Polymyxin-B-binding sites in the cochlea as demonstrated by polymyxin-B/gold labeling

A polymyxin-B/bovine-serum-albumin/gold complex was used as a probe to detect the binding sites of polymyxin B on thin sections of cochlea embedded in Spurr's resin. The binding sites were found to be mainly located on the stereocilia, the cuticular plate of hair cells, the head plate of Deiters' cells, the tonofilaments in pillar cells and Deiters' cells, fibrous structures in the spiral limbus, the tectorial membrane and the basilar membrane and neural elements such as nerve endings, fibers, and the myelin sheath. The mitochondria, plasma membrane, and chromatin of the nuclei of the cells observed also exhibited binding. Our results suggest that phospholipids, glycoconjugates, cytoskeletal proteins and nucleic acids are responsible for this binding activity.     

Aminoglycoside binding sites in the cochlea as revealed by neomycin-gold labelling

Neomycin/bovine serum albumin/gold was used as a probe to detect the binding sites of aminoglycosides on the thin sections of the cochlea embedded in Spurr. The binding sites were mainly located on the stereocilia, the cuticular plate of hair cells, the head plates of Deiters' cells, fibrous structures in pillar cells, in the spiral limbus and tectorial membrane and basilar membrane, plasma membranes, mitochondria and the chromatin of various kinds of cells. Triphosphoinositide, acidic glycosaminoglycans, and RNA were considered to be responsible for the binding activity.     

Aminoglycoside binding sites in the cochlea as revealed by neomycin-gold labelling

Summary Neomycin/bovine serum albumin/gold was used as a probe to detect the binding sites of aminoglycosides on the thin sections of the cochlea embedded in Spurr. The binding sites were mainly located on the stereocilia, the cuticular plate of hair cells, the head plates of Deiters' cells, fibrous structures in pillar cells, in the spiral limbus and tectorial membrane and basilar membrane, plasma membranes, mitochondria and the chromatin of various kinds of cells. Triphosphoinositide, acidic glycosaminoglycans, and RNA were considered to be responsible for the binding activity.     

Localization of triphosphoinositide in the cochlea. An electronmicroscopic immunocytochemical study

Triphosphoinositide (TPI) has been demonstrated to be a receptor for aminoglycosides in the cochlea and may regulate ionic permeability by its binding with Ca++. This phospholipid was localized by a protein A-gold technique in the cochlea at the electronmicroscopic level. TPI was prepared by a neomycin column and antibodies to it were raised in rabbits. The antibody used in this study reacted virtually only to TPI among the tested lipids. TPI was localized mainly at stereocilia, cuticular plates, head plates of Deiters' cells, plasma membrane, and mitochondria of various cells in the organ of Corti. In the vascular stria, TPI was found mainly at the plasma membrane of basal infoldings of the marginal cells. Possible physiological and pathophysiological roles of TPI in the cochlea are briefly discussed.     

Binding sites of an aminoglycoside in the cochlea examined by immunocytochemistry

To localize the binding sites of aminoglycosides in the cochlea, immunocytochemistry was used with the antibody to gentamicin and the protein-A/gold complex. We found that the main binding sites were the stereocilia, the cuticular plates of hair cells, the head plates of Deiters' cells, cell filaments and the cones of pillar cells, tectorial membranes, basilar membranes, the matrix of the spiral limbus, plasma membranes, mitochondria, and the chromatin of various kinds of cells. Triphosphoinositide and acidic glycosaminoglycans are the two most likely candidates for the cause of binding activity.     

Binding sites of an aminoglycoside in the cochlea examined by immunocytochemistry

Summary To localize the binding sites of aminoglycosides in the cochlea, immunocytochemistry was used with the antibody to gentamicin and the protein-A/gold complex. We found that the main binding sites were the stereocilia, the cuticular plates of hair cells, the head plates of Deiters' cells, cell filaments and the cones of pillar cells, tectorial membranes, basilar membranes, the matrix of the spiral limbus, plasma membranes, mitochondria, and the chromatin of various kinds of cells. Triphosphoinositide and acidic glycosaminoglycans are the two most likely candidates for the cause of binding activity.     

