The relationship between mouthrinse matrix metalloproteinases (MMP-1, 8, 13) and albumin levels with the degree of oral mucositis in allogeneic stem cell transplant patients.

Our aim was to examine the relationship between mouthrinse matrix metalloproteinases (MMPs) and whole albumin levels (AL) relative to oral mucositis (OM) in allogeneic stem cell transplant (alloSCT) patients. Mouthrinse vertebrate collagenase levels are positively correlated with connective tissue destruction (CTD) in periodontitis and may also be involved in CTD associated with OM. Increases in salivary AL have been noted prior to OM onset and may serve as a predictive tool for OM and as a positive control in this study. A total of 23 alloSCT patients were visited eight times over 4 weeks following the transplant. OM was scored via a previously validated examiner-based ordinal system. Mouthrinse samples were collected and analyzed for MMP-1, 8, 13 (members of the vertebrate collagenase group) and AL. No significant correlation was found for MMP levels relative to OM scores. AL were positively and significantly associated with OM scores (P<0.001). MMP levels may not be an important factor in OM development and severity; however, mouthrinse AL may serve as a more objective measure of OM development and severity.

Inhibition of osteogenesis in vitro by a cigarette smoke-associated hydrocarbon combined with Porphyromonas gingivalis lipopolysaccharide: reversal by resveratrol.

BACKGROUND: Smoking and infection with Gram-negative bacterial pathogens are risk factors for alveolar bone loss. The aims of this study were: 1) to examine the combined effects of an aryl hydrocarbon, benzo[a]pyrene (BaP), that is concentrated in cigarette smoke, and lipopolysaccharide (LPS) extracted from Porphyromonas gingivalis on osteogenesis in a rat bone marrow cell (RBMC) model of osteogenesis; and 2) to determine whether resveratrol (Res), an aryl hydrocarbon receptor antagonist, could reverse the putative inhibitory effects of BaP + LPS on osteogenesis. METHODS: LPS of P. gingivalis strain 2561 was introduced in various concentrations to the RBMC in 96-well plates and kept in culture for 8 to 12 days. The same protocol was used for studying BaP and LPS + BaP combinations. Following the incubation periods, parameters of osteogenesis were measured, including formation of mineralized bone nodules, alkaline phosphatase activity, and total cell protein. Transcription of the pro-inflammatory cytokine interleukin (IL)-1beta in the cultures was determined by reverse transcriptase polymerase chain reaction (RT-PCR). RESULTS: Bone nodule formation generally decreased significantly with increasing LPS concentrations (P<0.05), whereas total cell protein decreased only slightly (P>0.05). BaP in previously high concentrations alone also caused a significant dose-dependent decrease in bone nodule formation (P<0.05) but when half maximal doses were used, significant decreases were most often seen when LPS was added. Hence, in combination, the inhibitory effects of LPS + BaP on osteogenesis were additive, inhibiting bone nodule formation up to 9-fold. Resveratrol partially reversed the inhibitory effects of low concentrations of LPS alone, and completely reversed the inhibition of nodule formation when low concentrations of LPS were combined with BaP. IL-1beta expression generally fluctuated inversely to the inhibitory activity of LPS, LPS + BaP, and LPS + BaP + Res combinations. CONCLUSIONS: Smoke-derived aryl hydrocarbons and bacterial LPS may act additively to inhibit bone formation. The findings may explain, in part, why net periodontal bone loss is greater and bone healing is less successful in smokers than non-smokers with periodontal infections. Reversal of the inhibitory effects in vitro by resveratrol suggests that this phytoalexin should be studied further for its potential therapeutic value, given its aryl hydrocarbon receptor antagonism and apparent anti-inflammatory activity.

Inhibition of dioxin effects on bone formation in vitro by a newly described aryl hydrocarbon receptor antagonist, resveratrol.

