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Abstract
The aim of this study was to establish whether there are seasonal or age-related changes in circulating levels of somatolactin (SL) in rainbow trout (Onchorhynchus mykiss). SL levels were determined in blood sampled at monthly intervals over a 2-year period from a population of rainbow trout maintained under a natural daylength and temperature regime (North-West England, latitude 54°20′ N). SL levels displayed a distinct circannual cycle, with peak levels in summer (17–20 μg/l) and lowest levels occurring in winter (0·2–2 μg/l). This variation in SL levels was closely correlated with water temperature (P<0·001) but was out of phase with changes in daylength. Plasma SL levels were significantly higher in both mature male and female fish compared with immature fish. Plasma prolactin levels were determined to provide information on a hormone structurally related to SL, and also because mammalian prolactin is known to show distinct seasonal cycles. However, trout prolactin, in contrast to SL, did not show a pronounced seasonal pattern, although prolactin levels were significantly, but inversely, correlated with water temperature (P<0·001).
Journal of Endocrinology (1995) 146, 113–119
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ABSTRACT
Somatolactin (SL), a newly discovered fish pituitary protein belonging to the GH/prolactin family, was isolated from coho salmon (Oncorhynchus kisutch). Antibodies were raised to purified coho SL, and a homologous radioimmunoassay was developed and validated. The assay was specific for SL as indicated by the absence of cross-reactivity with coho salmon GH, gonadotrophins I and II and less than 0·2% cross-reaction to prolactin. Serial dilutions of plasma and pituitary extracts from Oncorhynchus species including coho salmon, chinook salmon and rainbow trout were parallel to the coho salmon SL standard curve. Displacement curves for dilutions of Atlantic salmon (Salmo salar) plasma, but not pituitary extract were parallel to the standards. Plasma levels of SL were measured in coho salmon throughout the final year of reproductive maturation. During the period of gonadal growth, plasma SL levels increased and were highly correlated to oestradiol levels in females and 11-ketotestosterone levels in males. Peak levels of SL were observed at the time of final maturation and spawning in both sexes. It is hypothesized that SL may regulate some physiological aspect of reproduction.
Journal of Endocrinology (1992) 133, 393–403
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ABSTRACT
The preliminary finding that plasma levels of somatolactin (SL) were markedly elevated following stress caused by confinement in chinook salmon (Oncorhynchus tshawytscha) prompted a more detailed study of SL dynamics during stress. SL levels have been determined in the plasma of rainbow trout (Oncorhynchus mykiss) during exposure to acute (0–30 min) and short (0–24 h) periods of stress resulting from handling and confinement. The results show that SL levels increase rapidly within minutes following the onset of stress, reach a peak between 1 and 2 h, decline over the next 3 h, and then show an additional increase again by 24 h. During acute stress caused by confinement, the increase in plasma SL levels occurred within 2 min, thus showing a more rapid response than cortisol. This suggests that the response is mediated directly by the hypothalamus and is not a result of a feedback mechanism. The results also demonstrate that SL secretion in response to stress is at least partially under genetic control. In the short-term stress experiment, progeny of fish selected as high responders or low responders to stress, based on the magnitude of the plasma cortisol levels induced by stress, were used, and these fish showed similarly accentuated or attenuated release of SL following stress. These results clearly demonstrate that non-specific environmental stress causes rapid activation of SL-secreting cells in the pars intermedia, suggesting that this hormone has an important role in the adaptive response of fish to stress.
Journal of Endocrinology (1993) 138, 509–515