An investigation of the factors controlling the adsorption of protein antigens to anionic PLG microparticles

This work examines physico-chemical properties influencing protein adsorption to anionic PLG microparticles and demonstrates the ability to bind and release vaccine antigens over a range of loads, pH values, and ionic strengths. Poly(lactide-co-glycolide) microparticles were synthesized by a w/o/w emulsification method in the presence of the anionic surfactant DSS (dioctyl sodium sulfosuccinate). Ovalbumin (OVA), carbonic anhydrase (CAN), lysozyme (LYZ), lactic acid dehydrogenase, bovine serum albumin (BSA), an HIV envelope glyocoprotein, and a Neisseria meningitidis B protein were adsorbed to the PLG microparticles, with binding efficiency, initial release and zeta potentials measured. Protein (antigen) binding to PLG microparticles was influenced by both electrostatic interaction and other mechanisms such as van der Waals forces. The protein binding capacity was directly proportional to the available surface area and may have a practical upper limit imposed by the formation of a complete protein monolayer as suggested by AFM images. The protein affinity for the PLG surface depended strongly on the isoelectric point (pI) and electrostatic forces, but also showed contributions from nonCoulombic interactions. Protein antigens were adsorbed on anionic PLG microparticles with varying degrees of efficiency under different conditions such as pH and ionic strength. Observable changes in zeta potentials and morphology suggest the formation of a surface monolayer. Antigen binding and release occur through a combination of electrostatic and van der Waals interactions occurring at the polymer-solution interface.     

Characterization of antigens adsorbed to anionic PLG microparticles by XPS and TOF-SIMS

The chemical composition of the surface of anionic PLG microparticles before and after adsorption of vaccine antigens was measured using X-ray photoelectron spectroscopy (XPS) and time-of-flight secondary ion mass spectrometry (TOF-SIMS). The interfacial distributions of components will reflect underlying interactions that govern properties such as adsorption, release, and stability of proteins in microparticle vaccine delivery systems. Poly(lactide-co-glycolide) microparticles were prepared by a w/o/w emulsification method in the presence of the anionic surfactant dioctyl sodium sulfosuccinate (DSS). Ovalbumin, lysozyme, a recombinant HIV envelope glyocoprotein and a Neisseria meningitidis B protein were adsorbed to the PLG microparticles, with XPS and time-of-flight secondary mass used to analyze elemental and molecular distributions of components of the surface of lyophilized products. Protein (antigen) binding to PLG microparticles was measured directly by distinct elemental and molecular spectroscopic signatures consistent with amino acids and excipient species. The surface sensitive composition of proteins also included counter ions that support the importance of electrostatic interactions being crucial in the mechanism of adsorptions. The protein binding capacity was consistent with the available surface area and the interpretation of previous electron and atomic force microscope images strengthened by the quantification possible by XPS and the qualitative identification possible with TOF-SIMS. Protein antigens were detected and quantified on the surface of anionic PLG microparticles with varying degrees of efficiency under different adsorption conditions such as surfactant level, pH, and ionic strength. Observable changes in elemental and molecular composition suggest an efficient electrostatic interaction creating a composite surface layer that mediates antigen binding and release.     

The potency of the adjuvant, CpG oligos, is enhanced by encapsulation in PLG microparticles

The objective of this work was to evaluate the potency of the CpG containing oligonucleotide encapsulated within poly(lactide-co-glycolide), and coadministered with antigen adsorbed to poly(lactide-co-glycolide) microparticles (PLG particles). The formulations evaluated include, CpG added in soluble form, CpG adsorbed, and CpG encapsulated. The antigen from Neisseria meningitidis serotype B (Men B) was used in these studies. The immunogenicity of these formulations was evaluated in mice. Poly(lactide-co-glycolide) microparticles were synthesized by a w/o/w emulsification method in the presence of a charged surfactant for the formulations. Neisseria meningitidis B protein was adsorbed to the PLG microparticles, with binding efficiency and initial release measured. CpG was either added in the soluble or adsorbed or encapsulated form based on the type of formulation. The binding efficiency, loading, integrity and initial release of CpG and the antigen were measured from all the formulations. The formulations were then tested in mice for their ability to elicit antibodies, bactericidal activity and T cell responses. Encapsulating CpG within PLG microparticles induced statistically significant higher antibody, bactericidal activity and T cell responses when compared to the traditional method of delivering CpG in the soluble form.     

