Interaction of prolyl 4-hydroxylase with synthetic peptide substrates. A conformational model for collagen proline hydroxylation.

With the aim of understanding the structural basis for the substrate specificity of collagen prolyl 4-hydroxylase, we have studied the conformational features of synthetic oligopeptide substrates and their interaction with the enzyme purified from chicken embryo. Circular dichroism and infrared spectral data, taken in conjunction with relevant crystal structure data, indicated an equilibrium mixture of the polyproline-II (PP-II) helix, the beta-turn, and the random coil conformations in aqueous and trifluoroethanol solutions of the "collagen-related" peptides: t-Boc-Pro-Pro-Gly-Pro-OH, t-Boc-Pro-Pro-Gly-Pro-NHCH3, t-Pro-Pro-Gly-Pro-Pro-OH, t-Boc-Pro-Pro-Ala-Pro-OH, and t-Boc-Pro-Pro-Gln-Pro-OCH3, where t-Boc is tert-butoxycarbonyl. In another set of peptides related to elastin, t-Boc-Val-Pro-Gly-Val-OH and t-Boc-Gly-Val-Pro-Gly-Val-OH, the data indicated the beta-structure, rather than the PP-II helix, was in equilibrium with the beta-turn. Kinetic parameters for the enzymatic hydroxylation of the peptides showed that as a group, the first (proline-rich) set of peptides has higher Km values and lower Vmax and Kcat/Km values than the valine-rich peptides. Data on the inhibition of hydroxylation of the standard assay substrate (Pro-Pro-Gly)10 by the oligopeptides pointed to common binding sites for the peptides. Hydroxyproline-containing peptides had no effect on the hydroxylation of the standard substrate, showing the absence of product inhibition. Based on these and earlier data, we propose that in collagen and related peptides, a supersecondary structure consisting of the PP-II helix followed by the beta-turn is the minimal structural requirement for proline hydroxylation. The PP-II structure would aid effective interaction at the substrate binding subsites, while the beta-turn would be essential at the catalytic site of the enzyme. In elastin and related peptides, the beta-strand structure may be interchangeable with the PP-II structure. This conformational model for proline hydroxylation resolves the discrepancies in earlier proposals on the substrate specificity of prolyl 4-hydroxylase. It is also consistent with the available information on the active site geometry of the enzyme.     

Covalent modification of substrate-binding sites of Escherichia coli ADP-glucose synthetase. Isolation and structural characterization of 8-azido-ADP-glucose-incorporated peptides

A photoaffinity substrate analogue, 8-azido-ADP-[14C]glucose, reacts specifically and covalently with Escherichia coli ADP-glucose synthetase. The site(s) of reaction of 8-azido-ADP-[14C]glucose with the enzyme was identified by isolation of tryptic peptides containing the labeled analogue by use of high performance liquid chromatography technique and subsequent NH2-terminal sequence analysis of the purified radioactive peptides. One major binding region of the azido analogue is a peptide segment composed of residues 107-114 of the enzyme's polypeptide chain. Lys 108 and Arg 114 become trypsin-resistant sites when the enzyme is photoinactivated by 8-azido-ADP-[14C] glucose, suggesting that the analogue binds at or near the vicinity of these 2 basic amino acid residues. Conformational analysis of this peptide segment (residues 107-114) shows a strong probability of a reverse beta-turn secondary structure, suggesting that this peptide segment is on the enzyme surface. Two minor reaction regions of the enzyme with the analogue were also identified by chemical characterization. One region was composed of residues 162-207. Lys 194 was previously suggested as the activator-binding site by chemical modification studies with pyridoxal phosphate (Parsons, T. F., and Preiss, J. (1978) J. Biol. Chem. 253, 7638-7645). Another minor region where the analogue binds the tryptic peptide composed of residues 380-385 is near the COOH-terminal side of the enzyme. It is postulated that all these peptide segments are juxtaposed in tertiary structure.     

