Optimal conditions for 4-hydroxybenzoyl- and 2-furoylhydrazine as reagents for the determination of carbohydrates, including ketosamines

4- Hydroxybenzoylhydrazine ( PAHBAH ) reacts with glucose in hot aqueous solution when alkali exceeds aroylhydrazine concentration. The related 2- furoylhydrazine ( FAH ) reacts at lower alkali concentrations, making this an attractive alternative carbohydrate reagent since it is (unlike PAHBAH ) freely water soluble. FAH reacts with monosaccharides more slowly than does PAHBAH , giving about half the color. Its specificity and behavior with a bismuth catalyst parallel those of PAHBAH . Solutions which contain 0.05 mol/liter PAHBAH with 1.5 mmol/liter bismuth III (as tartrate complex) and 0.5 mol/liter sodium hydroxide, or 0.01 mol/liter FAH with 1.5 mmol/liter bismuth III and 0.1 mol/liter sodium hydroxide are sensitive reagents for quantitative analysis, giving stable colors with many carbohydrates within 10 min at 75 degrees C. Ketosamines react more rapidly than glucose at lower temperatures and undergo similar reactions in less alkaline solutions. At pH less than 8, the reaction is specific for these 1- aminohexoses , and FAH can be used as a reagent for their assay.     

Parallel on-line detection of a methylbismuth species by hyphenated GC/EI-MS/ICP-MS technique as evidence for bismuth methylation by human hepatic cells

Methylation of metal(loid)s by bacteria or even mammals is a well known process that can lead to increased toxicity for humans. Nevertheless, reliable analytical techniques and tools are indispensable in speciation analysis of trace elements, especially since environmental or biological samples are usually characterised by complex matrices. Here the methylating capability of hepatic cells was observed in vitro. HepG2 cells were incubated with colloidal bismuth subcitrate, bismuth cysteine and bismuth glutathione, respectively for a period of 24 h. For identification the cell lysate was ethylated by sodium tetraethyl borate under neutral conditions. After cryo focussing by purge and trap, the bismuth speciation was carried out via GC/EI-MS/ICP-MS. Colloidal bismuth subcitrate and bismuth cysteine were methylated by HepG2 cells, while no methylated bismuth species was detected after incubation with bismuth glutathione.     

Bismuth staining for light and electron microscopy.

Bismuth salts on aldehyde fixed tissue give a highly selective pattern of staining suitable for light and electron microscopy. Structures stained include the nucleolus, ribosomes, inter- and perichromatin granules, the Golgi complex beads and the outer face of the tubule doublets of mouse sperm, certain neurosecretory vesicles believed to contain biogenic amines, some junctions (some central synapses, neuromuscular junctions, tight junctions), specialized membranes such as the post acrosomal dense lamina of mouse sperm and the inner alveolar membrane of Paramecium, and a variety of structures associated with the cytoplasmic face of membranes, such as plasma membrane plaques, cleavage furrows, the leading edge of the spreading acrosome and sperm annuli.Staining is not reduced by nucleases and spot tests show no reaction between nucleic acids and bismuth under conditions similar to those used to stain tissues. However, spot tests do show strong binding of bismuth by basic proteins and by some phosphorylated molecules.It is hypothesized that bismuth reacts with cell components in two ways, distinguishable by their glutaraldehyde sensitivity. For example, staining of the nucleolus and ribosomes is blocked by glutaraldehyde but the inter- and perichromatin granules and the GC beads are unaffected. Spot tests show that basic proteins (histones, protamines, polylysine and polyargenine) and other molecules with free amino groups (5HT, tryptamine, dopamine) bind bismuth strongly, a reaction that is blocked to varying degrees by glutaraldehyde. We presume that most bismuth staining of tissues is due to reaction with amine groups and is glutaraldehyde sensitive and some may be due to guanidine groups which are less sensitive to fixation by glutaraldehyde. Organic phosphates may be the cause of the glutaraldehyde insensitive staining since ATP and some other phosphates bind bismuth in a reaction that is not blocked by glutaraldehyde.     

