A Unique 2-Sulfated β-Galactan from the Egg Jelly of the Sea Urchin Glyptocidaris crenularis

Castro, Michelle O.; Pomin, Vitor H.; Santos, Livia Loiola Dos; Vilela-Silva, Ana-Cristina E.S.; Hirohashi, Noritaka; Pol-Fachin, Laércio; Verli, Hugo; Mourāo, Paulo A.S.

doi:10.1074/jbc.m109.005702

Cited by 45 publications

(17 citation statements)

References 42 publications

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“…The pharmaceutical preparations of bovine and porcine heparin used in this study were analyzed by one-dimensional (1D) 1 H NMR spectra, as described [5,13]. Approximately 0.4 mL of the pharmaceutical preparations, containing ~10 mg of heparin, were lyophilized and dissolved in 0.5 mL of 99.9% deuterium oxide (Cambridge Isotope Laboratory, Cambridge, MA, USA).…”

Section: Methodsmentioning

confidence: 99%

Bovine and porcine heparins: different drugs with similar effects on human haemodialysis

et al. 2013

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BackgroundHeparins from porcine and bovine intestinal mucosa differ in their structure and also in their effects on coagulation, thrombosis and bleeding. However, they are used as undistinguishable drugs.MethodsWe compared bovine and porcine intestinal heparin administered to patients undergoing a particular protocol of haemodialysis. We compared plasma concentrations of these two drugs and also evaluated how they affect patients and the dialyzer used.ResultsCompared with porcine heparin, bovine heparin achieved only 76% of the maximum plasma concentration as IU mL-1. This observation is consistent with the activities observed in the respective pharmaceutical preparations. When the plasma concentrations were expressed on weight basis, bovine heparin achieved a maximum concentration 1.5 fold higher than porcine heparin. The reduced anticoagulant activity and higher concentration, on weight basis, achieved in the plasma of patients under dialysis using bovine instead of porcine heparin did not affect significantly the patients or the dialyzer used. The heparin dose is still in a range, which confers security and safety to the patients.DiscussionDespite no apparent difference between bovine and porcine intestinal heparins in the haemodialysis practice, these two types of heparins should be used as distinct drugs due to their differences in structure and biological effects.ConclusionsThe reduced anticoagulant activity achieved in the plasma of patients under dialysis using bovine instead of porcine heparin did not affect significantly the patients or the dialyzer.

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Section: Methodsmentioning

confidence: 99%

Bovine and porcine heparins: different drugs with similar effects on human haemodialysis

et al. 2013

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“…These sialic acidrich molecules potentiate the acrosome reaction in the sea urchin sperm, which is induced in a species-specific way by the egg jelly sulfated polysaccharides (Hirohashi and Vacquier 2002). Interestingly, one particular species of sea urchin, Glyptocidaris crenularis, sialic acid-rich polysaccharide is absent in the egg jelly (Castro et al 2009). Several studies have been conducted on the characterization of sulfated polysaccharides from the egg jelly coat of sea urchins and characterized the unique polysaccharide structures of welldefined units, composed of sulfated fucose or sulfated galactose (Alves et al 1998;Vilela-Silva et al 1999.…”

Section: Discussionmentioning

confidence: 99%

Sperm and Egg Jelly Coat from Sea Urchin Lytechinus variegatus Collected in Rio de Janeiro Contain Distinct Sialic Acid-Rich Polysaccharides

Valle

Cinelli

Todeschini

et al. 2015

Braz. arch. biol. technol.

