Dermatan sulfate in tunicate phylogeny: Order-specific sulfation pattern and the effect of [→4IdoA(2-Sulfate)β-1→3GalNAc(4-Sulfate)β-1→] motifs in dermatan sulfate on heparin cofactor II activity
- Eliene O Kozlowski†1,
- Paula C Lima†1,
- Cristina P Vicente2,
- Tito Lotufo3,
- Xingfeng Bao4, 5,
- Kazuyuki Sugahara4, 6 and
- Mauro SG Pavão1Email author
© Kozlowski et al; licensee BioMed Central Ltd. 2011
Received: 23 March 2011
Accepted: 29 May 2011
Published: 29 May 2011
The Erratum to this article has been published in BMC Biochemistry 2011 12:37
Previously, we have reported the presence of highly sulfated dermatans in solitary ascidians from the orders Phlebobranchia (Phallusia nigra) and Stolidobranchia (Halocynthia pyriformis and Styela plicata). Despite the identical disaccharide backbone, consisting of [→4IdoA(2S)β-1→3GalNAcβ-1→], those polymers differ in the position of sulfation on the N-Acetyl galactosamine, which can occur at carbon 4 or 6. We have shown that position rather than degree of sulfation is important for heparin cofactor II activity. As a consequence, 2,4- and 2,6-sulfated dermatans have high and low heparin cofactor II activities, respectively. In the present study we extended the disaccharide analysis of ascidian dermatan sulfates to additional species of the orders Stolidobranchia (Herdmania pallida, Halocynthia roretzi) and Phlebobranchia (Ciona intestinalis), aiming to investigate how sulfation evolved within Tunicata. In addition, we analysed how heparin cofactor II activity responds to dermatan sulfates containing different proportions of 2,6- or 2,4-disulfated units.
Disaccharide analyses indicated a high content of disulfated disaccharide units in the dermatan sulfates from both orders. However, the degree of sulfation decreased from Stolidobranchia to Phlebobranchia. While 76% of the disaccharide units in dermatan sulfates from stolidobranch ascidians are disulfated, 53% of disulfated disaccharides are found in dermatan sulfates from phlebobranch ascidians. Besides this notable difference in the sulfation degree, dermatan sulfates from phlebobranch ascidians contain mainly 2,6-sulfated disaccharides whereas dermatan sulfate from the stolidobranch ascidians contain mostly 2,4-sulfated disaccharides, suggesting that the biosynthesis of dermatan sulfates might be differently regulated during tunicates evolution. Changes in the position of sulfation on N-acetylgalactosamine in the disaccharide [→4IdoA(2-Sulfate)β-1→3GalNAcβ-1→] modulate heparin cofactor II activity of dermatan sulfate polymers. Thus, high and low heparin cofactor II stimulating activity is observed in 2,4-sulfated dermatan sulfates and 2,6-sulfated dermatan sulfates, respectively, confirming the clear correlation between the anticoagulant activities of dermatan sulfates and the presence of 2,4-sulfated units.
Our results indicate that in ascidian dermatan sulfates the position of sulfation on the GalNAc in the disaccharide [→4IdoA(2S)β-1→3GalNAcβ-1→] is directly related to the taxon and that the 6-O sulfation is a novelty apparently restricted to the Phlebobranchia. We also show that the increased content of [→4IdoA(2S)β-1→3GalNAc(4S)β-1→] disaccharide units in dermatan sulfates from Stolidobranchia accounts for the increased heparin cofactor II stimulating activity.
Dermatan sulfate (DS) is a heterogeneous glycosaminoglycan (GAG), formed by repeating disaccharide units consisting of 4-linked glucuronic acid, 1,3-linked N-acetyl galactosamine ([→4GlcAβ-1→3GalNAcβ-1→]). The extensive heterogeneity of the polymer results from variation in the degree of epimerization on carbon 5 of glucuronic acid, O-sulfation on carbon 4 or 6 of N-Acetyl galactosamine (GalNAc) and on carbon 2 of iduronic acid (IdoA) . It has been shown that regions enriched in [→4IdoA(2S)β-1→3GalNAc(4S)β-1→] units in DS bind to heparin cofactor II (HCII) (2S and 4S represent 2-O- and 4-O-sulfate, respectively), enhancing the HCII-induced inhibition of thrombin [2, 3].