Aryl hydrocarbon receptor (AhR) ligands are environmental contaminants found in cigarette smoke and other sources of air pollution. The prototypical compound is TCDD (2,3,7, 8-tetrachlorodibenzo-p-dioxin), also known as dioxin. There is an increasing body of knowledge linking cigarette smoking to osteoporosis and periodontal disease, but the direct effects of smoke-associated aryl hydrocarbons on bone are not well understood. Through the use of resveratrol (3,5,4'-trihydroxystilbene), a plant antifungal compound that we have recently demonstrated to be a pure AhR antagonist, we have investigated the effects of TCDD on osteogenesis. It was postulated that TCDD would inhibit osteogenesis in bone-forming cultures and that this inhibition would be antagonized by resveratrol. We employed the chicken periosteal osteogenesis (CPO) model, which has been shown to form bone in vitro in a pattern morphologically and biochemically similar to that seen in vivo, as well as a rat stromal cell bone nodule formation model. In the CPO model, alkaline phosphatase (AP) activity was reduced by up to 50% (P<0.01 vs control) in the presence of 10(-9) M TCDD and these effects were reversed by 10(-6) M resveratrol (P<0.05 vs TCDD alone). TCDD-mediated inhibition of osteogenesis was restricted primarily to the osteoblastic differentiation phase (days 0-2) as later addition did not appear to have any effects. Message levels for important bone-associated proteins (in the CPO model) such as collagen type I, osteopontin, bone sialoprotein and AP were inhibited by TCDD, an effect that was antagonized by resveratrol. Similar findings were obtained using the rat stromal bone cell line. TCDD (at concentrations as low as 10(-10)M) caused an approximately 33% reduction in AP activity, which was abrogated by 3. 5x10(-7) M resveratrol. TCDD also induced a marked reduction in mineralization ( approximately 75%) which was completely antagonized by resveratrol. These data suggest that AhR ligands inhibit osteogenesis probably through inhibition of osteodifferentiation and that this effect can be antagonized by resveratrol. Since high levels of AhR ligands are found in cigarette smoke, and further since smoking is an important risk factor in both osteoporosis and periodontal disease, it may be postulated that AhR ligands are the component of cigarette smoke linking smoking to osteoporosis and periodontal disease. If so, resveratrol could prove to be a promising preventive or therapeutic agent for smoking-related bone loss.

Regulation of osteogenesis by fetuin.

Osteoporosis is a common problem of aging and results from a failure of homeostatic mechanisms to regulate osteogenesis and mineralization. Bovine and human forms of fetuin glycoprotein bind to the transforming growth factor (TGF)-beta/BMP (bone morphogenic protein) cytokines and block their osteogenic activity in cell culture assays (Demetriou, M., Binkert, C., Sukhu, B., Tenenbaum, H. C., and Dennis, J. W. (1996) J. Biol. Chem. 271, 12755-12761). Fetuin is a prominent serum glycoprotein and a major noncollagenous component of mineralized bone in mammals. In this study, we show that recombinant fetuin and native serum protein have similar potency as inhibitors of osteogenesis in dexamethasone-treated rat bone marrow cell cultures (dex-RBMC). Recombinant bovine fetuin also bound to TGF-beta1 and BMP-2 in vitro with kinetics similar to native fetuin. Although TGF-beta1 is required for osteogenesis in dex-RBMC, the cytokine also inhibited osteogenesis at concentrations >/=10 pM. Titration of fetuin or anti-TGF-beta1 antibodies into the bone marrow cultures in the presence of 10 pM TGF-beta1 restored osteogenesis, whereas titrations of the same reagents into cultures with 0.3 pM added TGF-beta1 were inhibitory, confirming the biphasic nature of the TGF-beta1 response. Suppression of osteogenesis by both TGF-beta1 and the antagonist proteins required their presence within the first 6 days of culture, well before mineralization at 10-12 days. Northern analysis showed that both fetuin and high dose TGF-beta1 suppressed expression of the bone-associated transcripts alkaline phosphatase, osteopontin, collagen type I, and bone sialoprotein. The suppression of osteogenesis by fetuin and by high dose TGF-beta1 was accompanied by the differentiation of an alternate cell lineage with adipocyte characteristics. In summary, the biphasic osteogenic response to TGF-beta1 suggests that overlapping gradients of TGF-beta/BMP cytokines and fetuin regulate osteogenesis in remodeling bone.

Tamoxifen attenuates glucocorticoid actions on bone formation in vitro.

