CRP,immunologically cross-reacting protein of prolyl hydroxylase. Its role in assembly of active prolyl hydroxylase and cellular localization in L-929 fibroblasts

There are two forms of prolyl hydroxylase in L-929 flbroblasts. One is the enzymatically active tetramer having two α- and two β-subunits. The other is monomeric cross-reacting protein which is enzymatically inactive but is structurally related to β-subunit of the enzyme. Cultured L-929 fibroblasts at mid-log phase were labeled by ³H-labeled amino acid mixture and the radioactivity was chased for 24 h while cells were harvested and plated at higher cell densities in cultures. The results indicated that both α-subunit of the tetrameric prolyl hydroxylase and cross-reacting protein were labeled, but the β-subunit of the tetrameric active prolyl hydroxylase was not labeled until the cells were crowded for 24 h. Using immunofluorescent techniques with antibodies directed against pure tetrameric prolyl hydroxylase, capping or patching was observed when the cells were incubated at 37 °C. Also, it was found that phagosomes prepared from L-929 flbroblasts contained about 30% of total enzyme protein as determined immunologically but contained no significant prolyl hydroxylase activities. Labeling cells with ¹²⁵I by lactoperoxidase, cross-reacting protein was labeled but both α- and β-subunits of tetrameric active prolyl hydroxylase were not labeled. The results indicate that cross-reacting protein can be utilized as the precursor of β-subunit by the cells to form tetrameric active prolyl hydroxylase and that cross-reacting protein is found associated with cytoplasmic membranes.     

The association between prolyl hydroxylase metabolism and cell growth in cultured L-929 fibroblasts

Prolyl 4-hydroxylase (EC 1.14.11.2) is a key enzyme in collagen biosynthesis, its active form is a tetramer (alpha 2 beta 2). In L-929 fibroblasts in the log phase of culture there is a low level of active enzyme. When the cell culture reaches confluency, prolyl hydroxylase activity in cells increases by a process that requires de novo RNA and protein synthesis. The same result may be achieved by crowding the cells (replating log phase cells at the density of stationary phase cells). In the work reported here we further examined induction of the enzyme. RNA synthesis necessary for enzyme induction is complete 6 h after "crowding" while protein synthesis requires 12 h. Thymidine (0.2-0.5 mM) added to log phase cells will also cause enzyme induction to the level found in "crowded" or resting cells. We also looked at the decay of the enzyme activity after subculture. This occurs rapidly (enzyme half-life is 1-2 h) and is concurrent with the re-entry of resting cells into cell cycle; however, thymidine added at the time of subculture to block DNA synthesis does not prevent the loss of prolyl hydroxylase activity. These results suggest that when cells are not engaged in propagation, they begin to synthesize luxury proteins such as prolyl hydroxylase. However, the loss of prolyl hydroxylase during subculture is probably not a direct consequence of DNA synthesis.     

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.     

The assembly of tetrameric prolyl hydroxylase in tendon fibroblasts from newly synthesized α-subunits and from preformed cross-reacting protein

Embryonic-chick tendon cells were incubated in suspension for 4h with (14)C-labelled amino acids, cell extracts were subjected to gel filtration, and the effluent was examined by rocket immunoelectrophoresis by using antibodies specific for the beta-subunit of chick prolyl hydroxylase. Two peaks of immunoreactive protein were found. The first peak contained 40% of the immunoreactive protein eluted from the column and 100% of the enzyme activity. Polyacrylamide-slab-gel electrophoresis in sodium dodecyl sulphate of an immunoprecipitate of this peak demonstrated that it consisted of the tetrameric form of prolyl hydroxylase, subunit composition alpha(2)beta(2) where alpha and beta are non-identical subunits. Only the alpha-subunits were labelled, indicating that they were synthesized during the 4h labelling period. The beta-subunits were unlabelled, indicating that they had been synthesized before the labelling period. The second peak eluted from the gel-filtration column contained 60% of the immunoreactive protein eluted from the column and was enzymically inactive. Polyacrylamide-slab-gel electrophoresis of an immunoprecipitate of this peak indicated that it consisted of a single labelled polypeptide chain, identified as cross-reacting protein, which was related to, but not identical with, the beta-subunit of prolyl hydroxylase. Pulse-chase experiments were performed on cultured chick tendon cells to demonstrate that alpha-subunits and cross-reacting protein had half-lives of about 60h. The half-life of beta-subunits was considerably longer, and the kinetic pattern was consistent with their being derived from a labelled precursor such as cross-reacting protein. The data presented here indicate that the active tetrameric form of prolyl hydroxylase in cells is assembled from alpha-subunits which are newly synthesized, and from beta-subunits which are derived from cross-reacting protein.     

