Intestinal absorption enhanced by unsaturated fatty acids: inhibitory effect of sulfhydryl modifiers

In vitro absorption of carboxyfluorescein was performed with everted colonic segments of rats. Oleic acid solubilized by a nonionic surfactant HCO-60, but not HCO-60 alone, markedly enhanced the permeation of the otherwise poorly permeant carboxyfluorescein through the colonic mucosa. The effect produced by oleic acid was reduced to different extents by pretreating the mucosa with several SH reagents, with N-ethyl-maleimide being the most effective. The inhibitory effect of N-ethylmaleimide was concentration dependent, with more than 5 mM completely blocking the enhancement of transmucosal permeability by oleic acid. The in vitro effect of N-ethylmaleimide in the absorption experiments was also observed in situ. The inhibitory effects of HgCl2 and iodoacetamide were comparable to that of N-ethylmaleimide, whereas PCMPS, an impermeant SH blocker, had no effect on the enhanced permeation. Various other amino-group modifiers had also no effect on the enhancement. On the other hand, the inhibition was accompanied by a significant reduction in the level of non-protein thiols as well as protein SH groups. Diethyl maleate, which reduced only the non-protein SH level, had no pronounced effect on the oleic acid-induced permeability change. These results suggest that the intact SH group of membrane-associated protein is necessary for the enhanced permeation of carboxyfluorescein elicited by oleic acid.     

Effect of factors of favism on the protein and lipid components of rat erythrocyte membrane

Erythrocytes prepared from riboflavin- and tocopherol-deficient (RT^?) and from control rats were used to investigate the mechanism of oxidative hemolysis by the factors of favism. RT^? erythrocytes have a defense system against the oxidative stress which is blocked either where regeneration of GSH occurs or the scavenging of the radicals from the membrane is prevented. The oxidative factors used were isouramil, divicine and diamide. When RT^? erythrocytes were treated with isouramil, GSH decreased to undetectable levels and was not regenerated. Complete hemolysis occurred, but no oxidation of SH groups of membrane proteins or formation of spectrin polymers was detected. A similar effect was observed with diamide. However, SH groups of membrane proteins were completely oxidized and spectrin polymers were formed. Extensive lipid peroxidation was also detected together with a 30% fall in the arachidonic acid level. Control erythrocytes treated with either isouramil or diamide were not hemolyzed. When treated with isouramil, after a fall in the first few minutes, the GSH level was completely regenerated after 20 min. Incubation with diamide caused extensive oxidation of SH groups of membrane proteins and formation of spectrin polymers. No lipid peroxidation was detected after treatment with isouramil, but the same decrease of arachidonic acid occurred as in RT^? erythrocytes. These results support the hypothesis that oxidative hemolysis by the factors of favism is caused by uncontrolled peroxidation of membrane lipids.     

Alteration of rheological properties of human erythrocytes by crosslinking of membrane proteins

The crosslinking of membrane proteins of human erythrocytes by diamide (diazene dicarboxylic acid bis(N,N-dimethylamide) ) was quantified by 4% polyacrylamide gel electrophoresis in 1% sodium dodecyl sulfate. The relation between the crosslinking of membrane proteins and erythrocyte functions (rheological and oxygen transporting) was quantitatively examined. (i) The crosslinking of membrane protein was induced by diamide, without changing the shape and the contents of intracellular organic phosphates (adenylates and 2,3-diphosphoglycerate). The intensity of spectrin 2 in SDS-polyacrylamide gel electrophoresis decreased proportionally to diamide concentration. The percentage decrease in spectrin 2 (using band 3 as an internal standard) was the most appropriate indicator for crosslinking ("% crosslinking'). (ii) The suspension viscosity of erythrocytes increased in proportion to the percentage of crosslinking, in the range of applied shear rates of 3.76-752 s-1. (iii) Erythrocyte deformability (measured by a high-shear rheoscope) was reduced by the crosslinking. The change was detectable even at 5% crosslinking. (iv) Rouleaux formation (measured by a television image analyzer combined with a low-shear rheoscope) was inhibited by the crosslinking. The inhibition was also sensitively detected at more than 5% crosslinking. (v) Hemoglobin in erythrocytes was chemically modified by higher dose of diamide (probably by the binding of diamide with sulfhydryl groups). Also the oxygen affinity of hemoglobin increased and the heme-heme interaction decreased. (vi) The reduction of the crosslinking of membrane proteins by dithiothreitol apparently reversed the intensity of spectrin bands in SDS-polyacrylamide gel electrophoresis and the erythrocyte functions (the suspension viscosity and the deformability), though not completely.     

