Hemoglobin-oxygen-affinity and acid-base properties of blood from the fossorial mole-rat, Cryptomys hottentotus pretoriae.

Oxygen affinity and other hematological parameters in strictly subterranean mole-rats, Cryptomys hottentotus (subspecies pretoriae) were measured immediately upon capture and after 14-21 days in captivity. The pH, hematocrit, hemoglobin (Hb) concentration, blood oxygen content, 2,3 bisphosphoglycerate (2,3 BPG) concentration and oxygen dissociation curves (ODC), as well as tonometric measurements, were determined using whole blood. Additionally ODCs were also determined for stripped hemolysates of individual animals. Compared to other mammals, blood of freshly caught animals had low pH (7.32+/-0.22), elevated hematocrits (48.4+/-3.8 %) and significantly lower P50 values for whole blood (21.1+/-1.6 mm Hg at pH 7.4) than those reported for other similar-sized fossorial and terrestrial mammals. Blood carbon dioxide content (22.4+/-3.9 mMol L(-1)), hemoglobin concentration (1.9+/-0.15 mMol L(-1)), oxygen content (164.8+/-26 mL L(-1)), bicarbonate concentrations (22.5+/-3.5 mMol L(-1)) were within the range of values reported for similar-sized mammals. We conclude that high blood-oxygen affinity, low body temperature and possibly also high hematocrit enable C. h. pretoriae to maintain an adequate oxygen supply to the tissues in a potentially hypoxic burrow atmospheres, but that the blood of this species shows no exceptional CO2 sensitivity or buffering capacity.

The effect of lead on the metabolic and energetic status of the Yabby, Cherax destructor, during environmental hypoxia.

The concomitant effects of Pb and hypoxia on respiration and muscle energy status were examined in the freshwater crayfish Cherax destructor to determine if Pb intoxication exacerbated the effects of hypoxia. C. destructor, either intoxicated for 14 days with 0.5 mgL(-1)Pb, or from Pb-free control conditions, were subjected to progressive hypoxia at -2.7 kPah(-1) to a O2 partial pressure in the water (PwO2) of 1.33 kPa. This hypoxia was then sustained for 3 h. Pb-exposure reduced O2-uptake (MO2) at all PwO2 above 1.33 kPa but without any saving in ventilation, implying that Pb either unlinked ventilation from actual O2 requirements or rendered O2 transfer across the gill less efficient. Hypoxia alone induced no change in the adenylate energy charge (AEC), total adenylate (TAN), ATP/ADP ratio or in the equilibrium constant for adenylate kinase K'(ADEN), apparently due to protection of ATP levels by arginine phosphate. Under maximal hypoxia (PwO2=1.33 kPa) the Pb-exposed crayfish increased muscle ADP by 73% (tail) and 158% (chelae) but without any change in AMP, ATP or TAN. Thus, AEC declined (chelae AEC=0.71; tail AEC=0.85), as did the ATP/ADP ratio and K'(ADEN). L-Lactate increased in the muscle tissues of control but not Pb-exposed crayfish, consistent with a lowered O2 requirement in the Pb-exposed animals. The Pb intoxication slowed respiration and probably glycolysis, possibly altering the [ATP]:[ADP] equilibrium concentrations for adenylate kinase K'(AK). Lowered MO2 during severe hypoxia slows oxidative phosphorylation and ADP accumulation could occur as non-utilised substrate and may reflect a transient disequilibrium. During this time ATP levels were protected by arginine phosphate. AEC is sensitive to Pb in hypoxic crayfish but the changes have low importance for the energetic competence of the crayfish. During sustained hypoxia the crayfish recovered their energy status regardless of the Pb-exposure and this was, therefore, not a feature of Pb intoxication. Consequently, the ADP was recovered into the ATP pool of the hypoxic crayfish, and demand on arginine phosphate relieved. The Pb exposure did not otherwise exacerbate the effect of sustained hypoxia and C. destructor appeared to cope well with Pb intoxication, apparently by a specific Pb-induced hypometabolism separate from hypoxic response. Lowered metabolism as a survival response has limitations in the longer term and the implications for crustaceans generally warrant further study.

The respiratory properties of Biomphalaria glabrata exposed to Schistosoma mansoni infection, starvation, CO, and choices of different oxygen concentrations.

The oxygen consumption rate (VO(2)) of Biomphalaria glabrata populations, using polarometric and manometric methods, when plotted against dried body mass as logarithmic co-ordinates, respectively, fell on a regression line with a slope between 0.933 and 1.02. The slope of the regression line for non-infected Schistosoma mansoni populations was found to be 1.04 with no differences in the VO(2) between infected and non-infected snails. The VO(2) of CO-treated snails was the same as for the control snails. The VO(2) of starved snails declined after 3 days and was half the original value after 10 days starvation at 27 degrees C. The P(50) value for snail haemolymph containing haemoglobin suspended in a Tris-HCl buffer was 5.57(+/-0.73)mmHg at a pH of 7.51 and 25 degrees C. For Sephadex-75 cleaned haemolymph the P(50) value was 1.72(+/-0.07)mmHg at 25 degrees C and pH 7.51. Snails exposed to oxygen fs and to choices of different oxygen concentrations in water did not exclusively prefer high (130mmHg), low (15mmHg), or normal (80mmHg) oxygen tensions. The oxygen consumption rate of 782 cercariae at 27 degrees C was measured as 0.0092 microl O(2)/h per single cercaria. The results, when compared with the data in the literature [Z. Vergl. Physiol. 46 (1963) 467;; S. A. J. Zool. 14 (1979) 202], indicate that the mantle cavity gas bubble plays an insignificant or no role at all when pulmonate snails are kept in water with high partial pressures of oxygen and at low temperatures.

