Chemical modification of the brown fat mitochondrial uncoupling protein with tetranitromethane

N-ethylmaleimide and mercurials modulate inhibition of the mitochondrial inner membrane anion channel by H+, Mg2+ and cationic amphiphiles

Previously it has been shown that the mitochondrial inner membrane anion channel is reversibly inhibited by matrix Mg2+, matrix H+ and cationic amphiphiles such as propranolol. Furthermore, the IC50 values for both Mg2+ and cationic amphiphiles are dependent on matrix pH. It is now shown that pretreatment of mitochondria with N-ethylmaleimide, mersalyl and p-chloromercuribenzenesulfonate increases the IC50 values of these inhibitors. The effect of the mercurials is most evident when cysteine or thioglycolate is added to the assay medium to reverse their previously reported inhibitory effect (Beavis, A.D. (1989) Eur. J. Biochem. 185, 511-519). Although the IC50 values for Mg2+ and propranolol are shifted they remain pH dependent. Mersalyl is shown to inhibit transport even in N-ethylmaleimide-treated mitochondria indicating that N-ethylmaleimide does not react at the inhibitory mercurial site. However, the effects of N-ethylmaleimide and mersalyl on the IC50 for H+ are not additive which suggests that mercurials and N-ethylmaleimide react at the same 'regulatory' site. It is suggested that modification of this latter site exerts an effect on the binding of Mg2+, H+ and propranolol by inducing a conformational change. It is also suggested that a physiological regulator may exist which has a similar effect in vivo.

The mitochondrial inner-membrane anion channel possesses two mercurial-reactive regulatory sites

The mitochondrial inner membrane anion channel catalyzes the electrophoretic transport of a wide variety of anions and is inhibited by matrix divalent cations and protons. In this paper, evidence is provided that mersalyl and p-chloromercuribenzene-sulfonate each interact with this uniporter at two distinct sites. Binding to site 1 causes a shift in the pH dependence of transport, characterized by a decrease in the pIC50 for protons from about 7.8 to about 7.3, and leads to substantial stimulation of transport in the physiological pH range. This effect is not reversed by addition of thiols such as thioglycolate. Binding of mersalyl and p-chloromercuribenzenesulfonate to site 2 inhibits the transport of most anions including Pi, citrate, malonate, sulfate and ferrocyanide. The transport of Cl- is inhibited about 60% by mersalyl, but is not inhibited by p-chloromercuribenzenesulfonate. These data suggest that inhibition is a steric effect dependent on the size of the anion and the size of the R group of the mercurial. This inhibition is reversed by thioglycolate. Dose/response curves indicate that mersalyl binds to site 1 as the dose increased from 7 to 13 nmol/mg, whereas it binds to site 2 as the dose is increased from 10 to 18 nmol/mg. Thus, at certain pH values both stimulatory and inhibitory phases can be seen in the same dose/response curve. It is suggested that these sites may contain thiol groups and that physiological regulators may exist which can effect changes in activity of the inner membrane anion uniporter similar to those exerted by mercurials.

Sulfhydryl groups of the uncoupling protein of brown adipose tissue mitochondria. Distinction between sulfhydryl groups of the H+ channel and the nucleotide binding site

Mersalyl, 5,5'-dithio-bis(2-nitrobenzoate) (Nbs2) and fluorescent Thiolyte DB react with SH groups in the H+ channel (SHc) of the uncoupling protein of brown adipose tissue mitochondria, as inferred from their inhibition of H+ transport. Cl- transport by the uncoupling protein was unaffected. Using these modifiers and N-ethylmaleimide (MalNEt), distinct SH groups (SHB) in the purine nucleotide binding site were identified. Nbs2 reacts more readily with the SHB than with the SHc groups, but mersalyl and Thiolyte DB are more reactive with the SHc groups. MalNEt reacts exclusively with the SHB. GDP inhibition is fully prevented after sufficient modification of the SHB. Pretreatment with p-diazobenzenesulfonate (N2PhSO2) suppresses only 20-25% of fluorescence of Thiolyte-DB-labeled uncoupling protein on SDS/PAGE gels, while MalNEt suppresses 66% and Nbs2 80-90%. Since N2PhSO2 also affects the GDP binding site, these results demonstrate that the N2PhSO2-reactive residue is not identical with the SHB.

Effect of hydrophobic sulphydryl reagents on the uncoupling protein and inner-membrane anion channel of brown-adipose-tissue mitochondria

The effects of three sulphydryl reagents of differing hydrophobicity (N-ethylmaleimide, N-benzylmaleimide and N,N'-o-phenylenedimaleimide) on ion permeation through the inner membrane of brown-adipose-tissue mitochondria are investigated. GDP-sensitive permeation of chloride and protons (hydroxyl ions) through the uncoupling protein is increased exponentially with time by all three reagents. With increasing hydrophobicity of the reagents, modification is enhanced and an initial inhibited state becomes apparent. Results are interpreted in terms of a two-stage modification via a non-transporting intermediate, which does not bind GDP, to a final highly conducting product. The reagents also react with a hydrophilic sulphydryl group on an independent protein to induce a GDP-insensitive pathway which allows chloride, phosphate and sulphate to cross the membrane. The use of different sulphydryl reagents allows the two pathways to be clearly distinguished.

pH-temperature interactions on protein function and hibernation: GDP binding to brown adipose tissue mitochondria

