The brown algae Padina gymnospora contain different fucans. Powdered algae were submitted to proteolysis with the proteolytic enzyme maxataze. The first extract of the algae was constituted of polysaccharides contaminated with lipids, phenols, etc. Fractionation of the fucans with increasing concentrations of acetone produced fractions with different proportions of fucose, xylose, uronic acid, galactose, and sulfate. One of the fractions, precipitated with 50% acetone (v/v), contained an 18-kDa heterofucan (PF1), which was further purified by gel-permeation chromatography on Sephadex G-75 using 0.2 M acetic acid as eluent and characterized by agarose gel electrophoresis in 0.05 M 1,3 diaminopropane/acetate buffer at pH 9.0, methylation and nuclear magnetic resonance spectroscopy. Structural analysis indicates that this fucan has a central core consisting mainly of 3-ß-D-glucuronic acid 1-> or 4-ß-D-glucuronic acid 1 ->, substituted at C-2 with alpha-L-fucose or ß-D-xylose. Sulfate groups were only detected at C-3 of 4-alpha-L-fucose 1-> units. The anticoagulant activity of the PF1 (only 2.5-fold lesser than low molecular weight heparin) estimated by activated partial thromboplastin time was completely abolished upon desulfation by solvolysis in dimethyl sulfoxide, indicating that 3-O-sulfation at C-3 of 4-alpha-L-fucose 1-> units is responsible for the anticoagulant activity of the polymer.
Fucan; Anticoagulant activity; Sulfated polysaccharides; Brown algae; Padina gymnospora
Braz J Med Biol Res, April 2005, Volume 38(04) 523-533
Partial characterization and anticoagulant activity of a heterofucan from the brown seaweed Padina gymnospora
T.M.A. Silva1, L.G. Alves3, K.C.S. de Queiroz1, M.G.L. Santos1, C.T. Marques1, S.F. Chavante1, H.A.O. Rocha2 and E.L. Leite1
Laboratórios de 1Glicobiologia and 2Biotecnologia de Polímeros Naturais, Departamento de Bioquímica, Universidade Federal do Rio Grande do Norte, Natal, RN, Brasil
3Departamento de Bioquímica, Escola Paulista de Medicina, Universidade Federal de São Paulo, São Paulo, SP, Brasil
Correspondence and Footnotes
The brown algae Padina gymnospora contain different fucans. Powdered algae were submitted to proteolysis with the proteolytic enzyme maxataze. The first extract of the algae was constituted of polysaccharides contaminated with lipids, phenols, etc. Fractionation of the fucans with increasing concentrations of acetone produced fractions with different proportions of fucose, xylose, uronic acid, galactose, and sulfate. One of the fractions, precipitated with 50% acetone (v/v), contained an 18-kDa heterofucan (PF1), which was further purified by gel-permeation chromatography on Sephadex G-75 using 0.2 M acetic acid as eluent and characterized by agarose gel electrophoresis in 0.05 M 1,3 diaminopropane/acetate buffer at pH 9.0, methylation and nuclear magnetic resonance spectroscopy. Structural analysis indicates that this fucan has a central core consisting mainly of 3-ß-D-glucuronic acid 1® or 4-ß-D-glucuronic acid 1 ®, substituted at C-2 with a-L-fucose or ß-D-xylose. Sulfate groups were only detected at C-3 of 4- a-L-fucose 1 ® units. The anticoagulant activity of the PF1 (only 2.5-fold lesser than low molecular weight heparin) estimated by activated partial thromboplastin time was completely abolished upon desulfation by solvolysis in dimethyl sulfoxide, indicating that 3-O-sulfation at C-3 of 4- a-L-fucose 1 ® units is responsible for the anticoagulant activity of the polymer.
