Vitronectin (VN) is a multifunctional adhesive glycoprotein that is present in normal plasma at high concentrations (0.2–0.4 mg·mL⁻¹ in humans) . The liver is the primary source of plasma VN, and hepatocytes have been shown to synthesize large quantities of VN . VN regulates the blood systems related to protease cascades such as cell lysis by complement, coagulation, and fibrinolysis . Both inactive monomeric and active multimeric forms of VN have been identified in circulating blood . Most VN in normal plasma exists mainly as an inactive monomeric form that scarcely binds to its ligands, but it acquires binding activity to its ligands in a multimeric forms by treatment with denaturants such as urea in vitro . This characteristic is the basis of the VN purification method using heparin-affinity chromatography . VN is also found in the extracellular matrix (ECM) of most tissues and is considered to play a role in cell adhesion, cell motility, and matrix remodeling; VN is present as an active multimeric form that interacts with various matrix ligands, such as type 1 plasminogen activator inhibitor and urokinase receptor to regulate pericellular proteolysis, various types of integrins on the cell surface, and various types of collagen .

Vitronectin is a glycoprotein. It is considered that N-glycosylation of VN is critical for its functions and conformation because the consensus sequences for N-glycosylation are highly preserved in mammals . In our previous study, the structures of N-glycans of porcine and human plasma VNs were elucidated . Recombinant human plasma VN and its recombinant domains bind to type I collagen under physiological conditions . The collagen-binding activity of rat plasma VN is enhanced with decreased glycosylation during the liver regeneration induced by two-thirds partial hepatectomy . Stepwise trimming of N-glycans of VN with various exoglycosidases increases the collagen-binding activity and induces formation of large-sized multimer VNs .

Fibrosis of the liver, which synthesizes most VN, can progress to liver cirrhosis (LC). LC is a disease characterized by pathological accumulation and alteration of ECM proteins. The excessive accumulation and alteration of ECM proteins are led by continuous ECM remodeling during chronic liver injuries . Collagens and VN are the main structural constituents of ECM. Therefore, the interaction between VN and collagen is considered to be the key to controlling ECM remodeling in LC, and increasing active VN against collagen would lead to advanced liver fibrosis, which results in cirrhosis. However, changes in glycosylation of VN and its collagen activity during LC have not been elucidated. If it is possible to control the modification of oligosaccharides on VN, it may be possible to open a way to retard progression of LC.

Carbon tetrachloride (CCl₄) is toxic and induces liver lesions and liver fibrosis. Animals repeatedly administered CCl₄ over time develop cirrhosis via fibrosis of the liver. Therefore, CCl₄-injected animals are commonly used as a model of chronic liver injuries such as LC. Rats treated with CCl₄ for 8 weeks have a lipid profile, liver enzymes, and oxidative stress markers that are increased remarkably and total protein and high-density lipoprotein levels that are decreased dramatically . However, the toxicological mechanisms of CCl₄ remain not fully understood.

In this study, we focused on modulations of VN and determined the glycosylation and collagen-binding activity of plasma VN in cirrhosis patients. We also examined the VN modulations in CCl₄-treated rats to evaluate the usefulness of rats with liver injury equivalent to chronic liver disease.

The total protein concentration in LC plasma decreased to approximately 72% of that in normal plasma (Fig. A). Parallel to the decrease of the total protein concentration in plasma, the VN level in LC plasma decreased to approximately 69% of that in normal plasma (Fig. B). VNs were purified from plasma samples by repeated heparin affinity chromatography before and after activation with urea treatment. The amounts of purified normal and LC VNs in 1 mL of plasma were approximately 0.12 and 0.04 mg, respectively. The yield of VNs purified from LC plasma was approximately 36% of that from normal plasma. Both normal and LC-VNs gave double bands at the same migration positions of approximately 65 and 75 kDa on SDS/PAGE. The 75 kDa band of LC-VN was thin compared with the 65 kDa band, while these two bands from normal VN had equivalent widths (Fig. C).