Previously, we reported the presence of highly sulfated DSs in solitary ascidians from orders Phlebobranchia (Phallusia nigra) and Stolidobranchia (Halocynthia pyriformis and Styela plicata) [4–6]. These polymers are composed by the same disaccharide backbone, consisting of [→4IdoA(2S)β-1→3GalNAcβ-1→], but differ in the position of sulfation on GalNAc, which can be sulfated at carbon 4 or 6 . The DS from the stolidobranchs H.pyriformis and S.plicata are sulfated at carbon 2 of IdoA and carbon 4 of GalNAc  and are potent activators of HCII. On the other hand, the DS from the phlebobranch P.nigra is sulfated at carbon 2 of IdoAc and at carbon 6 of GalNAc, and is a poor activator of HCII .
Ascidians (sea-squirts) are an ancient life form with fossils dating back to the Early Cambrian [8, 9]. They belong to the phylum Chordata, subphylum Tunicata (Urochordata). Because of their basal position on the chordate phylogeny, ascidians are key to understanding chordate evolution and the origin of vertebrates [10–13]. The traditional classification of the Ascidiacea includes three orders: Aplousobranchia, Stolidobranchia and Phlebobranchia. This traditional view has been disputed by many recent reconstructions of their evolution, gathering evidence of the paraphyly of Ascidiacea, although confirming the monophyly of Tunicata . While all ascidian orders include colonial forms, solitary species are only present in Stolidobranchia and Phlebobranchia .
The study of ascidians has demonstrated several ways in which these organisms can inform us about our own development and evolution. To increase our understanding about how DS sulfation evolved in chordates, we analyzed the disaccharide composition of DSs obtained from two species of stolidobranch (Herdmania pallida and Halocynthia roretzi), and one species of phlebobranch ascidians (Ciona intestinalis). The results were further compared with our previous data on DSs from other ascidians of the same orders. In addition, we investigated the ability of the ascidian DSs to potentiate HCII. Our results indicate that in ascidians the position of sulfation on the GalNAc in the disaccharide [→4IdoA(2S)β-1→3GalNAcβ-1→] is directly related to the taxon and that the 6-O sulfation is a novelty apparently restricted to the Phlebobranchia. We also show that the presence of [→4IdoA(2S)β-1→3GalNAc(4S)β-1→] disaccharide units in DSs from stolidobranch ascidians accounts for their increased HCII-stimulating activity.
Analysis of the GAGs from H. pallida and C. intestinalis
Fractionation of H. pallida and C. intestinalis GAGs
Characterization of the purified DSs from the ascidians by agarose and polyacrylamide gel electrophoresis
Analysis of the ascidian DS by polyacrylamide gel electrophoresis in barbital buffer, revealed that there is not a similar electrophoretic mobility pattern among the DS from different species of the same ascidian order (Figure 3B). The DSs from species of the orders Stolidobranchia and Phlebobranchia differ in molecular weight as well as in polydispersity. The DSs from S. plicata and P. nigra have the lowest average molecular weight (~30 KDa). On the other hand, the DS from H. roretzi has the highest average molecular weight (~50 KDa), whereas the DSs from the H. pallida and C. intestinalis have an intermediate average molecular weight (~45 KDa). The DS from S. plicata and P. nigra have high molecular weight and are very polydisperse, similar to what is observed for porcine skin DS. It is interesting to notice that differences in molecular weight do not influence the mobility of the DSs in the agarose gel electrophoresis.
Disaccharide composition of the ascidian DSs
The purified DSs from H. pallida, H. roretzi and C. intestinalis were exhaustively degraded with chondroitinase ABC. The disaccharides formed (>95%) were separated by gel filtration chromatography, as described in material and methods and analyzed on a strong anion-exchange HPLC.
Disaccharide composition of the ascidian DSs
The DS from the phlebobranch C. intestinalis has a more heterogeneous disaccharide composition, when compared with the DSs from stolidobranch species (Figure 4 and Table 1). Whereas disulfated disaccharides prevail in Stolidobranchia DSs, accounting for at least 70% of the polymers, mono-sulfated disaccharides are the major units in the DS from C. intestinalis, corresponding to about 55% of the composition. These units are sulfated at either carbon 4 or carbon 6 of the galactosamine, while the mono-sulfated disaccharides in stolidobranch DSs are mainly sulfated at carbon 4 of the galactosamine (Table 1). The main disulfated disaccharide in Phlebobranchia DSs is the ΔUA(2S)-GalNAc(6S), accounting for 36% and 77% in C. intestinalis and P. nigra DSs, respectively. The DSs from Phlebobranchia ascidians differ in that the 4-sulfated galactosamine units are present in C. intestinalis and absent in P. nigra.
