Incorporation of 3H-N-ethylmaleimide into sheep red cell membrane thiol groups following protection by diamide-induced oxidation

The thiol oxidant diazene dicarboxylic acid bis [N,N-dimethylamide] (diamide) is known to reversibly activate K-Cl cotransport in sheep red blood cells [1]. Although the detailed mechanism of activation is unknown, functional thiols at the membrane or at the cytoplasmic level are recognized as important. To search for membrane bound thiols involved in the regulation of K-Cl cotransport, sheep red cells were first exposed to diamide at concentrations activating K-Cl cotransport, and then to the alkylating agent N-ethylmaleimide (NEM) in order to block non-oxidized thiols. White ghosts, prepared by osmotic lysis from these cells, were again treated with NEM followed by reduction of the diamide-induced dithiols with dithio-threitol (DTT) concentrations known to reverse the diamide-induced K-Cl flux [1]. Maximum ³H-NEM incorporation into the DTT-reduced thiols occurred at 50 M DTT. Saturation labelling by ³H-NEM of about 2 × 10⁴ diamide-protected thiols/cell occurred at 25 M NEM. Diamide protected about 0.1% of all membrane thiols chemically determined earlier [2]. Membranes from high K (HK) and low K (LK) sheep red cells did not differ significantly in the number of diamide-protected thiols, and polyacrylamide gels revealed a similar protein distribution of 3H-NEM-labelled thiols. Since diamide is known to stimulate K-Cl flux in LK cells ten times more than in HK cells this finding is consistent with the hypothesis of a cytoplasmic control effecting different K-Cl flux activities in the membranes of the two cation genotypic red blood cells.     

Thiol-dependent passive K/Cl transport in sheep red cells: VII. Volume-independent freezing by iodoacetamide,and sulfhydryl group heterogeneity

Summary The sulfhydryl (SH) reagent iodoacetamide (IAAM) inhibits stimulation of Cl-dependent K transport in low K (LK) sheep red cells by another SH reagent, N-ethylmaleimide (NEM), without itself activating this transport pathway (J. Membrane Biol., 1983,73:257–261). We now report that IAAM alone, acting with a kinetic slower than NEM, sharply reduced the capability of the Cl-dependent K transport system to regulate its activity in response to cell volume changes. This effect of IAAM did not depend on the cell volume maintained during chemical treatment, a fact ruling out that the reactivity of the SH groups with IAAM was a function of the volume-dependent turnover rate of the transporter. On the other hand, the prevention of the NEM-stimulatory effect on Cl-dependent K transport was found to be volume-dependent since 1) the rate with which IAAM blocked the subsequent NEM action was twice as fast in cells swollen in 250 mOsm as opposed to cells shrunken in 370 mOsm media, and 2) the dose response of the IAAM effect was different in swollen and shrunken cells. The action of IAAM with or without subsequent treatment with NEM seemed to be independent of cellular ATP which is required for full expression of the stimulatory modification of Cl-dependent K transport by NEM (Am. J. Physiol., 1983,245:C445–C448). Clusters of SH groups on the Cl-dependent K transporter apparently react differently with IAAM and NEM when separately applied but, used in combination, reflect a complex volume-dependent effect that may reveal a volume-sensing component of the transport molecule.     

Thiol-dependent passive K:Cl transport in sheep red blood cells: X. A hydroxylamine-oxidation induced K:Cl flux blocked by diethylpyrocarbonate

Summary Hydroxylamine, a potent oxidizing agent used to reverse carbethoxylation of histidine by diethylpyrocarbonate, activated Cl-dependent K flux (KCl cotransport) of low K sheep red blood cells almost sixfold. When KCl cotransport was already stimulated by N-ethylmaleimide, hydroxylamine caused an additional twofold activation suggesting modification of sites different from those thiol alkylated. This conclusion was supported by the finding that hydroxylamine additively augmented also the diamide-induced KCl flux (Lauf, P.K. 1988.J. Membrane Biol. 101:179–188) with dithiothreitol fully reversing the diamide but not the hydroxylamine effect. Stimulation of KCl cotransport by hydroxylamine was completely inhibited by treatment with diethylpyrocarbonate also known to prevent KCl cotransport stimulation by N-ethylmaleimide, both effects being independent of the order of addition. Hence, although the effect of carbethoxy modification on KCl flux cannot be reversed by hydroxylamine and thus excludes histidine as the target for diethylpyrocarbonate, our finding reveals an important chemical determinant of KCl cotransport stimulation by both hydroxylamine oxidation and thiol group alkylation.     