Sublethal effects of copper on the freshwater crab Potamonautes warreni.

The mass specific rates of oxygen consumption (M (O(2)) M(b)(-1)), ammonia excretion (M (NH(4)-N) M(b)(-1)) and carbon dioxide production (M (CO(2)) M(b)(-1)) were measured after 7, 14 and 21 days exposure of adult Potamonautes warreni to a sublethal concentration of 1.0 mg Cu l(-1) (15.75 micromol l(-1)). Under control (non-copper-exposed) conditions M (O(2)) M(b)(-1) was 35.7+/-8.5 micromol kg(-1)min(-1) (mean+/-S.D.), M (NH(4)-N) M(b)(-1) 2.92+/-0.26 micromol kg(-1)min(-1) and M (CO(2)) M(b)(-1) 25.6+/-9.0 micromol kg(-1)min(-1). The oxygen:nitrogen (O:N) ratio and respiratory quotient (RQ) were 24.5+/-3.0 and 0.80+/-0.06, respectively. M (O(2)) M(b)(-1) of copper-exposed crabs showed a significant increase after 7 and 14 days, but decreased significantly by 40% after 21 days. From the increased O:N ratio and RQ below 0.7, it is clear that crabs exposed to 1 mg Cul(-1) metabolize lipids during the entire 21-day exposure period. Free fatty acids in the midgut gland were determined by GC-MS, and showed increases of up to 600% in some C14 to C18 fatty acids. It is proposed that the excess lipids inhibit the pyruvate dehydrogenase complex, leading to the acceleration of the gluco- and glyco-neogenic pathways. Increased glyconeogenesis results in elevated glycogen concentrations in all tissues after 21 days. Experiments on acutely exposed P. warreni show increased incorporation of 14C-labelled lactate into glycogen.

Ecophysiological adaptations to dry thermal environments measured in two unrestrained Namibian scorpions, Parabuthus villosus (Buthidae) and Opisthophthalmus flavescens (Scorpionidae).

The daily changes in body temperature experienced by Parabuthus villosus (Buthidae), a scorpion found on the gravel plains around Gobabeb, Namibia, and by Opisthophthalmus flavescens (Scorpionidae), a dune-dwelling species from the same area, were measured under similar field conditions. Thermocouples implanted under the segments of the mesosoma measured maximum temperatures as high as 43 degrees C in the shade. Air temperatures reached a maximum of 33 degrees C during the daytime and a minimum of 12 degrees C at night. Very low metabolic rates compared with those of other nonsedentary invertebrates were recorded in both species; oxygen consumption ranged from 8 microL g-1 h-1 at 16 degrees C to 115 microL g-1 h-1 at 40 degrees C. A pulsed Doppler system was used to measure heart rate in situ in free-moving scorpions. At night, heart rate declined to about 4 beats min-1 in resting undisturbed scorpions. During daylight excursions and while scorpions hunted for food, heart rates as high as 180 beats min-1 were observed. Heart rate was linearly correlated with temperature in P. villosus, with a slope of 2.37 (Q10 = 2.18), but in O. flavescens only a limited correlation was observed, with a slope of 1.18 (Q10 = 1.69). In O. flavescens, heart rate showed hysteresis as body temperature rose during daylight and then decreased during the late afternoon and evening; the reverse was observed in P. villosus. In both species, haemocyanin-oxygen affinity was independent of temperature, with a higher oxygen affinity and a larger pH sensitivity in O. flavescens. The Q10's of oxygen consumption and heart rate are quite different in O. flavescens but not as different in P. villosus. Although changes in the cardiovascular system, such as stroke volume, may also play a role in meeting increased oxygen demand, the features of the haemocyanin oxygen transport system, such as the absence of temperature sensitivity and a marked pH sensitivity, can also influence the maintenance of VO2 under temperature stress. The differences in the normal thermal habitats of the two species may be used to explain the distinctions between the evolved physiological responses to temperature increase shown by the two species.

Blood respiratory properties of the mudsucker fish Labeo capensis (Smith).

For Labeo capensis (Smith) the increase in blood organic phosphates (ATP, GTP) in winter fish exceeds the increase in summer fish. Blood chlorides, blood osmotic pressure, hematocrit and hemoglobin concentration decrease significantly in winter fish when compared to summer fish. Four effectors, viz. temperature, organic phosphates, H+ and Cl-, could lower the oxygen affinity of whole blood, especially in summer fish.

An electrolytic method for determining oxygen dissociation curves using small blood samples: the effect of temperature on trout and human blood.

1. A detailed account is given of an electrolytic method for determining the oxygen dissociation curve of fish blood using a single sample of 50-100 mul for the whole curve. The accuracy and some of the problems arising from its uses are discussed. 2. Oxygen dissociation curves have been determined for trout blood and human blood at temperatures of 15 and 37 degrees C. The relationship between P50 and temperature is similar to that obtained using other methods. Absolute values of P50 are generally lower than those obtained by other methods, especially in the case of fish blood. 3. The effect of PCO2 and pH on the oxygen dissociation curve of trout blood is tested and it is shown that PCO2 has a more marked effect than pH when the other factor is maintained at a constant level. The Bohr factor (delta log P50/delta pH) appears to be approximately the same and independent of the PCO2. 4. The P50 of ray blood determined from fish during and after an operation showed an increased Bohr factor.