Tumor-promoting phorbol esters induce rapid internalization of the C3b receptor via a cytoskeleton-dependent mechanism

Plasma membrane expression as well as phagocytic capability of the C3b receptor (CR1) are under regulatory control. Phorbol esters are one class of agents which have been shown to influence both of these events. In this study, by using radiolabeled Fab fragments of a monoclonal anti-CR1 antibody to tag the receptor and acid elution of surface-bound Fab, we showed that both phorbol myristate acetate and phorbol dibutyrate induced internalization of the C3b receptor; this occurred in a dose- and time-dependent manner in the absence of occupancy of the receptor by ligand. This was shown to occur in neutrophils, monocytes, and macrophages. We also showed that phorbol esters enhanced CR1-dependent phagocytosis despite the presence of two-thirds fewer receptors present on the plasma membrane. However, fibronectin, another agent that influences phagocytosis, had no effect on receptor internalization. Phorbol ester internalization was temperature-dependent and was inhibitable by cytochalasins B and D. Inhibition of internalization was reversible when cytochalasin B was removed. Phorbol esters also induced increased detergent insolubility of CR1 with kinetics similar to those of receptor internalization. It is possible that association of CR1 with the cytoskeleton is important to the process of "activation" of CR1 in phagocytosis.     

Sodium fluoride reveals multiple pathways for regulation of surface expression of the C3b/C4b receptor (CR1) on human polymorphonuclear leukocytes

We have examined the effects of NaF on C3b receptor (CR1) expression and function in human polymorphonuclear leukocytes (PMN). Plasma membrane expression of CR1 was determined with a monoclonal antibody (3D9); CR1 function was assessed with erythrocytes bearing C3b (EC3b) or C3b oligomers prepared with avidin and biotin. NaF inhibited in a dose-dependent manner CR1-mediated phagocytosis and NaF inhibited f-met-leu-phe or phorbol dibutyrate-induced increases in CR1 expression, with 50% inhibition at 5 mM NaF. Increased plasma membrane expression of CR3 induced by f-met-leu-phe also was inhibited by NaF. However, increased CR1 and CR3 expression due to incubation at 37 degrees C were unaffected by 10 mM NaF. Incubation of PMN with 10 mM NaF depleted 80% of intracellular adenosine triphosphate (ATP) after 10 min. However, inhibition of CR1 function was unrelated to ATP level, inasmuch as normal increases in CR1 expression and in phagocytosis occurred 20 min after removal of NaF, whereas ATP levels remained below 25% of normal. Strikingly, internalization of soluble oligomeric C3b ligands was unaffected by 10 mM NaF, which completely inhibited phorbol dibutyrate-induced CR1 internalization and EC3b phagocytosis. We conclude that there are two different mechanisms for increasing plasma membrane expression of CR1, one of which is inhibitable by NaF. Moreover, there are two distinct pathways of CR1 internalization which can also be distinguished by their sensitivity to NaF.     

Intracellular degradation of the complement C3b/C4b receptor in the absence of ligand

Human neutrophils (PMN) respond to various soluble stimuli by translocating intracellular complement C3b/C4b receptors (CR1) to the cell surface. Ligand-independent internalization of surface CR1 has been demonstrated previously, but the fate of total cellular CR1 during PMN stimulation has not been determined. In order to study the fate of CR1 during neutrophil activation, we have employed a unique approach for the quantitative analysis of intracellular antigens which allows simultaneous measurement of total cellular and surface membrane antigen pools. Stimulation of isolated PMN with N-formyl-Met-Leu-Phe or ionomycin resulted in a mean 7-fold increase in surface CR1 expression within 15 min. Total cellular CR1 decreased by as much as 45% within 15 min, with loss continuing for up to 1 h. Inclusion of NH4Cl during PMN stimulation inhibited the loss of total CR1 without affecting surface CR1 expression. Addition of phenylmethylsulfonyl fluoride inhibited loss of total CR1 and enhanced the stimulus-induced increases in surface CR1. These data suggest that intracellular degradation of CR1 occurs during stimulation of PMN and may involve proteolysis in an acidic intracellular compartment. Since our experiments were done with isolated PMN in the absence of serum and complement components, this degradation occurred in the absence of C3b, the ligand for CR1. To our knowledge, ligand-independent degradation of a cell surface receptor has not been previously detected.     

