An intramembranous reductant which participates in the proline hydroxylation reaction with intracisternal prolyl hydroxylase and unhydroxylated procollagen in isolated microsomes from L-929 cells

We previously have described a substance present in crude sonicates of L-929 cells which replaced ascorbate in vitro as a reductant for prolyl hydroxylase (B. Peterkofsky, D. Kalwinksy and R. Assad, 1980, Arch. Biochem. Biophys.199, 362–373). In the present study we found that almost 90% of the substance was particulate after differential centrifugation of stationary phase L-929 cell homogenates. The substance was not localized in nuclei or mitochondria and was found in the same fractions as microsomes, but these fractions also contained lysosomes and cell membranes. The reductant could not be solubilized from particles by Brij-35, indicating that it is an intrinsic component of a membrane rather than intracisternally located. The intramembranous cofactor, in the absence of ascorbate, participated in the in vitro hydroxylation of [4-³H]proline in radio-actively labeled, intracisternal unhydroxylated procollagen in isolated microsomes which also contained prolyl hydroxylase. Hydroxylation was determined by measuring tritiated water formed from release of the 4-trans tritium atom. Since it is unlikely that such participation could occur if the cofactor were located within the membrane of another subcellular organelle, we have concluded that it is in the same particle as prolyl hydroxylase and unhydroxylated procollagen, that is, the microsome. With the endogenous reductant the reaction was slower than with saturating ascorbate and was increased by NADH. Maximum hydroxylation with the endogenous reductant was close to that which could be achieved with ascorbate. These results provide strong evidence that the endogenous reductant alone can account for the phenomenon of ascorbate-independent proline hydroxylation in L-929 cells. As in the case of ascorbate, the microsomal reductant functioned only in the presence of α-ketoglutarate and Fe²⁺ and served as reductant for lysyl hydroxylase. It also was detected in the particulate fraction of virally transformed BALB 3T3 cells and in purified microsomes from bones of intact chick embryos. Since ascorbate could be taken up and concentrated in bone microsomes, it is unlikely that the endogenous reductant serves as an intermediary between ascorbate and intracisternal prolyl hydroxylase.     

Modification of the tritium-release assays for prolyl and lysyl hydroxylases using Dowex-50 columns.

The tritium release assay of Hutton et al. (Anal. Biochem.16, 384, 1966) for prolyl hydroxylase and of Miller (Anal. Biochem.45, 202, 1972) for lysyl hydroxylase have been modified. The reaction is carried out on a microscale, and tritiated water is collected after passage of the trichloroacetic acid-soluble reaction products through a small Dowex-50 (H⁺) column instead of using a vacuum distillation apparatus as described in the original procedures. When measured by the modified procedures, both the prolyl and lysyl hydroxlyase reactions showed regions of linearity with respect to enzyme concentration, time and substrate concentration and were almost completely dependent on ascorbate and α-ketoglutarate. In addition, both reactions were completely inhibited by the iron chelator, α,α′-dipyridyl. The results indicate that these assay procedures are valid means of measuring prolyl and lysyl hydroxylase activities.     

Ascorbate-independent proline hydroxylation resulting from viral transformation of Balb 3T3 cells and unaffected by dibutyryl cAMP treatment.

Collagen synthesis, hydroxylation of proline in collagen, and collagen secretion were studied in the contact-inhibited mouse fibroblast line, Balb 3T3; the Kirsten virus transformed line, Ki-3T3; and dibutyryl cAMP (dbcAMP)-treated Ki-3T3 cells, during the various phases of the growth cycle. Transformed cells in both logarithmic and stationary phase produced lower levels of collagen than the parent line but 85-90% of the theoretically possible hydroxyproline residues of the collagen were formed even when ascorbic acid was not added to the culture medium. Moreover, the transformed cells showed only about a 20% increase of collagen secretion upon addition of ascorbate. This was in contrast to the ascorbate requirement for maximal proline hydroxylation and the 2-3 fold stimulation of collagen secretion by ascorbate in the parent Balb 3T3 cells. Although dbcAMP treatment caused Ki-3T3 cells to assume a more normal morphology and increased the relative rate of collagen synthesis to levels similar to that of 3T3, such treatment did not restore an ascorbate requirement for proline hydroxylation or collagen secretion. The specific activity of the enzyme prolyl hydroxylase also was not affected by dbcAMP treatment although collagen synthesis was increased by such treatment. In addition, it was found that ascorbic acid was not effective in activating prolyl hydroxylase derived from Ki-3T3 or dbcAMP-treated Ki-3T3 cell cultures either in logarithmic phase or stationary phase. Ki-3T3 cultures did not accumulate ascorbic acid in cells or medium nor was ascorbic acid synthesized from the precursor 14C-glucuronate in cell homogenates. The results suggest that virally transformed Balb 3T3 cells acquire the capacity to synthesize a reducing cofactor for prolyl hydroxylase and that this function may be related to the increased glycolytic metabolism of these cells since neither cellular metabolism nor ascrobate-independent hydroxylation was altered by treatment with dbcAMP.     