Anionic microparticles are a potent delivery system for recombinant antigens from Neisseria meningitidis serotype B

The adsorption behavior of model proteins onto anionic poly(lactide-co-glycolide) (PLG) microparticles was evaluated. PLG microparticles were prepared by a w/o/w solvent evaporation process in the presence of the anionic surfactant dioctyl sodium sulfosuccinate (DSS). The effect of surfactant concentration and adsorption conditions on the adsorption efficiency and release rates in vitro was also studied. Subsequently, the microparticle formulation was tested to evaluate the efficacy of anionic microparticles as delivery systems for recombinant antigens from Neisseria meningitides type B (Men B), with and without CpG adjuvant. Protein (antigen) binding to anionic PLG microparticles was influenced by both electrostatic interaction and by other mechanisms, including hydrophobic attraction. The Men B antigens adsorbed efficiently onto anionic PLG microparticles and, following immunization in mice, induced potent enzyme-linked immunosorbent assay (ELISA) and serum bactericidal activity in comparison to alum-adsorbed formulations. These Men B antigens represent an attractive approach for vaccine development.     

Polylactide-co-glycolide microparticles with surface adsorbed antigens as vaccine delivery systems

Several groups have shown that vaccine antigens can be encapsulated within polymeric microparticles and can serve as potent antigen delivery systems. We have recently shown that an alternative approach involving charged polylactide co-glycolide (PLG) microparticles with surface adsorbed antigen(s) can also be used to deliver antigen into antigen presenting cell (APC). We have described the preparation of cationic and anionic PLG microparticles which have been used to adsorb a variety of agents, which include plasmid DNA, recombinant proteins and adjuvant active oligonucleotides. These PLG microparticles were prepared using a w/o/w solvent evaporation process in the presence of the anionic surfactants, including DSS (dioctyl sodium sulfosuccinate) or cationic surfactants, including CTAB (hexadecyl trimethyl ammonium bromide). Antigen binding to the charged PLG microparticles was influenced by several factors including electrostatic and hydrophobic interactions. These microparticle based formulations resulted in the induction of significantly enhanced immune responses in comparison to alum. The surface adsorbed microparticle formulation offers an alternative and novel way of delivering antigens in a vaccine formulation.     

The Effect of CTAB Concentration in Cationic PLG Microparticles on DNA Adsorption and in Vivo Performance

Purpose. Cationic PLG microparticles with adsorbed DNA have previously been shown to efficiently target antigen presenting cells in vivo for generating higher immune responses in comparison to naked DNA. In this study we tried to establish the role of surfactant (CTAB) concentration on the physical behavior of these formulations. Methods. Cationic PLG microparticle formulations with adsorbed DNA were prepared using a solvent evaporation technique. Formulations with varying CTAB concentrations and a fixed DNA load were prepared. The loading efficiency and 24 h DNA release was evaluated for each formulation. Select formulations were tested in vivo. Results. Higher CTAB concentration correlated with higher DNA binding efficiency on the microparticles and lower in vitro release rates. Surprisingly though, the in vivo performance of formulations with varying CTAB concentration was comparable to one another. Conclusions. Cationic PLG microparticles with adsorbed DNA, as described here, offer a robust way of enhancing in vivo responses to plasmid DNA.     

Microparticles for intranasal immunization

Of the several routes available for mucosal immunization, the nasal route is particularly attractive because of ease of administration and the induction of potent immune responses, particularly in the respiratory and genitourinary tracts. However, adjuvants and delivery systems are required to enhance immune responses following nasal immunization. This review focuses on the use of microparticles as adjuvants and delivery systems for protein and DNA vaccines for nasal immunization. In particular we discuss our own work on poly(lactide co-glycolide) (PLG) microparticles with entrapped protein or adsorbed DNA as a vaccine delivery system. The possible mechanisms involved in the enhancement of immune responses through the use of DNA adsorbed onto PLG microparticles are also discussed.     