Sulfation pattern of ascidians DSs and HCII activity
As shown in Figure 5B, the compositional differences and HCII inhibition activity of most DSs correlates with variations in aPPT values. Thus, higher proportion of 2,4-disulfated units correlates with higher aPTT values.
The subphylum Tunicata comprises the ascidians and two other taxa, Appendicularia and Thaliacea. Tunicates are proposed in some phylogenies as the closest living relatives of the vertebrates [10, 11], although most of the recent reconstructions still place the Cephalochordata as the sister group of the back-boned animals [12–14].
In order to study how sulfation of DS evolved in tunicates we compared the disaccharide composition of DS polymers obtained from ascidians of two different orders: Stolidobranchia and Phlebobranchia. The disaccharide analysis indicated a high content of disulfated disaccharide units in the DSs from both taxa. Interestingly, the degree of DS sulfation decreased on Phlebobranchia clade. Thus, 76% of the disaccharide units in the DSs from stolidobranch ascidians are disulfated, compared to 53% in the DSs from the phlebobranch. In fact, the two taxa probably diverged early during the evolution of tunicates. Phlebobranch ascidians have a simpler pharynx, without the folds present in the stolidobranch. Additionally, the phlebobranch blood contains usually vanadium, while stolidobranch has iron instead . Other important distinctions are present in terms of the development of the atrial cavity and position of the gonads . Also, the aforementioned recent hypotheses about the evolution of the tunicates place the thaliaceans within the Phlebobranchia. Therefore, the study of the DS composition of thaliaceans will be relevant to understand the evolutionary history of the group.
The sulfation pattern of the tunicate DS disaccharides showed interesting results, pointing to an evident structural difference: DS from phlebobranch ascidians contain mainly 2,6-sulfated disaccharides, whereas DSs from stolidobranch ascidians contain mostly 2,4-sulfated disaccharides. Although information about sulfation pattern in DS from other Deuterostomia is scanty, both types of sulfation are found in vertebrates. While 2,4-sulfated disaccharides are commonly found in extracellular DS proteoglycans, such as decorin and biglycan present in different tissues as tendon, cartilage or skin , significant yet small proportions (5%) of 2,6-sulfated units have been found in mouse or pig brain [18, 19] and the biosynthetic regulation of the expression of 2,6-sulfated disaccharides by 6-O-sulfotransferases, 2-O-sulfotransferase and C5-epimerase might play critical roles in the development of the hippocampus and cerebellum . Considering those data, our results point to the 2,4-sulfation as a conserved feature along Chordata and the predominance of 2,6-sulfated disaccharides as the derived condition. Further investigation on the DS structure of echinoderms and hemichordates should clarify this issue.
In vertebrate chordates, four groups of sulfotransferases are involved in the modification of CS/DS: (1) DS-specific 4-O-sulfotransferase; (2) chondroitin 6-O-sulfotransferase; (3) uronyl 2-O-sulfotransferase; (4) GalNAc-4-sulfate 6-O-sulfotransferase. Interestingly, a comprehensive survey of sulfotransferases in the ascidian C. intestinalis showed similarity to vertebrate CS/DS-specific sulfotransferases. From eight C.intestinalis proteins found to be closely related to DS/CS 4-O-sulfotransferases, four were proposed to have arisen by duplication during the evolution of tunicates. Although eight genes encoding C6ST-like proteins were also found in C. intestinalis genome, their evolutionary history was not clear. It was suggested that divergence of the C6ST family genes has occurred independently during the evolution of tunicate, cephalochordate and vertebrate lineages . C. intestinalis genome presented also four genes encoding urosyl 2-O-sulfotransferases, one of them very closely related to human 2-O-sulfotransferases. However, a GalNAc-4-sulfate 6-O-sulfotransferase homologous gene was not found in C. intestinalis genome. In fact, no 4,6-sulfated disaccharides were found in DSs from C. intestinalis or other ascidians analyzed in the present work, despite the high content of 4-O-sulfated N-acetylgalactosamine in stolidobranch ascidians and the presence of these units also in C. intestinalis. On the other hand, albeit up 90% of disaccharide units in DS from P. nigra contains 6-O-sulfated N-acetylgalactosamine, no 4-O-sulfated units were found.
The differences in the sulfation patterns from C. intestinalis and P. nigra may also result from divergent evolution, as these species are not closely related within the Phlebobranchia. Our results on the structure of DSs from ascidians add to Tetsukawa's results, suggesting different mechanisms for GAG sulfation according to taxa, which may have been emerged via gene duplication, occurring independently in each group and leading to different types of 4-O-sulfotransferases and 6-O-sulfotransferases in ascidians and vertebrates, with distinct substrate specificities.