Inhibition of collagen synthesis by α, α′-dipyridyl in human skin fibroblasts in culture

Summary In human diploid skin fibroblasts in culture we have shown that nonhydroxylated collagen precursors remain in the cell when proline hydroxylation is inhibited by α, α′-dipyridyl, a chelator of ferrous ions. The inhibition of proline hydroxylation is reversed by addition of fresh medium containing 50 μg per ml of sodium ascorbate, whereupon nonhydroxylated collagen precursors are hydroxylated within the cell and extruded into the medium. Extrusion of collagen already formed within the cell is not appreciably affected by α, α′-dipyridyl inhibition. Under normal conditions collagen is released from the monolayer into the medium within 3 hr of a pulse ofL[¹⁴C]proline. In the presence of α, α′-dipyridyl, about 35% of theL[¹⁴C]proline incorporated into protein is released into the medium within 8 hr as a proline-rich, hydroxyproline-deficient protein; at the same time, approximately 15% of the protein-boundl-[¹⁴C]proline remains in the cell for as long as 12 hr. When proline hydroxylation is restored after 2 and 12 hr of α, α′-dipyridyl inhibition, approximately the same amount of hydroxyproline is formed after each time interval in the monolayer. Therefore, nonhydroxylated collagen precursors retained in the cell are not appreciably degraded during at least 12 hr of inhibition by α, α′-dipyridyl and are extruded into the medium only upon restoration of hydroxylation. This work was supported in part by a grant from the Easter Seal Research Foundation, and by Project 236, Health Services and Mental Health Administration, Department of Health, Education and Welfare, Grant HD-03110 from the National Institute of Child Health and Human Development, an American Cancer Society Institutional Grant (1N 15-J), a General Research Support Award (5-S01-FR-05406) from the National Institutes of Health, a University Research Council Grant, a National Science Foundation Equipment Grant (GB-4577), and a Research Career Development Award (5-K3-AM-5058) from the National Institute of Arthritis and Metabolic Disease (G.K.S.).     

Archenteron formation induced by ascorbate and alpha-ketoglutarate in sea urchin embryos kept in SO2- 4 -free artificial seawater

In permanent blastulae of the sea urchin, which were obtained by culture in SO^2?₄-free artificial seawater from the time of fertilization, ascorbate and α-ketoglutarate, activators of protocollagen proline hydroxylase, induced the formation of archenteron. By adding either ascorbate or α-ketoglutarate to the SO^2?₄-free culture at 12 hr of fertilization, spherical embryos with archenteron were obtained by successive 12 hr cultures at 20°C. The embryos thus obtained did not develop to plutei. Archenteron formation induced by these compounds in SO^2?₄-free-cultured embryos, as well as in the normal embryos, was inhibited by α,α′-dipyridyl, an inhibitor of protocollagen proline hydroxylase. Glutamate, malate, citrate, and fumarate did not stimulate archenteron formation in SO^2?₄-free cultured embryos. In the SO^2?₄-free-cultured embryos exposed to [¹⁴C]proline, considerable radioactivity was found in hot trichloroacetic acid-extractable proteins but the radioactivity of [¹⁴C]hydroxyproline residue, produced by hydroxylation of proline residue of protocollagen, was markedly lower than that in normal embryos. In the presence of ascorbate and α-ketoglutarate, the radioactivity of [¹⁴C]hydroxyproline residue became high and was lowered by α,α′-dipyridyl. Archenteron formation induced by ascorbate and α-ketoglutarate in the embryos kept in SO^2?₄-free artificial seawater probably results from the stimulated protocollagen hydroxylation.     