Type I collagen-binding activities of human plasma VNs were measured by ELISA. The inactive VN in human plasma was activated by urea treatment. The active VNs in normal and LC plasma before and after urea treatment were measured, and the ratio of active VN to total VN in plasma was calculated. In untreated plasma, VN in normal plasma showed low collagen-binding activity compared with that in LC plasma, which suggests that the VN in normal plasma exists mainly in the native inactive form and the VN in LC plasma exhibits higher activity than that in normal plasma (Fig. A, urea treatment −). When natively inactive VNs in plasmas were activated by urea treatment, the collagen-binding activities of the VNs in both normal and LC plasma increased in parallel with the VN levels in each plasma (Fig. A, urea treatment +). The ratio of active VN to total VN in untreated LC plasma was more than double that in normal plasma (Fig. B). The collagen-binding activity of purified VNs was also measured by ELISA. Both normal and LC-VNs dose-dependently bound to all types of collagens, and the binding activity was in the following order: type I > V > IV. LC-VN bound to all types of collagens like normal VN (Fig. A–C). These results showed that the ratio of active VN in LC plasma increased over that in normal plasma, while there was no difference between the purified normal and LC-VNs in collagen binding.

The carbohydrate composition of each purified VN was analyzed by HPLC after acid hydrolysis and fluorescence labelling. The noticeable changes in carbohydrates of purified VNs were increases in l-fucose (Fuc) and N-acetylneuraminic acid (NeuAc) in LC-VN (Fig. A,B). Neutral sugars and hexosamines are expressed as mol% of total carbohydrates in each purified VN (Fig. A). These sugars, except for Fuc, did not change significantly, and the presence of d-mannose (Man) and other neutral sugars suggested that both VNs contained complex-type N-glycans. There was no difference between normal VN and LC-VN in total carbohydrates. NeuAc had increased in LC-VN by 1.6-fold that of normal VN (Fig. B). The lectin reactivities of VNs illustrate the changes in glycans during LC (Table ). Both normal and LC VNs bound equally with ConA and Ricinus communis agglutinin (RCA). Enhanced reactivity of LC-VN was observed for Datura stramonium agglutinin (DSA), Aleuria aurantia lectin (AAL), and Sambucus nigra bark agglutinin (SNA), which indicates increases of lactosamine branching, fucosylation to the innermost N-acetylglucosamine (GlcNAc) residue, and sialyl α2-6Gal sequences in LC-VN, respectively, as shown in Fig. C–E. These results showed that the glycosylation of VN in the cirrhotic liver patients had changed dramatically from those of normal healthy individuals.

Lectin reactivity of VNs. The lectin reactivity of VNs illustrates the partial structures of glycans. The reactivity of each VN was measured with biotinyl lectins on the membrane and expressed as staining intensity. +, positive staining; ++, +++, positive staining with strong intensity; −, negative staining; NT, not tested

^*Reactivity after desialylation.

It is difficult to obtain human disease samples for analyses of chronic liver disease. Therefore, the CCl₄-treated rat has often been used as a model of chronic liver disease. From the viewpoint of the functions of glycosylation of VN, CCl₄-treated rats were analyzed in this study.

The rats treated with CCl₄ or olive oil as controls were weighed, and the concentrations of total plasma protein and the VN levels in plasma were measured. Liver injuries, including fibrosis and adherence to adjacent structures, were observed in CCl₄-treated rats (CCl₄-rats), and 4 out of 13 rats died, whereas the control rats were healthy. Blood biochemical parameters of liver damage [alanine aminotransferase (ALT) and aspartate aminotransferase (AST)] and liver function including parameters of cholestasis [total bilirubin (TBil)] in CCl₄ plasma and LC plasma were measured to determine whether CCl₄-treated rats had induced liver injury corresponding to chronic liver disease. As shown in Table S1, ALT, AST, and TBil were increased to 300%, 480%, and 140% compared to controls, as in previous reports using CCl₄-treated rats as a chronic liver disease model . In addition, these parameter changes were similar to those of cirrhosis patients. The body weights of CCl₄-rats decreased with the repeated injections (Fig. A). VN levels in CCl₄-plasma increased compared with those in the control plasma while total protein concentrations decreased in CCl₄ plasma (Fig. B,C). The yields of purified control and CCl₄-VN were approximately 21 and 34 μg·mL⁻¹ of plasma, respectively. Both purified control and CCl₄-VNs gave a single band, at close migration positions of approximately 70 kDa in SDS/PAGE (Fig. D). These results of the VN of CCl₄-treated rats were the opposite of those of the VN of human LC in plasma VN concentrations and the amount of purified VN.

