High-yield trapping of EGF-induced receptor dimers by chemical cross-linking

The binding of epidermal growth factor (EGF) to its plasma membrane receptor results in the stimulation of a tyrosyl residue-specific protein kinase, which has been shown to be part of the receptor. The mechanism by which EGF binding give rise to the stimulation of kinase activity is not understood in detail; however, a number of recent studies have implicated receptor dimerization or oligomerization in this process. We prepared Triton X-100 extracts of A431 cells in which the concentration of EGF receptors was on the order of 10(-7) M. When samples of the extracts were incubated with or without EGF and then treated with the high-yield cross-linking reagent bis(sulfosuccinimidyl)suberate (BS3), covalent receptor dimers could be detected in high yield in samples that had been treated with both EGF and BS3, whereas only monomeric receptor was detected in untreated samples or in samples that had been treated with either EGF or BS3. The yield of receptor dimers trapped by cross-linking correlated with the stimulation of autophosphorylation by EGF and with the concentration of EGF present. EGF-induced receptor dimers were also efficiently cross-linked in highly purified receptor preparations, suggesting that EGF-induced dimerization is a process intrinsic to the receptor, requiring no additional accessory proteins.     

Modulation of sodium-cotransport systems by other ions

After a brief review of Na+-cotransport systems which also accept other ions as co-ions or modifiers, modulation of the Na+-L-glutamate transport system in rabbit renal brush border membranes by K+ and H+ is discussed in more detail. Intravesicular K+ increases the initial uptake rate and electrogenicity of the cotransport. This effect of K+ is attributed to the formation of a K+-carrier complex that moves much more rapidly than do the other complexes. The resulting shift in rate limitancy (relative increase in overall rate over the relative increase in rate of step under consideration) from an electroneutral towards a charge-translocating pathway unmasks the electrogenicity of the initial L-glutamate uptake. A positive correlation between relative rate limitancy of the electrogenic pathway and electrogenicity is demonstrated supporting this model. Protons, in addition to acting as co-ions, modify Na+-glutamate cotransport by increasing both the initial rate and the electrogenicity of uptake. This phenomenon is assumed to represent a transition of the transport system from a carrier-like to an open channel-like translocation mode. Thus, the intrinsic properties of Na+-cotransport systems may vary under the influence of other ions. This holds true in particular for the electrogenicity of the initial transport rate which may change independently of alterations in charge stoichiometry.     

Calcium ions and cell fusion. Effects of chemical fusogens on the permeability of erythrocytes to calcium and other ions.

1. Fusogenic and non-fusogenic chemicals were tesetd for their ability to allow 45Ca2+ and 3H2O to enter hen and human erythrocytes. 2. The ratio of 45Ca2+/3H2O in treated cells to that in untreated cells is referred to as the entry ratio. 3. Within 1 min at 37 degrees C both water-soluble and lipid-soluble fusogens increased the value of the entry ratio, which reached maximum values in 5--10 min. 4. Values of the entry ratio in the range of 4--12 were found under conditions that led to cell fusion. 5. Closely related but non-fusogenic chemicals did not significantly alter the entry ratio. 6. The entry ratios for 86Rb+, 22Na+ and 35SO42- were also significantly increased by both lipid-soluble and water-soluble fusogens, though the increases were not as large as those for 45Ca2+. 7. It is suggested that fusogenic compounds increase the permeability of biological membranes to ions, and that an increase in the concentration of intracellular Ca2+ initiates or facilitates events that lead to the chemically induced fusion of erythrocytes.     

Experimental alterations of neurofilaments and neurotubules by calcium and other ions

Short segments of desheathed rat peripheral nerve were immersed in phosphate, tris-HCl and cacodylate buffers containing varying concentrations and admixtures of CaCl₂, AgCl, MgCl₂, PbCl₂, and AlCl₃ before fixation. These tissues were subsequently processed for electron microscopic examination.     