Differential interaction of the C3b/C4b receptor and MHC class I with the cytoskeleton of human neutrophils

As measured by fluorescence microscopy and radioligand binding, C3b/C4b receptors (CR1) became attached to the detergent-insoluble cytoskeleton of human neutrophils when receptors were cross-linked by affinity-purified polyclonal F(ab')2 anti-CR1, dimeric C3b, or Fab monoclonal anti-CR1 followed by F(ab')2 goat anti-mouse F(ab')2. CR1 on neutrophils bearing monovalent anti-CR1 was not attached to the cytoskeleton. In contrast, cross-linked CR1 on erythrocytes and cross-linked MHC Class I on neutrophils were not cytoskeleton associated. A possible role for filamentous actin (F-actin) in the binding of cross-linked CR1 to neutrophil cytoskeleton was suggested by three observations. When neutrophils were differentially extracted with either Low Salt-detergent buffer or High Salt-detergent buffer, stained with FITC-phalloidin, and examined by fluorescent flow cytometry, the residual cytoskeletons generated with the former buffer were shown to contain polymerized F-actin, whereas cytoskeletons generated with the latter buffer were found to be depleted of F-actin. In parallel experiments, High Salt-detergent buffer was also found to release cross-linked CR1 from neutrophils. Second, depolymerization of F-actin by DNAse I released half of the cytoskeletal-associated cross-linked CR1. Third, immunoadsorbed neutrophil CR1, but not MHC Class I or erythrocyte CR1, specifically bound soluble 125I-actin. In addition, Fc receptor and CR3, other phagocytic membrane proteins of neutrophils, specifically bound 125I-actin. These data demonstrate that CR1 cross-linked on neutrophils becomes associated with detergent-insoluble cytoskeleton and that this interaction is mediated either directly or indirectly by actin.     

The complement-mediated binding of soluble antibody/dsDNA immune complexes to human neutrophils

The complement-mediated binding of soluble antibody/3H-dsDNA immune complexes (prepared in vitro) to human polymorphonuclear leukocytes (PMN) has been investigated quantitatively. Studies with isolated complement components in conjunction with experiments on the binding of these complexes to human red blood cells suggest that the binding to both cell types is mediated predominantly by CR1 (C4b-C3b) receptors but that CR3 (iC3b or C3d-g) receptors may play a role in binding to PMN but probably not to RBC. Our results also indicate that under the standard conditions of these assays (37 degrees C, 20 to 40 min incubations) there is no significant internalization of the soluble antibody/dsDNA immune complexes after they are bound by the PMN.     

Evidence for distinct intracellular pools of receptors for C3b and C3bi in human neutrophils

