Growth, survivorship, and juvenile physiology of triploid steelhead (Oncorhynchus mykiss)

Abstract

Abstract Induced triploidy typically causes sterility in teleost fishes, and has therefore been proposed as a tool to manage genetic risks that farmed and hatchery-produced salmon pose to wild populations. Application of this technology for aquaculture has been challenged by inferior growth, survivorship and, in the case of free-ranging anadromous salmonids, relatively low numbers of adult returns. There is little information on whether or not triploidy affects the physiological development of juvenile salmonids in ways that impair their ability to grow, imprint on natal waters, survive, and return from the ocean as adults. In this study we pressure treated fertilized eggs to produce two cohorts of triploid hatchery steelhead trout (i.e., anadromous Oncorhynchus mykiss). We calculated survivorship through early life stages, and measured gill ATPase and plasma thyroxine (T4) for yearling triploids and their full-sibling diploid controls. We found no clear pattern of difference between diploid and triploid steelhead for the biomarkers of smoltification T4 or ATPase. After a year of freshwater rearing, we transferred 448 tagged treatment and control fish to a saltwater tank, and tracked their growth and survivorship for over 15 months. Diploids outperformed triploids in growth and, by the end of our study, survivorship of diploids (72%) was more than twice that of triploids (35%). Our findings suggest that inferior growth and survivorship of triploids in saltwater seriously challenge the application of this technology for free-ranging steelhead and, by extension, Pacific salmon. Additional research is needed to identify and offset the causal mechanisms underpinning triploid attrition during saltwater rearing.