Adipose tissue pathways involved in weight loss of cancer cachexia.

BACKGROUND: The regulatory gene pathways that accompany loss of adipose tissue in cancer cachexia are unknown and were explored using pangenomic transcriptome profiling. METHODS: Global gene expression profiles of abdominal subcutaneous adipose tissue were studied in gastrointestinal cancer patients with (n=13) or without (n=14) cachexia. RESULTS: Cachexia was accompanied by preferential loss of adipose tissue and decreased fat cell volume, but not number. Adipose tissue pathways regulating energy turnover were upregulated, whereas genes in pathways related to cell and tissue structure (cellular adhesion, extracellular matrix and actin cytoskeleton) were downregulated in cachectic patients. Transcriptional response elements for hepatic nuclear factor-4 (HNF4) were overrepresented in the promoters of extracellular matrix and adhesion molecule genes, and adipose HNF4 mRNA was downregulated in cachexia. CONCLUSIONS: Cancer cachexia is characterised by preferential loss of adipose tissue; muscle mass is less affected. Loss of adipose tissue is secondary to a decrease in adipocyte lipid content and associates with changes in the expression of genes that regulate energy turnover, cytoskeleton and extracellular matrix, which suggest high tissue remodelling. Changes in gene expression in cachexia are reciprocal to those observed in obesity, suggesting that regulation of fat mass at least partly corresponds to two sides of the same coin.

Metabolic consequences of the presence or absence of the thermogenic capacity of brown adipose tissue in mice (and probably in humans).

Only with the development of the uncoupling protein 1 (UCP1)-ablated mouse has it become possible to strictly delineate the physiological significance of the thermogenic capacity of brown adipose tissue. Considering the presence of active brown adipose tissue in adult humans, these insights may have direct human implications. In addition to classical nonshivering thermogenesis, all adaptive adrenergic thermogeneses, including diet-induced thermogenesis, is fully dependent on brown adipocyte activity. Any weight-reducing effect of ß(3)-adrenergic agonists is fully dependent on UCP1 activity, as is any weight-reducing effect of leptin (in excess of its effect on reduction of food intake). Consequently, in the absence of the thermogenic activity of brown adipose tissue, obesity develops spontaneously. The ability of brown adipose tissue to contribute to glucose disposal is also mainly related to thermogenic activity. However, basal metabolic rate, cold-induced thermogenesis, acute cold tolerance, fevers, nonadaptive adrenergic thermogenesis and processes such as angiogenesis in brown adipose tissue itself are not dependent on UCP1 activity. Whereas it is likely that these conclusions are also qualitatively valid for adult humans, the quantitative significance of brown adipose tissue for human metabolism--and the metabolic consequences for a single individual possessing more or less brown adipose tissue--awaits clarification.

Alpha 1-adrenergic inositol trisphosphate production in brown adipocytes is Na+ dependent.

In order to investigate the ionic requirements for inositol trisphosphate production, brown adipocytes were prelabelled with myo-[3H]inositol and the formation of inositol trisphosphates and inositol bisphosphates as a consequence of alpha 1-adrenergic stimulation was monitored. Omission of Ca2+ from the incubation medium diminished the norepinephrine-induced increase in inositol trisphosphate levels, but it would seem that this reduction can be fully accounted for by a decreased level of the 'inactive' isomer inositol 1,3,4-trisphosphate. Omission of Na+ fully abolished the norepinephrine-induced inositol trisphosphate response. However, it was observed that the presence of Li+ in the incubation medium could fully reconstitute the ability of the cells to yield the early response of inositol trisphosphate production; Li+ could, however, not substitute for Na+ in the entire alpha 1-adrenergic cellular pathway. It was concluded that the Na+-dependent step is found in the coupling mechanism between the alpha 1-receptor and the activation of the phosphodiesterase responsible for inositol trisphosphate production. Thus, all events in the alpha 1-adrenergic pathway which are consequences of IP3 production should appear to be Na+-dependent in these cells.

Sulfonates are low-affinity ligands for the GDP-binding site of brown-fat mitochondria.

