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The role of crude human saliva and purified salivary MUC5B and MUC7 mucins in the inhibition of Human Immunodeficiency Virus type 1 in an inhibition assay

Virology Journal volumeĀ 3, ArticleĀ number:Ā 99 (2006) Cite this article

Abstract

Background

Despite the continuous shedding of HIV infected blood into the oral cavity and the detectable presence of the AIDS virus at a high frequency, human saliva is reported to inhibit oral transmission of HIV through kissing, dental treatment, biting, and aerosolization. The purpose of this study was to purify salivary MUC5B and MUC7 mucins from crude saliva and determine their anti-HIV-1 activities.

Methods

Following Sepharose CL-4B column chromatography and caesium chloride isopycnic density-gradient ultra-centrifugation, the purity and identity of the mucins was determined by SDS-PAGE and Western blotting analysis respectively. Subsequently an HIV-1 inhibition assay was carried out to determine the anti-HIV-1 activity of the crude saliva and purified salivary mucins by incubating them with subtype D HIV-1 prior to infection of the CD4+ CEM SS cells.

Results

Western blotting analysis confirmed that the mucin in the void volume is MUC5B and the mucin in the included volume is MUC7. The HIV inhibition assay revealed that both the crude saliva and salivary MUC5B and MUC7 mucins inhibited HIV-1 activity by 100%.

Conclusion

Although the mechanism of action is not clear the carbohydrate moieties of the salivary mucins may trap or aggregate the virus and prevent host cell entry.

Background

Several studies have shown that the human immunodeficiency virus (HIV) is not transmitted via the oral route [1]. It has also been reported that there is a continuous shedding of HIV infected blood into the oral cavity from mucosal and gingival lesions in HIV-infected patients, resulting in the detectable presence of the acquired immunodeficiency syndrome (AIDS) virus at a high frequency in the oral cavity [2ā€“6]. However, several epidemiological studies have failed to present any conclusive evidence about oral transmission of HIV through kissing, dental treatment, biting, and aerosolization [7ā€“14].

Extensive studies have been carried out after the initial findings of Fultz [1] that human saliva inhibited the activity of the AIDS virus [8, 15, 16]. These studies showed that the anti-HIV activity appeared to be highest in sub-mandibular secretions and whole saliva rather than parotid secretions [2, 3, 11, 17ā€“19]. Although most of these studies suggested that HIV-1 particles were aggregated by high-molecular weight components (of mucus) in both whole saliva and specifically in sub-mandibular/sublingual secretions, and which were removable by filtration through 0.45 Ī¼m pore filter [3, 8, 17, 20, 21], there has been no detailed analysis to identify the mucin components of these secretions and determine which of these components displays HIV inhibitory activity.

Thus far five secreted gel-forming (MUC2, MUC5AC, MUC5B, MUC6 MUC19), three secreted non gel-forming (MUC7, MUC8, MUC9), ten membrane bound (MUC1, MUC3A, MUC3B, MUC4, MUC11, MUC12, MUC13, MUC16, MUC17, MUC20) and three unclassified mucins (MUC14, MUC15, MUC18) have been identified [22]. Human saliva is known to contain, amongst many other factors two types of mucins, namely MUC5B and MUC7 [23], and more recently MUC19 [24]. The aim of this study was to isolate and purify these mucins in the saliva and to determine their anti-HIV-1 activity individually.

In its special report on HIV and AIDS on 30 May 2006, UNAIDS stated that since its outbreak in 1981, AIDS was found to be responsible for the deaths of more than 25 million people world-wide, with 2.8 million deaths and over 4.1 million new infections in 2005 alone [25]. This report estimated that there were more than 38.6 million HIV positive people world-wide at the end of 2005, of which two-thirds of those infected lived in Sub-Saharan Africa. Of these, South Africa with 27.9% of its adult population living with HIV [26] remains one of the worst affected countries in the world [27]. This epidemic is expected to cost South Africa 17 % of its GDP growth by 2010 [26]. With this in mind, the present study could make a significant contribution to the efforts being made in controlling this epidemic.

In this study we report the anti-HIV-1 activities of human crude saliva and purified salivary MUC5B and MUC7 mucins in an in vitro inhibition assay. We have shown that both crude saliva and purified MUC5B and MUC7 mucins inhibit HIV-1 activity by 100% in the range from 900 Ī¼g to 0.09 Ī¼g mucin concentration.

Materials and methods

Ethics

The University of Cape Town Research and Ethics Committee approved this study (ethics approval number REC REF: 283/2004).

Materials

The ECLā„¢ Western Blotting Detection Kit was from Amersham Biosciences (Amersham UK). Nitrocellulose membrane and dialysis tubing were from Kimix (chemical and laboratory suppliers, SA). Polyclonal rabbit anti-MUC5B (Lum 5B-2), goat anti-MUC7, goat anti-rabbit and rabbit anti-goat horse radish peroxidise (HRPO) linked secondary antibodies were from Santa Cruz Biotechnology, Inc (Santa Cruz, California). The CD4+ CEM SS cells were from AIDS Research and Reference Reagent Programme (Germantown, USA). RPMI 1640, L-Glutamine and heat-inactivated fetal bovine serum were from Gibco (Massachusetts, USA). IL-2 and p24 antigen kit were from Roche Diagnostics (Germany) and Vironostika HIV-1 Antigen kit BiomĆ©rieux (France) respectively. Sepharose CL-4B and reagent solvents such as guanidinium chloride (GuHCl), phenylmethylsulfonylfluoride (PMSF), caesium chloride (CsCl), ethylenediaminetetra-acetic acid disodium salt (Na2-EDTA), N-ethylmaleimide (NEM), and 3-((3-cholamidopropyl)-dimethyl-ammonio)-1-propane-sulfonate (CHAPS) were from Sigma (UK). Trypan Blue Dye solution was from Merck (Germany).