The effect of hypoxia on collagen synthesis in cultured 3T6 fibroblasts and its relationship to the mode of action of ascorbate.

When exposed to low oxygen tension, in the absence of added ascorbic acid 3T6 mouse fibroblast cultures in late log phase respond by increased lactate production and increased hydroxylation of proline in nascent collagen, which is paralleled by an increase in prolyl hydroxylase activity. After 6 h recovery from the anoxic stimulus, however, cultures still yield more prolyl hydroxylase than controls, but the effect on hydroxylation of nascent collagen has disappeared. These observations help to dissect the dual role of ascorbate which can stimulate hydroxylation both by increasing the amount of active enzyme and by a cofactor-like role; in addition, these observations may be relevant to wound healing.     

Prolyl hydroxylase activity during sea urchin development

Prolyl hydroxylase activity appears at the blastula stage of development in the sea urchin Strongylocentrotus purpuratus and increases over 7-fold by the prism larva stage. The enzyme requires ascorbate, ferrous ions, and α-ketoglutarate for maximum activity and is inhibited by α,α′-dipyridyl. The significance of prolyl hydroxylase activity in embryonic collagen metabolism and morphogenesis is discussed.     

Synthesis and Secretion of Hydroxyproline-containing Macromolecules in Carrots: II. In vivo Conversion of Peptidyl Proline to Peptidyl Hydroxyproline

The chelator α,α′-dipyridyl prevents the formation of protein-bound hydroxyproline without affecting protein synthesis as measured by the incorporation of ¹⁴C-proline. The inhibitory effect can be overcome by exogenous ferrous ions. Neither α,α′-dipyridyl nor Fe²⁺ interferes in any other known way with the synthesis and secretion of the hydroxyproline-rich proteins normally found in the cell wall. This reversal by Fe²⁺ of the inhibition of proline hydroxylation by α,α′-dipyridyl is used for a study in vivo of the hydroxylation reaction. This reaction has a temperature coefficient of 2.2, suggesting that it is an enzymatic process. Reversal by Fe²⁺ of the α,α′-dipyridyl inhibition can occur after protein synthesis has been arrested with cycloheximide, indicating that peptidyl proline is the substrate of the hydroxylation reaction. Hydroxylation occurs in the cytoplasm, and not in the cell wall, and only for a limited time after the incorporation of proline into the polypeptide chain. This suggests a spatial separation of the enzyme and the substrate.     

The in vivo inhibition of collagen synthesis and the reduction of prolyl hydroxylase activity by 3,4-dehydroproline.

Various proline analogs and iron chelators were tested for their effect on collagen formation which occurs in the uterus of the immature rat following the administration of estradiol-17β. dl-3,4-Dehydroproline, l-α-azetidine-2-carboxylic acid and l-pyroglutamic acid reduced the estradiol-17β stimulated formation of hydroxyproline which occurs in the uterus following administration of the hormone while l-thiazolidine-4-carboxylic acid was without effect on this response. The activity of the d- and l-isomers of 3,4-dehydroproline was compared with the racemic mixture; the l-isomer was twice as active as the latter, while the d-isomer was only half as active. l-3,4-Dehydroproline was approximately four times as potent as l-α-azetidine-2-carboxylic acid, the second most active analog of those tested. dl-3,4-Dehydroproline inhibited the incorporation of l-[¹⁴C]proline into the proline and hydroxyproline of uterine collagen; it also inhibited the incorporation of [¹⁴C]glycine into collagen while having less effect on the incorporation of these amino acids into noncollagen protein. These results indicate dl-3,4-dehydroproline is a fairly specific and potent inhibitor of collagen formation in vivo.These observations indicate that dl-3,4-dehydroproline reduces the hydroxylation of prolyl residues in collagen. Presumably, this occurs in part due to the incorporation of the analog into the collagen molecule in place of proline. It is probably also related to a reduction of prolyl hydroxylase activity which can be demonstrated in the tissues of animals treated with 3,4-dehydroproline. A significant reduction of prolyl hydroxylase activity was shown to persist in the uterus, lung, and heart for approximately 24 h following a single intraperitoneal dose of dl-3,4-dehydroproline (200 mg/kg).     