THE USE OF BISMUTH AS AN ELECTRON STAIN FOR NUCLEIC ACIDS

Evidence is presented to show that bismuth combines in vitro with the phosphate of nucleic acids in a manner similar to its reaction with inorganic phosphate. When tested under similar conditions, protein exhibited no attraction for bismuth. The results of the in vitro experiments, which are of interest within themselves, may be indirectly applicable to in vivo staining. Dividing cells of onion root tips were fixed in OsO₄, stained with bismuth, and examined in the electron microscope. The electron opacity of cell structures known to contain nucleic acids was enhanced by bismuth, while organelles known to lack appreciable quantities of DNA or RNA showed little, if any, change. Bismuth is particularly effective as a stain for the chromatin material during interphase and for the chromosomes during division.     

Bismuth chemistry and the glutaraldehyde insensitive staining reaction

The free metal ion, Bi3+, is the only chemical species of bismuth that stains a strongly bismuth-reactive molecule, polyarginine, in vitro. The bismuth solution specifically requires tartrate as a chelating agent for the reaction to occur between pH 7.4 and 8.0. Since Bi3+ reacts strongly with polyarginine, creatine and ATP fixed to cellulose acetate strips and DEAE-cellulose and P-cellulose, the free metal ion (Bi3+) may bind to phosphate or guanidyl groups, or both, after glutaraldehyde fixation.     

Localization of highly phosphorylated proteins in cells altered by Herpes simplex virus infection

Highly phosphorylated proteins detectable by their ability to bind bismuth ions were localized in rabbit fibroblasts before and during infection with Herpes simplex viruses type 1 and type 2. The bismuth tartrate procedure of Locke and Huie applied to glutaraldehyde-fixed cells revealed a low level of bismuth binding in a restricted portion of the normal nucleolus in non-infected cells. From 2.5-17 hr post-infection during virus development and maturation, the phosphorylated proteins were more widespread and the intensity of reaction was augmented. Bismuth deposits were then associated with virus-modified pre-existing structures including all of the nucleolar fibrils, the more abundant interchromatin granules, reduplications of some areas of the inner nuclear membrane and the Golgi apparatus. Virus-induced structures which were stained included nuclear dense bodies, the teguments of enveloped virions and the contents of extranuclear enveloped structures devoid of capsids. Following detergent-induced destruction of membranes, staining was lost from the nuclear envelope and cytoplasmic virions, which demonstrated that the highly phosphorylated proteins were tightly bound to nuclear and viral membranes. Bismuth staining of nitrocellulose sheets containing proteins extracted from whole cells revealed no reaction in normal cells but three positive bands were found in infected cells.     

Binding of bismuth to serum proteins: implication for targets of Bi(III) in blood plasma

Bismuth complexes have been widely used in clinical treatment as antiulcer drugs. However, different adverse effects have been observed and the diagnosis is generally confirmed by the detection of bismuth in blood or blood plasma. In this study, binding of bismuth to human serum albumin was studied by fluorescence spectroscopy with the binding constant logK(a) to be 11.2. Competitive binding of bismuth to human albumin and transferrin was carried out at pH 7.4 by FPLC and ICP-MS. It was found that over 70% of bismuth binds to transferrin even in the presence of a large excess of albumin (albumin/transferrin=13:1) at pH 7.4, 10 mM bicarbonate. The distribution of bismuth between the two proteins was almost unchanged when Cys(34) of albumin was blocked. However, all bismuth binds to albumin when iron-saturated transferrin was used. Almost all of the bismuth was distributed over the fractions containing transferrin (70%) and albumin (<30%) in serum. The percentage of bismuth associated with transferrin was further increased by 15% with elevated transferrin in serum. Binding of bismuth to transferrin is much stronger than human albumin. Transferrin is probably the major target of bismuth in blood plasma, and it may play a role in the pharmacology of bismuth.     

