Distribution of oligodendrocyte loss and mitochondrial toxicity in the cuprizone-induced experimental demyelination model.

Cuprizone is a copper-chelating mitochondrial toxin that causes oligodendrocyte apoptosis and demyelination preferentially in the corpus callosum (CC) and the superior cerebellar peduncles, but not in the spinal cord (SC) of C57BL/6 mice. Here we aimed to determine the activities of copper-containing enzymes in correlation with the distribution of demyelination during exposure to cuprizone. The study revealed mitochondrial complex IV and superoxide dismutase activity alterations in both the pathology-affected CC and the non-affected SC. This observation raises the possibility that regionally different subcellular molecular interactions lead to the selective oligodendrocyte loss induced by the nonselective mitochondrial toxin, cuprizone.

Mitochondrial energetic and AKT status mediate metabolic effects and apoptosis of metformin in human leukemic cells.

Previous reports demonstrate that metformin, an anti-diabetic drug, can decrease the risk of cancer and inhibit cancer cell growth. However, its mechanism in cancer cells is still unknown. Metformin significantly blocks cell cycle and inhibits cell proliferation and colony formation of leukemic cells. However, the apoptotic response to metformin varies. Furthermore, daily treatment with metformin induces apoptosis and reduces tumor growth in vivo. While metformin induces early and transient activation of AMPK, inhibition of AMPKα1/2 does not abrogate anti-proliferative or pro-apoptotic effects of metformin. Metformin decreases electron transport chain complex I activity, oxygen consumption and mitochondrial ATP synthesis, while stimulating glycolysis for ATP and lactate production, pentose phosphate pathway for purine biosynthesis, fatty acid metabolism, as well as anaplerotic and mitochondrial gene expression. Importantly, leukemic cells with high basal AKT phosphorylation, glucose consumption or glycolysis exhibit a markedly reduced induction of the Pasteur effect in response to metformin and are resistant to metformin-induced apoptosis. Accordingly, glucose starvation or treatment with deoxyglucose or an AKT inhibitor induces sensitivity to metformin. Overall, metformin elicits reprogramming of intermediary metabolism leading to inhibition of cell proliferation in all leukemic cells and apoptosis only in leukemic cells responding to metformin with AKT phosphorylation and a strong Pasteur effect.

Reduced activity of AMP-activated protein kinase protects against genetic models of motor neuron disease.

A growing body of research indicates that amyotrophic lateral sclerosis (ALS) patients and mouse models of ALS exhibit metabolic dysfunction. A subpopulation of ALS patients possesses higher levels of resting energy expenditure and lower fat-free mass compared to healthy controls. Similarly, two mutant copper zinc superoxide dismutase 1 (mSOD1) mouse models of familial ALS possess a hypermetabolic phenotype. The pathophysiological relevance of the bioenergetic defects observed in ALS remains largely elusive. AMP-activated protein kinase (AMPK) is a key sensor of cellular energy status and thus might be activated in various models of ALS. Here, we report that AMPK activity is increased in spinal cord cultures expressing mSOD1, as well as in spinal cord lysates from mSOD1 mice. Reducing AMPK activity either pharmacologically or genetically prevents mSOD1-induced motor neuron death in vitro. To investigate the role of AMPK in vivo, we used Caenorhabditis elegans models of motor neuron disease. C. elegans engineered to express human mSOD1 (G85R) in neurons develops locomotor dysfunction and severe fecundity defects when compared to transgenic worms expressing human wild-type SOD1. Genetic reduction of aak-2, the ortholog of the AMPK α2 catalytic subunit in nematodes, improved locomotor behavior and fecundity in G85R animals. Similar observations were made with nematodes engineered to express mutant tat-activating regulatory (TAR) DNA-binding protein of 43 kDa molecular weight. Altogether, these data suggest that bioenergetic abnormalities are likely to be pathophysiologically relevant to motor neuron disease.

Manipulating thyroid status alters endoplasmic reticulum calcium homeostasis in rat cerebellum.

