Studies on enzymes of collagen biosynthesis and the synthesis of hydroxyproline in macrophages and mast cells

The activities of four intracellular enzymes of collagen biosynthesis were assayed in freshly isolated rat peritoneal macrophages and mast cells and compared with the same enzymes in freshly isolated chick-embryo tendon cells. The macrophages were found to contain activities of all four enzymes, those of prolyl and lysyl hydroxylase being 7 and 12% respectively of those in the tendon cells when expressed per cell or 3 and 4% when expressed per unit of soluble cell protein. The corresponding values for hydroxylysyl galactosyltransferase and galactosylhydroxylysyl glucosyltransferase activities were about 82 and 68% or 32 and 24% respectively. When the macrophages were incubated in suspension with [(14)C]proline, they synthesized a small but significant amount of non-diffusible hydroxy[(14)C]proline. The synthesis per cell was only about 0.1% of that formed by the tendon cells, and its distribution between the cells and the medium also differed from that in the tendon cells. The hydroxy[(14)C]proline synthesized by the macrophages may be present in the Clq subcomponent of the complement, but its amount was too small to allow any characterization of the protein. All four enzyme activities, and in particular the two hydroxylysyl glycosyltransferase activities, seem to be present in macrophages in a large excess compared with the very low rate of synthesis of hydroxy-proline-containing polypeptide chains. The mast cell extract was found to inhibit all four enzyme activities, but even when corrected for this inhibition, prolyl and lysyl hydroxylase activities in the mast cells were less than 0.08% and the two hydroxylysyl glycosyltransferase activities less than 1% of those in the tendon cells. The intracellular enzyme pattern of collagen biosynthesis in the mast cells is thus completely or virtually completely repressed.     

Localization of collagen prolyl hydroxylase to the hepatocyte : Studies in primary monolayer cultures of parenchymal cells from adult rat liver

Significant levels of prolyl hydroxylase activity (prolyl-glycyl-peptide, 2-oxoglutarate: oxygen oxidoreductase; EC 1.14.11.2) have been found in freshly isolated hepatocytes prepared from normal or regenerated adult rat liver and primary non-proliferating monolayer cultures of these cells. Four days after partial hepatectomy, the intact regenerated liver contained two times the normal level of prolyl hydroxylase activity. Freshly isolated hepatocytes contained 24% of the total prolyl hydroxylase activity in normal liver and 47% of that in regenerated liver. Upon incubation of hepatocytes for 24 h in a chemically defined culture medium containing insulin, prolyl hydroxylase activity rose 2- to 3-fold, and gradually declined during the next 48 h. The rise in prolyl hydroxylase activity was blocked by addition of cycloheximide to the culture medium. The presence of prolyl hydroxylase activity in hepatocyte cultures was not likely due to contamination with non-parenchymal liver cells. The latter cells contained less than 20% of the total enzyme activity recovered in all cells isolated from the liver. Furthermore, prolyl hydroxylase was localized by immunofluorescence uniformly to the hepatocytes in culture. Cultured hepatocytes converted [¹⁴C]proline to [¹⁴C]hydroxyproline at rates comparable to those reported for whole liver. However, only a small portion of the hydroxyproline containing product was present as collagen protein, suggesting its rapid degradation in culture. We conclude that the liver parenchymal cell may actively participate in collagen synthesis and possibly in collagen degradation.     

Regulation of collagen post-translational modification in transformed human and chick-embryo cells.