An inhibitory protein of intestinal fluid secretion reverses neuronal GABA transport

Intestinal challenge with cholera toxin induces the synthesis of a hormone-like protein which counteracts intestinal hypersecretion. This study shows that the protein also inhibits GABA transport across the plasma membrane of Deiters' cells in rabbits. The inhibitory action of the protein was dose dependent, and 10(3) times more potent than met 5-enkephalin, hitherto the most effective known inhibitor of GABA transport in vitro. The influence of the protein on the plasma membrane was reversible, and did not affect either postsynaptic binding or uptake of GABA.     

MEASUREMENT OF γ-AMINOBUTYRIC ACID IN ISOLATED NERVE CELLS OF CAT CENTRAL NERVOUS SYSTEM

Abstract— A sensitive method for measuring γ-aminobutyric acid (GABA) has been developed. This method consists of a combination of the enzymic GABA assay of J akoby and S cott (1959) with the enzymic cycling technique of L owry , P assonneau , S chulz and R ock (1961) and permits the measurement of as little as 2 × 10⁻¹⁴ mol of GABA. Using this method, GABA analyses were made on single isolated nerve cell bodies of different types from the CNS of the cat. Average GABA concentrations in these cell bodies were: spinal ganglion cells, 0.2 m m ; spinal mononeurons, 0.9 m m ; large cells of the ventral part of Deiters' nucleus, 2.7 m m ; large cells of the dorsal part of Deiters' nucleus, 6.3 m m ; cerebellar nuclei cells, 6.0 m m ; cerebellar Purkinje cells, 6.6mM; cerebral Betz cells, 2.5 m m .
The GABA concentrations in the isolated dorsal Deiters' cells were greatly reduced (1.7 m m ) after the removal of the cerebellar vermis while those of the ventral Deiters' cells were unaffected by the denervation. These results suggest that GABA is concentrated within axon terminals, probably of Purkinje neurons, synapsing with the dorsal Deiters' cells. The results of GABA analyses on isolated nerve cells are discussed in relation to the relevant neuronal functions and the possible role of GABA as an inhibitory transmitter.     

Subcellular localization of binding sites for cytochalasin D: evidence from activation energies.

The activation energies for binding of tritiated cytochalasin D to HEp-2 cells and isolated plasma membrane were determined by Arrhenius plots. The higher value for intact cells (24 kcal/mol) compared to the plasma membrane fraction (4 kcal/mol at greater than 11.5 degrees C, 18 kcal/mol at less than 11.5 degrees C) was taken as evidence that [3H]cytochalasin D must penetrate the plasma membrane in order to reach its binding sites. The data support the conclusion that binding sites for [3H]cytochalasin D are intracellular, on the cytoplasmic face of the plasma membrane (rather than within the lipid bilayer), and on microsomes (endomembranes).     

Binding of anti-band 3 autoantibody to oxidatively damaged erythrocytes. Formation of senescent antigen on erythrocyte surface by an oxidative mechanism

Incubation of human erythrocytes oxidized by iron catalysts, ADP/Fe3+ or xanthine/xanthine oxidase/Fe3+, with autologous IgG resulted in IgG binding as detected by enzyme immunoassay using protein A-beta-galactosidase conjugate. The binding of autologous IgG to ADP/Fe3(+)-treated erythrocytes maximized when the cells were treated with 1.8:0.1 mM ADP/Fe3+, and declined when treated above this concentration, suggesting that autologous IgG binds to moderately but not to excessively oxidized erythrocytes. The antibody involved in the binding was anti-Band 3, the autoantibody known to bind to aged erythrocytes, because isolated anti-Band 3 bound to the oxidized cells, but anti-Band 3-depleted autologous IgG did not. In addition, purified Band 3 inhibited the autologous IgG binding. Anti-alpha-galactosyl IgG, another natural antibody which has been reported to bind to aged erythrocytes, did not bind to the oxidized cells. Oxidation of membrane lipids, SH-groups of membrane proteins, and Hb of these cells was slight, but the cells contained an increased amount of membrane-bound native Hb, indicating that the oxidized cell membrane has an altered property. alpha-Tocopherol prevented the lipid oxidation and the subsequent IgG binding. Reduction of the oxidized erythrocytes with dithiothreitol resulted in a loss of the IgG binding. These results suggest that anti-Band 3 binding sites (Band 3 senescent antigen) are formed on moderately oxidized erythrocytes as a result of oxidation of membrane protein SH-groups which can be mediated by the membrane lipid oxidation and that formation of the anti-Band 3 binding sites on the oxidized cells is an essentially reversible membrane event which is linked to oxidation and restoration of the protein SH-groups.     

