Relationship between Na+-dependent respiration and Na+ + K+-adenosine triphosphatase activity in the action of thyroid hormone on rat jejunal mucosa.

Administration of three successive doses of triiodothyronine (T3) (50 micrograms/100 g body wt), given on alternate days to thyroidectomized and euthyroid rats, stimulated oxygen consumption (QO2) and Na+ transport-dependent respiration (QO2 [5]) in the stripped jejunal mucosa, a preparation that consisted mostly of epithelial cells. The increase in QO2(t) accounted for 57% of the increment in QO2 in the transition from the hypothyroid to the euthyroid state and for 29% of the increment in the transition from the euthyroid to the hyperthyroid state. Administration of T3 to hypothyroid rats also increased the yield of epithelial cells. Injection of T3 into thyroidectomized and euthyroid rats increased the specific activity (at Vmax) of the (Na+ + K+)-dependent adenosine triphosphatase (NaK-ATPase) in jejunal crude membrane preparations. No significant change was recorded in the activity of Mg-ATPase in the same preparation. The ratio of QO2/NaK-ATPase and QO2(t)/NaK-ATPase in the various thyroid states remained constant, indicating proportionate increased in the respiratory and enzymatic indices. The effect of administration of T3 to thyroidectomized rats on the number of NaK-ATPase units (recovered in the crude membrane preparation) was estimated by: (a) Na+ + Mg++ + ATP-dependent binding of [3H]-ouabain to crude membrane fractions, and (b) the amount of the phosphorylated intermediate formed in the NaK-ATPase reaction from AT32P(gamma). Estimates were obtained of the maximal number of [3H]ouabain binding sites (Nm) and dissociation constants (Kd). Nm for [3H]ouabain and Nak-ATPase specific activity increased to about the same extent after T3 administration to thyroidectomized rats, with no change in the apparent Kd values. The amount of phosphorylated intermediate formed in jejunal crude membrane preparations also increased significantly. Thus, thyroid hormone administration may increase the number of active Na+pump sites in the plasma membrane. The apparent increase in the number of Na+ pump sites also correlated with the hormone dependent increases in QO2 and QO2(t).     

Simulation of pulmonary O2 uptake during exercise transients in humans

Computer simulation of blood flow and O2 consumption (QO2) of leg muscles and of blood flow through other vascular compartments was made to estimate the potential effects of circulatory adjustments to moderate leg exercise on pulmonary O2 uptake (VO2) kinetics in humans. The model revealed a biphasic rise in pulmonary VO2 after the onset of constant-load exercise. The length of the first phase represented a circulatory transit time from the contracting muscles to the lung. The duration and magnitude of rise in VO2 during phase 1 were determined solely by the rate of rise in venous return and by the venous volume separating the muscle from the lung gas exchange sites. The second phase of VO2 represented increased muscle metabolism (QO2) of exercise. With the use of a single-exponential model for muscle QO2 and physiological estimates of other model parameters, phase 2 VO2 could be well described as a first-order exponential whose time constant was within 2 s of that for muscle QO2. The use of unphysiological estimates for certain parameters led to responses for VO2 during phase 2 that were qualitatively different from QO2. It is concluded that 1) the normal response of VO2 in humans to step increases in muscle work contains two components or phases, the first determined by cardiovascular phenomena and the second primarily reflecting muscle metabolism and 2) the kinetics of VO2 during phase 2 can be used to estimate the kinetics of muscle QO2. The simulation results are consistent with previously published profiles of VO2 kinetics for square-wave transients.     