Key words: Fucan, Anticoagulant activity, Sulfated polysaccharides, Brown algae, Padina gymnospora
Brown algae contain a wide variety of acid polysaccharides such as the alginic acids, consisting exclusively of uronic acid, the homo fucans, consisting of sulfated fucan, and the heterofucans, that contain portions of other neutral sugars and uronic acids in addition to sulfated fucose (1,2). In these cases, branches, a complex distribution of sulfate and occasionally acetyl groups may be observed (3,4).
All algal fucans have complex structures but recent studies have revealed ordered repeated units in homofucans from several species. These studies clearly show that several homofucans have large proportions of both a-(1 ®3) and a-(1 ®4) glycosidic linkages with sulfate groups at C-2, without excluding the presence of other sulfates, acetyl groups or branches at positions 2, 3 or 4 (5,6). Furthermore, little is known about the structural features of the heterofucans. Most of the difficulties of structural studies arise from the fact that these compounds are very heterogeneous, yielding complex nuclear magnetic resonance (NMR) spectra with broad signals and thereby interfering with resolution. In fact, for these algal polysaccharides even high-field NMR provides data of limited value, and complete descriptions of their structures are not available (7).
Since the first description of fucans from algae, these polysaccharides have been tested for biological activities in different mammalian systems. Algal fucans have anticoagulant/antithrombotic (5,8,9), anticomplement (10), antiproliferative (11), antiviral (12), and antiadhesive activities (13). However, the relationship between structure and biological activity of fucans has not been fully elucidated.
Several homofucans with demonstrated anticoagulant activity have been extracted from different brown seaweeds (5,14). However, there are only few reports of their mechanism of action. In general, the proposed mechanism is predominantly mediated by antithrombin and/or heparin co-factor II.
The composition of algal fucans varies according to species (15), extraction procedure (8), season of harvest, and local climatic conditions (2). Thus, each newly described fucan is a unique compound with unique structural features, consequently having the potential of being used as a novel drug.
On the basis of these considerations, the purpose of the present study was to obtain heterofucans from the seaweed Padina gymnospora, to compare their anticoagulant activity with heparin and low molecular weight heparin and to determine the structural requirement for anticoagulant activity.
Material and Methods
Chemicals of analytical grade were purchased from Quimis (São Paulo, SP, Brazil), Vetec (São Paulo, SP, Brazil) and Merck (São Paulo, SP, Brazil). Chondroitin 4-sulfate was purchased from Miles Laboratories (Elkhart, IN, USA). Propylenediamine (1,3-diaminopropane) was purchased from Aldrich (Milwaukee, WI, USA). Heparan sulfate, dermatan sulfate, glucose, glucuronic acid, xylose, fucose, galactose, and mannose were purchased from Sigma (St. Louis, MO, USA). Standard Low-mr agarose was purchased from BioRad (Richmond, CA, USA). Heparin from bovine lung (175 IU) was a gift from Dr. Carl Peter von Dietrich, Department of Biochemistry, UNIFESP.
Extraction and purification
The marine alga Padina gymnospora was collected along the southern coast of Natal, RN, Brazil. Immediately after collection, the algae were identified by Dr. Heliane Marinho from Centro de Biociências/UFRN, Natal, RN, Brazil. The algae were stored in our laboratories and dried at 50ºC under ventilation in an oven, ground in a blender and incubated with acetone to eliminate lipids and pigments. About 50 g of powdered algae was suspended with 5 volumes of 0.25 M NaCl and the pH was adjusted to 8.0 with NaOH. Ten milligrams maxataze, an alkaline protease from Esporobacillus (BioBrás, Montes Claros, MG, Brazil), was then added to the mixture for proteolytic digestion. After incubation for 24 h at 60ºC under shaking and periodical adjustments of pH, the mixture was filtered through cheesecloth and precipitated with 0.3 volumes of ice-cold acetone under gentle shaking at 4ºC. The solution was left to stand at the same temperature for an additional 24 h. The precipitate formed was collected by centrifugation at 10,000 g for 20 min, dried under vacuum, resuspended in distilled water, and analyzed. Acetone at 0.5, 0.8, 1.0 and 1.5 volumes, calculated from the initial solution, was added to the supernatant and precipitated as described above. Five fractions were obtained and were named according to the volumes of acetone used. The fraction precipitated with 1.0 volume of acetone was subjected to gel-permeation chromatography on Sephadex G-75 (120 x 1.8 cm), using 0.2 M acetic acid as eluent. The elution was monitored for uronic acid (16) and total sugar (17). The polysaccharides eluted were dialyzed against water, freeze-dried and used in the anticoagulant assays.