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“…The sulfation groups are highlighted by red dashed ellipses or rectangle when just percentage can be estimated. The structures are the following: (A) Ludwgothurea grisea [→3)-α-L-Fuc p -2,4(OSO 3− )-(1→3)-α-L-Fuc p -(1→3)-α-L-Fuc p -2(OSO 3− )-(1→3)-α-L-Fuc p -2(OSO 3− )-(1→] n (Mulloy et al, 1994); (B) Lytechinus variegates I [→3)-α-L-Fuc p -2,4(OSO 3− )-(1→3)-α-L-Fuc p -2(OSO 3− )-(1→3)-α-L-Fuc p -2(OSO 3− )-(1→3)-α-L-Fuc p -4(OSO 3− )-(1→] n (Mulloy et al, 1994); (C) Strongylocentrotus pallidus [→3)-α-L-Fuc p -4(OSO 3− )-(1→3)-α-L-Fuc p -4(OSO 3− )-(1→3)-α-L-Fuc p- 2(OSO 3− )-(1→3)-α-L-Fuc p- 2(OSO 3− )-(1→] n (Vilela-Silva et al, 2002); (D) Arbacia lixula [→4)-α-L-Fuc p -2(OSO 3− )-(1→4)-α-L-Fuc p -2(OSO 3− )-(1→4)-α-L-Fuc p -(1→4)-α-L-Fuc p -(1→] n (Alves et al, 1997); (E) Strongylocentrotus purpuratus I ~80% [→3)-α-L-Fuc p -2,4(OSO 3− )-(1→] n and ~20% [→3)-α-L-Fuc p -2(OSO 3− )-(1→] n (Alves, Mulloy, Moy, Vacquier and Mourão, 1998) and (F) S. purpuratus II [→3)-α-L-Fuc p -2,4(OSO 3− )-(1→3)-α-L-Fuc p -4(OSO 3− )-(1→3)-α-L-Fuc p -4(OSO 3− )-(1→] n (Alves, Mulloy, Moy, Vacquier and Mourão, 1998); (G) Strongylocentrotus droebachiensis [→4)-α-L-Fuc p -2(OSO 3− )-(1→] n (Vilela-Silva et al, 2002); (H) Strongylocentrotus franciscanus [3)-α-L-Fuc p -2(OSO 3− )-(1→] n (Vilela-Silva et al, 1999); (I) L. varieagtus II [3)-α-L-Fuc p -4(OSO 3− )-(1→] n (Cinelli et al, 2007); (J) Echinometra lucunter [→3-α-L-Gal p -2(OSO 3− )-1→] n (Alves et al, 1997); (K) Glyptocidaris crenularis [→3-β-L-Gal p -2(OSO 3− )-1→3-β-L-Gal p -1→] n (Castro et al, 2009); (L) Herdmania monus [→4)-α-L-Gal p -3(SO 3− )-(1→] n (Santos et al, 1992); (M) Styela plicata {→4)-α-L-Gal p -2[→1)- α-L-Gal p -3(OSO 3− )]-3(OSO 3− )-(1→} n (Mourão and Perlin, 1987); (N,O) both Botriocladia occidentalis and Gelidium crinale express structures of [3-β-D-Gal p -1→4-α-Gal-1→] n with different sulfation contents (Farias et al, 2000; Pereira et al, 2005b). …”

Section: Introductionmentioning

confidence: 99%

Specific sulfation and glycosylationâ€”a structural combination for the anticoagulation of marine carbohydrates

Pomin

Mourão

2014

Front. Cell. Infect. Microbiol.

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Based on considered achievements of the last 25 years, specific combinations of sulfation patterns and glycosylation types have been proved to be key structural players for the anticoagulant activity of certain marine glycans. These conclusions were obtained from comparative and systematic analyses on the structure-anticoagulation relationships of chemically well-defined sulfated polysaccharides of marine invertebrates and red algae. These sulfated polysaccharides are known as sulfated fucans (SFs), sulfated galactans (SGs) and glycosaminoglycans (GAGs). The structural combinations necessary for the anticoagulant activities are the 2-sulfation in α-L-SGs, the 2,4-di-sulfation in α-L-fucopyranosyl units found as composing units of certain sea-urchin and sea-cucumber linear SFs, or as branching units of the fucosylated chondroitin sulfate, a unique GAG from sea-cucumbers. Another unique GAG type from marine organisms is the dermatan sulfate isolated from ascidians. The high levels of 4-sulfation at the galactosamine units combined with certain levels of 2-sulfation at the iduronic acid units is the anticoagulant structural requirements of these GAGs. When the backbones of red algal SGs are homogeneous, the anticoagulation is proportionally dependent of their sulfation content. Finally, 4-sulfation was observed to be the structural motif required to enhance the inhibition of thrombin via heparin cofactor-II by invertebrate SFs.

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A Unique 2-Sulfated β-Galactan from the Egg Jelly of the Sea Urchin Glyptocidaris crenularis

Cited by 45 publications

References 42 publications

Bovine and porcine heparins: different drugs with similar effects on human haemodialysis

Bovine and porcine heparins: different drugs with similar effects on human haemodialysis

Sperm and Egg Jelly Coat from Sea Urchin Lytechinus variegatus Collected in Rio de Janeiro Contain Distinct Sialic Acid-Rich Polysaccharides

Specific sulfation and glycosylationâ€”a structural combination for the anticoagulation of marine carbohydrates

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