Regional hemodynamic responses to hypoxia in polycythemic dogs

Polycythemia increases blood viscosity so that systemic O2 delivery (QO2) decreases and its regional distribution changes. We examined whether hypoxia, by promoting local vasodilation, further modified these effects in resting skeletal muscle and gut in anesthetized dogs after hematocrit had been raised to 65%. One group (CON, n = 7) served as normoxic controls while another (HH, n = 6) was ventilated with 9% O2--91% N2 for 30 min between periods of normoxia. Polycythemia decreased cardiac output so that QO2 to both regions decreased approximately 50% in both groups. In compensation, O2 extraction fraction increased to 65% in muscle and to 50% in gut. When QO2 was reduced further during hypoxia, blood flow increased in muscle but not in gut. Unlike previously published normocythemic studies, there was no initial hypoxic vasoconstriction in muscle. Metabolic vasodilation during hypoxia was enhanced in muscle when blood O2 reserves were first lowered by increased extraction with polycythemia alone. The increase in resting muscle blood flow during hypoxia with no change in cardiac output may have decreased O2 availability to other more vital tissues. In that sense and under these experimental conditions, polycythemia caused a maladaptive response during hypoxic hypoxia.     

Continued divergence in VO2max of rats artificially selected for running endurance is mediated by greater convective blood O2 delivery.

We previously showed that after seven generations of artificial selection of rats for running capacity, maximal O2 uptake (VO2max) was 12% greater in high-capacity (HCR) than in low-capacity runners (LCR). This difference was due exclusively to a greater O2 uptake and utilization by skeletal muscle of HCR, without differences between lines in convective O2 delivery to muscle by the cardiopulmonary system (QO2max). The present study in generation 15 (G15) female rats tested the hypothesis that continuing improvement in skeletal muscle O2 transfer must be accompanied by augmentation in QO2max to support VO2max of HCR. Systemic O2 transport was studied during maximal normoxic and hypoxic exercise (inspired PO2 approximately 70 Torr). VO2max divergence between lines increased because of both improvement in HCR and deterioration in LCR: normoxic VO2max was 50% higher in HCR than LCR. The greater VO2max in HCR was accompanied by a 41% increase in QO2max: 96.1 +/- 4.0 in HCR vs. 68.1 +/- 2.5 ml stpd O2 x min(-1) x kg(-1) in LCR (P < 0.01) during normoxia. The greater G15 QO2max of HCR was due to a 48% greater stroke volume than LCR. Although tissue O2 diffusive conductance continued to increase in HCR, tissue O2 extraction was not significantly different from LCR at G15, because of the offsetting effect of greater HCR blood flow on tissue O2 extraction. These results indicate that continuing divergence in VO2max between lines occurs largely as a consequence of changes in the capacity to deliver O2 to the exercising muscle.     

The increase of oxygen consumption after a flash of light is tightly coupled to sodium pumping in the lateral ocellus of barnacle

In the lateral ocellus of the barnacle, we have tested the hypothesis that the transient increase of oxygen consumption (delta QO2) induced by light results from an increase in the rate of Na+ pumping. With a Na(+)-sensitive microelectrode, we measured the intracellular concentration of Na+ (Nai) in the photoreceptor cells. Nai was 17.6 +/- 1.2 mM (SE; n = 18) in darkness and it increased transiently by 10-20 mM after an 80-ms flash of intense light. The increase of Nai recovered in about the same time as the delta QO2, and the Na+/O2 ratio was 19.2 +/- 3.8 (SE; n = 6). Removing Na+ from the bath caused the delta QO2 to decrease by 79 +/- 3% (SE; n = 5). Exposure to 25 microM ouabain inhibited Na+ pumping and abolished the delta QO2. Removal of K+ from the bathing solution inhibited Na+ pumping in darkness, but mostly shortened the duration of the delta QO2; with a K(+)-sensitive microelectrode, we measured pericellular [K+] and found that it increased after the flash for about the same time as the delta QO2. Increasing Na+ pumping in darkness by reintroducing K+ in the bath or by injecting Na+ into one of the photoreceptor cells induced a delta QO2. Finally, intracellular injection of adenosine diphosphate and inorganic phosphate (ADP + Pi), the metabolic products of ATP splitting by the Na+ pump, also induced a delta QO2 in darkness. We conclude that all the results obtained are consistent with the formulated hypothesis.     

