D-glucose metabolism in normal dispersed islet cells and tumoral INS-1 cells

The metabolism of D-glucose was characterized in both normal dispersed rat islet cells and the 2-mercaptoethanol-dependent insulin-secreting cells of the INS-1 line. The normal and tumoral islet cells differed from one another by the relative magnitude, concentration dependency and hierarchy of the increase in the production of ³HOH from D-[5-³H]glucose and ¹⁴C-labelled CO₂, acidic metabolites and amino acids from D-[U-¹⁴C]glucose at increasing concentrations of the hexose. For instance, whilst the paired ratio between D-[U-¹⁴C]glucose oxidation and D-[5-³H]glucose utilization augmented in a typical sigmoidal manner in normal islet cells exposed to increasing concentrations of D-glucose, it progressively decreased under the same experimental conditions in INS-1 cells. Nevertheless, the absolute values and concentration-response relationship for the increase in ATP generation rate attributable to the catabolism of D-glucose were virtually identical in normal and tumoral cells. These findings indicate that the analogy in the secretory response to D-glucose of normal and INS-1 islet cells, although coinciding with a comparable response to the hexose in terms of ATP generation, contrasts with a vastly different pattern of D-glucose metabolism in these two cell types.     

Polarization of chlorotetracycline fluorescence in pancreatic islet cells and its response to calcium ions and D-glucose.

Suspensions rich in pancreatic beta-cells were prepared from non-inbred ob/ob-mice, incubated with 10 micrometer-chlorotetracycline, and analysed for fluorescence polarization in a microscope. Throughout the temperature range 16--38 degrees C, fluorescence was enhanced by 5 mM-Ca2+ in the incubation medium; 20 mM-D-glucose decreased the fluorescence measured in the presence of Ca2+. Fluorescence showed a curvilinear negative regression on temperature. The curves were rectified to a virtually ideal degree by Arrhenius transformations of data. Non-parametric testing of differences between linearized regression lines forms the basis for the following conclusions. The temperature-dependence of fluorescence intensity appeared to be smaller for Ca2+-specific signals than for the background fluorescence of chlorotetracycline in Ca2+-deficient cells. D-Glucose significantly diminished the polarization of fluorescence in cells incubated with Ca2+. It is suggested that D-glucose increases the mobility of Ca2+ in beta-cell plasma membranes; this mobility increase may help to explain previously reported effects of D-glucose on 45Ca2+ fluxes and membrane electric potential.     

Hexose metabolism in pancreatic islets. Feedback control of D-glucose oxidation by functional events

A rise in extracellular D-glucose concentration in pancreatic islet cells causes a greater relative increase in the oxidation of pyruvate and acetyl residues than in glycolysis. A possible explanation for such an unusual situation was sought in the present study. The preferential stimulation of mitochondrial oxidative events was found to display a sigmoidal dependency on hexose concentration, and an exponential time course during prolonged exposure of the islets to a high concentration of D-glucose. The preferential stimulation of mitochondrial oxidative events was abolished in islets incubated in the presence of cycloheximide and absence of Ca2+, in which case the oxidation of D-[6-14C]glucose was more severely inhibited than that of D-[3,4-14C]glucose. Likewise, the inhibitor of protein biosynthesis and the absence of Ca2+ affected the oxidation of L-[U-14C]leucine preferentially, relative to that of L-[1-14C]leucine, in islets exposed to a high, but not a low, concentration of the amino acid. These results demonstrate that in pancreatic islets it is possible to dissociate both glycolysis from mitochondrial oxidative events and the oxidation of acetyl residues from their generation rate. Moreover, the experimental data suggest that nutrient-responsive and ATP-requiring functional processes exert a feedback control on mitochondrial respiration in this fuel-sensor organ.     

Stimulation of mitochondrial protein synthesis by metal ions.

1--10 muM Cu2+, Ag+, and Au3+ were found to stimulate rat liver mitochondrial protein synthesis in vitro. Cu2+ and Ag+ also produced an increase in mitochondrial volume ("swelling"). Thus, thyroid hormones and their analogs are not unique, as suggested previously (Buchanan, J.L., Primack, M.P. and Tapley, D.F. (1970) Endocrinology 87, 993--999), in stimulating both mitochondrial protein synthesis and swelling. Furthermore, the data suggest a role for Cu2+ in the regulation of mitochondrial protein synthesis.     