Chemical methods and composition
The content of uronic acid (16), fucose (18) and total sugars (17) was estimated by colorimetric methods. After acid hydrolysis of the polysaccharides (6 N HCl, 100ºC, 6 h) sulfate content was measured by a turbidimetric method, as described previously (19). The sugar composition of the polymers was determined by paper chromatography in isobutyric acid: 1 M NH4OH, 5:3 (v/v), or n-butanol:pyridine: water, 3:1:1 by volume, for 24 h and by gas-liquid chromatography of derived alditol acetates (20). The type of uronic acid was determined by electrophoresis on Whatman No. 3 MM paper in 0.25 M ammonium formate buffer, pH 2.7, at 300 V (21). Protein content was measured by the method of Lowry et al. (22).
Agarose gel electrophoresis
Agarose gel electrophoresis of the acid polysaccharides was performed on 0.6% agarose gels (7.5 x 10 cm, 0.2 cm thick) prepared in four different buffers: 0.05 M 1,3-diaminopropane/acetate buffer, pH 9.0; discontinuous buffer containing 0.04 M barium acetate, pH 4.0/0.05 M diaminopropane acetate, pH 9.0, and 0.05 M phosphate buffer, pH 8.0, as described by Dietrich et al. (23). Aliquots of the fractions (about 50 µg) were applied to the gel and run for 1 h at 100 V. The compounds in the gel were fixed with 0.1% N-cetyl-N,N,N-trimethylammonium bromide for 4 h. The gel was dried and stained for 15 min with 0.1% Toluidine blue in acetic acid:ethanol:water (0.1:5:4.9, v/v) and destained with the same solution without Toluidine blue. For visualization of the polyuronides, the gel was restained with Toluidine blue and destained with 0.1 M sodium acetate buffer, pH 4.2 (24).
Desulfation of PF1
About 20 mg of the polysaccharide was dissolved in 5 ml of distilled water and mixed with 1 g (dry weight) of Dowex 50-W (H+, 200-400 mesh). After neutralization with pyridine, solutions were lyophilized. The resulting pyridinium salt was dissolved in 2.5 ml dimethyl sulfoxide:methanol (9:1, v/v) (25). The mixture was heated at 80ºC for 4 h, and the desulfated products were exhaustively dialyzed against distilled water and lyophilized. The extent of desulfation was estimated by the molar ratio of sulfate/total sugar (17,19).
Carboxyreduction and methylation
Native and desulfated fucans were reduced using NaBD4 and 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate as described previously (20). Polysaccharides (10 mg) were subjected to three rounds of methylation as described (26,27). Methylated polymers were hydrolyzed in 6 M trifluoroacetic acid for 5 h at 100ºC and reduced with NaBD4 and the alditols were acetylated with acetic anhydride:pyridine (1:1, v/v) (28). The alditol acetates of methylated sugars were dissolved in chloroform and analyzed with a gas chromatograph/mass spectrometer model 5890; Hewlett Packard.
Fourier transform-infrared spectroscopy
The Fourier transform-infrared spectrum (FT-IR) was recorded with an IR spectrophotometer (model 8300; Shimadzu, Tokyo, Japan) between 400 and 4000 cm-1. The samples (10 mg) were analyzed as a KBr pellet.
Fifty milligrams of the sample was dissolved in D2O and the 13C-NMR spectrum obtained using a Bruker (DRX 600; Bremen, Germany) spectrometer at 60ºC.
