Your search keyword '"Daniels CB"' showing total 4 results

1. Purifying selection drives the evolution of surfactant protein C (SP-C) independently of body temperature regulation in mammals.

Author

Potter S, Orgeig S, Donnellan S, and Daniels CB

Abstract

The pulmonary surfactant system of heterothermic mammals must be capable of dealing with the effect of low body temperatures on the physical state of the lipid components. We have shown previously that there is a modest increase in surfactant cholesterol during periods of torpor, however these changes do not fully explain the capacity of surfactant to function under the wide range of physical conditions imposed by torpor. Here we examine indirectly the role of surfactant protein C (SP-C) in adapting to variable body temperatures by testing for the presence of positive (adaptive) selection during evolutionary transitions between heterothermy and homeothermy. We sequenced SP-C from genomic DNA of 32 mammalian species from groups of closely related heterothermic and homeothermic species (contrasts). We used phylogenetic analysis by maximum likelihood estimates of rates of non-synonymous to synonymous substitutions and fully Bayesian inference of these sequences to determine whether the mode of body temperature regulation exerts a selection pressure driving the molecular adaptation of SP-C. The protein sequence of SP-C is highly conserved with synonymous or highly conservative amino acid substitutions being predominant. The evolution of SP-C among mammals is characterised by high codon usage bias and high rates of transition/transversion. The only contrast to show evidence of positive selection was that of the bears (Ursus americanus and U. maritimus). The significance of this result is unclear. We show that SP-C is under strong evolutionary constraints, driven by purifying selection, presumably to maintain protein function despite variation in the mode of body temperature regulation.

Published

2007

2. Control of pulmonary surfactant secretion in adult California sea lions.

Author

Miller NJ, Daniels CB, Costa DP, and Orgeig S

Subjects

Animals, Cell Survival, Cells, Cultured, Diving, Lung pathology, Pressure, Pulmonary Alveoli metabolism, Respiration, Sea Lions, Sheep, Time Factors, Pulmonary Surfactants metabolism

Abstract

Marine mammals have a spectacular suite of respiratory adaptations to deal with the extreme pressures associated with deep diving. In particular, maintaining a functional pulmonary surfactant system at depth is critical for marine mammals to ensure that inspiration is possible upon re-emergence. Pulmonary surfactant is secreted from alveolar type II (ATII) cells and is crucial for normal lung function. It is not known whether ATII cells have the ability to continue to secrete pulmonary surfactant under pressure, or how secretion is maintained and controlled. We show here that surfactant secretion in California sea lions (Zalophus californianus) was increased after high pressures (25 and 50 atm) of short duration (30 min), but was unaffected by high pressures of long duration (2 h). This is in contrast to a similar sized terrestrial mammal (sheep), where surfactant secretion was increased after high pressures of both long and short duration. Z. californianus and terrestrial mammals also show similar responses to stimulatory hormones and autonomic neurotransmitters. It therefore seems that an increase in the quantity of surfactant in seal lungs after diving is most likely caused by mechanostimulation induced by pressure and volume changes, and that seals are adapted to maintain constant levels of surfactant under long periods of high pressure.

Published

2004

3. The effect of temperature on adrenergic receptors of alveolar type II cells of a heterothermic marsupial.

Author

Ormond CJ, Orgeig S, and Daniels CB

Subjects

Animals, Body Temperature, Cyclic AMP metabolism, Dose-Response Relationship, Drug, Hibernation, Isoproterenol pharmacology, Kinetics, Male, Marsupialia, Protein Binding, Radioligand Assay, Receptors, Adrenergic biosynthesis, Surface-Active Agents pharmacology, Temperature, Time Factors, Up-Regulation, Pulmonary Alveoli metabolism, Receptors, Adrenergic metabolism

Abstract

Fat-tailed dunnarts, Sminthopsis crassicaudata, survive dramatic changes in body temperature during torpor without experiencing surfactant dysfunction. Adrenergic factors regulate surfactant secretion through beta(2)-adrenergic receptors on alveolar type II cells. Temperature has no effect on the secretory response of dunnart type II cells to adrenergic stimulation. We hypothesise that during torpor, dunnart type II cells up-regulate the number of adrenergic receptors present on type II cells to enable stimulation at lower concentrations of agonist. Here, we isolated type II cells from warm-active (35 degrees C) and torpid (15 degrees C) dunnarts and examined the effects of an in vitro temperature change on the number and activity of adrenergic receptors. Torpor did not affect the beta-adrenergic receptor number. However, we observed a significant decrease in adrenergic receptor number when cells from warm-active animals were incubated at 15 degrees C and when cells from torpid animals were incubated at 37 degrees C. cAMP production was significantly higher in type II cells from torpid dunnarts than warm-active dunnarts and this may contribute, in part, to the temperature insensitivity we have previously observed in the adrenergic regulation of surfactant secretion.

Published

2003

4. Alterations in surface activity of pulmonary surfactant in Gould's wattled bat during rapid arousal from torpor.

Author

Codd JR, Orgeig S, Daniels CB, and Schürch S

Subjects

Adaptation, Physiological, Adsorption, Animals, Kinetics, Male, Periodicity, Surface Tension, Temperature, Arousal, Chiroptera physiology, Pulmonary Surfactants chemistry

Abstract

The small microchiropteran bat, Chalinolobus gouldii, undergoes large daily fluctuations in metabolic rate, body temperature, and breathing pattern. These alterations are accompanied by changes in surfactant composition, predominantly an increase in cholesterol relative to phospholipid during torpor. Furthermore, the surface activity changes, such that the surfactant functions most effectively at that temperature which matches the animal's activity state. Here, we examine the surface activity of surfactant from bats during arousal from torpor. Bats were housed at 24 degrees C on an 8:16h light:dark cycle and their surfactant was collected during arousal (28

Published

2003