Sulfhydryl and Disulfide Patterns Associated with Vernalization of Wheat

Analyses of plumules from seedlings of a winter wheat variety (Elgin) and a spring wheat variety (Red Bobs) indicated that SH and SS contents based on protein levels were similar in the whiter and spring wheat tissues grown at 20 C. Boll) varieties, when grown nt 3 C, contained greater concentrations of SH and SS groups, based on protein levels, than those present in the tissues grown at 20 C. The spring wheat tissues at 3 C maintained relatively constant levels of SH and SS during the growth period. Sulfhydryl (SH) and SS groups based on fresh weights were present in greater quantities in the tissues of the spring wheat grown at 20 C than in the winter wheat tissues grown at 20 C. The high SH and SS concentrations present in the warm-grown spring wheat tissues were due to a high concentration of protein extracted from that tissue. The SH and SS contents per unit fresh weight were quite similar in the cold-grown tissues of both varieties during the growth period. Both varieties at both temperatures showed a similar decrease in SH and SS contents, based on fresh weights, as maturation progressed. The spring wheats grown at 3 C and 20 C and the winter wheat grown at 3 C all showed similar characteristics and differed considerably from the winter wheat grown at 20 C. These data were positively correlated with the flowering potential of the wheat varieties.     

Immune oxidative injury induced in mice exposed to normobaric O2: effects of thiol compounds on the splenic cell sulfhydryl content and Con A proliferative response

In vivo exposure of mice to normobaric O2 depresses the cellular immune response by a mechanism that remains unknown. In vitro oxidative injury leads to decreased sulfhydryl groups (SH) in lymphocytes. To determine whether in vivo exposure to O2 would have similar effects, we measured the SH content in spleen cells both from mice that had been exposed to normobaric O2 (O2 SC) and from controls exposed to ambient air (Air SC). The SH content of the fresh O2 SC was slightly decreased, whereas after 48 hr of culture, the SH content and the proliferative response of these cells were found to vary with the type and concentration of thiol or disulfide compounds added to the culture medium. Under standard culture conditions, i.e., RPMI 1640 medium containing 0.41 mM half-cystine, the SH content in O2 SC decreased sharply to about 10 and 20% that of Air SC in the absence or presence of Con A (2 micrograms/ml), respectively. Under these culture conditions, the proliferative response of O2 SC was 20.5% +/- 3.2 of Air SC. In cystine-free RPMI 1640 medium supplemented with various concentrations of L-cystine, L-cystine and 2-mercaptoethanol (2-ME), L-cysteine, or reduced glutathione (GSH), the proliferative response to Con A and the SH content of the O2 SC varied in parallel and were correlated (p less than 0.01). Half-cystine (0.41 mM) plus 2-ME (5 X 10(-5) M) or L-cysteine alone (4 mM) completely protected the SH content of O2 SC and induced a proliferative response 82% +/- 6 that of the controls. In cystine-free RPMI 1640 medium supplemented with GSH (4 mM), the SH content and proliferative response of O2 SC were 79 and 67.5% of Air SC, respectively. Other concentrations of these compounds were less effective. Oxygen scavengers such as SOD, catalase, mannitol, and vitamin E did not protect against the decrease of the O2 SC. The induced oxidative cellular damage might be related in part to a membrane lipid peroxidative process. These data show that in vivo exposure of mice to normobaric O2 induced lesions in splenic cells manifested under standard culture conditions by a decrease in both SH content and Con A proliferative response. The extent of these alterations could be modulated by variations of the thiol environment. Protection of the SH content correlated with protection of the proliferative response of the O2 SC.     