Modification of ultraviolet radiation effects on the membrane of myelinated nerve fibers by sulfhydryl compounds

Summary The modification of the ultraviolet blocking of sodium channels and of the ultraviolet-induced potential shift of the gating parameters by means of the sulfhydryl compoundsl-cysteine and 2-mercaptoethanol was investigated in the node of Ranvier under voltage-clamp conditions. The UV wavelength was 280 nm. The radiation-induced potential shift of the voltage-dependent gating parameters was prevented or even reversed by the action of the sulfhydryl compounds (internal application), while the blocking effect was not affected. It is concluded that the two radiation effects are caused by two separate photoreactions. Internally applied N-ethylmaleimide, binding specifically to protein-SH groups, exhibits an effect similar to the ultraviolet-induced potential shift, without affecting the maximum sodium permeability. Therefore, the ultraviolet-induced potential shift might be caused by a photocatalyzed oxidation of —SH groups of membrane proteins changing the surface charge density at the inner side of the nodal membrane.     

Inhibition of lymphatic absorption of cholesterol by cholestane-3 beta, 5 alpha, 6 beta-triol

The effect of cholestane-3,5alpha,6-triol (CT) on the intestinal absorption of cholesterol and oleic acid, as well as the absorption of labeled CT, was studied in lymph ductcannulated rats. Intragastric administration of 50 mg of CT in an emulsion with cholesterol-7alpha-(3)H and oleic acid-1-(14)C resulted in 50% inhibition of sterol transfer into lymph but only 8% depression of fatty acid absorption over an 8 hr period. The absorption of labeled CT into lymph was only 2-3% compared with 50% absorption of cholesterol when each was fed alone. 10% of the fed CT was recovered in the intestinal mucosa, and of this, one-half was associated with the brush border fraction. In rats fed CT 6 days prior to cholesterol and fatty acid administration, there was no effect on fatty acid absorption, while cholesterol absorption was reduced by almost 30%. When the intestinal mucosa from these animals were investigated by electron microscopy, it appeared that CT feeding resulted in numerous enlarged mitochondria and a marked increase in length of the microvilli. If animals were allowed to recover for 6 days from the CT prefeeding regime, the intestinal mucosa appeared normal, and the absorption of cholesterol approached that in controls. A possible mechanism for CT inhibition of cholesterol absorption was shown to be competition for the enzyme cholesterol esterase which esterifies cholesterol prior to entrance into the lymphatic system. CT itself is poorly esterified and poorly absorbed, but it is effective in inhibiting esterification of cholesterol in vitro.     

DNA biosynthesis in rat liver mitochondria: Inhibition by sulfhydryl compounds and stimulation by cytoplasmic proteins