The activated partial thromboplastin time (aPTT) was determined using citrated normal human plasma according to the manufacturer specifications (Labtest, São Paulo, SP, Brazil). For the prothrombin time (PT) assay, 90 µl of citrated normal human plasma was mixed with 10 µl of a purified fucan F1 (PF1) solution at different concentrations and incubated for 1 min at 37ºC. The PT assay reagent (200 µl), preincubated for 10 min at 37ºC, was then added and the clotting time recorded with a Quick Times coagulometer (Drake Ltda., São Paulo, SP, Brazil).
Fractionation and sugar composition of the polysaccharides from the different acetone fractions
The compositions of the polysaccharides obtained from different acetone fractions are shown in Table 1. With the exception of fraction 0.3, all fractions contained uronic acid, xylose, galactose, fucose, sulfate,and a small amount of protein (0.6-5.8%). However, differences in the relative proportions of the sugars were observed when the fractions obtained with different volumes of acetone were compared. Thus, uronic acid was the main sugar present in the polymers precipitated with 0.3, 0.5 and 0.8 volumes of acetone. The higher content of uronic acid in these fractions may be explained by the presence of alginic acid. Furthermore, neutral sugars were found in larger amounts in fractions 1.0 and 1.5. Since glucose was not detected, it is unlikely that these fractions were contaminated with laminarans, a group of ß-D-glucans found in brown algae.
Agarose gel electrophoresis analysis of the polysaccharides from the different acetone fractions
The polysaccharides from the different acetone fractions were subjected to agarose gel electrophoresis in diaminopropane-acetate buffer (Figure 1A). Electrophoresis revealed the presence of two or three bands in several fractions while the fractions obtained with 1.0 and 1.5 volumes of acetone showed a single band each. Figure 1B shows the same agarose gel restained and destained with sodium acetate buffer. This procedure revealed the presence of a fourth compound (alginic acid) in the fractions obtained with 0.3 and 0.8 volumes of acetone.
Fractions 1.0 and 1.5 were found to be more homogeneous than the other fractions, but, due to the small amount of fraction 1.5 (Table 1), we chose fraction 1.0 for further study. This fucan showed a single component by agarose gel electrophoresis and high anticoagulant activity compared to the other polysaccharides.
Purification and chemical characterization of fraction 1.0
Fraction 1.0 was applied to a Sephadex G-75 column (Figure 2) and eluted with 0.2 M acetic acid. Fractions of approximately 1 ml were collected. Two peaks were obtained and denoted PF1 (fraction numbers 34-54), with 18,000 kDa, and PF2 (fraction numbers 56-82). The chemical composition of PF1 and PF2 is shown in Table 2. PF1 is a heterofucan with a high content of uronic acid and low contamination with protein. Electrophoresis in formate buffer showed that glucuronic acid is the single uronic acid present in PF1. PF2 showed a higher level of contamination with proteins and was discarded. PF1 was subjected to agarose gel electrophoresis using three different buffer systems (Figure 3). In all of them PF1 migrated as a single component, showing once again that the compound was essentially homogeneous and free of other acidic polysaccharide fractions.
Fourier transform-infrared spectra of PF1
The FT-IR spectra of PF1 showed an intense absorption band at 1264 cm-1 (S=O) common to all sulfate esters (Figure 4). An additional sulfate absorption band at 822 cm-1 (C-O-S, equatorial sulfate) indicated that most sulfate groups are located at positions 2 and/or 3. Absorption bands at 3330 cm-1 and 1648 cm-1 correspond to hydroxyl and carboxyl groups, respectively. In addition, we did not find absorption bands around 1720 cm-1, which would have indicated the presence of O-acetyl groups.