A substance in L-929 cell extracts which replaces the ascorbate requirement for prolyl hydroxylase in a tritium release assay for reducing cofactor; correlation of its concentration with the extent of ascorbate-independent proline hydroxylation and the level of prolyl hydroxylase activity in these cells

Reductant used as cofactor for the prolyl hydroxylase reaction, was measured by a tritium release assay modified from an enzyme assay by making all components of the assay system saturating except for the reductant, but including prolyl hydroxylase. Reduced glutathione (6 mm), which had little activity as a cofactor, and thymol (0.1 mm), an antioxidant which exhibited no cofactor activity at all, were required for optimal proline hydroxylation dependent on reducing cofactor, with thymol fulfilling the previously described requirement for catalase. Ascorbate, cysteine and 6,7-dimethyltetrahydropterin were active as cofactors, in descending order of activity at equimolar concentrations, and activity was concentration dependent for all of these compounds. Sonicates of stationary phase L-929 cells which exhibit ascorbate-independent proline hydroxylation in culture contained reducing cofactor which could replace ascorbate in the cofactor assay, while sonicates of log phase cells which exhibit an ascorbate requirement in culture contained about one-third or less of that amount. NADH and NADPH, which themselves have little or no activity as cofactor, increased the cofactor activity of log phase cell sonicates but had relatively little effect on the activity of stationary cell sonicates suggesting that the cofactor is in a more reduced state in stationary phase. Within 24 h after replating dense, stationary phase cell cultures at low density, conditions where cells return to ascorbate dependence, prolyl hydroxylase activity had decreased to one-fifth the original activity while the concentration of functional reducing cofactor had decreased to less than 1% of its original concentration, largely as a result of oxidation. Ascorbate was not present in L-929 cells sonicates and the levels of tetrahydropterin and cysteine in sonicates could not account for the amount of cofactor activity exhibited by the sonicates in the assay system. Treatment of L-929 cultures with aminopterin did not decrease ascorbate independence, suggesting that tetrahydrofolate did not contribute significantly to cellular proline hydroxylation. These results suggest that an unidentified reductant present in L-929 cells can account for ascorbate-independent proline hydroxylation and also regulate prolyl hydroxylase activity in these cells and that cellular levels of reduced pyridine nucleotides may regulate the reduction state of this substance.     

Differential effects of ascorbate depletion and α,α′-dipyridyl treatment on the stability,but not on the secretion,of type IV collagen in differentiated F9 cells

Ascorbic acid stimulates secretion of type I collagen because of its role in 4-hydroxyproline synthesis, but there is some controversy as to whether secretion of type IV collagen is similarly affected. This question was examined in differentiated F9 cells, which produce only type IV collagen, by labeling proteins with [¹⁴C]proline and measuring collagen synthesis and secretion. Hydroxylation of proline residues in collagen was inhibited to a greater extent in cells treated with the iron chelator α,α′-dipyridyl (97.7%) than in cells incubated without ascorbate (63.1%), but both conditions completely inhibited the rate of collagen secretion after 2–4 h, respectively. Neither treatment affected laminin secretion. Collagen synthesis was not stimulated by ascorbate even after treatment for 2 days. On SDS polyacrylamide gels, collagen produced by α,α′-dipyridyl-treated cells consisted mainly of a single band that migrated faster than either fully (+ ascorbate) or partially (− ascorbate) hydroxylated α1(IV) or α2(IV) chains. It did not contain interchain disulfide bonds or asn-linked glycosyl groups, and was completely digested by pepsin at 15°C. These results suggested that it was a degraded product lacking the 7 S domain and that it could not form a triple helical structure. In contrast, the partially hydroxylated molecule contained interchain disulfide bonds and it was cleaved by pepsin to collagenous fragments similar in size to those obtained from the fully hydroxylated molecule, but at a faster rate. Kinetic experiments and monensin treatment suggested that completely unhydroxylated type IV collagen was degraded intracellularly in the endoplasmic reticulum or cis Golgi. These studies indicate that partial hydroxylation of type IV collagen confers sufficient helical structure to allow interchain disulfide bond formation and resistance to pepsin and intracellular degradation, but not sufficient for optimal secretion. J Cell. Biochem. 67:338–352, 1997. Published 1997 Wiley-Liss, Inc.     