Tamoxifen is a synthetic estrogen analog which may regulate osteogenesis in vivo by virtue of its antiglucocorticoid properties. We have examined tamoxifen regulation of glucocorticoid-induced osteogenesis in two different in vitro bone systems: the chicken periosteal osteogenesis model (CPO) and rat bone marrow stromal cells (RBMC). Hormone uptake studies were conducted with the osteosarcoma cell line, ROS 17/2.8. In the CPO model, alkaline phosphatase (AP) activity and collagen synthesis were stimulated by the glucocorticoid dexamethasone (Dex; 0.1 microM). These Dex-mediated effects were inhibited by increasing concentrations of tamoxifen (10-100 microM). Similarly, in the RBMC model, Dex-dependent (0.01 microM Dex) mineralized tissue formation and AP activity were blocked by tamoxifen (0.1 microM). Although tamoxifen inhibited Dex-mediated increases of AP activity in ROS 17/2.8 cells, it did not inhibit uptake of 3H-Dex or of 3H-estrogen. Northern analyses showed that tamoxifen did not affect messenger RNAs (mRNAs) for AP. Tamoxifen did seem to reduce mRNA for collagen type I, but not bone sialoprotein, osteopontin, and osteocalcin. Dex-induced increases for all proteins mRNAs in the RBMC model were not reduced by tamoxifen. Similarly, tamoxifen had no effects on cellular proliferation. We conclude that tamoxifen has no direct effect on gene expression of bone-related proteins of osteoblastic cells. Further, in the ROS 17/2.8 cell line, the antiglucocorticoid properties of tamoxifen do not appear to be mediated through either Dex or estrogen receptors.

Fetuin/alpha2-HS glycoprotein is a transforming growth factor-beta type II receptor mimic and cytokine antagonist.

The serum glycoprotein fetuin is expressed during embryogenesis in multiple tissues including limb buds and has been shown to promote bone remodeling and stimulate cell proliferation in vitro. In this report, we demonstrate that fetuin antagonizes the antiproliferative action of transforming growth factor-beta1 (TGF-beta1) in cell cultures. Surface plasmon resonance measurements show that fetuin binds directly to TGF-beta1 and TGF-beta2 and with greater affinity to the TGF-beta-related bone morphogenetic proteins (BMP-2, BMP-4, and BMP-6). In a competitive enzyme-linked immunosorbent assay, fetuin blocked binding of TGF-beta1 to the extracellular domain of TGF-beta receptor type II (TbetaRII), one of the primary TGF-beta-binding receptors. A comparison of fetuin and TbetaRII shows homology in an 18-19-amino acid sequence, which we have designated TGF-beta receptor II homology 1 domain (TRH1). Since the TRH1 sequence is known to form a disulfide loop in fetuin, cyclized TRH1 peptides from both fetuin and TbetaRII were chemically synthesized and tested for cytokine binding activity. Cyclized TRH1 peptide from TbetaRII bound to TGF-beta1 with greater affinity than to BMP-2, while the cyclized TRH1 peptide from fetuin bound preferentially to BMP-2. Finally, fetuin or neutralizing anti-TGF-beta antibodies blocked osteogenesis and deposition of calcium-containing matrix in cultures of dexamethasone-treated rat bone marrow cells. In summary, these experiments define the TRH1 peptide loop as a cytokine-binding domain in both TbetaRII and fetuin and suggest that fetuin is a natural antagonist of TGF-beta and BMP activities.

Expression of tissue non-specific alkaline phosphatase stimulates differentiated behaviour in specific transformed cell populations.

BACKGROUND: Tissue non-specific alkaline phosphatase (TN-AP) is a membrane-bound glycoprotein enzyme which is characterized by its phosphohydrolytic activity. This enzyme is distributed virtually in all mammalian tissues during embryonic development (it can be demonstrated as early as the 2-cell stage) where its expression is stage specific. The expression of TN-AP is frequently associated with cell differentiation and as such it has been used as a marker for this process. By employing a stable gene transfer and forced gene expression technique, previous findings suggested that TN-AP expression might influence cellular proliferation and morphological differentiation. The focus of this study was to determine whether this was a cell-specific effect or not. METHODS: The effects of TN-AP on various aspects of cellular activity were assessed by transferring and expressing the gene for this enzyme into three target populations; 1) CHO, 2) R1610, and 3) Rat-2. The parameters of cellular activity studied included cellular proliferation, cell cycle, cell migration, and tumorigenic potential (in the nude mouse). Cell cycle and cell proliferation analyses were accomplished, in part, through the use of fluorescence activated cell sorting (FACS) as were determinations of cell-associated TN-AP activity and amount. Northern and southern blot analyses were used to estimate gene copy number and to evaluate gene expression respectively in transfected cell lines. RESULTS: Our data indicate that the TN-AP gene under control of various gene promoters was stably integrated into three fibroblast-like cell lines (CHO, R1610, and Rat-2). TN-AP activity and TN-AP protein levels were correlated to the strength of the various gene promoters, but not to inserted gene copy numbers. The expression of the TN-AP gene in these three cell types further suggests cell-specific effects as demonstrated by the following findings. The expression of TN-AP under control of a weak gene promoter in CHO and Rat-2 cells clearly decreased cell proliferation and cell migration. However, the expression of TN-AP under control of either a weak or even a strong gene promoter in R1610 cells did not induce any changes in that cell line's behaviour (apart from expression of TN-AP). Such changes in CHO cells were also associated with a 2.2-fold increase in tubulin transcription as well as suppressed tumorigenic potential. CONCLUSION: Taken together, these findings suggest that the inhibitory effects of TN-AP expression on proliferation and cell migration are not non-specific and that high expression of TN-AP may induce changes in cell behaviour which may be consistent with or at least related to induction of terminal differentiation.