In this report, the modulation and localization of complement receptors CR1 and CR3 in neutrophils were examined with the use of monoclonal antibodies (mab) directed against these membrane proteins. We first studied complement receptor modulation in a patient with neutrophil-specific granule deficiency. With flow cytometric analysis, we determined that, while N-formyl-methionyl-leucyl-phenylalanine (f-met-leu-phe) (10(-6) M) caused an increase in the binding of both anti-CR1 and anti-CR3 mab to normal neutrophils, the fmet-leu-phe-stimulated neutrophils from our patient increased anti-CR1 binding but decreased anti-CR3 binding. This suggested that CR3, but not CR1, might be associated with specific granules. We next studied receptor modulation in organelle-depleted neutrophil cytoplasts obtained from normal donors. Unlike the specific granule-deficient neutrophils, the normal cytoplasts failed to augment expression of either receptor after stimulation. Immunofluorescence studies of permeabilized polymorphonuclear leukocytes (PMN) revealed considerable internal binding of both anti-CR1 and anti-CR3. In additional studies, phorbol myristate acetate (PMA) was used as a stimulus for receptor modulation in normal neutrophils. Unlike fmet-leu-phe and C5a, PMA elicited a biphasic dose-response curve. High doses of PMA (greater than 0.5 ng/ml) caused a reduction in the magnitude of membrane expression of both CR1 and CR3. In studies designed to localize the internal pool of receptors, we evaluated the binding of 125I-anti-receptor mab to plasma membrane-, specific granule, and azurophilic granule-enriched fractions obtained from sucrose gradient fractionation of disrupted neutrophils. 125I-anti-CR1 mab bound to the membrane-enriched fraction but bound little to either granule-enriched fraction. In contrast, 125I-anti-CR3 mab bound more to the specific granule-enriched fraction than to the plasma membrane-enriched fraction. Azurophilic granules showed no increased anti-CR3 binding. Immunoprecipitation of radiolabeled solubilized subcellular fractions with anti-receptor mab confirmed these findings. CR3 was present in the plasma membrane-, and specific granule-enriched fraction but not in the azurophilic granule-enriched fraction. CR1, however, was present only in the plasma membrane-enriched fraction. These data indicate that there are intracellular pools for both the CR1 and CR3, but the intracellular locations for these pools are distinct. The pool for CR3 co-sediments with specific granules, while the pool for CR1 does not. Nonetheless, a variety of stimulatory agents increase and decrease the membrane expression of both receptors in parallel.     

Caveolin internalization by heat shock or hyperosmotic shock

We investigated the cellular localization of caveolin, a landmark protein of caveolae, by indirect immunofluorescence after heat shock or hyperosmotic shock. Caveolin was internalized to the perinucleus by heat shock (43 degrees C) and relocalized in the plasma membrane after recovery of NIH3T3 cells at 37 degrees C for 4 h. The caveolin internalization was also observed after cells were exposed to hyperosmotic shock. Caveolin disappeared from detergent-insoluble complexes in the heat-shocked cells, but alkaline phosphatase was still there, suggesting that their responses to heat shock are quite different even though both of them were enriched in detergent-insoluble complexes of normal cells. Caveolin was internalized by the actin depolymerizer cytochalasin D, but not by the tubulin depolymerizer nocodazole. In addition, cellular exposure to hydrogen peroxide caused caveolin internalization along with disintegrated microfilaments and intact microtubules. Since cellular exposure to heat shock showed disintegrated microfilaments but intact microtubules, caveolin internalization might be due to depolymerized microfilaments. When cells were exposed to heat shock and allowed to recover for 4 h, actin depolymerization and caveolin internalization were not induced by a second heat shock, suggesting that some heat shock protein(s) might prevent actin depolymerization and caveolin internalization.     

Regulation of proteolytic activity of complement factor I by pH: C3b/C4b receptor (CR1) and membrane cofactor protein (MCP) have different pH optima for factor I-mediated cleavage of C3b

C3b/C4b receptor (CR1) and membrane cofactor protein (MCP) are integral membrane glycoproteins with factor I-dependent cofactor activity. They bind to C3b, allowing factor I to cleave C3b at two sites (first and second cleavage), which results in the generation of C3bi, a hemolytically inactive form which is a ligand for complement receptor type three (CR3). C3bi is further degraded by factor I and CR1 (third cleavage) to C3dg (a ligand for complement receptor type two, CR2) and C3c. Using two different substrates, fluid-phase C3b and cell-bound C3b, the cleavage of C3b by MCP and factor I was compared to that by CR1 and factor I under various conditions. The optimal pH for the first and second cleavage of either substrate was 6.0 for MCP and 7.5 for CR1. The third cleavage was mediated only by CR1 and factor I, the optimal pH being 8.0. Low ionic conditions enhanced the C3b binding and cofactor activity of both CR1 and MCP. The efficiency of binding C3b to CR1 or MCP was maximal at pH 6.2. The isoelectric point (pI) of MCP was acidic (approximately 4.0), while that of CR1 was 6.8. Therefore, compared to CR1, MCP possesses distinct functional profiles relative to C3b-binding and factor I-cofactor activity.     