Japanese encephalitis virus vaccine formulations using PLA lamellar and PLG microparticles

Japanese encephalitis virus (JEV)-loaded poly(lactide) (PLA) lamellar and poly(DL-lactide-co-glycolide) (PLG) microparticles were successfully prepared with low molecular weight PLA by the precipitate method and with 6% w/v PLG in the organic phase, 10% w/v PVP and 5% w/v NaCl in the continuous phase, by using a water-in-oil-in-water emulsion/solvent extraction technique, respectively. JEV was entrapped in the PLG microparticles by a solvent extraction technique with trapping efficiencies up to 98%, loading level 5.5% w/w, and mean particle size 3.8 microm. The distribution (%) of JEV on the PLG microparticles surface, outer layer, and core were 11.2, 41.7 and 46.4%, respectively. The cumulative release of JEV had an upper limit of approximately 58% of the JEV load at 24 days. The steady release rate was 1.33 microg JEV/mg microparticles/day of JEV release maintained for 24 days. The corresponding virus loading of the PLA lamellae is approximately 0.78% w/w and the loading efficiency (77.8%), JEV content (7.84 microg/mg), and yield (96.3%), respectively. The distribution (%) of JEV on the microparticles surface, outer layer, and core were 82.1, 13.3 and 2.2%, respectively. The live JEV challenge in mice test, in which mice received one dose of 20 mg JEV-loaded PLG microparticles, 20 mg JEV-loaded PLA lamellar in comparison with JEV or PBS solution, was evaluated after IP immunization of BALB/c mice. The study results show that the greatest survival was observed in the group of mice immunized with 20 mg JEV-loaded PLG microparticles and 20 mg JEV-loaded PLA microparticles group (80%). The JEV incorporation, physicochemical characterization data, and the animal results obtained in this study may be relevant in optimizing the vaccine incorporation and delivery properties of these potential vaccine targeting carriers.     

Composition and Surface Charge of DNA-Loaded Microparticles Determine Maturation and Cytokine Secretion in Human Dendritic Cells

PURPOSE: Biodegradable microparticles prepared from poly(lactide) (PLA) and poly(lactide-co-glycolide) (PLGA) have been shown to be promising carrier systems for vaccine delivery. Here, we have investigated the capacity of different PLA and PLGA microparticle formulations to induce stimulation of human blood monocyte-derived dendritic cells (DCs). METHODS: Stimulation of human derived dendritic cells by plain microparticles were compared with microparticles loaded with plasmid DNA or double-stranded salmon DNA either by encapsulation or adsorption to the surface of cationic microparticles. Stimulation of DCs was monitored by the up-regulation of surface maturation markers CD83 and CD86 and the secretion of IL-12 and TNF-alpha. RESULTS: Slowly degrading PLA microparticles did not induce any detectable stimulation or activation of DCs. In contrast, fast degrading PLGA microparticles were able to influence DC maturation and cytokine secretion dependent on their surface charge. Anionic PLGA microparticles induced an up-regulation of CD83 and high TNF-alpha secretion, which was further enhanced up to the level of the potent stimulator lipopolysaccharide (LPS) when plasmid DNA was encapsulated. Moreover, the secretion of significant amounts of IL-12 was observed. Cationic PLGA microparticles induced an up-regulation of CD86 and moderate TNF-alpha secretion, but no IL-12 secretion, with no additional effects in the presence of plasmid DNA. CONCLUSIONS: The data suggest that the composition and charge of biodegradable DNA-loaded microparticles profoundly influences maturation and cytokine secretion in DCs. Thus, the individual formulation of microparticles used as a vaccine carrier system might considerably influence the profile of the immune response.     

Biodegradable microparticles as a delivery system for the allergens of Dermatophagoides pteronyssinus (house dust mite): I. Preparation and characterization of microparticles

The encapsulation of allergens into biodegradable microparticles may offer the potential for novel forms of hyposensitization therapy. The use of microparticles for hyposensitization therapy may offer the potential advantages of a reduced number of doses, through controlled release of allergens, and the possibility of oral delivery. Nevertheless, a possible concern is the effect of the microencapsulation process on the integrity and activity of the entrapped allergens. Therefore, in the current studies, an allergen, Dermatophagoides pteronyssinus (D.Pt.), was entrapped in poly(lactide-co-glycolide) (PLG) microparticles and several established techniques were used to investigate the integrity of the entrapped allergen. Isoelectric focusing indicated that all the protein components of the allergen were successfully entrapped in the microparticles. A radioallergosorbent test (RAST) inhibition assay indicated that there was a minor reduction in the binding of specific IgE to the entrapped allergen, but this was thought unlikely to affect the ability of the allergen to act as a hyposensitizing agent. Finally, the IgG binding activity of the major allergenic component of D.Pt. (Der P1) was shown to be unchanged following microencapsulation. Hence, the current studies indicated that the allergen D.Pt., was not adversely affected following encapsulation into PLG microparticles. Therefore, microparticles may have potential as delivery systems for hyposensitization therapy.     

