Many viruses display affinity for cell surface heparan sulfate proteoglycans with biological relevance in virus entry. This raises the possibility of the application of sulfated polysaccharides in antiviral therapy.
Methods:
In this study, we analysed polysaccharide fractions isolated from Sebdenia polydactyla.
Results:
The purified xylomannan sulfate and its further sulfated derivatives showed strong activity against herpes simplex virus type-1 (HSV-1). Their 50% inhibitory concentration values were in the range 0.35–2.8 µg/ml and they lacked cytotoxicity at concentrations up to 1,000 µg/ml. The major polysaccharide, which had 0.6 sulfate groups per monomer unit and an apparent molecular mass of 150 kDa, contained a backbone of α-(1→3)-linked D-mannopyranosyl residues substituted at position 6 with a single stub of ß-D-xylopyranosyl residues.
Conclusions:
The degree of sulfation seemed to play an important role because desulfation and/or further sulfation of the isolated macromolecules largely influenced their in vitro anti-HSV-1 activity.
References
1.
AradSMGinzbergAHuleihelM. Antiviral activity of sulfated polysaccharides of marine red algae. In FingermanMNagabhusanR (Editors). Biomaterials from Aquatic and Terrestrial Organizations. Enfield, NH: Science Publishers2006; pp. 37–62.
2.
DamonteEBMatulewiczMCCerezoAS. Sulfated seaweed polysaccharides as antiviral agents. Curr Med Chem2004; 11: 2399–2419.
3.
WitvrouwMDe ClercqE. Sulfated polysaccharides extracted from sea algae as potential antiviral drugs. Gen Pharmacol1997; 29: 497–511.
4.
BalzariniJVan DammeL. Microbicide drug candidate to prevent HIV infection. Lancet2007; 369: 787–797.
5.
KilmarxPHvan de WijgertJHHMChaikummaoS. Safety and acceptability of the candidate microbicide carraguard in Thai women findings from a Phase II clinical trial. J Acquir Immune Defic Syndr2006; 43: 327–334.
6.
NikolicDSGarciaEPiguetV. Microbicides and other topical agents in the prevention of HIV and sexually transmitted infections. Expert Rev Anti Infect Ther2007; 5: 77–88.
7.
KleymannG. Agents and strategies in development for improved management of herpes simplex virus infection and disease. Expert Opin Investig Drugs2005; 14: 135–161.
8.
PujolCACarlucciMJMatulewiczMCDamonteEB. Natural sulfated polysaccharides for the prevention and control of viral infections. Top Hetero Chem2007; 11: 259–281.
9.
GhoshTChattopadhyayKMarschallMKarmakarPMandalPRayB. Focus on antivirally active sulfated polysaccharides: From structure-activity analysis to clinical evaluation. Glycobiology2009; 19: 2–15.
10.
DuboisMGillesKAHamiltonJKRebersPASmithF. Colorimetric method for determination of sugars and related substances. Anal Chem1956; 28: 350–366.
11.
AhmedALabavitchJM. A simplified method for accurate determination of cell wall uronide content. J Food Biochem1977; 1: 361–365.
12.
BlakeneyABHarrisPHenryRJBruceAB. A simple rapid preparation of alditol acetates for monosaccharide analysis. Carbohydr Res1983; 113: 291–299.
13.
ChattopadhyayKMateuCGMandalPPujolCADamonteEBRayB. Galactan sulfate of Grateloupia indica: Isolation, structural features and antiviral activity. Phytochemistry2007; 68: 1428–1435.
14.
YorkWSDarvillAGO'NeilMStevensonTTAlbersheimP. Isolation and characterisation of plant cell walls and cell wall components. Methods Enzymol1986; 118: 3–40.
15.
CraigieJSWenZCvan der MeerJP. Interspecific, intraspecific and nutritionally-determined variations in the composition of agars from Gracilaria spp. Bot Mar1984; 27: 55–61.
16.
RochasCLahayeMYapheW. Sulfate content of carrageenan and agar determined by infrared spectroscopy. Bot Mar1986; 29: 335–340.
17.
FalshawRFurneauxRH. Structural analysis of carrageenans from the tetrasporic stages of the red algae Gigartina lanceata and Gigartina chapmanii (Gigartinaceae, Rhodophyta). Carbohydr Res1998; 307: 325–331.
18.