Saliva collection

Saliva was collected from healthy symptom free 'normal' female and male volunteers (who declared a risk-free lifestyle) from the laboratory who abstained from eating and drinking for at least 2 h prior to collection. Whole saliva was stimulated by chewing on parafilm and collected into 6 M GuHCl containing a spectrum of protease inhibitors (10 mM EDTA, 5 mM NEM, 1 mM PMSF) and 0.1% CHAPS pH 6.5. Samples were collected on ice and then stored at -20Ā°C.

Sepharose CL-4B gel filtration

Crude salivary mucus was solubilised by overnight mixing at 4Ā°C on a revolving rotor. The insoluble debris was then separated from the soluble mucus by centrifugation at 4400 g for 10 min at 4Ā°C.

Aliquots of the supernatant (20 ml) were chromatographed on a Sepharose CL-4B gel filtration column equilibrated and eluted with 4 M GuHCl containing 10 mM EDTA, 5 mM NEM and 0.05% CHAPS at pH 6.5 and at a flow rate of 48 ml/h at room temperature. Following PAS and protein (A280) assays, the void (Vo) and included volume (Vi) materials were pooled separately, dialysed against three changes of distilled water at 4Ā°C and freeze-dried.

Mucin preparation

For the HIV inhibition assay, crude saliva was collected into 0.1 M Tris-HCl, 2% (w/v) EDTA and 5 mM PMSF pH 7.5 (saliva:buffer ratio 1:2). After solubilisation by overnight mixing at 4Ā°C on a revolving rotor, the insoluble debris was separated by centrifugation at 10 000 g for 10 min at 4Ā°C. The supernatant was then dialysed over three changes of distilled water at 4Ā°C and freeze-dried.

The mucin that eluted in the included volume (Vi) of the column was subjected to caesium chloride isopycnic density-gradient ultra-centrifugation, twice for 48 h at a 105 000 g and 4Ā°C in a Beckman L45 ultra-centrifuge [28]. Briefly, Vi samples dissolved in 4 M GuHCl containing a cocktail of proteolytic inhibitors (as described above) were adjusted to a density of 1.39 to 1.40 g/ml with caesium chloride prior to centrifugation. Mucin rich fractions were pooled, dialysed against three changes of distilled water at 4Ā°C and freeze-dried.

SDS-PAGE

SDS-PAGE was carried out according to the method of Laemmli [29] in a buffer containing 0.2% SDS using 4% (w/v) stacking gels and 10% separating gels [30, 31], in a Hoefer Mighty Small mini-electrophoresis system. Samples were prepared in reducing gel loading buffer containing 2% SDS, 10% glycerol, 0.01% bromophenol blue and 5% mercaptoethanol and boiled for 2 min prior to loading. After electrophoresis gels were stained for carbohydrate with PAS [32] and for protein with Coomassie Brilliant Blue G-250.

Western blotting

After gel electrophoresis mucins were transferred to a nitrocellulose membrane (Nitrocellulose, 0.22 Micron) using a semi-dry electroblotting unit at 0.8 mA/cm2. The transfer buffer used contained 192 mM glycine, 25 mM Tris, 1.3 mM SDS and 20% (v/v) methanol. After electro-blotting non-specific binding was blocked by incubating the membranes overnight in 5% (m/v) low fat milk powder in TBS, 0.05% Tween-20 (TBST) at 4Ā°C. The membranes were then washed with TBST for 3 Ɨ 5 min and incubated for 2 h with rabbit anti-MUC5B and goat anti-MUC7 polyclonal antibodies diluted in 5% (m/v) low fat milk powder in TBST at 1:500 and 1:100 dilutions respectively. The membranes were washed for 3 Ɨ 5 min with TBST and incubated for 1 h with HRPO linked secondary antibodies (goat anti-rabbit and rabbit anti-goat) diluted in 5% (m/v) low fat milk powder in TBST at 1:5000 dilution. After another TBST wash (3 Ɨ 5 min) bands that interacted with the antibodies were detected by exposing the membrane to ECL detection.

Amino acid analysis

The amino acid contents of purified MUC5B and MUC7 mucins were analysed using a high pressure liquid chromatography (HPLC) system. The analysis procedure was similar to that of Klapper [33] and Cohen and Strydom [34]. The samples were vacuum-dried and placed in a hydrolysis vessel containing some constant boiling HCl and 1% (v/v) phenol. The vessel was cleaned with nitrogen gas and sealed under vacuum. The samples were then hydrolysed in the gas phase at 110Ā°C for 24 h. Following hydrolysis, the vials were cooled and vacuum dried to remove the residual HCl. The dried samples were re-dissolved in citrate buffer pH 2.2 and injected into a HPLC column from Waters Associates, Medford, MA., packed with a cation exchange resin (sulfonated polystyrene cross-linked with divinylbenzene) and eluted with a series of buffers ranging from a low (0.25 M trisodium citrate, pH 3.05) to high (0.25 M sodium nitrate, pH 9.5) pH. Detection was carried out using post column derivatization with o-phthalaldehyde (OPA), a fluorescent reagent that reacts with all the amino acids except proline. The relative ratios of the individual amino acids for each sample was determined and compared to each other. For proline detection samples were treated with sodium hypochlorite prior to post column derivatization with o-phthalaldehyde (OPA).