Effect of endotoxin on systemic and skeletal muscle O2 extraction

Patients with the adult respiratory distress syndrome (ARDS) show a pathological dependence of O2 consumption (VO2) on O2 delivery (QO2, blood flow X arterial O2 content). In these patients, a defect in tissues' ability to extract O2 from blood can leave tissue O2 needs unmet, even at a normal QO2. Endotoxin administration produces a similar state in dogs, and we used this model to study mechanisms that may contribute to human pathology. We measured systemic and hindlimb VO2 and QO2 while reducing cardiac output by blood withdrawal. At the onset of supply dependence, the systemic QO2 was 11.4 +/- 2.7 ml.kg-1.min-1 in the endotoxin group vs. 8.0 +/- 0.7 in controls (P less than 0.05). At this point, the endotoxin-treated animals extracted only 61 +/- 11% of the arterial O2, whereas control animals extracted 70 +/- 7% (P less than 0.05). Systemic VO2 rose by 15% after endotoxin (P less than 0.05) but did not change in controls. Despite this poorer systemic ability to extract O2 by the endotoxin-treated dogs, isolated hindlimb O2 extraction at the onset of supply dependence was the same in endotoxin-treated and control dogs. At normal levels of QO2, hindlimb VO2 in endotoxin-treated dogs was 23% higher than in controls (P less than 0.05). Fractional blood flow to skeletal muscle did not differ between control and endotoxin-treated dogs. Thus skeletal muscle was not overperfused in endotoxemia and did not contribute to a systemic extraction defect by stealing blood flow from other tissues. Skeletal muscle in endotoxin-treated dogs demonstrated an increase in VO2 but no defect in O2 extraction, differing in both respects from the intestine.     

Dissociation of changes in VO2 max, muscle QO2, and performance with training in rats

Before the start and after 4, 8, and 12 wk of a treadmill training program male rats were randomly selected and tested for running performance, maximum O2 consumption (VO2 max), running economy (VO2 submax), and skeletal muscle oxidative capacity (QO2). Data were compared with values from untrained weight-matched control rats. Maximum running time to exhaustion increased significantly (P less than 0.01) by 4 wk and again at 12 wk (P less than 0.01). Submaximal running endurance increased by 120 (4 wk), 320 (8 wk), and 372% (12 wk) (P less than 0.01). VO2 max was increased only at 12 wk (86.0 +/- 2.7 vs. 75.5 +/- 1.9 ml O2.kg-1.min-1); VO2 submax was decreased at 4 and 8 wk but not at 12 wk. Soleus QO2 was unchanged after 4 wk of training and increased by 50% at 8 wk and by 77% at 12 wk. This study is the first to show a dissociation in both the time course and the magnitude of longitudinal changes in VO2 max, VO2 submax, QO2, and maximal and submaximal running performance. We conclude that factors other than those measured explain the improvement in running performance that resulted from endurance training in these rats.     

Treatment of canine aspiration pneumonitis: fluid volume reduction vs. fluid volume expansion

The aspiration of gastric acid causes pulmonary edema and hypoxemia. One approach to the management of this syndrome is to raise cardiac output (Qt) and O2 delivery (QO2) to ensure tissue oxygenation (VO2) at the risk of increasing the edema. Another approach reduces the edema by reducing pulmonary microvascular pressure (Pmv) at the risk of reducing QO2 and VO2. We compared these approaches in 24 anesthetized, ventilated dogs with pulmonary wedge pressure (Ppw), a clinical approximation of Pmv, of 12.5 mmHg. Before and again 1 h after endobronchial instillation of 0.1 N HCl, we measured Qt, QO2, VO2, venous admixture, and in vivo extravascular lung liquid. The dogs were then randomly divided into four equal groups: 1) 12.5 mmHg Ppw, high Qt; 2) 7.5 mmHg Ppw, intermediate Qt; 3) 4.5 mmHg Ppw, low Qt; and 4) 4.5 mmHg Ppw plus dopamine, intermediate Qt. Measured values were followed for 4 more h, after which the lungs were excised to compare wet weight-to-body weight ratios (W/B). When plasmapheresis reduced Ppw at 1 h, edema did not increase further and W/B of groups 2 (21 +/- 3), 3 (18 +/- 3), and 4 (22 +/- 3) were significantly less than in group 1 (27 +/- 3) (P less than 0.001). Although Qt decreased with Ppw, increased hematocrit and reduced venous admixture maintained QO2 in group 2 but not in group 3. In group 4 an intermediate Qt maintained QO2 even at 4.5 mmHg Ppw but edema increased to the group 2 level presumably because Pmv rose with Qt on dopamine. VO2 remained constant over time in each group. These data demonstrate that canine HCl-induced pulmonary edema, measured in vivo or gravimetrically, is very sensitive to reductions in Pmv. Moreover, the lowest Pmv (and QO2) was well tolerated because an O2 supply dependency of VO2 was not observed.     