13C-NMR spectroscopy of PF1
The 13C-NMR spectrum of PF1 (Figure 5) showed peaks at 101-101.5 ppm corresponding to C-1 of 4-a-L-fucose and 3 (OSO3)-1 and C-1 of 3- a-L-fucose-1, respectively. The signals at 77.5 ppm (C-3), 80.5 ppm (C-4) and 18 ppm (C-6) confirmed the presence of sulfated fucose. The same spectrum also showed peaks at 105.0-106.2 ppm corresponding to ß-D-glucuronic acid and 103.2 corresponding to 4-ß-D-xylose-1, in agreement with the methylation analysis. Absorption at 99.0 ppm may correspond to 3,6-di-substituted ß-D-galactose. Minor signals observed at 81.5 and 69.0 ppm confirmed 3,6-disubstituted ß-D-galactose units. The signal observed at 32 ppm may be attributed to acetone.
Methylation analysis of PF1 and desulfated PF1
The results of the methylation analysis of intact and desulfated PF1 are shown in Table 3. The methylated derivatives obtained from PF1 suggest the presence of a central core composed of 3- or 4-linked ß-D-glucuronic acid with minor amounts of 3- or 4-linked galactose units. Almost 50% of 3-linked glucuronic acid units are branched at C-2. The branches of galactoses should be at C-6, C-2 or C-3 on disubstituted galactose. The fucose chains are made up of 3- and 4-linked fucose; in addition, minor amounts of 4-linked fucose are branched at C-2 with chains of xylose and/or fucose. Desulfation eliminated about 76% of the sulfate groups in PF1. The 3,4-disubstituted fucosyl residues almost disappeared in the desulfated PF1, suggesting that most are sulfated at C-3, in agreement with NMR analysis and IR spectrum results. The high content of non-reducing fucose and xylopyranose terminal residues indicated that PF1 is a highly branched polymer.
The PT and the aPTT tests are used to distinguish the effects on extrinsic and intrinsic coagulation pathways, respectively. None of the fractions had an anti-clotting effect when examined by the PT test. In contrast, the aPTT test revealed anticoagulant activity in fractions 0.8, 1.0, and 1.5. Fraction 1.0, with the highest anticoagulant activity, was separated into PF1 and PF2 by Sephadex G-75. Only PF1 showed anticoagulant activity (only 2.5-fold lesser than low molecular weight heparin). Desulfation of PF1 by solvolysis in dimethyl sulfoxide abolished its anticoagulant activity (Table 4).
Agarose gel electrophoresis of sulfated fucans extracted from Padina gymnospora. Sulfated fucans were extracted after maxataze digestion and partially purified by acetone precipitation. The sulfated fucans (50 µg) were applied to 0.5% agarose, and electrophoresis was carried out for 1 h at 110 V in 0.05 M 1,3-diaminopropane/acetate, pH 9.0. Gels were then maintained in 0.1% N-cetyl-N,N,N-trimethylammonium bromide solution for 4 h and dried. The polysaccharides in the gel were stained with 0.1% Toluidine blue in acetic acid/ethanol/water (0.1:1:5, v/v) for 15 min and destained with acetic acid/ethanol/water (0.1:1:5, v/v) (A) or with 0.1 M sodium acetate, pH 4.0, in water for 5 min (B). Standard of glycosaminoglycans: chondroitin sulfate (CS), dermatan sulfate (DS) and heparan sulfate (HS), 5 µg each. OR = origin. The definition of acetone fractions is given in the legend to Table 1.)
Gel filtration of fraction 1.0. The fraction precipitated with 1.0 volume of acetone was applied to a Sephadex G-75 column (1.8 x 120 cm). The column was eluted with 0.2 M acetic acid, 1-ml fractions were collected and the effluent was analyzed for the presence of sugars by the phenol-H2SO4 method (20). The arrows indicate the void volume (V0) and the total volume (Vt).
Agarose gel electrophoresis of fraction PF1. Fraction PF1 (50 µg) obtained from the Sephadex G-75 column was subjected to electrophoresis in 40 mM barium acetate buffer, pH 4.0 (A); 50 mM sodium phosphate buffer, pH 8.0 (B); 50 mM diaminopropane/acetate buffer, pH 9.0 (C) as described in Material and Methods. St = standard of glycosaminoglycans: chondroitin sulfate (CS), dermatan sulfate (DS) and heparan sulfate (HS), 5 µg each.