Interaction of human monomeric C3b with its receptor (complement receptor type 1, CR1) on neutrophils. Evidence for negative cooperativity

The binding of highly purified monomeric 125I-C3b to its receptor (CR1) on resting human polymorphonuclear neutrophils (PMN) was analyzed under equilibrium conditions, at 4 degrees C and low ionic strength. Scatchard analysis of specific binding data yielded curvilinear concave upward plots, which resulted from the presence of site-site interactions of the negative type among PMN C3b-receptors (negative cooperativity), as shown by dissociation kinetic experiments. Indeed, the dissociation rate of 125I-C3b from PMN was markedly increased in the presence of an excess of unlabeled C3b in the dilution medium and was directly dependent on the degree of initial receptor occupancy with the radioligand. These interactions occurred when 2% of the receptors were occupied with 125I-C3b and resulted in a 4-fold decrease in CR1 affinity when the receptor went from its "empty" to its "filled" conformation. In a disease associated with a continuous production of C3b (factor I deficiency), CR1 on in vivo circulating PMN was found to be in a "low affinity" and "high dissociating" state similar to that of normal CR1 at high occupancy. Finally, negative cooperativity among CR1 sites disappeared after PMN activation with chemotactic peptides.     

Activation of the C3b receptor: effect of diacylglycerols and calcium mobilization

The plasma membrane expression and the phagocytic function of the C3b receptor (CR1) on human neutrophils (PMN) are under the control of cellular regulatory mechanisms, and phorbol esters are one class of agents that modulate both membrane expression and function. Phorbol esters also activate protein kinase C; however, the physiologic activation of protein kinase C is thought to be mediated by diacylglycerol. Diacylglycerols are generated during phosphatidyl inositol turnover, which is associated with a rise in intracellular calcium due to another product of polyphosphoinositide metabolism, inositol trisphosphate. We therefore studied the effects of synthetic diacylglycerols and calcium mobilization on CR1 function. In our experiments, treatment of neutrophils with two synthetic diacylglycerols, 1-oleoyl-2-acetoyl-sn-3-glycerol (OAG) and sn-1,2-dioctanoylglycerol, like phorbol esters, induced ligand-independent internalization of CR1. In contrast, the addition of exogenous phospholipase C had no effect on receptor internalization over the time course studied. OAG treatment also enabled neutrophils to specifically phagocytose via CR1. Calcium mobilization with the calcium ionophore A23187 (1 microM) had a synergistic effect on phorbol ester-induced internalization of CR1, but abrogated the phorbol ester enhancement of CR1-dependent phagocytosis. Both trimethoxybenzoate, the intracellular calcium antagonist, and chlorpromazine inhibited phorbol ester-induced internalization of CR1, whereas chelation of extracellular calcium did not. We conclude that activation of protein kinase C modulates the expression and function of CR1, and that calcium mobilization also influences these processes. We speculate that polyphosphoinositide turnover may be involved in the physiologic regulation of CR1.     

CR3 (Mac-1, alpha M beta 2, CD11b/CD18) and Fc gamma RIII cooperate in generation of a neutrophil respiratory burst: requirement for Fc gamma RIII and tyrosine phosphorylation

