Oral administration of the biomimetic [Cr3O(O2CCH2CH3)6(H2O)3]+ increases insulin sensitivity and improves blood plasma variables in healthy and type 2 diabetic rats

The in vivo effects of gavage administration of the synthetic, functional biomimetic cation [Cr₃O(O₂CCH₂CH₃)₆(H₂O)₃]⁺ to healthy and type 2 diabetic model rats are described. After 24 weeks of treatment (0–1,000 g Cr/kg body mass) of healthy Sprague Dawley rats, the cation results in a lowering (P<0.05) of fasting blood plasma low-density lipoprotein (LDL) cholesterol, total cholesterol, triglycerides, and insulin levels and of 2-h plasma insulin and glucose concentrations after a glucose challenge. Zucker obese rats (a model of the early stages of type 2 diabetes) and Zucker diabetic fatty rats (a model for type 2 diabetes) after supplementation (1,000 g Cr/kg) have lower fasting plasma total, high-density lipoprotein, and LDL cholesterol, triglycerides, glycated hemoglobin, and insulin levels and lower 2-h plasma insulin levels in glucose tolerance tests. The lowering of plasma insulin concentrations with little effect on glucose concentrations suggests that the supplement increases insulin sensitivity. The cation after 12 and 22 or 24 weeks of administration lowers (P<0.05) fasting plasma glycated hemoglobin levels in the Zucker diabetic and Zucker obese rats, respectively, and thus can improve the glucose status of the diabetic models. The effects cannot be attributed to the propionate ligand.Supplementary material is available for this article at .An erratum to this article can be found at     

The influence of lecithin on plasma choline concentrations in triathletes and adolescent runners during exercise

An investigation was carried out on the effect of lecithin (phosphatidylcholine, 90%) on the plasma choline concentrations during continuous strain in 10 top level triathletes (4 women and 6 men), trial I, and 13 excellent adolescent runners (3 girls and 10 boys), trial II. Venous blood, collected before and immediately after the race, was separated and plasma was assayed by an improved high performance liquid chromatography method for choline. Each study comprised three experiments. In trial I the triathletes performed two periods of bicycle exercise each lasting 2 h at an average speed of 35 km · h^–1, and in the second study (trial II) the subjects were subjected to severe physical stress on two occasions during cross-country races of durations between 30–60 min according to their ages. The participants received either a placebo or 0.2 g lecithin · kg body mass^–1, 1 h before each exercise. As a control the same dose of lecithin was administered without any exercise (both trials I and II). Bicycle exercise without lecithin supply decreased plasma choline concentrations in all the triathletes, on average by 16.9% (P0.01). When lecithin was given before exercise, average plasma choline concentrations remained at the same level as the initial values. The supply of lecithin without exercise led to a significant increase of the plasma choline concentrations, on average by 26.9% (P0.01). In trial II, when running without a supply of lecithin, the mean plasma choline concentrations in the adolescent runners remained stable which may have been due to the duration of the physical stress. When lecithin was given before exercise, plasma choline concentrations increased, on average by 18.9% (P0.01). The administration of lecithin without exercise led in these participants to an increase in plasma choline concentrations, on average by 54% (P0.001).It was found from the present study that a combination of both lecithin intake and hard physical stress prevented in most subjects a decrease in plasma choline and this could affect performance.     

Mechanisms of acid-base and ionoregulation in white suckers (Catostomus commersoni) in natural soft water

Summary Simultaneous measurements of whole body proton flux and both unidirectional and net ion fluxes together with assessment of the blood acid-base, respiratory gas, electrolyte and lactate status were performed in white suckers (Catostomus commersoni) originating from a natural soft water lake ([Ca⁺⁺]=0.18 meq·l^–1) in Ontario, Canada. Fish were examined under control (pH 6.8) and acidic conditions (pH4.3) in natural soft water at 19–20 °C. Resting blood composition was similar to that previously reported for this species in natural hard water except for a marked enhancement of both plasma pH and bicarbonate levels.Acute acid exposure promoted a significant net influx of protons (or loss of base) concomitant with a plasma acidosis of mixed origin (metabolic+respiratory) as well as whole body Na⁺, Cl^–, Ca⁺⁺ and K⁺ losses. Circulating ion levels in plasma were partially conserved by intracellular ion depletion. Radiotracer studies showed that net body losses of Na⁺ and Cl^– ensued largely through stimulation of efflux components and, to a lesser extent, inhibition of inward transport. Cl^– loss eventually exceeded Na⁺, suggesting transport of an unmeasured substance to maintain electroneutrality. A markedly reduced blood , enhanced plasma , elevated blood lactate levels and significant hemoconcentration were also observed. Thus, disturbances in acid-base regulation, ionoregulation and respiratory function may all contribute to acid toxicity in white suckers in natural soft water.Abbreviations ECF extracellular fluid - Hb hemoglobin - Ht hematocrit - ICF intracellular fluid - MCHC mean corpuscular hemoglobin concentration - TEP transepithelial electrical potential To whom offprint requests should be sent     

