Cytolytic effect of polylysine on rabbit polymorphonuclear leukocytes

A stimuli-responsive nanoparticulate system using poly(ethylenimine)-graft-polysorbate for controlled protein release

Proteins have emerged as an important class of therapeutic agents due to their high specificity in their physiological actions. Over the years, diverse protein carriers have been developed; however, some concerns, such as the relatively low loading efficiency and release sustainability, have limited the efficiency of protein delivery. This study reports the use of hydrogel nanoparticles based on a novel copolymer, poly(ethylenimine)-graft-polysorbate (PEIP), as effective protein carriers. The copolymer is fabricated by grafting poly(ethylenimine) (PEI) with polysorbate 20 using carbonyldiimidazole chemistry. Its cytotoxicity is much lower than that of unmodified PEI in RGC5 and HEK293 cells. In comparison with nanoparticles formed by unmodified PEI, our nanoparticles are not only more efficient in cellular internalization, as indicated by the 5- to 6-fold reduction in the time they take to cause 90% of cells to exhibit intracellular fluorescence, but also give a protein loading efficiency as high as 70-90%. These, together with the salt-responsiveness of the nanoparticles in protein release and the retention of the activity of the loaded protein, suggest that PEIP and its hydrogel nanoparticles warrant further development as protein carriers for therapeutic applications.

Particulate systems for targeting of macrophages: basic and therapeutic concepts

Particulate systems in the form of liposomes, polymeric micelles, polymeric nano- and microparticles, and many others offer a rational approach for selective delivery of therapeutic agents to the macrophage from different physiological portals of entry. Particulate targeting of macrophages and intracellular drug release processes can be optimized through modifications of the drug carrier physicochemical properties, which include hydrodynamic size, shape, composition and surface characteristics. Through such modifications together with understanding of macrophage cell biology, targeting may be aimed at a particular subset of macrophages. Advances in basic and therapeutic concepts of particulate targeting of macrophages and related nanotechnology approaches for immune cell modifications are discussed.

Design, synthesis, and biocompatibility of an arginine-based polyester

Polycations are very useful in biotechnology. However, most existing polycations have high toxicity that significantly limits their clinical translation. We designed poly(ethylene argininylaspartate diglyceride) (PEAD) that is based on arginine, aspartic acid, glycerol, and ethylene glycol. A set of in vitro assays demonstrated that PEAD exhibited no cytotoxicity at 1 mg/mL, which is at least 100 times higher than the widely used polycation-polyethylenimine. Subcutaneous injection of 1 mg PEAD in rats did not cause an adverse response acutely or after 4 weeks. Zeta potential measurements revealed that PEAD has high affinity to biological polyanions such as DNA and hyaluronic acid. This polycation represents a new platform of biocompatible polycations that may lead to clinical innovations in gene therapy, controlled release, tissue engineering, biosensors, and medical devices.

Inhibition of gamma-thrombin-induced human platelet aggregation by histone H1subtypes and H1.3 fragments

Human platelets are differentially activated by varying concentrations of alpha-thrombin or by beta- and gamma-thrombin via three thrombin receptors, PAR-1, PAR-4 and GPIbalpha.It is likely that the development of a normal or abnormal hemostatic event in humans is dictated, in part, by the selective activation of these receptors. The ability to differentially inhibit these thrombin receptors could, therefore, have clinical significance. We have previously demonstrated that histone H1 selectively inhibits the PAR-4 receptor. In the current study we investigated whether five subtypes of the H1 molecule or fragments of the H1.3 subtype differentially inhibited the PAR-4 receptor. PAR-4 inhibition by all H1 subtypes was saturated at 1 uM with no statistical difference observed with the five H1 subtypes tested. Of the five fragments generated from the H1.3 molecule only one had significant inhibitory activity against PAR-4. The C-terminal fragment, N.1, generated by the proteolysis of the parent molecule by Asp-N endoproteinase (Aeromonas proteolytica) at the single aspartate residue, showed the same level of PAR-4 inhibition as the intact H1.3 at 1 uM concentrations. Removal of two N-terminal amino acids (Asp-Val as determined by MALDI analysis) from the N.1 fragment further enhanced its inhibitory activity. These studies may help to develop specific drugs to differentially inhibit the platelet thrombin receptors.