Changes in the regulation of collagen post-translational modification in transformed cells were studied in three established human sarcoma cell lines and in chick-embryo fibroblasts freshly transformed by Rous sarcoma virus. The collagens synthesized by all but one of these and by all the control human and chick-embryo cell lines were almost exclusively of types I and/or III. The relative rate of collagen synthesis and the amounts of prolyl hydroxylase activity and immunoreactive protein were markedly low in all the transformed human cell lines. The other enzymes studied, lysyl hydroxylase, hydroxylysyl galactosyltransferase and galactosylhydroxylysyl glucosyltransferase, never showed as large a decrease in activity as did prolyl hydroxylase, suggesting a more efficient regulation of the last enzyme than of the three others. The chick-embryo fibroblasts freshly transformed by Rous sarcoma virus differed from the human sarcoma cells in that prolyl hydroxylase activity was distinctly increased, whereas the decreases in immunoreactive prolyl hydroxylase protein and the three other enzyme activities were very similar to those in the simian-virus-40-transformed human fibroblasts. It seems possible that this increased prolyl hydroxylase activity is only a temporary phenomenon occurring shortly after the transformation, and may be followed by a decrease in activity later. The newly synthesized collagens of all the transformed cells that produced almost exclusively collagen types I and/or III had high extents of lysyl hydroxylation, and there was also an increase in the ratio of glycosylated to non-glycosylated hydroxylysine. The data suggest that one critical factor affecting modification is the rate of collagen synthesis, which affects the ratio of enzyme to substrate in the cell.     

Regulation of plasminogen receptor expression on human monocytes and monocytoid cell lines

The capacity of human monocytoid cell lines and peripheral blood monocytes to modulate their expression of plasminogen receptors has been assessed. After PMA stimulation, THP-1 or U937 monocytoid cells were separated into adherent and nonadherent populations. Plasminogen bound to adherent cells with similar capacity and affinity as to nonstimulated cells. In contrast, the nonadherent cells bound plasminogen with 5-17-fold higher capacity (without a change in affinity). This increase was selective as urokinase bound with similar affinity and capacity to the adherent and nonadherent populations. Upregulation of plasminogen receptors on the nonadherent monocytoid cells was rapid, detectable within 30 min, and reversible, adhesion of the nonadherent cells resulted in a sixfold decrease in plasminogen binding within 90 min. The increase in plasminogen binding to the nonadherent cells was associated with a marked increase in their capacity to generate plasmin activity from cell-bound plasminogen. PMA stimulation of human peripheral blood monocytes increased their expression of plasminogen receptors by two- to fourfold. This increase was observed in both adherent and nonadherent monocytes. Freshly isolated monocytes maximally bound 5.0 x 10(5) plasminogen molecules per cell, whereas monocytes cultured for 18 h or more maximally bound 1.7 x 10(7) molecules per cell, a 30-fold difference in receptor number. These results indicate that both monocytes and monocytoid cell lines can rapidly and markedly regulate their expression of plasminogen binding sites. As enhanced plasminogen binding is correlated with an increased capacity to generate plasmin, an enzyme with broad substrate recognition, modulation of plasminogen receptors may have profound functional consequences.     

Phosphorylation of pig brain microtubule proteins. General properties and partial characterization of endogenous substrate and cyclic AMP-dependent protein kinase.

Collagen synthesis and the activities of prolyl hydroxylase, lysyl hydroxylase, collagen galactosyltransferase and collagen glucosyltransferase were studied in isolated chick-embryo tendon cells after the administration of cortisol acetate to the chick embryos. When the steroid was injected 1 day before isolation of the tendon cells, collagen synthesis was decreased, even though the enzyme activities were not changed. When cortisol acetate was given as repeated injections over a period of 4 days, both collagen synthesis and the enzyme activities decreased. The hydroxylase activities decreased even more than the two collagen glycosyltransferase activities, both in isolated cells and in whole chick embryos. The amount of prolyl hydroxylase protein diminished to the same extent as the enzyme activity, indicating that cortisol acetate inhibits enzyme synthesis. The inhibitory effect of cortisol acetate on collagen synthesis and on the enzyme activities was partially reversible in 3 days. Total protein synthesis was completely restored within this time. Only massive doses of cortisol acetate inhibited collagen synthesis in vitro. Additional experiments indicated that cortisol acetate did not decrease the rate of the enzyme reactions when added directly to the enzyme incubation mixtures. The results suggest that cortisol acetate decreases collagen synthesis both by its direct effect on collagen polypeptide-chain synthesis and by decreasing the activities of enzymes involved in post-translational modifications.     