Prolyl hydroxylase activity in L-929 fibroblasts incubated with and without ascorbate

An improved procedure was used to assay prolyl hydroxylase activity in both early-log and late-log L-929 fibroblasts grown on plastic surfaces. When 40 μg/ml of ascorbate was added to early-log phase cultures, the rate of hydroxy-[¹⁴C] proline synthesis increased 2-fold within 4 h, but there was no change in prolyl hydroxylase activity per cell. The results indicated therefore that ascorbate did not “activate” prolyl hydroxylase in the sense of converting inactive enzyme protein to active enzyme protein. Instead ascorbate appeared to increase hydroxyproline synthesis in early-log L-929 fibroblasts because the prolyl hydroxylase reaction in such cells was limited by the availability of ascorbate or a similar cofactor. When 40 μg/ml of ascorbate was added to late-log phase cultures, there was essentially no effect on the rate of hydroxyl[¹⁴C]-proline synthesis or prolyl hydroxylase activity. The late-log phase cells, however, contained three times more enzyme activity and about two times more immuno-reactive enzyme protein than early-log phase cells. In addition, the rate of protein synthesis per cell in late-log phase cells was only one-tenth the rate in early-log phase cells. The results suggested that as the cells grew to confluency, collagen polypeptides were more completely hydroxylated in part because the rate of polypeptide synthesis decreased and at the same time prolyl hydroxylase activity per cell increased. The results appear to provide an alternate explanation for previous observations on the effects of ascorbate and “crowding” on hydroxy[roline synthesis in cultures of L-929 fibroblasts.     

Collagen biosynthesis by human skin fibroblasts III. The effects of ascorbic acid on procollagen production and prolyl hydroxylase activity

Human skin fibroblasts were cultured under conditions optimized for collagen synthesis, and the effects of ascorbic acid on procollagen production, proline hydroxylation and the activity of prolyl hydroxylase were examined in cultures. The results indicated that addition of ascorbic acid to confluent monolayer cultures of adult human skin fibroblasts markedly increased tha amount of [³H]hydroxyproline syntehsized. Ascorbic acid, however, did not increase the synthesis of ³H-labeled collagenous polypeptides assayed independently of hydroxylation of proline residues, nor did it affect the amount of prolyl hydroxylase detectable by an in vitro enzyme assay. Also long-term cultures of the cells or initiation of fibroblast cultures in the presence of ascorbic acid did not lead to an apparent selection of a cell population which might be abnormally responsive to ascorbic acid. Thus, ascorbic acid appears to have one primary action on the synthesis of procollagen by cultured human skin fibroblasts: it is necessary for synthesis of hydroxyproline, and consequently for proper triple helix formation and selection of procollagen.     

Iron-dependent uptake of ascorbate into isolated microsomes

A preliminary study (J.M. Mata, R. Assad, and B. Peterkofsky (1981) Arch. Biochem. Biophys. 206, 93-104) suggested that chick embryo limb bone microsomes took up and concentrated [14C]ascorbate in the presence of cofactors for prolyl hydroxylase. In the present study, we found that the apparent Km for ascorbate in the hydroxylation of intracisternal unhydroxylated procollagen by endogenous prolyl hydroxylase was approximately an order of magnitude less than the value obtained when enzyme solubilized from microsomes was used with an exogenous substrate. These results are compatible with a concentrative uptake of ascorbate into microsomes. The uptake of [14C]ascorbate into microsomes was confirmed and it required only iron, in either the ferrous or ferric form, and was time and temperature dependent, proportional to microsome concentration, and substrate saturable at 2-3 mM ascorbate. Iron-dependent ascorbate uptake also was observed with L-929 cell microsomes. [14C]Ascorbate seemed to be taken up without prior oxidation, since only unlabeled ascorbate, and not dehydroascorbate, competed for uptake into limb bone microsomes. A functional requirement for Fe2+ in ascorbate transport was demonstrated using the intracisternal proline hydroxylating system. L-929 cell microsomes were preincubated with ascorbate with or without the metal and then external ascorbate was oxidized to inactive dehydroascorbate using ascorbic acid oxidase, which cannot penetrate the microsomal membrane. Samples which did not receive iron during the preincubation received it, along with other requirements for prolyl hydroxylase, in a final incubation to measure hydroxylation. Significant hydroxylation was obtained only in samples incubated with iron prior to oxidase treatment, consistent with the conclusion that an iron-dependent process was required to translocate ascorbate and protect it from the oxidase.     

