Arachidonic acid level in cellular lipids determines the amount of prostaglandins synthesized during cell growth in tissue culture

Methylcholanthrene transformed mouse fibroblast cells can be induced to synthesize prostaglandins by a short term incubation with various vasoactive agents including serum, bradykinin and thrombin or in response to mechanical detachment from the culture dish. The ability of the cells to synthesize prostaglandins upon stimulation changes during growth of the culture on the dish; the response is maximal on the first day after inoculation and decreased sharply thereafter. Feeding of the cells with fresh growth medium enhances prostaglandin production induced by all stimuli. The difference in the cell response during growth is probably not due to change of prostaglandin synthetase activity since the specific enzyme activities assayed with microsomal preparations of cells harvested from the first and third day culture are similar. However, analysis of the cellular content of arachidonic acid after saponification of the total lipid extract of cells harvested at different days of growth reveals that the level of arachidonic acid per cell during growth is parallel to the response to stimuli. It is maximal on the first day and decreases sharply on the second day and stays low on the third day. Our study suggests that the level of arachidonic acid in the cell governs the extent of prostaglandin synthesis upon stimulation.     

Synthesis of prostaglandins and cyclic AMP by cultured embryonic palate mesenchyme at various population densities

During embryonic development, facial and palate mesenchymal cells exhibit differential growth rates. Normal palatal growth is regulated in part by hormones and growth factors. Because hormonal responsiveness of some cells correlates with their cell density, we have investigated the relationship between embryonic palate mesenchymal cell population density and their ability to synthesize prostaglandins (PGs) and cyclic AMP. Primary cultures of palate mesenchymal cells exhibited typical lag, log, and stationary phases of growth with a doubling time of 32-34 hrs. The ability of cells to produce PGE2 in response to a calcium ionophore (A23187), an activator of phospholipase A2 (melittin), arachidonic acid, or serum was maximal during the period of early exponential growth. Prostaglandin F2 alpha synthesis in response to A23187 or arachidonic acid showed a similar transient increase also corresponding temporally to the period of early exponential growth. The ability to synthesize PGF2 alpha in response to melittin, however, failed to diminish after early exponential growth. The pattern of cAMP synthesis in response to isoproterenol and PGE1 was different from that seen for induced prostaglandin synthesis. A transient increase in sensitivity to isoproterenol and PGE1 was seen that corresponded temporally to the period of late exponential growth just prior to attainment of confluency. Decreased sensitivity to stimulation of either prostaglandin or cAMP production as the cells became confluent was shown to be a density-dependent phenomenon; confluent cultures that were subcultured to reestablish logarithmic growth exhibited density-dependent hormonal responses identical to those seen in primary cultures. The ability of palate mesenchymal cells to synthesize both prostaglandins and cAMP, thought to be critical for proper palatal development, might thus be related to local differential craniofacial growth rates.     

Regulation of macrophage eicosanoid production by hydroperoxy-and hydroxy-eicosatetraenoic acids.

Resident mouse peritoneal macrophages when exposed to zymosan during the first day of cell culture synthesize and secrete large amounts of prostaglandin E2 (PGE2) and leukotriene C4 (LTC4), the respective products of cyclo-oxygenase- and 5-lipoxygenase-catalysed oxygenations of arachidonic acid. Under these conditions of cell stimulation only small amounts of hydroxyeicosatetraenoic acids (HETEs) are concomitantly produced. However, exogenously added arachidonic acid is metabolized to large amounts of 12- and 15-HETE and only relatively small amounts of PGE2. No LTC4 is formed under these conditions. In contrast, resident mouse peritoneal macrophages in cell culture for 4 days synthesized less PGE2 and LTC4 when exposed to zymosan. However, these macrophage populations continue to synthesize 12-HETE from exogenously added arachidonic acid. Zymosan induced the secretion of a lysosomal enzyme, N-acetyl-beta-glucosaminidase, equally in both 1- and 4-day cultures. Both 12- and 15-hydroperoxyeicosatetraenoic acids (HPETEs), the precursors of 12- and 15-HETE, were found to be irreversible inhibitors of the cyclo-oxygenase pathway and reversible inhibitors of the 5-lipoxygenase pathway in macrophages. 15-HETE were found to be reversible inhibitors of both pathways. Thus the oxidation of arachidonic oxidation of arachidonic acid to both prostaglandins and leukotrienes may be under intracellular regulation by products of 12- and 15-lipoxygenases.     

