Influence of temperature on the development of the heart ventricle in herring (Clupea harengus) larvae

Critical windows in embryonic development: Shifting incubation temperatures alter heart rate and oxygen consumption of Lake Whitefish (Coregonus clupeaformis) embryos and hatchlings

Critical windows are periods of developmental susceptibility when the phenotype of an embryonic, juvenile or adult animal may be vulnerable to environmental fluctuations. Temperature has pervasive effects on poikilotherm physiology, and embryos are especially vulnerable to temperature shifts. To identify critical windows, we incubated whitefish embryos at control temperatures of 2°C, 5°C, or 8°C, and shifted treatments among temperatures at the end of gastrulation or organogenesis. Heart rate (fH) and oxygen consumption ( [Formula: see text] ) were measured across embryonic development, and [Formula: see text] was measured in 1-day old hatchlings. Thermal shifts, up or down, from initial incubation temperatures caused persistent changes in fH and [Formula: see text] compared to control embryos measured at the same temperature (2°C, 5°C, or 8°C). Most prominently, when embryos were measured at organogenesis, shifting incubation temperature after gastrulation significantly lowered [Formula: see text] or fH. Incubation at 2°C or 5°C through gastrulation significantly lowered [Formula: see text] (42% decrease) and fH (20% decrease) at 8°C, incubation at 2°C significantly lowered [Formula: see text] (40% decrease) and fH (30% decrease) at 5°C, and incubation at 5°C and 8°C significantly lowered [Formula: see text] at 2°C (27% decrease). Through the latter half of development, [Formula: see text] and fH in embryos were not different from control values for thermally shifted treatments. However, in hatchlings measured at 2°C, [Formula: see text] was higher in groups incubated at 5°C or 8°C through organogenesis, compared to 2°C controls (43 or 65% increase, respectively). Collectively, these data suggest that embryonic development through organogenesis represents a critical window of embryonic and hatchling phenotypic plasticity. This study presents an experimental design that identified thermally sensitive periods for fish embryos.

Hyperthermia induced atrial natriuretic peptide expression and deviant heart development in Atlantic salmon Salmo salar embryos

Heart abnormalities are increasingly recognized as a problem in salmon aquaculture. Fish in early life-stages are particularly susceptible to teratogens, including elevated water temperature. Recently, heat-induced mRNA expression of the cardiac hormone atrial natriuretic peptide (ANP), which is known to be involved in modulation of cardiac growth and regulation of cardiac homeostasis, was demonstrated in Atlantic salmon (Salmo salar) embryos by RAP-PCR. The relation between heat sensitive ANP expression and heart abnormalities was explored in two experiments. In an experiment with short-term exposure, salmon eggs were heat shocked at 16 degrees C at eight different embryonic stages from gastrulation till completion of somitogenesis. The RT-PCR results showed that the ANP mRNA expression was down-regulated at the onset of heart formation at the gastrula stage, while the transcription became heat inducible from the fusioning of the heart tube around the 15th-20th somite stage and onwards. This was confirmed by whole-mount in situ hybridization, which also showed that ANP is exclusively expressed in the heart of Atlantic salmon embryos. In a second long-term experiment, salmon embryos were incubated at either 10 degrees C (high temperature) or 8 degrees C (controls) from fertilization till first feeding, and subsequently reared within normal conditions to an average size of 52 g. The long-term hyperthermic embryos showed up-regulated ANP transcription at the approximately 9th and approximately 20th somite stage and at the completion of somitogenesis. The cardiosomatic index [CSI; (ventricle weight/body weight) *100] demonstrated a significant decrease in the relative heart weight of fish incubated at 10 degrees C during the embryogenesis compared with controls. In these fish, aplasia of septum transversum was observed in 2 of 25 fish, resulting in abnormally shaped hearts situated partly within the abdominal cavity. Altogether, our results demonstrate that hyperthermia both induce deviant development of heart and associated structures and up-regulation of ANP transcription during embryogenesis. A possible role of ANP in development of heart malformations is thus suggested.