Probing glucocorticoid-dependent osteogenesis in rat and chick cells in vitro by specific blockade of osteoblastic differentiation with progesterone and RU38486.

Glucocorticoids and sex-steroids can modulate osteogenesis in vivo and in vitro. Although the effects of glucocorticoids on bone cells in vitro have been described in detail, the role of sex-steroids is not as well defined. We examined whether sex-steroids influence bone metabolism indirectly by regulating glucocorticoid effects on bone. Interactions of the sex-steroid progesterone or its analog RU38486 with the glucocorticoid dexamethasone (dex) were studied in functional assays of osteogenesis. Three osteoblastic models were evaluated: (1) the rat bone marrow stromal cell (RBMC) nodule system; (2) the chick periosteal osteogenesis (CPO) model; and (3) ROS 17/2.8 cells. RU38486, progesterone, and unlabelled dex competitively inhibited 3H-dex uptake by ROS 17/2.8 cells as well as its (3H-dex) binding to cytosol preps. Both RU38486 and progesterone inhibited dex-induced increases in alkaline phosphatase in CPO cultures, in RBMC cultures, and in ROS 17/2.8 cells. Dex-induced decreases in cell proliferation in ROS 17/2.8 cells were reversed by RU38486 but dex-induced increases in proliferation in the CPO model were not affected. In CPO cultures, dex-induced increases in collagen synthesis were inhibited completely by RU38486 and progesterone. Dex-dependent nodule formation in the RBMC was blocked by RU38486. Both RU38486 and dex mediated reduction of calcium uptake in the CPO model but did not affect mineralized tissue area. The data indicate that RU38486 and progesterone competitively inhibit dex-mediated stimulation of osteogenesis in vitro; this inhibition is exerted on early but not late stage differentiation events of osteoprogenitor cells.

Effects of bisphosphonates APD and HEBP on bone metabolism in vitro.

Although the effects of the bisphosphonates on resorption have been well documented, their effects on bone formation are not as clear. Therefore, this investigation was undertaken to elucidate the role played by bisphosphonates in the regulation of bone formation in vitro. To evaluate bisphosphonate-mediated regulation of bone formation in vitro, the effects of two drugs, ethane-1-hydroxy,1-diphosphate (Etidronate) (HEBP), and the second-generation bisphosphonate, disodium-1-hydroxy-1-aminopropylidine-1,1-diphosphate (Pamidronate) (APD), were assessed in the chick periosteal osteogenesis (CPO) model. In this study, drug-induced changes in alkaline phosphatase were assessed at the cellular level by means of quantitative fluorescence histochemistry. Cellular proliferation was quantified by means of autoradiography ([3H]thymidine). Mineralization and matrix production were measured morphometrically, whereas collagen synthesis and degradation were measured biochemically. The data suggest that in addition to their effects on bone resorption, the bisphosphonates have marked and direct effects on bone formation and other parameters of osteogenesis. HEBP may affect cellular proliferation (75-80% reduction, p < 0.05) in zones distant from bone; alkaline phosphatase positive cell numbers were increased in the osteoblastic layer of cells (twofold relative to control, p < 0.05) in 12-day cultures. HEBP, but not APD, prevented mineralization-induced suppression of matrix synthesis in early stages of culture. In 6-day cultures induced to mineralize with beta-glycerophosphate, (GP) cotreatment with HEBP induced a 70% increase in collagen synthesis. In addition, degradation of collagen in the CPO cultures was inhibited by HEBP (25%) and to a lesser extent by APD (8%). Although there were no differences in bone-osteoid areas measured in 12-day cultures treated with various regimens of bisphosphonate or GP, a clear increase in bone-osteoid area was detected in 6-day cultures treated with GP and HEBP as compared to GP only. This may suggest that initially, osteoblasts may be induced to synthesize increased volumes of bone matrix when mineralization is inhibited (e.g., with HEBP), but that over time the osteoblasts make the same amount of matrix. Taken together, these findings indicate that whereas the bisphosphonates do have well-documented effects on bone resorption, their effects on bone formation may also be important.(ABSTRACT TRUNCATED AT 400 WORDS)

Direct effects of metabolic products and sonicated extracts of Porphyromonas gingivalis 2561 on osteogenesis in vitro.