Arachidonic acid in uterine phospholipid during early pregnancy and following hormone treatment

Evidence that prostaglandins are involved in intercellular communication during blastocyst implantation suggested that development and loss of uterine sensitivity to deciduogenic stimuli during early pregnancy might depend upon changes in uterine capacity to mobilize arachidonic acid from phospholipid. We measured levels of arachidonic acid in lipid fractions on Day 6 of pregnancy in uterine segments containing implantation sites, in uterine segments between implantation sites, and in luminal epithelial cells after a deciduogenic stimulus. Arachidonic acid in uterine phospholipid was depleted at implantation sites. With an intrauterine deciduogenic stimulus of hormonally primed ovariectomized rat uteri, the arachidonic acid content of the luminal epithelium decreased. When the fatty acid composition of the luminal epithelium was examined during pseudopregnancy and after progestin-estrogen treatment, however, no changes in arachidonic acid composition and content were observed. These data suggest that during blastocyst implantation, luminal epithelial cells at implantation sites mobilize arachidonic acid from phospholipid for prostaglandin synthesis, but that uterine sensitivity and the capacity to synthesize prostaglandins in response to the blastocyst does not depend upon changes in arachidonic acid levels in uterine phospholipid.     

Comparison of arachidonic acid metabolism between myofibroblasts and fibroblasts isolated from rat palatal mucoperiosteum

Myofibroblasts were cultured successfully from experimental wound tissue in rat palatal mucoperiosteum. Arachidonic acid metabolizing activity in cultured myofibroblasts was compared with that in fibroblasts cultured from normal mucoperiosteum. Prostaglandins biosynthesized from [14C]arachidonic acid in cell-free homogenates of both myofibroblasts and fibroblasts were prostaglandins D2, E2 and F2 alpha, and the activity producing each prostaglandin was not significantly different between the myofibroblasts and the fibroblasts, whereas smooth muscle cells, which are histologically similar to myofibroblasts, produced mainly 6-ketoprostaglandin F1 alpha, and relatively small amounts of prostaglandin E2. The release of arachidonic acid from cells prelabeled with [14C]arachidonic acid was compared among three types of cell. The calcium ionophore A23187 strongly enhanced arachidonic acid release in all three cell types. Bradykinin, 5-hydroxytryptamine and prostaglandin F2 alpha affected the stimulation of arachidonic acid release in the fibroblasts but were less or not effective in the myofibroblasts and smooth muscle cells. In addition, prostaglandin E2 biosynthesized in response to several stimuli was measured by radioimmunoassay. The content of prostaglandin E2 correlated closely with arachidonic acid release. In this study, we showed homogeneity between the myofibroblasts and fibroblasts in prostaglandin synthesizing activity and similarity in response to various stimuli between the myofibroblasts and smooth muscle cells, from the standpoint of arachidonic acid metabolism.     

Microtubule disruption enhances prostaglandin E2 production in osteoblastic cells

Prostaglandins have been implicated in the response of bone to mechanical stimuli. To explore the potential role of the cytoskeleton in the control of prostaglandin production, we examined the effect of cytoskeleton disrupting agents on arachidonic acid metabolism in rat calvaria osteoblastic cells. We found that microtubule disrupting agents increase prostaglandin E production 4-5-fold. Stimulation was first detectable at 4 h and rose sharply between 4 and 8 h. 2 h exposure to 1 microM colchicine was sufficient to produce the maximum effect. Cytochalasin B at concentrations which caused marked shape changes had no effect on prostaglandin E production or on its stimulation by colchicine. Taxol, a stabilizer of microtubules, reduced the colchicine effect. The increase in prostaglandin E production was associated with enhanced conversion of arachidonic acid to prostaglandin E2 rather than enhanced release of arachidonic acid from phospholipids. This increase in enzymatic activity was not abolished by cycloheximide treatment at concentrations which inhibited 90% of protein synthesis in the cells.     