Enhancing the therapeutic efficacy of CpG oligonucleotides using biodegradable microparticles

Oligonucleotides, with specific sequence surrounding CpG motifs, appear to be very effective for the induction of a potent Th1 responses. This molecule represents pathogen-associated molecular patterns (PAMPs) that allows the pathogen recognition receptors (PRRs) present on innate immune cells to recognize them and become activated. PAMPs and related compounds are often labelled as immunopotentiators, allowing a clear distinction between them and particulate delivery systems such as emulsions, liposomes, virus-like particles and microparticles.Microparticles prepared from biodegradable, biocompatible polyesters, and poly (lactide co-glycolide) (PLG). They have been proven to be a good particulate delivery system for the co-delivery of antigens and adjuvants. PLG has been used in humans for many years as a resorbable suture material and controlled-release drug delivery systems. It has been demonstrated that antigen presenting cells (APCs) efficiently uptake the PLG microparticles (∼ 1 μm) both in vivo and in vitro. After uptake, the PLG subsequently induces an antigen specific CTL response in rodents.Several groups, including our group, have evaluated CpG as an immunopotentiator in various formulations and delivery systems (i.e. emulsions and particulate systems). This review will discuss in detail the work conducted so far with CpG using PLG microparticles as a delivery system. We will also discuss the advantages and enhancement of immune properties of formulating CpG (soluble, adsorbed, and encapsulated forms) with PLG microparticles along with future directions for these microparticles with CpG.     

Preparation, physiochemical characterization, and oral immunogenicity of Abeta(1-12), Abeta(29-40), and Abeta(1-42) loaded PLG microparticles formulations

Alzheimer's disease (AD) is caused by the deposition of beta-amyloid (Abeta) protein in brain. The current AD immunotherapy aims to prevent Abeta plaque deposition and enhance its degradation in the brain. In this work, the peptides B-cell epitope Abeta(1-12), T-cell epitope Abeta(29-40) and full-length Abeta(1-42) were loaded separately to the poly (D,L-lactide co-glycolide) (PLG) microparticles by using W/O/W double emulsion solvent evaporation method with entrapment efficacy of 70.46%, 60.93%, and 65.98%, respectively. The prepared Abeta PLG microparticles were smooth, spherical, individual, and nonporous in nature with diameters ranging from 2 to 12 microm. The cumulative in vitro release profiles of Abeta(1-12), Abeta(29-40), and Abeta(1-42) from PLG microparticles sustained for long periods and progressively reached to 73.89%, 69.29%, and 70.08% by week 15. In vitro degradation studies showed that the PLG microparticles maintained the surface integrity up to week 8 and eroded completely by week 16. Oral immunization of Abeta peptides loaded microparticles in mice elicited stronger immune response by inducing anti-Abeta antibodies for prolonged time (24 weeks). The physicochemical characterization and immunogenic potency of Abeta peptides incorporated PLG microparticles suggest that the microparticles formulation of Abeta can be a potential oral AD vaccine.     

Adsorption of Monoclonal Antibodies to Glass Microparticles

Microparticulate glass represents a potential contamination to protein formulations that may occur as a result of processing conditions or glass types. The effect of added microparticulate glass to formulations of three humanized antibodies was tested. Under the three formulation conditions tested, all three antibodies adsorbed irreversibly at near monolayer surface coverages to the glass microparticles. Analysis of the secondary structure of the adsorbed antibodies by infrared spectroscopy reveal only minor perturbations as a result of adsorption. Likewise, front-face fluorescence quenching measurements reflected minimal tertiary structural changes upon adsorption. In contrast to the minimal effects on protein structure, adsorption of protein to suspensions of glass microparticles induced significant colloidal destabilization and flocculation of the suspension.     

A comparison of anionic nanoparticles and microparticles as vaccine delivery systems

The objective of this work was to conduct an in vivo comparison of nanoparticles and microparticles as vaccine delivery systems. Poly (lactide-co-glycolide) (PLG) polymers were used to create nanoparticles size 110 nm and microparticles of size 800-900 nm. Protein antigens were then adsorbed to these particles. The efficacy of these delivery systems was tested with two protein antigens. A recombinant antigen from Neisseria meningitides type B (MenB) was administered intramuscularly (i.m.) or intraperitonealy (i.p.). An antigen from HIV-1, env glycoprotein gp140 was administered intranasally (i.n.) followed by an i.m. boost. From three studies, there were no differences between the nanoparticles and micro-particles formulations. Both particles led to comparable immune responses in mice. The immune responses for MenB (serum bactericidal activity and antibody titers) were equivalent to the control of aluminum hydroxide. For the gp140, the LTK63 was necessary for high titers. Both nanoparticles and microparticles are promising delivery systems.     