Vitronectin in rat CCl₄ plasma showed lower collagen-binding activity compared with that in control rat plasma before urea treatment (Fig. A, urea treatment −). After urea treatment, the collagen-binding activities of both VNs significantly increased (Fig. A, urea treatment +). The ratios of active VN in untreated plasma were decreased in the CCl₄ plasma to approximately one-half of that of the control plasma (Fig. B). These results suggest that the active VN in the CCl₄ plasma was much lower than that in the control plasma. The results of CCl₄-treated rats were the opposite of those of human LC, too.

In an HPLC analysis, mainly GlcNAc, galactose (Gal), and Man, as well as a minute amount of N-acetylgalactosamine (GalNAc), were detected in control and CCl₄-VNs, suggesting that rat VNs contain mainly complex-type N-glycans and a few O-glycans. In the composition of neutral sugars and hexosamines, there was no distinct difference between control and CCl₄-VNs (Fig. A). Amounts of NeuAc and NeuGc in CCl₄-VN tended to be higher than those in control VN (Fig. B). As shown in Table  and Fig. C, enhanced reactivity of CCl₄-VN was observed for Psathyrella velutina lectin (PVL), DSA, and Lycopersicum esculentum lectin (LEL), which indicates increases of sialyl α2-3Gal sequences, lactosamine branching, and polylactosamine, respectively (Table  and Fig. C). Reduced reactivity of CCl₄-VN was observed for two N-glycan-specific lectins, ConA and RCA (Table  and Fig. D). Both rat VNs bound equally with fucose-specific lectin, AAL (Table ). These results suggested that complex type N-glycans were reduced and that the sialic acid concentration tended to be increased in purified VN by CCl₄. The changes in glycosylation of VN are different in CCl₄-treated rats and LC patients, except for NeuAc.

Collagen-binding activities of VNs treated with glycosidases were measured to clarify the relationship between carbohydrate and collagen-binding activities of purified LC-VN. Human VN (hVN) and porcine VN (pVN) were used for analysis because hVN has only a few N-glycans with Fuc, but pVN has many N-glycans with Fuc (Table ) . hVN (65 and 75 kDa) and pVN (58 kDa) were purified from human and porcine plasma, and carbohydrates on the VNs were trimmed by fucosidase (F), neuraminidase (N), or a combination of F and N and N-glycosidaseF (NG) (Fig. A). deN-glycosylation by NG and desialylation by N were confirmed by the lower molecular masses of VNs (Fig. B). Because defucosylation by F could not be confirmed by molecular mass reduction, it was confirmed by staining reduction of the Fuc-recognition lectin Ulex europaeus agglutinin (UEA-I) in dot-blot analyses (Fig. C). Binding of VNs treated with glycosidases to collagen type I showed the same tendency in hVN and pVN, and the binding increased in the following order: NG > F, N, F + N > C (Fig. ). These results suggest that defucoslylation and desialylation of purified VNs slightly increased the collagen-binding activity and that the collagen-binding activity was most enhanced by deN-glycosylation of purified VNs.

Molar ratio and structure of N-linked oligosaccharides on hVN and pVN

[IMAGE OMITTED. SEE PDF.]: α2, 3-linked Neu; [IMAGE OMITTED. SEE PDF.]: α2, 6-linked Neu; [IMAGE OMITTED. SEE PDF.]: β1, 4-linked Gal; [IMAGE OMITTED. SEE PDF.]: α1, 6-linked Fuc; [IMAGE OMITTED. SEE PDF.]: GlcNAc; [IMAGE OMITTED. SEE PDF.]: Man.

This study showed that human VN in cirrhotic patients differs from VN in normal individuals in the plasma VN level, the ratio of active VN, and its glycosylation (Figs. 1, 2, 4). The VN synthesis appears to parallel the decrease in protein synthesis caused by lowered liver function due to cirrhosis (Fig. ). Under the untreated physiological condition, a higher percentage of VN was found to be the active form in LC plasma than in normal plasma (Fig. A, urea treatment − and B). These results suggest that the increase of active VN in cirrhotic plasma may contribute to the incorporation of plasma VN into the matrix and subsequent repair or remodeling processes during cirrhosis. On the other hand, the amount of VNs activated by treatment with urea was lower in LC plasma than in normal plasma (Fig. A, urea treatment +). Because urea activates inactive VN, the amount of VN treated with urea corresponds to the total amount of VN in plasma (Fig. B).