Hydroxylation of (Pro-Pro-Gly)5 and (Pro-Pro-Gly)10 by prolyl hydroxylase. Evidence for an asymmetric active site in the enzyme.

Previous studies with 14C-labeled synthetic peptides demonstrated that prolyl hydroxylase, which synthesizes the hydroxyproline in collagen, preferentially hydroxylates the fourth triplet from the NH-terminal end of the peptide (Pro-Pro-Gly)5. In the experiments reported here, the prolyl hydroxylase reaction was investigated further by preparing chemically modified derivatives of (Pro-Pro-Gly)5 and by synthesizing 14C-labeled preparations of (Pro-Pro-Gly)10. Essentially, the same kcat value was found for the hydroxylation of (Pro-Pro-Gly)5, N-acetyl-(Pro-Pro-Gly)5, (Pro-Pro-Gly)5 methyl ester, (Pro-Pro-Gly)10, and for larger polypeptide substrates of the enzyme. It appeared therefore that preferential hydroxylation of specific triplets in peptides of the structure (Pro-Pro-Gly)n cannot be explained by differences in the kinetic constants for individual triplets. Hydroxylation of 14C-labeled preparations of (Pro-Pro-Gly)10 demonstrated that the ninth triplet was preferentially hydroxylated over any other triplet. The results were best explained by the hypothesis that prolyl hydroxylase has an asymmetric active site in which binding subsites are located adjacent to but not symmetrical with the catalytic subsite.     

Characterization of collagenous peptides bound to lysyl hydroxylase isoforms

Lysyl hydroxylase (LH, EC 1.14.11.4) is the enzyme catalyzing the formation of hydroxylysyl residues in collagens and other proteins with collagenous domains. Although lower species, such as Caenorhabditis elegans, have only one LH orthologue, LH activity in higher species, such as human, rat, and mouse, is present in three molecules, LH1, LH2, and LH3, encoded by three different genes. In addition, LH2 is present in two alternatively spliced forms (LH2a, LH2b). To understand the functions of the four molecular forms of LH in vertebrates, we analyzed differences in the binding and hydroxylation of various collagenous peptides by the LH isoforms. Nine-amino acid-long synthetic peptides on Pepspot were used for the binding analysis and an activity assay to measure hydroxylation. Our data with 727 collagenous peptides indicated that a positive charge on the peptide and specific amino acid residues in close proximity to the lysyl residues in the collagenous sequences are the key factors promoting peptide binding to the LH isoforms. The data suggest that the LH binding site is not a deep hydrophobic pocket but is open and hydrophilic where acidic amino acids play an important role in the binding. The data do not indicate strict sequence specificity for the LH isoforms, but the data indicated that there was a clear preference for some sequences to be bound and hydroxylated by a certain isoform.     

Recombinant expression of hydroxylated human collagen in Escherichia coli

Collagen is the most abundant protein in the human body and thereby a structural protein of considerable biotechnological interest. The complex maturation process of collagen, including essential post-translational modifications such as prolyl and lysyl hydroxylation, has precluded large-scale production of recombinant collagen featuring the biophysical properties of endogenous collagen. The characterization of new prolyl and lysyl hydroxylase genes encoded by the giant virus mimivirus reveals a method for production of hydroxylated collagen. The coexpression of a human collagen type III construct together with mimivirus prolyl and lysyl hydroxylases in Escherichia coli yielded up to 90 mg of hydroxylated collagen per liter culture. The respective levels of prolyl and lysyl hydroxylation reaching 25 % and 26 % were similar to the hydroxylation levels of native human collagen type III. The distribution of hydroxyproline and hydroxylysine along recombinant collagen was also similar to that of native collagen as determined by mass spectrometric analysis of tryptic peptides. The triple helix signature of recombinant hydroxylated collagen was confirmed by circular dichroism, which also showed that hydroxylation increased the thermal stability of the recombinant collagen construct. Recombinant hydroxylated collagen produced in E. coli supported the growth of human umbilical endothelial cells, underlining the biocompatibility of the recombinant protein as extracellular matrix. The high yield of recombinant protein expression and the extensive level of prolyl and lysyl hydroxylation achieved indicate that recombinant hydroxylated collagen can be produced at large scale for biomaterials engineering in the context of biomedical applications.     