Cooperation among plasma membrane receptors in activating signal transduction cascades is not well understood. For almost 20 years, it has been clear that when a particulate foreign body is opsonized with complement as well as IgG, the efficiency of IgG effector functions is markedly enhanced. However, the molecular mechanisms involved in cooperation between IgG Fc receptors and complement receptors have not been elucidated. In this work, we show that when human neutrophils (PMN) are plated on a surface coated with both anti-CR3 and anti-Fc gamma RIII antibodies, the respiratory burst which occurs is equivalent to that stimulated by anti-Fc gamma RII. The CR3 ligand iC3b is as effective as anti-CR3 for cooperating with anti-Fc gamma RIII in generation of a respiratory burst. The synergy between CR3 and Fc gamma RIII for activating the NADPH oxidase is abolished by Fab of anti-Fc gamma RII. Nonetheless, the observed synergy is not an artifact of unintended Fc gamma RII ligation, since (a) only this combination of antibodies works to generate H2O2; (b) coating plates with either of the antibodies alone cannot activate the respiratory burst at any dose; (c) LAD (CR3 deficient) cells, which are perfectly competent to mount a respiratory burst when Fc gamma RII is engaged, are incapable of activating the respiratory burst when adherent to wells coated with anti-Fc gamma RIII and anti-CR3; (d) direct engagement of Fc gamma RII activates the respiratory burst by a pathway pharmacologically distinguishable from the synergistic respiratory burst. Fc gamma RIII/CR3 synergy is abolished by cytochalasin B and herbimicin, suggesting that both the actin cytoskeleton and tyrosine phosphorylation are necessary for activation of the synergistic respiratory burst. Further analysis shows that CR3 and Fc gamma RIII have distinct roles in activation of this Fc gamma RII-dependent assembly of the NADPH oxidase. Ligation of CR3 is sufficient to lead to Fc gamma RII association with the actin cytoskeleton on the adherent PMN surface. Coligation of Fc gamma RIII is required for tyrosine phosphorylation of Fc gamma RII. These data are consistent with a model in which phosphorylation of Fc gamma RII or a closely associated substrate initiates activation of a signal transduction pathway leading to oxidase assembly. These are the first data to demonstrate a molecular mechanism for synergy between IgG Fc and complement receptors in activation of phagocyte effector functions.     

Granulocyte-macrophage colony-stimulating factor increases synthesis and expression of CR1 and CR3 by human peripheral blood neutrophils

Polymorphonuclear leukocytes (PMN) constitutively synthesize various plasma membrane proteins including CR1(3) (CD35), CR3 (or Mac-1) alpha-chain (CD11b) and MHC class I. PMN are also able to up-regulate rapidly the expression of CR1 and CR3 to the plasma membrane in response to agonists such as FMLP. To determine whether constitutive PMN translation was static or up-regulatable, PMN were cultured in the presence or absence of the cytokine granulocyte-macrophage colony-stimulating factor (GM-CSF) for 8 h. CR1, CR3 and class I proteins immunoprecipitated from lysates of 35S-methionine pulse-labeled PMN were resolved by SDS-PAGE, fluorographed and quantified by densitometry. GM-CSF-treated PMN synthesized 4.5-fold more class I protein, 3.7-fold more CR1, 2.4-fold more CD11b and 3.4-fold more CR3 beta-chain (CD18), compared with untreated control cells. Actinomycin D treatment of replicate samples of PMN decreased the amount of these proteins synthesized by each group of PMN from 30 to 90%, implying that continued translation was required for the increases in protein synthesis. Nascent CR and class I proteins were inserted into the plasma membrane of PMN, thereby supplementing the molecules already expressed on the cell surface. In addition to these longer term effects of GM-CSF, we observed its acute up-regulatory effects on PMN. GM-CSF induced a five- to 12-fold increase in the expression of CR1 and CR3 on the PMN cell surface within 30 min. These increases were both dose- and time-dependent with maximum up-regulation occurring at 25 pM and at 30 min. In contrast to the long term biosynthetic events, this rapid up-regulation was not dependent on protein synthesis but was due instead to mobilization of CR from intracellular compartments similar to those up-regulated by FMLP. These results demonstrate that PMN can respond to microenvironmental stimuli such as GM-CSF both by rapidly up-regulating and increasing translation and expression of functionally important plasma membrane proteins.     