Effect of divalent and other ions on potassium uptake by barley roots

Summary Potassium uptake as affected by the presence of divalent and other ions was studied from KCl solutions to which other salts were added. The study also includes the effect of the initial Ca-content of roots on the uptake of K⁺ from KCl and KCl + CaCl₂ solutions. The effect of time on K-uptake from electrolyte mixtures containing Mg-ions was also included. The experimental results seem to fit well a model of K⁺-uptake based on diffusion of ions in mixed electrolytes.     

Binding of mercuric and other heavy metal ions by microbial growth media

Ion-specific electrodes were used to study the binding of Hg²⁺, Pb²⁺, Cu²⁺, and Cd²⁺ ions to widely used bacterial growth media (Nutrient broth, trypticase soy broth, the medium of Foot and Taylor [6] and of Nelsonet al.[12]) and to media components [yeast extract, peptone, tryptone, proteose peptone, and casamino acids (acid hydrolyzed casein)]. Volatilization of Hg²⁺ from aqueous solutions could be prevented by any of the growth media or their components. All media bound large amounts of Hg²⁺, Pb²⁺, and Cu²⁺, but much less Cd²⁺. Of the media components, casamino acids showed the most binding activity for all metal ions; the relative affinity of other media components to different ions varied with the cation studied. In general, the Irving-Williams [8] series for cation affinity to organic ligands was followed: Hg²⁺>Pa²⁺ Cu²⁺ Cd²⁺.After adding 20 ppm of Hg²⁺, Pb²⁺, or Cu²⁺ (concentrations inhibitory to the growth of most microorganisms) to the growth media, 80 ppb or less remained as free cations in the solution. This might suggest that such ions enter bacterial cells as organic complexes, or that bacterial cells can compete successfully with growth media for the bound ions.     

Inhibitive determination of mercury and other metal ions by potentiometric urea biosensor

The biosensor with urease entrapped in PVC layer at the surface of pH-sensitive iridium oxide electrode was applied for testing of mercury and other metal ions inhibition on enzymatic reaction. The calculation of inhibition effect was based on the measurement of initial rate of decrease of biosensor potential (proportional to the initial rate of enzymatic reaction) after addition of substrate after inhibition step. Some differences of inhibition extent were observed for various mercury forms (Hg(NO3)2, HgCl2, PhHgCl and Hg2(NO3)2) as well as for other heavy metal ions investigated as potential interferents. Because the method was not specific, it was applied for the determination of total inhibition effect caused by heavy metal ions in water samples. In the case of most cations tested the total recovery of enzyme activity was possible using Tris buffer solution with EDTA and thioacetamide after less than 10 min regeneration time.     

Stimulation of enzymatic phe-tRNA binding to mammalian ribosomes by thallium ions at concentrations blocking other ribosomal functions.

Thallium acetate (TIOAc) effectively stimulates poly(U)-directed Phe-tRNA binding to mouse ascitic tumour ribosomes under conditions when other ribosomal functions are completely blocked. The TI+ optimum is about 200 mM. The reaction is stimulated by EF-1, but not significantly by GTP. EF-1-dependent ribosomal GTPase is inhibited by T1+. The isolated Phe-tRNA . ribosome complex is relatively stable. The bound Phe-tRNA does not react with puromycin in the presence of 175 mM KCl. The complex formed in the presence of 90-100 mM TlOAc can, after isolation, be directly utilized for polyphenylalanine synthesis. The complex formed at 200 mM TlOAc is less active, apparently because of damage to the 60-S subunits. TlOAc at low concentrations (8 mM) stimulates K+ -containing poly(U)-translating systems, probably by stabilizing the translation complex.     

