Dennis Moe

The buffer capacity and buffer systems of human whole saliva measured without loss of CO2

The buffer capacity of unstimulated (UWS) and stimulated (SWS) whole-mouth saliva involves three major buffer systems. The aim was to determine the buffer capacity of UWS and SWS at specific pH in the interval from pH 7.5 down to pH 3.0. The contribution of each of the buffer systems was also determined under conditions resembling those in the mouth. UWS and SWS were collected from 20 healthy volunteers; the saliva was collected under paraffin oil in order to avoid loss of CO2. The buffer capacity of UWS and SWS in samples with and without bicarbonate (HCO3-) and CO2 were measured at various pH by acid titration in a closed system at 36 C. The mean concentrations of the buffer systems in UWS (mean flow rate 0.55 ml/min) were 4.4 mmol/l HCO3-, 4.5 mmol/l phosphate (of which 1.3 mmol/l was present in the form of HPO4(2-)), 1876 microg/ml protein; the saliva pH was 6.8 and the P(CO2) 29.3 mmHg. The corresponding mean concentrations in SWS (mean flow rate 1.66 ml/min) were 9.7 mmol/l HCO3-, 3.8 mmol/l phosphate (of which 1.9 mmol/l was present in the form of HPO4(2-)), 1955 microg/ml protein; pH 7.2 and P(CO2) 25.7 mmHg, The highest buffer capacity of UWS and SWS was 6.0 and 8.5 mmol H+ /(1 saliva*pH unit) at pH 6.25, respectively. At saliva pH in the range from pH 7 down to pH 5, the following had significant impact on buffer capacity: the HCO3- concentration (p < 0.001), the flow rate (p < 0.01), and the pH of the saliva (p < 0.05). At acidic pH in the range from pH 5 down to pH 4, however, only the protein concentration had a significant impact on buffer capacity (p < 0.01).

Binding of Griffonia simplicifolia 1 isolectin B4 (GS1 B4) to α-galactose antigens

Glycoconjugates with terminal Galα1–3Galβ1–4GlcNAc sequences (α‐galactosyl epitopes, natural xenoreactive antigens) are present on various tissues in pigs and are recognized by human anti‐αgalactosyl (αGal) antibodies1. Hence xenotransplantation (pig‐to‐human) would trigger immune reactions involving complement activation and lead to the hyperactute rejection of the graft. Xenoreactive antigens are often studied by using the lectin Griffonia simplicifolia 1 isolectin B4 (GS1 B4), which shows high affinity to galactose. We here estimate the specificity of GS1 B4 for detecting various galactosyl epitopes by measuring lectin binding to neoglycoproteins, thyroglobulin and pig skeletal muscle. Enzyme linked lectin assays confirmed that GS1 B4 was highly specific to α‐galactosylated neoglycoproteins while the lectin did not detect a β‐galactosylated ligand. The length of the sugar chains influenced the lectin–carbohydrate interaction. A monosaccharide linked to serum albumin showed higher lectin affinity than did neoglycoproteins with di‐ and tri‐α‐galactosyl epitopes. When the carbohydrate was extended, as in the xenoreactive pentasaccharide (Galα1‐3Galβ1‐4GlcNAcβ1‐3Galβ1‐4Glc), the carbohydrate– lectin interaction was meagre. Not only the terminal, but also the subterminal sugar affected the lectin binding because the GS1 B4 affinity to Galα1‐3Gal was much stronger than to Galα1‐3GalNAc. In bovine and porcine thyroglobulin most αGal epitopes appear to be cryptic, but are unmasked by a heat denaturation. In pig skeletal muscle there was lectin reaction not only in the muscle capillaries, but also in the connective tissue and intracellularly in muscle fibres. In Western blots of isolated proteins from pig muscle at least three bands were strongly stained after incubation with lectin.

Sirius Red and Acid Fuchsin Staining Mechanisms

The purpose of the study was to investigate the staining mechanism of acid fuchsin and Sirius red. Acid (poly-glutamic acid), neutral (poly-hydroxyproline) and basic (poly-arginine, poly-histidine, poly-lysine) poly-amino acids, collagen types I, II and III, and arginine- and lysine-containing histones were used as test substances applied to nitrocellulose membranes as dot blots. Five micrometer sections of granulation tissue on slides were tested in parallel. Some dots and sections were treated with chloramine-T before staining with acid fuchsin and Sirius red and some with 1 M NaOH after staining. The acid and neutral poly-amino acids were not stained, but the basic amino acids polylysine and poly-arginine, poly-amino acids containing these basic amino acids and the histones and the collagens exhibited intense staining. Oxidative deamination by chloramine-T abolished the staining and 1 M NaOH removed the staining except in the case of poly-arginine. Tissue sections treated in the same way showed a considerable decrease in staining after oxidative deamination with chloramine-T; in particular, the staining of the smaller fibers was abolished. The staining was totally removed by destaining with 1 M NaOH. Therefore, acid fuchsin and Sirius red are not selectively bound to collagen; they are also bound to other proteins containing basic amino acids, and staining to a large extent is influenced by electrostatic forces. The staining seems not to be selective for collagen, and one must account for this when quantitative conclusions are drawn from collagen methods using these stains.

