Beta amyloid fragments derived from activated platelets deposit in cerebrovascular endothelium: usage of a novel blood brain barrier endothelial cell model system.

Amyloid precursor protein (A betaPP) processing results in generation of amyloid beta peptide (A beta) which deposits in the brain parenchyma and cerebrovasculature of patients with Alzheimer's disease (AD). Evidence that the vascular deposits derive in part from A betaPP fragments originating from activated platelets includes findings that individuals who have had multiple small strokes have a higher prevalence of AD compared to individuals who have taken anti-platelet drugs. Thus, determination of whether platelet A betaPP fragments are capable of traversing the blood-brain barrier (BBB) is critical. We have established that activated platelets from patients with AD retain more surface transmembrane-bound A betaPP (mA betaPP) than control platelets. We report here that this mA betaPP can be cleaved to A beta-containing fragments which pass through a novel BBB model system. This model utilizes human BBB endothelial cells (BEC) isolated from brains of patients with AD. These BEC, after exposure to activated platelets which have been surface-labeled with fluorescein and express surface-retained mA betaPP, cleave fluorescein-tagged surface proteins, including mA betaPP, resulting in passage to the BEC layer The data confirm that BEC contribute to processing of platelet-derived mA betaPP and show that the processing yields A beta containing fragments which could potentially contribute to cerebrovascular A beta deposition.

Human neutrophil-mediated nonoxidative antifungal activity against Cryptococcus neoformans.

It has long been appreciated that polymorphonuclear leukocytes (PMN) kill Cryptococcus neoformans, at least in part via generation of fungicidal oxidants. The aim of this study was to examine the contribution of nonoxidative mechanisms to the inhibition and killing of C. neoformans. Treatment of human PMN with inhibitors and scavengers of respiratory burst oxidants only partially reversed anticryptococcal activity, suggesting that both oxidative and nonoxidative mechanisms were operative. To define the mediators of nonoxidative anticryptococcal activity, PMN were fractionated into cytoplasmic, primary (azurophil) granule, and secondary (specific) granule fractions. Incubation of C. neoformans with these fractions for 18 h resulted in percent inhibition of growth of 67.4 +/- 3.4, 84.6 +/- 4.4, and 29.2 +/- 10.5 (mean +/- standard error, n = 3), respectively. Anticryptococcal activity of the cytoplasmic fraction was abrogated by zinc and depletion of calprotectin. Antifungal activity of the primary granules was significantly reduced by pronase treatment, boiling, high ionic strength, and magnesium but not calcium. Fractionation of the primary granules by reverse phase high-pressure liquid chromatography on a C(4) column over an acetonitrile gradient revealed multiple peaks with anticryptococcal activity. Of these, peaks 1 and 6 had substantial fungistatic and fungicidal activity. Peak 1 was identified by acid-urea polyacrylamide gel electrophoresis (PAGE) and mass spectroscopy as human neutrophil proteins (defensins) 1 to 3. Analysis of peak 6 by sodium dodecyl sulfate-PAGE revealed multiple bands. Thus, human PMN have nonoxidative anticryptococcal activity residing principally in their cytoplasmic and primary granule fractions. Calprotectin mediates the cytoplasmic activity, whereas multiple proteins, including defensins, are responsible for activity of the primary granules.

Platelets and DAMI megakaryocytes possess beta-secretase-like activity.

