Characterization of human immunodeficiency virus type 1 resistant to modified cyclodextrin sulphate (mCDS71) in vitro

Drug resistance of human immunodeficiency virus type 1 (HIV) to modified cyclodextrin sulphate (mCDS71) has been analysed with respect to both the in vitro appearance of resistance to the compound and the mechanism of the acquisition of resistance. Resistant strains could be obtained in all three strains (NL432, KK-1 and A018) tested after serial passages in MT-4 cells with a gradual increase of the concentration of mCDS71. Cross-resistance both to mCDS71 and dextran sulphate 8000 was observed. As a result of sequencing analysis of the gp120 V3-C5 region of resistant strains, the mechanism of resistance can be explained in several ways: (i) substitution of sugar chain-binding amino acids, N and S; (ii) three to five amino acid deletion in V4 loop; and (iii) several mutations in V3 and V4 regions. The real cause of the resistance may be a combination of these three mechanisms. The results suggest that the target of mCDS71 is relatively widely distributed on the viral surface glycoprotein.

Respiratory syncytial virus (RSV) disease and prospects for its control

Respiratory syncytial virus (RSV) is a major virus pathogen of infants and young children, an important cause of disease in adults and is responsible for a significant amount of excess morbidity and mortality in the elderly. It also can be devastating in immunosuppressed populations. Vaccines are being developed, but none are currently licensed. Moreover, even if one or more are approved, they may not be suitable for some populations vulnerable to RSV (e.g. very young infants and the immunosuppressed). Ribavirin and immunoglobulin preparations with high titers of RSV-specific neutralizing antibodies are currently approved for use to treat and prevent RSV infection. However, neither of these is cost-effective or simple to administer. New agents are needed to reduce the impact of RSV. This review is concerned with the means currently available for controlling RSV, the search for new agents effective against this virus, and future prospects for preventing and treating RSV infections.

The basic domain in HIV-1 Tat protein as a target for polysulfonated heparin-mimicking extracellular Tat antagonists

Heparin binds extracellular HIV-1 Tat protein and modulates its HIV long terminal repeat (LTR)-transactivating activity (M. Rusnati, D. Coltrini, P. Oreste, G. Zoppetti, A. Albini, D. Noonan, F. d'Adda di Fagagna, M. Giacca, and M. Presta (1997) J. Biol. Chem. 272, 11313-11320). On this basis, the glutathione S-transferase (GST)-TatR49/52/53/55/56/57A mutant, in which six arginine residues within the basic domain of Tat were mutagenized to alanine residues, was compared with GST-Tat for its capacity to bind immobilized heparin. Dissociation of the GST-TatR49/52/53/55/56/57A.heparin complex occurred at ionic strength significantly lower than that required to dissociate the GST-Tat.heparin complex. Accordingly, heparin binds immobilized GST-Tat and GST-TatR49/52/53/55/56/57A with a dissociation constant equal to 0.3 and 1.0 microM, respectively. Also, the synthetic basic domain Tat-(41-60) competes with GST-Tat for heparin binding. Suramin inhibits [3H]heparin/Tat interaction, 125I-GST-Tat internalization, and the LTR-transactivating activity of extracellular Tat in HL3T1 cells and prevents 125I-GST-Tat binding and cell proliferation in Tat-overexpressing T53 cells. The suramin derivative 14C-PNU 145156E binds immobilized GST-Tat with a dissociation constant 5 times higher than heparin and is unable to bind GST-TatR49/52/53/55/56/57A. Although heparin was an antagonist more potent than suramin, modifications of the backbone structure in selected suramin derivatives originated Tat antagonists whose potency was close to that shown by heparin. In conclusion, suramin derivatives bind the basic domain of Tat, prevent Tat/heparin and Tat/cell surface interactions, and inhibit the biological activity of extracellular Tat. Our data demonstrate that tailored polysulfonated compounds represent potent extracellular Tat inhibitors of possible therapeutic value.

The system of sulfated alpha-(1-->3)-linked D-mannans from the red seaweed Nothogenia fastigiata: structures, antiherpetic and anticoagulant properties

Structural analysis of two xylomannans extracted from Nothogenia fastigiata was carried out. The results are consistent with the general pattern previously reported for other xylo-mannans of the same system, alpha-(1-->3)-linked D-mannans 2- and 6-sulfated and having single stubs of beta-(1-->2)-linked D-xylose, but one of the new samples contains a significant amount of 2,6-disulfated units. Both xylomannans studied are obtained as complexes with a beta-D-(1-->3)-, alpha-L-(1-->4)-galactan and a beta-D-(1-->3)-, beta-D-(1-->4)-'mixed linkage' xylan co-existing in the seaweed, a fact that limits the accuracy of the data determined. The structures of the galactan and the xylan are similar to those previously informed for this seaweed. The antiviral activity against four different herpes simplex viral strains and the anticoagulant properties of all the xylo-mannans of the system are reported.