Growth and Metabolism of Lactic Acid Bacteria during and after Malolactic Fermentation of Wines at Different pH

A new medium, called novobiocin-brilliant green-glucose (NBG) agar, was developed for the isolation of Salmonella spp. and evaluated against other conventionally used media including bismuth sulfite, xylose-lysine decarboxylase, brilliant green-sulfa, hektoen enteric, and salmonella-shigella agars. NBG had recovery rates comparable to the other enteric media tested with pure cultures as well as with naturally contaminated amphibian and reptile waters and fecal specimens. However, NBG, hektoen enteric, and salmonella-shigella agars failed to differentiate Salmonella typhi from a fecal specimen even after enrichment in selenite F. Although Citrobacter freundii could grow and resembled salmonellae on NBG, at no time was the recovery of Salmonella spp. colonies jeopardized by the presence of C. freundii in either seeded or naturally contaminated samples. Confirmation rates of typical colonies from NBG agar also compared favorably to the other media tested; however, bismuth sulfite, although selective, was found to have varied differential characteristics for Salmonella spp. As a result, many more colonies had to be picked, which caused bismuth sulfite agar to have the lowest confirmation rate of the media tested. The distinct advantage that NBG agar offers over the conventional method tested, including bismuth sulfite, is the consistent differential reaction of all Salmonella subgroups including biochemically atypical strains. The medium is inexpensive, easy to prepare, and can be stored for at least 2 weeks at 4 degrees C without loss of selective or differential properties.     

Growth and Metabolism of Lactic Acid Bacteria during and after Malolactic Fermentation of Wines at Different pH

A new medium, called novobiocin-brilliant green-glucose (NBG) agar, was developed for the isolation of Salmonella spp. and evaluated against other conventionally used media including bismuth sulfite, xylose-lysine decarboxylase, brilliant green-sulfa, hektoen enteric, and salmonella-shigella agars. NBG had recovery rates comparable to the other enteric media tested with pure cultures as well as with naturally contaminated amphibian and reptile waters and fecal specimens. However, NBG, hektoen enteric, and salmonella-shigella agars failed to differentiate Salmonella typhi from a fecal specimen even after enrichment in selenite F. Although Citrobacter freundii could grow and resembled salmonellae on NBG, at no time was the recovery of Salmonella spp. colonies jeopardized by the presence of C. freundii in either seeded or naturally contaminated samples. Confirmation rates of typical colonies from NBG agar also compared favorably to the other media tested; however, bismuth sulfite, although selective, was found to have varied differential characteristics for Salmonella spp. As a result, many more colonies had to be picked, which caused bismuth sulfite agar to have the lowest confirmation rate of the media tested. The distinct advantage that NBG agar offers over the conventional method tested, including bismuth sulfite, is the consistent differential reaction of all Salmonella subgroups including biochemically atypical strains. The medium is inexpensive, easy to prepare, and can be stored for at least 2 weeks at 4 degrees C without loss of selective or differential properties.     

Induced synthesis of chromochelatin, the low molecular weight bismuth-binding protein in rat kidneys.

Bismuth administered subcutaneously to rats as BiCl3 is deposited in the kidneys, where it is bound to two classes of proteins: one of high molecular weight and a fraction of molecular weight approx. 7500 (chromochelatin). The latter fraction prevails on repeated exposure to bismuth. The bismuth-binding protein is heterogenous and using polyacrylamide gel may be divided into three fractions of which all contain bismuth and copper. In parallel with increasing concentration of chromochelatin due to bismuth administration, the incorporation of L-[35S]cysteine is elevated in all three fractions. The incorporation is augmented especially if repeated administration of bismuth is applied. Cycloheximide (CH) completely abolishes the inducing effect of bismuth on the incorporation of L-[35S]cysteine into chromochelatin both following single and repeated administration of bismuth. Actinomycin D (AcD) eliminates the incorporation only in the case of single dose of bismuth. The obtained results suggest that the elevation of chromochelatin levels in the kidney following administration of bismuth is due to the induction of the de novo protein synthesis.     

Cooperative influence of thiolate ligands on the bio-relevant coordination chemistry of bismuth

The widespread use of bismuth compounds (e.g., bismuth subsalicylate, colloidal bismuth subcitrate) in medicine for over 200 years is founded on empirical observations, and definitive chemical mechanisms associated with the bioactivity of these compounds are not understood. The thiophilic nature of bismuth is a strong indication that sulfur-containing biological molecules are likely preliminary targets for bismuth. Using electrospray ionization mass spectrometry (ESI-MS), we have discovered a dramatic cooperative influence of thiolate ligands on the formation of bismuth complexes containing other biologically significant non-thiolate moieties. Reactions of Bi(NO3)3 with L-cysteine, 3-mercaptopropionic acid or 2-mercaptoethylamine, together with citric acid provide the first evidence of bismuth-citrate complexes in the gas phase. Analogously, reactions of Bi(NO3)3 with L-cysteine, together with other amino acids, reveal a wide range of new biologically relevant complex ions of bismuth that provide insight into the bioactivity of bismuth.     

