Effects of prolonged lung inflation or deflation on pulmonary stretch receptor discharge in the alligator (Alligator mississippiensis).

The American alligator (Alligator mississippiensis) is a semi-aquatic diving reptile that has a periodic breathing pattern. Previous work identified pulmonary stretch receptors, that are rapidly and slowly adapting, as well as intrapulmonary chemoreceptors (IPC), sensitive to CO2, that modulate breathing patterns in alligators. The purpose of the present study was to quantify the effects of prolonged lung inflation and deflation (simulated dives) on pulmonary stretch receptors (PSR) and/or IPC discharge characteristics.

Involvement of β(3)-adrenergic receptors in in vivo cardiovascular regulation in rainbow trout (Oncorhynchus mykiss).

Currently, we have little information concerning the involvement of β(3)-adrenergic receptors (AR) in cardiovascular regulation in fishes. The goal of this study was to investigate the effect of β(3)-AR ligands on in vivo cardiovascular function in larval and adult rainbow trout (Oncorhynchus mykiss). In adult fish, injection of BRL(37344) (β(3)-AR agonist) resulted in an increase in heart rate (f(H)) (~31%) while stroke volume (Sv) was reduced (-25.

Cross Tolerance to Environmental Stressors: Effects of Hypoxic Acclimation on Cardiovascular Responses of Channel Catfish (Ictalurus punctatus) to a Thermal Challenge.

Hypoxia and temperature are two major, interactive environmental variables that affect cardiovascular function in fishes. The purpose of this study was to determine if acclimation to hypoxia increases thermal tolerance by measuring cardiovascular responses to increasing temperature in two groups of channel catfish. The hypoxic group was acclimatized to moderate hypoxia (50% air saturation, a P(O2) of approximately 75 torr) at a temperature of 22° C for seven days.

Sensory innervation of the Gills: O2-sensitive chemoreceptors and mechanoreceptors.

Physical characteristics of water (O(2) solubility and capacitance) dictate that cardiovascular and ventilatory performance be controlled primarily by the need for oxygen uptake rather than carbon dioxide excretion, making O(2) receptors more important in fish than in terrestrial vertebrates. An understanding of the anatomy and physiology of mechanoreception and O(2) chemoreception in fishes is important, because water breathing is the primitive template upon which the forces of evolution have modified into the various cardioventilatory modalities we see in extant terrestrial species. Key to these changes are the O(2)-sensitive chemoreceptors and mechanoreceptors, their mechanisms and central pathways.

Respiratory chemoreceptor function in vertebrates comparative and evolutionary aspects.

The sensing of blood gas tensions and/or pH is an evolutionarily conserved, homeostatic mechanism, observable in almost all species studied from invertebrates to man. In vertebrates, a shift from the peripheral O(2)-oriented sensing in fish, to the central CO(2)/pH sensing in most tetrapods reflects the specific behavioral requirements of these two groups whereby, in teleost fish, a highly O(2)-oriented control of breathing matches the ever-changing and low oxygen levels in water, whilst the transition to air-breathing increased the importance of acid-base regulation and O(2)-related drive, although retained, became relatively less important. The South American lungfish and tetrapods are probably sister groups, a conclusion backed up by many similar features of respiratory control.

Peripheral arterial chemoreceptors and the evolution of the carotid body.

There has been a reduction in the distribution of peripheral respiratory O(2) chemoreceptors from multiple, dispersed sites in fish and amphibia to a single dominant receptor site in birds and mammals. In the process, the cells in the fish gill associated with O(2) chemosensing (5-HT containing neuroepithelial cells often found in association with ACh/catecholamine (CA) containing cells) are replaced by the glomus cells of the mammalian carotid body (which contain multiple putative neurotransmitter substances, including 5-HT, CA and ACh, all within the same cells), although this difference may be more superficial than first appears. While still highly speculative, these trends would appear to be correlated with the transition from aquatic respiration and bimodal breathing, and from animals with intra-cardiac shunts (two situations where the ability to sense O(2) at multiple sites would be an advantage), to strictly air breathing in animals with no intra-cardiac shunts.

Isolation and characterization of putative O2 chemoreceptor cells from the gills of channel catfish (Ictalurus punctatus).

Little is known about the cells or mechanisms of O2 chemoreception in vertebrates other than mammals. The purpose of this study, therefore, was to identify O2-sensitive chemoreceptors in a fish. Putative O2-sensitive chemoreceptors were dissociated from the gills of channel catfish, Ictalurus punctatus, and cultured.

An evaluation of cobalt chloride as an O2-sensitive chemoreceptor stimulant in channel catfish.

The effects of cobalt chloride on heart rate, blood pressure, ventilatory frequency and opercular pressure amplitude in channel catfish, Ictalurus punctatus were measured to evaluate the potential of cobalt as a histochemical probe to study mechanisms of oxygen chemoreception, as well as assess the general effects of cobalt on the cardioventilatory physiology of fishes. Cobalt, like cyanide, has been previously used to stimulate oxygen chemoreceptors and hypoxic reflexes in mammals but there is little information on the cardioventilatory effects of cobalt on fish. Catfish were exposed to increasing concentrations (1-20 mg/kg) of cobalt in the water (external) or injections into the dorsal aorta (internal) and the cardioventilatory effects recorded.

Cardioventilatory effects of acclimatization to aquatic hypoxia in channel catfish.

The mechanisms responsible for altering cardioventilatory control in vertebrates in response to chronic hypoxia are not well understood but appear to be mediated through the oxygen-sensitive chemoreceptor pathway. Little is known about the effects of chronic hypoxia on cardioventilatory control in vertebrates other than mammals. The purpose of this study was to determine how cardioventilatory control and the pattern of response is altered in channel catfish (Ictalurus punctatus) by 1 week of moderate hypoxia.