Uncoupling of mitochondrial oxidative phosphorylation by thallium.

The mechanism of integration of λ$\text{bio}$ll, which is deleted of all the known λ recombination genes, was studied using $\text{bio}$ deleted hosts as recipients. The presence of $\text{rec}$BC DNase and $\text{exo}$I in the recipient cells affected the fate of λ$\text{bio}$ll DNA. In nine of ten $\text{imm}\text{λ}{}^{\mathrm{+}}$ transductants, insertion of the λ$\text{bio}$ll genome took place somewhere between J and N and the remaining one had abnormally permuted prophage λ. In this lysogen (#42), the sequence of prophage genes was similar to that of vegetative phage λ. The properties of lysogen #42 were compared with those of other lysogens.     

Stimulation of rat liver mitochondrial adenosine triphosphatase by anions.

The hydrolysis of MgATP by isolated rat liver mitochondrial ATPase (EC 3.6.1.3) at pH 8.0 was stimulated by various anions. The rate of hydrolysis was increased from 18 to 170 mumol per min per mg, a 9.4-fold stimulation, by HSeO3 at 1 mM MgATP. In the absence of a stimulatory anion, reciprocal plots of initial velocity studies with MgATP as the variable substrate were curved (Hill coefficient approximately 0.5). With the addition of anion, the reciprocal plots became linear. When the substrate was MgITP or MgGTP with the isolated enzyme or MgATP with submitochondrial particles, no curvature of the reciprocal plots was observed. With purified ATPase, anions stimulated the hydrolysis of MgITP, MgGTP, MgUTP or MgCTP only slightly. With submitochondrial particles the stimulation by anions of MgATP hydrolysis was limited to approximately 2-fold. These data are interpreted to indicate the existence of two substrate sites for MgATP and an anion-binding site on the isolated enzyme.     

DAPK2 regulates oxidative stress in cancer cells by preserving mitochondrial function

Death-associated protein kinase (DAPK) 2 is a serine/threonine kinase that belongs to the DAPK family. Although it shows significant structural differences from DAPK1, the founding member of this protein family, DAPK2 is also thought to be a putative tumour suppressor. Like DAPK1, it has been implicated in programmed cell death, the regulation of autophagy and diverse developmental processes. In contrast to DAPK1, however, few mechanistic studies have been carried out on DAPK2 and the majority of these have made use of tagged DAPK2, which almost invariably leads to overexpression of the protein. As a consequence, physiological roles of this kinase are still poorly understood. Using two genetically distinct cancer cell lines as models, we have identified a new role for DAPK2 in the regulation of mitochondrial integrity. RNA interference-mediated depletion of DAPK2 leads to fundamental metabolic changes, including significantly decreased rate of oxidative phosphorylation in combination with overall destabilised mitochondrial membrane potential. This phenotype is further corroborated by an increase in the production of mitochondrial superoxide anions and increased oxidative stress. This then leads to the activation of classical stress-activated kinases such as ERK, JNK and p38, which is observed on DAPK2 genetic ablation. Interestingly, the generation of oxidative stress is further enhanced on overexpression of a kinase-dead DAPK2 mutant indicating that it is the kinase domain of DAPK2 that is important to maintain mitochondrial integrity and, by inference, for cellular metabolism.Death-associated protein kinase (DAPK) 2 shares a high level of homology within its kinase domain with the other two DAPK family members, DAPK1 (DAPk) and DAPK3 (ZIPK/DLK). Since the identification of DAPK1 by Kimchi and co-workers¹ numerous studies have shown that DAPK1 functions as a tumour suppressor, is linked to key events in autophagy and is involved in mitochondrial maintenance² and metabolism.³ DAPK2, which was characterised in 1999,⁴ is significantly smaller than DAPK1, and it lacks ankyrin repeats, the cytoskeletal binding domain and the death domain, all of which are part of DAPK1''s unique structure.¹ Several functions have been ascribed to DAPK2 and they often coincide with those of DAPK1. Like DAPK1, DAPK2 is also involved in the formation of autophagic vesicles,^{5, 6} modulation of receptor induced cell death^{7, 8, 9} and several modes of intrinsic apoptotic cell death.⁶ While epigenetic silencing of DAPK1 has been reported in many different human cancers,^{10, 11} DAPK2 appears to be silenced mainly in haematological disorders,¹² although it has been shown to modulate TRAIL-induced apoptosis in several cancer cell lines of non-haematological origin.⁹ Most approaches used for studying the role of DAPK2 used tagged DAPK2 and it is, therefore, still unclear whether these functions are also carried out by the native protein, expressed at much lower, endogenous, levels.DAPK1 has been shown to regulate mitochondrial integrity and to modulate the mitochondrial membrane potential² but, to the best of our knowledge, no work has been carried out in this respect with regard to DAPK2. Since DAPK1 and DAPK2 appear to share many functions and both are thought to reside, at least partially, in the mitochondria, we hypothesised that DAPK2 depletion regulated mitochondrial metabolism. Mitochondrial dysfunction is characterised by the induction of reactive oxygen species (ROS) in the cell.¹³ Ultimately, dysfunctional mitochondria can no longer be powerhouses of use to the cell and are, therefore, targeted for degradation. Alternatively, their membranes can depolarise leading to the release of cytochrome c, an early apoptotic process.¹⁴ Using two distinct cancer cell types, namely U2OS osteosarcoma and A549 non-small cell lung cancer cells,^{9, 15} we show that DAPK2 depletion increases the levels of intracellular ROS, leads to mitochondrial depolarisation and impairs mitochondrial metabolism. DAPK2 thus exerts metabolic and mitochondria-regulating functions, which have not been described to date and that can explain why it is downregulated in haematological malignancies,^{12, 16, 17} and involved in modulating death-inducing signalling in solid tumours.⁹     