Sulfide-hemoglobin interactions in the sulfide-tolerant salt marsh resident,the California killifish Fundulus parvipinnis

Summary Sulfide can potentially damage hemoglobin or be detoxified by hemoglobin. In the sulfide-tolerant California killifish neither seems to be the case at environmentally realistic (micromolar) and physiologically relevant (millimolar) sulfide concentrations. An 8-h exposure of killifish to 5 and 8 mmol sulfide · 1^-1 results in 50–100% mortality, but not due to sulfhemoglobin (where sulfide covalently binds to the porphyrin) nor ferric hemoglobin (Hb⁺), both dysfunctional hemoglobin derivatives. Killifish hemoglobin converts to sulfhemoglobin in vitro only in the presence of 1–5 mmol sulfide · 1^-1. The amount of sulfhemoglobin formed increases with time and heme concentration but decreases with pH. Hb⁺ binds sulfide as ferric hemoglobin sulfide (Hb⁺S, an unstable complex where sulfide ligates to the iron), and also as sulfhemoglobin. Killifish blood does not catalyze the oxidation of 10–500 mol sulfide · 1^-1 to any appreciable extent. Radiolabeled sulfide incubated with oxyhemoglobin or whole blood disappears at rates greater than in buffers, but only minimal amounts of thiosulfate and no sulfate nor sulfite are formed (elemental sulfur and bound sulfide not quantified). Sulfide disappearance rates increase linearly with initial sulfide concentration. Hb⁺ does catalyze the oxidation of sulfide to thiosulfate in vitro. Similar experiments on another sulfide-tolerant species, the long-jawed mudsucker Gillichthys mirabilis, produced similar results.Abbreviations ANOVA analysis of variance - BV benzyl viologen - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - HPLC high-pressure liquid chromatography - RBC red blood cells - SHb sulfhemoglobin     

Respiratory adaptations in carp blood influences of hypoxia, red cell organic phosphates, divalent cations and CO2 on hemoglobin-oxygen affinity

Summary This study concerns the adaptation of oxygen transporting function of carp blood to environment hypoxia, tracing the roles played by erythrocytic cofactors, inorganic cations, carbon dioxide and hemoglobin multiplicity.Carp acclimated to hypoxia ( 30 mmHg) display striking increases in blood oxygen affinity compared to normoxic ( =120–150 mm) specimens (P ₅₀'s are 3.0 and 7.0 mm, respectively, at pH 7.9 and 20°C). This correlates with a marked decrease in erythrocytic concentrations of NTP (nucleoside triphosphates) (Figs. 1, 2, Table 1), permitting investigation of the time-course of the response (Fig. 3). That GTP (guanosine triphosphate) plays a greater role than ATP in the allosteric regulation of blood oxygen affinity, follows from greater decreases in its concentration during hypoxia, and its greater effect on oxygen affinity of the hemoglobin (Figs. 1, 5). It is furthermore shown that divalent cations (which complex with NTP) inhibit the regulatory role of GTP on O₂ affinity to a lesser extent than that of ATP (Fig. 7). However, the divalent cation, Mg²⁺, occurs in similarly high concentrations in the erythrocytes of hypoxic and normoxic fish (Table 1). CO₂ specifically depresses the O₂ affinity of carp hemoglobin, but below pH 8.3, its effect is obliterated by ATP and GTP suggesting that the chains are the main sites for CO ₂ ^– binding. Four carp hemoglobin components are isolated and their oxygen-binding properties compared with those of the cofactor-free hemolysate (Figs. 4, 8, 9). The results are discussed comparatively with special reference to hemoglobin function in fish and mammals.     