We report here the discovery of two novel human platelet and megakaryocytic DAMI cell enzymes that have beta-secretase-like activity. These activities could potentially effect cleavage of the amyloid precursor protein (APP) at the beta-amyloid peptide N-terminus, by an EC 3.4.24.15-like metalloprotease, and the N terminus-1 position, by a serine protease. Thus both enzymes may generate the amyloidogenic beta-peptide. Studies of intact and Triton X-100-lysed DAMI cells, as well as intact versus subcellular fractions of platelets, demonstrate the presence of these proteolytic activities. The resting platelet has (1) a surface serine protease, demonstrated by its ability to cleave a beta-secretase substrate and by its inhibitor sensitivity; and (2) a metalloprotease, recognized by an antibody to EC 3.4.24.15, which resides intracellularly in the alpha-granule membrane, is translocated to the surface on activation, and shows beta-secretase-like activity by cleaving the same substrate. This metalloprotease can also cleave recombinant APP to a potentially amyloidogenic fragment. Surface metalloprotease was identified in DAMI cells by flow cytometry and Western blotting with a specific anti-EC 3.4.24.15 monoclonal antibody, while activity was identified by using two beta-secretase substrates. This article is the first to document two previously unknown endoproteinases with beta-secretase-like activity in platelets and DAMI cells. These proteases are capable of effecting cleavage of APP and could therefore contribute to Abeta deposition in the cerebrovasculature.

Cryptococcus neoformans resides in an acidic phagolysosome of human macrophages.

Recently, we demonstrated that human monocyte-derived macrophages (MDM) treated with chloroquine or ammonium chloride had markedly increased antifungal activity against the AIDS-related pathogen Cryptococcus neoformans. Both of these agents raise the lysosomal pH, which suggested that the increased antifungal activity was a function of alkalinizing the phagolysosome. Moreover, there was an inverse correlation between growth of C. neoformans in cell-free media and pH. These data suggested that C. neoformans was well adapted to survive within acidic compartments. To test this hypothesis, we performed studies to determine the pH of human MDM and neutrophil phagosomes containing C. neoformans. Fungi were labeled with the isothiocyanate derivatives of two pH-sensitive probes: fluorescein and 2',7'-difluorofluorescein (Oregon Green). These probes have pKas of 6.4 and 4.7, respectively, allowing sensitive pH detection over a broad range. The phagosomal pH averaged approximately 5 after ingestion of either live or heat-killed fungi and remained relatively constant over time, which suggested that C. neoformans does not actively regulate the pH of its phagosome. The addition of 10 and 100 microM chloroquine resulted in increases in the phagosomal pH from a baseline of 5.1 up to 6.5 and 7.3, respectively. Finally, by immunofluorescence, colocalization of C. neoformans and the MDM lysosomal membrane protein LAMP-1 was demonstrated, establishing that fusion of C. neoformans-laden phagosomes with lysosomal compartments takes place. Thus, unlike many other intracellular pathogens, C. neoformans does not avoid fusion with macrophage lysosomal compartments but rather resides and survives in an acidic phagolysosome.

Blood brain barrier endothelial cells express candidate amyloid precursor protein-cleaving secretases.

Proteolytic cleavage of the amyloid precursor protein (A beta PP) results in the generation of the amyloidogenic fragment known as amyloid beta peptide (A beta). Deposition of A beta in the brain parenchyma and cerebrovasculature is a feature of Alzheimer's disease (AD). To date, the process whereby A beta is generated and deposited remains unclear. We have previously established that activated platelets from AD patients retain more A beta PP on their surface than control platelets. We report here that an endothelial cell-derived enzyme can cleave this surface platelet A beta PP. Human blood brain barrier endothelial cells from brains of AD patients were assayed for potential A beta PP-cleaving enzymes using synthetic peptide substrates encompassing the A beta N-terminus cleavage site. A protease activity capable of cleaving A beta PP on the surface of AD platelets was noted. The A beta PP cleavage is partially inhibited by EDTA, by ZincOV, as well as by a specific inhibitor of the Zn metalloprotease E.C.3.4.24.15. Furthermore, the protease is recognized by an antibody directed against it, using immunohistochemistry, Western blot analysis and flow cytometry. The protease is not secreted, but rather resides intracellularly as well as on the surface of the endothelial cells. The data suggest that E.C.3.4.24.15 synthesized by brain endothelial cells may process the platelet-derived A beta PP, yielding fragments which could contribute to cerebrovascular A beta deposits.

Brain endothelial cell enzymes cleave platelet-retained amyloid precursor protein.