In this study, two-step heparin-affinity chromatography was used for purification of VN . In the first step, originally active VN in plasma binds to a heparin column under a non-denaturing condition and is removed. The inactive VN in the pass-through fraction in the first step is activated by urea and purified by the second step. The purified VNs were originally inactive and artificially activated forms. Therefore, the yield of purified LC-VN was approximately one-third of normal VN, as seen in Fig. A.

In the carbohydrate analyses of purified VNs, the mol% values of Fuc and NeuAc were increased, while those of GlcNAc, Gal, and Man tended to decrease (Fig. ). The reactivities with DSA, AAL, and SNA were enhanced in LC-VN (Table ). The results suggest that the number of oligosaccharides transferred to the VN peptide decreased, while branching, fucosylation, and sialylation of oligosaccharides in LC-VN increased. Figure  is a schematic representation of the changes of N-glycans in LC-VN expected from these results. Collagen-binding activities of both hVN and pVN treated with glycosidases were in the order NG > F, N, F + N > C (Fig. ). Among the changes in glycosylation of LC-VN, the number of oligosaccharides transferred to the VN peptide decreased, which would enhance collagen-binding activity of LC-VN because the collagen-binding activities of VNs were enhanced by deN-glycosylation, as shown in Fig. . On the other hand, changes in the glycosylation of LC-VN, branching, fucosylation, and sialylation of oligosaccharides would reduce the collagen-binding activity of LC-VN because collagen-binding activity of VNs was enhanced by defucosylation and desialylation, as shown in Fig. . Consequently, the purified human VNs from normal and LC plasma showed almost the same binding to collagens (Fig. ), which can be considered to be a result of preventing the enhancement due to the decreasing N-glycosylation and the suppression due to the increase of Fuc and sialic acids. Previously, we showed that the collagen-binding activity of purified VN is enhanced by the change in glycosylation in vitro and during liver regeneration after partial hepatectomy in vivo . In glycosylation changes, carbohydrate composition analysis and lectin reactivity indicated a decrease in sialic acid in VN from partially hepatectomized rats at 24 h. The desialylation and deN-glycosylation of purified rat VN increased the collagen-binding activity by 2.9 and 1.2 times, respectively . The desialylation and deN-glycosylation of human VN also increased the collagen-binding activity by 1.5 and 2.8 times, respectively . This study clarified not only the reproducibility of these previous reports but also the effect of Fuc in carbohydrates on VN in collagen-binding activity, as shown in Figs  and .

In LC, significantly high levels of serum sialic acid were reported as compared to controls . The levels of fucosylated species of α-fetoprotein in patients with hepatocellular carcinoma, LC, and chronic hepatitis are increased compared with those in normal controls . The plasma fucosyltransferases are specifically elevated in hepatocellular carcinoma . The changes of VN glycosylation observed in LC (Fig. ) agree with the reported changes of other serum proteins and related enzymes such as glycosyltransferases. In this study, we clarified that the oligosaccharide structures of the purified LC-VN, which were originally inactive, were activated by urea treatment during the purification step. Therefore, in future work, it will be necessary to clarify the oligosaccharide structures on active VN in order to elucidate the relationship between oligosaccharide structures on VN and the collagen-binding activity in LC in more detail. However, for this future subject, a method for isolating active VN from plasma has not been established. Thus, this problem needs to be solved before such future studies.

Plasma samples of human patients are limited. Therefore, we attempted to determine whether CCl₄-treated rats are an appropriate model of LC to study the mechanism of the pathological matrix remodeling in view of VN. Several effects of CCl₄ injection into rats were observed on the plasma VN level, the ratio of active forms, and the glycosylation of VN when compared to the rats injected with olive oil as a control. However, the effects were almost the opposite of those of human cirrhotic disease except for a small part of the glycosylation changes (Figs 5–7). Rat VN is both N- and O-glycosylated, and the molecular mass is uniformly 70 kDa. Human VN is only N-glycosylated and exists in two forms, with the molecular mass of 75 kDa and the nicked products of 65 kDa plus 10 kDa . The amino acid sequence identity between human and rat VNs is 73% with four common domains and ligand-binding activities. Human VN has three N-glycosylation sites (Asn 86, 169, and 242), all of which are conserved in rat VN with one additional N-glycosylation site (Asn 96), but rat VN is also O-glycosylated. The results of this study clarify that the CCl₄-treated rat has a significantly different pathology from human LC when VN is the focus.