Subcellular localization of binding sites for cytochalasin D: Evidence from activation energies

The activation energies for binding of tritiated cytochalasin D to HEp-2 cells and isolated plasma membrane were determined by Arrhenius plots. The higher value for intact cells (24 kcal/mol) compared to the plasma membrane fraction (4 kcal/mol at > 11.5 °C, 18 kcal/mol at < 11.5 °C) was taken as evidence that [³H]cytochalasin D must penetrate the plasma membrane in order to reach its binding sites. The data support the conclusion that binding sites for [³H]cytochalasin D are intracellular, on the cytoplasmic face of the plasma membrane (rather than within the lipid bilayer), and on microsomes (endomembranes).     

Interaction between Cytokinesis-Related Callose and Cortical Microtubules in Dividing Cells of the Liverwort Riella helicophylla

Abstract: In juvenile walls of dividing cells of the liverwort Riella helicophylla the nitroso-derivative of photolysed Nifedipine (a calcium antagonist) stimulates the deposition of callose. This enhanced biosynthesis of β-1,3-glucan can only be observed in the cell plate, the juvenile cell walls and the walls of adjacent cells. An immunocytological analysis of this effect revealed that no cortical microtubules occurred at the sites of callose deposition. The cells of the control displayed a normal distribution of cortical microtubules at the plasma membrane as long as no callose was deposited along the corresponding walls. In a second set of experiments, inhibitors of microtubule polymerization and depolymerization (amiprophosmethyl and taxol, respectively) were used. At low concentrations, these substances also caused a significant stimulation of callose deposition in the plane of cell division. Based on these findings, we propose a regulatory model of callose and cellulose biosynthesis that depends on the binding of the cellulose/callose synthase complex to cortical microtubules that may be mediated by unknown binding protein(s).     

ELECTRON MICROSCOPE AND EXPERIMENTAL INVESTIGATIONS OF THE NEUROFILAMENTOUS NETWORK IN DEITERS'' NEURONS : Relationship with the Cell Surface and Nuclear Pores

The assembly of filamentous elements and their relations to the plasma membrane and to the nuclear pores have been studied in Deiters' neurons of rabbit brain. Electron microscopy of thin sections and of ectoplasm spread preparations have been integrated with physicochemical experiments and differential interference microscopy of freshly isolated cells. A neurofilamentous network extends as a continuous, three-dimensional, semilattice structure throughout the ectoplasm, the "plasma roads," and the perinuclear zone of the perikaryon. This space network consists of ~90-Å wide neurofilaments arranged in fascicles which are interconnected by an exchange of neurofilaments. The neurofilaments consist of intercoiled ~20-Å wide unit-filaments and are associated through cross-associating filaments with other neurofilaments of the fascicle and with microfilaments. The ~20–50-Å wide microfilaments display intimate associations with the plasma membrane and with the nuclear pores. Electron microscopy of thin sections from glycerinated and heavy meromyosin-treated Deiters' neurons shows that actin-like filaments are present in the pre- and postsynaptic regions of synapses terminating on these neurons. It is proposed that the neurofilamentous space network serves a transducing function by linking plasma membrane activities with the genetic machinery of the neuron.     

The kinetics of dissociation of the inhibitor of nucleoside transport, nitrobenzylthioinosine, from the high-affinity binding sites of cultured hamster cells.