The sulfhydryl compounds, 2-mercaptoethanol, dithiothreitol, cysteine. and glutathione inhibit the incorporation of [³H]dTTP or [³H]dATP into mitochondrial DNA by rat liver mitochondria in vitro. The lack of inhibition by non-SH-containing analogs indicates that the SH group is responsible for the inhibition.The inhibition does not result from an effect of the sulfhydryl compounds on precursor permeability, ATP formation, or respiration, or the action of the thiol on the outer mitochondrial membrane. An intact inner membrane is not required for the action of the inhibitor. Furthermore, SH compounds do not appear to exert their effect by activation of a mitochondrial nuclease, chemical breakdown of high molecular-weight mitochondrial DNA or dissociation of membrane-bound DNA from the inner mitochondrial membrane. Incorporation of labeled precursor into DNA by mitochondrial DNA polymerase, when removed from the inner mitochondrial membrane, is not inhibited by SH compounds.Cytoplasmic extracts prepared from rat and mouse tumors and 22-h regenerating rat liver contain a protein(s) not detectable in normal rat liver which can reverse the inhibition by SH compounds of the synthesis of mitochondrial DNA in rat liver mitochondria in vitro.More importantly, when the stimulatory protein(s) is partially purified by affinity chromatography on DNA-cellulose, it is possible to demonstrate that this protein(s) also stimulates the synthesis of mitochondrial DNA by normal rat liver mitochondria in vitro in the absence of the sulfhydryl inhibitor.     

Involvement of cytoskeletal proteins in the barrier function of the human erythrocyte membrane. III. Permeability of spectrin-depleted inside-out membrane vesicles to hydrophilic nonelectrolytes. Formation of leaks by chemical or enzymatic modification of membrane proteins.

Spectrin-depleted inside-out vesicles (IOV's) prepared from human erythrocyte membranes were characterized in terms of size, ground permeability to hydrophilic nonelectrolytes and their sensitivity to modification by SH reagents, DIDS and trypsin. IOV's proved to have the same permeability of their lipid domain to erythritol as native erythrocytes, in contrast to resealed ghosts (Klonk, S. and Deuticke, B. (1992) Biochim. Biophys. Acta 1106, 126-136 (Part I in this series)), which have a residual leak. On the other hand, IOV's have a slightly elevated permeability for mannitol and sucrose, nonelectrolytes which are almost (mannitol) or fully (sucrose) impermeant in the native membrane. These increased fluxes, which have a high activation energy and can be stimulated by phloretin, are, however, also much smaller than the corresponding leak fluxes observed in resealed ghosts. In view of these differences, formation of IOV's can be concluded to go along with partial annealing of barrier defects persisting in the erythrocyte membrane after preparation of resealed ghosts. Oxidation of SH groups of the IOV membrane by diamide produces an enhancement of permeability for hydrophilic nonelectrolytes which is much less pronounced than that induced by a similar treatment of erythrocytes or ghosts (Klonk, S. and Deuticke, B. (1992) Biochim. Biophys. Acta 1106, 126-136 (Part I in this series)). Moreover, proteolytic treatment of the vesicle membrane, although leading to a marked digestion of integral membrane proteins, only induces a minor, saturating increase of permeability, much lower than that in trypsinized resealed ghosts (Klonk, S. and Deuticke, B. (1992) Biochim. Biophys. Acta 1106, 137-142 (Part II of this series)). Since absence of the cytoskeletal proteins, spectrin and actin, is the major difference between IOV's and resealed ghosts, these results may be taken as further evidence for a dependence of the barrier properties of the erythrocyte membrane bilayer domain on its interaction with cytoskeletal elements. In contrast, these barrier properties seem to be rather insensitive to perturbations of integral proteins.     

Diminished Oleic Acid Absorption in Man by <Emphasis Type="SmallCaps">L</Emphasis>-Phenylalanine Inhibition of an Intestinal Phosphohydrolase

EXPERIMENTS in our laboratory have shown that a change in the position and concentration of intestinal alkaline phosphatase (IAP) in the jejunal mucosa is induced by absorption of oleic acid. To determine whether alkaline phosphatase and fatty acid absorption are causally related, we investigated the effect of an inhibitor of IAP, L-phenylalanine, on the rate of absorption of oleic acid (C₁₈) in man.     