Volume-sensitive K(+)/Cl(-) cotransport in rabbit erythrocytes. Analysis of the rate-limiting activation and inactivation events

The kinetics of activation and inactivation of K(+)/Cl(-) cotransport (KCC) have been measured in rabbit red blood cells for the purpose of determining the individual rate constants for the rate-limiting activation and inactivation events. Four different interventions (cell swelling, N-ethylmaleimide [NEM], low intracellular pH, and low intracellular Mg(2+)) all activate KCC with a single exponential time course; the kinetics are consistent with the idea that there is a single rate-limiting event in the activation of transport by all four interventions. In contrast to LK sheep red cells, the KCC flux in Mg(2+)-depleted rabbit red cells is not affected by cell volume. KCC activation kinetics were examined in cells pretreated with NEM at 0 degrees C, washed, and then incubated at higher temperatures. The forward rate constant for activation has a very high temperature dependence (E(a) approximately 32 kCal/mol), but is not affected measurably by cell volume. Inactivation kinetics were examined by swelling cells at 37 degrees C to activate KCC, and then resuspending at various osmolalities and temperatures to inactivate most of the transporters. The rate of transport inactivation increases steeply as cell volume decreases, even in a range of volumes where nearly all the transporters are inactive in the steady state. This finding indicates that the rate-limiting inactivation event is strongly affected by cell volume over the entire range of cell volumes studied, including normal cell volume. The rate-limiting inactivation event may be mediated by a protein kinase that is inhibited, either directly or indirectly, by cell swelling, low Mg(2+), acid pH, and NEM.     

Restoration and stimulation of the in vitro immune response of B cells to sheep erythrocytes by interleukins and muramyl dipeptide (MDP)

MDP, a synthetic muramyl dipeptide, is capable of increasing the primary in vitro antibody response, to sheep erythrocytes, of purified B cells restored with a monokine and helper T cell factors, including Interleukin 2 and the late-acting T cell replacing factor (TRF). First, the possibility that the adjuvanticity of MDP could be due to the elaboration of Interleukin 1, caused by its effect on macrophages, was excluded. In addition, a kinetic study showed that the effect of MDP was greater when added later, concomitantly with or one day after the helper T cell factors. Therefore, it appears that MDP acts directly on B cells, in a late stage of their differentiation to antibody-producing cells.     

In vitro immune response to sheep erythrocytes in macrophage depleted cultures. Restoration with interleukine 1 or a monokine from resident macrophages and stimulation by N-acetyl-muramyl-L-alanyl-D-isoglutamine (MDP)

The involvement of macrophages in the adjuvanticity of N-acetyl-muramyl-L-alanyl-D-isoglutamine (MDP) has been examined. The stimulation of the in vitro primary immune response to sheep red blood cells (SRBC) has been studied, because it is known that macrophages cooperate through the mediation of soluble compounds for the induction of the anti-SRBC response. The cultures depleted of macrophages by passing spleen cells on Sephadex G-10 were unable to give any response to SRBC. Their immune responsiveness was fully restored by the addition of either Interleukine 1 (IL 1) obtained from P388D1 cells or a factor able to replace macrophages (FRM) obtained from resident peritoneal macrophages. MDP alone, at any dose, was unable to induce any response in such macrophage depleted cultures, but it was able to enhance the antibody response of these cultures reconstituted with monokines, with the same characteristics in dose effect and timing dependence than in whole spleen cells.     