Further characterization of embryonic tendon fibroblasts and the use of immunoferritin techniques to study collagen biosynthesis

Morphological studies were carried out on fibroblasts from chick embryo tendons, cells which have been used in a number of recent studies on collagen biosynthesis. The cells were relatively rich in endoplasmic reticulum and contained a well-developed Golgi complex comprised of small vesicles, stacked membranes, and large vacuoles. Techniques were then devised for preparing cell fragments which were penetrated by ferritin-antibody conjuates but which retained the essential morphological features of the cells. Finally, the new procedures were employed to develop further information as to how collagen is synthesized. As reported elsewhere, preliminary studies with ferritin-labeled antibodies showed that prolyl hydroxylase was found in the endoplasmic reticulum of freshly isolated fibroblasts and that procollagen is found in both the cisternae of the endoplasmic reticulum and the large Golgi vacuoles. In the experiments described here, the cells were manipulated so that amino acids continued to be incorporated into polypeptide chains but assembly of the molecule was not completed because hydroxylation of prolyl and lysyl residues was prevented. The results indicated that these manipulations produced no change in the distribution of prolyl hydroxylase. Examination of the cells with ferritin conjugated to antibodies which reacted with protocollagen, the unhydroxylated form of procollagen, demonstrated that protocollagen was retained in the cisternae of the endoplasmic reticulum during inhibition of the prolyl and lysyl hydroxylases. Assays for prolyl hydroxylase with an immunologic technique demonstrated that although the enzyme is found within the endoplasmic reticulum, it is not secreted along with procollagen. The observations provided further evidence for a special role for prolyl hydroxylase in the control of collagen biosynthesis.     

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.     

Collagen biosynthesis. Characterization of subcellular fractions from embryonic chick fibroblasts and the intracellular localization of protocollagen prolyl and protocollagen lysyl hydroxylases

1. Subcellular fractions of freshly isolated matrix-free embryonic chick tendon and sternal cartilage cells have been characterized by chemical analysis, electron microscopy and the location of specific marker enzymes. These data indicate the fractions to be of a high degree of purity comparable with those obtained from other tissues, e.g. liver and kidney. 2. When homogenates were assayed for protocollagen prolyl hydroxylase and protocollagen lysyl hydroxylase activities, addition of Triton X-100 (0.1%, w/v) was found to stimulate enzyme activities by up to 60% suggesting that the enzymes were probably membrane-bound. 3. Assay of subcellular fractions obtained by differential centrifugation for protocollagen prolyl hydroxylase activity indicated the specific activity to be highest in the microsomal fraction. Similar results were obtained for protocollagen lysyl hydroxylase activity. 4. Submicrosomal fractions obtained by discontinuous sucrose-gradient centrifugation were assayed for the two enzymes and protocollagen prolyl hydroxylase and protocollagen lysyl hydroxylase were found to be associated almost exclusively with the rough endoplasmic reticulum fraction in both tendon and cartilage cells.     

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.     

Lack of collagen type specificity for lysyl hydroxylase isoforms

Lysyl hydroxylase is the enzyme catalyzing the formation of hydroxylysyl residues in collagens. Large differences in the extent of hydroxylysyl residues are found among collagen types. Three lysyl hydroxylase isoenzymes (LH1, LH2, LH3) have recently been characterized from human and mouse tissues. Nothing is known about the distribution of these isoforms within cells or whether they exhibit collagen type specificity. We measured mRNA levels of the three isoforms, as well as the mRNAs of the main collagen types I, III, IV, and V and the alpha subunit of prolyl 4-hydroxylase, another enzyme involved in collagen biosynthesis, in different human cell lines. Large variations were found in mRNA expression of LH1 and LH2 but not LH3. Immunoblotting was utilized to confirm the results of Northern hybridization. The levels of mRNA of LH1, LH2, and the alpha subunit of prolyl 4-hydroxylase showed significant correlations with each other. The LH3 mRNA levels did not correlate with those of LH1, LH2, or the alpa subunit of prolyl 4-hydroxylase, clearly indicating a difference in the regulation of LH3. No correlation was observed between LH isoforms and individual collagen types, indicating a lack of collagen type specificity for lysyl hydroxylase isoforms. Our observations suggest that LH1, LH2, and the alpha subunit of prolyl 4-hydroxylase are coregulated together with total collagen synthesis but not with the specific collagen types and indicate that LH3 behaves differently from LH1 and LH2, implying a difference in their substrates. These observations set the basis for further studies to define the functions of lysyl hydroxylase isoforms.     