Inhibition of glutathione-insulin transhydrogenase by metal ions and activation by histidine and other chelating agents

The catalytic activity of purified glutathione-insulin transhydrogenase (thiol:protein-disulfide oxidoreductase/isomerase, EC 1.8.4.2) from bovine pancreas is markedly stimulated by histidine and other chelating agents. The activation produced was highest with EDTA, followed by EGTA, 8-hydroxyquinoline and 1,10-phenanthroline. Of the many amino acids tested, histidine was the only one that activated the enzyme; the structurally related compounds, 3-methylhistidine and imidazole also stimulated the enzyme, but 1-methylhistidine and histamine were without effect. The activation of EDTA was negated by metal ions, most effectively by Se2+, Hg2+, Cu2+ and Zn2+, and less effectively by Ca2+ and Ni2+. Likewise, activation by histidine was negated by Zn2+ but not by Ca2+ or Mg2+. Thus, activation of glutathione-insulin transhydrogenase is apparently achieved in part by the chelation of inhibitory metal ion(s). These findings are consistent with a regulatory scheme for glutathione-insulin transhydrogenase in which (a) the enzyme is inhibited by selenium and heavy metal ions normally present in tissues and (b) this inhibition can be relieved by the addition of histidine or chelating agents.     

Phosphate-dependent glutaminase in enterocyte mitochondria and its regulation by ammonium and other ions

Summary.  The effects of ammonium and other ions on phosphate dependent glutaminase (PDG) activity in intact rat enterocyte mitochondria were investigated. Sulphate and bicarbonate activated the enzyme in absence and presence of added phosphate. In presence of 10 mM phosphate, ammonium at concentrations <1 mM inhibited the enzyme. This inhibition was reversed by increased concentration of phosphate or sulphate. The inhibition of PDG by ammonium in presence of 10 mM phosphate was biphasic with respect to glutamine concentration, its effect being through a lowering of V_max at glutamine concentration of ≤5 mM, and increased K_m for substrate concentration above 5 mM. The activation of the enzyme by bicarbonate was through an increase in V_max. Ammonium and bicarbonate ions may therefore be important physiological regulators of PDG. It is suggested that phosphate and other polyvalent ions may function by preventing product inhibition of the enzyme through promotion of PDG dimer formation. The dimerized enzyme may have a high affinity for glutamine and reduced sensitivity to inhibition by ammonium ions. Received August 10, 2001 Accepted April 1, 2002 Published online August 30, 2002 Acknowledgement This work was supported by University of Zimbabwe research grant to Dr. B. Masola. Authors' address: Dr. Bubuya Masola, Department of Biochemistry, University of Zimbabwe, P O Box MP167, Mount Pleasant, Harare, Zimbabwe, E-mail: masolab@yahoo.co.uk     

Immobilization of lymphocytes at surfaces by lectins

Phytohemagglutinin (PHA) and Concanavalin A (ConA) cause normal chicken lymphocytes to adhere to glass and plastic surfaces. Pokeweed mitogen (PWM) does not cause adherence. The effect of ConA was studied in detail. The reaction begins within 15 min at 25 °C and proceeds to completion by 2 h. It is independent of pH and resembles in this respect the spontaneous adherence which can occur in protein-depleted suspensions of chicken lymphocytes. It is distinguished from spontaneous adherence by conducting the reaction in 1% or more serum protein; high concentrations exert a slight restraint, which can be overcome by increasing the concentration of ConA. The reaction is slightly greater at high cell concentrations, is inhibited by 3 mM sodium cyanide, and is effectively blocked by 3 mM iodoacetamide and the α-methyl- -glycosides of glucose and mannose. The reaction is not affected by 2-deoxy- -glucose or N-acetyl glucosamine. Adherent lymphocytes detach when the lectin solution is replaced with lectin-free saline; they readhere when reexposed to ConA or to alloantibody directed against lymphocyte surface antigen. At low concentrations of ConA the large lymphocytes of the bursa of Fabricius adhere more rapidly than the small lymphocytes of the blood and thymus. Mouse lymph node lymphocytes adhere in the same manner as small chicken lymphocytes.     