Aldosterone alters the phospholipid composition of rat colonocytes

Previous studies have shown that aldosterone treatment of amphibian epithelial cells results not only in stimulation of Na(+) absorption but also in changes in phospholipid composition which are necessary for the mineralocorticoid action of aldosterone. The present study was designed to investigate the effect of aldosterone on phospholipids of mammalian epithelia. Phospholipid and fatty acid composition was examined in colonic epithelium (mineralocorticoid target tissue) and thymus (non-mineralocorticoid but glucocorticoid target tissue) of rats which had received aldosterone or vehicle by a miniosmotic pump for 7 days. Aldosterone increased the mass of colonic phospholipids relative to cellular proteins with concomitant changes in the percentage distribution of fatty acids, whereas the relative distribution of membrane phospholipds was not changed. Phosphatidylcholine increased the content of polyunsaturated and decreased that of monounsaturated fatty acids, which predominantly reflected the accretion of arachidonic and a decrease in oleic and palmitoleic acids. Within the phosphatidylethanolamine subclass, pretreatment of rats with aldosterone decreased the content of monounsaturated fatty acids (predominantly oleic and palmitoleic acid) and of n-3 fatty acids, and increased the content of saturated fatty acids (palmitic acid). The saturated-to-nonsaturated fatty acid ratio also significantly increased after aldosterone treatment. No changes in thymic phospholipids were seen. The results are consistent with the contention that aldosterone specifically modulates phospholipid concentration and metabolism in mineralocorticoid target tissue. The changes in phospholipid content and its fatty acid composition during the fully developed effect of aldosterone may reflect a physiologically important phenomenon with long-term consequences for membrane structure and function.     

Identification and characterization of some bacterial membrane sulfhydryl groups which are targets of bacteriostatic and antibiotic action

Covalent modification of sulfhydryl groups which become sensitive toward sulfhydryl agents during germination of Bacillus cereus spores exerts a profound bacteriostatic effect, resulting in outgrowth inhibition. The modified spore components are membrane species of 13,000, 28,000, and 29,000 daltons. Detergent disruption of the membrane inactivated the sulfhydryl groups. A highly sigmoid inhibition curve (n = 11.8) with diamide suggested the participation of closely neighboring sulfhydryl groups. Substate and substrate analogs of the lactose and dicarboxylic acid permeases protected the sulfhydryl groups against modification. Nisin, a 34-residue peptide antibiotic, inhibited spore outgrowth and sulfhydryl modification at a concentration of about 0.1 microM. Since these sulfhydryl groups have been implicated as involved with the bacteriostatic action of nitrite, substances directed toward them may be a useful new class of bacteriostatic agents and antibiotics.     

Thiol-dependent K:Cl transport in sheep red cells: VIII. Activation through metabolically and chemically reversible oxidation by diamide

The sulfhydryl (SH) oxidant diamide activated in a concentration-dependent manner ouabain-resistant (OR), Cl-dependent K flux in both low potassium (LK) and high potassium (HK) sheep red cells as determined from the rate of zero-trans K efflux into media with Cl or Cl replaced by NO3 or methane sulfonate (CH3SO3). Diamide did not alter the OR Na efflux into choline Cl. The diamide effect on K efflux appeared after 80% of cellular glutathione (GSH) was oxidized to GSSG, its disulfide. The stimulation of K efflux was completely reversed during metabolic restitution of GSH, a process that depended on the length of exposure to and the concentration of diamide. The action of diamide on both the K:Cl transporter and GSH was also fully reversed by the reducing agent dithiothreitol (DTT). Diamide apparently oxidized the same SH groups alkylated by N-ethylmaleimide (NEM) (Lauf, P.K. 1983. J. Membrane Biol. 73:237-246). Like NEM, diamide activated K:Cl transport several-fold more in LK cells than in HK cells, and the effect on LK cells was partially inhibited by anti-L1, the allo-antibody known to inhibit OR K fluxes.     