Nucleoside transport in various types of animal cells is inhibited by the binding of nitrobenzylthioinosine (NBMPR) to a set of high-affinity sites on the plasma membrane. This work examined the binding of [3H]NBMPR to the nucleoside transporters of cultured Nil 8 hamster fibroblasts and of cells of a virus-transformed clone (Nil SV) derived from Nil 8. Experiments conducted with intact Nil 8 and Nil SV cells and with membrane preparations indicated that the two lines differed significantly in the cellular content of binding sites and only slightly in the affinities of these sites for NBMPR. Nil 8 and Nil SV cells possessed (4.2-8.0) X 10(5) and (2.0-4.0) X 10(6) sites per cell respectively, whereas the dissociation constants of site-bound NBMPR obtained with intact cells and with membrane preparations were similar, ranging from 0.29 to 1.5 nM. Dilazep, a potent inhibitor of nucleoside transport that is structurally unrelated to NBMPR, appeared to compete with NBMPR for binding to the high-affinity sites when tested under equilibrium conditions with Ki values for inhibition of NBMPR binding to Nil 8 and Nil SV cells respectively of 15 +/- 4 and 32 +/- 4 nM. The dissociation of NBMPR from the binding site--NBMPR complex of Nil SV membrane preparations was a first-order decay process with a rate constant of 0.68 +/- 0.26 min-1. The rate of dissociation of NBMPR from the binding-site complex of membrane preparations and intact cells was decreased significantly in the presence of dilazep and increased in the presence of the permeant uridine. These results suggest that the apparent competitive-inhibition kinetics obtained for dilazep under equilibrium conditions should not be interpreted as binding of dilazep to the same site as NBMPR but rather as binding of the two inhibitors to closely associated sites on the nucleoside transporter. Similarly, uridine also appears to bind to a site separate from the NBMPR-binding site.     

Control of erythrocyte membrane microviscosity by insulin

The human erythrocyte membrane binds insulin through high-affinity, low-capacity binding sites (dissociation constant Kd1 2.45 X 10(-9)M; capacity n1 207 fmol/mg protein) and low-affinity, high-capacity binding sites (Kd2 0.63 X 10(-6) M; n2 37 pmol/mg protein). Treatment of the erythrocyte membrane or the intact cells with the physiological concentration of insulin, which is within the range of Kd value of the high-affinity sites, results in a significant reduction of the membrane microviscosity and the filtration time of the intact cells. Use of supraphysiological concentrations of the hormone reverses the effect of the lower concentration of insulin on the membrane microviscosity and the filtration time.     

Transport of Vitamin B12 in Escherichia coli: Common Receptor Sites for Vitamin B12 and the E Colicins on the Outer Membrane of the Cell Envelope

The first step in the transport of cyanocobalamin (CN-B(12)) by cells of Escherichia coli was shown previously to consist of binding of the B(12) to specific receptor sites located on the outer membrane of the cell envelope. In this paper, evidence is presented that these B(12) receptor sites also function as the receptors for the E colicins, and that there is competition between B(12) and the E colicins for occupancy of these sites. The cell strains used were E. coli KBT001, a methionine/B(12) auxotroph, and B(12) transport mutants derived from strain KBT001. Colicins E1 and E3 inhibited binding of B(12) to the outer membrane B(12) receptor sites, and CN-B(12) protected cells against these colicins. Half-maximal protection was given by CN-B(12) concentrations in the range of 1 to 6 nM, depending upon the colicin concentration used. Colicin E1 competitively inhibited the binding of (57)Co-labeled CN-B(12) to isolated outer membrane particles. Functional colicin E receptor sites were found in cell envelopes from cells of only those strains that possessed intact B(12) receptors. Colicin K did not inhibit the binding of B(12) to the outer membrane receptor sites, and no evidence was found for any identity between the B(12) and colicin K receptors. However, both colicin K and colicin E1 inhibited the secondary phase of B(12) transport, which is believed to consist of the energy-coupled movement of B(12) across the inner membrane.     