Toxicity assay

The toxicity of crude saliva and purified salivary MUC5B and MUC7 mucins to the CD4+ CEM SS cells was determined by a toxicity assay. Briefly, 500 Ī¼l of the CD4+ CEM SS cells in RPMI complete containing 10% Fetal Calf Serum, 1% Penicillin/Streptomycin antibiotic, 10 Ī¼mol Fungin and 50 Ī¼mol 2-mercaptoethanol (final concentration 2.5 Ɨ 106 cells/ml) was incubated with 250 Ī¼l of IL-2 and 250 Ī¼l (0.9 mg) of crude saliva or purified salivary MUC5B and MUC7 mucins in a CO2 incubator for 24 h. As controls CEM SS cells with IL-2 only and IL-2 without CEM SS cells (blank) were used. After spinning at 1400rpm for 5 min, cells were re-suspended in 500 Ī¼l of RPMI and live and dead cells were counted using Trypan blue exclusion criteria. The percentage of viable cells was calculated as live cells/total cells Ɨ 100.

Inhibition assay

The anti-HIV-1 activities of crude saliva and purified salivary MUC5B and MUC7 mucins were tested in an inhibition assay according to the method of Nagashunmugam et al. [3]. Briefly, the crude saliva and purified salivary MUC5B and MUC7 mucins were dissolved in 0.25% PBS and (500 Ī¼l or 0.9 mg each) were mixed with 4 ml of the subtype D HIV-1 supernatant fluid (SNF) and incubated for 60 min at 37Ā°C. As controls heat inactivated HIV-1 and HIV-1 plus media (RPMI 1640 with 10% fetal calf serum and IL-2) were used. The virus was first isolated from an AIDS patient by the Department of Medical Virology, Tygerberg Hospital, University of Stellenbosch, in February 1986, and it was fully characterised and sequenced subsequently. At the end of the incubation period the mixtures (virus plus mucins) and the control (virus plus media) were filtered through 0.45 Ī¼m pore size cellulose acetate filter (25 mm diameter), and both the unfiltered and filtered samples were incubated with CD4+ CEM SS cells at 37Ā°C at a concentration of 0.5 Ɨ 106 cells/ml for 30 min, 1 h and 3 h. Cells were then washed three times with PBS to remove free virus and cultured. Supernatant fluid was harvested on Day 4 and viral replication was measured by a qualitative p24 antigen assay. Endpoints were calculated by the Reed-Muench formula and the 50% tissue culture infective dose (TCID50) was expressed as the highest dilution that produced a positive qualitative p24 antigen result. All samples were done in triplicate and the anti-HIV-1 activity of each mucin was tested in a serial tenfold dilution (10-1 to 10-4).

Results

Sepharose CL-4B gel filtration

Sepharose CL-4B gel filtration demonstrated that saliva contains two species of carbohydrate-rich mucin macromolecules which are distinguishable according to their size. Of these two populations, the glycoprotein (MG1) was excluded in the void volume (Vo) [23] and the glycoprotein (MG2) in the included volume (Vi) of the gel filtration column [23] (Fig. 1). A sharp PAS positive peak was seen eluting in the void volume and a broader peak in the included volume of the column, which was alongside a protein positive peak. The protein peak that eluted in the void volume, coinciding with the PAS positive peak, was much smaller.

Figure 1
figure 1

Sepharose CL-4B gel filtration of crude saliva. An aliquot (20 ml) of soluble human crude saliva extracted in 6 M GuHCl containing 10 mM EDTA, 5 mM NEM, 1 mM PMSF and 0.1% CHAPS pH 6.5 was chromatographed and eluted with 4 M GuHCl containing 10 mM EDTA, 5 mM NEM and 0.05% CHAPS pH 6.5 at flow rate of 48 ml/h at room temperature. Fractions were analysed for carbohydrate with PAS at 555 nm (ā—†) and for protein A280 (ā– ). Materials eluted in the void volume (Vo) and included volume (Vi) were pooled separately, dialysed against three changes of distilled water for overnight at 4Ā°C and freeze-dried.

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SDS-PAGE

To check the purity of the materials eluted in the Vo and the Vi of the gel filtration column, fractions eluting under these peaks were pooled separately, dialysed extensively against distilled water, freeze-dried and subjected to 10% SDS-PAGE and stained for protein with Coomassie Brilliant Blue G-250 (Fig. 2a and 3a) and for carbohydrate with PAS (Fig. 2b and 3b).

Figure 2
figure 2

SDS-PAGE analysis of the salivary mucus eluted in the Vo of the Sepharose CL-4B gel filtration column. Freeze-dried material (30 Ī¼g) of the Vo prepared in reducing gel loading buffer was separated by 10% SDS-PAGE and stained with Coomassie Brilliant Blue G-250 (a) and PAS (b). The molecular weight marker is indicated by Mw and lanes 1 to 6 represents samples from 6 donors.

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Figure 3
figure 3

SDS-PAGE analysis of the salivary mucus eluted in the Vi of the Sepharose CL-4B gel filtration column. Freeze-dried material (30 Ī¼g) of the Vi prepared in reducing gel loading buffer was separated by 10% SDS-PAGE and stained with Coomassie Brilliant Blue G-250 (a) and PAS (b). The molecular weight marker is indicated by Mw and lanes 1 to 6 represents samples from 6 donors.

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The PAS positive void volume material gave a strong band sitting on the top of the stacking and running gels, very characteristic of the electrophoretic behaviour of large-sized mucins (Fig. 2b) [30]. On the other hand the material that eluted in the Vi showed a prominent band of greater electrophoretic mobility and of relatively smaller size than Vo mucin, in that the mucins slightly entered the running gel (Fig. 3b). Also there were a range of fainter bands ranging in size from 66ā€“30kDa (Fig. 3b, lanes 1ā€“3 and 5 and 6). More contaminant protein associated with mucin was present in the Vi peak (Fig. 3a) than the Vo peak (Fig. 2a) suggesting the need for further purification of the material that eluted in the included volume of the column.