The response of an established line of rat liver cells to thyroid hormone

The response of an established line of non-transformed adult rat liver epithelial cells (ARL 15) to thyroid hormone (T3) (3,5,3'-triiodothyronine) was characterized. Exposure of confluent monolayers to 1.10(-8) M T3 for 3 days increased O2 consumption (QO2) between 14-58%, ouabain-sensitive Rb+ uptake 26%, (Na+ + K+)-ATPase activity 32%, alpha-glycerophosphate dehydrogenase activity 103% and cytochrome oxidase activity 208%. The ARL 15 cells, maintained in continuous culture, therefore, exhibit the hallmarks of an authentic physiological response to thyroid hormone.     

Kinetics of oxygen consumption after a single flash of light in photoreceptors of the drone (Apis mellifera)

The time course of the rate of oxygen consumption (QO2) after a single flash of light has been measured in 300-micrometers slices of drone retina at 22 degrees C. To measure delta QO2(t), the change in QO2 from its level in darkness, the transients of the partial pressure of O2 (PO2) were recorded with O2 microelectrodes simultaneously in two sites in the slice and delta QO2 was calculated by a computer using Fourier transforms. After a 40-ms flash of intense light, delta QO2, reached a peak of 40 microliters O2/g.min and then declined exponentially to the baseline with a time constant tau 1 = 4.96 +/- 0.49 s (SD, n = 10). The rising phase was characterized by a time constant tau 2 = 1.90 +/- 0.35 s (SD, n = 10). The peak amplitude of delta QO2 increased linearly with the log of the light intensity. Replacement of Na+ by choline, known to decrease greatly the light-induced transmembrane current, caused a 63% decrease of delta QO2. With these changes, however, the kinetics of delta QO2 (t) were unchanged. This suggest that the recovery phase is rate-limited by a single reaction with apparent first-order kinetics. Evidence is provided that suggests that this reaction may be the working of the sodium pump. Exposure of the retina to high concentrations of ouabain or strophanthidin (inhibitors of the sodium pump) reduced the peak amplitude of delta QO2 by approximately 80% and increased tau 1. The increase of tau 1 was an exponential function of the time of exposure to the cardioactive steroids. Hence, it seems likely that the greatest part of delta QO2 is used for the working of the pump, whose activity is the mechanism underlying the rate constant of the descending limb of delta QO2 (t).     

Effects of hyperthermia and hypothermia on oxygen extraction by tissues during hypovolemia