Localization of thiol and disulfide groups in guinea pig spermatozoa during maturation and capacitation using bimane fluorescent labels

The distribution of thiols and disulfides in the guinea pig spermatozoon during maturation and capacitation was studied using both membrane-permeable (mBBr) and impermeable (qBBr) forms of bromobimane, a specific fluorescent probe for thiol groups. In conjunction with the disulfide (SS)-reducing agent dithiothreitol (DTT) and the thiol-alkylating agent N-ethylmaleimide (NEM), quantitative spectrofluorometric measurements of the relative amounts of total thiol (SH) versus SS were performed on cauda epididymal spermatozoa. Under conditions labeling 70% of the reactive thiols, the ratio total SS/SH was 2.4/1.0. Contamination by other cell types prevented similar measurements on spermatozoa at earlier stages of epididymal maturation; thus, the qualitative localization of SH and SS groups in these and in capacitated spermatozoa was visualized using fluorescence microscopy. As spermatozoa moved from the testis to the caput epididymidis, there was a slight apparent increase in staining both on the surface and internally in all regions. Thereafter, surface and internal staining decreased by the time spermatozoa reached the cauda epididymidis. Fluorescence patterns were unaltered under short-term (1 h) capacitation conditions in calcium-free modified Tyrode's medium containing lysophosphatidyl choline and after induction of the acrosome reaction with 2 mM calcium. However, long-term capacitation (16-18 h) in calcium-free modified Tyrode's medium resulted in a loss of detectable SH in the head and acrosome. Regardless of the stage examined, sperm tails contained the greatest relative amount of SH, followed by the head and the acrosome. In addition, there was always more SH detectable internally than on the surface. DTT pretreatment caused a dramatic increase in staining in all regions, both surface and internal, consistent with the quantitative estimates of the SS/SH ratio.     

Sulphydryl and Disulphide Levels in Protein Fractions from Hydrated and Dry Leaves of Resurrection Plants

Significant changes in sulphydryl (‘SH’) and disulphide(‘SS’) levels during air-drying in leaves of ‘resurrection’plants (whose protoplasm survives dehydration) stemmed mainlyfrom protein turnover effects. No significant changes were foundin the SH, SS levels in leaves of the desiccation sensitivespecies Sporobolus pyramidalis following air-drying. The three tolerant species studied differed in the directionof change. Some data were consistent with Levitt's SH, SS hypothesis:increases in protein-SS levels in Sporobolus stapfianus (desiccationtolerant) were consistent with a stabilization of new proteinby SS bonds; lower reactivity of protein-SH in the tolerantspecies Talbotia elegans (which on the other hand has decreasedprotein-SS) is consistent with a second mechanism of decreasingprotein denaturation proposed in Levitt's hypothesis. Evidence of some conversion of SH to SS in the soluble proteinsof Xerophyta viscosa (a tolerant species) would on Levitt'shypothesis indicate an injurious process. Some degree of proteindenaturation might be indicated by partial inactivation of thesoluble enzyme ribulose bisphosphate carboxylase in this species,and loss of some soluble isoenzymes (peroxidase and alkalinephosphatase). An apparent lack of SH conversion to SS in thesensitive species Sporobolus pyramidalis was not consistentwith the SH, SS hypothesis. Resurrection plants, Sporobolus pyramidalis, Sporobolus stapfianus, Talbotia elegans, Xerophyta viscosa, drought resistance, desiccation tolerance, protein turnover, sulphydryl groups     

The effect of L-DOPA on the accumulation of lipid peroxidation products in separate brain structures during irradiation

A study was made of the effect of L-DOPA on the dynamics of changes in lipid peroxidation products (LPP) and the content of various types of SH groups in certain brain structures (oblongata, cerebellum, visual and sensorimotor cortex) and their synaptosomal fractions upon irradiation. The preadministration of L-DOPA to irradiated rats inhibited LPP accumulation, prevented the decrease in the content of various types of thiols and thus exerted an antioxidant effect.     

Interrelations between photoperiod, frost hardiness and sulfhydryl groups in cabbage

Hardening of SD (8 and 12 hrs) and LD (18- and 24-hr photoperiods) cabbage plants in stages at temperatures starting with + 5° and ending with − 3° led to the following changes:

Soluble protein plus nonprotein N showed a net increase only in the SD plants. In both SD and LD plants, it decreased to a minimum toward the end of the first stage of hardening, increased to a maximum in the second stage. The degree of this change was proportional to the photoperiod. These changes were mainly due to the proteins.