Effect of Saliva Composition on Experimental Root Caries

The aim of this study was to determine the effect of saliva composition on caries lesion development independently of the flow rate of unstimulated whole saliva (UWS) and other caries-related variables such as lesion progression time, oral hygiene level, and fluoride exposure. We hypothesized that this could be done by developing experimental root caries under carefully controlled conditions in situ in test subjects with UWS flow rates within a narrow window of normalcy. Fifteen female and 5 male subjects (66 ± 6 years) were selected for the study according to their UWS flow rates between 0.2 and 0.4 ml/min. All subjects developed experimental root caries lesions during a 62-day period in which UWS as well as stimulated whole saliva (SWS) were repeatedly collected and analysed for flow rate, pH, buffer capacity, inorganic, and organic composition. Caries lesion development was determined by quantitative microradiography. The mean UWS flow rate was 0.30 ± 0.05 ml/min. Significant negative correlations were obtained between UWS total phosphate concentration and mineral loss (ΔZ; rs = –0.72, p < 0.001) and UWS total protein concentration and ΔZ (rs = –0.70, p < 0.01). SWS and its constituents had only limited or no effect on ΔZ. Qualitative UWS protein analysis (SDS-PAGE) revealed that subjects with low ΔZ values had broader and more stained amylase bands than subjects with high ΔZ values. These findings were confirmed quantitatively by HPLC. We conclude that, within a group of subjects with normal UWS flow rates, the UWS composition was more important for caries lesion development than the SWS composition. Furthermore, high UWS concentrations of phosphate, protein, and amylase were caries-protective.

Biotin carboxylases in mitochondria and the cytosol from skeletal and cardiac muscle as detected by avidin binding

Biotin carboxylases in mammalian cells are regulatory enzymes in lipogenesis and gluconeogenesis. In this study, endogenous biotin in skeletal and cardiac muscle was detected using avidin conjugated with alkaline phosphatase and applied in high concentrations to muscle sections. The avidin binding was subsequently visualized by histochemical demonstration of the alkaline phosphatase activity. All cardiac muscle cells showed high affinity for avidin with only the nuclei and the intercalated discs remaining unstained. In skeletal muscle a diffuse reaction could be detected in the sarcoplasm of the muscle fibres. A granular reaction was noted in the same fibres that showed activity for succinic dehydrogenase. The specificity of the coloured reaction product in the muscle sections was investigated and is suggested to be caused by avidin binding to biotin moieties in mitochondria and the cytosol. Mitochondrial and cytosolic preparations of skeletal muscle were electrophoresed in sodium dodecyl sulphate gels. After blotting and incubation with conjugated avidin, two bands with molecular weights of 75 kDa and 130 kDa respectively were evident in the mitochondrial preparation. It is suggested that the 75-kDa band represents comigration of the biotin-containing subunits of propionyl-CoA carboxylase and methylcrotonyl-CoA carboxylase. The 130-kDa band may represent the biotin-containing pyruvate carboxylase. In the cytosolic preparation a 270-kDa band was stained in blots that had been incubated with conjugated avidin; this band is suggested to represent acetyl-CoA carboxylase. A 190-kDa cytosolic band might be a cleavage product of acetyl-CoA carboxylase. We propose that using alkaline phosphatase-conjugated avidin it is possible to detect the mitochondrial and cytosolic biotin-dependent carboxylases in striated muscle.

Optimal Drinking Water Composition for Caries Control in Populations

Apart from the well-documented effect of fluoride in drinking water on dental caries, little is known about other chemical effects. Since other ions in drinking water may also theoretically influence caries, as well as binding of fluoride in the oral environment, we hypothesized that the effect of drinking water on caries may not be limited to fluoride only. Among 22 standard chemical variables, including 15 ions and trace elements as well as gases, organic compounds, and physical measures, iterative search and testing identified that calcium and fluoride together explained 45% of the variations in the numbers of decayed, filled, and missing tooth surfaces (DMF-S) among 52,057 15-year-old schoolchildren in 249 Danish municipalities. Both ions had reducing effects on DMF-S independently of each other, and could be used in combination for the design of optimal drinking water for caries control in populations.

Immunohistochemistry of the intercellular matrix components and the epithelio-mesenchymal junction of the human tooth germ.