In order to study the function of the brown-fat specific uncoupling protein thermogenin (UCP), the effect of certain sulfonates on [3H]GDP binding to the GDP-binding site of brown adipose tissue mitochondria was studied. The affinity of [3H]GDP for the site was 1.3 microM in the normal sucrose medium, but the apparent KD was increased to approximately 20 microM in 100 mM hexanesulfonate medium. This increase in apparent KD was found to be due to a competitive binding of hexanesulfonate to the GDP-binding site; the affinity of hexanesulfonate was only 13 mM but this was sufficient to affect the apparent affinity of GDP under experimental conditions. Also in KCl-medium, the affinity of GDP was high (approximately 3 microM), but both in a benzenesulfonate medium and in a para-aminobenzenesulfonate (sulfanilate) medium, the apparent affinity was lower (approximately 12 microM); as benzenesulfonate is well transported by thermogenin but sulfanilate is not, the reduction in affinity was unrelated to transport. In agreement with earlier data (Jezek, P. and Garlid, K.D. (1990) J. Biol. Chem. 265, 19303-19311), the potency of GDP to inhibit transport was dependent on the species transported; the fact that GDP potency was lower for benzenesulfonate transport (EC50 = 324 microM) than for Cl- transport (EC50 = 32 microM) could adequately be explained by the competitive interaction of benzenesulfonate with the GDP-binding site, but this effect could only partly explain the even lower potency of GDP to inhibit hexanesulfonate transport (EC50 = 4074 microM). It was concluded that these types of substrate for thermogenin-mediated transport may directly interact with the GDP-binding site, but that this effect could only partly explain the dependence of GDP potency on substrate species.

Presence of a Ca2+-dependent K+ channel in brown adipocytes. Possible role in maintenance of alpha 1-adrenergic stimulation.

We have previously demonstrated mobilization of Ca2+ in and efflux of Rb+ (K+) from isolated hamster brown adipocytes as a consequence of norepinephrine stimulation. We have now investigated the adrenoceptor subtype specificity of these responses and found them both to be of the alpha 1-subtype. Further, we have found that the Rb+ (K+) efflux was dependent upon a primary Ca2+ mobilization event in response to the alpha 1-adrenergic stimulation, since the Rb+ efflux could also be demonstrated by the addition of the Ca2+ ionophore A23187 to the cells. The norepinephrine- and A23187-stimulated Rb+ effluxes were both inhibited by the Ca2+-dependent K+-channel blocker apamin. Apamin also significantly attenuated Ca2+ mobilization in cells in response to a submaximal concentration of norepinephrine. We conclude that alpha 1-adrenergic stimulation of brown fat cells leads to a mobilization of intracellular Ca2+ which, in itself or via other mechanisms, leads to an increase in cytosolic Ca2+ concentration which, in turn, activates a Ca2+-dependent K+ channel, leading to a K+ release from these cells. A possible role for this channel to sustain and augment the response to alpha 1-adrenergic stimulation is discussed.

Alpha-adrenergic effects on 86Rb+ (K+) potentials and fluxes in brown fat cells.

Net K+ fluxes in isolated hamster brown fat cells were studied by the use of the K+ analogue 86Rb+. In isolated cells, cold-stored overnight to diminish K+ gradients, an equilibrium 86Rb+ (K+) clearance value of 27 microliter/million cells was obtained after 30 min incubation at 37 degrees C. This corresponds to a 10-fold K+ gradient over the plasma membrane, and a K+ potential of about -60 mV. The attainment of this equilibrium was dependent upon the presence of Na+ in the extracellular medium, and the uptake was fully inhibited by the (Na+ + K+)-ATPase inhibitor ouabain. Ouabain had, however, no significant acute effect on the maximal rate of thermogenesis achieved after norepinephrine stimulation of the cells, but if the restoration of ionic equilibrium was inhibited by ouabain in prolonged incubations, a decreased thermogenesis was observed. This was probably due to the low cytosolic K+ content then encountered, and the resulting inhibition of lipolysis. The addition of norepinephrine to cells in which 86Rb+ (K+) equilibrium had been attained resulted in a rapid efflux of 86Rb+ and the establishment of a new equilibrium value, at about 65% of the unstimulated value. This corresponds to a decrease in K+ potential of about 15 mV. The effect of norepinephrine was stereospecific and reversible, and had an EC50 value of about 10 nM. As catecholamine effects were much more sensitive to phentolamine than to propranolol, the adrenergically-induced efflux was classified as predominantly alpha-adrenergic. It is suggested that the norepinephrine-induced K+ efflux is due to a (probably Ca2+-mediated) opening of K+ channels in the cell membrane, and that this effect occurs secondarily to the alpha-adrenergically induced membrane depolarization (and increase in cytosolic Ca2+). The increased PK over the cell membrane would counteract further depolarization, and the K+ gradient would then approach the Nernst equilibrium under the new steady-state conditions.