Immunoadsorption of Alloantibodies onto Erythroid Membrane Antigens Encapsulated into Polymeric Microparticles

Purpose Classical immunoadsorbents used for the removal of deleterious molecules in blood such as auto-antibodies are prepared by covalent coupling of antigens onto previously chemically activated supports. Such a chemical treatment may induce a potential toxicity which can be reduced if new immunoadsorbents are prepared by encapsulating erythrocytes-ghosts carrying antigens inside polymeric and porous microparticles. Materials and Methods Erythrocyte-ghosts obtained by hemolysis in hypotonic buffer were encapsulated into ethylcellulose microparticles by w/o/w emulsification. The porosity of microparticles was evaluated by mercury porosimetry. The adsorption ability of encapsulated antigens was evaluated by hemagglutination after contact in tube or elution in column with polyclonal antibody solutions or human blood-plasma. Results The encapsulation process did not significantly alter the evaluated antigens since a significant decrease in anti-A (from 256 to 4) as well as anti-Kell (from 64 to 2) antibody titer has been observed in column after eight chromatographic runs (2 h). The higher the ghost concentration (total protein content of 6 mg/ml), the higher the adsorption capacity. Conclusion Encapsulation, currently used for drug delivery purposes, may consequently also be applied to the design of new immunoadsorbents as biomaterials. In memoriam of Nathalie Ubrich (deceased on April 24, 2007)     

Effect of the strength of adsorption of HIV 1 SF162dV2gp140 to aluminum-containing adjuvants on the immune response

The importance of the strength of antigen adsorption by aluminum-containing adjuvants on immunopotentiation was studied using HIV 1 SF162dV2gp140 (gp140), a potential HIV/AIDS antigen. The strengths of adsorption by aluminum hydroxide (AH) adjuvant and aluminum phosphate adjuvant, as measured by the Langmuir adsorptive coefficient, were 1900 and 400 mL/mg, respectively. The strength of adsorption by AH was modified by pretreatment of AH with two different concentrations of potassium dihydrogen phosphate to produce phosphate-treated aluminum hydroxide adjuvants having adsorptive coefficients of 1200 and 800 mL/mg. The four adjuvants were used to prepare vaccines containing either 1 or 10 μg of gp140 per dose. Antibody studies in mice revealed that the presence of an adjuvant increased the immune response in comparison with a solution of gp140 when the dose was 1 μg. Furthermore, the immune response was inversely related to the adsorptive coefficient. In contrast, no significant difference in immunopotentiation was observed between treatments in the presence or absence of an adjuvant when the dose of gp140 was 10 μg. Analysis of the binding of gp140 to CD4 and anti-gp140 monoclonal antibodies by surface plasmon resonance suggests that tight binding induced structural changes in the antigen.     

Glycosaminoglycans and protein disulfide isomerase-mediated reduction of HIV Env

Conformational changes within the human immunodeficiency virus-1 (HIV-1) surface glycoprotein gp120 result from binding to the lymphocyte surface receptors and trigger gp41-mediated virus/cell membrane fusion. The triggering of fusion requires cleavage of two of the nine disulfide bonds of gp120 by a cell-surface protein disulfide-isomerase (PDI). Soluble glycosaminoglycans such as heparin and heparan sulfate bind gp120 via V3 and, possibly, a CD4-induced domain. They exert anti-HIV activity by interfering with the HIV envelope glycoprotein (Env)/cell-surface interaction. Env also binds cell-surface glycosaminoglycans. Here, using surface plasmon resonance, we observed an inverse relationship between heparin binding by gp120 and its thiol content. In vitro, and in conditions in which gp120 could bind CD4, heparin and heparan sulfate reduced PDI-mediated gp120 reduction by approximately 80%. Interaction of Env with the surface of lymphocytes treated using sodium chlorate, an inhibitor of glycosaminoglycan synthesis, led to gp120 reduction. We conclude that besides their capacity to block Env/cell interaction, soluble glycosaminoglycans can effect anti-HIV activity via interference with PDI-mediated gp120 reduction. In contrast, their presence at the cell surface is dispensable for Env reduction during the course of interaction with the lymphocyte surface. This work suggests that the reduction of exofacial proteins in various diseases can be inhibited by compounds targeting the substrates (not by targeting PDI, as is usually done), and that glycosaminoglycans that primarily protect proteins by preserving them from proteolysis also have a role in preventing reduction.     