The Fourier transform- infrared (FT-IR) spectrum of fucans from Padina gymnospora at 4000 and 400 cm-1 in potassium bromide table. A, PF1 fucan; B, desulfated fucan.
13C-NMR spectrum at 500 MHz of sulfated fucans from the brown alga Padina gymnospora. The spectrum was recorded at 60ºC in a D2O solution of fraction PF1.
Partial chemical composition of acidic polysaccharides obtained from Padina gymnospora by acetone precipitation.
Partial chemical composition of the polysaccharide fractions obtained from the Sephadex G-75 column.
Methylation analyses of native and desulfated PF1.
Anticoagulant activity of fucans from Padina gymnospora.
In the present study, the brown seaweed Padina gymnospora was treated with acetone to remove lipids, pigments and mannitol. Proteolysis with maxataze resulted in a low level of contamination with proteins. This step was important because fucans bind to a large number of proteins by an ion-exchange process. Subsequently, the extract was submitted to fractionation with different concentrations of acetone.
The electrophoretic profiles of the polysaccharides obtained in fractions 0.3, 0.5 and 0.8 showed the presence of two or three bands, while those from fractions 1.0 and 1.5 showed a single band each. All fractions were demonstrated to contain uronic acid, xylose, galactose, fucose, and sulfate. However, there were differences in the relative proportions of the sugars, suggesting the presence of different fucans in P. gymnospora. At least three different polysaccharides have been demonstrated in heterofucan preparations from Sargassum vulgare, Dictyota mertensis (15), Spatoglossum schröederi (24), and Sargassum stenophylum (29).
All fractions contained similar monosaccharide components. Fractions 0.3 and 0.5 had no anticoagulant activity, while fraction 0.8 had minimal activity, probably because this fraction is a mixture of polysaccharides, as observed in Figure 1. Due to the small amount of fraction 1.5 and the higher anticoagulant activity of fraction 1.0, we concentrated the structural studies on the latter fraction denoted PF1.
Chemical studies showed that PF1 is a glucuronofucan containing minor quantities of xylose and galactose and traces of mannose. FT-IR studies revealed characteristic absorption bands of sulfated polysaccharides (5). There was notable absorption at 1264 cm-1 (S=O stretching) and 822 cm-1 (C-O-S bending of sulfates in an equatorial position) (24). The 822 cm-1 absorption is generally attributed to O-3 and/or O-2 sulfates in fucose residues (6). No absorption attributable to O-4 axial sulfates was found (around 840 cm-1). The molecular weight of PF1 (18 kDa) is similar to that reported for other brown seaweed fucans (24,30,31) although in many cases products with values higher than 50,000 were also reported (3,31).
Structural studies clearly show that several homofucans have large proportions of both a-(1 ®3) and a-(1 ®4) glycoside linkages with the sulfate groups at C-2, without excluding the presence of other sulfate groups or branches at positions 2, 3 or 4 (4,5). However, heterofucans are more complex than homofucans. The glucuronic acid and fucose domains of the glucuronofucan PF1 were analyzed separately since one of them could be a linear backbone or side chain. Nagaoka et al. (31) proposed that a fucan from C. okamuranus contains a linear backbone of (1 ®3) linked fucose. Parts of its fucose units were substituted with (1 ®2) linked a-glucuronic acid (29). Furthermore, Abdel-Fattah et al. (32) isolated a fucan from S. linifolium containing a central core made of ß-D-glucuronic acid and ß-D-mannose and Leite et al. (24) showed a xylofucoglucuronan composed of a core of (1 ®3) linked ß-D-glucuronic acid with branches at C-4 of (1 ®3) linked a-fucose chains. Our data indicate that the fucose from PF1 was mostly substituted at C-2 with chains of (1 ®4) linked ß-D-xylose.