Spontaneous methylation of hemoglobin by S-adenosylmethionine by a specific and saturable mechanism

The methyl group from S-adenosylmethionine (AdoMet) is transferred into hemoglobin without any evident involvement of an enzyme. There are multiple sites for incorporation of the methyl group into hemoglobin, since both and chains are methylated. The methyl linkages formed in hemoglobin are stable at both alkaline and acidicpH, and the reaction occurs optimally at slightly below neutralpH. Only a small fraction (2%) of hemoglobin tetramers are methylated under the conditions tested. Acid hydrolysis of [³H-methyl]-labeled hemoglobin and determination of phenylisothiocynate derivatives yields N-methyl lysine, which accounts for about one-half of the incorporated [³H-methyl] radioactivity. Other amino acids are methylated as well, with much of the remaining radioactivity being distributed among one or more of the side chains of histidine, cysteine, and arginine. Methyl group transfer to hemoglobin from AdoMet is slow and inefficient (k _cat/K _m5×10^–2), but the reaction velocity tends toward a plateau with increasing AdoMet concentration in a manner suggesting that saturable binding of AdoMet onto hemoglobin is involved in methyl transfer. The velocity of hemoglobin methylation is inhibited by S-adenosylhomocysteine, the known end-product inhibitor of methyltransferases, a further indication that methyl group transfer involves binding and catalysis by a specific site (or sites) in the hemoglobin molecule. These observations may help to explain the known existence of methylated hemoglobins in erythrocyte.     

Effects of nitrite exposure on blood respiratory properties,acid-base and electrolyte regulation in the carp (Cyprinus carpio)

Summary Adult carp were subjected to 1 mM environmental nitrite for 48 h and nitrite uptake and changes in blood respiratory properties, extracellular electrolyte composition and acid-base status were examined.A constant influx of nitrite caused an accumulation of NO ₂ ^– in plasma to 5.4 mM in 48 h. The fraction of methaemoglobin rose with plasma [NO ₂ ^– ] to 83%, and the arterial oxygen content decreased to extremely low values. Arterial increased as a compensation to this O₂-shortage, whereas the O₂ saturation of the functional (unoxidized) haemoglobin decreased, revealing a reduction in its O₂ affinity.Blood haematocrit decreased as a result of red cell shrinkage, which caused very high red cell haemoglobin (Hb) concentrations. The erythrocytic nucleoside triphosphate (NTP) concentration showed a parallel increase whereby NTP/Hb, as well as the relative contributions of ATP and GTP to NTP, remained unchanged.Plasma [Cl^–] declined by 15 mM in 48 h, off-setting the plasma [NO ₂ ^– ] increase, minor changes in plasma [HCO ₃ ^– ] and a considerable increase in plasma [lactate]. Arterial pH and [HCO ₃ ^– ] rose slightly during the first 24 h of nitrite exposure, but returned to control values at 48 h. The rise in plasma [lactate] was not reflected in an extracellular metabolic acidosis. Plasma [K⁺] increased by 94% in 48 h, revealing an uncompensated extracellular hyperkalemia, whereas plasma [Na⁺] decreased, and plasma [Ca⁺⁺] was unchanged. Plasma osmolality remained essentially constant.The NO ₂ ^– accumulation could be reversed by transfer of the fish to NO ₂ ^– -free water, but nitrite off-loading was slower than the preceding NO ₂ ^– loading.Abbreviations Hb hemoglobin - NTP nucleoside triphosphate - Hct hematocrit - fractional saturation of Hb with oxygen     

In vitro effect of nicotine and cotinine on the susceptibility of LDL oxidation and hemoglobin glycosylation

Nicotine, a major component of cigarette smoke, plays an important role in the development of cardiovascular disease and lung cancer in smokers. This study was designed to determine the in vitro effects of nicotine and its metabolite cotinine on the susceptibility of LDL to oxidation and hemoglobin glycosylation. Three different concentrations of each one (10, 15, 25 g/ml) were used. Our data show that nicotine and cotinine are inhibitors for Cu²⁺-induced LDL oxidation but also they increase the glycosylation degree of hemoglobin. Nicotine at final concentrations of (10, 15, 25 g/ml) increases the rate of hemoglobin glycosylation 25, 32 and 47%, respectively, and cotinine at final concentrations increase the rate of glycosylation 8, 10 and 12%, respectively. Therefore promoting hemoglobin glycosylation is one of the alternations caused by smoking that increase risk of cardiovascular disease.     

