A comparison of intraoral antimicrobial effects of stabilized stannous fluoride dentifrice, baking soda/peroxide dentifrice, conventional NaF dentifrice and essential oil mouthrinse.

The intraoral antimicrobial activity of four commercial oral products-conventional NaF dentifrice (Crest), baking soda/peroxide/NaF dentifrice (Mentadent), essential oil mouthrinse (Listerine) and SnF2 dentifrice (Crest Plus Gum Care)-have been compared in three test regimens. Formulations were compared for their ability to suppress the regrowth and apical extension of dental plaque following toothbrushing during thirty hours of non-brushing where products were used as oral rinses (30-hour plaque regrowth model). Formulations were also compared for their ability to suppress the colony-forming units (cfu) of facultative anaerobic bacteria sampled from buccal gingival surfaces following use (Gingival Surface Microbial Index-GSMI model). Lastly, formulations were compared for effects in suppressing the glycolytic metabolic activity and regrowth activity of in vivo-treated dental plaques sampled at various periods following topical use and incubated under controlled ex vivo conditions (Plaque Glycolysis and Regrowth-PGRM model). In thirty-hour plaque regrowth testing, the rank ordered antimicrobial efficacy of formulations followed SnF2 > essential oils > NaF = water = baking soda/peroxide. In GSMI testing, all formulations were shown to suppress the cfu of facultative anaerobic bacteria relative to baseline, although SnF2 treatment was observed to reduce bacterial levels to a significantly greater degree than NaF dentifrice or baking soda/peroxide dentifrice up to two hours following brushing. In PGRM testing, the SnF2 dentifrice provided significant inhibition of bacterial metabolism and regrowth following topical application when compared with the NaF dentifrice as control. The baking soda/peroxide dentifrice provided no reduction in either bacterial metabolism or regrowth in PGRM. Previous studies had demonstrated modest effects for essential oil rinse in reducing PGRM plaque regrowth, with no effects for this treatment on plaque metabolism. Overall, these results demonstrate that SnF2 dentifrice provides substantial intraoral antimicrobial effects. The essential oil mouthrinse also exhibits significant intraoral antimicrobial effects, albeit apparently less than SnF2 dentifrice. The baking soda/peroxide dentifrice did not produce any antimicrobial effects following in vivo use compared with conventional dentifrice. These results provide mechanistic rationale for the chemotherapeutic efficacy of SnF2 and essential oil formulations in reducing gingivitis, while providing no support for the expectation of clinical efficacy for formulations containing baking soda and peroxide.

Suspected lead poisoning in a public school.

Reports of lead exposure can generate considerable public concern, particularly when children are involved. In December, 1996, a public elementary school in rural Utah was found to have elevated concentrations of lead in its drinking water. The local public health department responded by instituting remediation of the water supply and by warning parents of the possible danger to their children. Subsequent blood lead testing in 116 of the approximately 300 children involved showed an average lead concentration in the range expected for the U.S. population at large. One of the 116 specimens was marginally elevated and was probably unrelated to the school drinking water. Reducing lead exposure is an important public health concern which sometimes generates a response out of proportion to the danger involved.

Assessing the efficacy of three dentifrices in the treatment of dentinal hypersensitivity.

A multicenter clinical trial conducted by the authors compared the desensitizing efficacy of a new 5 percent potassium nitrate: 0.243 percent sodium fluoride dentifrice along with two clinically proven, commercially available desensitizing dentifrices to a placebo dentifrice. Sensitivity to cold air and tactile stimulation, along with patients' subjective assessments, were evaluated to assess the dentinal desensitizing efficacy of the test dentifrices. Results demonstrated that after four weeks, participants who used the new dentifrice formulation experienced significant decreases in dentinal sensitivity compared to the placebo group for all measured indexes.

Transfection of a manganese-containing superoxide dismutase gene into hamster tracheal epithelial cells ameliorates asbestos-mediated cytotoxicity.