Formation of disulfide bonds between glutathione and membrane sh groups in human erythrocytes

In erythrocytes treated with the SH-oxidizing agent, diamide, mixed disulfide bonds between membrane proteins and GSH are formed involving 20% of the membrane SH groups. To study the distribution of these mixed disulfides over the membrane protein fractions, intracellular GSH was labelled biosynthetically with [2-³H]glycine prior to diamide treatment of the cells and the radioactivity of defined membrane peptide fractions determined. Mixed disulfides preferentially occur in the extrinsic protein, spectrin (six SH groups), in addition to the formation of peptide disulfides. Intrinsic proteins are much less reactive: only one SH group of the major intrinsic protein (band 3) reacts with GSH, which accounts for previously observed impossibility to dimerize band 3 via disulfide bonds in intact cells. The labelling method described offers a promising strategy to label and map exposed endofacial SH groups of membrane proteins with a physiological, impermeable marker, GSH.In ghosts treated with diamide and GSH the number of mixed disulfides formed is greater than in erythrocytes. Polymerization of spectrin via intermolecular disulfide bridges is suppressed, while intramolecular disulfides are still formed, providing a means for the analysis of spectrin structure.The diamide-induced mixed membrane-GSH disulfides are readily reduced by GSH. This suggests, that GSH may also be able to reduce mixed disulfides formed in the erythrocyte membrane under oxidative stress in vivo. The reversible formation of mixed disulfides may serve to protect sensitive membrane structures against irreversible oxidative damage.     

Aminophospholipid translocation in erythrocytes: evidence for the involvement of a specific transporter and an endofacial protein

The transport of exogenously supplied fluorescent analogues of aminophospholipids from the outer to inner leaflet in red blood cells (RBC) is dependent upon the oxidative status of membrane sulfhydryls. Oxidation of a sulfhydryl on a 32-kDa membrane protein by pyridyldithioethylamine (PDA) has been previously shown [Connor & Schroit (1988) Biochemistry 27, 848-851] to inhibit the transport of NBD-labeled phosphatidylserine (NBD-PS). In the present study, other sulfhydryl oxidants were examined to determine whether additional sites are involved in the transport process. Our results show that diamide inhibits the transport of NBD-PS via a mechanism that is independent of the 32-kDa site. This is shown by the inability of diamide to block labeling of the 32-kDa sulfhydryl with 125I-labeled PDA and to protect against PDA-mediated inhibition of NBD-PS transport. diamide-mediated inhibition, but not PDA-mediated inhibition, could be reversed by reduction with cysteamine or endogenous glutathione. Similarly, treatment of RBC with 5,5'-dithiobis(2-nitrobenzoic acid), which depletes endogenous glutathione and induces oxidation of endofacial proteins [Reglinski et al. (1988) J. Biol. Chem. 263, 12360-12366], inhibited NBD-PS transport in a manner analogous to diamide. Once established, the asymmetric distribution of NBD-PS could not be altered by oxidation of either site. These data indicate that a second site critical to the transport of aminophospholipids resides on the endofacial surface and suggest that the transport of aminophospholipids across the bilayer membrane of RBC depends on a coordinated and complementary process between a cytoskeletal component and the 32-kDa membrane polypeptide; both must be operative for transport to proceed.     

Distribution of free sulfhydryl and disulfide groups among platelet membrane proteins.

Reactive sulfhydryl and disulfide groups were identified in platelet membrane proteins resolved by sodium dodecyl sulfate-polycrylamide gel electrophoresis. Platelet membranes treated with N-ethyl(1-14C)maleimide, phenyl(203Hg)mercuric acetate and p-chloro(203Hg)mercuribenzoate showed similar patterns of distribution of sulfhydryl groups among the sodium dodecyl sulfate-solubilized membrane proteins. Four major and two minor polypeptides ranging in molecular weight from greater than 200 000 to 20 000 were found to have reactive SH groups. Reduction of membrane proteins by sulfite coupled with subsequent mercaptide formation of the resultant monothiols led to the identification of four polypeptides with disulfide bonds. Reaction of platelet membranes with 14C-labeled 5,5'-dithio-bis(2-nitrobenzoic acid) resulted changes in the distribution profile of the solubilized membrane proteins suggestive of a polymerization process dependent upon, 5,5'-dithio-bis(2-nitrobenzoic acid)-induced intermolecular disulfide interchange.     