Ion chromatographic separation and determination of phosphate and arsenate in water and hair

A simple and sensitive method for the sequential determination of phosphate and arsenate was developed based on initial ion chromatographic separation followed by detection as the ion-association complex formed by heteropolymolybdophosphate and arsenate with bismuth. With 200 microl sample injection and separation on a AS4A-SC column using an eluent of 3.5 mM sodium hydrogen carbonate-10.0 mM sodium hydroxide, the detection limits which are calculated as the concentration equivalent to twice the baseline noise, were found to be 0.8 microg/l and 4.2 microg/l for P and As, respectively. Spiked samples were analyzed and recoveries were found to be satisfactory in the range of 95-105% for phosphate and 90-105% for arsenate. Samples of water and hair were analyzed by the proposed method.     

The correlation between bismuth and uranyl staining and phosphorus content of intracellular structures as determined by electron spectroscopic imaging

Four groups of intracellular structures can be recognized according to bismuth and uranyl staining and phosphorus content. (1) Those which contain phosphorus and stain strongly with uranyl acetate but not with bismuth (ribosomes, heterochromatin and mature ribosomal precursor granules), presumably because of their nucleic acid content. (2) Those which contain phosphorus and stain with uranyl acetate and bismuth (interchromatin granules, immature ribosomal precursor granules and mitochondrial granules), presumably because at least some of their phosphate is available to react with bismuth. (3) Those which contain little phosphorus but which stain strongly with bismuth and weakly with uranyl acetate (Golgi complex beads), perhaps because some ligand in addition to phosphate reacts with bismuth, and (4) those which do not contain phosphorus and stain with neither uranyl acetate nor bismuth (portasomes). Uranyl staining correlates strongly with the phosphorus content of nucleic acids, proteins and inorganic deposits. Bismuth will stain some phosphorylated molecules but not all. Thus only some phosphates stain with bismuth.     

Bismuth(III) complexes with tetra-pyridylmethyl-cyclen

Bimuth(III) complexes with 1,4,7,10-tetrakis(2-pyridylmethyl)-1,4,7,10-tetraazacyclododecane have been prepared in dichloromethane and ethanol and investigated. These complexes have been characterized structurally by X-ray diffraction and NMR-2D studies. They present different coordination scheme depending on the reaction conditions: according to the nature of solvent, bismuth coordinates from six to eight nitrogen atoms and forms in the solid state a chiral structure which is maintained in solution.     

A novel effect of bismuth ions: selective inhibition of the biological activity of glycine-extended gastrin

Although bismuth salts have been used for over two centuries for the treatment of various gastrointestinal disorders, the mechanism of their therapeutic action remains controversial. Because gastrins bind two trivalent ferric ions with high affinity, and because ferric ions are essential for the biological activity of glycine-extended gastrin 17, we have investigated the hypothesis that trivalent bismuth ions influence the biological activity of gastrins. Binding of bismuth ions to gastrins was measured by fluorescence quenching and NMR spectroscopy. The effects of bismuth ions on gastrin-stimulated biological activities were measured in inositol phosphate, cell proliferation, and cell migration assays. Fluorescence quenching experiments indicated that both glycine-extended and amidated gastrin 17 bound two bismuth ions. The NMR spectral changes observed on addition of bismuth ions revealed that Glu-7 acted as a ligand at the first bismuth ion binding site. In the presence of bismuth ions the ability of glycine-extended gastrin 17 to stimulate inositol phosphate production, cell proliferation, and cell migration was markedly reduced. In contrast, bismuth ions had little effect on the affinity of the CCK-2 receptor for amidated gastrin 17, or on the stimulation of inositol phosphate production by amidated gastrin 17. We conclude that bismuth ions may act, at least in part, by blocking the effects of glycine-extended gastrin 17 on cell proliferation and cell migration in the gastrointestinal tract. This is the first report of a specific inhibitory effect of bismuth ions on the action of a gastrointestinal hormone.     