Cultured endothelial cells increase their capacity to synthesize prostacyclin following the formation of a contact inhibited cell monolayer

The synthesis of the prostaglandins (PG), prostacyclin (PGI2), PGE2, and thromboxane A2 (TXA2), has been investigated in actively growing and contact-inhibited bovine aortic endothelial cell cultures. Cells were stimulated to synthesize prostaglandins by exposure to exogenous arachidonic acid or to the endoperoxide PGH2 and by the liberation of endogenous arachidonic acid from cellular lipids with melittin or ionophore A23187. Increased capacity of the cells to synthesize PGI2 and PGE2 was observed as a function of time in culture, regardless of the type of stimulation. TXA2 production increased with time only upon stimulation of the cells with ionophore A23187. This increased PG synthetic capacity was independent of cell density since it was mainly observed in confluent, nondividing endothelial cell cultures. The fact that increased PGI2 production in confluent cells was also observed with PGH2, a direct stimulator of PGI2 synthetase, implies that this process is independent of the arachidonate concentration within the cells or in the culture medium. This increased capacity is likely to reflect an increased activity of the PG synthetase system associated with the formation of a contact inhibited endothelial cell monolayer. A similar time-dependent increase in the PGI2 production capacity was also observed during growth of cultured bovine corneal endothelial cells.     

Beta-adrenergic stimulation of prostaglandin production by human amnion tissue

Arachidonic acid is released from specific glycerophospholipids in human amnion and is used to synthesize prostaglandins that are involved in parturition. In an investigation of the regulation of prostaglandin production in amnion, the effects of isoproterenol on discs of amnion tissue maintained in vitro were examined. Isoproterenol caused a large but transitory increase in the amount of cyclic AMP in amnion discs and this was accompanied by a sustained stimulation of the release of arachidonic acid (but not palmitic acid or stearic acid) and prostaglandin E2. The dependencies of cyclic AMP accumulation, arachidonic acid mobilization and prostaglandin E2 release on the concentration of isoproterenol were similar, each response was maximal at 10(-6) M isoproterenol and was inhibited by propranolol. Dibutyryl cyclic AMP stimulated the release of prostaglandin E2 from amnion discs. Although prostaglandin E2, when added to amnion discs caused an accumulation of cyclic AMP, it did not appear to mediate isoproterenol-induced accumulation of cyclic AMP since the latter effect was insensitive to indomethacin in concentrations at which prostaglandin production was inhibited greatly. These data support the proposition that catecholamines, found in increasing amounts in amniotic fluid during late gestation, may be regulators of prostaglandin production by the amnion.     

Preliminary observations on in vitro biosynthesis of prostaglandins E in tumor cells and virus transformed cells

Biosynthesis of prostaglandins of E series in BK virus-transformed rabbit-kidney cells (RKBK) and mouse hepatoma cells cultured in vitro with and without exogenous arachidonic acid was determined by radioimmunoassay. Elevated concentrations of prostaglandin E2 were observed in both cell types; moreover, tumor and transformed cells were capable to synthesize higher levels of prostaglandin E2 than normal cells. Mouse hepatoma cells produced more prostaglandins compared to RKBK cells; in addition they seemed less sensitive to inhibition by indomethacin. These data suggest that arachidonic acid metabolism may be another one of the intrinsic biochemical properties that differentiate tumor and virus transformed cells.     