Mucin purification

Material that eluted in the included volume of the gel filtration column was subjected to density-gradient ultra-centrifugation in caesium chloride. Mucin rich fractions from the first density gradient (Fig. 4a) were pooled and subjected to a second spin in caesium chloride (Fig. 4b), after which the mucin rich fractions were pooled, dialysed against distilled water and freeze-dried. SDS-PAGE analysis of these mucins showed less protein contaminant (Fig. 5, lane 2), except for low molecular weight material of 30kDa and under. As indicated by the arrows, the PAS stain of the same material gave two prominent bands in the region of 220kDa and 46ā€“60kDa (Fig. 5, lane 3). Traces of material were also seen at 21.5kDa and under (Fig. 5, lane 3).

Figure 4
figure 4

Caesium chloride isopycnic density-gradient ultra-centrifugation of the material eluted in the Vi of the gel filtration column. Freeze-dried material eluted in the Vi was dissolved in 4 M GuHCl containing 10 mM EDTA, 5 mM NEM and 0.05% CHAPS pH 6.5 and adjusted to a density of 1.39 to 1.40 g/ml with caesium chloride. Density gradient centrifugation was performed in a Beckman L45 ultra-centrifuge for 48 h at 105 000 g at 4Ā°C. Fractions with high PAS (ā—†) and low protein (Lowry) (ā– ) (a) were pooled and adjust to a density of 1.39 to 1.40 g/ml with caesium chloride for a second step centrifugation (b). Mucin rich fractions with a density (ā–²) between 1.37ā€“1.42 were pooled, dialysed against three changes of distilled water for overnight at 4Ā°C and freeze-dried.

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Figure 5
figure 5

SDS-PAGE analysis of the purified Vi material. After purification, mucins were loaded onto a 10% SDS-PAGE and stained with Coomassie Brilliant Blue G-250 (lane, 1 and 2) and PAS (lane, 3). Molecular weight markers and the two mucin isoforms are indicated by lane 1and the arrows respectively.

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Western blotting

To determine the identity of the Vo and Vi mucins from the gel filtration column material eluting under these peaks was subjected to 10% SDS-PAGE and then transferred to nitrocellulose membrane and probed with rabbit anti-MUC5B and goat anti-MUC7 polyclonal antibodies respectively. The results showed that the Vo material sitting on the top of the gel is MUC5B (Fig. 6a, lanes 2 and 3) and the two bands slightly entered the running gel that interacts with the anti-MUC7 polyclonal antibody are the two glycoforms of MUC7 (Fig. 6b, lane 3). The two glycoforms of MUC7 in Figure 6b are indicated by arrows.

Figure 6
figure 6

Western blotting analysis of Vo and Vi material from the gel filtration column using rabbit anti-MUC5B and goat anti-MUC7 polyclonal antibodies. a) Lanes 1, MUC7 (negative control), 2 and 3, Vo material from two donors and 4, respiratory MUC5B (positive control) and in b) Lanes 1, crude saliva (positive control), 2, gastric mucin (negative control) and 3, purified Vi material were separated by 10% SDS-PAGE and transferred to nitrocellulose membrane. Following overnight blocking, the membranes were incubated for 2 h with rabbit anti-MUC5B (a) and goat anti-MUC7 (b) polyclonal antibodies. Membranes were then incubated for 1 h with goat anti-rabbit (a) and rabbit anti-goat (b) HRPO linked secondary antibodies and bands that interacted with the antibodies were detected by exposing the membrane to ECL detection. The arrows indicate the two glycoforms of MUC7.

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Amino acid analysis

Following the amino acid analysis (Table 1) both MUC5B and MUC7 mucins were found to contain higher amounts of threonine, serine, glutamic acid, glycine and aspartic acid. However, the amount of threonine in MUC7 is very low. Of these signature amino acids of mucins, serine, threonine, and proline were found to comprise 26% and 28% of the MUC5B and MUC7 mucins respectively.

Table 1 Amino acid composition of MUC5B and MUC7 mucins.
Full size table

Toxicity assay

Prior to the HIV inhibition assay the toxicity of the crude saliva and purified salivary MUC5B and MUC7 mucins to the CD4+ CEM SS cells was determined by toxicity assay. Based on this assay (data not shown) no cell death or toxicity of these mucins to the CD4+ CEM SS cells was detected.

Inhibition assay

Subsequent to the toxicity assay the anti-HIV-1 activities of the crude saliva and purified salivary MUC5B and MUC7 mucins were determined by HIV inhibition assay. The result revealed that after a 30 min incubation period during which the mixtures three separate mixtures (HIV-1 plus crude saliva), (HIV-1 plus MUC5B) and (HIV-1 plus MUC7) were incubated with the CD4+ CEM SS cells, no HIV-1 infection of these cells was observed (Fig. 7). Simultaneously, to determine the effect of the incubation period between the CD4+ CEM SS cells and the mixtures described above on the infectivity of these cells, incubation was carried out at different time-points (1 h and 3 h). No difference in the rate of inhibition due to time differences was detected (Fig. 7). Serial tenfold dilution (10-1 to 10-4) of the mucins was also done to determine the anti-HIV-1 activity of these mucins at the highest dilution. All the mucins showed anti-HIV-1 activity down to the concentration of 0.09 Ī¼g or in the range of 900 Ī¼g to 0.09 Ī¼g (data not shown).

Figure 7
figure 7

Inhibition of HIV-1 activity by human crude saliva and purified salivary MUC5B and MUC7 mucins. Crude saliva and purified salivary MUC5B and MUC7 mucins (0.9 mg each) were incubated with subtype D HIV-1 for 60 min and filtered through 0.45 Ī¼m pore size cellulose acetate filter. As controls HIV-1 treated with media and heat inactivated HIV-1 were used. The unfiltered samples were then incubated with CD4+ CEM SS cells at a concentration of 0.5 Ɨ 106cells/ml for 30 min, 1 h and 3 h. After PBS wash cells were cultured and viral replication was measured by a qualitative p24 antigen assay.