To determine if overexpression of manganese-containing SOD (MnSOD) alters cell sensitivity to asbestos, an expression cassette containing murine MnSOD cDNA was cotransfected with pSV2neo, a plasmid conferring resistance to the antibiotic G418, into a diploid cell line of hamster tracheal epithelial (HTE) cells. Pools of G418-resistant transfectants were characterized by Southern and Northern blot analyses and enzyme activity assays. Although increases in MnSOD gene copies in individual cell pools ranged from approximately 7- to 86-fold in comparison to cells transfected with pSV2neo alone, steady-state levels of MnSOD mRNA were increased only by 1.4-to 2.3-fold. Despite modest increases in MnSOD mRNA, significant elevations in MnSOD enzyme activity were observed in pools of G418-resistant cells. MnSOD-transfected cell lines were more resistant to the cytotoxic effects of crocidolite asbestos using a sensitive colony-forming efficiency (CFE) assay. These data show that MnSOD has a direct role in cell defense against asbestos-induced cytotoxicity, an oxidant-dependent process.

Overexpression of manganous superoxide dismutase (MnSOD) in pulmonary endothelial cells confers resistance to hyperoxia.

Treatment of cells or organisms with agents that increase the expression of MnSOD confers resistance to certain types of oxidative damage. However, since these treatments also affect other cellular systems with antioxidant capabilities, the role of MnSOD remains uncertain. To better determine whether increased MnSOD expression confers increased resistance to oxidant stress, a eukaryotic expression vector harboring a mouse MnSOD cDNA was constructed. Bovine lung microvessel endothelial cells were co-transfected with the MnSOD expression vector and pSV2-neo, which contains the neor gene and provides a dominant selectable marker. Control clones were generated by transfecting the cells with psV2-neo alone. Stably transfected cell lines were selected and cell lines overexpressing MnSOD were confirmed by Northern blotting, immunoblot analysis, and activity gels. The activities of copper/zinc superoxide dismutase, catalase, and glutathione peroxidase were examined, and no increase in activity of any of these enzymes was detected. Cells were exposed to hyperoxic challenge by treatment with 95% O2 and 5% CO2 for 24 h. Viability was assessed by a clonogenic assay. The cell lines that overexpressed MnSOD showed a twofold increase in survival compared to control cells. These results demonstrate a significant resistance to hyperoxia induced oxidative stress in endothelial cells overexpressing MnSOD.

Expression of human catalase in acatalasemic murine SV-B2 cells confers protection from oxidative damage.

Reactive oxygen species have been implicated in aerobic organisms as causative agents in damage to DNA, proteins, and lipids. Catalase is a major enzyme in the defense against such oxidant damage. To determine whether increased catalase expression confers greater resistance to oxidant stress, a eukaryotic expression vector harboring a human catalase cDNA clone was constructed. Acatalasemic murine fibroblasts were then co-transfected with that catalase expression vector and pSV2-neo, and successfully transfected cells were identified by their ability to grow in the presence of geneticin. Clones that contained integrated copies of the catalase expression vector were identified by Polymerase Chain Reaction (PCR) analysis. Stably transfected geneticin-resistant cell lines that overexpressed catalase in potentially positive cell lines were confirmed by catalase enzyme assays. To examine the physiological relevance of catalase overexpression, cells were exposed to oxidant stresses (hydrogen peroxide and hyperoxia), and survival rates were determined. Results demonstrated a significant resistance to oxidative stress in cells overexpressing catalase when compared to controls. These transfected cell lines will provide important models for further evaluation of the role of catalase in protecting cells against the toxic effects of oxygen-derived free radicals and their derivatives.

Site-directed alanine mutagenesis of Phe33, Arg35, and Arg42-Ser43-Lys44 in the human gonadotropin alpha-subunit.