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.     

Submicrosomal localization of prolyl hydroxylase from chick embryo limb bone.

A fraction greatly enriched in microsomes was prepared from chick embryo limb bone tissue homogenates by differential centrifugation in a high density solution of Metrizamide. This fraction was used to determine the submicrosomal localization of prolyl hydroxylase. At a low concentration (0.05%) of the non-ionic detergents Triton X-100 and Brij-35, 90 to 93% of prolyl hydroxylase activity was released from microsomes. Concentrations of Triton X-100 greater than 0.1% were required to solubilize the intrinsic membrane enzyme NADH-ferricyanide reductase and to release membrane-bound ribosomes, while Brij-35 did not extensively solubilize membrane components even at concentrations up to 0.4%. In addition, prolyl hydroxylase activity which could subsequently be released from microsomes by Brij-35 was relatively resistant to trypsin proteolysis at concentrations which removed more than 50% of the ribosomes and approximately 40% of the protein from microsomes. These results suggest that 90 to 93% of prolyl hydroxylase activity in connective tissue is located within the cisternae of the endoplasmic reticulum. Gel filtration of prolyl hydroxylase released from microsomes or found in the soluble fraction of limb bone homogenates revealed two peaks of activity corresponding to molecular weights of 230,000 and 450,000 to 500,000. The latter is twice the value reported for purified chick embryo prolyl hydroxylase. A fraction of the total prolyl hydroxylase activity (generally 20 to 35%) in microsome preparations could be measured in the absence of detergent, although the microsomal membrane should be impermeable to the large unhydroxylated collagen chains used as substrate. On the basis of experimental data, it was concluded that detergent-independent activity was most likely due to damaged microsomal membranes and that this damage was sufficient to allow substrate and trypsin to enter the cisternae but not to allow prolyl hydroxylase to be released.     

Heterogeneity of human monocytes: differences in response to IFN-gamma

Human peripheral blood monocytes can be separated into two subpopulations which differ in the efficiency of their adherence to glass after 16 hours of incubation. The adherent subpopulation was found to be about twice as effective in binding mannose-resistant E. coli 0-124, mannose-sensitive E. coli 0-128 and opsonised E. coli than the nonadherent one. In addition, reduction of cytochrome C in response to E. coli binding or 12-myristate 13-acetate (PMA) stimulation was two fold higher in adherent cells. The binding of E. coli O-124 and the superoxide generation stimulated by E. coli were inhibited by the addition of mannose only in the adherent monocytes, indicating the presence of mannose receptors on the cell surface in the adherent subpopulation. The treatment of the nonadherent cells with 0.1-1000 U/ml of Interferon (IFN-gamma) for 24 hours resulted in a dose dependent increase in superoxide generation. After 72 hours of incubation with IFN-gamma (1000 U/ml) the amount of superoxide generated by the nonadherent cells was elevated to 20.5 +/- 1.4 nmoles/10(6) cells/15 min, similar to that of the adherent cells (24.5 +/- 1.2 nmoles/10(6) cells/15 min untreated adherent monocytes). The generation of superoxide in the IFN-gamma treated nonadherent monocytes stimulated by E. coli 0-128 was significantly reduced by addition of mannose.     

Regulation of prolyl and lysyl hydroxylase activities in cultured human skin fibroblasts by ascorbic acid

Studies with confluent human skin fibroblasts maintained in 0.5% serum supplemented medium have given new insight into the regulatory influences of ascorbate. These include a reduction of prolyl hydroxylase activity, a stimulation of lysyl hydroxylase activity, and an acceleration of collagen production. The lack of parallel between prolyl hydroxylase activity and collagen production indicates that the rate of collagen synthesis is not controlled by the level of prolyl hydroxylase.     

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.     

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.     