Quercetin inhibits advanced glycation end product formation via chelating metal ions,trapping methylglyoxal,and trapping reactive oxygen species

Physiological concentration of Mg²⁺, Cu²⁺, and Zn²⁺ accelerated AGE formation only in glucose-mediated conditions, which was effectively inhibited by chelating ligands. Only quercetin (10) inhibited MGO-mediated AGE formation as well as glucose- and ribose-mediated AGE formation among 10 polyphenols (1–10) tested. We performed an additional structure-activity relationship (SAR) study on flavanols (10, 11, 12, 13, and 14). Morin (12) and kaempherol (14) showed inhibitory activity against MGO-mediated AGE formation, whereas rutin (11) and fisetin (13) did not. These observations indicate that 3,5,7,4′-tetrahydroxy and 4-keto groups of 10 are important to yield newly revised mono-MGO adducts (16 and 17) and di-MGO adduct (18) having cyclic hemiacetals, while 3′-hydroxy group is not essential. We propose here a comprehensive inhibitory mechanism of 10 against AGE formation including chelation effect, trapping of MGO, and trapping of reactive oxygen species (ROS), which leads to oxidative degradation of 18 to 3,4-dihydroxybenzoic acid (15) and other fragments.     

Virulent spores of Bacillus anthracis and other Bacillus species deposited on solid surfaces have similar sensitivity to chemical decontaminants

AIMS: To compare the relative sensitivity of Bacillus anthracis and spores of other Bacillus spp. deposited on different solid surfaces to inactivation by liquid chemical disinfecting agents. METHODS AND RESULTS: We prepared under similar conditions spores from five different virulent and three attenuated strains of B. anthracis, as well as spores of Bacillus subtilis, Bacillus atrophaeus (previously known as Bacillus globigii), Bacillus cereus, Bacillus thuringiensis and Bacillus megaterium. As spore-surface interactions may bias inactivation experiments, we evaluated the relative binding of different spores to carrier materials. The survival of spores deposited on glass, metallic or polymeric surfaces were quantitatively measured by ASTM standard method E-2414-05 which recovers spores from surfaces by increasing stringency. The number of spores inactivated by each decontaminant was similar and generally within 1 log among the 12 different Bacillus strains tested. This similarity among Bacillus strains and species was observed through a range of sporicidal efficacy on spores deposited on painted metal, polymeric rubber or glass. CONCLUSIONS: The data obtained indicate that the sensitivity of common simulants (B. atrophaeus and B. subtilis), as well as spores of B. cereus, B. thuringiensis, and B. megaterium, to inactivation by products that contain either: peroxide, chlorine or oxidants is similar to that shown by spores from all eight B. anthracis strains studied. SIGNIFICANCE AND IMPACT OF THE STUDY: The comparative results of the present study suggest that decontamination and sterilization data obtained with simulants can be safely extrapolated to virulent spores of B. anthracis. Thus, valid conclusions on sporicidal efficacy could be drawn from safer and less costly experiments employing non-pathogenic spore simulants.     

Mesothelial primary cilia of peritoneal and other serosal surfaces

The conspicuous presence of primary cilia, a small immotile cilium present on most cell types, left researchers with little doubt of their functional relevance. Recently mechanosensitive functional significance was established and a link with the pathogenesis of polycystic kidney disease. Together these discoveries have raised the profile of this, previously considered "vestigial", organelle. Primary cilia are expressed on the apical surface of serosal mesothelium and display regional variation but are more abundant on biosynthetically active cells. Adult mesothelial cells are highly biosynthetic producing a phospholipid rich surfactant that lubricates and protects the visceral organs. The mesothelium is utilized as a semipermeable membrane during peritoneal dialysis for patients with end stage renal failure. However, little is known about the functional role of primary cilia on this highly specialized cell type. The present review, examines the significance of the primary cilium in serosal mesothelial cell biology with an emphasis on ciliary location, structure, form and function. Future research is identified and discussed in view of the emerging role cilia have in other cells and the established function of the serosal mesothelium in development, normal function, peritoneal dialysis and pathology of the serosal membranes.