As in previous investigations, SH content rose during the first 1 to 2 weeks, but only in the SD plants. This rise was primarily due to the protein fraction. After the first 1 to 2 weeks both SD and LD plants showed a decrease in SH content, most pronouncedly during the second stage of hardening.

Nonprotein SH content was very low and decreased during hardening in both SD and LD plants. Nonprotein SS increased during the first stage of hardening. Total nonprotein SH+2SS rose to a maximum during the first stage of hardening, paralleling both osmotic potential and hardiness. During the second stage the total decreased, in spite of the rise in hardiness. These results held true for both SD and LD plants.

These results are all explainable on the basis of the SHSS theory of frost resistance.

     

Effect of Cysteine and Its Derivatives on 1-Methyladenine Production by Starfish Follicle Cells

Spawning of the gametes in the starfish, Asterina pectinifera , induced by a gonad-stimulating substance (GSS) was inhibited by cysteine. This inhibitory effect of cysteine was due to the reduction of GSS activity and the inhibition of 1-methyadenine (1-MeAde) production in follicle cells. Homocysteine and cysteamine also reduced GSS activity, but cystamine had no effect on the activity. This suggests that the loss of GSS activity is related to a SH group. Furthermore, the effect of cysteine on 1-MeAde production was investigated using isolated follicle cells. The half maximum decrease of the GSS-dependent 1-MeAde production in follicle cells was obtained with the concentration of 2.0 mM L-cysteine. A similar effect was observed with D-cysteine. Homo cysteine and cysteamine also reduced the GSS-dependent 1-MeAde production. But methionine, serine, glutamic acid and aspartic acid did not affect the 1-MeAde production of follicle cells. In addition, cystamine also inhibited the GSS-dependent 1-MeAde production. These suggest that both a SH group and a SS bond of these compounds are effective on the inhibition of the GSS-dependent 1-MeAde biosynthesis. Cysteine and homocysteine also inhibited concanavalin A (Con A).induced 1-MeAde production of follicle cells, but they had no effect on binding of Con A to the surface of follicle cells.     

Variations in Sulfhydryl, Disulfide, and Protein Content during Synchronous and Asynchronous Growth of HeLa Cells

The cellular contents of protein-bound and nonprotein sulfhydry (—SH) and disulfide (—SS—) groups were measured in both asynchronous and synchronous HeLa S3 cultures. About 90% of these groups are associated with proteins, the majority in the —SH form. The content of protein-bound groups, and hence the total content of —SH and —SS— groups (28 × 10^-15 moles/cell, or 1.1 × 10^-6 moles/g protein on average), changes in parallel with the protein content (which varies between 2 and 4 × 10^-10 g/cell) as asynchronous populations pass from the lag through the exponential to the stationary phase of growth. The concentration of nonprotein —SH groups, in contrast, increases 10-fold during lag phase and decreases in stationary phase; it follows the protein concentration closely during the exponential phase, at a level of about 2.8 × 10^-15 moles/cell. In synchronous cultures the protein content doubles during the cell cycle, possibly in an exponential fashion. The total —SH and —SS— content also doubles, but the rate of increase appears to fluctuate. The concentrations of the protein-bound groups show 2- to 3-fold fluctuations per unit protein: protein-bound —SH groups and mixed —SS— linkages rise to maxima while protein-bound —SS— groups fall to a minimum at the G₁/S transition, and fluctuations in these groups occur again during G₂. In addition, the protein-bound —SH concentration falls continuously during the S phase. The nonprotein —SH concentration undergoes the largest (relative) fluctuations, dropping from 4 × 10^-15moles/cell in early G₁ to about 0.4 × 10^-15 moles/cell (of standard protein content) at the end of G₁, and then rising to 30 times this value by the end of S.     

Protein thiols in spermatozoa and epididymal fluid of rats.