Furosemide-sensitive K+ (Rb+) transport in human erythrocytes: Modes of operation,dependence on extracellular and intracellular Na+, kinetics,pH dependency and the effect of cell volume and N-ethylmaleimide

Summary The effect of extracellular and intracellular Na⁺ (Na _o ⁺ , Na _i ⁺ ) on ouabain-resistant, furosemide-sensitive (FS) Rb⁺ transport was studied in human erythrocytes under varying experimental conditions. The results obtained are consistent with the view that a (1 Na⁺+1 K⁺+2 Cl^–) cotransport system operates in two different modes: modei) promoting bidirectional 11 (Na⁺–K⁺) cotransport, and modeii) a Na _o ⁺ -independent 11 K _o ⁺ /K _i ⁺ exchange requiring Na _i ⁺ which, however, is not extruded. The activities of the two modes of operation vary strictly in parallel to each other among erythrocytes of different donors and in cell fractions of individual donors separated according to density. Rb⁺ uptake through Rb _o ⁺ /K _i ⁺ exchange contributes about 25% to total Rb⁺ uptake in 145mm NaCl media containing 5mm RbCl at normal Na _i ⁺ (pH 7.4). Na⁺–K⁺ cotransport into the cells occurs largely additive to K⁺/K⁺ exchange. Inward Na⁺–Rb⁺ cotransport exhibits a substrate inhibition at high Rb _o ⁺ . With increasing pH, the maximum rate of cotransport is accelerated at the expense of K⁺/K⁺ exchange (apparent pK close to pH 7.4). The apparentK _m ^Rb _o ⁺ of Na⁺–K⁺ cotransport is low (2mm) and almost independent of pH, and high for K⁺/K⁺ exchange (10 to 15mm), the affinity increasing with pH. The two modes are discussed in terms of a partial reaction scheme of (1 Na⁺+1 K⁺+2 Cl^–) cotransport with ordered binding and debinding, exhibiting a glide symmetry (first on outside = first off inside) as proposed by McManus for duck erythrocytes (McManus, T.J., 1987,Fed. Proc., in press). N-ethylmaleimide (NEM) chemically induces a Cl^–-dependent K⁺ transport pathway that is independent of both Na _o ⁺ and Na _i ⁺ . This pathway differs in many properties from the basal, Na _o ⁺ -independent K⁺/K⁺ exchange active in untreated human erythrocytes at normal cell volume. Cell swelling accelerates a Na _o ⁺ -independent FS K⁺ transport pathway which most probably is not identical to basal K⁺/K⁺ exchange. K _o ⁺ o ⁺

o ⁺ o ²⁺ reduce furosemide-resistant Rb⁺ inward leakage relative to choline _o ⁺ .     

Effect of the central metal ion on the cleavage of DNA by [M(TPA)Cl]ClO4 complexes (M = Co, Cu and Zn, TPA = tris(2-pyridylmethyl)amine): An efficient artificial nuclease for DNA cleavage

[M(TPA)Cl]ClO₄·nH₂O complexes (1: M = Co^II, n = 0; 2: M = Cu^II, n = ½; 3: M = Zn^II, n = 0) where TPA = tris(2-pyridylmethyl)amine, were synthesized and structurally characterized. The molecular structure of [Cu(TPA)Cl]ClO₄·½H₂O was determined by single crystal X-ray crystallography. In aqueous solution, the complex ions [M(TPA)Cl]⁺ (M = Co^II or Cu^II) are hydrolyzed to the corresponding aqua species [M(TPA)(H₂O)]²⁺. In contrast to the TBP [Cu(TPA)(H₂O)]²⁺, the corresponding TBP cobalt(II) species showed severe distortion towards tetrahedral geometry. The interactions of the three complexes with DNA have been investigated at pH 7.0 (1.0 mM Tris-Cl buffer) and 37 °C. Significant DNA cleavages were obtained for complexes 1 and 2, whereas complex 3 did not show any detectable cleavage for DNA. Under pseudo Michaelis-Menten kinetic conditions, the kinetic parameters k_cat and K_M were determined as k_cat = 6.59 h⁻¹ and K_M = 2.20 × 10⁻⁴ M for 1 and the corresponding parameters for 2 are k_cat = 5.7 × 10⁻² h⁻¹ and K_M = 6.9 × 10⁻⁵ M, and the reactivity of the complexes in promoting the cleavage of DNA decreases in the order 1 > 2 ? 3. The rate enhancements for the DNA cleavage by 1 and 2 correspond to 1.8 × 10⁸ and 1.6 × 10⁶, respectively, over the non-catalyzed DNA. The reactivity of the two complexes was discussed in relation to other related artificial nucleases.