It is well documented that oral microorganisms play a significant role in the initiation and progression of periodontal disease. By using various in vitro models, it has been shown that some bacteria considered periodontal pathogens or their products can stimulate bone resorption and some other parameters of osteoblast-like cell activity. However, the effects of these organisms and their products on osteogenesis itself are not known. This study was undertaken to determine the direct effects of metabolic products and sonicated extracts of Porphyromonas gingivalis on bone formation in the chick periosteal osteogenesis model. Cultures of P. gingivalis 2561 were grown under standard anaerobic culture conditions. The spent medium was collected, and following centrifugation, sonicated bacterial extracts were prepared from the bacterial pellet. These were added in various proportions to the chick periosteal osteogenesis cultures. Sonicated extracts were further fractionated into five molecular-size ranges and similarly tested. Parameters of osteogenesis, including alkaline phosphatase activity, calcium and Pi accumulation, and collagen synthesis, were measured on 6-day-old cultures. Compared with controls devoid of bacterial products, osteogenesis was inhibited significantly in cultures treated with either conditioned medium or extracts obtained from P. gingivalis. Various amounts of inhibitory activity were observed in the different ultrafiltration molecular-size fractions, with very profound inhibitory effects observed in the < 5-kDa range. Histological observations indicated the presence of cells, some bone, and/or new fibrous connective tissue at all concentrations, indicating that toxicity was not a factor. These results suggest that periodontal pathogens such as P. gingivalis might contribute to the bone loss in periodontal diseases not only by stimulating resorption but, possibly, by inhibiting bone formation directly.

Osteogenic phase-specific co-regulation of collagen synthesis and mineralization by beta-glycerophosphate in chick periosteal cultures.

Mineralized bone formation in vitro can be induced by the alkaline phosphatase substrate beta-glycerophosphate (GP). GP may not only be essential for mineralization in vitro, but could also modulate other metabolic activities of bone cells, particularly if GP is presented to these cells during different phases of development. To assess GP modulation of bone cell metabolism, biochemical and autoradiographic analyses of chick periosteal cultures treated with GP were performed. About 50% less (p less than 0.05) Type I collagen was produced in periosteal cultures treated with GP. If the fibrous portion of the periostem was microdissected from the osteogenic layer prior to culture, GP inhibition of Type I collagen synthesis was even more marked (60%: p less than 0.05). To define organic phosphate-sensitive phases of osteogenesis, cultures were exposed to GP for various time periods. Mineralization occurred reproducibly when periosteal cultures were treated with GP from the outset of the incubation period (positive control). However, if GP was added after the third day of incubation, phosphate content was the same as in positive control cultures, whereas calcium content was significantly (20%: p less than 0.05) lower. Moreover, if GP was added on day 6, there was virtually no calcium accumulation by day 12, while massive amounts of phosphate had accumulated. Taken together, these findings indicate that organic phosphates may modulate phenotypic expression of osteogenic cells, and that osteogenic cells traverse an organic phosphate-sensitive phase, after which they may be incapable of normal mineralization.

Effects of bisphosphonates and inorganic pyrophosphate on osteogenesis in vitro.

The bisphosphonates, which are chemically related to pyrophosphate, have been studied extensively both in vivo and in vitro to elucidate their effects on bone tissues and cells. However, because these agents have important effects on bone resorption, the majority of investigations have focused on this area. Few studies regarding direct bisphosphonate effects on bone formation have been carried out in the past and, thus, we chose to use the chick periosteal osteogenesis (CPO) in vitro model system to test the direct effects of pyrophosphate and the bisphosphonates ethane-1-hydroxy-1,1-diphosphate (HEBP) and disodium-1-hydroxy-1-amino-propylidine (APD) on various parameters of osteogenesis in vitro. The data show that the bisphosphonate HEBP inhibits bone mineralization reversibly while APD, at low doses, may actually enhance mineralization of bone. Similarly, pyrophosphate (PPi) will prevent mineralization in CPO cultures. However, CPO cultures can circumvent PPi-mediated blockage of mineralization with longer-term, continuous (10-day) incubation, whereas this does not occur if cultures are incubated continuously with bisphosphonates. Both drugs appear to be able to reverse beta-glycerophosphate-induced changes in alkaline phosphatase activity, but do not appear on their own to regulate the activity of this enzyme. The findings show that in addition to their well-known effects on resorption, bisphosphonates have significant and direct effects on mineralization in bone-forming cultures. Their direct effects on osteoblastic activity and differentiation remain to be determined.