Improving Protein Delivery from Microparticles Using Blends of Poly(DL lactide co-glycolide) and Poly(ethylene oxide)-poly(propylene oxide) Copolymers

Purpose. Microparticles containing ovalbumin as a model for protein drugs were formulated from blends of poly(DL lactide-co-glycolide) and poly(ethylene oxide)-poly(propylene oxide) copolymers (Pluronic). The objectives were to achieve uniform release characteristics and improved protein delivery capacity. Methods. The water- in oil -in oil emulsion/solvent extraction technique was used for microparticle production. Results. A protein loading level of over 40% (w/w) was attained in microparticles having a mean diameter of approximately 5 µm. Linear protein release profiles over 25 days in vitro were exhibited by certain blend formulations incorporating hydrophilic Pluronic F127. The release profile tended to plateau after 10 days when the more hydrophobic Pluronic L121 copolymer was used to prepare microparticles. A delivery capacity of 3 µg OVA/mg particles/ day was achieved by formulation of microparticles using a 1:2 blend of PLG:Pluronic F127. Conclusions. The w/o/o formulation approach in combination with PLG:Pluronic blends shows potential for improving the delivery of therapeutic proteins and peptides from microparticulate systems. Novel vaccine formulations are also feasible by incorporation of Pluronic L121 in the microparticles as a co-adjuvant.     

Detection of functional galactosylceramide (GalCer) receptors on CD4-negative HIV-1 target cells

Summary HIV-1 infection in CD4-negative cells is now a well-established alternative route of infection for several cell types, including mucosal epithelial cells. Among different proposed mechanisms for HIV-1 entry into CD4-negative cells, the glycosphingolipid galactosylceramide (GalCer) has been characterized as a specific receptor for the surface envelope glycoprotein gp120 in cell lines of neural and epithelial origin. In this report we describe a protocol for identifying the GalCer receptor on the surface of CD4-negative cells. The development of this assay has been motivated by the unavailability of GalCer-specific antibodies, rendering the unambiguous immunological detection of this glycolipid on the cell surface impossible. For instance, we show that the commercially available anti-GalCer mAb (the R-mAb) can bind to the surface of both GalCer-positive and GalCer-negative human colon epithelial cell lines. This lack of specificity is due to a cross-reaction with several intestinal glycolipids that are not recognized by gp120. By contrast, gp120 only binds to the surface of GalCer-positive colon cells and the binding is specifically abolished by the R-mAb, as well as by compounds previously characterized as inhibitors of the GalCer-gp120 interaction. The specificity of gp120 binding was further demonstrated by incorporating sulfatide (the sulfated derivative of GalCer) in the membrane of GalCer-negative cells: in this case, gp120 binding was easily detectable by indirect immunofluorescence. Based on these data, we suggest the following protocol for assessing the expression of functional GalCer/sulfatide receptors on the surface of CD4-negative cells: (i) binding of gp120 revealed by indirect immunofluorescence; and (ii) inhibition of gp120 binding by the R-mAb. This would be preferable to using the R-mAb directly as a probe for GalCer/sulfatide expression.     

Guanine-rich oligonucleotide modified at the 5′ terminal by dimethoxytrityl residue inhibits HIV-1 replication by specific interaction with the envelope glycoprotein

Previous studies have shown that a guanine-rich oligonucleotide SA-1042, DmTr-TGGGAGGTGGGTCTG, neutralizes HIV-1 infectivity, blocks syncytium formation and inhibits the binding of recombinant gp120 to immobilized soluble CD4 in vitro (Furukawa et al., 1994). We have now investigated the precise mode of action of SA-1042. We show here that SA-1042 specifically antagonizes the binding of anti-V3 loop antibodies or anti-CD4 binding-site antibodies to recombinant gp120, and also blocks the binding of an anti-V3 loop antibody to the V3 peptide (gp120_HIB: aa302-324). In contrast, SA-1042 does not inhibit gp120 binding of monoclonal antibodies directed to other regions of gp120, such as the conserved N-terminal regions (gp120_HIB: aa35-108 or gp120_HIB: aa72-130) or the C-terminal region (gp120_HIB: aa481-496). Furthermore, SA-1042 does not interfere with the binding of monoclonal antibodies directed to other molecules, gp41, CD4, CD11a, CD18, CD26, CD44 or CD54. These data suggest that SA-1042 exerts its antiviral effects by targeting the V3 loop as well as the CD4 binding site on gp120.