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In the controls, where the virus was incubated with the media only, prior to addition to the CD4+ CEM SS cells at all time points (30 min, 1 h and 3 h), 100% of HIV-1 replication or infection of the CD4+ CEM SS cells was detected (Fig. 7). However no HIV-1 infection was revealed when heat inactivated HIV-1 was used (Fig. 7).

To determine whether the HIV-1 activity of the crude saliva and purified salivary MUC5B and MUC7 mucins is by aggregation or trapping of the virus, the mixtures (HIV-1 plus crude saliva), (HIV-1 plus purified salivary MUC5B), (HIV-1 plus purified salivary MUC7) and (HIV-1 plus media), at the end of the 60 min incubation period, were filtered through 0.45 Ī¼m pore size cellulose acetate filter (25 mm diameter) and the filtrates were incubated with the CD4+ CEM SS cells at all time-points (30 min, 1 h and 3 h). While 100% of viral replication or infection of the CD4+ CEM SS cells was detected with the filtrate of the control (HIV-1 plus media) (Fig. 8), no HIV-1 replication or infection of the CD4+ CEM SS cells was detected when the filtrates from the three mixtures were used (Fig. 8).

Figure 8
figure 8

Inhibition of HIV-1 activity by human crude saliva and purified salivary MUC5B and MUC7 mucins. Crude saliva and purified salivary MUC5B and MUC7 mucins (0.9 mg each) were incubated with subtype D HIV-1 for 60 min and filtered through 0.45 Ī¼pore size cellulose acetate filter. As controls HIV-1 treated with media and heat inactivated HIV-1 were used. The filtrates of the mixtures were then incubated with CD4+ CEM SS cells at a concentration of 0.5 Ɨ 106cells/ml for 30min, 1h and 3h. After PBS wash cells were cultured and viral replication was measured by a qualitative p24 antigen assay.

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Discussion

In the present study human crude saliva was separated by Sepharose CL-4B gel filtration column into material eluting as two major PAS positive peaks in the void (MG1) and included (MG2) volumes respectively and the material under each peak identified as MUC5B and MUC7 respectively, confirming previous findings of Thornton et al [23]. Amino acid analysis further supported this material to be mucin [35]. The small protein peak that eluted in the void volume of the gel filtration column, under the large excluded PAS positive peak is very likely the protein moiety of MUC5B (Fig. 1) [31]. The elution of the larger protein peak, which begins under the included volume (Vi) PAS positive peak and elutes nearer the total volume of the column suggests that gel filtration was partially but not entirely successful in removing a considerable amount of protein contaminant from the crude saliva. SDS-PAGE analysis of the PAS positive Vi peak material, when stained for protein with Coommassie Blue, still showed protein contamination of MUC7 (Fig. 2c). This material was therefore further purified by caesium chloride density gradient ultra-centrifugation.

To avoid any possible endogenous enzymatic degradation, sample analysis was carried out in 6 M GuHCl containing protease inhibitors such as EDTA, NEM, and PMSF. According to the report by Carlstedt et al. [36] while PMSF and EDTA inhibit serine and metallo-proteases respectively, NEM which inhibits thiol proteases is reported to reduce disulfide bond formation between mucins and non-mucinous components of the saliva by blocking the free thiol groups on mucins.

Salivary mucins are known to bind with the non-mucinous components of the saliva such as amylase, lysozyme, proline-rich protiens, statherin, histatins, SIgA and lactoferrin which may change their physicochemical properties [37ā€“39]. As reported by Mehrotra et al. [40] and Zalewska et al. [41] the hydrophobic regions of mucins are responsible for these complex formations as well as for their sticky characters. As a result mucins may stick to gels and dialysis tubes during the purification and dialysis processes. Therefore in the present study CHAPS a detergent was included in the chromatography buffer to minimize the sticky characteristic and prevent loss of mucins during dialysis and column chromatography [42].

The electrophoretic behaviour of the purified saliva was typical of mucins which, because of their large size, appear at the top of the stacking and running gels (Fig. 2b and 3b, and Fig 5, lane 3) [31, 43, 44]. The MUC7 mucin showed two bands on SDS-PAGE (Fig 5, lane 3) and Western Blotting (Fig. 6b, lane 3). This result agreed with that of Reddy et al. [45], Mehrotra et al. [40] and Bolscher et al. [42], which revealed the presence of two isoforms of MUC7, designated MUC7a and MUC7b in saliva. According to these authors the two isoforms have an identical amino acid composition but a different glycosylation pattern with respect to sialic acid and fucose. In the case of MUC5B, although SDS-PAGE analysis revealed the presence of two closely situated mucin bands on the top of the gel (Fig. 2b), Western blotting gave just one band (Fig. 6a, lanes 2 and 3), again at the top of the membrane.

The amino acid analysis has shown the presence of higher amounts of threonine, serine, glycine, glutamic acid, and aspartic acid in salivary MUC5B and MUC7 mucins. This agreed with the findings of Tabak et al. [46] that, mucins contain large amounts of serine, threonine, proline, glutamic acid, glycine and alanine. The presence of methionine in a very small amount also agreed with that of Thomsson et al. [47]. Strangely enough threonine presented in smaller amount than the expected value especially in MUC7. According to Mehrotra et al. [40], this could be due to the level of oligosaccharide substitution of this residue.

It has been shown that the incubation of HIV with human whole and submandibular saliva leads to a decrease in viral infectivity and that this inhibition is considerably reduced upon filtration of the saliva [11, 15, 18]. These observations suggest that saliva-induced viral aggregation serves to clear the virus from the oral cavity and lessen the possibility of oral transmission [11]. It has also been suggested that the most likely candidate in the oral defence against AIDS is a macromolecular component [9], specifically the mucus component of oral secretions [2]. Although these researchers speculated that crude saliva [8], MUC5B and MUC7 [2], two of the known mucins in saliva [23] are potentially involved in inhibition through the entrapment of virus particles, a definitive attempt to purify, identify and individually test these purified mucins from saliva, against the AIDS virus, has not been done.