Thyroid-related hormones regulate the efficiency and expression of sarco-endoplasmic reticulum calcium ATPases in cardiac and skeletal muscle. However, little is known about the relationship between thyroid hormones and calcium (Ca2+) homeostasis in the brain. It is hypothesized that manipulating rat thyroid hormone levels would induce significant brain Ca2+ adaptations consistent with clinical findings. Adult male Sprague-Dawley rats were assigned to one of three treatment groups for 28 days: control, hypothyroid (6-n-propyl-2-thiouracil (PTU), an inhibitor of thyroxine (T4) synthesis), and hyperthyroid (T4). Throughout, rats were given weekly behavioral tests. Ca2+ accumulation decreased in the cerebellum in both hyper- and hypothyroid animals. This was specific to different ER pools of calcium with regional heterogeneity in the response to thyroid hormone manipulation. Behavioral tasks demonstrated sensitivity to thyroid manipulation, and corresponded to alterations in calcium homeostasis. Ca2+ accumulation heterogeneity in chronic hyper- and hypothyroid animals potentially explains clinical manifestations of altered thyroid status.

Reactivating HIF prolyl hydroxylases under hypoxia results in metabolic catastrophe and cell death.

Cells exposed to low-oxygen conditions (hypoxia) alter their metabolism to survive. This response, although vital during development and high-altitude survival, is now known to be a major factor in the selection of cells with a transformed metabolic phenotype during tumorigenesis. It is thought that hypoxia-selected cells have increased invasive capacity and resistance to both chemo- and radiotherapies, and therefore represent an attractive target for antitumor therapy. Hypoxia inducible factors (HIFs) are responsible for the majority of gene expression changes under hypoxia, and are themselves controlled by the oxygen-sensing HIF prolyl hydroxylases (PHDs). It was previously shown that mutations in succinate dehydrogenase lead to the inactivation PHDs under normoxic conditions, which can be overcome by treatment with alpha-ketoglutarate derivatives. Given that solid tumors contain large regions of hypoxia, the reactivation of PHDs in these conditions could induce metabolic catastrophe and therefore prove an effective antitumor therapy. In this report we demonstrate that derivatized alpha-ketoglutarate can be used as a strategy for maintaining PHD activity under hypoxia. By increasing intracellular alpha-ketoglutarate and activating PHDs we trigger PHD-dependent reversal of HIF1 activation, and PHD-dependent hypoxic cell death. We also show that derivatized alpha-ketoglutarate can permeate multiple layers of cells, reducing HIF1alpha levels and its target genes in vivo.

Succinate dehydrogenase and fumarate hydratase: linking mitochondrial dysfunction and cancer.

The phenomenon of enhanced glycolysis in tumours has been acknowledged for decades, but biochemical evidence to explain it is only just beginning to emerge. A significant hint as to the triggers and advantages of enhanced glycolysis in tumours was supplied by the recent discovery that succinate dehydrogenase (SDH) and fumarate hydratase (FH) are tumour suppressors and which associated, for the first time, mitochondrial enzymes and their dysfunction with tumorigenesis. Further steps forward showed that the substrates of SDH and FH, succinate and fumarate, respectively, can mediate a 'metabolic signalling' pathway. Succinate or fumarate, which accumulate in mitochondria owing to the inactivation of SDH or FH, leak out to the cytosol, where they inhibit a family of prolyl hydroxylase enzymes (PHDs). Depending on the PHD inhibited, two newly recognized pathways that support tumour maintenance may ensue: affected cells become resistant to certain apoptotic signals and/or activate a pseudohypoxic response that enhances glycolysis and is conveyed by hypoxia-inducible factor.

Mitochondrial activity in Pompe's disease.