MandalPMateuCGChattopadhyayKPujolCADamonteEBRayB. Structural features and antiviral activity of sulfated fucans from the brown seaweed Cystoseira indica. Antivir Chem Chemother2007; 18: 153–162.
19.
ChattopadhyayKGhoshTPujolCACarlucciMJDamonteEBRayB. Polysaccharides from Gracilaria corticata: Sulfation, chemical characterization and anti-HSV activities. Int J Biol Macromol2008; 43: 346–351.
20.
FrySC. The growing plant cell wall: Chemical and metabolic analysis. Essex: Longman Scientific and Technical, Longman Group UK Limited1988; pp. 333.
21.
StevensonTTFurneauxRH. Chemical methods for the analysis of sulphated galactans from red algae. Carbohydr Res1991; 210: 277–298.
22.
BlakeneyABStoneBA. Methylation of carbohydrates with lithium methylsulphinyl carbanion. Carbohydr Res1985; 140: 319–324.
23.
RayB. Polysaccharides from Enteromorpha compressa: Isolation, purification and structural features. Carbohydr Polym2006; 66: 408–416.
MandalPPujolCACarlucciMJChattopadhyayKDamonteEBRayB. Sulfated xylomannan of Scinaia hetai: Isolation, structural features and antiviral activity. Phytochemistry2008; 69: 2193–2199.
26.
KolenderAAPujolCADamonteEBMatulewiczMCCerezoAS. The system of sulfated α-(1→3)-linked D-mannans from the red seaweed Nothogenia fastigiata: Structures, antiherpetic and anticoagulant properties. Carbohydr Res1997; 304: 53–60.
27.
PercivalEWoldJK. The acid from green seaweed Ulva lactuca. Part II. The site of ester sulphate. J Chem Soc1963; 5459–5468.
HirstEMacKieWPercivalE. The water-soluble polysaccharides of Caldophora rupestris and of Chaetomorpha spp. Part II. The site of ester sulphate groups and the linkage between the galactose residues. J Chem Soc1965; 2958–2967.
30.
MazumderSGhosalPKPujolCACarlucciMJDamonteEBRayB. Isolation, chemical investigation and antiviral activity of polysaccharides from Gracilaria corticata (Gracilariaceae, Rhodophyta). Int J Biol Macromol2002; 31: 87–95.
31.
MatulewiczMCCerezoAS. Water-soluble sulfated polysaccharides from the red seaweed Chaetangium fastigiatum. Analysis of the system and the structures of the α-D-(1→3)-linked mannans. Carbohydr Polym1987; 7: 121–132.
32.
McReynoldsKDGervay-HagueJ. Chemotherapeutic interventions targeting HIV interactions with host-associated carbohydrates. Chem Rev2007; 107: 1533–1552.
33.
HeroldBCGerberSIBelvalBJSistonAMShulmanN. Differences in the susceptibility of herpes simplex virus type 1 and 2 to modified heparin compounds suggest serotype differences in viral entry. J Virol1996; 70: 3461–3469.
34.
CohenJ. Microbicide fails to prevent against HIV. Science2008; 319: 1026–1027.
35.
GrantRMHamerDHopeT. Whither or wither micobicides?Science2008; 321: 532–534.
36.
KlassePJShattockRMooreJP. Antiretorviral drug-based microbicides to prevent HIV-1 sexual transmission. Annu Rev Med2008; 59: 455–471.
37.
KilmarxPHKellyBSupapornC. A randomized, placebo-controlled trial to assess the safety and acceptability of use of Carraguard vaginal gel by heterosexual couples in Thailand. Sex Transm Dis2008; 35: 226–232.
38.
BollenLJMKellyBKilmarxPH. No increase in cervicovaginal proinflammatory cytokines after Carraguard use in a placebo-controlled randomized clinical trial. J Acquir Immune Defic Syndr2008; 47: 253–257.
39.
BracheVHoracioCRégineSW. Effect of a single vaginal administration of levonorgestrel in Carraguard® gel on the ovulatory process: A potential candidate for dual protection emergency contraception. Contraception2007; 76: 111–116.
40.
LiuSLuHNeurathARJiangS. Combination of candidate microbicides cellulose acetate 1,2-benzenedicarboxylate and UC781 has synergistic and complementary effects against human immunodeficiency virus type-1 infection. Antimicrob Agents Chemother2005; 49: 1830–1836.