Thermodynamic studies and binding mechanisms of cell-penetrating peptides with lipids and glycosaminoglycans

Cell-penetrating peptides (CPPs) traverse the membrane of biological cells at low micromolar concentrations and are able to take various cargo molecules along with. Despite large differences in their chemical structure, CPPs share the structural similarity of a high cationic charge density. This property confers to them the ability to bind electrostatically membrane constituents such as anionic lipids and glycosaminoglycans (GAGs). Controversies exist, however, about the biological response after the interaction of CPPs with such membrane constituents. Present review compares thermodynamic binding studies with conditions of the biological CPP uptake. It becomes evident that CPPs enter biological cells by different and probably competing mechanisms. For example, some amphipathic CPPs traverse pure lipid model membranes at low micromolar concentrations--at least in the absence of cargos. In contrast, no direct translocation at these conditions is observed for non-amphipathic CPPs. Finally, CPPs bind GAGs at low micromolar concentrations with potential consequences for endocytotic pathways.

Therapeutic potential of nanoparticulate systems for macrophage targeting

The use of non-viral nanoparticulate systems for the delivery of therapeutic agents is receiving considerable attention for medical and pharmaceutical applications. This increasing interest results from the fact that these systems can be designed to meet specific physicochemical requirements, and they display low toxic and immunogenic effects. Among potential cellular targets by drug-loaded nanoparticles, macrophages are considered because they play a central role in inflammation and they act as reservoirs for microorganisms that are involved with deadly infectious diseases. The most common and potent drugs used in macrophage-mediated diseases treatment often induce unwanted side effects, when applied as a free form, due to the necessity of high doses to induce a satisfactory effect. This could result in their systemic spreading, a lack of bioavailability at the desired sites, and a short half-life. Therefore, the use of drug-loaded nanoparticles represents a good alternative to avoid, or at least decrease, side effects and increase efficacy. In this manuscript, we present an overview of the usefulness of nanoparticles for macrophage-mediated therapies in particular. We discuss, though not exhaustively, the potential of therapeutic agent-loaded nanoparticles for some macrophage-mediated diseases. We also underline the most important parameters that affect the interaction mechanisms of the macrophages and the physicochemical aspects of the particulate systems that may influence their performance in macrophage-targeted therapies.

Prevention of postoperative peritoneal adhesions: effects of lysozyme, polylysine and polyglutamate versus hyaluronic acid

OBJECTIVE

Intraperitoneal adhesions are an important cause of postoperative intestinal obstruction, abdominal discomfort and infertility. In the present study we hypothesized that a combination of polypeptides with different surface properties, resulting in fine disperse low-soluble complexes, could be of benefit in the prevention of abdominal adhesions.

MATERIAL AND METHODS

Various polypeptides including lysozyme, polyglutamate, polylysine and combinations of all three were evaluated as compared to hyaluronic acid. A standard wound on the parietal peritoneum in mice was used and the evaluated agents were administered immediately postoperatively. The extent of peritoneal adhesions to the injured area was measured and expressed as a percentage of the wound length as evaluated after 7 days. Flow cytometry was performed to evaluate the effect on peritoneal macrophage survival and phagocytic function and the Pick test was used to determine peroxide production in order to estimate toxicity and potential impairment of macrophage function caused by the chemicals.

RESULTS

Significant differences were seen among the treatment groups (p<0.001). Both polyglutamate and lysozyme, and polyglutamate together with polylysine significantly decreased adhesion formation as compared to hyaluronic acid. The polylysine-polyglutamate combination was still visible macroscopically on the peritoneal surface after 1 week, though not after 1 month. The polyglutamate-lysozyme mixture was less effective than these individual components alone. The chemicals did not show any toxic effects or altered function in macrophage cell culture.

CONCLUSIONS

Lysozyme, polyglutamate and, most effectively, a polyglutamate-polylysine combination significantly decreased experimental abdominal adhesion formation. A strong mechanical connection to the wound and prolonged attendance in the surface were noted. Peritoneal phagocyte function did not seem to be influenced by the chemicals.