Sulfated polysaccharides extracted from sea algae as potential antiviral drugs

The inhibitory effects of polyanionic substances on the replication of herpes simplex virus (HSV) and other viruses were reported almost four decades ago. However, these observations did not generate much interest, because the antiviral action of the compounds was considered to be largely nonspecific. Shortly after the identification of human immunodeficiency virus (HIV) as the causative agent of the acquired immune deficiency syndrome (AIDS) in 1984, heparin and other sulfated polysaccharides were found to be potent and selective inhibitors of HIV-1 replication in cell culture. Since 1988, the activity spectrum of the sulfated polysaccharides has been shown to extend to various enveloped viruses, including viruses that emerge as opportunistic pathogens (e.g., herpes simplex virus [HSV] and cytomegalovirus [CMV]) in immunosuppressed (e.g., AIDS) patients. As potential anti-HIV drug candidates, sulfated polysaccharides offer a number of promising features. They are able to block HIV replication in cell culture at concentrations as low as 0.1 to 0.01 microgram ml-1 without toxicity to the host cells at concentrations up to 2.5 mg ml-1. We noted that some polysulfates show a differential inhibitory activity against different HIV strains, suggesting that marked differences exist in the target molecules with which polysulfates interact. They not only inhibit the cytopathic effect of HIV, but also prevent HIV-induced syncytium (giant cell) formation. Furthermore, experiments carried out with dextran sulfate samples of increasing molecular weight and with sulfated cyclodextrins of different degrees of sulfation have shown that antiviral activity increases with increasing molecular weight and degree of sulfation. A sugar backbone is not strictly needed for the anti-HIV activity of polysulfates because sulfated polymers composed of a carbon-carbon backbone have also proved to be highly efficient anti-HIV agents in vitro. Other, yet to be defined, structural features may also play an important role. Sulfated polysaccharides may act synergistically with other anti-HIV drugs (e.g., azidothymidine [AZT]). They are known to lead very slowly to virus-drug resistance development and they show activity against HIV mutants that have become resistant to reverse transcriptase inhibitors, such as AZT, tetrahydro-imidazo [4,5,l-jk] [1,4]-benzodiazepin-2(1H)-thione (TIBO) and others. From studies on their mechanism of action we concluded that polysulfates exert their anti-HIV activity by shielding off the positively charged sites in the V3 loop of the viral envelope glycoprotein (gp120). The V3 loop is necessary for virus attachment to cell surface heparan sulfate, a primary binding site, before more specific binding occurs to the CD4 receptor of CD4+ cells. This general mechanism also explains the broad antiviral activity of polysulfates against enveloped viruses. Variations in the viral envelope glycoprotein region may result in differences in the susceptibility of different enveloped viruses to compounds that interact with their envelope glycoproteins. The efficacy of polysulfates in the therapy and/or prophylaxis of retroviral infections and opportunistic infections remains to be demonstrated both in animal models and humans. It is important to consider not only treatment of patients who are already infected with HIV, but also prophylaxis and protection from HIV and/or other virus infections. Because (i) sexual transmission is responsible for the large majority of HIV infections worldwide; (ii) this transmission is mostly mediated via mononuclear cells that infect epithelial cells of the genital tract; and because (iii) polysulfates effectively inhibit cell-cell adhesion, polysulfates may be considered as potentially effective in a vaginal formulation to protect against HIV infection.

Inhibition of sandfly fever Sicilian virus (Phlebovirus) replication in vitro by antiviral compounds