Mitochondrial oxidative metabolism was examined in two infants with Pompe's disease. The clinical diagnosis was confirmed by the demonstration of intralysosomal glycogen accumulation and a deficiency of acid alpha-D-glucosidase in muscle biopsies. Light and electron microscopy studies demonstrated a normal number of mitochondria with normal ultrastructure. Spectrophotometric measurements revealed that the specific activities of citrate synthase and the partial reactions of electron transport were markedly elevated in the skeletal muscle homogenates prepared from both infants with Pompe's disease when calculated as micromoles per minute per gram wet weight of tissue. However, when respiratory chain enzyme activities were expressed relative to citrate synthase as a marker mitochondrial enzyme, a different pattern emerged, in which all Pompe muscle respiratory enzymes, except complex IV, were decreased relative to control subjects. These observations demonstrate that caution should be exercised when analyzing and interpreting data obtained from tissue homogenates in general and, in particular, in those prepared from tissues in which the wet weight of tissue may be altered, for example, by pathologic accumulation of carbohydrate or lipid.

Cathepsin G and thrombin: evidence for two different platelet receptors.

Neutrophil cathepsin G and thrombin, the only platelet agonists that are proteases, exhibit a mandatory requirement for catalytic activity to induce platelet aggregation and signal transduction. The thrombin receptor is a G-protein-coupled receptor which undergoes proteolysis to generate a tethered ligand that causes self-activation. Since cathepsin G strongly resembles thrombin in its ability to activate platelets, we have attempted to determine whether cathepsin G and thrombin function through the same or different receptors. Evidence that thrombin and cathepsin G act at different receptors was as follows: (a) an antibody directed against the thrombin receptor blocked thrombin-induced but not cathepsin G-induced platelet responses; (b) human fibroblasts responded to thrombin and to a synthetic thrombin receptor peptide (comprising residues 42-55 of the thrombin receptor) by exhibiting an elevation in cytosolic Ca2+ concentration but did not respond to cathepsin G; and (c) platelets pretreated with neutrophil elastase failed to respond to thrombin but responded when rechallenged by cathepsin G. Thrombin and cathepsin G exhibit heterologous desensitization that is potentiated by okadaic acid and is attenuated by staurosporine, indicating that phosphorylation of serine/threonine residues is important for desensitization and that protein kinase C may be involved. Since catalytic activity of cathepsin G is required for platelet stimulation, it is probable that platelet activation by cathepsin G requires receptor proteolysis and that a tethered ligand mechanism is involved, suggesting that platelets may possess a family of protease receptors.

Neutrophil-platelet interactions in inflammation.

Inflammation is a multicomponent system that involves a network of cellular crosstalk and control. Many different cell types, including neutrophils and platelets, participate as both sources and targets of biological mediators that are generated or released in acute and chronic inflammatory states. Owing to the complex nature of inflammation, the magnitude as well as the spatial and temporal characteristics of the responses are likely to vary with the type, concentration, and duration of the inflammatory stimulus. Despite the potential variations in responses to diverse stimuli, a feature common to and responsible for the major characteristics of inflammation (heat, pain, redness, swelling) is proteases. In the early stages of inflammation, the neutrophil is the predominant cell to infiltrate the tissue, and the extent of inflammatory injury has been shown to be directly dependent on the extent of neutrophil infiltration. Since both cathepsin G and elastase are neutral serine proteases present in large amounts in azurophilic granules and are known to affect platelet function, it is thus likely that these neutrophil enzymes are important contributing factors to inflammatory reactions in general and to neutrophil-platelet interactions specifically.

Cathepsin g activates platelets in the presence of plasma and stimulates phosphatidic Acid formation and lysosomal enzyme release.