Influence of TAT-peptide polymerization on properties and transfection activity of TAT/DNA polyplexes

Use of bioactive cationic peptides as gene carriers is limited by instability of their DNA complexes in vivo and by the loss of their biological activity due to undesired interactions of their bioactive parts with the DNA. To overcome the two major limitations, biodegradable high-molecular-weight form of TAT peptide (POLYTAT) sensitive to cellular redox-potential gradients was synthesized in this study by oxidative polycondensation. Physicochemical and transfection properties of DNA polyplexes based on POLYTAT were investigated and compared with polyplexes based on TAT polymer prepared by in situ template-assisted polymerization. Physicochemical properties of TAT-based polyplexes were affected by the molecular weight and method of polymerization of the TAT peptide. All TAT-based DNA polyplexes exhibited reduced cytotoxicity when compared with control polyethylenimine (PEI) polyplexes. Polyplexes based on both high-molecular-weight TAT polypeptides exhibited increased transfection efficiency compared to control TAT peptide but lower than that of PEI polyplexes. The evidence shows that transfection activity of TAT-based polyplexes is strongly dependent on the presence of chloroquine and therefore suggests that TAT polyplexes are internalized by an endocytosis. Overall, high-molecular-weight reducible polycations based on bioactive peptides has the potential as versatile carriers of nucleic acids that display low cytotoxicity and can prove to be especially beneficial in cases that require surface presentation of membrane-active or cell-specific targeting peptides.

Migration of poly-L-lysine through a lipid bilayer

When a giant vesicle, composed of neutral and anionic lipid (90:10 mol %), comes into contact with various poly-l-lysines (MW 500-29 300), ropelike structures form within the vesicle interior. By using fluorescence lipids and epi-fluorescence microscopy, we have shown that both neutral and anionic lipids are constituents of the ropes. Evidence that the ropes are also comprised of poly-l-lysine comes from two experiments: (a) direct microinjection of poly(acrylic acid) into rope-containing vesicles causes the ropes to contract into small particles, an observation consistent with a polycation/polyanion interaction; and (b) direct microinjection of fluorescein isothiocyanate (a compound that covalently labels poly-l-lysine with a fluorescent moiety) into rope-containing vesicles leads to fluorescent ropes. The results may be explained by a model in which poly-l-lysine binds to the vesicle exterior, forms a domain, and enters the vesicle through defects or at the domain boundary. The model helps explain the ability of poly-l-lysine to mediate the permeation of a cancer drug, doxorubicine, into the vesicle interior.

Vectors based on reducible polycations facilitate intracellular release of nucleic acids

BACKGROUND

Inefficient intracellular delivery of nucleic acids limits the therapeutic usefulness of synthetic vectors such as poly(L-lysine) (PLL)/DNA polyplexes. This article reports on the characterisation of a new type of synthetic vector based on a linear reducible polycation (RPC) that can be cleaved by the intracellular environment to facilitate release of nucleic acids.

METHODS

RPCs of molecular weight (mwt) 45 and 187 kDa were prepared by oxidative polycondensation of the peptide Cys-Lys(10)-Cys and used to condense nucleic acids. The stability of RPC-based polyplexes to reduction was determined using electrophoresis, dynamic light scattering and fluorescence techniques. Transfection activity was studied in several cancer cell lines (HeLa, LNCaP, PC-3 and B16-F10) using luciferase and green fluorescent protein (GFP) genes as reporter genes in the presence of chloroquine or the cationic lipid (N-(1-(2,3-dioleoyloxy)propyl)-N, N, N-trimethylammonium chloride) (DOTAP). A CMV-driven plasmid expressing the nitroreductase (ntr) gene was used to evaluate the therapeutic efficacy of RPC-based delivery vectors.