Lipoxygenase pathways of macrophages

Resident mouse peritoneal macrophages when exposed to zymosan during the first day of cell culture synthesize and secrete large amounts of prostaglandin E2 and leukotriene (LT) C4, the respective products of cyclooxygenase- and 5-lipoxygenase-catalyzed oxygenations of arachidonic acid. Under these conditions of cell stimulation only small amounts of hydroxyeicosatetraenoic acids (HETEs) are concomitantly produced. However, exogenously added arachidonic acid is metabolized to large amounts of 12- and 15-HETE. No LTC4 is formed under these conditions. Inasmuch as 12- and 15-HETE have been shown to modulate certain lymphocyte responses, further study of the regulation of their production by macrophages is warranted.     

Specific and non specific stimulation of prostaglandin release by human skin fibroblasts in culture.--Are changes of membrane fluidity involved?

In order to study a bidirectional relationship between changes of membrane fluidity and prostaglandin synthesis, the arachidonic acid cascade was stimulated in cultured human skin fibroblasts by unspecific stimuli (hypotonicity, low calcium concentrations) and by the specific stimulus, bradykinin. Fluorescence anisotropy of trimethylammoniumdiphenylhexatriene was used to measure membrane fluidity in cell monolayers. Hypotonicity or low calcium concentrations induce membrane fluidisation and prostaglandin synthesis. However, after specific stimulation of prostaglandins with bradykinin (at normocalcic and isotonic conditions) a rigidification of plasma membranes was observed in living cells. Fluidisation of membranes and bradykinin activate phospholipase A2 and induce prostaglandin synthesis. Although in cell membrane preparations increased phospholipase A2 activity leads to fluidisation, in our model a membrane fluidisation was not observed after stimulation of phospholipase with bradykinin. This suggests that in living cells a fluidizing effect of lysolecithin resulting from phospholipase A2 activation may be rapidly counteracted by its removal. A decrease of phosphatidylcholin content and consequently a rigidification of the membrane may ensue. Thus, the cell culture model using two different ways of stimulating phospholipase activity, helps to define the directional relationship between changes of membrane fluidity and activation of phospholipase and the arachidonic acid cascade in living human cells.     

Beta-adrenergic stimulation of prostaglandin production by human amnion tissue

Arachidonic acid is released from specific glycerophospholipids in human amnion and is used to synthesize prostaglandins that are involved in parturition. In an investigation of the regulation of prostaglandin production in amnion, the effects of isoproterenol on discs of amnion tissue maintained were examined. Isoproterenol caused a large but transitory increase in the amount of cyclic AMP in amnion discs and this was accompanied by a sustained stimulation of the release of arachidonic acid (but not palmitic acid or stearic acid) and prostaglandin E₂. The dependencies of cyclic AMP accumulation, arachidonic acid mobilization and prostaglandin E₂ release on the concentration of isoproterenol were similar, each response was maximal at 10⁻⁶ M isoproterenol and was inhibited by propranolol. Dibutyryl cyclic AMP stimulated the release of prostaglandin E₂ from amnion discs. Although prostaglandin E₂, when added to amnion discs caused an accumulation of cyclic AMP, it did not appear to mediate isoproterenol-induced accumulation of cyclic AMP since the latter effect was insensitive to indomethacin in concentrations at which prostaglandin production was inhibited greatly. These data support the proposition that catecholamines, found in increasing amounts in amniotic fluid during late gestation, my be regulators of prostaglandin production by the amnion.     

Prostacyclin production by human endothelial and bovine smooth muscle cells in culture. Effect of repeated stimulation with arachidonic acid, thrombin and ionophore A23187