Intracellular enzymes of collagen biosynthesis in rat liver as a function of age and in hepatic injury induced by dimethylnitrosamine. Purification of rat prolyl hydroxylase and comparison of changes in prolyl hydroxylase activity with changes in immunoreactive prolyl hydroxylase.

Prolyl hydroxylase was purified from newborn rats by affinity chromatography using poly(L-proline), and antiserum to the enzyme was prepared in rabbits. The rat prolyl hydroxylase was similar to the chick and human enzymes with respect to specific activity, molecular weight and molecular weights of the polypeptide chains. The activity of prolyl hydroxylase and the content of immunoreactive enzyme were measured in rat liver as a function of age in experimental hepatic injury. Active prolyl hydroxylase comprised about 13.2% of the total immunoreactive protein in the liver of newborn rats and the value decreased to about 3.6% at the age of 420 days. This decrease was due to a decrease in the enzyme activity, whereas only minor changes were found in the content of the immunoreactive protein. In hepatic injury, a significant increase was found in the ratio of active enzyme to total immunoreactive protein, owing to an increase in the enzyme activity. The data indicate that prolyl hydroxylase activity in rat liver is controlled in part by a mechanism which does not involve changes in the content of the total immunoreactive protein.     

Turnover of prolyl hydroxylase and an immunologically related protein in rabbit tissue

The turnover rates of prolyl hydroxylase and immunologically related (cross reacting) protein were examined using labeled leucine as precursor or by measuring the decay of elevated prolyl hydroxylase and immunologically cross-reacting protein back to basal levels. Prolyl hydroxylase and immunologically cross-reacting protein were purified from neonatal rabbit skin at various times following the administration of [³H]leucine. Prolyl hydroxylase was purified by affinity chromatography. Immunologically cross-reacting protein was purified by antibody precipitation from the dialyzed 70% (NH₄)SO₄ supernatants and subsequent electrophoresis on 10% sodium dodecyl sulfate-polyacrylamide slab gels. The radioactivity of the species isolated, which corresponded to the two major subunits of prolyl hydroxylase, was used in the turnover studies of immunologically cross-reacting protein. The peak incorporation of label into prolyl hydroxylase was found to be 12 h while for immunologically cross-reacting protein this occured within 2 h. The loss of radioactivity from these protein pools denotes an apparent $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ for prolyl hydroxylase of 73 h and a $\text{1}\text{2}$ for immunologically cross-reacting protein of 53 h. From the specific activity of free skin leucine pools, the effect of reutilization could be corrected and a true $\text{t}\text{1}\text{2}$ for prolyl hydroxylase of 45 h was determined. The $\text{t}\text{1}\text{2}$ values of these proteins were determined by a second method in which prolyl hydroxylase and immunologically cross-reacting protein in the aorta and liver of adult male rabbits were elevated by daily epinephrine-thyroxine treatment for 12 days. The decline of prolyl hydroxylase and immunologically cross-reacting protein with termination of treatment in the aorta denotes values of 42 h for enzyme and 53 h for immunologically cross-reacting protein. Calculated enzyme κ_d values, by both methods, indicate that breakdown of enzyme does not account for tissue immunologically cross-reacting protein.     

Ascorbate increases the synthesis of procollagen hydroxyproline by cultured fibroblasts from chick embryo tendons without activation of prolyl hydroxyla.