In summary, we showed that the VN level in plasma was decreased but active VNs were increased in chronic liver disease. The glycosylation of VN was also changed, with high fucosylation and sialylation in chronic liver disease. In contrast, VN levels in plasma were increased but active VN was decreased in CCl₄-treated rats, while glycosylation changes were observed in CCl₄-VN. These data suggested two findings: one is that the glycosylation of VN might modulate the collagen-binding activity related to liver fibrosis in chronic liver disease, and the other is that CCl₄-treated rats are not an appropriate model for the VNs in human LC disease.

Sheep anti-human VN IgGs were purchased from the Binding Site Ltd (Birmingham, UK), and horseradish peroxidase (HRP)-conjugated rabbit anti-sheep IgGs were purchased from ICN Biomedicals, Inc. (Costa Mesa, CA, USA). Rabbit anti-VN IgGs were purchased from the Cosmo Bio Co., Ltd (Tokyo, Japan), and HRP-conjugated goat anti-rabbit IgG was purchased from Millipore (Temecula, CA, USA). Various lectins, concanavalin A (ConA), R. communis agglutinin (RCA), D. stramonium agglutinin (DSA), lectins of L. esculentum (LEL) and A. aurantia (AAL), Sambucus nigra bark agglutinin (SNA), and Ulex europaeus agglutinin (UEA-I) were purchased from Seikagaku Kogyo (Tokyo, Japan). P. velutina lectin (PVL) was purified from the fruiting bodies of P. velutina mushrooms collected in Japan . Lectins were labeled with N-hydroxysuccinimide biotin (Pierce, Rockford, IL, USA) according to the method reported previously . Collagen types I, IV, and V from porcine skin and other reagents of special grade were from Wako Pure Chemicals (Osaka, Japan). Fucosidase (GKX-5006) from bovine kidney was purchased from Prozyme (Hayward, CA, USA). Neuraminidase (sialidase) from Arthrobacter ureafaciens and N-glycosidase F from Flavobacterium meningosepticum and expressed in Escherichia coli were purchased from Roche Diagnostics (Mannheim, Germany).

Human plasma samples from 10 healthy normal people were provided by I. Ishizuka of Teikyo University and S. Yamada of Tottori University. Human plasma samples from 10 LC patients were provided by S. Yamada of Tottori University and S. Oda-Tamai of St Marianna University. Informed written consent was obtained from all subjects in accordance with the Ethical Guidelines for Medical and Health Research Involving Human Subjects published by the Ministry of Health, Labor and Welfare, Japan (MHLW). This study was approved by the Research Ethics Committee of Ochanomizu University and conforms to the standards set by the Declaration of Helsinki (2018-2). Male Wistar rats aged 8 weeks (weighing 130–150 g; Nihon Clea, Tokyo, Japan) were maintained at a constant temperature (23.5 °C) with 12 h each light (06.00–18.00 h) and darkness. Control or CCl₄-group rats were injected intraperitoneally with olive oil (1 mL·kg⁻¹) or CCl₄ (2 mL·kg⁻¹, CCl₄ : olive oil = 1 : 1), respectively, twice a week for 6 weeks. Rats were anesthetized and sacrificed, and blood was collected. Anticoagulant sodium citrate 3.8% (w/v) solution was added to blood at a ratio of 1 : 10 (v/v). Animal experimental procedure and housing condition were approved by the Institutional Animal Care and Use Committee of Ochanomizu University. Porcine plasma was purchased from Tokyo Shibaurazouki Co., Ltd (Tokyo, Japan).

Vitronectins were purified from each plasma by repeated heparin-affinity column chromatography before and after urea treatment according to the methods of Yatohgo et al. . Heparin–Sepharose, which is stable and has a high-binding capacity for VN, was prepared by reductive amination . VN was eluted with 0.5 m NaCl from the heparin column (1.8 × 4 cm, 10 g gel) in a urea-denatured condition and then refolded by step-wise dialysis with the ion concentration decreasing to 0.13 m from 2 m NaCl.

