 as a substrate. The Km and Ki values of P3H2 for 2-oxoglutarate and its certain analogues resembled those of the LHs rather than the C-P4Hs. Unlike P3H1, P3H2 was strongly expressed in tissues rich in basement membranes, such as the kidney. P3H2 hydroxylated more effectively two synthetic peptides corresponding to sequences that are hydroxylated in collagen IV than a peptide corresponding to the 3-hydroxylation site in collagen I. These findings suggest that P3H2 is responsible for the hydroxylation of collagen IV, which has the highest 3-hydroxyproline content of all collagens. It is thus possible that P3H2 mutations may lead to a disease with changes in basement membranes.     

Purification of tadpole collagenase and characterization using collagen and synthetic substrates.

Tadpole collagenase hydrolyzed native and denatured collagen and synthetic peptides with sequences of 2,4-dinitrophenyl-L-prolyl-L-leucylglycyl-L-isoleucyl-L-alanylglycyl-L-arginie amide and 2,4-dinitrophenyl-L-prolyl-L-glutaminyl-glycyl-L-isoleucyl-L-alanylglycyl-L-glutaminyl-D-arginine. The specific enzyme activity against the latter substrate and collagen fibrils is found to be 933 nmol/min per mg protein and 8440 units (microgram collagen degraded/min), respectively. Optimum pH for the enzyme is 7.5-8.5. A collagenase complex with alpha2-macroglobulin did not hydrolyze collagen fibrils, but digested the synthetic substrates at the Gly-Ile bond. The amino acid composition of the enzyme was determined. Immunoelectrophoresis of the enzyme at pH 8.6 against anti-tadpole collagenase rabbit immunoglobulin G shows a single precipitin line at a position migrating faster than human serum albumin and corresponding to enzyme activity against collagen fibril and synthetic substrates.