The high affinity binding of DS to HCII requires a rare sequence consisting of [IdoA(2S)-GalNA(4S)]3. Interestingly, DS with higher sulfation levels bind poorly to HCII, suggesting significant specificity of interaction [6, 21]. Corroborating with this idea, recent work has shown that a specific geometry of the [IdoA(2S)-GalNA(4S)]-hexasaccharide, which forms a 21-helix topology (21-°S2.1C4.1C4), is required for high affinity binding to HCII . This geometry allows the interaction of the [IdoA(2S)-GalNA(4S)]-hexasaccharide with key aminoacids involved in the binding to HCII and the correct orientation for the binding to exocite II of thrombin. Extention of the high-affinity sequence in DS polymers is expected to increase the binding and the activity of HCII .
In the present, work we observed that ascidian DSs with increasing content of 2,4-sulfated disaccharides showed increasing HCII activity, (Figure 5A-B). Therefore, in consonance with the previous paragraphy, it is possible to suggest that in the HCII-active DSs, [IdoA(2S)-GalNA(4S)]-disaccharides are clustered in 21-helix topology (21-°S2.1C4.1C4) sequences with inceasing lengh.
Finally, an interesting characteristic of ascidians is their ability to rapid vessel regeneration . Such event, taken together with the fact that in vertebrates DS have been demonstrated to be involved in wound repair, raises intriguing questions concerning the molecular mechanisms underlying angiogenesis. Is the presence of oversulfated DS in ascidians related to fast vessel regeneration by binding to growth factors?
Furthermore, the drastic difference between the DS disaccharide units from phlebobranch and stolidobranch ascidians may also be related to an angiogenesis event. The alteration between a 2,4 disaccharide from Stolidobranchia to a 2,6 disaccharide in Phlebobranchia might be involved in the branchial vessel organization. One of the main differences between these two ascidian orders is the pharyngeal structure. Phlebobranch ascidians possess a simpler pharynx, without folds and usually with less internal vessels. On the other hand, stolidobranch ascidians have a more complex structure, with a folded pharynx and a larger number of internal vessels. The DS structural differences from both ascidian orders could be related to the pharynx vascular organization.
Notably the evolution of glycosaminoglycans in animals including invertebrates as well as vertebrates has also recently been reviewed in terms of their structure and biological activities .
Our results indicate that in ascidians the position of sulfation on the GalNAc in the disaccharide [→4IdoA(2S)β-1→3GalNAcβ-1→] is directly related to the taxon and that the 6-O sulfation is a novelty apparently restricted to the Phlebobranchia. We also show that an increase in the content of [→4IdoA(2S)β-1→3GalNAc(4S)β-1→] disaccharide units in DS accounts for an increased HCII-stimulating activity.
Isolation of ascidian DSs
The ascidians H. pallida and P. nigra were collected in Angra dos Reis, Rio de Janeiro, Brazil; S. plicata was collected at Praia da Urca, Rio de Janeiro, Brazil; C. intestinalis was obtained from the Marine Biological Laboratory, Woods Hole, Massacchussets, USA; H. roretzi was obtained from the Japanese company (Maruha Nichiro Holdings, Inc., Tokyo). To extract the glycans, the animals had the tunic removed and were maintained in acetone at room temperature overnight. Tissues were dried at 60°C, homogenized, suspended in twenty-volumes of digestion buffer (50 mM sodium acetate, 5 mM EDTA, 10 mM cysteine, pH 5.0), containing 10% papain (w/w), and incubated at 60°C, overnight. Soluble glycans were precipitated with two-volumes of ethanol and fractionated in an anion exchange chromatography on a Mono-Q-FPLC column (HR 5/5) (Amersham Pharmacia Biotech), equilibrated in 20 mM Tris/HCl (pH 8.8), containing 4 mM EDTA. The column was developed with a linear gradient of 0-2.0 M NaCl in the same buffer, at a flow rate of 1 mL/min. The fractions from the column were monitored by metachromatic property with dimethylmethylene blue, at 525 nm . The metachromatic fractions were pooled, dialyzed, lyophilized and analyzed by agarose gel electrophoresis.
Agarose gel electrophoresis
The ascidian glycans were analyzed by agarose gel electrophoresis, as described . Briefly, GAGs (~15 mg) were applied to a 0.5% agarose gel and ran for 1 h at 100 V in 0.05 M 1,3-diaminopropane/acetate (pH 9.0). GAGs were fixed in the gel with 0.1% N-cetyl-N,N,N-trimethylammonium bromide solution. After 12 h the gel was dried and stained with 0.1% toluidine blue in acetic acid/ethanol/water (0.1:5:5, v/v).