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.     

Use of soluble, collagenous peptides from medium of chick calvaria cultures as substrate for prolyl hydroxylase

Underhydroxylated collagenous proteins accumulate in the media of embryonic chick calvaria cultured in the presence of α,α′-dipyridyl for 24 h. These soluble collagenous proteins, when labeled with radioactive proline, were shown to be a specific, stable, and highly efficient substrate for in vitro measurement of prolyl hydroxylase. The ability of the media proteins to serve as a substrate for prolyl hydroxylase was abolished by digestion with purified bacterial collagenase. This method of substrate preparation provides a soluble, efficient, economical substrate for routine prolyl hydroxylase assays, and permits the accumulation of sufficient quantities of substrate of one specific activity to serve for extended periods of time.     

Collagen polysomes: Site of hydroxylation of proline residues

The biosynthesis of collagen on polysomes has been studied by using a newly devised method for obtaining polysomes in high yield from stationary-phase mouse fibroblast (line 3T6; Goldberg &, Green, 1967). These polysomes were completely disaggregated to monosomes by brief exposure to ribonuclease and they lost most of their radioactivity to the top of the sucrose gradients as a result of a 30-minute chase with unlabeled proline. After a ten-minute pulse with [³H]proline, nascent collagen peptides could be identified in these polysomes on sucrose gradients. Most of the proline residues susceptible to hydroxylation by collagen proline hydroxylase were found, in most cases, to be already hydroxylated in these nascent peptides. The nascent nature of these peptides was confirmed by the observation that treatment of the polysomes with RNase transferred the radioactive collagen peptides to the monosome area and these peptides could subsequently be removed to the soluble material at the top of the gradient upon treatment with puromycin. These findings therefore, show clearly that the hydroxylation of proline residues is occurring, in vivo under normal conditions, on nascent collagen chains. In no case was the degree of hydroxylation of the released collagen chains higher than that on the nascent collagen peptides. It seems likely, therefore, that the major site of proline hydroxylation is the nascent collagen peptide.     

Proteolytic activity in human skin fibroblasts harvested with trypsin and its effect on measurements of collagen hydroxylase activities.

Lysates of human skin fibroblasts harvested without the use of trypsin do not contain detectable proteolytic activity, but when trypsin is used, lysates may contain activity equal to 10 ng of trypsin/10⁷ cells. The amount of cell lysate ordinarily examined for collagen prolyl and lysyl hydroxylase activity is sufficiently small that such amounts of trypsin have no observable effect on the unhydroxylated collagen substrate. Larger amounts of trypsin cause proteolysis of the unhydroxylated collagen substrate and a reduction of both prolyl and lysyl hydroxylation with lysyl hydroxylation more affected at low trypsin concentration than prolyl hydroxylation.     

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.     

Collagen prolyl hydroxylation in WI-38 fibroblast cultures: Action of hydralazine

Summary The action of hydralazine on collagen prolyl hydroxylation was studied in a cell culture system using WI-38 fibroblasts. The prolyl hydroxylation level was determined by a method involving the digestion of collagen by bacterial collagenase and the examination of specific peptides. The presence of low concentrations of hydralazine (0.2 mM) in both “young” and “old” fibroblast cultures strongly inhibited collagen prolyl hydroxylation. The degree of inhibition was greater in serum-deficient cultures. No significant improvement in the degree of hydroxylation was observed by increasing either ascorbate or iron levels in the hydralazine-containing cultures in which hydroxylation was inhibited. Some of the reported side effects of hydralazine seen in patients might be related to its inhibitory effects on mixed function oxidative (MFO) hydroxylation systems. While the ascorbate dependence of the prolyl hydroxylase system of WI-38 decreased with the “age” of the culture, hydralazine inhibition of hydroxylation was dramatic with cultures of all “ages”. This work was supported by NIH grants nos. AM15671, AM1675 and HD07376, and fellowship no. HD01998.