Cytosolic and mitochondrial glutathione in microglial cells are differentially affected by oxidative/nitrosative stress.

Glutathione (GSH), the major cellular protectant against reactive oxygen and nitrogen species, is compartmentalized in a cytosolic (c) and a mitochondrial (mt) pool. We investigated how c-GSH and mt-GSH are differentially affected by endogenously produced nitric oxide (NO). Microglial cell line (N9) cultures were immunostimulated with lipopolysaccharide/interferon-gamma to elicit the inducible isoform of NO synthase (iNOS). Despite a significant reduction in total GSH, the mt-GSH remained nearly unaffected by iNOS-mediated NO production. To investigate possible consequences of GSH depletion on the mitochondrial membrane potential, we used buthionine sulfoximine (BSO) to reduce separately the c-GSH, whereas ethacrynic acid (EA) was applied to deplete both mt-GSH and c-GSH. The mitochondrial membrane potential was more vulnerable to NO exposure in EA-pretreated cultures than in BSO-pretreated cultures, indicated by a potentiated release of tetramethylrhodamine from mitochondria into the cytosol. To relate the EA-mediated decrease in mitochondrial membrane potential to the oxidant buildup after GSH depletion, we loaded the cells with the oxidant-sensitive fluorochrome 2',7'-dihydrodichlorofluorescein (DCF) diacetate. EA treatment caused an increase in DCF fluorescence over time that was potentiated when the iNOS expression was stimulated. Inhibition of NO production abolished this effect. We conclude that endogenous NO production in microglial cells does not compromise the mt-GSH pool which, in turn, might explain the ability of these cells to combat high-output NO production.     

Direct evidence for the control of mitochondrial respiration by mitochondrial creatine kinase in oxidative muscle cells in situ

The efficiency of stimulation of mitochondrial respiration in permeabilized muscle cells by ADP produced at different intracellular sites, e.g. cytosolic or mitochondrial intermembrane space, was evaluated in wild-type and creatine kinase (CK)-deficient mice. To activate respiration by endogenous production of ADP in permeabilized cells, ATP was added either alone or together with creatine. In cardiac fibers, while ATP alone activated respiration to half of the maximal rate, creatine plus ATP increased the respiratory rate up to its maximum. To find out whether the stimulation by creatine is a consequence of extramitochondrial [ADP] increase, or whether it directly correlates with ADP generation by mitochondrial CK in the mitochondrial intermembrane space, an exogenous ADP-trap system was added to rephosphorylate all cytosolic ADP. Under these conditions, creatine plus ATP still increased the respiration rate by 2.5 times, compared with ATP alone, for the same extramitochondrial [ADP] of 14 microM. Moreover, this stimulatory effect of creatine, observed in wild-type cardiac fibers disappeared in mitochondrial CK deficient, but not in cytosolic CK-deficient muscle. It is concluded that respiration rates can be dissociated from cytosolic [ADP], and ADP generated by mitochondrial CK is an important regulator of oxidative phosphorylation.     