We have previously demonstrated that cathepsin G is a strong platelet agonist. However, the ability of cathepsin G to function in this capacity in vivo has remained speculative because the enzyme might be expected to be rapidly neutralized by the high concentration of circulating plasma antiproteases. To examine the physiological significance of cathepsin G as a paracrine mediator, indo-1 and (14)C-5-hydroxytryptamine-loaded platelets were incubated with autologous unloaded neutrophils specifically activated by addition of fMet-Leu-Phe. FMet-Leu-Phe induced substantial increases in cytosolic calcium and 5-hydroxytryptamine release even in the presence of increasing amounts of citrated plasma, indicating that cathepsin G can stimulate platelets under conditions similar to those that may be encountered in vivo. Platelet stimulation was abolished by addition of α1-antichymotrypsin, demonstrating that cathepsin G was the neutrophil mediator responsible for cell activation. Having obtained evidence that cathepsin G can function in the presence of plasma, we measured its ability to hydrolyze phosphatidylinositol 4,5-bisphosphate (PtdIns4,5-P2) and generate phosphatidic acid (PtdA) in aspirin-treated platelets. Our previous observations suggested that cathepsin G stimulates phospholipase C since the protease induces an elevation in [Ca(2+)]i in the presence of exogenous EGTA. Within 10 s of stimulation cathepsin G induced a transient loss in [(32)P]-PtdIns4,5-P2 and a concurrent increase in [(32)P]-PtdA. [(32)P]-PtdA formation was increased over 15-fold in a concentration-dependent manner by cathepsin G. We also determined that cathepsin G induces the release of the lysosomal enzyme ß-N-acetyl-glucosaminidase. Both the increase in PtdA and the release of ß-hexoseaminidase were comparable to responses elicited by thrombin. These results provide additional evidence that cathepsin G is a strong platelet agonist, support the conclusion that cathepsin G stimulates phospholipase C, and clearly suggest that cathepsin G can function as an agonist in vivo.

Cytosolic calcium as a second messenger for collagen-induced platelet responses.

We showed previously that direct platelet activation by collagen involves an increase in the platelet cytosolic free Ca2+ concentration ([Ca2+]i) but that this increase is not required for the adhesion of platelets to collagen. We now report that collagen-induced arachidonic acid liberation, myosin phosphorylation and 5-hydroxytryptamine secretion are dependent on increases in [Ca2+]i, as they were markedly inhibited in platelets loaded with the acetoxymethyl ester of the Ca2+ chelator BAPTA but not in cells loaded with the acetoxymethyl ester of the non-chelating diazo-3. BAPTA also partially inhibited the rate of collagen-induced phosphatidic acid (PtdA) formation but had little effect on increases in phosphorylation of pleckstrin (47 kDa protein; P47). From these results we infer that collagen-induced increases in [Ca2+]i are required for dense granule secretion and arachidonic acid liberation, but are not necessary for stimulation of the protein kinase C pathway.

Neutrophil elastase potentiates cathepsin G-induced platelet activation.

We have previously demonstrated that human neutrophil cathepsin G is a strong platelet agonist that binds to a specific receptor. This work describes the effect of neutrophil elastase on cathepsin G-induced platelet responses. While platelets were not activated by high concentrations of neutrophil elastase by itself, elastase enhanced aggregation, secretion and calcium mobilization induced by low concentrations of cathepsin G. Platelet aggregation and secretion were potentiated in a concentration-dependent manner by neutrophil elastase with maximal responses observable at 200 nM. Enhancement was observed when elastase was preincubated with platelets for time intervals of 10-60 s prior to addition of a low concentration of cathepsin G and required catalytically-active elastase since phenylmethanesulphonyl fluoride-inhibited enzyme failed to potentiate cell activation. Neutrophil elastase potentiation of platelet responses induced by low concentrations of cathepsin G was markedly inhibited by creatine phosphate/creatine phosphokinase and/or indomethacin, indicating that the synergism between elastase and cathepsin G required the participation of ADP and thromboxane A2. On the other hand, platelet responses were not attenuated by the PAF antagonist BN 52021, signifying that PAF-acether did not play a role in elastase potentiation. At higher concentrations porcine pancreatic elastase exhibits similar effects to neutrophil elastase, demonstrating that the effect of elastase was not unique to the neutrophil protease. While neutrophil elastase failed to alter the ability of cathepsin G to hydrolyze a synthetic chromogenic substrate, preincubation of platelets with elastase increased the apparent affinity of cathepsin G binding to platelets.(ABSTRACT TRUNCATED AT 250 WORDS)

Cyclic AMP does not inhibit collagen-induced platelet signal transduction.