Thiol (SH) oxidation to disulphides (SS) is thought to be involved in sperm chromatin condensation and tail structure stabilization, which occur during maturation of spermatozoa. Previously developed procedures, using the fluorescent labelling agent monobromobimane (mBBr), enabled us to study the thiol-disulphide status of spermatozoa. Electrophoretic separation of labelled sperm proteins from the caput and cauda regions showed that during maturation thiol oxidation occurs in many protein fractions from the tail and that the magnitude of oxidation differs between proteins. Among the protein bands, one major band (MPB), probably a dense fibre constituent, is quantitatively prominent. N-Ethylmaleimide (NEM) or mBBr alkylation (of intact spermatozoa) changes the mobility of the caput MPB, but not that of the cauda MPB. The results indicated that the altered mobility of MPB is mainly due to a change in its shape, possibly resulting from the alkylation of a few critical SH groups. Epididymal fluid proteins contain both SH and SS. The thiol and disulphide content of the various epididymal proteins appears similar, although some diminution in fluorescence is seen in epididymal fluid proteins from the cauda region as compared with those from the caput region. The prominent changes in thiol status occur in the spermatozoa.     

Epidermal growth factor (EGF) affects sulphydryl and disulphide levels in cultured mouse skin: possible relationship between effects of EGF and of the tabby gene on thiols

Studies from our laboratory have previously shown that the syndrome produced in the mouse by the X-linked gene tabby (Ta) has many features in common with human X-linked hypohidrotic ectodermal dysplasia. We have also demonstrated that tabby has abnormally elevated epidermal sulphydryl (SH): disulphide (SS) ratios, in common with an autosomal form of ectodermal dysplasia. The organs and tissues affected in many of the traits of these syndromes are targets of epidermal growth factor (EGF) and we have shown that the EGF-producing cells are deficient in tabby. In the present study we examined whether EGF affects SH and SS levels in normal mouse skin in tissue culture, and we report here that it does. EGF at a concentration of 25 ng/mL tissue culture medium lowers SH levels as compared with controls (0 ng/mL) in the epidermal layers examined (stratum malpighii of the tail and stratum malpighii and stratum corneum of flank skin). In general, other concentrations of EGF increase epidermal SH levels, although very high doses also reduce them. EGF at 25 ng/mL also lowers total SH + SS concentrations in the epidermal layers. Fetuses hemizygous for the Ta gene appear to have higher total SH + SS epidermal concentrations than their wild-type control littermates. These data, taken together with some of our previous findings, suggest the possibility that a relationship may exist between Ta, EGF, and thiol concentrations. Further study is required to elucidate this relationship.     

The effect of interaction between human urokinase and its competitive inhibitor, N alpha-benzoyl-L-arginine amide, on reduction of a specific SS bond related to enzymatic activity

The 55- (H-UK) and 36-kDa forms (L-UK) of human urinary urokinase lost most of esterase activity toward acetyl-glycyl-L-lysine methyl ester upon reductive cleavage of 3 SS bonds with dithiothreitol in the presence of the competitive inhibitor, N alpha-benzoyl-L-arginine amide (BAA), bound to polyacrylyl azide with C16N3-arm (PAA) at 0.3 M guanidine, a threshold point of the native state where a protein-denaturating transition began. One of the 3 SS bonds was protected from reduction, with an unaltered activity, under the similar conditions except for replacement of BAA-PAA conjugate by glycine-PAA conjugate. This "specific" SS bond was reduced and, after the other SH groups produced were blocked with iodoacetamide (IAM), selectively reoxidized, which resulted in complete reactivation. The intact B-chain isolated from H-UK was completely inactivated when its specific SS bond was reduced and selectively alkylated with IAM after the other SH groups were reversibly blocked with 5, 5'-dithiobis (2-nitrobenzoic acid), which was finally removed. The results indicate that a single specific SS bond is essential for retaining a conformation necessary to activity exhibition.     