Inhibition of acetyl-carnitine oxidation in rat brown-adipose-tissue mitochondria by erucoyl-carnitine is due to sequestration of CoA.

The cause underlying the inhibitory effect of erucoyl-carnitine on acetyl-carnitine oxidation in rat brown-adipose-tissue mitochondria was investigated. The inhibition was shown to be of a noncompetitive nature, with an I50 of about 10 microM erucoyl-carnitine. Erucoyl-carnitine did not inhibit the respiratory chain or the citric acid cycle to a significant degree. Incubation of mitochondria with erucoyl-carnitine led to about 2/3 of all CoA being sequestered in the form of acid-insoluble esters (probably erucoyl-CoA). This sequestration had an apparent Km of about 10 microM. Erucoyl-carnitine also inhibited pyruvate oxidation with an I50 of about 10 microM. When added at this concentration, it also inhibited the oxidation of a wide variety of acyl-carnitines by about 50%, despite very different oxidation rates of these different acyl-carnitines. It was concluded that the inhibitory effect of erucoyl-carnitine on all CoA-dependent substrates could be adequately explained by the suggestion that erucoyl sequesters a significant fraction of mitochondrial matrix CoA as slowly metabolizable erucoyl-CoA esters. Possible physiological effects of this sequestration for brown adipose tissue thermogenesis are discussed.

Requirement of gene transcription and protein synthesis for cold- and norepinephrine-induced stimulation of thyroxine deiodinase in rat brown adipose tissue.

The increase in propylthiouracil-insensitive 'type II' thyroxine 5'-deiodinase activity of brown adipose tissue was investigated in rats exposed to acute cold stress or single-dose norepinephrine injection. The 20-fold cold-induced increase in enzyme activity showed a 2-h lag phase and reached a maximum after only 8 h; reacclimation occurred with a 2-h time lag and a half-life of 2.2 h. 4 h after a single norepinephrine injection, the deiodinase activity was almost identical to that after a 4-h cold stress; norepinephrine could not potentiate the effect of the cold stress. Treatment with the protein synthesis inhibitor cycloheximide before exposure to cold or before norepinephrine injection totally blocked the increase in deiodinase activity, suggesting that the increase is due to de novo protein synthesis. The half-life of the enzyme in vivo was estimated to be 0.7 h. Treatment with the RNA synthesis inhibitor actinomycin D totally abolished the cold- and norepinephrine-induced increases, indicating that the increase requires mRNA synthesis. It was concluded that the dramatic cold-induced increase in thyroxine deiodinase activity in brown adipose tissue was not due to activation of preexisting enzyme but was fully due to a norepinephrine-induced increase in expression of the gene and subsequent synthesis of the protein.

NADH-sensitive propionyl-CoA hydrolase in brown-adipose-tissue mitochondria of the rat.

Acyl-CoA hydrolase activity was studied in brown adipose tissue (BAT) mitochondria of rats. The substrate specificity was investigated: total hydrolase activity showed two activity peaks, one sharp peak for propionyl-CoA and a broad peak at medium- to long-chain acyl-CoAs. The propionyl-CoA activity fully comigrated with a mitochondrial matrix marker enzyme in fractionation studies of tissue and mitochondria. The hydrolytic activity against short-chain acyl-CoAs was inhibited by NADH, and analyses of the substrate specificity of the hydrolases in the presence and absence of NADH allowed for the delineation of two distinct acyl-CoA hydrolases. These hydrolases could also be separated by gel filtration. It was concluded that rat BAT mitochondria possess at least two matrix acyl-CoA hydrolases: one broad-spectrum acyl-CoA hydrolase with an apparent native molecular weight of less than 100,000, and a specific propionyl-CoA hydrolase with an apparent native molecular weight at least 240,000; this hydrolase is regulated by NADH. It is suggested that the function of the propionyl-CoA hydrolase is to ensure that the level of propionyl-CoA in the mitochondria is not detrimentally increased.

Metabolic consequences of limited substrate anion permeability in brown fat mitochondria from a hibernator, the golden hamster.