Although the HIV-1 Subtype C virus is currently the most prevalent in South Africa, the Subtype D which was used in this study was found during the early HIV epidemic in South Africa and is still prevalent in the country, although less frequently. Although we would very much have liked to use the Subtype C strain, unfortunately, the Subtype D is the only laboratory adapted strain available for an in vitro HIV assay, in the entire country. As described in the methods, this virus was first isolated from an AIDS patient by the Department of Medical Virology, Tygerberg Hospital (Cape Town, South Africa) in February 1986, and fully characterised and sequenced subsequently. Simultaneously the T cell lines, CEM-SS cells which were used in this experiment are known to produce distinct and repeatable syncytia formation when infected with HIV-1. As reported by Nara et al. [48], following the addition of HIV-1, these cells develop easily quantifiable syncytia formation in four to six days.

In this study we have demonstrated that when the HIV-1 was incubated with the crude saliva and purified salivary MUC5B and MUC7 mucins and subsequently added to the CD4+ CEM SS cells no viral replication or infection of the CEM SS cells was detected by the p24 antigen assay. However, when the HIV-1 was incubated with media instead (as control), 100% infection of the CD4+ CEM SS cells was detected. A possible explanation of the findings of this study is that when mucins are incubated with HIV, the mucins trap or aggregate the virus, leaving it entangled in the mucin mesh which is retarded by filtration through a 0.45 Ī¼m pore cellulose acetate filter [3, 8, 17, 20, 21], thus preventing the virus from entering the host cells.

To prove this hypothesis we filtered the mixtures (HIV-1 plus crude saliva), (HIV-1 plus MUC5B), (HIV-1 plus MUC7) and the control (HIV-1 plus media), at the end of the incubation period, through a 0.45 Ī¼m pore size cellulose acetate filter, and added the filtrates to the CD4+ CEM SS cells. The filtrates from each of the mixtures failed to infect the CD4+ CEM SS cells, as shown by the absence of measurable p24 activity. This suggested that the mucins aggregated all the viruses, hence leaving no free viruses in the filtrates to cause viral infection. However, the filtrates from the control (HIV-1 plus media) where mucins are absent, gave 100% HIV-1 replication or infection of the CEM SS cells. Therefore the media, unlike the mucins failed to aggregate the viruses, resulting in free viruses in the filtrate, which were then infective to the CD4+ CEM SS cells.

Although the inhibition of HIV-1 by mucins is thought to be by aggregation of the virus prior to host cell entry [3, 8, 11, 18], the specificity of this aggregation is not at all clear. The findings by Fox et al. [9] and Nagashunmugam et al. [3], which demonstrated low or no potency of saliva against herpes simplex virus (HSV), HIV-2, simian immunodeficiency virus, Epstein-Barr virus, cytomegalovirus, hepatitis B virus and adenovirus implies that the specific aggregation of HIV-1 by saliva or purified mucins could require some specificity. One other possibility is that the negative charges on mucins through sialic acid and sulphate groups [35] could be responsible for specific interactions with receptors on the virus.

This study has shown that mucus and mucins have protective properties against the HI virus in certain situations. More light needs to be shed on these processes to understand further the role of mucins against infection to be able to design further studies that will investigate the significance of mucins in HIV-AIDS.

References

  1. Fultz PN: Components of saliva inactivate human immunodeficiency virus. Lancet 1986, 2: 1215. 10.1016/S0140-6736(86)92218-X

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  2. Bolscher JGM, Nazim K, Ran LJ, Van Engelenburg FAC, Schuitemaker H, Veerman ECI, Nieuw Amerongen AV: Inhibition of HIV IIIB and clinical isolates by human parotid, submandibular, sublingual and palatine saliva. Eur J Oral Sci 2002, 110: 149-156. 10.1034/j.1600-0722.2002.11175.x

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  3. Nagashunmugam T, Friedman HM, Davis C, Kennedy S, Goldstein LT, Malamud D: Human submandibular saliva specifically inhibits HIV type 1. AIDS Res Hum Retroviruses 1997, 13: 371-376.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  4. Phillips J, Qureshi N, Barr C, Menrard DR: Low level of cell-free virus detected at high frequency in saliva from HIV-1-infected individuals. AIDS 1994, 8: 1011-1012. 10.1097/00002030-199407000-00021

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  5. Wahl SM, Worley P, Jin W, McNeely TB, Eisenberg S, Fasching C, Orenstein JM, Janoff EN: Anatomic dissociation between HIV-1 and its endogenous inhibitor in mucosal tissues. Am J Pathol 1997, 150: 1275-1284.

    PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  6. Yeh CK, Fox PC, Goto Y, Austin HA, Brahim JS, Fox CH: Human immunodeficiency virus (HIV) and HIV infected cells in saliva and salivary glands of a patient with systemic lupus erythematosus. J Rheumatol 1992, 19: 1810-1812.

    CASĀ  PubMedĀ  Google ScholarĀ 

  7. Baron S, Poast J, Cloyd MW: Why is HIV rarely transmitted by oral secretions? Saliva can disrupt orally shed, infected leukocytes. Arch Intern Med 1999, 159: 303-310. 10.1001/archinte.159.3.303

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  8. Bergey EJ, Cho MI, Blumberg BM, Hammarskjold ML, Rekosh D, Epstein LG, Levine MJ: Interaction of HIV-1 and human salivary mucins. J Acquir Immune Defic Syndr 1994, 7: 995-1002.