We have previously demonstrated that thrombin-activated platelets from patients with advanced Alzheimer's disease (AD) retain significantly more surface membrane-bound amyloid precursor protein (mAPP) than platelets from non-demented age-matched individuals (AM). We have studied interactions between these platelets and the cerebrovascular endothelium to which activated platelets adhere in a model system, investigating their involvement in the formation of amyloid beta peptide (Abeta) deposits in AD patients. We report here that there appear to be alpha and beta secretase-like activities in primary human blood brain barrier endothelial cell (BEC) cultures from both AD patients and AM control subjects (AD-BEC and AM-BEC, respectively) as well as a gamma secretase-like activity that appears only in AD-BEC. No such activities were observed in human umbilical vein endothelial cells (HUVECs). Furthermore, there is more penetration of the platelet-released products platelet factor 4 and soluble APP through the BEC layer grown from AD patients than that grown from AM individuals, whereas none penetrate through a HUVEC layer. Thus the interaction between platelets, the APP they have retained or released, and cerebral vascular endothelial cells may be at least partially responsible for amyloidogenic deposits around the cerebral vasculature of AD patients.

Neutrophil degranulation and phospholipase D activation are enhanced if the Na+/H+ antiport is blocked.

Neutrophils phagocytize high-valency immune complexes (HIC) by an Fc receptor-mediated mechanism. Engaging Fc receptors in this manner induces PMN to generate superoxide and release the contents of both their specific and azurophilic granules. Signaling events that precede and accompany PMN secretion include activation of phospholipase D (PLD), as well as changes in cytoplasmic [Ca2+] (delta[Ca2+]in) and pH (delta pHin). Although the role of PLD and delta[Ca2+]in in mediating Fc receptor-mediated PMN secretion has been studied, whether pHin plays a regulatory role has not yet been defined. HIC-stimulated PMN undergo an intracellular acidification followed by a prolonged Na+/H+ antiport-mediated alkalinization. To investigate the role of the pH transient in controlling degranulation, the Na+/H+ antiport was inhibited either with 100 microM dimethylamiloride (DMA) or by substituting N-methyl-glucamine for extracellular sodium. Blocking the antiport with DMA led to hyperacidified PMN, which exhibited an increase in degranulation, but did not affect generation of superoxide. DMA did not alter the ability of neutrophils to phagocytose and oxidize dichlorodihydrofluoresceinated HIC, suggesting the increase in degranulation was not the result of failed phagocytosis. Investigation into whether the observed increase in degranulation when the antiport was blocked was mediated by PLD or delta[Ca2+]in revealed that blocking the antiport increased HIC-induced PLD activity but had no effect on HIC-induced delta[Ca2+]in. Blocking the Na+/H+ antiport by ion substitution caused similar effects on PMN signaling and secretion as was seen with DMA. These results indicate that Na+/H+ antiport activity is not necessary for degranulation or superoxide release in HIC-stimulated PMN and that hyperacidification of the cytoplasm can modulate degranulation. Therefore, pHin, via its effect on PLD, may be a control point of degranulation and may represent one way that neutrophils achieve differential control of their antibacterial products.

Human platelets damage Aspergillus fumigatus hyphae and may supplement killing by neutrophils.

Neutropenia is considered a significant risk factor for invasive aspergillosis but is almost always associated with concurrent thrombocytopenia. Studies determined that platelets, like neutrophils, attached to cell walls of the invasive hyphal form of Aspergillus fumigatus. Organisms were damaged as shown by loss of cell wall integrity in scanning laser confocal microscopy and release of defined hyphal surface glycoproteins. Rapid expression appearance of surface antigen CD63 and release of markers of platelet degranulation confirmed activation during attachment to hyphae. Optimal platelet activation required opsonization of hyphae with fresh or heat-inactivated whole plasma. These effects of opsonization with whole plasma could not be duplicated by pooled human serum, immunoglobulin G, or fibrinogen, whether used separately or combined. Thus, platelets in the presence of whole plasma have the potential to play an important role in normal host defenses against invasive aspergillosis.

Differential responses of human mononuclear phagocytes to mycobacterial lipoarabinomannans: role of CD14 and the mannose receptor.