Sandfly fever Sicilian virus (SFSV) was used in our laboratory to screen antiviral substances active toward viruses of the Bunyaviridae family. Antiviral activity was estimated by the reduction of the cytopathic effect of SFSV on infected Vero cells. Cytotoxicity was evaluated by determining the inhibition of Trypan blue exclusion. The specificity of action of each tested compound was estimated by the selectivity index (CD50/ED50). Selectivity indices of human recombinant interferon-alpha (IFN alpha) (Roferon and Introna), iota-, kappa- and lambda- carrageenans, fucoidan and 6-azauridine were much higher than that of ribavirin, the only antiviral substance which has been previously investigated for its inhibitory effects on Phlebovirus infections. Other compounds showed significant antiviral activity: glycyrrhizin, suramin sodium, dextran sulphate and pentosan polysulphate. All these compounds caused a concentration-dependent reduction in the virus yield. Ribavirin, 6-azauridine and IFN alpha have been shown to inhibit a late step of the virus replicative cycle, whereas glycyrrhizin and suramin sodium were active at an early step and the sulphated polysaccharides inhibited adsorption of SFSV on the cells. The antiviral compounds selected in this study as specific inhibitors of in vitro replication of SFSV are promising candidates for the chemotherapy of haemorrhagic fevers caused by viruses of the Bunyaviridae family. The combination of IFN alpha and ribavirin, which showed a synergistic antiviral effect, should be evaluated for the treatment of these infections.

The in vitro anti-HIV efficacy of negatively charged human serum albumin is antagonized by heparin

Succinylated human serum albumin (Suc-HSA) was synthesized by treating human serum albumin with succinic anhydride. Among similar proteins and neo(glyco)proteins tested, Suc-HSA exhibits a pronounced net negative charge, a feature that largely contributes to its efficacy against replication of human immunodeficiency virus type 1 (HIV-1). To assess further the antiviral effect of Suc-HSA, the effect on HIV-1 replication was studied in the presence of whole human plasma. Pretreatment of MT2 cells with Suc-HSA was more efficacious than direct Suc-HSA treatment of HIV prior to addition to the cells. No changes in the antiviral effect of Suc-HSA were observed in tissue culture medium, 30% plasma, or whole plasma when CPDA-1 (citrate-phosphate-dextrose-adenine 1) was used as the anticoagulant. However, a dramatic decrease (greater than 99%) in the antiviral activity was observed when these experiments were performed in plasma prepared from blood using heparin as anticoagulant. The antagonistic effect by heparin was observed both in the case that heparin was added prior to or after addition of Suc-HSA to the test system. In the present study we demonstrate that heparin largely reduces Suc-HSA activity on HIV replication in the same concentration in which if affects binding of Suc-HSA to the envelope protein gp120 and in particular its V3 domain. In the same concentration range, heparin reduced binding of Suc-HSA to MT4 cells, another HTLV-I-transformed cell line. It is concluded that heparin can displace Suc-HSA from its binding sites on hybrid lymphoid cells as well as on HIV-1 particles. Therefore, we conclude that both the binding to cells and to virus contribute to the potent anti-HIV-1 effect. The fact that heparin and heparin degradation products antagonize Suc-HSA without having a significant anti-HIV-1 effect indicates that the anticoagulant acts as a relatively weak partial inhibitor.

The multiple inhibitory mechanisms of GEM 91, a gag antisense phosphorothioate oligonucleotide, for human immunodeficiency virus type 1

GEM 91 (gene expression modulator) is a 25-mer oligonucleotide phosphorothioate complementary to the gag initiation site of HIV-1. GEM 91 has been studied in various in vitro cell culture models to examine inhibitory effects on different stages of HIV-1 replication. Experiments were focused on the binding of virions to the cell surface, inhibition of virus entry, reverse transcription (HIV DNA production), inhibition of steady state viral mRNA levels, inhibition of virus production from chronically infected cells, and inhibition of HIV genome packaging within virions. Experiments were also performed in vitro in an attempt to generate strains of HIV with reduced sensitivity to GEM 91. We observed sequence-dependent inhibition of virus entry/reverse transcription and a reduction in steady state viral RNA levels. We also observed sequence-independent inhibition of virion binding to cells and inhibition of virus production by chronically infected cells. Using in vitro methods that were successful in generating HIV strains with reduced sensitivity to AZT, we were unable to generate strains with reduced sensitivity to GEM 91.