Thiol redox and phosphate transport in renal brush-border membrane. Effect of nicotinamide

In the present study, the effect of thiol redox and its possible role in the inhibitory effect of nicotinamide on renal brush-border membrane (BBM) phosphate uptake was examined. Addition of thiol reducing agent, dithiothreitol (DTT, 5 mM), caused an increase, while addition of thiol oxidant, diamide (DM, 5 mM) caused a reversible decrease in sodium-dependent BBM phosphate uptake. Kinetic analyses revealed an increase in both Vmax and Km by DTT, and a decrease in Vmax by DM. These results suggest that thiol redox influences BBM phosphate uptake with sulfhydryl (SH) groups relate to its capacity and disulfide (SS) groups to its affinity for phosphate. Since changes in cytosolic NAD levels may affect BBM thiol redox through changes in redox states of NADP and glutathione systems, we have examined such possibility by studying the effect of nicotinamide (NM). Incubation of proximal tubules with NM (10 mM) induced an oxidative effect on redox states of cytosolic NAD, NADP systems as inferred from decreased cellular lactate/pyruvate, malate/pyruvate, respectively. Measurements of cytosolic glutathiones and BBM thiols also revealed that NM pretreatment shifted the cytosolic glutathione redox (GSH/GSSG) and BBM thiol redox (SH/SS) toward more oxidized state. On the other hand, incubation of proximal tubules with NM suppressed phosphate uptake by the subsequently isolated BBM vesicles. The lower phosphate uptake by NM-pretreated BBM vesicles was reversed by DTT and was resistant to the inhibitory effect of DM. These results thus suggest that BBM thiol oxidation may be involved in the inhibitory effect of NM on BBM phosphate uptake.     

Decrease in the Gel Strength of Tofu Caused by an Enzyme Reaction during Soybean Grinding and Its Control

The effect of soybean grinding temperature on the firmness of tofu was investigated. The firmness of tofu decreased with increasing grinding temperature between 0°C and 50°C, this being related to the content of sulfhydryl (SH) groups in soymilk. It could, therefore, be presumed that the decrease in firmness depended upon the decrease in SH content, which was of enzymatic nature and closely correlated with the peroxide value. These facts suggested that the decrease in SH content was caused by a lipid oxidative reaction of lipoxygenases in soybean. When the soybean was ground at a low temperature and in a nitrogen atmosphere to inhibit the action of lipoxygenase, the soymilk was rich in SH content and formed firmer tofu.     

The determination of glutathione, cyst(e)ine, and other thiols and disulfides in biological samples using high-performance liquid chromatography with dual electrochemical detection

A determination of glutathione, cysteine, and their disulfides using HPLC and dual electrochemical detection (HPLC-DEC) was described previously but was not validated in biological tissues for these and other important thiols and disulfides (SH/SS). Thus, our objectives were to develop this method to quantify simultaneously reduced and oxidized glutathione, cysteine, cystine, and other SH/SS in various tissues, including human blood and plasma, rat liver and hippocampus, mosquito, and spinach leaf. Optimal conditions were determined for sample processing and analysis using metaphosphoric acid and HPLC-DEC. Authentic standards of 10 common SH/SS compounds were resolved and eluted within 15 min, and all standard curves were linear from 5 to 1600 pmol. Validation was based on the following: First, tissue sample sizes were proportional to peak areas over an eightfold range. Second, recovery of SH/SS added to samples before processing was 96-101%. Finally, the results were equivalent and correlated highly with values for total SH by 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) assay (r2 = 0.996) and for total glutathione by DTNB-GSSG reductase assay (r2 = 0.998). The life span of the Au/Hg electrode was limited to 200-500 samples based on the lineal range of standard curves. On the basis of these results, we believe that this method will fill a long-time need for the simultaneous determination of SH/SS in biological tissues.     