CD14 is a signaling receptor for both gram-negative bacterial lipopolysaccharide (LPS) and mycobacterial lipoarabinomannan (LAM) that lacks terminal mannosyl units (AraLAM). In contrast, terminally mannosylated LAM (ManLAM) binds the macrophage mannose receptor (MMRc), although the ability of the MMRc to serve as a signaling receptor has not been previously reported. We compared the abilities of AraLAM and ManLAM to induce distinct responses in two monocytic cell populations, freshly isolated human peripheral blood monocytes (PBM) and monocyte-derived macrophages (MDM). The responses examined were chemotaxis and transient changes in free cytosolic calcium ([Ca2+]in). We found that AraLAM but not ManLAM was chemotactic for both PBM and MDM. Migration of these cells in vitro to AraLAM was specifically blocked by an anti-CD14 monoclonal antibody, suggesting that CD14 mediates the chemotactic response to AraLAM. Subsequently, we found that AraLAM induced a transient rise in [Ca2+]in levels within a subpopulation of PBM but not MDM. This response was blocked by anti-CD14 antibodies. In contrast, ManLAM induced a transient rise in [Ca2+]in levels within a subpopulation of MDM but not PBM. This response was blocked by either anti-CD14 or anti-MMRc antibodies. These data suggest that the MMRc can serve as a signaling receptor and that coligation of both CD14 and the MMRc is required to elicit a specific response. Thus, one response to LAM (chemotaxis) can be elicited solely by engaging CD14, whereas a different response (changes in [Ca2+]in levels) depends on both the differentiation state of the cells and concomitant engagement of CD14 and the MMRc.

A cytosolic calcium transient is not necessary for degranulation or oxidative burst in immune complex-stimulated neutrophils.

Receptor-mediated activation of neutrophils (PMN) initiates possibly interdependent events, including a rapid transient increase in [Ca2+]i, implicated as a second messenger. To investigate whether this transient is required for eventual degranulation, PMN were incubated with an intracellular Ca2+ chelator (BAPTA), then exposed to chemotactic peptide [N-formyl-methionyl-leucyl-phenylalanine (fMLP)l with or without cytochalasin B (CB) or to high-valency immune complexes (HIC); delta[Ca2+]i, delta(pH)i, oxidative burst, and elastase release were then evaluated (plus or minus EGTA 15 s before stimulation) after 2 and 15 min incubation in 0.9 mM Ca2+. With either fMLP plus CB or HIC stimulation, BAPTA-treated cells were unable to achieve a Ca2+ transient with a 2-min incubation, whereas a 15-min incubation allowed the BAPTA-treated cells to recover a portion of the delta[Ca2+]i. Even though BAPTA-treated cells were unable to mount a delta[Ca2+]i at 2 min, HIC-stimulated BAPTA-treated cells were able to elicit an oxidative burst (33% of control) and degranulation (67% of control). Therefore, we conclude that delta[Ca2+]i modulates but is not required for oxidative burst or degranulation.

Stimulus responses and amyloid precursor protein processing in DAMI megakaryocytes.

Platelets, when released as anuclear cells by their precursor megakaryocytes, already carry soluble proteolytic fragments of the amyloid precursor protein (APP) within their alpha-granules and intact APP in the alpha-granule membranes. In response to activation signals elicited by physiologic stimuli such as thrombin, platelets release their granules' soluble contents and translocate granule membrane-bound proteins to the plasma membrane. Because platelets carry >90% of the circulation's APP, activated platelets have been implicated as origins of the beta-amyloid peptide fragment of APP (A beta), whose deposition in the cerebrovasculature is characteristic of Alzheimer's disease. We have therefore studied the APP contents and proteolytic processing in resting DAMI human megakaryocytic cells, along with the consequences of the activation of these cells by thrombin, comparing the results in each case to those with human platelets. Resting and PMA-differentiated DAMI cell contents were examined by Western blotting, immunoprecipitation, or metabolic labeling with sulfur 35-labeled methionine during culture, while plasma membrane-bound APP was evaluated by flow cytometry. Activation was followed by changes in cytoplasmic calcium concentration ((Ca++)in) and in membrane potential. Like platelets, DAMI cells exhibited a thrombin dose-dependent delta(Ca++)in, and membrane potential change; in contrast to the surface of a platelet, the surface of an agranular resting DAMI cell expresses granule-membrane proteins (APP and CD63) that appear on platelets only after activation. DAMI cell culture with 35S-labeled methionine confirmed that megakaryocytes synthesize large amounts of APP, of slightly higher molecular weight, and degrade their APP extensively before platelets are formed.