NPA binding activity is peripheral to the plasma membrane and is associated with the cytoskeleton

N-1-Naphthylphthalamic acid (NPA) binding activity is released into the supernatant when plasma membranes are subjected to high-salt treatment, indicating that this activity is peripherally associated with the membrane. Extraction of plasma membrane vesicles with Triton X-100 resulted in retention of NPA binding activity in the detergent-insoluble cytoskeletal pellet. Treatment of this pellet with KI released NPA binding activity, actin, and alpha-tubulin. Dialysis to remove KI led to the repolymerization of cytoskeletal elements and movement of NPA binding activity into an insoluble cytoskeletal pellet. NPA binding activity partitioned into the detergent-insoluble cytoskeletal pellet obtained from both zucchini and maize membranes and was released from these pellets by KI treatment. Treatment of a cytoskeletal pellet with cytochalasin B doubled NPA binding activity in the resulting supernatant. Together, these experiments indicate that NPA binding activity is peripherally associated with the plasma membrane and interacts with the cytoskeleton in vitro.     

Mutations of the type A domain of complement factor B that promote high-affinity C3b-binding

Factor B is a zymogen that carries the catalytic site of the complement alternative pathway convertases. During C3 convertase assembly, factor B associates with C3b and is cleaved at a single site by factor D. The Ba fragment is released, leaving the active complex, C3bBb. During the course of this process, the protease domain becomes activated. The type A domain of factor B, also part of Bb, is similar in structure to the type A domain of the complement receptor and integrin, CR3. Previously, mutations in the factor B type A domain were described that impair C3b-binding. This report describes "gain of function" mutations obtained by substituting factor B type A domain amino acids with homologous ones derived from the type A domain of CR3. Replacement of the betaA-alpha1 Mg2+ binding loop residue D254 with smaller amino acids, especially glycine, increased hemolytic activity and C3bBb stability. The removal of the oligosaccharide at position 260, near the Mg2+ binding cleft, when combined with the D254G substitution, resulted in increased affinity for C3b and iC3b, a C3b derivative. These findings offer strong evidence for the direct involvement of the type A domain in C3b binding, and are suggestive that steric effects of the D254 sidechain and the N260-linked oligosaccharide may contribute to the regulation of ligand binding.     

Interaction of iC3b with recombinant isotypic and chimeric forms of CR2.

CR2 is a component of a signal transduction complex on B lymphocytes that augments B cell responses to Ag. We have quantitatively assessed binding by the two isotypic forms of CR2 for two of its ligands, the polymerized iC3b (p(iC3b)) fragment of C3, and gp350/220, the EBV membrane protein. The recombinant 15-SCR or 16-SCR forms of CR2 bound p(iC3b) with identical affinities. Full binding activity of CR2 for p(iC3b) was observed with a chimera comprised of SCR-1 and -2 of CR2 fused to SCR-17 through -30 of CR1. Therefore, the alternatively spliced SCR-10a has no role in binding p(iC3b), and the binding activity of wild type receptor for iC3b can be reconstituted with SCR-1 and -2 of CR2. The binding affinities of the two isoforms of CR2 for soluble gp350/220 were also similar. Additional sites in the C3c region of C3 have been postulated also to interact with CR2. However, monomeric iC3b and C3d were equally effective in inhibiting the binding of p(iC3b) to CR2, indicating that the C3c region of iC3b does not contribute to the interaction of iC3b with CR2. Finally, the relative abilities of C3b and iC3b to bind to CR1 and CR2 were compared. The conversion of C3b to iC3b generated a ligand with an approximate 100-fold decrease in affinity for CR1 and a 10-fold increased affinity for CR2, resulting in a 1000-fold greater likelihood for binding to the latter receptor that may then promote B cell activation.     