As systemic delivery of O2 (QO2 = QT X CaO2) is reduced during progressive hemorrhage, the O2 extraction ratio [(CaO2 - CVO2)/CaO2] increases until a critical delivery is reached below which O2 uptake (VO2) becomes limited by delivery (O2 supply dependence). When tissue metabolic activity and O2 demand are increased or reduced, the critical QO2 required to maintain VO2 should rise or fall accordingly, unless other changes in the distribution of a limited QO2 precipitate the onset of O2 supply dependence at a different critical extraction ratio. We compared the critical QO2 and critical extraction ratio in 23 normothermic (38 degrees C), hyperthermic (41 degrees C), or hypothermic (34 decrees C) dogs during stepwise reduction in delivery produced by bleeding, as arterial O2 content was maintained. Dogs were anesthetized, paralyzed, and mechanically ventilated. Hypothermia reduced whole-body VO2 by 31%, whereas hyperthermia increased VO2 by 20%. The critical QO2 was significantly reduced during hypothermia (5.6 +/- 0.95 ml.min-1.kg-1) (P less than 0.05) and increased during hyperthermia (8.9 +/- 1.1) (P approximately equal to 0.06) compared with normothermic controls (7.4 +/- 1.2). The extraction ratio at the onset of supply dependency was significantly increased in hyperthermia (0.76 +/- 0.05) compared with hypothermia (0.65 +/- 0.10) (P less than 0.05), and the normothermic critical extraction was 0.71 +/- 0.1. These results suggest that higher body temperatures are associated with an improved ability to maintain a VO2 independent of QO2, since a higher fraction of the delivered O2 can be extracted before the onset of O2 supply dependence, relative to lower body temperatures.     

Respiratory muscle blood flow in exercising dogs after pneumonectomy.

In three foxhounds after left pneumonectomy, the relationships of ventilatory work and respiratory muscle (RM) blood flow to ventilation (VE) during steady-state exercise were examined. VE was measured using a specially constructed respiratory mask and a pneumotach; work of breathing was measured by the esophageal balloon technique. Blood flow to RM was measured by the radionuclide-labeled microsphere technique. Lung compliance after pneumonectomy was 55% of that before pneumonectomy; compliance of the thorax was unchanged. O2 uptake (VO2) of RM comprised only 5% of total body VO2 at exercise. At rest, inspiratory muscles received 62% and expiratory muscles 38% of the total O2 delivered to the RM (QO2RM). During exercise, inspiratory muscles received 59% and expiratory muscles 41% of total QO2RM. Blood flow per gram of muscle to the costal diaphragm was significantly higher than that to the crural diaphragm. The diaphragm, parasternals, and posterior cricoarytenoids were the most important inspiratory muscles, and internal intercostals and external obliques were the most important expiratory muscles for exercise. Up to a VE of 120 l/min through one lung, QO2RM constituted only a small fraction of total body VO2 during exercise and maximal vasodilation in the diaphragm was never approached.     

First-order kinetics of muscle oxygen consumption, and an equivalent proportionality between QO2 and phosphorylcreatine level. Implications for the control of respiration

In frog sartorius muscle, after a tetanus at 20 degrees C, during which an impulse-like increase occurs in the rate of ATP hydrolysis, the rate of O2 consumption (QO2) reaches a peak relatively quickly and then declines monoexponentially, with a time constant not dependent on the tetanus duration (tau = 2.6 min in Rana pipiens and 2.1 min in Rana temporaria). To a good approximation, these kinetics are those of a first-order impulse response, and the scheme of reactions that couple O2 consumption to extramitochondrial ATP hydrolysis thus behaves as a first-order system. It is first deduced and then demonstrated directly that while QO2(t) is monoexponential, it changes in parallel with the levels of creatine and phosphorylcreatine, with proportionality constants +/- 1/tau p, where p is the P/O2 ratio in vivo. From this, it is further deduced that the mitochondrial creatine kinase (CK) reaction is pseudo-first order in vivo. The relationship between [creatine] and QO2 predicted by published models of the control of respiration is markedly different from that actually observed. As shown here, the first-order kinetics of QO2 are consistent with the hypothesis that respiration is rate-limited by the mitochondrial CK reaction; this has as a corollary the "creatine shuttle" hypothesis.     