Prostacyclin (prostaglandin I2) is the major product of arachidonic acid metabolism in vascular cells. Its physiological role may be linked to the ability of the cells to respond continuously with prostaglandin I2 production to a variety of stimuli. We report that human endothelial cells or bovine smooth muscle cells in culture respond with prostaglandin I2 synthesis to a first but not to a second stimulation with arachidonic acid. The development of this refractoriness was independent of the arachidonic acid concentration used (6.6-25 microM) and lasted for about 6 h. The same time was required for the cells to recover completely after inhibition of cyclooxygenase activity by aspirin. Neither cis-polyunsaturated fatty acids (linoleic or oleic acids) nor stearic acid (a long-chain saturated fatty acid) prevented the generation of prostaglandin I2 by arachidonic acid. Similarly to arachidonic acid, thrombin and ionophore A23187 could elicit vascular prostaglandin I2 synthesis only once. Pretreatment of the cells with arachidonic acid rendered the cells unresponsive to any other stimulus. These results indicate that the mechanism of the refractoriness induced by arachidonic acid was different from that induced by the other stimuli. It is proposed that vascular cells cannot be stimulated continuously to produce prostaglandin I2, but this process is regulated by different feedback mechanisms.     

Interactions of lectins with CHO cell surface membranes. I. Competition studies indicate concanavalin A and WGA bind to discrete populations of sites

Human platelet-derived growth factor (PDGF) stimulates release of arachidonic acid from cellular phospholipids, synthesis and release of prostaglandins from the cell, and initiation of DNA synthesis in cultures of 3T3 Swiss mouse fibroblasts at similar concentrations with four independent preparations representing a million-fold range of purification. Stimulation of archidonic acid and prostaglandin release is an early event (beginning within minutes) in the response to PDGF treatment. Incubating cells with PDGF at 4°C followed by washing leads to activation of archidonic acid release on warming the cells to 37°C, consistent with binding of the factor to the cell surface. PDGF-stimulated arachidonic acid release, prostaglandin release, and initiation of DNA synthesis are all inhibited by phenylglyoxal at similar concentrations. These results suggest that activation of arachidonic acid release from phospholipids plays an essential role in the mechanism by which PDGF stimulates the initiation of DNA synthesis in 3T3 cells. The stimulation of initiation of DNA synthesis by PDGF does not appear to be mediated by the synthesis of prostaglandins or other known arachidonic acid metabolites because neither indomethacin (a fatty acid cyclooxygenase inhibitor) nor phenidone (a lipoxygenase inhibitor) inhibit initiation of DNA synthesis at concentrations which inhibit arachidonic acid metabolism. Although the activation of arachidonic acid release by PDGF is a calcium-dependent process, a simple calcium flux appears unimportant to the mechanism of activation. Evidence was also obtained against an involvement of sodium fluxes or proteolytic activity in the mechanism of stimulating arachidonic acid release by PDGF or serum.     

Altered arachidonic acid metabolism during differentiation of the human monoblastoid cell line U937

The human cell line U937 was used as a model for differentiation along the mononuclear phagocyte lineage. Following treatment with the phorbol ester TPA, PGE2 and TxB2 secretion was induced 50-100-fold, and both PGF2 alpha and PGI2 levels became detectable in the supernatant of TPA-differentiated U937 cells. The content of the prostaglandin precursor, arachidonic acid, remained unchanged in the cellular phospholipids of undifferentiated and TPA-differentiated U937 cells. Of the enzymes involved in the availability and metabolism of arachidonic acid, phospholipase A2 activity was increased 2-fold in the membranes of TPA-differentiated U937 cells, whereas lysophosphatide acyltransferase activity remained unaltered. Cyclooxygenase activity, however, was enhanced 5-10-fold, which was due to enhanced expression of the enzyme as demonstrated by dot-blot analysis. The data suggest that the capacity to secrete prostaglandins is acquired during differentiation with TPA and results mainly from an increased cyclooxygenase activity. Despite the capacity of TPA-differentiated U937 cells to synthesize prostaglandins, none of the known monocytic stimuli further stimulated prostaglandin secretion in TPA-differentiated U937 cells. Generation of leukotrienes appears to represent a later state in the differentiation along the monocyte-macrophage lineage, since neither LTB4 nor cysteinyl-leukotrienes were detectable in the supernatants of either undifferentiated or TPA-differentiated U937 cells.     