Interferon-gamma-dependent modulation of C3b receptors (CR1) on human peripheral blood monocytes

Cell surface expression of the C3b receptor (CR1) was transiently down regulated on purified human monocytes exposed to purified recombinant human interferon-gamma(rIFN-gamma). Receptors were quantitated by using CR1-specific monoclonal antibody by radioimmunoassay or flow cytometry and by rosette analysis with the use of C3b-coated bovine erythrocytes. The reduction of CR1 was dependent on the dose of IFN-gamma used and the time of cellular exposure. Down-regulation was transient, with maximum loss occurring after 2 to 3 days of stimulation with IFN-gamma. However, after 6 days CR1 was re-expressed at the plasma membrane. This effect was observed with monocytes isolated by either centrifugal elutriation or adherence on fibronectin-coated dishes. IFN-gamma-dependent diminution of CR1 occurred concomitant with increased expression of Fc receptors and HLA-DQ antigen and unaltered expression of the C3bi receptor (CR3). The mechanism of CR1 loss from the monocyte cell surface was not due to internalization, because total cellular levels of CR1 (plasma membrane and intracellular pool) also decreased in response to IFN-gamma. These results indicate that IFN-gamma may be involved in regulating CR1 on mononuclear phagocyte surfaces.     

Invasion of Cryptococcus neoformans into human brain microvascular endothelial cells is mediated through the lipid rafts-endocytic pathway via the dual specificity tyrosine phosphorylation-regulated kinase 3 (DYRK3)

Cryptococcus neoformans is a neurotropic fungal pathogen, which provokes the onset of devastating meningoencephalitis. We used human brain microvascular endothelial cells (HBMEC) as the in vitro model to investigate how C. neoformans traverses across the blood-brain barrier. In this study, we present several lines of evidence indicating that C. neoformans invasion is mediated through the endocytic pathway via lipid rafts. Human CD44 molecules from lipid rafts can directly interact with hyaluronic acid, the C. neoformans ligand. Bikunin, which perturbs CD44 function in the lipid raft, can block C. neoformans adhesion and invasion of HBMEC. The lipid raft marker, ganglioside GM1, co-localizes with CD44 on the plasma membrane, and C. neoformans cells can adhere to the host cell in areas where GM1 is enriched. These findings suggest that C. neoformans entry takes place on the lipid rafts. Upon C. neoformans engagement, GM1 is internalized through vesicular structures to the nuclear membrane. This endocytic redistribution process is abolished by cytochalasin D, nocodazole, or anti-DYRK3 (dual specificity tyrosine-phosphorylation-regulated kinase 3) siRNA. Concomitantly, the knockdown of DYRK3 significantly reduces C. neoformans invasion across the HBMEC monolayer in vitro. Our data demonstrate that the lipid raft-dependent endocytosis process mediates C. neoformans internalization into HBMEC and that the CD44 protein of the hosts, cytoskeleton, and intracellular kinase-DYRK3 are involved in this process.     

PMA induces the ligand-independent internalization of CR1 on human neutrophils

Phorbol myristate acetate (PMA) has been reported to confer on the C3b receptor (CR1) of neutrophils a capacity for phagocytosis of particles bearing C3b without the involvement of other membrane receptors. In the present study, we employed a monoclonal antibody, YZ-1, that is specific for CR1 to assess the effect of PMA on plasma membrane expression of CR1, total cellular CR1, and internalization of CR1 by neutrophils. PMA had a biphasic effect on the membrane expression of CR1 by purified neutrophils, with 4 ng/ml inducing a 60% increment in receptor expression, and higher concentrations causing up to a 70% decrement. PMA-dependent increases in CR1 expression were not accompanied by corresponding changes in total cellular CR1 and were preempted by treatment of cells with formyl-methionyl-leucyl-phenylalanine (FMLP). PMA-induced decreases in CR1 expression by neutrophils, as measured by binding of indirectly fluoresceinated or radiolabeled YZ-1, or of 125I-labeled dimeric C3b, were maximal with 20 to 30 ng/ml PMA, and occurred within 30 min of incubation at 37 degrees C. The PMA-dependent down-regulation of CR1 by neutrophils was not associated with a comparable decrease in total cellular CR1, and this response was observed to occur also with monocytes but not with peripheral blood lymphocytes. By tagging neutrophil CR1 with 125I-YZ-1 Fab and monitoring accessibility to Protease, intracellular CR1 (inaccessible) was discriminated from receptor on plasma membrane (accessible). Internalization of CR1 occurred within 5 min after addition of PMA to neutrophils, was dose dependent, and involved up to two-thirds of the tagged receptors. Therefore, PMA caused internalization of CR1 by neutrophils in the absence of ligand, indicating that this response was independent of a transmembrane signal generated by a C3b-CR1 interaction.     