Differential response of Daphnia genotypes to oxygen stress: respiration rates,hemoglobin content and low-oxygen tolerance

Summary Laboratory respiration rate experiments using three electrophoretically identified clones of the fresh water, planktonic cladoceran, Daphnia pulex, from an eutrophic farm pond, indicated that clones acclimated to both low and high oxygen levels, regulated oxygen consumption across a wide range of oxygen concentrations (1.0–9.0 mg· liter^-1). A threshold oxygen level of 0.5–1.0 mg·liter^-1 was reached, where animals succumbed to oxygen stress, regardless of hemoglobin content. No significant clonal differences in respiration rates were found. These data suggest that members of this Daphnia population are able to regulate oxygen metabolism across a wide range of ambient oxygen concentrations, and indicate a well-adapted respiratory system.Low-oxygen tolerance experiments and hemoglobin measurements indicated further that physiological differences indeed exist between clones; one clone produced the lowest amount of hemoglobin and was least tolerant of low oxygen levels. These data imply that spatial and temporal changes in dissolved oxygen concentration may be an important selective force influencing the clonal (genotypic) composition of natural cladoceran populations.     

Relative contribution of AtHAK5 and AtAKT1 to K+ uptake in the high‐affinity range of concentrations

The relative contribution of the high‐affinity K⁺ transporter AtHAK5 and the inward rectifier K⁺ channel AtAKT1 to K⁺ uptake in the high‐affinity range of concentrations was studied in Arabidopsis thaliana ecotype Columbia (Col‐0). The results obtained with wild‐type lines, with T‐DNA insertion in both genes and specific uptake inhibitors, show that AtHAK5 and AtAKT1 mediate the ‐sensitive and the Ba²⁺‐sensitive components of uptake, respectively, and that they are the two major contributors to uptake in the high‐affinity range of Rb⁺ concentrations. Using Rb⁺ as a K⁺ analogue, it was shown that AtHAK5 mediates absorption at lower Rb⁺ concentrations than AtAKT1 and depletes external Rb⁺ to values around 1 μM. Factors such as the presence of K⁺ or during plant growth determine the relative contribution of each system. The presence of in the growth solution inhibits the induction of AtHAK5 by K⁺ starvation. In K⁺‐starved plants grown without , both systems are operative, but when is present in the growth solution, AtAKT1 is probably the only system mediating Rb⁺ absorption, and the capacity of the roots to deplete Rb⁺ is reduced.     

Oxygen transfer properties and dimensions of red blood cells in high-altitude camelids,dromedary camel and goat

Summary To estimate the advantage of the small red blood cells (RBC) of high-altitude camelids for O₂ transfer, the kinetics of O₂ uptake into and release from the RBC obtained from llama, vicuña and alpaca were investigated at 37°C with a stopped-flow technique. O₂ transfer conductance of RBC (G) was estimated from the rate of O₂ saturation change and the corresponding O₂ pressure difference between medium and hemoglobin. For comparison, O₂ kinetics for the RBC of a lowaltitude camelid (dromedary camel) and the pygmy goat were determined and previously measured values for human RBC were used. O₂ transfer of RBC was found to be strongly influenced by extracellular diffusion, except with O₂ release into dithionite solutions of sufficiently high concentration (>30 mM). TheG values measured in these standard conditions,G _st (in mmol · min^–1 · Torr^–1 · (ml RBC)^–1) were: high-altitude camelids, 0.58 (averaged for llama, alpaca and vicuña since there were no significant interspecific differences); camel 0.42; goat, 0.42; man, 0.39. The differences can in part be attributed to expected effects of the size and shape of the RBC (volume, surface area, mean thickness), as well as to the intracellular O₂ diffusivity which depends on the concentration of cellular hemoglobin. The highG _st of RBC of highaltitude camelids may be considered to enhance O₂ transfer in lungs and tissues. But the O₂ transfer conductance of blood, , equal toG _st multiplied by hematocrit (in mmol · min^–1 · Torr^–1 · (ml blood)^–1), was only slightly higher as compared to other species: 0.20 (llama, alpaca, vicuña), 0.14 (camel), 0.18 (goat), 0.17 (man).Abbreviations DPG 2,3-diphosphoglycerate - G conductance - Hb hemoglobin - RBC red blood cells - percent saturation of hemoglobin     