Phospholipase D mediates Fc gamma receptor activation of neutrophils and provides specificity between high-valency immune complexes and fMLP signaling pathways.

Neutrophils phagocytize high-valency immune complexes (HIC) by an Fc gamma receptor-mediated mechanism, activating an oxidative burst and initiating degranulation. In contrast, neutrophils exhibit chemotaxis to N-formylated peptides [e.g., N-formyl-methionyl-leucyl-phenylalanine (fMLP)] and secrete far fewer oxidants or granule contents than neutrophils activated by HIC. However, if neutrophils are treated with cytochalasin B (CB) or permeabilized with streptolysin O, chemoattractant-induced neutrophil secretion is increased to a level beyond that observed in response to HIC. Because priming neutrophils with CB, or permeabilizing them, also augments activation of phospholipase D (PLD) in response to fMLP, we reasoned that, in intact (i.e., nonpermeabilized) unprimed neutrophils, PLD may participate in a signaling pathway specific to phagocytic stimuli such as HIC and hence may contribute to degranulation control. PLD activity in response to HIC and fMLP correlated closely with stimulus-induced azurophilic degranulation under a wide variety of experimental conditions, including compounds that abrogated or augmented stimulus-induced PLD action. PLD activation preceded, and appeared to be necessary for, azurophilic degranulation. These results suggest that PLD may play a central role in controlling azurophilic degranulation and provide signaling specificity between pathways activated by fMLP and HIC in intact neutrophils.

Moderate and advanced Alzheimer's patients exhibit platelet activation differences.

We previously reported that platelets from advanced sporadic Alzheimer's disease (AD) patients exhibit two defects: first, an aberrant signal transduction presenting as a thrombin-induced hyperacidification, which is more severe for donors with the apolipoprotein E4 allele (apoE4), and second, an AD-specific Amyloid Precursor Protein (APP) processing defect that presents as retention of APP on the activated platelets' surface and in independent of the apo E allele. This retention of membrane APP correlates with decreased release of soluble APP. To determine at what stage in the disease progression these defects appear, we performed signal transduction and secretion studies on moderate AD patients. Thrombin-activated platelets from these patients do not exhibit either hyperacidification or APP retention; their APP processing and secretion are normal by Western blotting, suggesting that the two platelet defects appear in the advanced stages of AD.

Activated Alzheimer disease platelets retain more beta amyloid precursor protein.

Upon activation, platelet alpha-granules' soluble contents are secreted and membrane-bound contents are translocated to the plasma membrane. Membrane-bound proteins include the beta-amyloid precursor protein (APP) from which the beta-amyloid (A beta) deposits found surrounding the cerebrovasculature of patients with Alzheimer's Disease (AD) may originate. We show here that activated platelets from AD patients exhibit less APP processing, retain more of the protein on their surface, and secrete less as soluble fragments than do controls. Surface labeling demonstrated that there is little APP or CD62 on the surface of resting platelets. Upon activation, control platelets exhibited more of both proteins on their surface, while advanced AD patients exhibited similar amounts of CD62 as controls, but retained significantly more surface APP. AD platelets secreted similar amounts of most soluble alpha-granule contents as controls, but less APP fragments. Together these results suggest a processing defect that may account for greater deposition of A beta-containing products in the vasculature to which activated platelets adhere.

Adherence-dependent calcium signaling in monocytes: induction of a CD14-high phenotype, stimulus-responsive subpopulation.