Residues Phe33 and Arg35, individually, and a composite mutation of residues Arg42, Ser43, and Lys44 were changed to alanine in the human glycoprotein hormone common alpha-subunit using site-directed mutagenesis. These specific residues are highly conserved across species and have by chemical modification and synthetic peptide approaches been implicated in the binding of human chorionic gonadotropin (hCG) to leutinizing hormone (LH) receptor. In the present study we tested the hypothesis that specific alpha-subunit amino acid residues which stabilize the hormone receptor interaction for hCG have the same function in human follicle-stimulating hormone (hFSH). Wild type or mutant alpha-subunit cDNAs were coexpressed with wild type hFSH or hCG beta cDNA in sialylation defective Chinese hamster ovary cells. Recombinant hormones were tested in a radioligand receptor competition assay, using rat testis membranes as a source of FSH and LH receptors. Mutant hFSH heterodimers F33A-FSH, R35A-FSH, Arg42-Ser43-Lys44/Ala42-Ala43-Ala44- FSH all displaced 125I-hFSH in a similar fashion, indicating that these residues are not important for binding of hFSH to the rat FSH receptor. On the other hand, F33A-CG evidenced a 5-fold decrease in binding, while R35A-CG had over a 100-fold decrease in binding to the rat LH receptor when compared to the wild type recombinant hCG. These data demonstrate that a receptor-binding site on the common alpha-subunit which is very important for hCG binding to LH receptor is not important for the binding of hFSH to FSH receptor. Our interpretation of these findings is that there are fundamental structural differences in the receptor interface contacts of the common alpha-subunit, which stabilize receptor binding among members of the glycoprotein hormone family.

The flanking amino acids of the human follitropin beta-subunit 33-53 region are involved in assembly of the follitropin heterodimer.

Previous analyses of the topology of human follitropin (hFSH) with monoclonal antibodies and antipeptide antibodies have led to a current operating hypothesis that some amino acids within the hFSH beta 33-53 region are surface oriented, and others participate in subunit contact. Protein structural analysis predicts beta-turns within this region, and the immunochemical studies indicate that the ends may be involved in subunit contact. In this study, hFSH beta was mutagenized to change 34TRDL37 to 34AAAA37 or 48QKTCT52 to 48AAACA52, allowing us to study the ends of the hFSH beta 33-53 sequence contiguous with the hFSH beta sequence. Wild-type and mutant cDNAs were coexpressed with alpha-subunit cDNA in CHOPro-5 cells. Wild-type hFSH was secreted from cells cotransfected with wild-type hFSH alpha and hFSH beta cDNAs, as expected. However, heterodimeric hFSH was minimally detected in the medium from cells transfected with the 34TRDL37 mutant and was not detected in the case of the 48QKTCT52 mutant. Analysis of cell lysates (intracellular FSH) by immunoprecipitation and polyacrylamide gel electrophoresis showed that wild-type and mutant beta-subunits were indistinguishable and recoverable intact from each cell line. Additionally, analysis of lysates with a conformation-specific monoclonal antibody 3G3 revealed that similar levels of properly folded beta-subunit were produced in cells expressing wild-type or either mutated beta-subunit. These data indicate that the flanking amino acids of the hFSH beta 33-53 region, in particular 48QKTCT52, are critical for assembly of hFSH heterodimer.

Examination of osteoblast-orthopaedic biomaterial interactions using molecular techniques.

Molecular techniques can be used to elucidate the effects of extended periods of cell-biomaterial interactions on the time-course and level of expression of particular genes which determine cellular phenotype. We used the polymerase chain reaction to demonstrate the expression of genes for the bone-related proteins osteocalcin, osteonectin and osteopontin by neonatal rat calvarial osteoblasts. In addition, Northern blotting was subsequently used to show that messenger RNAs encoding osteonectin and osteopontin were consistently expressed during a 5 wk period of interaction of osteoblasts with Ti-6Al-4V, a commercial brand of hydroxyapatite, and tissue culture polystyrene.

IL-6 enhances TNF-alpha- and IL-1-induced increase of Mn superoxide dismutase mRNA and O2 tolerance.