Cell binding, uptake and cytosolic partition of HIV anti-gag phosphodiester oligonucleotides 3'-linked to cholesterol derivatives in macrophages

The purpose of this study is to evaluate the cell interactions of a new class of compounds composed of phosphodiester oligonucleotides linked to the cholesterol group at position 3, 7, or 22 of the steroid structure. The resulting conjugates were assessed for their capacity to bind, penetrate and partition in the cytoplasmic compartment of murine macrophages. The results showed that lipophilic conjugates bind to cells much faster (t(1/2) < or = 10 min) than do underivatized oligomers. Oligomers tethered to the cholesterol at positions 3 and 7 (PO-GEM-3-Chol and PO-GEM-7-Chol) interacted more efficiently with cell membranes and were better internalized than oligomers attached to the cholesterol moiety at position 22 (PO-GEM-22-Chol). The cytosolic fraction of internalized oligomers was studied by a digitonin-based membrane permeabilization method. The recovered fraction of oligomers that can freely diffuse from the cytosol was comparable for GEM-91, a phosphorothioate congener, and for PO-GEM-7-Chol (50-60% of the internalized oligomers), while that of PO-GEM-3-Chol was less (30% of the internalized oligomers) indicating a higher membrane affinity of the latter derivative as compared to the other investigated compounds. Membrane binding and cell internalization correlated well with the hydrophobicity of the conjugates as characterized by their partition coefficients in a water-octanol system. Due to their capacity of rapid binding and cytosolic partition in cells, cholesterol-derivatized oligonucleotides at position 3 or 7 of the steroid molecule appeared as good candidates for systemic delivery of anti-HIV antisense compounds.     

Amidation of C3 at the thiolester site: stimulation of chemiluminescence and phagocytosis by a new inflammatory mediator

We studied the ability of particle-bound and fluid-phase C3b monomers and monomeric amidated C3 (prepared by treatment of purified human C3 with ammonium chloride or methylamine) to stimulate chemiluminescence of human polymorphonuclear leukocytes (PMN) and monocytes and to promote phagocytosis in the absence of antibody. Particle-bound C3b evoked chemiluminescence from both PMN and monocytes, and fluid-phase C3b (0.5 mg/ml) elicited significant chemiluminescence from PMN but not from monocytes. Amidated forms of C3, both particle bound and fluid phase, were potent stimulators of chemiluminescence from phagocytic cells and caused a significantly greater response than did C3b. The phagocytosis of 1-micron microspheres by PMN and monocytes was enhanced by coating them with purified C3b in an antibody-free system. Microspheres coated with amidated C3 were avidly phagocytized, and to a greater degree than were C3b-coated microspheres. In a direct binding assay with tritiated monomeric C3b and amidated C3, the affinity of the PMN complement receptor type 1 for C3b (Ka = 4.9 X 10(7) L/M) was similar to that for amidated C3 (Ka = 5.7 X 10(7) L/M). However, there was a fourfold increase in the number of apparent binding sites for amidated C3. This increase did not reflect binding of amidated C3 to the complement receptor type 3, because blocking of CR3 with the monoclonal antibody OKM 10 failed to decrease binding of amidated C3. In sites of increased ammoniagenesis, such as the kidney in chronic renal failure, amidated C3 may play a role as an inflammatory mediator by stimulating oxidative metabolism in phagocytic cells.