Asparaginyl hydroxylation of the Notch ankyrin repeat domain by factor inhibiting hypoxia-inducible factor

The stability and activity of hypoxia-inducible factor (HIF) are regulated by the post-translational hydroxylation of specific prolyl and asparaginyl residues. We show that the HIF asparaginyl hydroxylase, factor inhibiting HIF (FIH), also catalyzes hydroxylation of highly conserved asparaginyl residues within ankyrin repeat (AR) domains (ARDs) of endogenous Notch receptors. AR hydroxylation decreases the extent of ARD binding to FIH while not affecting signaling through the canonical Notch pathway. ARD proteins were found to efficiently compete with HIF for FIH-dependent hydroxylation. Crystallographic analyses of the hydroxylated Notch ARD (2.35A) and of Notch peptides bound to FIH (2.4-2.6A) reveal the stereochemistry of hydroxylation on the AR and imply that significant conformational changes are required in the ARD fold in order to enable hydroxylation at the FIH active site. We propose that ARD proteins function as natural inhibitors of FIH and that the hydroxylation status of these proteins provides another oxygen-dependent interface that modulates HIF signaling.     

The source of oxygen in the reaction catalysed by collagen lysyl hydroxylase.

The synthetic peptides (Pro-Pro-Gly)5 and (Ile-Lys-Gly)5-Phe were hydroxylated with collagen prolyl hydroxylase and lysyl hydroxylase in an 18O2 atmosphere. The oxygen atoms in the hydroxy groups of hydroxyproline and hydroxylysine were 87% and 6.5% respectively derived from the atmospheric 18O2. The results are consistent with those reported previously for proline hydroxylation in vivo [Fujimoto & Tamiya (1962) Biochem. J. 84, 333-335; Prockop, Kaplan & Udenfriend (1962) Biochem. Biophys. Res. Commun. 9, 192-196; Fujimoto & Tamiya (1963) Biochem. Biophys. Res. Commun. 10, 498-501; Prockop, Kaplan & Udenfriend (1963) Arch. Biochem. Biophys. 101, 499-503] and in vitro [Cardinale, Rhoads & Udenfriend (1971) Biochem. Biophys. Res. Commun. 43, 537-543] and for lysine hydroxylation in vivo [Fujimoto & Tamiya (1963) Biochem. Biophys. Res. Commun. 10, 498-501]. In view of the similarities of these two oxygenase-type hydroxylation reactions the participation of intermediates is proposed, the oxygen atoms of which are exchangeable with those of water. The atmospheric oxygen atoms incorporated into the intermediate must be equilibrated with water oxygen atoms in the slower lysyl hydroxylase reaction.     

Hydroxylation of lysyl residues in lysine-rich and arginine-rich histones by lysyl hydroxylase in vitro.

Lysine-rich and arginine-rich histones were examined as substrates for lysyl hydroxylase. Both proteins are known to be rich in lysyl residues, and lysine-rich histone also contains -X-Lys-Gly-sequences, whereas no such sequences are found in the arginine-rich histone. Both histones were found to be hydroxylated by lysyl hydroxylase, and the time courses of the hydroxylation reactions with these substrates were linear for at least 60 min. The Km values observed where 3 - 10(-6)M for heat-denatured lysine-rich histone and 6 - 10(-6)M for heat-denatured arginine-rich histone. Heat-denatured lysine-rich histone was hydroxylated at a higher rate than non-denatured both at 37 and 25 degrees C. No such phenomenon was found, however, when arginine-rich histone was examined as a substrate. Furthermore, at 37 degrees C lysine-rich histone was a better substrate for lysyl hydroxylase then arginine-rich histone, but this relationship was reversed at 25 degrees C. The synthesis of hydroxylysine observed with arginine-rich histone indicates that the lysyl hydroxylase preparation used in these experiments catalyzes the synthesis of hydroxylysine not only in the sequence -X-Lys-Gly-, but also in some other sequences. Certain collagen polypeptide chains are known to contain one hydroxlysyl residue in a sequence other than -X-Lys-Gly-, and the present results may explain this finding.     