Cutaneous cell and extracellular matrix responses to ultraviolet-B irradiation

The present study examined fibroblasts and keratinocytes in monolayers and cultured within dermal and skin substitutes and their use in assessing the effect of UVB irradiation on cutaneous cells and extracellular matrix organization. Dermal substitutes (DS) were produced by incorporating normal fibroblasts into a collagen lattice and skin substitutes (SS) were obtained by seeding normal keratinocytes onto the DS. Keratinocyte monolayers, fibroblast monolayers, DS, and SS were exposed once a day to a UVB source (10 ml/cm²). The irradiation protocol was stopped when the keratinocytes of the non-irradiated cultures (control groups) had reached confluence. Microscopic observations revealed that UVB radiation decreased both fibroblast and keratinocyte growth and enhanced their differentiation resulting in (1) less fibroblasts in the DS and SS, and (2) incomplete coverage of the DS by keratinocytes. Microscopic observations and histological analyses revealed major morphological changes. Both cell types became bigger and presented wide nuclei and vacuoles in the cytoplasm. No organized deep epidermal layer was observed in irradiated compared to non-irradiated SS. Irradiated DS and SS extracellular matrices showed an irregular aggregating collagen fiber organization with serious discrepancies suggesting large defects in the structural properties of the extracellular matrix. The present study demonstrated that exposure to a UVB source led to profound morphological and functional disturbances in both cutaneous cells and in the extracellular matrices of the DS and SS. The present technology would be of great interest for step-by-step studies of UVR effects on cutaneous cell morphology and functional properties, and could be an alternative to using animals for pharmacological and toxicological evaluations. © 1996 Wiley-Liss, Inc.     

Plant responses to H2S and SO2 fumigation. II. Differences in metabolism of H2S and SO2 in spinach

Fumigation of spinach (Spinacia oleracea L. cvs Estivato and Monosa) with H₂S or SO, for 1 to 6 days resulted in accumulation of sulfhydryl (SH) compounds in the shoots of both H₂S- and SO₂-exposed plants. The sulfate concentration in shoots of SO₂-exposed plants increased linearly with time. SH accumulation showed saturation kinetics as a function of time as well as H₂S concentration, ascribed to the internal H₂S concentration in the plant and the availability of substrates for glutathione synthesis, respectively. SH compounds accumulated more at lower exposure temperatures, whereas sulfate accumulation was more pronounced at higher temperatures. These results are discussed in relation to the possible foliar uptake of H₂S and SO₂, the temperature dependence of uptake and the water solubility of these gases. The possibility of SO₂-induced H₂S emission rather than sulfate accumulation as a source for SH accumulation is also discussed. Cessation of fumigation resulted in a decrease in SH compounds and sulfate content that could be accounted for by sulfur metabolism and growth, respectively.     

Determination of Sulfhydryl and Disulfide Contents of Soybean 11S Globulin and Their Change by lyophilization

Sulfhydryl (SH) and disulfide (SS) contents of soybean 11S globulin (var. Raiden) were determined by means of Ellman’s reagent. The amounts of surface SH, internal SH, and SS bonds of 11S globulin (not lyophilized) were 10.3, 4.6, and 17 mol/mol protein, respectively. On the other hand, when the 1 IS globulin was lyophilized, the surface and internal SH diminished to 5 and 3.6 mol/mol protein, respectively, and the SS bonds increased to 20.1 mol/mol protein. The result from sodium dodecyl sulfate polyacrylamide gel electrophoresis suggested the possibility that the newly formed SS bonds probably existed in each constituent subunit of 1 IS globulin and/or between the intermediary subunits which exist by nature. Differences and similarities between our result and those obtained by various workers were also discussed.     

Interactions of radioprotectors and oxygen in cultured mammalian cells. I. Dithiothreitol effects on radiation-induced cell killing

Radioprotection in vitro by sulfhydryl (SH)-containing compounds is usually greater in aerated than in hypoxic cells. This observation has been cited recently as one of the reasons for the relatively greater effectiveness of radioprotectors such as WR-2721 in normal tissues compared to tumor cells. It is demonstrated herein, however, that hypoxic V79 cells irradiated in vitro under carefully controlled conditions are protected to a greater extent by low concentrations (1-2 mM) of the SH compound dithiothreitol (DTT) than are aerated cells. The reverse, more general phenomenon is seen at high concentrations of DTT (greater than 2 mM). This complex SH concentration and oxygenation dependence results in an increase in the oxygen enhancement ratio (OER) at low concentrations of DTT relative to the OER in the absence of DDT, followed by a decrease in OER at concentrations greater than 2 mM DTT. The possible radiation chemical basis for this finding and its importance to the clinical use of SH-containing radioprotectors are discussed.