Like many other native fucans, PF1 had a very complex 13C-NMR spectrum, which was difficult to interpret. Unambiguous assignment of all peaks was not possible due to peak overlapping. Several intense signals appeared in anomeric (101-101.5 ppm) and high-field (16.8-18.0 ppm) regions, a phenomenon typical of 3- and 4-linked a-fucopyranosides (4). The presence of 3-O- sulfated fucose was confirmed by the signals at 77.5 ppm (C-3) and 80.5 ppm (C-4), as also observed by Chevolot et al. (5). No signal was observed at 20-25 ppm, a fact that might indicate the presence of acetyl groups (3).
The methylation analysis of native and desulfated PF1 (Table 3) suggested a highly branched molecule with approximately 14% of non-reducing terminal units. The fucose appeared mainly methylated at C-2 and dimethylated at C-2 and C-4. A significant amount of 3-O-methyl and 2,3-di-O-methylfucose was also found, together with terminal 2,3,4-tri-O-methylfucose. After desulfation, the amount of 2,3-di-O-methylfucose increased mostly at the expense of 2-O-methylfucose. Minor increases of 2,3,4-tri-O-methylfucose were also observed, while the proportion of other fucose residues remained mostly unchanged. These results suggest that the "fucan" (fucose domain) chains were formed by large amounts of (1®4) linked fucose units (±46% sulfated at C-3) together with lesser quantities of (1 ®3) linked fucose units. This structure profile is similar to that observed in homofucans. This is the first report of a fucan with fucose sulfated only at C-3. The (1 ®4) linked fucose units (±25%) could be branched through C-2 by (1 ®4) linked xylose residues or fucosyl/xylosyl end-chain residues, as previously observed by Leite et al. (24) in a fucan from Spatoglossum schröederi. The glucuronic domain was formed by (1 ®3) and (1 ®4) linked glucuronic acid units together with a smaller quantity of 3- and 4-linked galactose units. Almost 50% of 3-linked glucuronic acid units are branched at C-2. The branches should be at C-6, C-2 or C-3 in disubstituted galactose.
Several studies have reported the anticoagulant activity of fucans from brown algae (8,33,34). It was previously reported that only homofucans induce anticoagulant activity (5,35,36). However, relatively few studies have interpreted the biological activity of fucans in terms of molecular structure. The anticoagulant activity of fucan is unlikely to be merely a charge density effect; rather it depends critically on the distribution pattern of sulfate groups (33) and the size of the molecule (35). Chevolot et al. (5) demonstrated that the anticoagulant activity of a homofucan from A. nodosum with a high proportion of (1®4) linkage was related to 2-O-sulfation and 2,3-disulfation (5). It was also observed that desulfation of PF1 resulted in loss of anticoagulant activity. Thus, the presence of 3-O-sulfated (1 ®4) linked fucose in PF1 could be related to the higher anticoagulant activity of this heterofucan.
The authors are indebted to Daniel Leung, MSc from University of Iowa, for revising the paper. We are grateful to Centro Nordestino de Aplicação e Uso da Ressonância Magnética Nuclear (CENAUREMN), Universidade Federal do Ceará (UFC), for the NMR measurements. We would like to thank Dr. Paulo A.S. Mourão, Universidade Federal do Rio de Janeiro, for carrying out the methylation studies.
Correspondence and Footnotes
Address for correspondence: E.L. Leite, Centro de Biociências, Departamento de Bioquímica, UFRGN, Av. Salgado Filho, 3000, 59072-970, Natal, RN, Brasil. Fax: +55-84-211-9208. E-mail: firstname.lastname@example.org
Research supported by CAPES and CNPq. L.G. Alves and K.C.S. de Queiroz were recipients of CAPES fellowships. Publication supported by FAPESP. Received November 18, 2003. Accepted October 29, 2004.
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Publication in this collection
13 Apr 2005
Date of issue
18 Nov 2003
29 Oct 2004