The adhesion of platelets to collagen and their activation is the primary event in haemostasis. Following adhesion, platelet aggregation mediated by ADP, thromboxane A2 and thrombin leads to the formation of a platelet plug. It is known that platelet activation by each of these agonists involves an increase in the cytosolic free Ca2+ concentration, and this has been thought to be controlled by cyclic AMP. However, we report here that while signal transduction induced by ADP plus a thromboxane mimetic (U46619), or by thrombin, is inhibited by stimulators of adenylate cyclase such as a prostaglandin I2 (PGI2) analogue (Iloprost), PGD2 and forskolin, elevation of cyclic AMP does not inhibit either platelet adhesion to collagen or the associated Ca2+ mobilization, phosphatidic acid formation or 5-hydroxytryptamine secretion. Furthermore, collagen did not lower elevated levels of cyclic AMP in platelets measured in the presence of both a thromboxane antagonist and an ADP-removing system. The present results are discussed in the context of previous findings.

Prostaglandin-concentration-dependent desensitization of adenylate cyclase in human erythroleukaemia (HEL) cells is abolished by pertussis toxin and enhanced by induction by dimethyl sulphoxide.

Prostaglandin-regulated cyclic AMP metabolism in human erythroleukaemia (HEL) cells was similar to that previously described in platelets [Ashby (1989) Mol. Pharmacol. 36, 866-873], displaying prostaglandin-concentration-dependent desensitization that could be explained by the presence of separate stimulatory and inhibitory prostaglandin receptors. Pertussis toxin abolished prostaglandin-concentration-dependent desensitization, indicating that the process is mediated through a pertussis toxin-sensitive GTP-binding protein. Treatment of HEL cells for 4 days with the inducer dimethyl sulphoxide enhanced prostaglandin-concentration-dependent desensitization, but did not alter the initial rate of cyclic AMP synthesis or the amount of Gi2 alpha measured by immunoblotting, suggesting that the inhibitory receptor was selectively induced by changing the cells to a more platelet-like form.

Facile platelet adhesion to collagen requires metabolic energy and actin polymerization and evokes intracellular free calcium mobilization.

The attachment of platelets to collagen-coated microtiter plates at 20 degrees C was inhibited strongly by depletion of metabolic energy or by addition of cytochalasins and was slightly inhibited by the intracellular Ca2+ chelator BAPTA. In keeping with their respective potencies as inhibitors of actin polymerization, cytochalasins D and H were the most potent inhibitors of adhesion, while cytochalasin B was the least potent. Energy depletion, cytochalasin D or, to a much lesser extent, BAPTA also inhibited platelet adhesion to collagen in a suspension assay system at 37 degrees C. Collagen-induced platelet cytosolic Ca2+ mobilization was inhibited up to 70% by cytochalasin D and abolished by energy depletion or BAPTA. Elevation of intracellular platelet calcium by treatment with ionomycin had little effect on platelet adhesion to collagen. We propose that rapid platelet spreading along collagen fibers is both energy- and actin-dependent and necessary to produce maximal adhesion needed to elicit Ca2+ mobilization required for subsequent responses.

Cathepsin G binding to human platelets. Evidence for a specific receptor.

We have shown previously that purified human neutrophil cathepsin G is a strong platelet agonist. We now demonstrate that cathepsin G exhibits saturable, reversible binding to human platelets which is characteristic of binding to a specific receptor. At room temperature, cathepsin G displayed apparent positive co-operativity of binding, as indicated by sigmoidal binding curves and a Hill coefficient greater than unity. By contrast, binding curves conducted with native enzyme at 0.5 degrees C displayed a much smaller degree of sigmoidicity, and binding studies performed with phenylmethanesulphonyl fluoride-treated enzyme at 22-25 degrees C exhibited hyperbolic binding curves. The concentrations of cathepsin G required to give half-saturation (S0.5) with inhibitor-treated enzyme or with native enzyme at either room temperature or 0.5 degrees C were all similar, suggesting that sigmoidal binding curves did not result from an alteration in the affinity of the binding sites for cathepsin G. However, platelets bound approximately twice as many molecules of native enzyme as molecules of phenylmethanesulphonyl fluoride-treated cathepsin G per cell. From these observations it can be inferred that the apparent positive co-operativity may in part reflect the exposure of binding sites due to the proteolytic activity of cathepsin G. However, this conclusion is not supported by experiments conducted with subsaturating cathepsin G concentrations, which demonstrated that ligand binding did not show an expected increase at longer time intervals. Measurement of Ca2+ mobilization and cathepsin G binding in the same platelet suspensions demonstrated that elevations in cytosolic free Ca2+ concentration had achieved near-maximal levels in the presence of 15 micrograms of cathepsin G/ml, whereas maximal binding was observed at approx. 35 micrograms/ml, indicating that only a fraction of the total binding sites need be occupied to elicit platelet activation. Pretreatment of platelets with forskolin or phorbol 12-myristate 13-acetate (PMA) decreased cathepsin G binding by approx. 60% and 40% respectively, indicating that the receptor may be desensitized or down-regulated by phosphorylation due to protein kinases. Since forskolin and PMA could diminish receptor availability by activating negative feedback mechanisms, inhibition of negative signal-transduction pathways could conversely play a role in the up-regulation of cathepsin G binding. In any event, these results show that cathepsin G is an agonist that must bind to platelets to initiate processes associated with cell activation, and suggest a role for cathepsin G in platelet function.