Isolation of monocytes by plastic adherence alters cell morphology and function. In order to study the effects of cell isolation procedures and subsequent culture on monocyte function, we examined cytoplasmic calcium concentration changes (delta[Ca2+]in) in human monocytes isolated by either negative (magnetic bead) or positive (plastic adherence) selection then stimulated with formyl-Met-Leu-Phe (fMLP), either immediately after isolation, or after 48 h in culture. We have previously shown that fresh adherence-isolated monocytes respond to fMLP with small delta[Ca2+]in and oxidative burst responses, exhibiting larger responses following 48 h of incubation. We now demonstrate that fresh monocytes, prevented from adhering by negative selection, exhibit an even smaller fMLP-induced delta[Ca2+]in, which does not increase during 48 h in culture if cells are kept nonadherent, in Teflon. Calcium responses of adherent, fresh monocytes do not increase if cells are subsequently placed into suspension and maintained nonadherent, but increase if nonadherent cells are permitted to adhere to plastic. Furthermore, augmented fMLP-[Ca2+]in and oxidative burst responses in plastic-adherent cells are restricted to a CD14-high phenotype subpopulation. The CD14-high phenotype also describes a subpopulation of cells that responds to CD4 crosslinking with a rapid delta[Ca2+]in. Induction of a subpopulation of CD14-high expressing cells by adherence may explain in part maturation-induced response changes observed in macrophage but not in monocyte in vitro systems.

Neutrophil functional responses depend on immune complex valency.

Ligand-induced cross-linking of Fc gamma receptors (Fc gamma R) on neutrophils plays a significant role in their stimulation, shown here by contrasting the responses induced by low valency immune complexes (LICs) and high valency immune complexes (HICs) and by cross-linking LICs in situ (L/Ab) after their addition to the cells. Multiparameter flow cytometry was used to measure immune complex (IC)-elicited changes in cytoplasmic Ca2+ concentration and initiation of the oxidative burst simultaneously in the same cell and to correlate these with Fc gamma R occupancy. We have previously shown that subpopulations of neutrophils respond maximally to subsaturating concentrations of HIC; saturating dosages stimulate the entire population. This discrepancy was not due to differences in receptor occupancy. The magnitude of the transient Ca2+ increase was independent of the dose of HIC but depended on the dose when an LIC was used. As shown here, L/Ab cross-linking elicited Ca2+ responses similar to those observed in HIC-stimulated cells. In contrast, LIC elicited only minimal intracellular delta pH and no oxidative burst or membrane potential changes at all unless Fc gamma R was cross-linked, accomplished by HIC or by L/Ab. However, azurophilic degranulation, as determined by elastase release, was not observed in cells stimulated by the in situ cross-linking method, whereas the HIC preparation triggered azurophilic degranulation. Thus, some Fc gamma R-mediated neutrophil effector functions such as azurophilic degranulation and oxidative burst initiation have an absolute requirement for Fc gamma R cross-linking, whereas signaling functions such as changes in membrane potential, intracellular pH, and intracellular Ca2+ concentration can occur, albeit more slowly and to a lesser extent, if single Fc gamma R are occupied.

Role of the Fc gamma R subclasses Fc gamma RII and Fc gamma RIII in the activation of human neutrophils by low and high valency immune complexes.