RESULTS

A 187-fold higher level of gene expression indicated that intracellular delivery of DNA was more efficient using RPC/DOTAP compared with vectors based on non-reducible PLL. Analysis by flow cytometry also showed enhanced delivery of the GFP gene by RPC/DOTAP in HeLa (51.5 +/- 7.9%), LNCaP (55.2 +/- 6.7%) and PC-3 (66.1 +/- 3.7%) cells. Transfection with the ntr gene and treatment with the prodrug CB1954 resulted in significant cell killing, achieving IC(50) values similar to those previously attained with adenoviral vectors. Delivery of mRNA (20-75% of cells) was also more efficient using RPC/DOTAP than PLL/DOTAP (<5% of cells).

CONCLUSIONS

These results demonstrate that lipid-mediated activation of RPC-based polyplexes is a useful strategy to enhance intracellular delivery of nucleic acids and potentiate therapeutic activity.

Polymer-based gene delivery with low cytotoxicity by a unique balance of side-chain termini

Protein expression after delivery of plasmid DNA to the cell nucleus depends on the processes of transcription and translation. Cytotoxic gene-delivery systems may compromise these processes and limit protein expression. This situation is perhaps most prevalent in current nonviral polycationic gene-delivery systems in which the polycationic nature of the delivery system can lead to cytotoxicity. To approach the problem of creating nontoxic but effective gene-delivery systems, we hypothesized that by optimizing the balance between polymer cationic density with endosomal escape moieties, effective gene transfer with low cytotoxicity could be created. As a model system, we synthesized a series of polymers whose side-chain termini varied with respect to the balance of cationic centers and endosomal escape moieties. Specifically, by polymer-analogous amidation we conjugated imidazole groups to the epsilon-amines of polylysine in varying mole ratios (73.5 mol % imidazole, 82.5 mol % imidazole, and 86.5 mol % imidazole). The primary epsilon-amine terminus of polylysine served as a model for the cationic centers, whereas the imidazole groups served as a model for the endosomal escape moieties. These polymers condensed plasmid DNA into nanostructures <150 nm and possessed little cytotoxicity in vitro. Transfection efficiency, as measured by luciferase protein expression, increased with increasing imidazole content of the polymers in a nonlinear relationship. The polymer with the highest imidazole content (86.5 mol %) mediated the highest protein expression, with levels equal to those mediated by polyethylenimine, but with little to no cytotoxicity.

Polymer-based gene delivery with low cytotoxicity by a unique balance of side-chain termini

Protein expression after delivery of plasmid DNA to the cell nucleus depends on the processes of transcription and translation. Cytotoxic gene-delivery systems may compromise these processes and limit protein expression. This situation is perhaps most prevalent in current nonviral polycationic gene-delivery systems in which the polycationic nature of the delivery system can lead to cytotoxicity. To approach the problem of creating nontoxic but effective gene-delivery systems, we hypothesized that by optimizing the balance between polymer cationic density with endosomal escape moieties, effective gene transfer with low cytotoxicity could be created. As a model system, we synthesized a series of polymers whose side-chain termini varied with respect to the balance of cationic centers and endosomal escape moieties. Specifically, by polymer-analogous amidation we conjugated imidazole groups to the epsilon-amines of polylysine in varying mole ratios (73.5 mol % imidazole, 82.5 mol % imidazole, and 86.5 mol % imidazole). The primary epsilon-amine terminus of polylysine served as a model for the cationic centers, whereas the imidazole groups served as a model for the endosomal escape moieties. These polymers condensed plasmid DNA into nanostructures <150 nm and possessed little cytotoxicity in vitro. Transfection efficiency, as measured by luciferase protein expression, increased with increasing imidazole content of the polymers in a nonlinear relationship. The polymer with the highest imidazole content (86.5 mol %) mediated the highest protein expression, with levels equal to those mediated by polyethylenimine, but with little to no cytotoxicity.

Polylysine-based transfection systems utilizing receptor-mediated delivery

Receptor-mediated gene transfer is a promising gene delivery technique. It employs a DNA-binding polycation, such as polylysine, to compact plasmid DNA to a size that can be taken up by cells (<100-200 nm). To allow internalization by receptor-mediated endocytosis, cell binding ligands, such as asialoglycoproteins or galactose for hepatocytes, anti-CD3 and anti-CD5 for T-cells, and transferrin, have been covalently attached to polylysine. Intracellular barriers for successful gene transfer include release of DNA complexes from endosomes or lysosomes, nuclear import of DNA complexes, and disassembly of the DNA-polylysine particles. Release of particles from internal vesicles has been achieved by the addition of lysosomotropic agents or glycerol to the transfection medium, or by the incorporation of endosomolytic compounds, such as viruses or membrane active peptides. This technique has already been used to transfect certain organs in vivo, including liver and lung.