Brown fat mitochondria obtained from a hibernator, the golden hamster, were investigated in order to elucidate the significance of membrane permeability for metabolic functioning at different temperatures. The mitochondria were shown to have active permeases for phosphate and pyruvate, but very poorly developed permeases for di- and tricarboxylate substrate anions. This was shown with both osmotic swelling techniques and respiration-driven uptake studies. It was shown that the very limited malate permeation observed was compatible with it being a non-carrier-mediated diffusion process. The role of malate transport in supporting fatty-acid oxidation in vitro as a function of temperature was studied in detail. The results support our earlier suggestion that physiologically pyruvate carboxylase probably functions to generate oxaloacetate when high concentrations of condensing partner are needed during thermogenesis. They may also explain earlier observations that acetate was produced from palmitoyl-carnitine at low temperatures even when malate was present; this is here shown to be due to the limited malate permeability at these low temperatures. Thus, even at the body temperature of the hibernating hamster (4-5 degrees C), brown fat is probably able to combust fatty acids totally.

UCP1: the only protein able to mediate adaptive non-shivering thermogenesis and metabolic inefficiency.

The uniqueness of UCP1 (as compared to UCP2/UCP3) is evident from expression analysis and ablation studies. UCP1 expression is positively correlated with metabolic inefficiency, being increased by cold acclimation (in adults or perinatally) and overfeeding, and reduced in fasting and genetic obesity. Such a simple relationship is not observable for UCP2/UCP3. Studies with UCP1-ablated animals substantiate the unique role of UCP1: the phenomenon of adaptive adrenergic non-shivering thermogenesis in the intact animal is fully dependent on the presence of UCP1, and so is any kind of cold acclimation-recruited non-shivering thermogenesis; thus UCP2/UCP3 (or any other proteins or metabolic processes) cannot substitute for UCP1 physiologically, irrespective of their demonstrated ability to show uncoupling in reconstituted systems or when ectopically expressed. Norepinephrine-induced thermogenesis in brown-fat cells is absolutely dependent on UCP1, as is the uncoupled state and the recoupling by purine nucleotides in isolated brown-fat mitochondria. Although very high UCP2/UCP3 mRNA levels are observed in brown adipose tissue of UCP1-ablated mice, there is no indication that the isolated brown-fat mitochondria are uncoupled; thus, high expression of UCP2/UCP3 does not necessarily confer to the mitochondria of a tissue a propensity for being innately uncoupled. Whereas the thermogenic effect of fatty acids in brown-fat cells is fully UCP1-dependent, this is not the case in brown-fat mitochondria; this adds complexity to the issues concerning the mechanisms of UCP1 function and the pathway from beta(3)-adrenoceptor stimulation to UCP1 activation and thermogenesis. In addition to amino acid sequences conserved in all UCPs as part of the tripartite structure, all UCPs contain certain residues associated with nucleotide binding. However, conserved amongst all UCP1s so far sequenced, and without parallel in all UCP2/UCP3, are two sequences: 144SHLHGIKP and the C-terminal sequence RQTVDC(A/T)T; these sequences may therefore be essential for the unique thermogenic function of UCP1. The level of UCP1 in the organism is basically regulated at the transcriptional level (physiologically probably mainly through the beta(3)-adrenoceptor/CREB pathway), with influences from UCP1 mRNA stability and from the delay caused by translation. It is concluded that UCP1 is unique amongst the uncoupling proteins and is the only protein able to mediate adaptive non-shivering thermogenesis and the ensuing metabolic inefficiency.

Analysis of inhibition by H89 of UCP1 gene expression and thermogenesis indicates protein kinase A mediation of beta(3)-adrenergic signalling rather than beta(3)-adrenoceptor antagonism by H89.

Although it has generally been assumed that protein kinase A (PKA) is essential for brown adipose tissue function, this has not as yet been clearly demonstrated. H89, an inhibitor of PKA, was used here to inhibit PKA activity. In cell extracts, it was confirmed that norepinephrine stimulated PKA activity, which was abolished by H89 treatment. In isolated brown adipocytes, H89 inhibited adrenergically induced thermogenesis (with an IC(50) of approx. 40 microM), and in cultured cells, adrenergically stimulated expression of the uncoupling protein-1 (UCP1) gene was abolished by H89 (full inhibition with 50 microM). However, H89 has been reported to be an adrenergic antagonist on beta(1)/beta(2)-adrenoceptors (AR). Although adrenergic stimulation of thermogenesis and UCP1 gene expression are mediated via beta(3)-ARs, it was deemed necessary to investigate whether H89 also had antagonistic potency on beta(3)-ARs. It was found that EC(50) values for beta(3)-AR-selective stimulation of cAMP production (with BRL-37344) in brown adipose tissue membrane fractions and in intact cells were not affected by H89. Similarly, the EC(50) of adrenergically stimulated oxygen consumption was not affected by H89. As H89 also abolished forskolin-induced UCP1 gene expression, and potentiated selective beta(3)-AR-induced cAMP production, H89 must be active downstream of cAMP. Thus, no antagonism of H89 on beta(3)-ARs could be detected. We conclude that H89 can be used as a pharmacological tool for elucidation of the involvement of PKA in cellular signalling processes regulated via beta(3)-ARs, and that the results are concordant with adrenergic stimulation of thermogenesis and UCP1 gene expression in brown adipocytes being mediated via a PKA-dependent pathway.