Two Fc gamma receptor (Fc gamma R) subclasses on human neutrophils, Fc gamma RII and Fc gamma RIII, activate different cellular functions. To examine the involvement of each receptor subtype in polymorphonuclear leukocyte activation, Fab and F(ab')2 fragments of subclass-specific monoclonal antibodies ([mAbs] mAb IV.3 against Fc gamma RII and mAb 3G8 against Fc gamma RIII, respectively) were used to block the binding of low valency immune complexes (LICs) and high valency immune complexes (HICs). Flow cytometry then permitted the simultaneous quantitation of antibody and ligand binding, the elicited intracellular Ca2+ concentration (delta[Ca2+]int), initiation of the oxidative burst, and/or the phospholipase A activation in the same cell. We have previously demonstrated that subsaturating dosages of HIC bind uniformly to all the cells but elicit an "all-or-none" (i.e., dose independent) maximal delta[Ca2+]int in a dose-dependent subpopulation of the cells. In contrast, both the proportion of cells responding and the magnitude of the delta[Ca2+]int transient depend on the subsaturating dose of LIC, even though it too binds uniformly to all the cells, nonresponding as well as responding. These earlier findings have here been extended by single cell flow cytometric analysis to demonstrate that F(ab')2 Fc gamma RIII is the major Fc gamma R involved in HIC binding (and [Ca2+]int mobilization), as well as in oxidative burst and phospholipase A activation. In contrast, both receptor subclasses must be available for LIC-elicited delta[Ca2+]int, as blockage by either of the mAb Fab or F(ab')2 fragments abrogates this response, even though LIC binding to the receptors is not decreased. Furthermore, LIC elicited little oxidative burst activity and failed to activate phospholipase A but cross-linking to achieve multivalency, previously shown to induce [Ca2+]int and oxidative burst responses, elicited phospholipase A activity via Fc gamma RIII. Fc gamma RII's role appears to be modulation of the small, late Ca2+ influx observed at > 1 min, whereas Fc gamma RIII modulates all the earlier larger events. Thus, simultaneous observation of receptor identity, receptor occupancy, and consequent activation parameters in the same cell by flow cytometry permits use to demonstrate that Fc gamma RII is necessary for the small signal transduction elicited by LIC; it plays a relatively small role in polymorphonuclear leukocyte stimulation by HIC. Fc gamma RIII is the main receptor responsible for immune complex-elicited polymorphonuclear leukocyte responses; its efficacy is greatly enhanced when the receptors are cross-linked, either by preequilibrated multivalent complexes or by in situ cross-linking of bound LIC with excess antibody.

Expression of integrin and organization of F-actin in epithelial cells depends on the underlying surface.

PURPOSE: To evaluate the role of ionic interactions in the cell surface expression of integrins and the organization of F-actin. Understanding these interactions will allow the development of surfaces for prosthetic purposes that will promote the normal expression of adhesion proteins. METHODS: Hema (hydroxyethylmethacrylate) hydrogels were used to mimic the charges present on extracellular matrix proteins. The surfaces were modified by the addition of amines (N,N-dimethylaminoethylmethacrylate; NDAM) or carboxyl moieties (methacrylic acid). The effects of ionic interactions on cellular spreading and on the expression of proteins were examined by modification of the stoichiometrically defined amounts of positive and negative charges on the Hemas. Changes in intracellular pH and the distribution and localization of protein were monitored using fluorescent markers, spectrofluorometry, and confocal laser scanning microscopy, respectively. The immunohistochemical studies were confirmed by flow cytometric analysis. RESULTS: The data indicate that although cells adhered to all the surfaces, the number of cells possessing adhesion receptors is significantly greater on surfaces with amine functionalities. Cell seeding and plating efficiency after 2 hours were identical on all surfaces. The intracellular pH of epithelial cells grown on surfaces containing NDAM, a tertiary amine, was higher than that of cells grown on Hemas containing only methacrylic acid. Lamellipodial extensions and an extensive actin network were present on surfaces containing 5% NDAM. The alpha 6 subunit was localized along the lateral cell membranes. The alpha 2 and 3 subunits were present along cell membranes and at lamellipodial extensions. Cells cultured on surfaces containing only methacrylic acid did not spread. Actin filaments were not detected, and alpha 6 was negligible on these surfaces. CONCLUSIONS: This is a novel approach to understanding cell-substrate interactions, and one that allows quantitative evaluation of the response of cells to defined surfaces. The organization of F-actin is altered by the substrates containing only carboxyl moieties. The distribution of integrin subunits is also altered by the substrate. These results indicate that epithelial cell spreading and protein expression may be regulated by ionic interactions.

