High-frequency hearing in a hummingbird.

Some hummingbirds produce unique high-frequency vocalizations. It remains unknown whether these hummingbirds can hear these sounds, which are produced at frequencies beyond the range at which most birds can hear. Here, we show behavioral and neural evidence of high-frequency hearing in a hummingbird, the Ecuadorian Hillstar (Oreotrochilus chimborazo). In the field, hummingbirds responded to playback of high-frequency song with changes in body posture and approaching behavior. We assessed neural activation by inducing ZENK expression in the brain auditory areas in response to the high-frequency song. We found higher ZENK expression in the auditory regions of hummingbirds exposed to the high-frequency song compared to controls, while no difference was observed in the hippocampus between groups. The behavioral and neural responses show that this hummingbird can hear sounds at high frequencies. This is the first evidence of the use of high-frequency vocalizations and high-frequency hearing in conspecific communication in a bird.

Elevation of plasma cortisol during the spawning migration of landlocked kokanee salmon (Oncorhynchus nerka kennerlyi).

Kokanee salmon (Oncorhynchus nerka kennerlyi ), a landlocked subspecies of sockeye salmon, exhibited hypothalamic-pituitary interrenal (HPI, adrenal homologue) axis activation and an increase in plasma cortisol concentration up to 639 +/- 55.9 ng/ml in association with upstream migration in the upper Colorado River even though they were not exposed to a change in salinity and lengthy migration. Kokanee salmon were collected at various stages of migration and concomitant sexual maturation. The pattern of cortisol elevation in kokanee is similar to that in ocean-run sockeye salmon (O. nerka nerka). The presence of plasma cortisol elevation in an upstream migrating, landlocked Pacific salmon suggests that stressors previously considered to cause the cortisol increase, such as long-distance migration and changes in salinity, may not be primary causes of the HPI axis activation.

Cell density and intracellular translocation of glucocorticoid receptor-immunoreactive neurons in the kokanee salmon (Oncorhynchus nerka kennerlyi) brain, with an emphasis on the olfactory system.

This study tested the hypothesis that neurons in olfactory regions of the kokanee salmon brain contain glucocorticoid receptors. Distribution and neuronal number of glucocorticoid receptor-like immunoreactive (GRir) neurons were identified in the kokanee salmon brain using immunohistochemistry with an antibody to GR (polyclonal rabbit anti-human, dilution 1:1500; and monoclonal mouse, dilution 5 micrograms/ml). Distribution of GRir neurons similar to the mammalian pattern was observed in the brains of sexually immature (n = 8; 4 female and 4 male) as well as spawning (n = 8; 4 female and 4 male) salmon. Olfactory-related areas containing GRir positive neuronal bodies included the internal cell layer of the olfactory bulb, ventral-lateral and lateral parts of the dorsal telencephalon (homologue of the mammalian hippocampus), ventral area of the telencephalon (homologue of the mammalian amygdala), glomerulosus complex of the thalamus, the preoptic area, and inferior lobe of the hypothalamus. The pattern of GRir neuronal distribution in sexually immature and spawning fish was similar. However, spawning fish brains, compared to sexually immature brains, exhibited a significantly greater GRir neuronal number in several olfactory regions in paired immunohistochemical runs. There also were differences in intraneuronal location of GRir in olfactory regions, with staining being predominantly cytoplasmic in sexually immature fish but nuclear in spawning fish. These results are consistent with a role for cortisol in olfactory-mediated homing in kokanee salmon. Although GRir were identified in many nonolfactory regions, the focus of this study is on GRir present in brain regions involved in olfaction.

Evidence against the existence of a membrane form of murine IL-1 alpha.

Previous studies have demonstrated that paraformaldehyde-treated macrophages possess IL-1 alpha activity in a variety of bioassay systems. However, no definitive biochemical data in support of the membrane IL-1 alpha concept has been reported. The purpose of the present study was to determine if the biologic activity associated with treated cells is due to a membrane form of IL-1 alpha or alternatively, to the leakage of IL-1 alpha. If the former case was true, then the exposed membrane IL-1 alpha should bind anti-IL-1 alpha antibodies or be cleaved by mild trypsin treatment. In both instances, IL-1 alpha activity should be lost when measured in a subsequent IL-1 bioassay. Our results indicate that pulsing paraformaldehyde-treated normal or cell line macrophages with anti-IL-1 alpha antibodies or treating the cells with trypsin did not affect the ability of the treated cells to function in a murine thymocyte proliferation assay. Furthermore, the standard short term treatment of cells with paraformaldehyde (15 min) did not prevent the leakage of IL-1 alpha from the cells or the processing of the precursor forms of the protein. When cells were treated with paraformaldehyde for 2 h, they no longer released IL-1 alpha or possessed thymocyte stimulatory activity. We also found that short term glutaraldehyde treatment of macrophages completely blocked the release of IL-1 alpha from cells as well as the appearance of cell-associated IL-1 alpha activity. Our results support the conclusion that the stimulatory activity of paraformaldehyde-treated macrophages is not due to a membrane form of IL-1 alpha but is, in fact, due to the continuous release of IL-1 alpha from the cells.