Jean M.P. Joss

Maternal basking behaviour determines offspring sex in a viviparous reptile.

Two primary dichotomies within vertebrate life histories involve reproductive mode (oviparity versus viviparity) and sex determination (genotypic sex determination versus environmental sex determination). Although reptiles show multiple evolutionary transitions in both parameters, the co–occurrence of viviparity and environmental–dependent sex determination have heretofore been regarded as incompatible. Our studies on the viviparous lizard Niveoscincus ocellatus show that the extent of basking by a female influences the sex of her offspring. Critically, our data reveal this effect both in the field (via correlations between date of birth and litter sex ratio) and in a laboratory experiment (females with reduced basking opportunities produced more male offspring). Changes in thermoregulatory behaviour thus allow pregnant female lizards to modify the sex of their offspring.

Parathyroid hormone-related protein (PTHrP) in cartilaginous and bony fish tissues

Tissues from a range of fish were examined for the presence of parathyroid hormone-related protein (PTHrP) to investigate PTHrP protein distribution and PTHrP gene expression in jawless fish, cartilaginous fish, and bony fish. Immunoreactive PTHrP was localized using antisera to N-terminal and mid-molecule regions of human PTHrP and PTHrP gene expression examined using a digoxigenin labeled riboprobe to a conserved region of the mammalian PTHrP gene. In all of the fish studied, PTHrP protein and messenger RNA (mRNA) were localized to the skin, kidney, and skeletal muscle, following the pattern seen in higher vertebrates. Additional sites of localization for both protein and mRNA included gill, nerve cord, and pituitary, as well as developing dermal denticles and rectal gland in the elasmobranch species. The sites of PTHrP distribution indicate that PTHrP may have roles in ionoregulation as well as growth and differentiation in fish, as has been suggested in higher vertebrates. The results imply that the distribution of PTHrP is widespread in fish and that there is homology between the PTHrP molecules found in humans and fish. The conservation of localization and possible similarity of the PTHrP molecules between tetrapods and fish suggests that PTHrP has a number of fundamental roles in vertebrates. J. Exp. Zool. 284:541-548, 1999.

The seasonal reproductive cycle of a marsupial, Antechinus stuartii: effects of oral administration of melatonin.

Antechinus stuartii is a small marsupial with a brief, highly synchronised mating period believed to be controlled by the rate of change of photoperiod. Two experiments were performed to explore aspects of photoperiodic control of the seasonal cycle. In the first experiment the pineal hormone, melatonin, administered in the drinking water from the winter solstice, changed the normal response of A. stuartii to increasing rate of change of photoperiod. Melatonin administration shifted the induction of estrus in the females from the first week of August (controls) to an earlier time of mid-July and the consequent pouch changes associated with pregnancy and pseudo-pregnancy were also shifted by the same length of time. Post-mating decline and consequent death of males were also accelerated. In the second experiment melatonin was administered from the autumnal equinox, and this experimental protocol resulted in a desynchronisation of reproductive events. Melatonin administration desynchronised the female reproductive cycle, such that the mating period was extended to eight weeks, instead of the two weeks displayed by control females. Pouch changes and birth of young reflected this desynchronisation. Melatonin administration in males resulted in desynchronisation of reproductive parameters. While the normal yearly reproductive cycle was approximated in these males, the high syncronisation of reproductive maturation and male mortality events observed in control males, was not evident in melatonin-treated males. These results indicate that the pineal gland by way of the hormone melatonin is important in the synchronisation of the unusual life history of this marsupial mammal.