Glycerol and polylysine synergize in their ability to rupture vesicular membranes: a mechanism for increased transferrin-polylysine-mediated gene transfer

The presence of about 1.2 M glycerol during transfection with DNA/transferrin-polylysine and DNA/polylysine complexes dramatically increases transgene expression in a variety of cell types, provided that the complexes have an excess of polylysine. We have characterized this phenomenon using a human melanoma cell line (H225). The addition of 1.2 M glycerol to the transfection medium has no influence on the internalization of DNA complexes or on the promoter activity used to direct reporter gene expression. Neither prenor postincubation of the cells with glycerol results in a notable increase in transgene expression. Bafilomycin A1 and chloroquine, two drugs affecting the endosomal pathway, both influenced transgene expression, indicating that glycerol acts on internal vesicles. Glycerol and polylysine synergized in their ability to lyse erythrocytes as well as internal vesicles (microsomes) isolated from H225 cells, indicating that the glycerol effect is due to a labilization of vesicular membranes, which facilitates membrane disruption by polylysine. Our current model suggests that the excess of polylysine in the DNA complexes disrupts vesicular membranes in the presence of glycerol, thus allowing the release of DNA complexes into the cytoplasm.

Reduction of histone cytotoxicity by the Alzheimer beta-amyloid peptide precursor

In a search for Alzheimer beta-amyloid peptide precursor ligands, Potempska et al. (Arch. Biochem. Biophys. (1993) 304, 448) found that histones bind with high affinity and specificity to the secreted precursor. Because exogenous histones can be cytotoxic, we compared the effects of histones on the viability of cells which produce little beta-amyloid peptide precursor (U-937) to those on cells that produce twenty times as much precursor (COS-7). Addition of purified histones caused necrosis of U-937 cells (histone H4, LD50 = 1.5 microM). Extracellular A beta precursor in the submicromolar range prevented histone-induced U-937 cell necrosis. Cell-surface precursor also reduced histone toxicity: COS-7 cells were less sensitive to the toxic effects of histone H4 (LD50 = 5.4 microM). COS-7 cells in which the expression of an APP mRNA-directed ribozyme reduced the synthesis of the protein by up to 80% were more sensitive to histone H4 (LD50 = 3.2 microM) than cells that expressed the vector alone. Histone H4 binds to cell-associated A beta precursor. Cells expressing the A beta precursor-directed ribozyme bound less 125I-labeled histone H4 than those expressing the vector alone. In the limited extracellular space of tissues in vivo, both secreted and cell-surface A beta precursor protein may play significant roles in trapping chromatin or histones and removing them from the extracellular milieu.

The role of calcium ions in DEAE-dextran-induced stimulation of neutrophil migration

The polycation DEAE-dextran caused a strong enhancement of non-directed migration of rabbit peritoneal neutrophils. The activating effect on migration was completely annulled in the presence of the polyanion poly-D-glutamic acid, indicating that the effect depended on the positive charge of the macromolecule. Chemotaxis activated by the chemotactic peptide fMLP was only slightly affected by the polycation. In contrast with fMLP-activation, stimulation of migration by DEAE-dextran was dependent on the presence of extracellular Ca2+. DEAE-dextran also stimulated migration of electroporated neutrophils. The stimulation was absent when calcium was not present; the increase of migration was strongest at Ca(2+)-concentrations between 100 nM and 1 microM Ca2+. This indicates that the requirement for extracellular Ca2+ in intact cells is a reflection of the intracellular requirement. Several types of calcium blockers gave a moderate inhibition of DEAE-dextran activated migration. Activation of migration by DEAE-dextran of electroporated neutrophils was completely inhibited by calcium channel blockers, at very low concentrations. The results suggest that both Ca(2+)-fluxes across the plasma membrane and Ca2+ from intracellular stores are required for DEAE-activated migration, and that the calcium from the intracellular source is required on a place where the extracellular Ca2+ has no, or limited, admittance.