Contrasting adrenergic effects on lipoprotein lipase gene expression in the brown adipose tissue of intact mice and in cultured brown adipocytes from mice.

To examine the regulation of lipoprotein lipase (LPL) gene expression, LPL mRNA levels in the brown adipose tissue of intact mice and in mouse brown adipocyte cultures were examined. In intact mice, exposure to cold resulted in a rapid, transient, 5-fold increase in LPL mRNA level. Norepinephrine (NE) injection could fully mimic the effect of acute exposure to cold, and LPL mRNA and enzymatic activity were increased in parallel after NE injection. These results indicated positive adrenergic control of LPL gene expression in the brown adipose tissue of intact mice. In cultured mouse brown adipocytes, the level of spontaneously expressed LPL mRNA decreased in parallel with the progression of brown adipocyte differentiation. NE treatment of undifferentiated cells led to a decrease in LPL mRNA levels. In brown adipocytes that had reached a mature state, NE had a small negative or no effect on LPL mRNA levels, irrespective of whether the experiment was performed in the presence or absence of insulin or of newborn-calf serum. It was concluded that LPL gene expression in brown adipose tissue in intact mice is under adrenergic control but that this gene is not under positive adrenergic control in cultured brown adipocytes from mice, although these cells are otherwise adrenergically sensitive. The presence of additional factors may be necessary to confer adrenergic sensitivity to the LPL gene in the cultured brown adipocytes; alternatively, cells other than the mature brown adipocytes may confer the positive adrenergic sensitivity to the brown adipose tissue depots in situ.

Norepinephrine as a morphogen?: its unique interaction with brown adipose tissue.

Norepinephrine is normally considered a neurotransmitter mediating acute metabolic effects in target cells. However, analysis of the regulation of the recruitment process in brown adipose tissue has indicated that norepinephrine may interact with this tissue in such a way that it could be considered a morphogen for this tissue. Besides stimulating the acute thermogenic processes, norepinephrine can induce the expression of tissue-specific proteins such as the uncoupling protein, induce expression of non-tissue specific proteins necessary of the thermogenic processes (e.g. lipoprotein lipase) and repress the expression of non-essential proteins (e.g. subunit c of the ATP-synthase). Upon chronic adrenergic stimulation, the general differentiation state of the tissue is advanced, indicating that the expression of factors with a more general effect on brown adipocyte differentiation is also under adrenergic control. It may even be discussed that norepinephrine may be involved early in the embryonal determination process directing cell clones into this line. The molecular basis for these effects of norepinephrine are only poorly known at present, but adrenergic effects on the expression level of many transcription factors, such as C/EBPalpha, C/EBPbeta, and PPARgamma 2, have been noted. These collective recruitment effects of norepinephrine are well suited to allow the tissue to grow or atrophy in response to the physiological needs of the organism.

beta1 to beta3 switch in control of cyclic adenosine monophosphate during brown adipocyte development explains distinct beta-adrenoceptor subtype mediation of proliferation and differentiation.

To explain the distinctive pharmacological profiles observed for adrenergic stimulation of cell proliferation (beta1) and cell differentiation (beta3), the adrenergic control of cAMP accumulation was investigated during brown adipocyte development. In preadipocytes, norepinephrine (NE) increased cAMP levels but the beta3-agonists BRL-37344 and CGP-12177 did not; in contrast, when the cells had differentiated into mature brown adipocytes, a large cAMP response to the beta3-agonists had emerged and was now double that to NE (although the affinity of NE had increased 10-fold). Beta1-messenger RNA (mRNA) levels were high in both pre- and mature brown adipocytes; beta3-mRNA did not appear until maturation but then abruptly. Although beta1-receptors remained detectable by [3H]CGP-12177 binding in the mature brown adipocytes, the cAMP response to NE (based on propranolol inhibitory potency) switched from beta1 to beta3. Even the established beta1-agonist dobutamine acted through beta3-receptors in the mature brown adipocytes. The increases in cAMP levels could adequately explain the increased cell proliferation in NE-stimulated preadipocytes and the NE-induced UCP1 gene expression in mature brown adipocytes. The distinctive adrenergic profiles for stimulation of proliferation and of differentiation were thus not due to the existence of additional pathways but to a switch in the type of beta-receptor mediating the NE response, coordinated with an alteration in the nuclear response to increased cAMP levels. The study implies that full recruitment of brown adipose tissue cannot be induced by exclusive beta3-stimulation.