Antiherpetic and anticoagulant properties of carrageenans from the red seaweed Gigartina skottsbergii and their cyclized derivatives: correlation between structure and biological activity

The antiviral activity against herpes simplex virus types 1 and 2 of kappa/l-, partially cyclized mu/v-, and lambda-carrageenans isolated from the red seaweed Gigartina skottsbergii and their cyclized derivatives was analyzed. lambda-Carrageenans and the partially cyclized mu/v-carrageenan were the most potent inhibitors of herpes viruses (including acyclovir-resistant variants and clinical isolates), with IC50 values lower than 1 microgram ml-1 against both serotypes and selectivity indices higher than 10(3). kappa/l-Carrageenans were slightly less effective than the other two types with IC50 values in the range 1.6-4.1 micrograms ml-1. Antiherpetic activity was directly correlated to the amount of alpha-D-galactose 2,6-disulfate residues in the natural carrageenans. The cyclization of the alpha-D-galactose 6-sulfate and 2,6-disulfate units into 3,6-anhydro-alpha-D-galactose and 3,6-anhydro-alpha-D-galactose 2-sulfate residues in these polysaccharides, in general, lowers the antiherpetic activity of the derivatives with respect to the natural carrageenans. Some carrageenans showed a very reduced anticoagulant activity only at concentrations that were considerably higher than the IC50, whereas others were totally devoid of anticoagulant properties. Among natural carrageenans, the mu/v-type IC3 shows the best relationship between antiviral efficacy and lack of anticoagulant action, resulting a very promising compound.

A natural sulfated polysaccharide, calcium spirulan, isolated from Spirulina platensis: in vitro and ex vivo evaluation of anti-herpes simplex virus and anti-human immunodeficiency virus activities

A sulfated polysaccharide named calcium spirulan (Ca-SP) has been isolated from a sea alga, Spirulina platensis, as an antiviral component. The anti-human immunodeficiency virus type 1 (HIV-1) and anti-herpes simplex virus type 1 (HSV-1) activities of Ca-SP were compared with those of dextran sulfate (DS) as a representative sulfated polysaccharide. Anti-HIV-1 activities of these agents were measured by three different assays: viability of acutely infected CD4-positive cells, or a cytopathology assay; determination of HIV-1 p24 antigen released into culture supernatants; and inhibition of HIV-induced syncytium formation. Anti-HSV-1 activity was assessed by plaque yield reduction. In addition, their effects on the blood coagulation processes and stability in the blood were evaluated. These data indicate that Ca-SP is a potent antiviral agent against both HIV-1 and HSV-1. Furthermore, Ca-SP is quite promising as an anti-HIV agent because even at low concentrations of Ca-SP an enhancement of virus-induced syncytium formation was not observed, as was observed in DS-treated cultures, Ca-SP had very low anticoagulant activity, and showed a much longer half-life in the blood of mice when compared with that of DS. Thus, Ca-SP can be a candidate agent for an anti-HIV therapeutic drug that might overcome the disadvantages observed in many sulfated polysaccharides. When the role of chelation of calcium ion with sulfate groups was examined by removing calcium or its replacement by sodium, the presence of calcium ion in the molecule was shown to be essential for the dose-dependent inhibition of cytopathic effect and syncytium formation induced by HIV-1.

Antiviral effects of milk proteins: acylation results in polyanionic compounds with potent activity against human immunodeficiency virus types 1 and 2 in vitro

A number of native and modified milk proteins from bovine or human sources were analyzed for their inhibitory effects on human immunodeficiency virus type 1 (HIV-1) and HIV-2 in vitro in an MT4 cell test system. The proteins investigated were lactoferrin, alpha-lactalbumin, beta-lactoglobulin A, and beta-lactoglobulin B. By acylation of the amino function of the lysine residues in the proteins, using anhydrides of succinic acid or cis-aconitic acid, protein derivatives were obtained that all showed a strong antiviral activity against human immunodeficiency virus type 1 and/or 2. The in vitro IC50 values of the aconitylated proteins were in the concentration range of 0.3 to 3 nM. Succinylation or aconitylation of alpha-lactalbumin and beta-lactoglobulin A/B also produced strong anti-HIV-2 activity with IC50 values on the order 500 to 3000 nM. All compounds showed virtually no cytotoxicity at the concentration used. Peptide-scanning studies indicated that the native lactoferrin as well as the charged modified proteins strongly bind to the V3 loop of the gp120 envelope protein, with Kd values in the same concentration range as the above-mentioned IC50. Therefore, shielding of this domain, resulting in inhibition of virus-cell fusion and entry of the virus into MT4 cells, may be the likely underlying mechanism of antiviral action.