Platelet-activating factor-induced calcium mobilization in human platelets and neutrophils: effects of PAF-acether antagonists.

Since one of the first measurable events that occurs as a consequence of receptor-mediated cell activation is an increase in the cytosolic free calcium concentration, the calcium-selective fluorescent indicator fura-2 was employed to monitor increases in cytosolic calcium following PAF-acether stimulation of human neutrophils and platelets. In neutrophils, approximately 70% of the increase in cytosolic calcium was attributed to release from an intracellular source and 30% could be attributed to enhanced influx through the plasma membrane. In platelets, only 30% was released from an intracellular pool and the remainder reflected enhanced influx of calcium. In both cell types, the intracellular source of calcium was a non-mitochondrial, vesicular compartment, probably endoplasmic reticulum. The ability of different compounds to antagonize the PAF-acether-induced increase in cytosolic calcium was investigated using quin2 and fura-2 as calcium indicators. In decreasing order of potency, the following PAF-acether antagonists inhibited the change in platelet cytosolic free calcium elicited by 10 nM PAF-acether: L-652,731, kadsurenone, triazolam, diltiazem and alprazolam. L-652,731, kadsurenone, triazolam and diltiazem were also tested in neutrophils stimulated by 10 nM PAF-acether. While the antagonists were 7-20 times less active in neutrophils as compared to platelets, they all inhibited the rise in free calcium with the same order of potency in both cell types. Each of the antagonists was PAF-acether-specific, inhibited both the rate and magnitude of calcium mobilization and appeared to exhibit competitive antagonism. These data demonstrate that calcium mobilization can provide a rapid, sensitive and quantitative method by which to evaluate agonists such as PAF-acether and PAF-acether antagonists such as kadsurenone in different cell types.

Cathepsin G is a strong platelet agonist released by neutrophils.

The present studies were undertaken to characterize a serine protease released by N-formyl-L-Met-L-Leu-L-Phe (fMet-Leu-Phe)-stimulated neutrophils that rapidly induces platelet calcium mobilization, secretion and aggregation. The biological activity associated with this protease was unaffected by leupeptin, was only weakly diminished by N-p-tosyl-L-Lys-chloromethane, but was strongly inhibited by alpha 1-antitrypsin, soyabean trypsin inhibitor, N-tosyl-L-Phe-chloromethane and benzoyloxycarbonyl-Gly-Leu-Phe-chloromethane (Z-Gly-Leu-PheCH2Cl). These observations indicated that the biological activity of neutrophil supernatants could be attributed to a chymotrypsin-like enzyme such as cathepsin G. Furthermore, platelet aggregation and 5-hydroxytryptamine release induced by cell-free supernatants from fMet-Leu-Phe-stimulated neutrophils were found to be blocked by antiserum to cathepsin G in a concentration-dependent manner but were unaffected by antiserum to elastase. The biological activity present in neutrophil supernatants co-purified with enzymic activity for cathepsin G during sequential Aprotinin-Sepharose affinity chromatography and carboxymethyl-Sephadex chromatography. SDS/polyacrylamide-gel electrophoresis of the reduced, purified protein, demonstrated three polypeptides with apparent Mr values of 31,500, 29,000 and 28,000 and four polypeptides were resolved on acid-gel electrophoresis. Purified cathepsin G from neutrophils cross-reacted with anti-(cathepsin G) serum in a double immunodiffusion assay and elicited platelet calcium mobilization, 5-hydroxytryptamine secretion and aggregation. Calcium mobilization and secretion induced by low concentrations of cathepsin G were partially dependent on arachidonic acid metabolites and ADP, while stimulation by higher enzyme concentrations was independent of amplification pathways, indicating that cathepsin G is a strong platelet agonist. These results suggest that pathological processes which stimulate neutrophils and release cathepsin G can in turn result in the recruitment and activation of platelets.