An improved procedure was developed to extract prolyl hydroxylase from tendon cells of chick embryos with detergent, and improved assays were developed for both the activity of the enzyme and the amount of enzyme protein. Freshly isolated tendon cells were found to contain approx. 100 mug of enzyme protein per 10(8) cells and 40-50% of the enzyme protein was active. When the cells were cultured, they were found to contain the same amount of enzyme protein but only 15-20% of the enzyme protein was active. Gel filtration of cell extracts indicated that the active form of prolyl hydroxylase in freshly isolated tendon cells and incultured tendon cells had the same apparent size and the same activity per mug of immunoreactive protein as enzyme which was shown to be a tetramer. The inactive form was found to have about the same apparent size as subunits of the enzyme. When freshly isolated cells were incubated for 2 h in the presence of 40 mug per ml of ascorbate, there was a slight increase in the rate of hydroxyproline synthesis. In cultured cells, ascorbate at a concentration of 40 mug per ml caused a 2-fold increase in the rate of hydroxyproline synthesis within 30 min. However, ascorbate did not icrease the activity of prolyl hydroxylase in extracts from either cell system. Therefore it appears that the influence of ascorbate on synthesis of procollagen hydroxyproline by the cells studied here must be ascribed to a cofactor effect on the hydroxylation reaction similar to that observed with purified enzyme, and it does not involve "activation" of inactive enzyme protein to active enzyme as has been observed in cultures of L-929 and 3T6 mouse fibroblasts.     

Ascorbate increases the synthesis of procollagen hydroxyproline by cultured fibroblasts from chick embryo tendons without activation or prolyl hydroxylase

An improved procedure was developed to extract prolyl hydroxylase from tendon cells of chick embryos with detergent, and improved assays were developed for both the activity of the enzyme and the amount of enzyme protein. Freshly isolated tendon cells were found to contain approx. 100 μg of enzyme protein per 10⁸ cells and 40–50% of the enzyme protein was active. When the cells were cultured, they were found to contain the same amount of enzyme protein by only 15–20% of the enzyme protein was active. Gel filtration of cell extracts indicated that the active form of prolyl hydroxylase in freshly isolated tendon cells and in cultured tendon cells had the same apparent size and the same activity per μg of immunoreactive protein as enzyme which was shown to be a tetramer. The inactive form was found to have about the same apparent size as subunits of the enzyme.When freshly isolated cells were incubated for 2 h in the presence of 40 μg per ml of ascorbate, there was a slight increase in the rate of hydroxyproline synthesis. In cultured cells, ascorbate at a concentration of 40 μg per ml caused a 2-fold increase in the rate of hydroxyproline synthesis within 30 min. However, ascorbate did not increase the activity of prolyl hydroxylase in extracts from either cell system. Therefore it appears that the influence of ascorbate on synthesis of procollagen hydroxyproline by the cells studied here must be ascribed to a cofactor effect on the hydroxylation reaction similar to that observed with purified enzyme, and it does not involve “activation” of inactive enzyme protein to active enzyme as has been observed in cultures of L-929 and 3T6 mouse fibroblasts.     

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.     

Hydroxylation of prolyl residues in type II procollagen in vitro and in cellulo. Lack of preferential hydroxylation of specific regions of the protein

[14C]Proline-labeled protocollagen, the unhydroxylated form of procollagen, was isolated from cartilage cells incubated with alpha, alpha'-dipyridyl. For examination of the initial steps in the hydroxylation of the protein, it was incubated in vitro with prolyl hydroxylase so that an average of 1.3-2.7 prolyl residues per chain was hydroxylated. The partially hydroxylated alpha chain were cleaved with cyanogen bromide, and the fragments were separated by polyacrylamide gel electrophoresis or column chromatography. The cyanogen bromide fragments were hydroxylated to the same degree. The results indicated, therefore, that in the initial hydroxylation of alpha chains in vitro, there was no preferential hydroxylation of any specific regions of the protein. In a second series of experiments, cartilage cells were incubated with [14C]proline and alpha, alpha'-dipyridyl so that prolyl hydroxylase in the cells was extensively, but not completely, inhibited. Partially hydroxylated alpha chains were isolated, and cyanogen bromide fragments of the alpha chains from the cells were assayed for hydroxy[14C]proline. The alpha chains contained an average of two residues of hydroxyproline per chain, and the cyanogen bromide fragments were hydroxylated to about the same degree. The results indicated, therefore, that when prolyl hydroxylase activity in cells is low relative to the rate at which pro alpha chains are synthesized, hydroxylation of prolyl residues occurs as it does in vitro, and there is no preferential hydroxylation of a specific region of the protein.     