Molecularly imprinted hollow sphere array for the sensing of proteins

Mono‐dispersed molecularly imprinted hollow spheres (MIHSs) for hemoglobin (Hb) were prepared by employing silica nanospheres as the sacrificial templates. The obtained hollow spheres with uniform particle size of 360 nm in diameter were characterized by transmission electron microscopy. The outstanding affinities of these MIHSs to the target protein were confirmed by adsorption experiment in aqueous solution. Adsorption equilibrium was achieved within 10 min while the binding capacity (Q_max) of Hb was 8.84 µmol g^–1 at pH7.0. Furthermore, the MIHSs were successfully assembled into a closely‐packed 3D colloidal array. The molecularly imprinted hollow sphere array (MIHSA) can selectively recognize Hb. As the concentration of Hb increased, the structure color of the MIHSA changed from blue to green, and turn to white finally with maximum red shift for 43 nm. The MIHSA showed promising potential for the naked‐eye detection of target Hb.

Reflection spectra of the MIHSA in response to different Hb concentrations (0.075–15 µmol L^–1)     

Effect of Hypoxia on Physiological-Biochemical Blood Parameters in Some Marine Fish

Changes of hematocrit, hemoglobin, and blood plasma glucose and Na⁺ and K⁺ content in response to hypoxia were studied in three Black Sea fish species. It was shown that in response to hypoxia in low-mobile rock perch Scorpaena porcus L., hematocrit and the blood plasma glucose level increased, while the content of K⁺ in erythrocytes decreased and the content of Na⁺ increased. In moderately mobile sea carp Diplodus annularis L. autogenic hypoxia caused a rise of hematocrit and blood plasma glucose. In actively swimming jack mackerel Trachurus mediterraneus ponticus Aleev, only considerable increase of Na⁺ content was revealed in hypoxia. The obtained results indicate that fish with different mobility under hypoxic conditions use different adaptation mechanisms. The value and direction of changes of the chosen parameters can be used to determine resistance of fish to oxygen deficit.     

Does body size affect the response to exercise in shortnose sturgeon (Acipenser brevirostrum)?

The effect of body size on various hematological variables was examined in juvenile shortnose sturgeon (Acipenser brevirostrum) ranging in mass from 38 to 730 g. The blood was examined for differences in plasma ionic composition (Na⁺, K⁺, Cl^?), blood oxygen carrying capacities (hemoglobin, hematocrit), and plasma metabolite concentrations (lactate, glucose), before and following a standard 5‐min chasing stress. All measured resting hematological variables were size independent in shortnose sturgeon. After exercise, levels of plasma lactate, potassium, and hemoglobin increased in all fish. Only post‐exercise levels of chloride and hemoglobin changed in a size‐dependent manner; however, the relationships were weak. The general lack of a relationship between body size and hematological variables might reflect the narrow range of fish sizes used in the present study. From a practical perspective, the results suggest that when examining the hematological stress response in juvenile shortnose sturgeon, a range of fish sizes could be used. This is important considering the variability in the growth rates of juvenile shortnose sturgeon under laboratory conditions.     

Reduction in DHA transport to the brain of mice expressing human APOE4 compared to APOE2

Benefits on cognition from docosahexaenoic acid (DHA, 22 : 6 n‐3) intake are absent in humans carrying apolipoprotein E ε4 allele (APOE4), the most important genetic risk factor for Alzheimer's disease (AD). To test the hypothesis that carrying APOE4 impairs DHA distribution, we evaluated plasma and brain fatty acid profiles and uptake of [¹⁴C]‐DHA using in situ cerebral perfusion through the blood–brain barrier in 4‐ and 13‐month‐old male and female APOE‐targeted replacement mice (APOE2, APOE3, and APOE4), fed with a DHA‐depleted diet. Cortical and plasma DHA were 9% lower and 34% higher in APOE4 compared to APOE2 mice, respectively. Brain uptake of [¹⁴C]‐DHA was 24% lower in APOE4 versus APOE2 mice. A significant relationship was established between DHA and apoE concentrations in the cortex of mice (r² = 0.21) and AD patients (r² = 0.32). Altogether, our results suggest that lower brain uptake of DHA in APOE4 than in APOE2 mice may limit the accumulation of DHA in cerebral tissues. These data provide a mechanistic explanation for the lack of benefit of DHA in APOE4 carriers on cognitive function and the risk of AD.