Alpha 1-adrenergic stimulation of Cl- efflux in isolated brown adipocytes.

Unidirectional 36Cl- efflux from preloaded isolated brown adipocytes was studied. A norepinephrine-stimulated 36Cl- efflux pathway was found which approximately doubled the rate of 36Cl- efflux from the cells. The response to norepinephrine was fully inhibited by the alpha 1-adrenergic antagonist prazosin, but was unaffected by the beta-adrenergic antagonist propranolol, showing that norepinephrine stimulated the 36Cl- efflux pathway via the alpha 1-adrenoceptor. The stimulation of 36Cl- efflux could not be mimicked by the Ca2+ ionophore A23187, indicating that the effect was not mediated by elevation of the intracellular Ca2+ level. It is concluded that brown fat cells possess a specific mechanism for alpha 1-adrenergic stimulation of Cl- efflux. The possibility is discussed that this Cl- efflux pathway could be the basis for the early alpha-adrenergic depolarization seen in brown fat cells.

Physiological activation of brown adipose tissue destabilizes thermogenin mRNA.

The amount of mRNA coding for the brown fat specific uncoupling protein thermogenin was followed in the brown adipose tissue of adult mice. As expected, cold exposure or norepinephrine injection caused an increase in the amount of thermogenin mRNA. However, contrary to expectation, the half-life of thermogenin mRNA was dramatically reduced, from about 18 h to about 3 h, when the mice were cold exposed. This destabilization of thermogenin mRNA was not related to the activity of protein synthesis. It was concluded that in brown adipose tissue an unusual mechanism operates which leads to a destabilization of thermogenin mRNA under the same physiological conditions which increase thermogenin gene expression.

Exclusive occurrence of thermogenin antigen in brown adipose tissue.

Thermogenin is the purine-nucleotide binding polypeptide in brown adipose tissue mitochondria (Mr 32 000) which confers upon these mitochondria the ability to produce heat. An enzyme-linked immunosorbent assay (ELISA) has been developed to demonstrate and quantitate the occurrence of thermogenin antigen in small amounts of tissue, and thus to characterize different depots of fat tissue as white or brown. The extreme sensitivity of the method allows determination of thermogenin in samples equivalent to less than 1 mg tissue. The results indicate that thermogenin seems to be exclusively localised in brown fat mitochondria (as compared to white fat, liver or heart muscle mitochondria), and thermogenin antigen could only be found in brown adipocytes (as compared to white adipocytes). Thus, brown and white adipose tissue are probably ontogenetically different.

Kinetics of the inhibition of mitochondrial respiration by NO.

The kinetics of the inhibition of mitochondrial respiration by NO was examined in isolated mitochondria (here obtained from rat brown adipose tissue). The Ki of NO for the inhibition was approximately 27 nM; the IC50 of NO increased in proportion to the square of an increase in O2 tension. The Km of O2 for respiration was approximately 16 microM; in the presence of NO, the dependence of respiration on O2 tension had a Hill coefficient of approximately 2. The unusual kinetics is probably related to the ability of cytochrome c oxidase to use 2 NO or 1 O2 as electron acceptor. The interaction between NO and O2 in the control of respiration could be described by the formula VO2(O2, NO) = VO2max x ([O2]2/((16 microM x (1 + [NO]/27 nM))2 + [O2]2)). Thus, the kinetics is such that respiration in the presence of physiological levels of NO is very sensitive to decreasing O2 tension.

Norepinephrine-induced synthesis of the uncoupling protein thermogenin (UCP) and its mitochondrial targeting in brown adipocytes differentiated in culture.

Synthesis of the brown adipocyte-specific mitochondrial uncoupling protein thermogenin (UCP) is demonstrated here in brown adipocytes differentiated in culture from precursor cells. By immunoblotting, no UCP was detectable in untreated multilocular adipocytes. The synthesis of UCP was stimulated by norepinephrine at physiological concentrations and was observable already after 2 h. It was evident from immunoelectron microscopy that the newly synthesised protein was targeted to the mitochondrial inner membrane, demonstrating the functional competence of these cultured cells.