Total protein in plasma was measured by using a protein assay kit, Tunein-TP (Otsuka Pharmaceutical Co., Ltd., Tokyo, Japan). The plasma sample was diluted 100–200 times (5 μL) and mixed with the protein assay reagent (300 μL) in 96-well Iwaki assay plates. After standing for 5 min at room temperature, the absorbance of the sample was measured at 595 nm using a microplate reader (Vient, DS Pharma Biomedical, Osaka, Japan). Bovine serum albumin was used as a protein standard.

The VN concentration of plasma was measured by sandwich ELISA or dot-blotting using an anti-VN polyclonal antibody (sheep anti-human VN IgGs) and labelled polyclonal antibody. For ELISA, sheep anti-human VN IgGs (0.2 μg·mL⁻¹, 100 μL) were immobilized in wells of 96-well plates (Immulon 1; Dynatech Laboratories, Alexandria, VA, USA) at 4 °C overnight. Then wells were blocked with 5% BSA in 10 mm PBS (pH 7.5) for 2 h at room temperature. Each plasma sample was diluted with PBS to 100–5000 times (50 μL) and added to each well, followed by incubation at room temperature for 1 h. The amount of VN in each well was determined by biotin-labeled sheep anti-human VN IgGs (0.2 μg·mL⁻¹, 100 μL) and then HRP–avidin–biotin complex (4 μg·mL⁻¹, 100 μL) at room temperature for 1 h each. After washing with PBS four times, the bound HRP was developed using 0.04% O-phenylenediamine in 0.1 m phosphate–citrate buffer (pH 5.0) containing 0.01% H₂O₂ (200 μL), stopped by addition of 2 m H₂SO₄ (50 μL), and measured at 490 nm using a microplate reader (model 680, Bio-Rad, Hercules, CA, USA). For dot-blotting, two-fold dilution series of plasma samples (each 100 μL) were dot-blotted onto polyvinylidene fluoride (PVDF) membranes and blocked with 3% BSA, then cut into lanes and reacted with the biotin-labeled sheep anti-human VN IgGs (1 μg·mL⁻¹) and the HRP–avidin–biotin complex (1 μg·mL⁻¹) at room temperature for 2 h each. The membrane was developed with 0.05% 4-chloro-1-naphthol containing 0.01% H₂O₂. The staining intensities were measured by a refractive densitometer (Shimadzu CS9300PC, Shimadzu, Kyoto, Japan).

Vitronectins were loaded on each lane of a 9.5% polyacrylamide gel, and SDS/PAGE was run in the presence of 2-mercaptoethanol according to the methods of Laemmli . Proteins were blotted onto a PVDF membrane and stained with Coomassie brilliant blue (CBB) or immunostained with sheep anti-human VN IgGs and HRP-conjugated rabbit anti-sheep IgGs. The color was developed with 0.05% 4-chloro-1-naphthol containing 0.01% H₂O₂.

Collagen-binding activities were assayed by ELISA. Collagen types I, IV, and V (10 μg·mL⁻¹ in 0.1 m carbonate buffer, pH 9.5, 100 μL) were immobilized onto wells of a 96-well Immulon 1 plate for 3 h at room temperature, and then the wells were blocked with 300 μL of 0.5% skim milk in PBS overnight at 4 °C. Purified VN or plasma before and after urea treatment (50 μL) was added to each well, followed by incubation for 2 h at room temperature. The VNs bound to the immobilized collagens were detected with sheep anti-human VN IgG and HRP-conjugated rabbit anti-sheep IgG. After washing with PBS (300 μL) four times, the HRP was developed by the same method described for sandwich ELISA in the Materials and methods. For activation of plasma VNs by urea treatment, urea was added to the plasma, then the volume was adjusted to 10 volumes with PBS containing 5 mm EDTA and 1 mm phenylmethylsulfonyl fluoride to a final concentration of 8 m urea . The solution was incubated for 2 h at 37 °C and diluted with 8 volumes of PBS for ELISA.