Detection by bismuth staining of highly phosphorylated nucleo-proteins in plants. Determination of its specificity by X-ray microanalysis,SDS-PAGE and immunological analysis

Summary— Staining with bismuth salts after glutaraldehyde fixation is a very useful technique for preferential detection of phosphorylated nucleoproteins in mammalians and insects. In the present work we report an adaptation of this method for plant nuclei: staining with bismuth salts either in tissue blocks before embedding, or on thin sections of acrylic resin. Both procedures are highly reproducible and give the same pattern of staining in the nuclei in situ or isolated at the electron microscope. The specificity of bismuth binding to the dense nucleolar fibrillar component and interchromatin granules is proven by X-ray microanalysis. The nuclear proteins which bind bismuth have been identified by bismuth and immunostains of blots from total nuclear proteins. This technique is a very useful and specific cytochemical tool for studying nuclear organization and functions in plants.     

Syntheses, crystal structures and antimicrobial activities of monomeric 8-coordinate, and dimeric and monomeric 7-coordinate bismuth(III) complexes with tridentate and pentadentate thiosemicarbazones and pentadentate semicarbazone ligands

Novel bismuth(III) complexes 1-4 with the tridentate thiosemicarbazone ligand of 2N1S donor atoms [Hmtsc (L1); 2-acetylpyridine (4N-morpholyl thiosemicarbazone)], the pentadentate double-armed thiosemicarbazone ligand of 3N2S donor atoms [H2dmtsc (L3); 2,6-diacetylpyridine bis(4N-morpholyl thiosemicarbazone)] and the pentadentate double-armed semicarbazone ligand of 3N2O donor atoms [H2dasc (L4b); 2,6-diacetylpyridine bis(semicarbazone)], were prepared by reactions of bismuth(III) nitrate or bismuth(III) chloride and characterized by elemental analysis, thermogravimetric and differential thermal analysis (TG/DTA), FTIR and NMR (1H and 13C) spectroscopy. The crystal and molecular structures of complexes 1, 2a, 2b and 4b, and the "free" ligand L1 were determined by single-crystal X-ray structure analysis. The dimeric 7-coordinate bismuth(III) complex [Bi(dmtsc)(NO3)]2, 1, and the monomeric 7-coordinate complexes [Bi(Hdasc)(H2O)](NO3)2.H2O (major product), 2a, and [Bi(dasc)(H2O)]NO3.H2O (minor product), 2b, all with pentagonal bipyramidal bismuth(III) centers, are depicted with one electron pair (6s2) of the bismuth(III) atom, deprotonated forms of multidentate thiosemicarbazone or semicarbazone ligands, and monodentate NO3 or H2O ligands, respectively. These complexes are related to the positional isomers of one electron pair of the bismuth(III) atom; 1 has an electron pair positioned in the pentagonal plane (basal position), while 2a and 2b have an electron pair in the apical position. The monomeric 8-coordinate complex [Bi(mtsc)2(NO3)], 4b, which was obtained by slow evaporation in MeOH of the 1.5 hydrates 4a, was depicted with one electron pair of the bismuth(III) atom, two deprotonated mtsc- ligand and one nitrate ion. On the other hand, crystals of the complex "[Bi(mtsc)Cl2]", 3, prepared by a reaction of BiCl3 with L1 showed several polymorphs (3a, 3b, 3c and 3d) due to coordination and/or solvation of dimethyl sulfoxide (DMSO) used in the crystallization. Bismuth(III) complexes 1 and 4a showed selective and effective antibacterial activities against Gram-positive bacteria. The structure-activity relationship was discussed.     