Interaction between phloretin and the red blood cell membrane

Phloretin binding to red blood cell components has been characterized at pH6, where binding and inhibitory potency are maximal. Binding to intact red cells and to purified hemoglobin are nonsaturated processes approximately equal in magnitude, which strongly suggests that most of the red cell binding may be ascribed to hemoglobin. This conclusion is supported by the fact that homoglobin-free red cell ghosts can bind only 10% as much phloretin as an equivalent number of red cells. The permeability of the red cell membrane to phloretin has been determined by a direct measurement at the time-course of the phloretin uptake. At a 2% hematocrit, the half time for phloretin uptake is 8.7s, corresponding to a permeability coefficient of 2 x 10(-4) cm/s. The concentration dependence of the binding to ghosts reveals two saturable components. Phloretin binds with high affinity (K diss = 1.5 muM) to about 2.5 x 10(6) sites per cell; it also binds with lower affinity (Kdiss = 54 muM) to a second (5.5 x 10(7) per cell) set of sites. In sonicated total lipid extracts of red cell ghosts, phloretin binding consists of a single, saturable component. Its affinity and total number of sites are not significantly different from those of the low affinity binding process in ghosts. No high affinity binding of phloretin is exhibited by the red cell lipid extracts. Therefore, the high affinity phloretin binding sites are related to membrane proteins, and the low affinity sites result from phloretin binding to lipid. The identification of these two types of binding sites allows phloretin effects on protein-mediated transport processes to be distinguished from effects on the lipid region of the membrane.     

Binding of Agonists and Antagonists to Muscarinic Acetylcholine Receptors on Intact Cultured Heart Cells

The binding of agonists and antagonists to muscarinic acetylcholine receptors on intact cultured cardiac cells has been compared with the binding observed in homogenized membrane preparations. The antagonists [3H]quinuclidinyl benzilate and [3H]N-methylscopolamine bind to a single class of receptor sites on intact cells with affinities similar to those seen in membrane preparations. In contrast with the heterogeneity of agonist binding sites observed in membrane preparations, the agonist carbachol binds to a homogeneous class of low-affinity sites on intact cells with an affinity identical to that found for the low-affinity agonist site in membrane preparations in the presence of guanyl nucleotides. Kinetic studies of antagonist binding to receptors in the absence and presence of agonist did not provide evidence for the existence of a transient (greater than 30 s) high-affinity agonist site that was subsequently converted to a site of lower affinity. Nathanson N. M. Binding of agonists and antagonists to muscarinic acetylcholine receptors on intact cultured heart cells.     

Mosaicism in the organization of Con A binding sites on the membrane surface of female cells of Nicotiana tabacum

The presence of mosaicism in the organization of concanavalin agglutinin (Con A) binding sites on murine egg cells was first reported 30 year ago. This discovery has triggered extensive studies into the roles of glycoproteins in gamete interactions in animals. This report comprises the first account of the existence of the mosaicism in higher plants. The distribution of Con A binding sites on both egg cells and central cells of tobacco (Nicotiana tabacum) was found to be polar and apparently determined by the location of the nucleus of the cell. On central cells, Con A binding sites were distributed on the section of the plasma membrane surface near the nucleus. By contrast, the binding sites on egg cells were concentrated away from the nucleus. Therefore, polarity of the plasma membrane component of female cells was confirmed for the first time. It is proposed that such polarized ConA binding sites could be involved in sperm recognition.     

Giant pools of DNA precursors in sea urchin eggs.

Tritiated cytochalasin D (³H-CD) is rapidly taken up by monolayers of HEp-2 HeLa and rhabdomyosarcoma cells, reaching a maximum incorporation within 5 min at 37 °C. Upon rinsing and refeeding, 80% of the bound drug rapidly dissociates from the cells; the remaining 20 % is lost more slowly. Binding is dose-dependent in a non-linear fashion; Scatchard plots are biphasic, suggesting binding of higher and lower affinity. Inhibitors of energy metabolism do not diminish binding of ³H-CD. The plasma membrane fraction of HEp-2 exhibits the highest specific binding activity (146 dpm/μg protein) and contains both high and low affinity binding sites. Endomembranes (microsomes) have moderate specific binding activity (35 dpm/μg protein) and appear to contain only low affinity binding sites. Nuclear, mitochondrial, and cytosol fractions exhibit low, probably negligible, binding. These results are consistent with the evidence afforded by radioautography. Selective enzyme digestions of whole cells and the plasma membrane fraction indicate that binding of CD requires proteins not exposed on the outer surface of the cell. Because electron micrographs of the plasma membrane fraction demonstrate microfilaments attached to the membrane, the binding data may be interpreted as evidence for an interaction of CD either with the subplasmalemmal microfilaments or directly with the plasma membrane.