Coping with climatic extremes: Dietary fat content decreased the thermal resilience of barramundi (Lates calcarifer).
Study Goal
The researchers aimed to determine whether increasing dietary fat content (20% vs. 10% crude fat) improves growth performance and thermal resilience in juvenile barramundi.
Results Summary
A high-fat diet increased fish weight but did not improve thermal sensitivity of swimming performance or metabolism. It reduced thermal tolerance by 0.48°C, compromising upper thermal limits.
Population
Juvenile barramundi (Lates calcarifer)
Effective Dosage
20% versus 10% crude fat diets
Duration
28 days
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
high fat diet (20% crude fat) | increase | growth performance | juvenile barramundi (Lates calcarifer) | - | resulted in heavier fish | #1 |
high fat diet (20% crude fat) | no change | thermal sensitivity of swimming performance | juvenile barramundi (Lates calcarifer) | - | did not affect | #2 |
high fat diet (20% crude fat) | no change | thermal sensitivity of metabolism | juvenile barramundi (Lates calcarifer) | - | did not affect | #3 |
high fat diet (20% crude fat) | decrease | thermal tolerance | juvenile barramundi (Lates calcarifer) | 0.48 °C | compromised | #4 |
high fat diet (20% crude fat) | decrease | upper thermal tolerance (CTMAX) | juvenile barramundi (Lates calcarifer) | - | significantly lower | #5 |
Aquatic organisms, including important cultured species, are forced to contend with acute changes in water temperature as the frequency and intensity of extreme weather events worsen. Acute temperature spikes are likely to threaten aquaculture species, but dietary intervention may play an important protective role. Increasing the concentration of macronutrients, for example dietary fat content, may improve the thermal resilience of aquaculture species, however, this remains unexplored. To evaluate this hypothesis, we used two commercially available diets (20% versus 10% crude fat) to examine if dietary fat content improves the growth performance of juvenile barramundi (Lates calcarifer) while increasing their resilience to acute thermal stress. Fish were fed their assigned diets for 28-days before assessing the upper thermal tolerance (CTMAX) and the thermal sensitivity of swimming performance (UCRIT) and metabolism. We found that feeding fish a high fat diet resulted in heavier fish, but did not affect the thermal sensitivity of swimming performance or metabolism over an 18 °C temperature range (from 20 to 38 °C). Thermal tolerance was compromised in fish fed the high fat diet by 0.48 °C, showing significantly lower CTMAX. Together, these results suggest that while a high fat diet increases juvenile L. calcarifer growth, it does not benefit physiological performance across a range of relevant water temperatures and may even reduce fish tolerance of extreme water temperatures. These data may have implications for aquaculture production in a warming world, where episodic extremes of temperature are likely to become more frequent.