     

Effects of rapid transfer from sea water to fresh water on respiratory variables,blood acid-base status and O2 affinity of haemoglobin in Atlantic salmon (Salmo salar L.)

Summary Oxygen consumption, gill ventilation, blood acid-base/ionic status and haemoglobin oxygen affinity were studied in seawater-adapted adult salmon (Salmo salar) during five weeks after transfer into fresh water. Freshwater exposure induced the following changes: Standard oxygen consumption ( ) and ventilatory flow ( ) decreased markedly during the first days after transfer, then decreased more gradually until a new steady-state was achieved at which and were about 80% and 56% of the control values, respectively. The marked increase in oxygen extraction coefficient (Ew _{O 2}) and the marked decrease in the oxygen convection requirement ( ) were associated with a reduction in the partial pressure of carbon dioxide in arterial blood (Pa _{CO 2}), in spite of a decrease of both ventilatory flow and water CO₂ capacitance. These results suggested that transfer into fresh water induced an increase in branchial diffusive conductance. A biphasic pattern was observed in the time-course of the changes in both plasma ion concentration and acid-base status. During the first 10 days, plasma Na⁺, K⁺, and Cl^– concentrations fell abruptly, then more gradually. [Cl^–] decreased more than [Na⁺] resulting in a progressive increase in the [Na⁺]/[Cl^–] ratio. During the second phase of acclimation to fresh water plasma Na⁺, K⁺, and Cl^– concentrations progressively increased. [Cl^–] increased more than [Na⁺], so that [Na⁺]/[Cl^–] ratio decreased. Transfer into fresh water did not significantly change plasma lactate concentration. Upon exposure to fresh water, blood pH increased from 7.94±0.04 to 8.43±0.06 at day 10 and then decreased to 8.08±0.03 at day 34. The increase in blood pH induced by transfer to fresh water initially represented a mixed metabolic/respiratory alkalosis. However, after 15 days Pa _{CO 2} had returned to pretransfer values and the alkalosis was purely metabolic. The metabolic component of the alkalosis was associated with appropriate changes in the plasma strong ion difference (S.I.D.). Blood alkalosis moved the oxygen dissociation curve to the left, so that P₅₀ was decreased by 30% below the value in seawater for the maximal increase in blood pH. This rise in haemoglobin affinity for O₂, associated with a marked increase in blood buffer capacity, are regarded as adaptative processes allowing the salmon to cope with the markedly increased energy expenditure required for upstream migration.     

Effects of freshwater to seawater transfer on osmoregulation,acid-base balance and respiration in river migrating whitefish (Coregonus lavaretus)

Osmoregulation, acid-base balance and respiratory parameters were investigated in whitefish following transfer from freshwater to salt water. Whitefish acclimated successfully to 25 ppt brackish water but died after direct transfer to 32 ppt sea water. Transfer to brackish water induced rapid (<6 h) and permanent increases in plasma [Na⁺], [Cl^–], total [Ca] and [Mg]. The extracellular hyperosmolality effected a transient (<3 days) muscle tissue dehydration and red blood cell shrinkage. Exposure to brackish water decreased both the arterial O₂ tension and whole body O₂ uptake. The extracellular acid-base status changed from an initial respiratory acidosis at 1 h towards a pronounced metabolic acidosis at 48 h of brackish water exposure. Red cell pH_i decreased in parallel with extracellular pH_e, but the in vivo pH_i/pH_e was only 0.26, suggesting some selective protection of red cell pH_i. Plasma cortisol concentration and gill Na⁺, K⁺-ATPase activity increased after exposure to high ambient salinity, reflecting the induction of hypo-osmoregulatory mechanisms. The physiological changes in whitefish are discussed in relation to salinity-induced effects in other salmonid fishes.Abbreviations CO₂ solubility in plasma - water O₂ capacitance coefficient - BW brackish water - C _T total CO₂ content in plasma - FW fresh water - Hb hemoglobin - Hct hematocrit - M _b body mass of fish - MCHC mean cellular hemoglobin concentration - PCO₂ carbon dioxide tension - pH _e extracellular pH - pH _i intracellular pH - PO_{2 in} oxygen tension in water flowing in - PO_{2 out} oxygen tension in water flowing out - ppt parts per thousand - RBC red blood cell(s) - SW sea water - V _m water flows through chamber - OV ₂ ml O₂ consumed per kg per hour     