Chemotactic peptide-induced cytoplasmic pH changes in incubated human monocytes.

Stimulation of phagocytic leukocytes with chemotactic factors results in transient acidification, followed by alkalinization of the cytosol. Human monocytes are known to alter their functional responses to the chemotactic peptide N-formylmethionyl-leucyl-phenylalanine (fMLP) in a complex fashion as they mature in vitro to macrophages. To examine the evolution of the cytoplasmic pH (pHi) response of monocytes to fMLP as they mature into macrophages, we incubated cells for 0, 24, 48, and 96 h (Medium-199 + 10% fetal bovine serum; 37 degrees C) and examined pHi using the fluorescent probe 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF; 1 microM) and a Perkin-Elmer 650/10 spectrofluorimeter (lambda em = 530 nm, lambda ex = 500, 450 nm) as previously described. The resting pHi of fresh (0 h) monocytes was 7.07 +/- 0.16 (SD) and was unchanged after incubation for 24, 48, or 96 h (7.09, 7.11, 7.05, respectively). Cells exhibited an fMLP dose-dependent cytoplasmic acidification, with maximal delta pHi occurring 30-60 s after exposure to 10(-7) M fMLP. The response to fMLP did not change with the duration of incubation and, as with neutrophils, cytoplasmic realkalinization was blocked by dimethylamiloride (20 microM). Incubation with 2-deoxyglucose (10 min, 5 mM), sufficient to inhibit by more than 90% the formyl peptide-stimulated superoxide generation by monocytes, slowed fMLP-induced acidification and abrogated the alkalinization. In addition, monocytes isolated from the blood of a patient with X-linked chronic granulomatous disease (CGD) underwent fMLP-induced acidification that was unmasked further by coincubation with dimethylamiloride, in a manner quantitatively similar to that of normal monocytes, despite the inability of the CGD cells to produce superoxide. The chemotactic factor-induced cytoplasmic pH responses of monocytes/macrophages remained constant as the cells matured in vitro and exhibited a dimethylamiloride-independent acidification and dependent alkalinization, as did the response in neutrophils. The cytoplasmic acidification of these cells thus did not correlate with the cells' production of superoxide and with the concomitant hexose monophosphate shunt activation, as has been suggested for other leukocyte types.

Role of the plasma membrane in signal transduction in human polymorphonuclear leukocytes.

To more closely examine the role of the cell surface in transmembrane signal transduction in human neutrophils, sealed right-side-out membrane vesicles free of organellar membrane components were used as models of the plasma membrane. These vesicles, incubated with a fluorescent analogue of the chemotactic peptide fMLP, bound this ligand similarly in extent and kinetics to intact neutrophils. Vesicles responded to this stimulation with a slow increase in internal [Ca++] which was inhibited by EGTA but not by verapamil; the cytosolic Ca++ transient seen in intact cells within 10 sec of stimulation was absent in vesicles. The vesicles also maintained a transmembrane potential (psi) and were depolarized by the K+ ionophore valinomycin. However, unlike intact cells which hyperpolarized and then depolarized in response to fMLP, the vesicles demonstrated only a sustained hyperpolarization. Vesicles also differed from intact cells by not producing superoxide (O2-) in response to fMLP. Finally, fMLP caused dramatic alterations in membrane vesicle lipid metabolism: at early time points (within 5-10 sec), there was a transient production of diacylglycerol (DAG) concomitant with inositol lipid breakdown, with no apparent hydrolysis of non-inositol phospholipids. For up to 5 min after stimulation, there was no increase in the levels of phosphatidic acid or of inositol lipids. Thus, a significant portion of the signalling pathway in neutrophils is located at the cell surface or in the plasma membrane and functions independently of intracellular components. Furthermore, the plasma membrane is intimately involved in events occurring during both the early (DAG generation) and late (slow, prolonged rise in [Ca++]) phases of cellular response. In contrast, several of the responses to fMLP (the Ca++ transient, depolarization, generation of O2-, recycling of lipid metabolites) involve signalling machinery not constitutively resident on the neutrophil surface.