Functional properties of hemoglobins from deep-sea fish: correlations with depth distribution and presence of a swimbladder.

The ligand binding properties of the hemoglobins of several deep-sea, bottom-living fish have been examined. These include five species of rattails (Macrouridae) and Antimora rostrata, all of which possess swimbladders, and two unrelated species without swimbladders, Bathysaurus mollis and Alepocephalus sp. All of the hemolysates of these fish exhibited the Root effect with a minimum ligand affinity at about pH 6 in the presence of organic phosphate. Under these conditions the hemolysates from fish which possess swimbladders exhibit two roughly equal populations of heme groups with markedly different ligand affinities. For the deeper-dwelling species the affinities for carbon monoxide differ by some 500-fold, the low-affinity population having a p50(CO) of 100 mmHg at 15 degrees C. This very low affinity is associated with a second-order rate constant for CO combination of the order of 10(3) M-1 X s-1. Those species without swimbladders have hemoglobins which do not have such heterogeneous binding sites, suggesting a relationship between these very-low-affinity heme groups and the pumping of oxygen into a swimbladder at high hydrostatic pressures.

Blood viscosity in arctic fishes.

The blood viscosity of arctic char, Salvelinus alpinus, and shorthorn sculpin, Myoxocephalus scorpius, from the arctic (74 degrees 42'N) was measured with a cone-plate viscometer. Blood viscosity of the two arctic species was considerably lower, less shear rate dependent, and less temperature dependent than the blood of winter flounder (Pseudopleuronectes americanus) from more temperate waters. The rheological properties of the arctic fish blood would minimize blood flow resistance and thus be advantageous at the low temperatures (0 degree C) characterizing their environment.

Hematology of three deep-sea fishes: a reflection of low metabolic rates.

Blood was collected from three species of fish, Antimora rostrata (Moridae), Lycodes esmarkii (Zoarcidae), Macrurus berglax (Macrouridae), caught at depths ranging from 280 to 2300 m. Hemoglobin concentrations were low in all three species, ranging from 4.4 to 5.4 g/100 ml. Mean erythrocyte volumes were relatively large, and ranged from 277 micron3 in M. berglax to 672 micron3 in A. rostrata. Blood oxygen dissociation curves were hyperbolic, with relatively low Hill constants (0.95-1.26). Mean P50 values ranged from 10 mmHg in M. berglax to 28 mmHg in L. esmarkii. It is concluded that the hematology and oxygen-binding characteristics of the blood of these three deep-sea fish reflects adaptations to low metabolic rates and low general activity habits.

Ceratoscopelus maderensis: peculiar sound-scattering layer identified with this myctophid fish.

A sound-scattering layer, composed of discrete hyperbolic echosequences and apparently restricted to the Slope Water region of the western North Atlantic, has been identified from the Deep Submergence Research Vehicle Alvin with schools of the meyctophid fish Ceratoscopelus maderensis. By diving into the layer and using Alvin's echo-ranging sonar, we approached and visually identified the sound scatterers. The number of echo sequences observed with the surface echo-soutnder (1/23.76 x 10(5) cubic meters of water) checked roughly with the number of sonar targets observed from the submarine (1/7.45 x 105 cubic meters). The fish schools appeared to be 5 to 10 meters thick, 10 to 100 meters in diameter, and on centers 100 to 200 meters apart. Density within schools was estimated at 10 to 15 fish per cubic meter.