Correlation of the steady-state RNA levels among the alpha-subunit of prolyl 4-hydroxylase and the alpha 1 and alpha 2 chains of type I collagen during growth of chicken embryo tendon fibroblasts.

The relative steady-state levels of RNAs encoding type I collagen and prolyl 4-hydroxylase were examined in exponentially growing primary cultures of chicken embryo tendon fibroblasts. The RNA levels of the alpha 1 and alpha 2 chains of type I collagen were maximal when the fibroblasts reached the confluent state. The RNA levels of the alpha-subunit of prolyl 4-hydroxylase were also maximal at confluency and rose and fell with the RNA levels of the two collagen chains. The RNA levels of the beta-subunit of prolyl 4-hydroxylase did not correlate with the changes observed for the alpha-subunit or for either chain of type I collagen. The RNA levels of the beta-subunit were slightly higher than the RNA levels of the alpha-subunit. These results support our hypothesis that the synthesis of the alpha-subunit and thus the association of newly synthesized alpha-subunits with pre-existing beta-subunits is the rate-limiting factor in determining prolyl 4-hydroxylase activity in cultured cells.     

Assembly of human prolyl 4-hydroxylase and type III collagen in the yeast pichia pastoris: formation of a stable enzyme tetramer requires coexpression with collagen and assembly of a stable collagen requires coexpression with prolyl 4-hydroxylase.

Prolyl 4-hydroxylase, the key enzyme of collagen synthesis, is an alpha2beta2 tetramer, the beta subunit of which is protein disulfide isomerase (PDI). Coexpression of the human alpha subunit and PDI in Pichia produced trace amounts of an active tetramer. A much higher, although still low, assembly level was obtained using a Saccharomyces pre-pro sequence in PDI. Coexpression with human type III procollagen unexpectedly increased the assembly level 10-fold, with no increase in the total amounts of the subunits. The recombinant enzyme was active not only in Pichia extracts but also inside the yeast cell, indicating that Pichia must have a system for transporting all the cosubstrates needed by the enzyme into the lumen of the endoplasmic reticulum. The 4-hydroxyproline-containing procollagen polypeptide chains were of full length and formed molecules with stable triple helices even though Pichia probably has no Hsp47-like protein. The data indicate that collagen synthesis in Pichia, and probably also in other cells, involves a highly unusual control mechanism, in that production of a stable prolyl 4-hydroxylase requires collagen expression while assembly of a stable collagen requires enzyme expression. This Pichia system seems ideal for the high-level production of various recombinant collagens for numerous scientific and medical purposes.     

Identification of a novel proline-rich peptide-binding domain in prolyl 4-hydroxylase.

Prolyl 4-hydroxylase (EC 1.14.11.2) catalyzes the hydroxylation of -X-Pro-Gly- sequences and plays a central role in the synthesis of all collagens. The [alpha(I)]2beta2 type I enzyme is effectively inhibited by poly(L-proline), whereas the [alpha(II)]2beta2 type II enzyme is not. We report here that the poly(L-proline) and (Pro-Pro-Gly)10 peptide substrate-binding domain of prolyl 4-hydroxylase is distinct from the catalytic domain and consists of approximately 100 amino acids. Peptides of 10-19 kDa beginning around residue 140 in the 517 residue alpha(I) subunit remained bound to poly(L-proline) agarose after limited proteolysis of the human type I enzyme tetramer. A recombinant polypeptide corresponding to the alpha(I) subunit residues 138-244 and expressed in Escherichia coli was soluble, became effectively bound to poly(L-proline) agarose and could be eluted with (Pro-Pro-Gly)10. This polypeptide is distinct from the SH3 and WW domains, and from profilin, and thus represents a new type of proline-rich peptide-binding module. Studies with enzyme tetramers containing mutated alpha subunits demonstrated that the presence of a glutamate and a glutamine in the alpha(II) subunit in the positions corresponding to Ile182 and Tyr233 in the alpha(I) subunit explains most of the lack of poly(L-proline) binding of the type II prolyl 4-hydroxylase. Keywords: collagen/dioxygenases/peptide-binding domain/ proline-rich/prolyl hydroxylase     

Effect of L-3,4-dehydroproline on collagen synthesis and prolyl hydroxylase activity in mammalian cell cultures.