Solubility, absorption, and anti-Helicobacter pylori activity of bismuth subnitrate and colloidal bismuth subcitrate: In vitro data Do not predict In vivo efficacy

Objectives. The aim of this study was to compare the dissolution, bioavailability, and anti– Helicobacter pylori activity of bismuth subnitrate and colloidal bismuth subcitrate. This could, first, provide insights into the mechanism of action of bismuth and, second, help to develop optimal therapeutic strategies.
Methods. Solubility and aquated size of bismuth species were determined in human gastric juice, while absorption into blood and urinary excretion of bismuth was determined in volunteers. Activity against H. pylori was determined in vitro in the presence and absence of antibiotics, while H. pylori eradication was compared in vivo.
Results. Bismuth from colloidal bismuth subcitrate was at least 10% soluble and ultrafilterable and was absorbed in volunteers (>0.5%), whereas that from bismuth subnitrate was insoluble and not absorbed (<0.01%). Colloidal bismuth subcitrate was active against H. pylori (mean inhibitory concentration, ≤12.5 μg/ml), while bismuth subnitrate was inactive (>400 μg/ml); neither was synergistic with antibiotics. With in vivo triple therapy, bismuth subnitrate was as effective as colloidal bismuth subcitrate in eradicating H. pylori (74% and 70% eradicated, respectively).
Conclusions. Colloidal bismuth subcitrate, unlike bismuth subnitrate, is partially soluble, absorbed in humans, and directly toxic to H. pylori in vitro. Surprisingly, however, these preparations had similar efficacy in vivo against H. pylori within triple therapy, suggesting that bismuth compounds may also exhibit indirect antimicrobial effects. We propose that this is an effect on the gastric mucus layer. Nonabsorbable bismuth compounds should be preferentially considered in bismuth-based therapies against H. pylori , as they would minimize toxicity while maintaining efficacy.     

Bismuth citrate in the quantification of inorganic phosphate and its utility in the determination of membrane-bound phosphatases

This paper describes a rapid and sensitive method to determine inorganic phosphate, even in the presence of labile organic phosphate compounds and large quantities of proteins. The method eliminates the use of sodium arsenite, a highly toxic compound, substituting bismuth citrate for it to stabilize the phosphomolybdic acid complex formed during the interaction of inorganic phosphate and molybdate reduced by ascorbic acid. This method has also been adapted to microplates and has been used to determine the activities of Na/K ATPase and alkaline phosphatase of intestinal basolateral and luminal plasma membranes.     

Antifungal activity of organobismuth compounds against the yeast Saccharomyces cerevisiae: structure-activity relationship

Antifungal activity of organobismuth(III) and (V) compounds 1-9 was examined against the yeast, Saccharomyces cerevisiae. A clear structure-activity relationship was observed in these compounds. Thus, triarylbismuth dichlorides 2 [(4-YC6H4)3BiCl2: Y=MeO, F, Cl, CF3, CN, NO2] and halobismuthanes 6 [2-(t)BuSO2C6H4(4-YC6H4)BiX: Y=MeO, Me, H, Cl; X=Cl, Br, I], 7 [Bi(X)(C6H4-2-SO2C6H4-1'-): X=Cl, Br, I], 8 [2-Me2NCH2C6H4(Ph)BiX: X=Cl, Br] and 9 [4-MeC6H4(8-Me2NC10H6-1-)BiCl] showed the growth inhibition effect, while triarylbismuth difluorides 3 [(4-YC6H4)3BiF2] and triarylbismuthanes 1 [(4-YC6H4)3Bi], 4 [2-(t)BuSO2C6H4(4-YC6H4)2Bi] and 5 [4-YC6H4Bi(C6H4-2-SO2C6H4-1'-)] were not active at all irrespective of the nature of the substituents. Generation of the inhibition effect is governed by the facility of nucleophilic reaction at the bismuth center and the Lewis acidic bismuth center is an active site. Of all the bismuth compounds attempted, halobismuthanes 7 derived from diphenyl sulfone exhibited the highest activities. An X-ray crystallographic study of 7a [Bi(Cl)(C6H4-2-SO2C6H4-1'-)] revealed that the bismuth center adopts a seven-coordinated geometry, which is unusual in organobismuth(III) compounds, through the intramolecular and intermolecular coordination between the bismuth and oxygen atoms. The marked inhibition effect of 7 may be attributed to such a highly coordinated geometry, which allows the bismuth center to bind tightly with some biomolecules playing important roles in the growth of S. cerevisiae.