Broad cytolytic specificity of myotoxin II, a lysine-49 phospholipase A2 of Bothrops asper snake venom

The cytotoxic activity of Bothrops asper myotoxin II, a lysine-49 phospholipase A2 isoform, on different cell types in culture, was investigated. Myotoxin II caused a dose-dependent cytolytic effect on all cell types tested, characterized by rapid release of cytoplasmic lactic dehydrogenase and drastic morphological cell alterations. Quantitative differences in the susceptibility to myotoxin II among cell types fell within a relatively narrow range, and in general, the toxin was cytolytic at concentrations of 50-100 micrograms/ml (3-7 microM), when assays were performed using culture medium as a diluent. Toxin activity was markedly enhanced if phosphate-buffered saline was utilized instead of medium. The cytotoxic activity of myotoxin III, an aspartate-49 isoform from the same venom, on both endothelial cells and skeletal muscle myoblasts was higher than that of myotoxin II, suggesting that, although phospholipase A2 activity is clearly not required for the induction of cell damage, it may have an enhancing role. In contrast to B. asper myotoxins, other basic phospholipases A2 with myotoxic activity in vivo (notexin from Notechis scutatus, and two enzymes isolated from Vipera russelli venom) did not affect endothelial cells and myoblasts. Pretreatment of cells with neuraminidase, tunicamycin, or protamine, did not alter their susceptibility to myotoxin II. At low temperatures (2-4 degrees C) myotoxin II was devoid of cytolytic effect. Washing and neutralization experiments using heparin with low affinity for antithrombin or mouse monoclonal antibody MAb-3 suggest that at low temperatures myotoxin II binds very weakly to the cells, and that its normal interaction with the putative target is probably not only based on charge, but that a membrane penetration event may be required.

The effect of human eosinophil granule major basic protein on airway responsiveness in the rat in vivo. A comparison with polycations

Major basic protein (MBP) is a highly cationic protein found in the granules of eosinophils. It has been postulated that MBP may participate in the pathogenesis of airway hyperresponsiveness exhibited by asthmatic patients. Accordingly, we used a rat model to investigate the effect of human MBP instillation on airway responsiveness and the possible role of cationic charge in the determination of this effect. Dose-response characteristics to inhaled methacholine (MDRC) were determined at baseline, and the animals were allowed to recover. Then animals in the experimental group received 100 micrograms of purified human MBP via direct instillation into the trachea. One hour after instillation, the MDRC were again assessed. Control animals received (in lieu of MBP) buffer from the void volume pool of the same chromatography column used to purify the MBP. One hour after instillation of MBP there was a significant increase in airway responsiveness to inhaled methacholine, whereas control animals exhibited no increase in airway responsiveness. Some animals from the MBP group were restudied 48 h after MBP instillation, by which time airway responsiveness had returned to baseline level. The effect of the polycations poly-L-arginine and poly-L-lysine on airway responsiveness was also examined. As with MBP, airway responsiveness to inhaled methacholine increased 1 h after the instillation of either polycation. In addition, acetylation of the charged groups on poly-L-lysine resulted in a loss of this effect. Histologic examination of the airways failed to reveal airway epithelial shedding 1 h after MBP or polycation instillation.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of macrophage cell-surface binding sites for cationized bovine serum albumin