The incorporation of DL-3,4-dehydro[14C]proline into collagen and total protein of 3T3 cells occurred at approximately one-fifth the rate observed for L-[14C]proline. Addition of L-3,4-dehydroproline to the culture medium inhibited markedly the incorporation of [14C]glycine and L-[3H]lysine into the collagen of 3T3 cells, but there was only slight inhibition of the incorporation of the radiolabeled amino acids into total cellular proteins, indicating that the action of L-3,4-dehydroproline is specific for collagen. When 1 mM L-3,4-dehydroproline was added to the culture medium the [14C]hydroxyproline content was reduced 40% in the cell layer and 70% in the medium. The D isomer of 3,4-dehydroproline did not inhibit [14C]hydroxyproline formation. These findings indicate that L-3,4-dehydroline reduced the hydroxylation of the susceptible prolyl residues in the collagen molecule and the secretion of collagen from the cell. The reduction in the hydroxyproline content is probably related in part to a reduction in the activity of prolyl hydroxylase; when various mammalian cell cultures were exposed to 0.2 mM L-3,4-dehydroproline, the specific activity of prolyl hydroxylase was reduced markedly, while that of lysyl hydroproline, the specific activity of prolyl hydroxylase was reduced markedly, while that of lysyl hydroxylase was not affected. Under these conditions, cell growth and lactic dehydrogenase required protein synthesis. Removal of L-3,4-dehydroproline from the growth medium resulted in a time-dependent increase in the specific activity of prolyl hydroxylase.     

Biosynthesis of prolyl hydroxylase: evidence for two separate dolichol-media pathways of glycosylation

Prolyl hydroxylase is a glycoprotein containing two nonidentical subunits, alpha and beta. The alpha subunit of prolyl hydroxylase isolated from 13-day-old chick embryos contains a single high mannose oligosaccharide having seven mannosyl residues. Two forms of alpha subunit have been shown to exist in enzyme purified from tendon cells of 17-day-old chick embryos, one of which (alpha) appears to be identical in molecular weight and carbohydrate content with the single alpha of enzyme from 13-day-old chick embryos, as well as another form (alpha') that contains two oligosaccharides, each containing eight mannosyl units [see Kedersha, N. L., Tkacz, J. S., & Berg, R. A. (1985) Biochemistry (preceding paper in this issue)]. Biosynthetic labeling studies were performed with chick tendon cells using [2-3H]mannose, [6-3H]glucosamine, [14C(U)]mannose, and [14C(U)]glucose. Analysis of the labeled products using polyacrylamide gel electrophoresis in sodium dodecyl sulfate showed that only the oligosaccharides on alpha' incorporated measurable mannose or glucosamine isotopes; however, both alpha subunits incorporated 14C amino acid mix and [14C(U)]glucose [metabolically converted to [14C(U)]mannose] under similar conditions. Pulse-chase labeling studies using 14C amino acid mix demonstrated that both glycosylated polypeptide chains alpha and alpha' were synthesized simultaneously and that no precursor product relationship between alpha and alpha' was apparent. In the presence of tunicamycin, neither alpha nor alpha' was detected; a single polypeptide of greater mobility appeared instead. Incubation of the cells with inhibitory concentrations of glucosamine partially depressed the glycosylation of alpha' but allowed the glycosylation of alpha.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of ascorbic acid on collagen polypeptide synthesis and proline hydroxylation during the growth of cultured fibroblasts

The rate of collagen synthesis relative to the rate of synthesis of noncollagen protein was determined in several lines of cultured fibroblasts using an assay which measures [¹⁴C]proline incorporation into the polypeptide chains of collagen. In this assay procedure, collagen is degraded by protease-free collagenase regardless of whether proline and lysine residues are hydroxylated, thus separating the process of polypeptide synthesis from hydroxylation. It was found that the relative rate of collagen synthesis in L-929 cells was approximately 0.8–1% at all stages of growth. There was no significant increase in the relative rate of collagen synthesis in stationary phase compared to log phase cells in the lines Balb 3T3, 3T6, 3T12, and Swiss mouse 3T6. In all cases, the absolute incorporation of [¹⁴C]proline into both collagen and noncollagen proteins expressed as radioactivity incorporated per milligram of cellular protein, was 2–10 times higher in log phase cells, depending on the line examined.     