Polyacrylamide gel electrophoresis-The molecular weight of the ascidian DSs was estimated by polyacrylamide gel electrophoresis. DS samples (~10 mg) were applied to a 7.5% 1-mm-thick polyacrylamide gel slab in 0.02 M sodium barbital (pH 8.6). After electrophoresis (100 V for 30 min), the gel was stained with 0.1% toluidine blue in 1% acetic acid and then washed for about 4 h in 1% acetic acid. The molecular weight markers were the same as those used previously .
Enzymatic treatments with chondroitin lyases
The glycans extracted from ascidians (~20 mg) were incubated with 0.005 U of chondroitin AC or ABC lyases, as described previously . Intact and enzyme-degraded glycans were analyzed by agarose gel electrophoresis, as described earlier.
Deaminative cleavage with nitrous acid - deaminative cleavage was performed by nitrous acid at pH 1.5, as described . Briefly, total glycans extracted from ascidians tissues (~20 μg) were incubated with 5 μL of fresh generated HNO2 at room temperature for 90 min. The reaction mixtures were then neutralized with 1.0 M Na2CO3. Intact and nitrous acid-degraded glycans were analyzed by agarose gel electrophoresis.
Analysis of the disaccharides formed by digestion of the dermatan sulfate with chondroitin ABC lyase
The purified DSs from the ascidians were exhaustively degraded with chondroitin ABC lyase, as described earlier. The disaccharides formed were recovered by Superdex 75 (Amersham Pharmacia Biotech), which was connected to a HPLC system from Shimadzu (Tokyo, Japan). The column was equilibrated with an aqueous solution of 20% acetonitrile (pH 3.5) and developed at a flow rate of 0.25 mL/min. Fractions of 0.5 mL were collected and checked for absorbance at 232 nm. Fractions containing disaccharides were pooled, freeze-dried and analyzed by strong anion-exchange chromatography on a 25-cm Spherisorb-SAX column (Sigma-Aldrich), linked to a HPLC system. The column was developed with a linear gradient of 0 - 1.0 M aqueous NaCl (pH 3.5) at a flow rate of 0.5 ml/min. The elution of the disaccharides was followed by absorbance at 232 nm, and identified by comparison with the elution positions of standard disaccharides.
Hexuronic acid determination
The content of DS was estimated measuring hexuronic acid in the purified samples by the carbazole reaction .
Activated partial thromboplastin time (aPTT) assay
aPTT clotting assays were carried out as described previously . Briefly, normal human plasma (90 μL) was incubated with 10 μL of DS at several dilutions and 100 μL of cephalin. After three minutes at 37°C, 100 μL of 0.25 M CaCl2 were added to the mixtures and the clotting time was recorded. The activity was expressed as units/mg using a standard unfractionated heparin (180 U/mg) curve.
Heparin cofactor II-mediated inhibition of thrombin by ascidian DSs
The inhibitory activity of ascidian DSs was measured in 96-well plate. Briefly, 30 μL of 68 nM HCII in 0.02 M Tris-HCl, pH 7.4/0.15 M NaCl/PEG 1 mg/mL were incubated with 30 μL of ascidian DSs at different concentrations. After incubating for 2 minutes, 10 μL of 50 μM thrombin was added. Thrombin activity was measured using a synthetic chromogenic substrate (S-2238 from DiaPharma Group). The HCII-mediated thrombin inhibition in presence of DSs was expressed as the percentage of thrombin activity during 9 minutes. All DSs were assayed twice in triplicate and expressed as the mean ± the standard deviation.
DHexUA, -4,5-unsaturated hexuronic acid 2-sulfate
-4,5-unsaturated hexuronic acid
GalNAc(6S) and GalNAc(4,6-diS), derivatives of 2-acetamido-2-deoxy-galactose bearing a sulfate ester at position 4, at position 6, and at both positions, respectively
-L-iduronic acid 2-sulfate
fast protein liquid chromatography
high performance liquid chromatography
activated partial thromboplastin time.
This work was supported by grants from CNPq, FAPERJ, CAPES (Edital Ciências Do Mar N°. 09/2009) and the Mizutani Foundation for Glycoscience (to MSGP). MSGP is a research fellow of CNPq and FAPERJ. Fundação de Amparo a Pesquisa de São Paulo 2010/11474-5 (to CPV).
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