Tumor necrosis factor-alpha (TNF-alpha), interleukin-1 alpha (IL-1), and interleukin-6 (IL-6) are multifunctional cytokines produced by a number of cells in response to endotoxin. We have previously demonstrated (M.-F. Tsan, J. E. White, T. A. Santana, and C. Y. Lee. J. Appl. Physiol. 68: 1211-1219, 1990, and M.-F. Tsan, C. Y. Lee, and J. E. White. J. Appl. Physiol. 71: 688-697, 1991) that tracheal insufflation of 5 micrograms of TNF-alpha or 1 microgram of IL-1 markedly protects rats against O2 toxicity and enhances pulmonary Mn superoxide dismutase (Mn SOD) activity. We now report that TNF-alpha and IL-1 at subprotective doses, e.g., 1 and 0.2 micrograms, respectively, act synergistically in protecting rats against O2 toxicity. Likewise, TNF-alpha and IL-1 at 0.005 microgram/ml each act synergistically in enhancing endothelial cell Mn SOD, but not Cu,Zn SOD mRNA levels. IL-6 at 5 or 10 micrograms provides no protective effect in rats against O2 toxicity and at up to 0.5 microgram/ml has no apparent effect on endothelial cell Mn or Cu,Zn SOD mRNA levels. However, IL-6 markedly enhances TNF-alpha- and IL-1-induced increases in Mn SOD mRNA levels and O2 tolerance. These results support an important role of Mn SOD in the protection against O2 toxicity.

Somatic cell mapping of bovine EC-SOD and SOD1L loci.

cDNA probes of human extracellular superoxide dismutase (EC-SOD) and bovine superoxide dismutase 1 (SOD1) genes were hybridized to Southern blots containing genomic DNAs from cow-rodent somatic cell lines segregating bovine chromosomes. The SOD1 probe identified two loci: the coding locus (SOD1), which mapped to bovine U10; and a related locus (SOD1L), which mapped to U11. EC-SOD mapped to bovine U15. The mapping of EC-SOD to human chromosome 4, and our mapping of EC-SOD to U15, further defines a region of extensive syntenic conservation between humans and domestic cows.

Mn and Cu/Zn SOD expression in cells from LPS-sensitive and LPS-resistant mice.

We examined the effect of lipopolysaccharide (LPS) treatment on the expression of manganese and copper/zinc superoxide dismutase (MnSOD and Cu/ZnSOD) mRNA and protein in resident peritoneal macrophages and lung endothelial cells derived from LPS-sensitive (LPS-s) and LPS-resistant (LPS-r) mice. Macrophages from both LPS-s and LPS-r mice treated with LPS for 24 h produced increased levels of MnSOD mRNA and protein. In contrast, levels of lung endothelial cell MnSOD mRNA and protein from LPS-s mice were increased by LPS treatment, while no increases in these parameters were observed in endothelial cells from LPS-r mice. Tumor necrosis factor-alpha (TNF alpha) treatment, however, did increase levels of MnSOD mRNA in both LPS-s and LPS-r endothelial cells to an equal extent. Both macrophage and endothelial cell Cu/ZnSOD mRNA and protein levels were not significantly affected by LPS treatment. These results demonstrate that the mutation that affects susceptibility to LPS in LPS-r mice exerts a differential influence on MnSOD inducibility in a cell specific manner.

Regulation of antioxidant enzyme expression in LPS-treated bovine retinal pigment epithelial and corneal endothelial cells.

Retinal pigment epithelial (RPE) and corneal endothelial (CE) cells, because of their locations and functions, are continuously exposed to toxic oxidants. Protection from these toxic materials may be due, in part, to the action of endogenous antioxidant enzymes. We have established the presence of mRNAs that encode antioxidant enzymes in bovine RPE and CE cells and have determined the effect of bacterial lipopolysaccharide (LPS) on their expression. The most striking change in antioxidant enzyme expression is an increase in the level of mitochondrial manganous superoxide dismutase (MnSOD) mRNA in the LPS-treated RPE and CE cells. This increase in mRNA expression is accompanied by a slight increase in MnSOD activity as determined by SOD activity gels.

Differential expression and isozymic composition of sn-glycerol-3-phosphate dehydrogenase in tissues from variant lines of Drosophila melanogaster.