    CASĀ  PubMedĀ  Google ScholarĀ 

  9. Fox PC, Wolff A, Yeh CK, Atkinson JC, Baum BJ: Saliva inhibits HIV-1 infectivity. J Am Dent Assoc 1988, 116: 635-637.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  10. Goto Y, Yeh CK, Notkins AL, Prabhakar BS: Detection of proviral sequence in saliva of patients infected with human immunodeficiency virus type 1. AIDS Res Hum Retroviruses 1991, 7: 343-347.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  11. Malamud D, Davis C, Berthold P, Roth E, Friedman H: Human submandibular saliva aggregates HIV. AIDS Res Hum Retroviruses 1993, 9: 633-637.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  12. Qureshi NM, Barr CE, Seshamma T, Reidy J, Pomerantz RJ, Bagasra O: Infection of oral mucosal cells by human immunodeficiency virus type 1 in seropositive persons. J Infect Dis 1995, 171: 190-193.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  13. Yeh CK, Handelman B, Fox PC, Baum BJ: Further studies of salivary inhibition of HIV-1 infectivity. J Acquir Immune Defic Syndr 1992, 5: 898-903.

    CASĀ  PubMedĀ  Google ScholarĀ 

  14. Yeung SCH, Kazazi F, Randle CGM, Howard RC, Rizvi N, Downie JC, Donovan BJ, Cooper DA, Sekine H, Dwyer DE, Cunningham AL: Patients infected with human immunodeficiency virus type 1 have low levels of virus in saliva even in the presence of periodontal disease. J Infect Dis 1993, 167: 803-809.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  15. Kennedy S, Davis C, Abrams WR, Billings PC, Nagashunmugam T, Friedman H, Malamud D: Submandibular salivary proteases: lack of a role in anti-HIV activity. J Dent Res 1998, 77: 1515-1519.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  16. Moore BE, Flaitz CM, Coppenhaver DH, Mark Nichols C, Kalmaz GD, David Bessman J, Cloyd MW, Lynch DP, Prabhakar BS, Baron S: HIV recovery from saliva before and after dental treatment: inhibitors may have critical role in viral inactivation. J Am Dent Assoc 1993, 124: 67-74.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  17. Archibald DW, Cole GA: In vitro inhibition of HIV-1 infectivity by human salivas. AIDS Res Hum Retroviruses 1990, 6: 1425-1432.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  18. Malamud D, Nagashunmugam T, Davis C, Kennedy S, Abrams WR, Kream R, Friedman HM: Inhibition of HIV infectivity by human saliva. Oral Dis 1997, (Suppl 3):58-63.

  19. Wu Z, Van Ryk D, Davis C, Abrams WR, Chaiken I, Magnani J, Malamud D: Salivary agglutinin inhibits HIV type 1 infectivity through interaction with viral glycoprotein 120. AIDS Res Hum Retroviruses 2003, 19: 201-209. 10.1089/088922203763315704

    ArticleĀ  PubMedĀ  Google ScholarĀ 

  20. Shugars DC, Alexander AL, Fu K, Freel SA: Endogenous salivary inhibitors of human immunodeficiency virus. Arch Oral Biol 1999, 44: 445-453. 10.1016/S0003-9969(99)00003-5

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  21. Shugars DC, Wahl SM: The role of the oral environment in HIV-1 transmission. J Am Dent Assoc 1998, 129: 851-858.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  22. Rose MC, Voynow JA: Respiratory tract mucin genes and mucin glycoproteins in healthy and disease. Physiol Rev 2006, 86: 245-278. 10.1152/physrev.00010.2005

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  23. Thornton DJ, Khan N, Mehrotra R, Howard M, Veerman E, Packer NH, Sheehan JK: Salivary mucin MG1 is comprised almost entirely of different glycosylated forms of the MUC5B gene product. Glycobiology 1999, 9: 293-302. 10.1093/glycob/9.3.293

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  24. Chen Y, Zhao YH, Kalaslavadi TB, Hamati E, Nehrke K, Le AD, Ann DK, Wu R: Genome-wide search and identification of a novel gel-forming mucin MUC19/Muc19 in glandular tissues. Am J Respir Cell Mol Biol 2004, 30: 155-165. 10.1165/rcmb.2003-0103OC

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  25. The NewScientist.com news service[http://www.newscientist.com/channel/health/hiv/dn9244-unaids]

  26. Stevens W, Apostolellis A, Napier G, Scott L, Gresak G: HIV/AIDS prevalence testing-merits, methodology and outcomes of a survey conducted at a large mining organisation in South Africa. S Afr Med J 2006, 96: 134-139.

    CASĀ  PubMedĀ  Google ScholarĀ 

  27. Shaikh N, Abdullah F, Lombard CJ, Smit L, Bradshaw D, Makubalo L: Masking through averages-intraprovincial heterogeneity in HIV prevalence within the Western Cape. S Afr Med J 2006, 96: 538-543.

    PubMedĀ  Google ScholarĀ 

  28. Creeth JM, Denborough MA: The use of equilibrium-density-gradient methods for the preparation and characterization of blood-group-specific glycoproteins. Biochem J 1970, 117: 879-91.

    ArticleĀ  PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  29. Laemmli UK: Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 1970, 227: 680-685. 10.1038/227680a0

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  30. Mall AS: Physical and Chemical changes in Porcine Gastric Mucus in the Normal and Ulcerated states. In MSc thesis. University of Cape Town, Surgery Department; 1984.