Concomitant hydroxylation of proline and lysine residues in collagen using purified enzymes in vitro

Concomitant hydroxylation of proline and lysine residues in protocollagen was studied using purified enzymes. The data suggest that prolyl 4-hydroxylase (prolyl-glycyl-peptide, 2-oxoglutarate: oxygen oxidoreductase (4-hydroxylating), EC 1.14.11.2) and lysyl hydroxylase (peptidyllysine, 2-oxoglutarate; oxygen 5-oxidoreductase, EC 1.14.11.4) are competing for the protocollagen substrate, this competition resulting in an inhibition of the lysyl hydroxylase but not of the prolyl 4-hydroxylase reaction. When the same protocollagen was used for these hydroxylases, the affinity of prolyl 4-hydroxylase to the protocollagen substrate was about 2-fold higher than that of lysyl hydroxylase. Hydroxylation of lysine residues in protocollagen had no effect on the affinity of prolyl 4-hydroxylase, whereas hydroxylation of proline residues decreased the affinity of lysyl hydroxylase to one-half of the value determined before the hydroxylation. When enzyme preparations containing different ratios of lysyl hydroxylase activity to prolyl 4-hydroxylase activity were used to hydroxylase protocollagen substrate, it was found that in the case of a low ratio the hydroxylation of lysine residues seemed to proceed only after a short lag period. Accordingly, it seems probable that most proline residues are hydroxylated to 4-hydroxyproline residues before hydroxylation of lysine residues if the prolyl 4-hydroxylase and lysyl hydroxylase are present as free enzymes competing for the same protocollagen substrate.     

Collagen lysyl hydroxylation occurs within the cisternae of the rough endoplasmic reticulum.

Resolution of the heavy microsomal fraction of lung tissue by Ficoll density gradient centrifugation yielded a rough endoplasmic reticulum microsomal fraction containing the highest specific activity of detergent-released lysyl hydroxylase. This same microsomal fraction was previously shown to contain the highest specific activity of detergent-released prolyl hydroxylase activity. When hydroxylation was inhibited during the biosynthesis of collagen, this microsomal fraction contained lysine-rich, hydroxylysine-deficient, collagenase-digestible substrate that could be hydroxylated in the absence of detergent. The results indicate coordinate localization of both prolyl and lysyl hydroxylation reactions within the cisternae of the rough endoplasmic reticulum.     

Low-energy conformations of two lysine-containing tetrapeptides of collagen: implications for posttranslational lysine hydroxylation

The possible role of conformational constraints in the posttranslational hydroxylation of lysyl residues in collagen has been investigated by means of conformational energy computations for the N-acetyl-N′-methylamides of the four tetrapeptides Ala-Xxx-Gly-Ser and Gly-Xxx-Ala-Gly, where Xxx = Lys or Ala. When hydration is taken into account, all four peptides are shown to exist as a mixture of conformations, but there is a strong preference for type II bends in the conformational ensembles of two Ala-Xxx-Gly-Ser tetrapeptides and for type I bends in the conformational ensembles of the other two. The results agree with experimental evidence suggesting that a type II bend is an important conformation for Ac-Ala-Lys-Gly-Ser-NHCH₃, and they support an earlier suggestion that a β-bend may play a role in the posttranslational hydroxylation of Lys residues in position Y of the Gly-X-Y triplet in collagen.     