Prolyl hydroxylase production can be uncoupled from the regulation of procollagen synthesis

Primary avian tendon (PAT) cells increase the production of procollagen from 10-12% to 40-50% of total protein synthesis in response to the addition of ascorbate and an increasing cell density. We now show that prolyl hydroxylase (PH) also increases its activity by greater than five-fold in response to increasing cell density; but unlike procollagen production, this is independent of the presence of ascorbate. The increased activity is a result of greater enzyme production and not a shift in the ratio of inactive to active forms which remains constant at about 10% of the total enzyme proteins. We present the possibility that at low cell density the levels of PH activity could limit production of collagen.     

Intracellular enzymes of collagen biosynthesis in rat liver as a function of age and in hepatic injury induced by dimethylnitrosamine. Changes in prolyl hydroxylase, lysyl hydroxylase, collagen galactosyltransferase and collagen glucosyltransferase activities.

The relationship between the changes in the four enzyme activities catalysing intracellular post-translational modifications in collagen biosynthesis were studied in rat liver as a function of age and in experimental hepatic injury induced by the administration of dimethylnitrosamine. During aging, relatively large changes were found in prolyl hydroxylase and lysyl hydroxylase activities, whereas only minor changes took place in collagen galactosyltransferase and collagen glucosyltransferase activities. In hepatic injury, the two hydroxylase activities increased earlier and to a larger extent than did the two glycosyltransferase activities, and the largest was found in lysyl hydroxylase activity. The data support previous suggestions that changes in the rate of collagen biosynthesis in the liver cannot be explained simply by a change in the number of collagen-producing cells, but regulation of the enzyme activities existed, so that the two hydroxylase activities altered considerably more than did the two collagen glycosyltransferase activities.     

The stimulatory effect of platelet homogenate on prolyl hydroxylase activity in L-929 cells

We have found that the addition of platelet homogenate to confluent cultures of L-929 cells increases 2-3 times the activity of prolyl hydroxylase in these cells. Furthermore, it was found that the platelet homogenate potentiates the effect of ferrous ions and ascorbic acid, which are known activators of prolyl hydroxylase. The effect of the platelet homogenate is diminished by cycloheximide. It seems probable that some products present in the platelet homogenate may promote biosynthesis of the enzyme or they stimulate glycolysis and accumulation of lactic acid, an activator of the hydroxylase.     

Immunological characterization of lysyl hydroxylase, an enzyme of collagen synthesis

Antibodies to pure lysyl hydroxylase from whole chick embryos were prepared in rabbits and used for immunological characterization of this enzyme of collagen biosynthesis. In double immunodiffusion a single precipitation line was seen between the antiserum and crude or pure chick-embryo lysyl hydroxylase. The antiserum effectively inhibited chick-embryo lysyl hydroxylase activity, whether measured with the biologically prepared protocollagen substrate or a synthetic peptide consisting of only 12 amino acids. This suggests that the antigenic determinant was located near the active site of the enzyme molecule. Essentially identical amounts of the antiserum were required for 40% inhibition of the same amount of lysyl hydroxylase activity units from different chick-embryo tissues synthesizing various genetically distinct collagen types. In double immunodiffusion a single precipitation line of complete identity was found between the antiserum and the purified enzyme from whole chick embryos and the crude enzymes from chick-embryo tendon, cartilage and kidneys. These results do not support the hypothesis that lysyl hydroxylase has collagen-type-specific or tissue-specific isoenzymes with markedly different specific activities or immunological properties. The antibodies to chick-embryo lysyl hydroxylase showed a considerable degree of species specificity when examined either by activity-inhibition assay or by double immuno-diffusion. Nevertheless, a distinct, although weak, cross-reactivity was found between the chick-embryo enzyme and those from all mammalian tissues tested. The antiserum showed no cross-reactivity against prolyl 3-hydroxylase, hydroxylysyl galactosyl-transferase or galactosylhydroxylysyl glucosyltransferase in activity-inhibition assays, whereas a distinct cross-reactivity was found against prolyl 4-hydroxylase. Furthermore, antiserum to pure prolyl 4-hydroxylase inhibited lysyl hydroxylase activity. These findings suggest that there are structural similarities between these two enzymes, possibly close to or at their active sites.