Autoimmune diseases are characterized by the presence of autoantibodies often restricted to host proteins exhibiting charge rich domains. Charged polypeptides elicit strong immune responses, and cationized bovine serum albumin and other cationic proteins are significantly more immunogenic than their less charged counterparts. These phenomena may involve enhanced protein uptake by macrophages, resulting in greater processing and presentation of antigenic peptide-MHC complexes to T-cells. We compared macrophage cell-surface binding and uptake of native and cationized bovine serum albumin. Specific binding of [125I]cationized bovine serum albumin to THP-1 macrophages in vitro was 11-16 fold greater than for native albumin. Half-maximal inhibition of [125I]cationized albumin binding was observed at 10-7M ligand. The specificity of [125I]cationized bovine serum albumin binding and uptake was further studied in terms of competitive inhibition of proteolysis by proteins of varying charge content. Cationized bovine serum albumin, but not native albumin, inhibited proteolysis of [125I]cBSA. Calf thymus histones also inhibited cBSA degradation. High concentration of myelin basic protein was moderately effective at blocking cBSA degradation, while myoglobin and beta lactalbumin showed no inhibition. These results indicate that specific cell-surface binding sites which occur on macrophages may mediate selective uptake of certain proteins with highly charged domains including some autoantigens.

Changes of plasma membrane permeability in neutrophils treated with polycations

The effects of the polycations poly-L-arginine, poly-L-lysine, and poly-ethyleneimine on rabbit neutrophil membrane permeability were compared. LDH release, quin2 release from quin2-loaded cells, and increase of indo 1 fluorescence were considered as measures for changes in membrane permeability. All polycations cause abundant LDH release. Quin2 release occurs more rapidly than LDH release, and the increase of indo 1 fluorescence is even faster. Apparently polycation-induced permeability changes occur gradually, allowing the influx (or efflux) of small molecules more rapidly than larger ones. A number of divalent and trivalent cations inhibit polycation-induced LDH and quin2 release in a way that resembles the inhibition of other cytotoxic agents described in literature. In the absence of extracellular Ca2+, the polycations induce little lysozyme release. In the presence of extracellular Ca2+, there is abundant lysozyme release, indicating that the influx of Ca2+ causes exocytosis. Exocytosis still occurs when Ca2+ is added some time after polycation addition, indicating that polycation treatment leaves the cells largely intact. All polycations tested have in common that they cause gradual changes in the permeability of the plasma membrane only, which opens the possibility to use them as membrane-permeabilizing agents for the study of Ca(2+)-induced exocytosis.

Charge distributions and amphipathicity of receptor-binding alpha-helices

Contacts between ligands and cell-surface receptors result in cellular activation. Defining principles which govern these important interactions are of interest and might facilitate pharmacologic intervention. We examined receptor-binding alpha-helical segments of polypeptide hormones and globular proteins for distinguishing amino acid content and distributions. There was a slight excess of basic residues in both sets of alpha-helices compared with a panel of control helices. Helical concentrations of charged residues were quantitated using the hydrophobic moment algorithm, adapted to obtain the vector sum of side chain charges. By this analysis we detected increased concentrations of the set of basic residues (arginine, lysine and histidine) on one side of the receptor-binding alpha-helices of the polypeptide hormones, and to a lesser extent the protein ligands. Comparable data were obtained for "lytic" venom peptides and calmodulin-regulated kinase segments. There was an even greater correlation between receptor-associating alpha-helical segments and large hydrophobic moments. Receptor-binding helical segments of polypeptide hormones, and to a lesser extent those of protein ligands, often are basic and amphipathic.

Permeabilization and calcium-dependent activation of rabbit polymorphonuclear leukocytes by poly-L-arginine

In the absence of extracellular Ca2+, poly-L-arginine induces little lysozyme release from rabbit polymorphonuclear leukocytes (PMNs). The polycation causes plasma membrane damage, which is evident from the release of the cytoplasmic enzyme lactate dehydrogenase (LDH). In the presence of Ca2+ concentrations higher than 0.2 mM, poly-L-arginine induces a strong lysozyme release that is superimposed on the membrane-damaging effect. The results suggest that poly-L-arginine permeabilizes the plasma membrane, enabling Ca2+ to enter the cell, which results in the exocytotic release of granule constituents. The GTP analog GTP gamma S shifts the Ca2+ requirement of exocytosis to slightly higher concentrations, whereas it completely inhibits poly-L-arginine-induced LDH release. Pertussis toxin gives a moderate inhibition, and La3+ completely inhibits poly-L-arginine-induced enzyme release. Whereas poly-L-arginine alone induces little superoxide generation in rabbit PMNs, there is a synergistic enhancement of superoxide production when GTP gamma S and poly-L-arginine are present together. Guanine nucleotides apparently have a modulating effect on the actions of poly-L-arginine on the PMN, but the nature of this effect remains to be determined.