1. [3H]GDP binding to the uncoupling protein of brown adipose tissue was determined on mitochondria isolated from hibernating European hamsters, at two temperatures, 35 and 15 degrees C, and four values of 25pH (pH corrected to 25 degrees C): 6.4, 6.8, 7.2 and 7.6, encompassing the physiological range of pH. Buffer composition was adjusted to get the same pH-temperature relationship as for mammalian blood, in which this relationship is mainly determined by protein imidazole buffers. 2. The maximal binding capacity was independent both of temperature and pH. The dissociation constant KD was highly pH-dependent, but was independent of temperature when 25pH was held constant. Under these conditions, the uncoupling protein thus fully conserves its regulatory properties over the temperature range studied (eurythermal adaptation). 3. The temperature coefficient of the apparent pK' for the pH effect (-0.012 +/- 0.004) differed significantly from that of GDP terminal phosphoryl group, but not from that of blood protein imidazole buffer groups, in good agreement with the imidazole alphastat theory. 4. The results indicate that GDP reaction with the protein involves an electrostatic binding with a titratable group of the protein, probably a sulfhydryl. 5. pH modulation of the uncoupling of brown adipose tissue mitochondria probably permits a reversible control of thermogenesis in the hibernation cycle, heat dissipation being inhibited by respiratory acidosis in deep hibernation, but facilitated by the hyperventilation of arousal.

Control of uncoupling protein in brown-fat mitochondria by purine nucleotides. Chemical modification by diazobenzenesulfonate

The uncoupling protein (UP) of isolated brown adipose tissue mitochondria was studied with respect to the mechanism of control of UP function by purine nucleotides. Passive transport of H+ and Cl- was followed simultaneously in a KCl medium. With both GDP and ATP a higher sensitivity of Cl- transport (apparent Ki = 2.2 microM and 4.7 microM respectively) than of H+ transport (apparent Ki = 7.7 microM and 34 microM respectively) was observed. Chemical modification of isolated mitochondria by diazobenzenesulfonate (DABS) up to 75 mumol/mg protein did not affect the transport, its ionic selectivity and regulation by endogenous free fatty acids. In contrast, the sensitivity to purine nucleotides of both H+ and Cl- translocation was decreased (apparent Ki increased 71 and 47 times respectively). DABS decreased the affinity of [3H]GDP for the specific nucleotide-binding site on mitochondria (Kd increased from 2.7 microM to 13 microM) and depressed, to a smaller extent, the GDP-binding capacity. Correlation between occupancy of the specific nucleotide-binding site by GDP and inhibition of transport yielded a linear relationship for Cl- transport in control mitochondria. For H+ transport in the control, and for both H+ and Cl- transports in DABS-treated mitochondria, a biphasic correlation was obtained. The results show that different structural parts of UP are involved in transport and its control by the regulatory ligands and that, in addition to binding of purine nucleotides to UP, the inhibition of ion transport by purine nucleotides depends on an intrinsic factor modulating the inhibitory effect.

The uncoupling protein from brown-adipose-tissue mitochondria. Chymotrypsin-induced structural and functional modifications

Mitoplasts prepared from brown adipose tissue mitochondria were treated with chymotrypsin and the fragments derived from the 32-kDa uncoupling protein identified by immunoblotting. Extensive proteolysis of the uncoupling protein occurred, the polypeptide pattern being affected by binding of the inhibitory nucleotide GDP. Chymotrypsin modifies the nucleotide binding site, lowering its affinity from 1.7 microM to 21 microM but without decreasing its binding capacity. Nucleotide bound to the modified site can still inhibit the permeation of H+ and Cl- through the protein. The ion conducting pathway itself is also sensitive to chymotrypsin, Cl- and H+ transport being partially inhibited in parallel. The ability of fatty acids to increase the H+ permeability of the protein is also inhibited in parallel with the basal H+ permeability. The results confirm that the transport of H+ and Cl-, and the fatty acid regulation of H+ permeation all share a common structural element within the 32-kDa protein.

Sulfhydryl groups are involved in H+ translocation via the uncoupling protein of brown adipose tissue mitochondria

Mersalyl inhibits H+ transport via the uncoupling protein (UP) in brown adipose tissue (BAT) mitochondria estimated as swelling in potassium acetate (Ki 67 microM) or as valinomycin-induced H+ extrusion in K2SO4 (Ki 55 microM) and KCl. The swelling in KCl is depressed only slightly. Some other SH-reagents (p-hydroxymercuribenzoate, 5,5'-dithiobis(2-nitrobenzoate) and thiolyte DB), but not hydrophobic reagents (N-ethylmaleimide and eosin-5-maleimide), exhibit analogous inhibition. Thus an essential SH-group localized at the water-accessible cytosolic surface of UP was found to be involved in H+ transport via UP but not in Cl- transport.

Chemical modification of the brown-fat-mitochondrial uncoupling protein with tetranitromethane and N-ethylmaleimide. A cysteine residue is implicated in the nucleotide regulation of anion permeability

Treatment of brown adipose tissue mitochondria with tetranitromethane or N-ethylmaleimide decreases the affinity with which inhibitory nucleotide GDP binds to the tissue-specific uncoupling protein. Both reagents modify cysteine residues which are 'accessible' and 'buried' to 5,5'-dithio-bis(2-nitrobenzoic acid) (Nbs2). Modification of the single Nbs2-accessible residue correlates with the loss of high-affinity binding sites for GDP. Tetranitromethane does not affect the Cl- or H+ permeability of the protein in the absence of nucleotide, while N-ethylmaleimide increases both by 70-80%. Bound GDP is a less effective inhibitor of Cl- permeability after N-ethylmaleimide or tetranitromethane treatment, but retains much of the ability to inhibit H+ permeation.