A comparison of gut evacuation models for larval mackerel (Scomber scombrus) using serial photography.

A novel technique is described, using serial photography of the gut contents of transparent living larval fishes, to generate individual gut evacuation time series. This technique was applied to Atlantic mackerel Scomber scombrus larvae to compare three widely used models of gut evacuation: linear, exponential and square-root. Regression r(2) for the exponential model exceeded those for the linear and square root models in 20 of 21 time series, strongly supporting the exponential model. At the initial gut fullness for each time series, total gut evacuation rates calculated with the exponential model averaged 2.2 and 1.3 times greater than those calculated with the linear and square-root models, respectively, and would produce correspondingly higher estimates of feeding rates for field-collected larvae with similar levels of gut fullness. The results highlight the importance of choosing the appropriate evacuation model in feeding studies, particularly those intended to examine short-term changes in larval fish feeding rates, a contributing factor to the highly variable yearly recruitment of many marine fish species.

Ingested prey increase risks of visual predation in transparent Chaoborus larvae.

Transparency reduces the chances of detection of large planktonic animals by visual predators. An important constraint on the transparency of planktonic animals may be ingested food which could be seen through the body, thereby increasing the vulnerability of transparent zooplankton to visual predators. To test this hypothesis, we presented fed and un-fed Chaoborus larvae to juvenile coho salmon (Oncorhynchus kisutch). Overall, the presence of prey in the gut of Chaoborus increased their probability of capture by 68%. Predation risks due to the visibility of ingested food increased in proportion to meal size: larvae with nearly full gut were captured about three times faster on the average than larvae which had little food in their gut. Although Chaoborus larvae may be able to reduce this increased predation risk by migrating downward to low light levels, this behavior would reduce feeding opportunities by removing the larvae from surface waters where prey density is generally high. In this way, visual predators may limit the growth and the maximum size that can be achieved by transparent animals.