Insulin-like effects of histones H3 and H4 on isolated rat adipocytes

Crude preparations of histones had insulin-like actions in isolated adipocytes. This activity was attributed to the arginine-rich histones, H3 and H4. The metabolic effects of purified H3 and H4 on isolated adipocytes were similar to those of insulin in a number of respects. Like insulin, H3 and H4 stimulated the incorporation of both glucose and pyruvate in isolated cells and stimulated intercellular oxidation of glucose; in contrast, the lipolytic agents ACTH and isoproterenol actually inhibited the incorporation of pyruvate into adipocytes. In contrast to the effects of the lipolytic hormones, the effects of H3 and H4, like insulin, were not blocked by the presence of adenosine deaminase in the medium. The same concentrations of phenylarsine oxide were required to inhibit the stimulation of glucose incorporation whether by insulin or by histones. Furthermore, the addition of H4 or insulin to isolated adipocytes resulted in the increased phosphorylation of 17 kDa phosphoproteins as detected by two-dimensional electrophoresis. The insulin-like effect of the active histones was specific to their structure. Lysine-rich histones (H1, H2A and H2B), various polycations, and proteolytic fragments of purified H3 or H4 were all inactive. It is unknown whether this phenomenon might imply a physiological function for such endogenous molecules; however, a comparison of the detailed effects of insulin and histones might be informative in terms of common intracellular transduction systems.

Guanine nucleotides inhibit poly-L-arginine-induced membrane damage in polymorphonuclear leukocytes

Poly-L-arginine induces a strong release of the cytoplasmic enzyme lactate dehydrogenase from rabbit polymorphonuclear leukocytes, indicating that plasma membrane damage occurs. GTP gamma S, a stable guanine nucleotide, completely inhibits poly-L-arginine-induced LDH release whereas pretreatment of the cells with pertussis toxin gives a moderate inhibition. The results suggest that poly-L-arginine-induced plasma membrane damage is mediated by guanine nucleotide binding structures.

Enzyme release from polymorphonuclear leukocytes during interaction with calcium oxalate microcrystals

The interaction between polymorphonuclear leukocytes and calcium oxalate crystals results in enzyme release from the cells, due to exocytosis and plasma membrane damage. Positive charges on the crystals apparently play a predominant role in the interaction. Removal of negatively charged sialic acid from the cell surface has little effect on crystal-induced enzyme release. Glucose-loaded liposomes release glucose upon exposure to calcium oxalate crystals when the liposomes are negatively charged but not when the liposomes bear a positive charge. Cytoplasts, which are devoid of granules, are severely damaged by calcium oxalate crystals. As with intact cells the damaging effect of the crystals on liposomes and cytoplasts can be counteracted by a polyanion. The results are consistent with the view that calcium oxalate crystals can cause enzyme release from polymorphonuclear leukocytes, mainly by a direct effect on the plasma membrane. The release might be due to an interaction of positive charges on the crystals with negative countercharges on the cells, possibly located in the phospholipid bilayer.

Protamine sulfate-induced enzyme secretion from rabbit neutrophils

Protamine sulfate induces enzyme secretion from rabbit neutrophils. Enzyme secretion is mainly due to exocytosis but, depending on the experimental conditions, a small amount of cytolysis may occur. As compared with stimulation of neutrophil functions by other activators, protamine sulfate-induced enzyme release by exocytosis is a relatively slow process and is not accompanied by a marked activation of the metabolic burst. For optimal exocytosis, extracellular Ca2+ is required, but there is still some enzyme release in its absence, and other metal ions (Sr2+, Ba2+, Mg2+) can partly mimic the effect of Ca2+. Positive charges on protamine are of primary importance because the polyanion heparin completely inhibits protamine sulfate-induced enzyme release. Protamine linked to agarose beads is able to induce enzyme release; thus the induction of exocytosis is due to an interaction of the positive charges on protamine with the plasma membrane. Sialic acid residues on the membrane, however, seem not to play an important role in this process.