Chemical Modification of Membranes : 1. Effects of sulfhydryl and amino reactive reagents on anion and cation permeability of the human red blood cell

Four different amino-reactive reagents, 4-acetamido-4'-isothiocyano-stilbene-2,2'-disulfonic acid (SITS),¹ 1-fluoro-2,4-dinitrobenzene (FDNB), 2,4,6-trinitrobenzene sulfonic acid (TNBS), and 2-methoxy-5-nitrotropone (MNT) decrease the anion permeability of the human red blood cell, as measured by sulfate fluxes, whereas the sulfhydryl agent, parachloromercuriphenyl sulfonic acid (PCMBS), does not. In contrast, PCMBS increases the cation permeability as measured by K⁺ leakage, whereas SITS does not. Of the other agents, FDNB increases the cation permeability to the same extent as PCMBS but MNT and TNBS produce smaller increases. PCMBS does not protect against FDNB as it does against other sulfhydryl agents (X-irradiation) and the FDNB effect on cations is attributed to amino groups. Studies of the binding of SITS indicate that it does not penetrate into the membrane and its failure to influence cation permeability is attributed to its inability to reach an internal population of amino groups. It is concluded that two ion permeability barriers, both involving proteins, are present in the red blood cell. The more superficial barrier contains amino groups and controls anion flow; the more internal barrier contains sulfhydryl and amino groups and controls cation flow. The amino groups contribute to the control of permeability by virtue of their positive charges, but the role of sulfhydryl groups is not clear. Only a small fraction of the membrane protein amino and sulfhydryl is involved in the barriers.     

Occurrence and characteristics of the mitochondrial permeability transition in plants.

The behavior of purified potato mitochondria toward the main effectors of the animal mitochondrial permeability transition has been studied by light scattering, fluorescence, SDS-polyacrylamide gel electrophoresis, and immunoblotting techniques. The addition of Ca(2+) induces a phosphate-dependent swelling that is fully inhibited by cyclosporin A if dithioerythritol is present. Mg(2+) cannot be substituted for Ca(2+) but competes with it. Disruption of the outer membrane and release of several proteins, including cytochrome c, occur upon completion of swelling. Ca(2+)-induced swelling is delayed and its rate is decreased when pH is shifted from 7.4 to 6.6. It is accelerated by diamide, phenylarsine oxide, and linolenic acid. In the absence of Ca(2+), however, linolenic acid (< or =20 microm) rapidly dissipates the succinate-driven membrane potential while having no effect on mitochondrial volume. Anoxic conditions favor in vitro swelling and the concomitant release of cytochrome c and of other proteins in a pH-dependent way. These data indicate that the classical mitochondrial permeability transition occurs also in plants. This may have important implications for our understanding of cell stress and death processes.     

Control of the mitochondrial inner membrane permeability by sulfhydryl groups

The effect of some thiol alkylating agents (N-substituted maleimide derivatives) on the permeability of the mitochondrial inner membrane was investigated. Several experimental approaches were used to study the modifications of the permeability properties. Alkylation of sulfhydryl groups led to an increase in the nonspecific permeability as judged by (i) the augmentation of the rate of osmotic shrinkage of mitochondria induced by polyethylene glycol, (ii) the sensitization of succinate dehydrogenase toward oxaloacetate, (iii) the enhancement of the oxidation rate of exogenous NADH, and (iv) the increase of the sucrose permeable space. The sulfhydryl groups involved in the maintenance of the selective permeability were shown to be located in the hydrophobic core of the membrane. Energization of mitochondria provoked an unmasking of these sulfhydryl groups. When magnesium ions were present in the incubation medium, N-substituted maleimide derivatives promoted gross modifications of the intramitochondrial ionic contents. Effluxes of endogenous calcium ions, inorganic phosphate, adenine nucleotides, and NAD(P)H were established. It was concluded that sulfhydryl groups probably play a crucial role in the maintenance of the membrane integrity and thus control the mitochondrial inner membrane permeability.     