Structural aspects of hydroxyproline-containing proteins

The occurrence of hydroxyproline (Hyp) in collagen, C1q and acetylcholineesterase (AChE) raises important questions concerning the role of this unusual imino acid in the structure and function of these proteins. Available data on collagen indicate that Hyp is necessary for the normal secretion of the protein after its synthesis and for the integrity of the triple-helical conformation. Studies from our laboratory have dealt with the structural aspects of the posttranslational conversion of proline to hydroxyproline in collagen mediated by prolyl hydroxylase. We proposed that the beta-turn conformation at the Pro-Gly segments in the nascent procollagen molecule are the sites of the enzymatic hydroxylation and that this conformation changes over to the collagen-like helix as a result of the hydroxylation process. Recently, we have provided additional experimental support to our proposal by a) synthesizing specific beta-turn oligopeptides containing the Pro-Gly as well as Pro-Ala and Pro-DAla sequences and showing that these act as inhibitors of the enzymatic hydroxylation of a synthetic substrate and b) demonstrating, by circular dichroism spectroscopy, the occurrence of a conformational change leading to the triple-helix as a direct consequence of proline hydroxylation in a non-helical polypeptide substrate. We have also observed that the acquisition of hydroxylation results in a significant enhancement of the rate of folding of the polypeptide chain from the unfolded to the triple-helical conformation. We believe that our observations on proline hydroxylation in collagen should also be applicable to C1q and acetylcholineesterase both of which share the general structural and functional properties of collagen in their "tail" regions. Using the techniques employed in collagen studies, one should be able to assess the role of hydroxyproline in the folding, structural stabilities and functions of C1q and AChE. This would also involve the study of the unhydroxylated and hydroxylated precursors of these proteins which may share common structural features with their collagen counterparts. Finally, a systematic study of hydroxyproline-containing peptides and polypeptides has been initiated by us so as to understand the exact manner in which Hyp participates in the formation and stability of the triple-helical conformation in the proteins in which it occurs.     

Lysyl hydroxylase 2 is a specific telopeptide hydroxylase, while all three isoenzymes hydroxylate collagenous sequences.

Lysyl hydroxylase (LH), with three isoenzymes in vertebrates, catalyzes the formation of hydroxylysine by acting on -X-Lys-Gly- triplets in the collagenous domains of proteins of the collagen superfamily and also in -X-Lys-Ala- or -X-Lys-Ser- sequences in the telopeptides located at the ends of the polypeptide chains in some fibril-forming collagens. The hydroxylysine residues are essential for the stability of collagen crosslinks and act as carbohydrate attachment sites. The extent of lysine hydroxylation varies between collagen types, between tissues in the same collagen type and in certain diseases, suggesting that the LH isoenzymes may have different substrate specificities. We studied here the hydroxylation of synthetic peptides representing various hydroxylation sites in type I and IV collagens by purified recombinant LHs in vitro and of a recombinant full-length type I procollagen chain coexpressed with each LH in insect cells. All three LHs hydroxylated peptides representing collagenous sequences of type I and IV collagens, although with different K(m) and V(max) values. Furthermore, all three hydroxylated the collagenous domain of the coexpressed type I procollagen chain to a similar extent. None of the isoenzymes hydroxylated peptides representing the N and C telopeptides of type I collagen, but LH2, unlike the other two isoenzymes, hydroxylated the N telopeptide in the coexpressed procollagen chain. Hydroxylation of the telopeptide lysines by LH2 thus occurs only in the context of a long peptide. These data provide the first direct evidence that LH2 is a specific telopeptide hydroxylase, while all three LHs act on collagenous sequences.     

Reactivity of Lys(NH2)-containing peptides toward endopeptidases.

Lys(NH2)-containing peptides were subjected to various proteolytic enzymes which were selected for their well-documented specificity for arginyl and/or lysyl peptide bonds. Lys(NH2)-containing peptides were cleaved more rapidly by clostripain than the corresponding lysyl peptides. On the other hand, they proved to be resistant to Achromobacter protease I hydrolysis. The modified peptides synthesized in this study were more stable than the arginyl and lysyl analogues when incubated with trypsin or thrombin. The same tendency was observed when Lys(NH2)-containing peptides were incubated in diluted human serum, suggesting that the replacement of Arg or Lys by Lys(NH2) could be used to increase the stability of peptides in vivo.     