Vitronectins were dot-blotted onto the PVDF membranes and washed with Milli-Q (Merck Millipore, Burlington, MA, USA) water. The membranes were placed in glass tubes and dried in a vacuum desiccator over KOH. Then hydrolysis was carried out in vacuo with a vapor of 2 m HCl and 2 m trifluoroacetic acid for 4 h at 100 °C. After hydrolysis, the released sugars in the mixture were N-acetylated and labelled with a fluorescent probe, 2-aminopyridine (PA), as described previously , and PA-carbohydrates were analyzed by reverse-phase HPLC on a PALPAK Type A column (4.6 × 150 mm; Takara, Shiga, Japan) according to the method previously reported . The sialic acid component was analyzed according to the method of Hara et al. . VNs (1.5 μg) were hydrolyzed with 0.025 m HCl at 80 °C for 1 h, and the sialic acids released were labelled with a fluorescent probe, 12-diamino-4,5-methylenedioxy-benzene, dihydrochloride-2 HCl containing 1.0 m β-mercaptoethanol and 10 mm Na₂S₂O₄, and they were analyzed on a Shim-pack CLC-ODS column (6.0 × 150 mm; Shimadzu).

Two-fold dilution series of VN samples (each 100 μL) were dot-blotted onto PVDF membranes and blocked with 3% BSA, then cut into lanes and reacted with each biotinyl lectin in PBS . After reacting with HRP–avidin–biotin complex, the membrane was developed with 0.05% 4-chloro-1-naphthol containing 0.01% H₂O₂ according to the method previously reported . The staining intensities were measured by a refractive densitometer (Shimadzu CS9300PC), at an absorbance of 370 nm for lectin staining or at 550 nm for CBB staining. Asialoglycoproteins were prepared by desialylation of intact glycoproteins by the treatment with 0.01 m HCl at 80 °C for 1 h.

Vitronectins were dot-blotted onto PVDF membrane and reacted with sheep anti-human VN IgG and HRP-conjugated rabbit anti-sheep IgG. The membrane was developed with 0.05% 4-chloro-1-naphthol containing 0.01% H₂O₂. The raw absorbance of 490 nm data of bound VN in ELISA was corrected using the relative antibody reactivity of each VN because the immunoreactivity against VN from CCl₄ plasma was higher than that of control plasma.

All blood samples were stored at −20 °C until use. Concentrations of ALT and AST and liver function tests including parameters of cholestasis (TBil) were determined spectrophotometrically using an automatic biochemical analyzer by Oriental Yeast Co., Ltd (Shiga, Japan).

Enzyme deglycosylation of hVN and pVN was performed according to the manufacturer's instructions (Roche Diagnostics, Indianapolis, IN, USA) and as described previously . VNs (150 μg) were treated with fucosidase (50 mU), neuraminidase (5 mU), fucosidase and neuraminidase (50 and 5 mU, respectively), or N-glycosidaseF (1 U) in 20 mm sodium citrate phosphate buffer (pH 6.0) at 37 °C for 48 h. The control was prepared by adding the same volume of the buffer as the enzymes. The treated VNs were dialyzed against PBS.

Three-fold dilution series of glycosidase-treated VNs (each 100 μL) were dot-blotted onto PVDF membranes and blocked with 3% BSA in 10 mm Tris/HCl saline (pH 7.5), then cut into lanes. The spots were reacted with the biotinylated UEA-I, which specifically binds to Fuc, and subsequently with HRP–avidin–biotin complex (diluted 1 : 1000) at room temperature for 1 h each. The spots containing Fuc were detected using ECL reagent (GE Healthcare GE Helthcare (Little Chalfont, Buckinghamshire, UK) ECL^TM Western Blotting Detection Reagents), and the intensity of each spot was visualized with an ImageQuant LAS4000 mini imager (GE Healthcare).

Data are expressed as the mean ± standard deviation (mean ± SD) and compared by the non-parametric Mann–Whitney U test or t-test. A P value of < 0.05 was assigned significance. All statistical analyses were done with ibm spss statistics (version 23; IBM Corp., Armonk, NY, USA).

We sincerely thank Dr Sadako Yamada from the Faculty of Medicine, Tottori University, Dr Nobu Akamatsu, Dr Hiroshi Mizuno and Dr Shigemi Kato from St Marianna University School of Medicine, Dr Ineo Ishitsuka and Dr Naoko Iida-Tanaka, Faculty of Medicine, Teikyo University, and Dr Zen-ichiro Honda of the Health Care Center, Ochanomizu University, for supporting this research. This research was supported in part by JSPS KAKENHI Grant Number JP 12680607. We thank K. Ono for editing the English.

The authors declare no conflict of interest.

KD and RS performed the experiments and analyzed the data. KD and HO wrote the manuscript. HO conceived the study. SO-T and HO initiated the study. All authors reviewed the manuscript.