Interaction of allosteric effectors (ATP,CO2, H+) modulating oxygen affinity of the hemoglobin in the carp,Cyprinus carpio,in vitro

Summary The interaction of allosteric effectors (CO₂, ATP, H⁺) with respect to the oxygen affinity of carp hemoglobin was analyzed by determining oxygen binding curves spectrophotometrically in dilute solutions of stripped hemoglobin at 20°C. The pH range studied was 6.8–8.2.P _CO2 was 0, 10 and 70 mmHg (0, 1.33 and 9.3 kPa). ATP/Hb₄ was 0, 8 and 24. In the presence of either CO₂ or ATP, the effects of the cofactors onP ₅₀ were as expected over the whole pH range. In contrast to other published data, each cofactor also had a significant effect onP ₅₀ in the presence of the other cofactor. Evidence was obtained that oxylabile carbamate is formed by carp hemoglobin and that the formation of carbamate persists at a lower level in the presence of ATP. The results support the view that the binding of ATP to carp hemoglobin requires only one terminal amino group, leaving the other N-terminal of the -chain free to react with CO₂.     

Ca<Superscript>2+</Superscript> Dependence and Inhibitory Effects of Trifluoperazine on Plasma Membrane ATPase of <Emphasis Type="Italic">Thermoactinomyces vulgaris</Emphasis>

Ca²⁺ enhanced the plasma membrane Ca²⁺-ATPase (PMCA) specific activities in wild-type strain 1227 and mutant strains 1278, 1286, and 1261 of Thermoactinomyces vulgaris. The Ca²⁺-ATPase specific activities showed marked increase with increasing concentrations of Ca²⁺ added in the form of CaCl₂ in the culture medium and reached the optimum values at 0.6 mM in strains 1227, 1278, and 1286 and at 0.7 mM in strain 1261 of T. vulgaris. Trifluoperazine, a specific blocker of calmodulin, when added in vivo at concentrations of 2 M and 8 M along with the respective optimal concentrations of Ca²⁺, decreased the PMCA-specific activities to a low level in a dose-dependent manner. The results of the present investigation suggest the presence of a Ca²⁺-dependent protein activator (CaDPA) in the microenvironment constituting this enzyme; and such Ca²⁺-modulated protein has been assigned to play an important role in the enhancement of PMCA levels in this aerobic, spore-forming, thermophilic actinomycete.     

Simultaneous photoreduction and Raman spectroscopy of red blood cells to investigate the effects of organophosphate exposure

Simultaneous photoreduction and Raman spectroscopy with 532 nm laser has been used to study the effects of organophosphate (chlorpyrifos [CPF]) exposure on human red blood cells (RBCs). Since in RBCs, auto‐oxidation causes oxidative stress, which, in turn, is balanced by the cellular detoxicants, any possible negative effect of CPF on this balance should results in an increased level of damaged (permanently oxygenated) hemoglobin. Therefore, when 532 nm laser, at a suitable power, was applied to photoreduce the cells, only common oxygenated form of hemoglobin got photoreduced leaving the permanently oxygenated hemoglobin detectable in the Raman spectra simultaneously excited by the same laser. Using the technique effects of CPF to build up oxidative stress on RBCs could be detected at concentrations as low as 10 ppb from a comparison of relative strengths of different Raman bands. Experiments performed using simultaneously exposing the cells, along with CPF, to H₂O₂ (oxidative agent) and/or 3‐Aminotriazole (inhibitor of anti‐oxidant catalase), suggested role of CPF to suppress the cellular anti‐oxidant mechanism. Since the high level of damaged hemoglobin produced by the action of CPF (at concentrations >100 ppm) is expected to cause membrane damage, atomic force microscopy (AFM) was used to identify such damages.Upper panel: Raman spectra of normal, photoreduced CPF exposed and unexposed RBCs. Lower panel: The weak Fe‐O₂ Raman band for CPF exposed cells shown on the left. The AFM images of unexposed and exposed cells are shown on the right. Scale bar, 2.5 μm.