Pathological supply dependence of systemic and intestinal O2 uptake during endotoxemia

When systemic delivery of oxygen (QO2 = blood flow X arterial O2 content) is reduced, the systemic O2 extraction ratio [(CaO2 - CVO2)/CaO2; where CaO2 is arterial O2 content and CVO2 is venous O2 content] increases until a critical limit is reached below which O2 uptake (VO2) becomes limited by delivery. Patients with adult respiratory distress syndrome and sepsis exhibit supply dependence of VO2 even at high levels of QO2, which suggests that a peripheral O2 extraction defect may be present. We tested the hypothesis that endotoxemia might produce a similar defect in the efficacy of tissue O2 extraction by determining the whole-body critical systemic QO2 (QO2 c) and critical extraction ratio in a control group of dogs and a group receiving a 5-mg/kg dose of Escherichia coli endotoxin. QO2 c was determined in each group by measuring VO2 as QO2 was gradually reduced by bleeding. The VO2 and QO2 of an isolated segment of small intestine were also measured to determine whether O2 extraction was impaired within a local region of tissue. The dogs were anesthetized, paralyzed, and ventilated with room air. Systemic QO2 was reduced in stages by hemorrhage as hematocrit was maintained. The systemic and intestinal critical points were determined from a plot of VO2 vs. QO2. The mean systemic QO2 c and critical O2 extraction ratio of the endotoxemic group (12.8 +/- 2.0 and 0.54 +/- 0.11 ml.min-1.kg-1) were significantly different from control (6.8 +/- 1.2 and 0.78 +/- 0.04) (P less than 0.001), indicating that endotoxin administration impaired systemic extraction of O2. Endotoxin also increased base-line systemic VO2 [6.1 +/- 0.7 (before) to 7.4 +/- 0.1 (after)] (P less than 0.001). The critical and maximal intestinal O2 extraction ratios of the endotoxemic group (0.47 +/- 0.10 and 0.71 +/- 0.04) were significantly less than control (0.69 +/- 0.06 and 0.83 +/- 0.05) (P less than 0.001). In addition, intestinal reactive hyperemia disappeared in six of seven endotoxemic dogs, whereas it remained intact in all control dogs. Thus endotoxin reduced the ability of tissues to extract O2 from a limited supply at the whole body level as well as within a 40- to 50-g segment of small intestine. These results could be explained by a defect in microvascular regulation of blood flow that interfered with the optimal distribution of a limited QO2 in accordance with tissue O2 needs.     

Changes in pyridine nucleotide levels alter oxygen consumption and extra-mitochondrial phosphates in isolated mitochondria: a 31P-NMR and NAD(P)H fluorescence study

Isolated rat-liver mitochondria were used to study the relation between mitochondrial NADH levels, oxygen consumption (QO2), and extra-mitochondrial phosphates. Alterations in NADH and QO2 were accomplished by incubating mitochondria with different substrates or varying amounts of exogenous ATPase while monitoring QO2 and NAD(P)H fluorescence. Two sets of conditions were studied: (1) in the presence of excess ADP and inorganic phosphate, an increase in NAD(P)H fluorescence was associated with a linear increase in QO2; (2) when QO2 was driven by the steady-state hydrolysis of ATP by exogenous ATPase, increases in QO2 were associated with proportional decreases in NAD(P)H fluorescence. For all substrates tested this relation was linear; however, the slope was substrate dependent. Different substrates were able to maintain different NAD(P)H levels at the same QO2. To investigate this further, effects of changing substrates at constant QO2 on NAD(P)H and extra-mitochondrial phosphates were determined. Addition of glutamate + malate to mitochondria respiring on citrate caused a 50% increase in NAD(P)H fluorescence, a 41% decrease in ADP, and a 30% decrease in inorganic phosphate. Similar changes for the substrate jump, pyruvate + malate to glutamate + malate were found. Finally, it was determined that a linear relation holds between increases in NAD(P)H fluorescence and increases in QO2 when substrates were varied at constant, physiologic levels of extra-mitochondrial ADP. These results indicate that QO2 depends on NAD(P)H levels as well as on extra-mitochondrial phosphates over a wide range of respiratory rates.     

Energy metabolism of the human fallopian tube.

The consumption of oxygen (QO2), the production of lactate and the profile of four key metabolic enzymes were measured in small samples of human oviductal mucosa (endosalpinx) removed at surgery. The QO2 in the absence of substrate was 3.4 microliters O2 (mg dry wt)-1 h-1, a value typical of quiescent tissue. The QO2 was stimulated by glucose, but diminished by glutamine and acetoacetate. Tissue lactate production was low and not increased by glucose. Hexokinase had the highest activity of the enzymes measured, followed by 2-oxoglutarate dehydrogenase; 6-phosphofructokinase and glycogen phosphorylase had low activities. The data are consistent with the proposition that glucose is a major metabolic fuel for human endosalpinx.     