The tissue-specific expression and isozymic composition of Drosophila sn-glycerol-3-phosphate dehydrogenase (GPDH) (EC 1.1.1.8) have been determined for a high-activity control line and two variant lines that alter either the temporal or systemic expression of GPDH through a reduction in rates of polypeptide synthesis. The temporal variant exhibits a reduction in enzyme levels in all larval tissues and in the adult abdomen, while levels of activity in the adult thorax are equal to the control line. Isozymic analyses of these tissues demonstrate that it is the GPDH-3 species that is reduced in a temporal and tissue-specific manner. In contrast, the systemic variant demonstrates a uniform reduction of all isozymic species in each tissue and developmental stage. Analyses of the tissues of F1 hybrid offspring of each variant line and appropriately marked electrophoretic variants demonstrate that the tissue-specific effects observed are due to cis-acting elements that are tightly linked to the structural gene.

Molecular basis for tumor necrosis factor-induced increase in pulmonary superoxide dismutase activities.

Tracheal insufflation of tumor necrosis factor (TNF) enhances pulmonary antioxidant enzyme activities and protects rats against oxygen toxicity (J. Appl. Physiol. 68: 1211-1219, 1990). We now report that tracheal insufflation of TNF selectively induced pulmonary Mn-superoxide dismutase (SOD) mRNA in normoxia- and hyperoxia-exposed rats, leading to increased amounts of Mn-SOD specific protein and enzyme activity. Tracheal insufflation of TNF had no effect on the levels of pulmonary Cu,Zn-SOD mRNA or specific protein. Hyperoxia alone also selectively induced pulmonary Mn-SOD mRNA. However, the hyperoxia-induced increase in Mn-SOD mRNA was not associated with an increase in Mn-SOD specific protein or enzyme activity. The results suggest that the increased pulmonary Mn-SOD in TNF-insufflated rats may contribute to the TNF-induced protection against oxygen toxicity.

Molecular analysis of an acatalasemic mouse mutant.

The Csb acatalasemia mouse mutant differentially expresses reduced levels of catalase activity in a tissue specific manner. In order to pinpoint the molecular lesion that imparts the acatalasemia phenotype in Csb mice we have utilized the polymerase chain reaction technique to isolate catalase cDNA clones from control and Csb mouse strains. Sequence analyses of these cDNA clones have revealed a single nucleotide difference within the coding region of catalase between control and Csb mice. This nucleotide transversion (G----T) is located in the third position of amino acid 11 in the catalase monomer. In control mouse strains glutamine (CAG) is encoded at amino acid 11, while in Csb mice this codon (CAT) encodes histidine. This amino acid is located within a region that forms the first major alpha-helix in the amino-terminal arm of the catalase subunit and, as such, may render the catalase molecule unstable under certain physiological conditions.

A rapid and convenient procedure for identifying recombinant plasmids.

We describe an improved method for identifying plasmids that contain recombinant DNA inserts. The protocol is inexpensive and easy to perform and allows for the examination of small colonies that might normally be excluded from this type of analysis.

Expression of bovine and mouse endothelial cell antioxidant enzymes following TNF-alpha exposure.

Endothelial cells are primary targets for injury by reactive oxygen species. Endothelial catalase, copper-zinc superoxide dismutase (CuZnSOD), and manganous superoxide dismutase (MnSOD) provide potential antioxidant enzymatic defenses against oxidant-induced cellular damage. Previous studies in vivo and in vitro have demonstrated that in certain cell types exposure to oxidants may increase the expression of one or more of these antioxidant enzymes, thus providing greater intracellular potential to withstand oxidant-induced cell stress. To test whether endothelial antioxidant enzyme expression is influenced by similar oxidant-induced stresses in vitro, we have exposed endothelial cells to tumor necrosis factor-alpha (TNF-alpha) and have measured levels of catalase, CuZnSOD and MnSOD mRNA, and protein. Our results demonstrate a selective increase of MnSOD mRNA, with coordinate increases of both MnSOD protein and enzyme activity in endothelial cells treated for 24/h with TNF-alpha. In contrast, levels of catalase and CuZnSOD mRNA and protein remained unchanged in these cells after TNF-alpha treatment. These observations were made in microvessel endothelial cells derived from murine and bovine sources. Our results indicate that TNF-alpha can act specifically to increase enzymatic antioxidant potential in endothelial cells by induction of a particular antioxidant enzyme encoding mRNA species. These data demonstrate the capacity of endothelial cells to mount an antioxidant defense in response to exposure to an inducer of oxidative damage.