Effects of isolation and culture on prostaglandin synthesis by porcine aortic endothelial and smooth muscle cells

Freshly isolated neonatal porcine aortic tissue (smooth muscle with or without endothelium present) produced approximately 30 ng/mg wet tissue of 6-oxo-prostaglandin F1 alpha (the stable hydrolysis product from prostacyclin) and approximately 15 ng/mg of prostaglandin E2, as measured by radioimmunoassay after 24 h incubation in culture medium. Primary cultures of porcine endothelial and smooth muscle cells (isolated by enzymic digestion of aortic tissue) exhibited the same pattern of prostaglandin production, but absolute values were greater than for fresh tissue, particularly in the case of endothelium. Subcultures of endothelium produced smaller amounts of prostaglandins, although the pattern remained similar. In contrast, subcultures of smooth muscle cells produced a greater total amount of prostaglandins than did primary cultures, and the main product was prostaglandin E2. Experiments with [14C] prostaglandin H2 or [14C]arachidonic acid confirmed that aortic tissue, cultured endothelium, and primary cultures or aortic smooth muscle cells synthesized prostacyclin, and demonstrated that subcultured smooth muscle cells enzymically isomerised prostaglandin H2 to prostaglandin E2. Kinetic studies showed that prostaglandin production by cultured vascular cells was transiently increased by subculture or changing the growth medium, and that production per cell declined with increasing cell density. The change in pattern of prostaglandin production during culture was shown to be due to a rapid decline in the rate of prostacyclin production (which apparently began immediately after tissue isolation), together with a more gradual rise in prostaglandin E2 production. These results indicate that the amounts and ratios of prostaglandins produced by vascular endothelial and smooth muscle cells are greatly affected by the conditions used to isolate and culture the cells; vascular cells in vivo may similarly alter their pattern of prostaglandin production in response to local changes in their environment.     

Relationship of thrombin-stimulated arachidonic acid release and metabolism to mitogenesis and phosphatidylinositol synthesis

Thrombin and certain prostaglandins are both capable of stimulating the proliferation of cultured cells. Since thrombin stimulates the release and metabolism of arachidonic acid, the precursor of prostaglandins, we examined the relationship between this release and metabolism and the stimulation of cell division in cultured fibroblasts. We also examined the role of prostaglandin synthesis in thrombin-stimulated phosphatidylinositol synthesis. The data in this report demonstrate that the release and metabolism of arachidonic acid are not necessary for thrombin-stimulated cell division. The presence of a low concentration of chymotrypsin prevented thrombin-stimulated arachidonic acid release and metabolism without affecting the stimulation of cell division. Furthermore, thrombin-stimulated cell division occurred in the presence of indomethacin concentrations that prevented cyclooxygenase-mediated metabolism of arachidonic acid. The following experiments showed that thrombin-stimulated phosphatidylinositol synthesis was brought about by a cyclooxygenase-mediated metabolite(s) of arachidonic acid. Indomethacin inhibited the cyclooxygenase-mediated metabolism of arachidonic acid without affecting the thrombin-stimulated release of arachidonic acid. Indomethacin also inhibited thrombin-stimulated phosphatidylinositol synthesis. The dose dependence of this inhibition paralleled the inhibition by indomethacin of cyclooxygenase-mediated metabolism of arachidonic acid. In addition, prostaglandin F2 alpha stimulated phosphatidylinositol synthesis in the presence of indomethacin concentrations which prevented thrombin-stimulated phosphatidylinositol synthesis.     

Prostaglandin generation in rabbit kidney. Hormone-activated selective lipolysis coupled to prostaglandin biosynthesis.