Structural aspects of Ca2+ binding by acyclic peptides: low-energy conformational domains and molecular dynamics of N-acetyl-L-prolyl-D-alanyl-L-alanine-N'-methylamide.

We have applied random-search, energy minimization and molecular dynamics simulations to investigate the structural aspects of the interaction of N-acetyl-L-prolyl-D-alanyl-L-alanine-N'-methylamide with Ca2+. Spectral data on related peptides had suggested that the beta-turn conformation might be a prerequisite for the binding of cation ion by such short linear peptides. In order to relate the conformational characteristics with the Ca(2+)-binding affinities of these peptides, the molecular events involved in cation binding need to be understood. We have addressed this problem in this study by using a systematic approach that involved the following steps. First, a random search technique was used to generate a large population of conformers for the free peptide in the absence of Ca2+. Next, the energies of these conformers were computed. Conformations with energies within 4 kcal/mol of the global minimum were analysed and found to fall into four main groups characterized by the presence of different types of hydrogen-bonded structures including single and consecutive beta-turns. The energies for interconversion of conformers from one group to another were computed and found to be relatively small (< 10 kcal/mol). Finally, molecular dynamics of the peptide at 300K in the presence of Ca2+ were used to simulate the cation binding process. Starting points for these simulations were generated by placing the ion in the vicinity of two molecules of the peptide. The simulation results showed that the conformers with two consecutive beta-turns led to the formation of a stable 2:1 (peptide:Ca2+) sandwich complex in agreement with earlier experimental observations on similar linear peptides. While the starting conformation of the peptide in the consecutive beta-turn structure allowed for the proper orientation of three carbonyl oxygen atoms for chelation to the metal ion, the dynamics of complex formation rearranged the peptide structure substantially, leading to the formation of an 8-coordinated Ca2+ complex in a dodecahedral spatial arrangement. Thus, based on the energetics of the structures and processes involved, the present study demonstrates that: a) peptide-Ca2+ complex formation is initiated by conformers adopting consecutive beta-turn structures which subsequently go over to a significantly different conformation found in the complex; and, b) The facile interconversion between the low-energy conformers in the different groups would help shift the equilibrium population towards the consecutive beta-turn structure during the complex formation.     

Molecular cloning of chick lysyl hydroxylase. Little homology in primary structure to the two types of subunit of prolyl 4-hydroxylase.

Lysyl hydroxylase (EC 1.14.11.4), an alpha 2 dimer, catalyzes the formation of hydroxylysine in collagens by the hydroxylation of lysine residues in X-Lys-Gly sequences. We report here on the isolation of cDNA clones coding for the enzyme from a chick embryo lambda gt11 library. Several overlapping clones covering all the coding sequences of the 4-kilobase mRNA and virtually all the noncoding sequences were characterized. These clones encode a polypeptide of 710 amino acid residues and a signal peptide of 20 amino acids. The polypeptide has four potential attachment sites for asparagine-linked oligosaccharides and 9 cysteine residues, at least one of which is likely to be involved in the binding of the Fe2+ atom to a catalytic site. A surprising finding was that no significant homology was found between the primary structures of lysyl hydroxylase and prolyl 4-hydroxylase in spite of the marked similarities in kinetic properties between these two enzymes. A computer-assisted comparison indicated only an 18% identity between lysyl hydroxylase and the alpha-subunit of prolyl 4-hydroxylase and a 19% identity between lysyl hydroxylase and the beta-subunit of prolyl 4-hydroxylase. Visual inspection of the most homologous areas nevertheless indicated the presence of several regions of 20-40 amino acids in which the identity between lysyl hydroxylase and one of the prolyl 4-hydroxylase subunits exceeded 30% or similarity exceeded 40%. Southern blot analyses of chick genomic DNA indicated the presence of only one gene coding for lysyl hydroxylase.     