The antiproliferative potency of histamine antagonists correlates with inhibition of binding of [3H]-histamine to novel intracellular receptors (HIC) in microsomal and nuclear fractions of rat liver.

Previously, we identified in rat liver microsomes, low (microM) affinity histamine receptors (HIC), associated with antiestrogen binding sites (AEBS). N,N-diethyl-2-[4-(phenylmethyl)phenoxy]ethanamine HCl (DPPE), a potent AEBS ligand, is a specific HIC antagonist. Through binding HIC, newly-formed intracellular histamine mediates, and DPPE inhibits, human platelet aggregation. We now provide evidence that histamine, mobilized from cytoplasmic stores, is a mediator of the mitogenic response to concanavalin A in mouse spleen cells. DNA synthesis and intracellular histamine levels are decreased over time by the histidine decarboxylase inhibitor, alpha-fluoromethylhistidine. For DPPE, H1 and H2 antagonists, rank order of potency to inhibit [3H]-histamine binding to HIC in rat liver microsomes correlates with antiproliferative potency. DPPE also competes for [3H]-histamine binding at low and high affinity sites in rat liver nuclei (IC50 approximately 2 microM). Thus, histamine may mediate growth through two intracellular subtypes of HIC.

Does intracellular histamine mediate mast cell histamine release?

Previously, we demonstrated that through binding a novel intracellular receptor of microM affinity (HIC), histamine mediates, and the HIC antagonist N,N-diethyl-2-[4-(phenylmethyl)phenoxy]ethanamine. HCl (DPPE) inhibits, platelet aggregation and serotonin granule secretion; the latter response is dependent upon the same processes that mediate histamine release from mast cell granules. We now show that, as for platelet serotonin release, DPPE blocks concanavalin A-stimulated mast cell histamine release with a potency (IC50 = 30 microM) greater than the H1-antagonist, pyrilamine (IC50 = 150 microM) or the H2-antagonist cimetidine (IC50 = 5 mM), correlating with rank order of potency to inhibit 3H-histamine binding in rat brain membranes and liver microsomes. We postulate that histamine release from mast cells is mediated at HIC by second messenger intracellular histamine. However, unlike platelets, mast cells do not appear to rely on newly synthesized histamine. Rather, as for calcium, histamine may be mobilized from bound stores to mediate histamine secretion.

Lipoxygenase-induced lipid peroxidation of isolated cardiac microsomes modulates their calcium-transporting function.

We demonstrated previously that products of linoleic and arachidonic acids, arising from enzymatic or non-enzymatic oxidation, inhibit ATP-dependent calcium accumulation into and promote release of calcium from vesicles derived from sarcoplasmic reticulum of guinea-pig heart. In the present study, direct enzymatic peroxidation of cardiac membrane lipids was performed and the effect on calcium transport was examined. Vesicles were preincubated at 37 degrees C with soybean lipoxygenase-1 (linoleate:oxygen oxidoreductase, EC 1.13.11.12) for up to 1 h prior to the initiation of calcium accumulation. The extent of membrane peroxidation was assessed by monitoring the production of malondialdehyde. Pretreatment of vesicles with lipoxygenase for 40 and 60 min markedly depressed calcium accumulation. The lipoxygenase-induced suppression of calcium transport was completely antagonized by nordihydroguaiaretic acid (1 microM), not at all by indomethacin (1 microM), and only partially by 5,8,11,14-eicosatetraynoic acid (0.3 microM). Low concentrations of calcium (10(-5)-5 X 10(-5) M) enhanced, and a high concentration (10(-3) M) inhibited lipoxygenase-induced peroxidation of membrane lipids. The calcium-accumulating ability of the vesicles was inversely related to the extent of membrane peroxidation. The vesicles which showed the highest degree of peroxidation in the presence of 5 X 10(-5) M calcium, accumulated the lowest amount of calcium. In contrast, calcium at 10(-3) M suppressed lipid peroxidation, resulting in higher calcium uptake than in vesicles peroxidized in the absence of calcium. Thus, calcium transport is depressed in microsomes undergoing lipoxygenase-induced peroxidation, a process which in turn is modulated by calcium.