The endogenous release of prostaglandins and free fatty acids from the isolated perfused rabbit kidney in the absence or presence of stimulation by bradykinin or angiotensin-II was investigated. Basal (nonstimulated) release of prostaglandin-precursor arachidonic acid was 15-20-fold higher than that of prostaglandin E2 indicating a low conversion of released arachidonate to prostaglandins. Addition of bovine serum albumin to the perfusion medium caused a substantial (50-250%) increase in the release of all fatty acids except myristic and arachidonic acids, and no significant change in prostaglandin E2 generation. In contrast, administration of bradykinin (0.5 microgram) or angiotensin-II (1 microgram) caused a 10-15-fold increase in prostaglandin E2 release, and with albumin present, also a 2-3-fold selective increase in arachidonic acid release. Thus, unlike what was observed under basal conditions, arachidonic acid released following hormone stimulation is efficiently converted to prostaglandin E2. We conclude that administration of bradykinin or angiotensin-II into the perfused kidney activates a lipase which selectively releases arachidonic acid, probably from a unique lipid entity. This lipase reaction is tightly coupled to a prostaglandin generating system so that the released arachidonate is first made available to the prostaglandin cyclooxygenase, resulting in its substantial conversion to prostaglandins.     

Cyclic AMP inhibits the release of prostaglandins and arachidonic acid from cultures of mouse embryo palate mesenchyme cells

Mouse embryo palate mesenchyme (MEPM) cells are able to synthesize and respond to prostaglandins. However, mechanisms that regulate their synthesis in these cells are not known. Cyclic adenosine 3',5' monophosphate (cAMP) has been implicated as being involved in differentiation of the palate, accumulates in MEPM cells in response to stimulation with selected prostaglandins, and has been found to modulate synthesis of prostaglandins by other cells and tissues. Therefore, we have investigated whether cAMP modulates synthesis of prostaglandins by MEPM mesenchyme cells and partially characterized the metabolic site at which such modulation occurs. We found that treatment of MEPM cells with various agents to stimulate a seven- to 100-fold increase in intracellular levels of cAMP inhibited release of various prostaglandins by at least 50%. Similarly, elevation of intracellular levels of cAMP inhibited release of radiolabeled arachidonic acid from membrane phospholipids by as much as 27%. The inhibitory effects of cAMP on release of prostaglandins from MEPM cells could be almost completely overcome by the addition of arachidonic acid to the culture medium. We interpret these data to mean that there is a regulatory cycle in MEPM cells in which intracellular levels of cAMP regulates synthesis of prostaglandins and prostaglandins regulate accumulation of cAMP and regulation of synthesis of prostaglandins by cAMP is predominantly through inhibition of a phospholipase.     

Collagen lattice effects on fibroblast arachidonic acid metabolism

Fibroblasts are routinely maintained in vitro on tissue culture plastic, in an environment which is devoid of collagen, the most abundant extracellular protein in dermis. Recent work has shown that by seeding fibroblasts into a collagen matrix, many aspects of their metabolism change dramatically: they stop proliferation, organize and contract the collagen matrix, and secrete much larger quantities of the usual extracellular matrix components. Because so many fibroblast functions are dramatically altered by the presence of the collagen matrix, matrix effects on fibroblast metabolism of arachidonic acid were examined. The studies presented here show that during the period of matrix contraction, metabolism of arachidonate to prostaglandins by fibroblasts is increased sixfold compared to cells plated on plastic, and that this increase is correlated with contraction but does not regulate it. The increase in prostaglandin synthesis is due in part to an increased new synthesis of the rate-limiting enzyme in prostaglandin synthesis, cyclooxygenase. No change in the profile of products the fibroblasts synthesize from arachidonate is induced by the presence of the matrix. After the lattice contraction is complete, the basal arachidonate metabolism of matrix-embedded cells have the same capacity to synthesize PGE2 in response to IL-1 as do cells grown on plastic. However, the response to the hormone agonist bradykinin by the matrix-embedded cells is present on day 1 but not on day 3, the time when cells grown on plastic are most responsive. These data indicate that while basal prostaglandin metabolism is unaffected in quiescent fibroblasts which have been embedded in a collagen matrix, response to hormone agonists may be greatly attenuated. The changes in the metabolism of arachidonate which occur during the process of matrix contraction and organization may play a part in the regulation of wound repair.