A new mitochondrial RNA deletion fragment accelerated by oxidative stress in rat L6 cells.

RNA deletions may be easier to detect and more extensive than DNA deletions. Two large deletion fragments (1120 and 7811 bp) of mitochondrial RNA were observed in rat L6 muscle cells. At the site of the 1120 bp deletion, the remaining RNA fragment was re-linked by a short additional section (GGTATGAAGCT). These kinds of deletions were accelerated by oxidative stress and were not observed in mitochondrial DNA.     

Stimulation of cardiac glucose transport by inhibitors of oxidative phosphorylation.

Previously we showed that hypoxia in heart stimulates glucose transport via translocation of glucose transporters from intracellular membranes to the plasma membrane. We later showed that rotenone, an inhibitor of oxidative phosphorylation, also decreased intracellular transporters. Here, using another membrane fractionation technique, we show that rotenone increases plasma membrane transporters, and that another respiratory chain inhibitor, azide, acts similarly. Thus, they likely activate the same signaling pathway as hypoxia. Genistein, a tyrosine kinase inhibitor, inhibited insulin- and azide-stimulated 3-O-methylglucose transport similarly in cardiac myocytes. It also increased glucose transporters in the plasma membranes of perfused hearts even though it inhibited glucose uptake, suggesting effects on membrane trafficking. Another tyrosine kinase inhibitor, lavendustin A, and the cyclic nucleotide-dependent protein kinase inhibitors H-8 and H-7 had little effect on basal or azide-stimulated transport. Polymyxin B was a weak inhibitor of basal, insulin-stimulated, and azide-stimulated transport. A nitric oxide donor and a nitric oxide synthase inhibitor had no effect on basal and azide-stimulated transport. The results indicate that tyrosine kinases; protein kinases A, G, and C; and nitric oxide are not involved in the hypoxic activation of cardiac glucose transport.     

Stimulation of mitoplast respiration by mitochondrial porin

Mitochondrial porin (2 ng/ml) being added to the rat liver mitoplasts considerably stimulates the respiration in the third and uncoupled states. As the same effect was observed previously with the addition of outer membrane fraction to the mitoplast suspension, it is concluded that mitochondrial porin participates in regulation of the mitochondria respiration and, probably, is the natural activator of the ADP/ATP carrier function.     

Impaired uptake of D-glucose by tumoral insulin-producing cells

At variance with the situation found in normal pancreatic islets, no equilibration of extracellular and intracellular D-glucose concentrations occurs in tumoral insulin-producing cells of the RINm5F line. This unexpected behaviour may account, in part at least, for the abnormal kinetics of glucose utilization in the tumoral cells and their poor secretory response to this hexose.     

Specific induction of metallothionein synthesis by mitochondrial oxidative stress.

Metallothionein (MT), a sulfhydryl-rich protein, may be increased by administration of a variety of agents, including metals, cytokines and oxidative stress agents. Mitochondria are a major source of reactive oxygen species, but antioxidant systems against mitochondrial free radicals are not fully understood. In this study, we examined the induction of MT synthesis by administration of mitochondrial-specific reactive oxygen generators such as antimycin A (AA), an electron transfer inhibitor, and 2,4-dinitrophenol (DNP), an uncoupling agent. Subcutaneous administration of AA to mice significantly increased the hepatic MT concentration in a dose- and time-dependent manner. AA slightly elevated glutathione peroxidase (GSHPx) activity, but the rate of increase in GSHPx (1.3-fold) was smaller than that in MT (11.8-fold). Other antioxidants such as catalase, manganese-superoxide dismutase (Mn-SOD), copper/zinc-superoxide dismutase (Cu/Zn-SOD) and GSHPx were not activated by AA treatment. Moreover, administration of DNP induced the synthesis of MT in the liver. Although DNP slightly elevated Mn-SOD activity, the rate of increase in Mn-SOD (1.3-fold) was smaller than that in MT (3.7-fold). Other antioxidants such as catalase, Cu/Zn-SOD and GSHPx were not activated by DNP treatment. These data suggest that MT plays a major role in protection against oxidative stress induced in mitochondria.