The supply of metabolic substrate from glia to photoreceptors in the retina of the honeybee drone

1. The drone retina is composed essentially of only two types of cells: a population of identical photoreceptor cells occupying 38% of the volume is embedded in a syncytium of glia (called outer pigment cells). Nearly all the mitochondria are in the photoreceptors. 2. A retinal slice consumes 18 microliter O2 (ml tissue)-1 min-1 in the dark for up to 6 h, even without exogenous substrate; in 6 h this would require the equivalent of 127 mM glucose in the photoreceptors or 8.7 mg glycogen (ml tissue)-1. 3. Freshly dissected retinas contain about 45 mg glycogen (ml tissue)-1, but this appears, from electron micrographs and from the PAS reaction, to be exclusively in the glia. After superfusion with substrate-free Ringer solution for 30 min, slices of retina contained less than 20 microM glucose. It therefore appears that to sustain respiration, carbohydrate substrate must be transferred from the glia to the photoreceptors. 4. Even after 6 h superfusion with substrate-free Ringer solution O2 consumption (QO2) was not increased by exogenous glucose, pyruvate, trehalose or lactate, nor decreased by 2-deoxy-D-glucose. QO2 was increased 2-3 fold by either light stimulation or (for at least 20 min) by 50 microM dinitrophenol. 5. QO2 was only slightly reduced when Na-dependent glucose transport was inhibited either by reduction of extracellular [Na+], or the presence of phlorizin. 6. It is suggested that drone retinal function does not require the uptake of glucose by the photoreceptors, but that the glia do take up glucose.     

Kinetics of oxygen consumption and light-induced changes of nucleotides in solitary rod photoreceptors

We made simultaneous measurements of light-induced changes in the rate of oxygen consumption (QO2) and transmembrane current of single salamander rod photoreceptors. Since the change of PO2 was suppressed by 2 mM Amytal, an inhibitor of mitochondrial respiration, we conclude that it is mitochondrial in origin. To identify the cause of the change of QO2, we measured, in batches of rods, the concentrations of ATP and phosphocreatine (PCr). After 3 min of illumination, when the QO2 had decreased approximately 25%, ATP levels did not change significantly; in contrast, the amount of PCr had decreased approximately 40%. We conclude that either the light-induced decrease of QO2 is not caused by an increase in [ATP] or [PCr], or that the light-induced change of [PCr] is highly heterogeneous in the rod cell.     

Synergism of triiodothyronine and corticosterone on muscle protein breakdown

The concerted effect of triiodothyronine (T3) and corticosterone on muscle protein synthesis and breakdown was studied. Thyroidectomized young male rats were treated with T3 (1.5 microgram/100 g body weight per day), corticosterone (10 mg/100 g body weight per day) and both T3 and corticosterone for 4 days. On the 3rd day of the experiment urine was collected to measure N tau-methylhistidine excretion as an index of muscle protein breakdown. On the last day of the experiment, the rates of protein synthesis in skeletal muscles were measured by the large-dose [3H]phenylalanine method. N tau-Methylhistidine excretion was slightly increased by T3 treatment and it was increased about 3-times by corticosterone treatment. When both T3 and corticosterone were administered, it was increased about 6-fold. The rate of muscle protein breakdown calculated from the difference between the rate of protein synthesis and the growth rate was consistent with these findings. The rate of muscle protein synthesis was increased by T3, and it was decreased by corticosterone. The rate was the same as that of the thyroidectomized control group when the animals were given T3 and corticosterone, showing that T3 restrained the inhibiting effect of corticosterone on muscle protein synthesis. The results indicate that a physiological level of T3 enhances the catabolic action of pharmacological doses of glucocorticoids on muscle protein breakdown.