Structure and Expression of the Human Lysyl Hydroxylase Gene (PLOD): Introns 9 and 16 Contain Alu Sequences at the Sites of Recombination in Ehlers-Danlos Syndrome Type VI Patients

Lysyl hydroxylase (EC 1.14.11.4) catalyzes the formation of hydroxylysine in collagens by the hydroxylation of lysine residues in peptide linkages. This enzyme activity is known to be reduced in patients with the type VI variant of the Ehlers-Danlos syndrome, and the first mutations in the lysyl hydroxylase gene (PLOD) have recently been identified. We have now isolated genomic clones for human lysyl hydroxylase and determined the complete structure of the gene, which contains 19 exons and a 5′ flanking region with characteristics shared by housekeeping genes. The constitutive expression of the gene in different tissues further suggests that lysyl hydroxylase has an essential function. We have sequenced the introns of the gene in the region where many mutations and rearrangements analyzed to date are concentrated. Intron 9 and intron 16 show extensive homology resulting from the many Alu sequences found in these introns. Intron 9 contains five and intron 16 eight Alu sequences. The high homology and many short identical or complementary sequences in these introns generate many potential recombination sites with the gene. The delineation of the structure of the lysyl hydroxylase gene contributes significantly to our understanding of the rearrangements in the genome of Ehlers-Danlos type VI patients.     

Failure of highly purified lysyl hydroxylase to hydroxylate lysyl residues in the non-helical regions of collagen.

The activity of highly purified lysyl hydroxylase towards lysyl residues within both the helical and the N-terminal non-helical telopeptide regions of chick type I collagen has been examined. The peptides alpha 1(I)-CB1 and alpha 2(I)-CB1, isolated from protocollagen following CNBr digestion and containing the N-terminal telopeptidyl lysyl residues, failed themselves to act as substrates. With protocollagen as substrate, analysis of products obtained following bacterial collagenase digestion of the reaction mixture showed that overall 37% hydroxylation of lysyl residues within the helical region of collagen had been obtained, which may be maximal. No hydroxylation, however, of the single lysyl residue in either alpha 1(I)-CB1 or alpha 2(I)-CB1, isolated following CNBr digestion of the reaction mixture, was observed, despite the known susceptibility of these residues to hydroxylation. These findings provide strong circumstantial evidence for the suggestion that a lysyl hydroxylase specific for the telopeptidyl residues and distinct from that active towards lysyl residues in the helical portion of the molecule may exist [Barnes, Constable, Morton & Royce (1974) Biochem. J. 139, 461-468].     

Discovery and characterization of hydroxylysine in recombinant monoclonal antibodies

Tryptic peptide mapping analysis of a Chinese hamster ovary (CHO)-expressed, recombinant IgG1 monoclonal antibody revealed a previously unreported +16 Da modification. Through a combination of MSⁿ experiments, and preparation and analysis of known synthetic peptides, the possibility of a sequence variant (Ala to Ser) was ruled out and the presence of hydroxylysine was confirmed. Post-translational hydroxylation of lysine was found in a consensus sequence (XKG) known to be the site of modification in other proteins such as collagen, and was therefore presumed to result from the activity of the CHO homolog of the lysyl hydroxylase complex. Although this consensus sequence was present in several locations in the antibody sequence, only a single site on the heavy-chain Fab was found to be modified.     

A novel supersecondary structure in globular proteins comprising the collagen-like helix and beta-turn

A structure consisting of the polyproline-II or collagen-like helix immediately succeeded by a beta-turn is seen in several synthetic peptides and has been suggested to be the conformational requirement for proline hydroxylation in nascent procollagen. Using a simple algorithm for detecting secondary structures, we have analysed crystal structure data on 40 globular proteins and have found eight examples of the collagen-helix + beta-turn supersecondary structure in 15 proteins that contain the collagen-like helical segments.