The formation of hydroxyproline in collagen by cells grown in the absence of serum

L-929 and 3T6 cells were conditioned to grow in a chemically defined medium lacking serum and ascorbate. Serum, when added, had a small stimulatory effect on the growth rate of the cells, but ascorbate had no effect either on the growth rate or on the rate of protein synthesis. These cells were also shown to lack gulonolactone oxidase activity and therefore could not synthesize their own ascorbate. Nevertheless, in the absence of serum and ascorbate both cell types were able to hydroxylate peptidyl proline to an appreciable extent. This suggest that reductant other than ascorbate can at least partially satisfy the requirement for a reductant in the prolyl hydroxylase reaction in vivo.     

The formation of hydroxyproline in collagen by cells grown in the absence of serum.

L-929 and 3T6 cells were conditioned to grow in a chemically defined medium lacking serum and ascorbate. Serum, when added, had a small stimulatory effect on the growth rate of the cells, but ascorbate had no effect either on the growth rate or on the rate of protein synthesis. These cells were also shown to lack gulonolactone oxidase activity and therefore could not synthesize their own ascorbate. Nevertheless, in the absence of serum and ascorbate both cell types were able to hydroxylate peptidyl proline to an appreciable extent. This suggests that reductants other than ascorbate can at least partially satisfy the requirement for a reductant in the prolyl hydroxylase reaction in vivo.     

Hydralazine differentially increases mRNAs for the alpha and beta subunits of prolyl 4-hydroxylase whereas it decreases pro alpha 1(I) collagen mRNAs in human skin fibroblasts.

We have used specific oligonucleotide probes to measure the effect of hydralazine on mRNA levels of the alpha and beta subunits of prolyl 4-hydroxylase (PH), a key post-translational modifying enzyme in collagen biosynthesis. Hydralazine exerts a paradoxical effect on collagen biosynthesis in cultured fibroblasts. Cells exposed to hydralazine synthesize substantially reduced amounts of collagen, which is severely deficient in hydroxyproline. Surprisingly, however, the level of prolyl hydroxylase activity assayed in extracts of treated cells is markedly increased, suggesting overproduction of the enzyme. Hybridization analysis indicated that in untreated cells the concentration of the alpha PH subunit mRNA was about 20-25% of the beta PH subunit mRNA concentration. Hydralazine treatment increased the mRNAs for both alpha and beta subunits of PH by three- to fourfold. A differential induction of these mRNAs was observed, however. The alpha subunit mRNA was maximally increased within 24 h, whereas the beta subunit mRNA was increased more slowly, reaching a maximum at 72 h. In contrast, the 5.8 and 4.8-kb mRNAs for pro alpha 1(I) collagen were virtually eliminated by 72 h. This study demonstrates that the increased prolyl hydroxylase activity is a direct result of hydralazine-mediated increases in steady state mRNA content for the alpha and beta subunits of this enzyme. Moreover, the earlier induction of alpha PH mRNA may provide the first evidence at the mRNA level that regulation of PH activity occurs mainly through regulation of the alpha subunit of PH. In addition, the decrease in collagen synthesis by hydralazine appears to result directly from suppression of both species of mRNA for pro alpha 1(I) collagen.     

A single polypeptide acts both as the beta subunit of prolyl 4-hydroxylase and as a protein disulfide-isomerase

A single polypeptide is shown to act both as the beta subunit of the proline hydroxylase (EC 1.14.11.2) and as a protein disulfide-isomerase (EC 5.3.4.1). When isolated from chick embryos or rat liver, the beta subunit of prolyl 4-hydroxylase and the enzyme protein disulfide-isomerase have identical molecular weights and peptide maps as produced by digestion with Staphylococcus aureus V8 protease. The apparent molecular weights of both proteins isolated from human placental tissue are slightly higher, and the human beta subunit and one of its peptides have molecular weights about Mr 500 higher than the protein disulfide-isomerase and its corresponding peptide. Experiments with polyclonal and monoclonal antibodies also suggest a structural identity between the two proteins. The beta subunit isolated from the prolyl 4-hydroxylase tetramer has protein disulfide-isomerase activity similar to protein disulfide-isomerase itself, and even the beta subunit when present in the prolyl 4-hydroxylase tetramer has one-half of this activity.