Respiration capacity of mitochondria isolated from unfertilized and fertilized sea urchin eggs.

Mitochondria were isolated from unfertilized and fertilized eggs of the sea urchin, Strongylocentrotus purpuratus. Both preparations exhibited coupled adenosine 5'-diphosphate (ADP)-dependent) oxidation of flavin and pyridine-linked substrates and both yielded the expected P:O ratios with these substrates. Highest respiratory control indices (greater than 4.0) were observed when succinate or pyruvate + malate were used as substrates. Mitochondria from unfertilized and fertilized eggs exhibited sensitivity to respiratory and phosphorylation inhibitors and uncouplers and both preparations exhibited cross-over points at sites I, II and III of the respiratory chain. Low-temperature difference spectra revealed a normal complement of cytochromes c, b and aa3, although cytochrome c from unfertilized eggs appears to be more subject to extraction during the course of mitochondrial isolation than does cytochrome c from fertilized eggs. An unidentified pigment absorbing at approx. 570 nm was visible in low-temperature spectra of unfertilized eggs and unfertilized egg mitochondria.

Direct evidence for the existence of a neutrophil-derived platelet activator (neutrophilin).

Human neutrophils and platelets were loaded with the intracellular calcium indicator fura-2. The chemotactic peptide N-formyl-Met-Leu-Phe (fMet-Leu-Phe) induced a rapid elevation of cytosolic free calcium in cytochalasin B-treated neutrophils but failed to increase the cytosolic calcium in platelets. On the other hand, when unloaded neutrophils were incubated together with autologous fura-2-loaded platelets, fMet-Leu-Phe stimulated a 6-fold increase in platelet cytosolic calcium subsequent to a brief lag. Parallel experiments demonstrated that the addition of fMet-Leu-Phe to neutrophil/platelet incubates also elicited platelet aggregation and serotonin release. Platelet activation showed a positive correlation with the concentration of fMet-Leu-Phe added to the mixed cell population. Cell-free supernatants prepared from fMet-Leu-Phe-stimulated neutrophils were capable of inducing platelet calcium mobilization, aggregation, and secretion. The amount of platelet-activating material present in the supernatant was proportional to the number of activated neutrophils. Preincubation of platelets with BN 52021, acetylsalicylic acid, SQ-29,548, or hirudin did not modify the aggregation response induced by the supernatant collected from fMet-Leu-Phe-activated neutrophils, suggesting that the material was not 1-alkyl-2-acetyl-sn-glycero-3-phosphocholine (paf-acether), arachidonic acid, thromboxane A2, or thrombin. Pretreatment of the neutrophil supernatant with an ADP (creatine phosphate/creatine phosphokinase) or a superoxide/peroxide (superoxide dismutase/catalase) scavenging system also had no effect on aggregation or secretion, indicating that these substances did not participate in platelet activation. The biological activity present in the neutrophil supernatant was destroyed by heat and inactivated by treatment with phenylmethylsulfonyl fluoride, indicating that it is a protein and most probably an enzyme with serine protease activity. These data provide the direct observation of secondary signal transmission to platelets following primary activation of neutrophils. We propose the name neutrophilin for the neutrophil-derived mediator.