SummaryThe immunohistochemical localization of heparan sulphate, collagen type I, III and IV, laminin, tenascin, plasma- and cellular fibronectin was studied in tooth germs from human fetuses. The lamina basalis ameloblastica or membrana preformativa, which separates the pre-ameloblasts from the pre-dentin and dentin, contained heparan sulphate, collagen type IV, laminin and fibronectin. Enamel reacted with antifibronectin, but the reaction varied depending on the type of fibronectin and the source of antibody. In early pre-dentin, collagen type I, laminin, tenascin and fibronectin were present. In late pre-dentin and dentin collagen type I was found in intertubular dentin and in the zone between enamel and dentin. The close relationship between collagen type I in dentin and fibronectin in immature enamel is interesting, as it may contribute to the stabilization of the amelodentinal interface. In dental pulp, collagen type IV and laminin were found in the endothelial basement membranes. Collagen type I and III, tenascin and fibronectin were localized to the mesenchymal intercellular matrix.The results of this study have supported the assumption that the lamina basalis ameloblastica is a basement membrane, and have lead to the suggestion that ameloblasts are producers of fibronectin or a fibronectin-like substance.

Antikeratin antibodies in routine diagnostic pathology

Ten commercially available antikeratin antisera were tested immunohistochemically on fresh frozen and formalin‐fixed paraffin‐embedded tissue. Eight of the antisera were in addition tested on protein‐immunoblottings. For six of the antisera a good correspondence was found between our immunoblots and data given by the manufacturers. Two monoclonal antisera did not react with keratinproteins. On immunohistochemical testing two of the antibodies showed qualitatively identical staining on both frozen and paraffin sections without background staining. Three of the antibodies reacted weakly or not at all on paraffin sections but gave acceptable staining on frozen sections. Three of the antibodies showed acceptable staining on paraffin sections, but background staining on frozen sections and one antibody gave the reverse staining pattern. For one of the antibodies it was impossible to obtain an acceptable staining due to high non‐specific binding of the secondary antibody. None of the antikeratins were true panepithelial tumour markers as all of them failed to detect keratin in at least one of the epithelial tumours. However, a combination of two or three antikeratins (Hybritech AE1 + AE3, Becton Dickinson No 7650, DAKO A622) covered most or all epithelial tumours examined. It is concluded that commercially available antisera show great variability with respect to quality and reactivity indicating that the majority need further purification, characterization and testing on tissues before they are introduced on the commercial market.

Lectin interactions with alpha-galactosylated xenoantigens.

α‐Galactosylated xenoantigens (Galα1‐3Galβ1‐4GlcNAcβ1 and Galα1‐3Galβ1‐4GlcNAcβ1‐3Galβ1‐4Glc) are often detected with the α‐Gal specific lectin Griffonia simplicifolia 1 isolectin B4 (GS1 B4). However, this lectin exhibits a broad and variable specificity for carbohydrates terminating in α‐Gal. Thus, both false positive and false negative results may occur when GS1 B4 is used to determine natural antigens in xeno (pig‐to‐primate) transplantation research. To refine the tools for detecting α‐galactosylated antigens we have studied the binding of various α‐galactophilic lectins to α‐galactosylated neoglycoproteins. The lectins were: Euonymus europaeus agglutinin (EEA), Griffonia simplicifolia 1 isolectin B4 (GS1 B4), Maclura pomifera agglutinin (MPA) and Pseudomonas aeruginosa agglutinin (PA‐IL). Although both GS1 B4 and MPA strongly bound glycoconjugates terminating in Gal there seems to be some differentiation in their sugar binding preferences. MPA was the only lectin that showed high affinity for the pentasaccharide Galα1‐3Galβ1‐4GlcNAcβ1‐3Galβ1‐4Glc and for the Galα‐glycans on non‐primate thyroglobulin. The length of the xenoantigenic carbohydrate chain may influence the nature of the inhibition when a simple sugar is used to inhibit GS1 B4 binding to the xenoantigen. Inhibition studies of MPA GS1 B4 interaction further suggest that both lectins attach to the same site of the carbohydrate antigen and that GS1 B4 in addition binds to at least one other site that has no affinity for MPA. When lectins are used for recognition and investigation of natural Galα‐antigens, we propose that GS1 B4 and MPA should accompany each other.

The protein effect on determination of DNA with Hoechst 33258

The present study was designed to afford a critical review of the effect of proteins on the Hoechst 33258 method for determination of DNA of crude homogenates. A considerable effect of proteins on the fluorescence was observed when the concentration exceeded 100 micrograms BSA equivalent protein. Below that value, practically no effect of proteins was noted. We used proteinase K to remove the proteins, but dilution of homogenates could be used as well. Moreover, we found that the concentration of the fluorochrome should be between 1 microgram and 2 micrograms when microgram levels DNA are to be determined.