    Google ScholarĀ 

  31. Mall AS, McLeod HA, Hickman R, Kahn D, Dent DM: Fragmentation pattern of mucins in normal and diseased gastric mucosae: a glycoprotein fractionates with gastric mucins purified from mucosal scrapings of cancer and peptic ulcer patients. Digestion 1999, 60: 216-226. 10.1159/000007662

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  32. Dubray G, Bezard G: A highly sensitive periodic acid-silver stain for 1,2-diol groups of glycoproteins and polysaccharides in polyacrylamide gels. Anal Biochem 1982, 119: 325-329. 10.1016/0003-2697(82)90593-0

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  33. Klapper DG: A new low cost fully automated amino acid analyser. In Methods in protein sequence analysis. Edited by: Elzinga M. New Jersey: Humana Press, Clifton; 1982:509-517.

    ChapterĀ  Google ScholarĀ 

  34. Cohen AS, Strydom DJ: Amino acid analysis utilizing phenylisothiocyanate derivatives. Anal Biochem 1988, 174: 1-16. 10.1016/0003-2697(88)90512-X

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  35. Allen A: Structure and function of gastrointestinal mucus. In Physiology of the gastrointestinal tract. Edited by: Johnson LR. New York: Raven Press; 1981:359-382.

    Google ScholarĀ 

  36. Carlstedt I, Lindgren H, Sheehan JK: The macromolecular structure of human cervical-mucus glycoproteins. Biochem J 1983, 213: 427-435.

    ArticleĀ  PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  37. Ge J, Catt DM, Gregory RL: Streptococcus mutants surface Ī±-enolase binds salivary mucin MG2 and human plasminogen. Infect Immun 2004, 72: 6748-6752. 10.1128/IAI.72.11.6748-6752.2004

    ArticleĀ  PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  38. Situ H, Bobek LA: In vitro assessment of antifungal therapeutic potential of salivary histatin-5, two variants of histatin-5, and salivary mucin (MUC7) domain 1. Antimicrob Agents Chemother 2000, 44: 1485-1493. 10.1128/AAC.44.6.1485-1493.2000

    ArticleĀ  PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  39. Tabak LA: In defence of the oral cavity: structure, biosynthesis, and function of salivary mucins. Annu Rev Physiol 1995, 57: 547-64. 10.1146/annurev.ph.57.030195.002555

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  40. Mehrotra R, Thornton DJ, Sheehan JK: Isolation and physical characterization of the MUC7 (MG2) mucin from saliva: evidence for self-association. Biochem J 1998, 334: 415-422.

    ArticleĀ  PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  41. Zalewska A, Zwierz K, Å»Ć³Å‚kowski K, Gindzienski A: Structure and biosynthesis of human salivary mucins. Acta Biochim Pol 2000, 47: 1067-1079.

    CASĀ  PubMedĀ  Google ScholarĀ 

  42. Bolscher JG, Groenink J, van der Kwaak JS, van den Keijbus PAM, van't Hof W, Veerman EC, Nieuw Amerongen AV: Detection and quantification of MUC7 in submandibular, sublingual, palatine, and labial saliva by anti-peptide antiserum. J Dent Res 1999, 78: 1362-1369.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  43. Mall AS, Merrifield E, Fourie J, McLeod HA, Hickman R: Alterations in porcine gastric mucin during the development of experimental ulceration. Digestion 1997, 58: 138-146.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  44. Pearson JP, Allen A, Parry S: A 70 000-molecular-weight protein isolated from purified pig gastric mucus glycoprotein by reduction of disulphide bridges and its implication in the polymeric structure. Biochem J 1981, 197: 155-162.

    ArticleĀ  PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  45. Reddy MS, Bobek LA, Haraszthy GG, Biesbrock AR, Levine MJ: Structural features of the low-molecular-mass human salivary mucin. Biochem J 1992, 287: 639-643.

    ArticleĀ  PubMed CentralĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  46. Tabak LA, Levine MJ, Mandel ID, Ellison SA: Role of salivary mucins in the protection of the oral cavity. J Oral Pathol 1982, 11: 1-17. 10.1111/j.1600-0714.1982.tb00138.x

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  47. Thomsson KA, Prakobphol A, Leffler H, Reddy MS, Levine MJ, Fisher SJ, Hansson GC: The salivary mucin MG1 (MUC5B) carries a repertoire of unique oligosaccharides that is large and diverse. Glycobiology 2002, 12: 1-14. 10.1093/glycob/12.1.1

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

  48. Nara PL, Hatch WC, Dunlop NM, Robey WG, Arthur LO, Gonda MA, Fischinger PJ: Simple, rapid, quantitative, syncytium-forming microassay for the detection of human immunodeficiency virus neutralizing antibody. AIDS Res Hum Retroviruses 1987, 3: 283-302.

    ArticleĀ  CASĀ  PubMedĀ  Google ScholarĀ 

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Acknowledgements

We thank Dr Jerry Rodriques for the amino acid analysis and the University of Cape Town Postgraduate Funding Office for financial support. This work was supported by the South African Medical Research Council grant CHM504-415566.

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Authors and Affiliations

  1. Department of Surgery, University of Cape Town, Cape Town, South Africa

    Habtom H Habte,Ā Anwar S Mall,Ā ZoĆ« E LotzĀ &Ā Delawir Kahn

  2. Discipline of Medical Virology, University of Stellenbosch and National Health Laboratory Service, Cape Town, South Africa

    Corena de Beer

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Correspondence to Anwar S Mall.

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Authors' contributions

HH carried out the biochemical studies and drafted the manuscript. AM conceived of the study, participated in its design and coordination and finalised the manuscript. CdB established and carried out the HIV inhibition assay. ZL participated in the biochemical studies. DK contributed ideas to the design and coordination of the study. All authors read and approved the final manuscript.

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Habte, H.H., Mall, A.S., de Beer, C. et al. The role of crude human saliva and purified salivary MUC5B and MUC7 mucins in the inhibition of Human Immunodeficiency Virus type 1 in an inhibition assay. Virol J 3, 99 (2006). https://doi.org/10.1186/1743-422X-3-99

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Virology Journal

ISSN: 1743-422X