Mechanism of anti-HIV activity of negatively charged albumins: biomolecular interaction with the HIV-1 envelope protein gp120

A novel class of polyanionic proteins with potent anti-human immunodeficiency virus type 1 activity, the negatively charged albumins (NCAs), have been reported previously. In vitro antiviral assays established that these compounds preferentially inhibit virus-cell fusion and syncytium formation and that virus-cell binding is less affected. Here the interaction of the NCAs with synthetic peptides composed of 15-36 amino acids and corresponding to different parts of the gp120 envelope protein is described. Among the gp120 peptides tested, binding of the NCAs was observed only with the s0-called V3 loop (amino acids 296-330) and the C-terminal part of gp120. A higher number of negatively charged residues in the albumins resulted in higher binding affinities. NCAs in which, in addition to negative charges, up to 7 or 14 lactose or mannose groups were introduced, respectively did not exhibit increasing binding affinity. In contrast, mannosylated albumin containing about 14 mannose groups showed an increased binding compared with native albumin. Binding of the NCAs to the V3 and C-terminal oligopeptide was competitively inhibited by sulfated polysaccharide heparin and dextran sulfate. This finding indicates that the binding between the gp120 peptides and the NCAs is likely caused by electrostatic interactions. However, the fact that the dissociation constants of dextran sulfate and heparin are orders of magnitude larger compared with the NCAs indicates that the spatial structure of the proteins and/or hydrophobic interactions between the NCAs and the envelope protein may also be involved.

Antiviral activity of the bicyclam derivative JM3100 against drug-resistant strains of human immunodeficiency virus type 1

Bicyclams have recently been identified as potent and selective inhibitors of human immunodeficiency virus type 1 (HIV-1) and type 2 (HIV-2) replication. The prototype of this series, JM3100 exhibits anti-HIV potency at concentrations ranging from 0.001 to 0.01 micrograms/ml. JM3100 proved to be active when tested against HIV strains resistant to the reverse transcriptase (RT) inhibitors 3'-azido-3'-deoxythymidine (AZT), 2',3'-dideoxyinosine (DDI), 3TC, alpha APA and TIBO, at roughly the same concentrations as for the wild-type strain. The virus was passaged in vitro in the presence of increasing concentrations of either TIBO or alpha APA alone or in combination with JM3100. The combination between TIBO, or alpha APA, and JM3100 delayed the development of TIBO- and alpha APA-resistant strains, without emergence of resistance to JM3100. In separate experiments, it took more than 60 passages (300 days) in MT-4 cells and 20 passages (140 days) in peripheral blood lymphocyte (PBL) cells for the virus to become resistant to JM3100. The JM3100-resistant virus showed cross-resistance to sulfated polysaccharides such as dextran sulfate (DS), pentosan sulfate (PS), heparin and cyclodextrin sulfate (CDS), suggesting that these compounds may share a common mechanism of action. Furthermore, the inhibitory effect of JM3100 on virus-induced syncytium formation was enhanced in the presence of heparin. The results presented here provide further support for the bicyclams as attractive candidate drugs for the chemotherapy of HIV infections.

Protein-glycosaminoglycan interactions: infectiological aspects

Glycosaminoglycans (GAGs) are linear heteropolysaccharides consisting of repeated disaccharide units that are variably N- and O-sulfated. Due to this heterogeneity, GAGs possess a high amount of structural information. Linked to a protein core to form a proteoglycan, GAGs are present on the surface of probably all mammalian tissues. During the recent years, a number of pathogens ranging from viruses to protozoans were found to interact specifically with cell surface GAGs to recognize and bind to their target cells. This review is intended to give a short overview over protein-GAG interaction under the aspects of infection.

Chemotherapy of human immunodeficiency virus (HIV) infection: anti-HIV agents targeted at early stages in the virus replicative cycle

Several compounds have been identified that inhibit an early stage in the replicative cycle of the human immunodeficiency virus (HIV): i) virus adsorption: polysulfates, polysulfonates, polycarboxylates, polyphosphates, and polyoxometalates; or ii) virus-cell fusion: plant lectins, negatively charged albumins and betulinic acid derivatives; iii) virus fusion/uncoating: bicyclam derivatives; iv) reverse transcription: dideoxynucleoside analogues, acyclic nucleoside phosphonates and non-nucleoside reverse transcriptase inhibitors. In principle, HIV may develop resistance to any of these specific anti-HIV agents. However, virus breakthrough can be completely prevented if these agents, alone or in combination, are added to the HIV-infected cells from the beginning at sufficiently high ('knock-out') concentrations.

Structural analysis of antiviral sulfated alpha-D-(1-->3)-linked mannans

The structures of two alpha-(1-->3)-alpha-D-xylo-mannans were determined. The different antiviral activity of the xylo-mannans from Nothogenia fastigiata was explained on the basis of a flexible backbone, molecular size, content and distribution of sulfate groups and of the single stubs of beta-(1-->2)-linked D-xylose.