Inhibition of phosphate transport across the human erythrocyte membrane by chemical modification of sulfhydryl groups.

Effects of sulfhydryl-reactive reagents on phosphate transport across human erythrocyte membranes were examined using 31P NMR. Phosphate transport was significantly inhibited in erythrocytes treated with sulfhydryl modifiers such as N-ethylmaleimide, diamide, and Cu2+/o-phenanthroline. Quantitation of sulfhydryl groups in band 3 showed that the inhibition is closely associated with the decrease of sulfhydryl groups. Data from erythrocytes treated with diamide or Cu2+/o-phenanthroline demonstrated that intermolecular cross-linking of band 3 by oxidation of a sulfhydryl group, perhaps Cys-201 or Cys-317, decreases the phosphate influx by about 10%. The inhibition was reversed by reduction using dithiothreitol. These results suggest that sulfhydryl groups in the cytoplasmic domain of band 3 may play an important role in the regulation of anion exchange across the membrane.     

The effect of sulfhydryl oxidation on the morphology of immature hamster epididymal spermatozoa induced to acquire motility in vitro

Immotile spermatozoa from the caput epididymidis become progressively motile when incubated in medium containing theophylline, seminal plasma, and albumin. We previously reported that under these incubation conditions the spermatozoa induced to acquire motility exhibited a marked flagellar angularity, with the sperm head or midpiece bent 90-180 degrees towards the tail. In addition, we demonstrated that sperm flagellar bending did not occur when the sulfhydryl oxidant diamide was added to the motility induction medium. In the present study, we examined further the effect of sulfhydryl oxidation on the morphology and sulfhydryl content of immature caput spermatozoa induced to acquire motility in vitro. We found that flagellar bending was prevented and sperm flagellar straightness was maintained in a dose-dependent manner by diamide. Moreover, flow cytometric analysis of caput sperm sulfhydryls using the sulfhydryl reagent monobromobimane (mBBr) revealed that 1) diamide oxidizes caput sperm sulfhydryls, and 2) less than 15% of the total reactive sperm sulfhydryls were oxidized at diamide concentrations capable of preventing sperm angulation. Sodium tetrathionate (NaTT), another sulfhydryl oxidant, and hamster cauda epididymal fluid (CEF) containing sulfhydryl oxidase enzyme activity also maintained flagellar straightness in induced caput spermatozoa and oxidized sperm sulfhydryls. The flagellar straightness in caput spermatozoa treated with sulfhydryl oxidants, however, was temporary; with extended incubation, diamide- or CEF-treated spermatozoa exhibited flagellar bending. Additional studies showed that the flagellar straightness observed in sulfhydryl-oxidized spermatozoa was sustained when nitrofurantoin, an inhibitor of glutathione reductase, was included in the induction medium. Flow cytometric analysis of nitrofurantoin-treated spermatozoa showed that nitrofurantoin maintained the sperm disulfides formed by diamide and prevented the reduction of sperm disulfides back to sulfhydryls. Taken together, these studies demonstrate the significance of sulfhydryl oxidation in maintaining the morphology of immature caput epididymal spermatozoa induced to acquire motility in vitro and suggest that sulfhydryl oxidation may be important in the development of motility during sperm epididymal maturation in vivo.     

What we can learn from the effects of thiol reagents on transport proteins.

Many secondary membrane transport systems contain reactive sulfhydryl groups. In this review the applications of SH reagents for analyzing the role of sulfhydryl groups in membrane transport systems will be discussed. First an overview will be given of the more important reagents, that have been used to study SH-groups in membrane transport systems, and examples will be given of transport proteins in which the role of cysteines have been analyzed. An important application of SH-reagents to label transport proteins using various SH-reagents modified with fluorescent- or spin-label moieties will be discussed. Two general models are shown which have been proposed to explain the role of sulfhydryl groups in some membrane transport systems.