The biological effects of emamectin benzoate (SLICE®) on spot prawn (Pandalus platyceros)

Park, Ashley

18 April 2013

British Columbia salmon aquaculture operations use the chemotherapeutant emamectin benzoate (EMB trade name SLICE®), a synthesized avermectin compound, delivered through feed to decrease sea lice (Lepeophtheirus salmonis) parasite abundance on production fish. Avermectins bind to ion channels in crustaceans and disrupts nerve impulse transmission. Detectable amounts of EMB can accumulate in the depositional area around farms during SLICE® treatment periods, thus presenting potential for exposure to populations of proximate non-target species. The distribution of spot prawn (Pandalus platyceros), an economically important crustacean, overlaps with areas of intensive salmon farm activity. The primary objective of this research was to determine if EMB exposure had a measurable biological effect on spot prawns in the field and in the laboratory. The field component was conducted in the Broughton Archipelago, BC, to determine if emamectin benzoate residues could be detected near actively treating salmon farms, and whether farm proximity affected spot prawn size distribution. Three laboratory experiments tested the mortality, molting and behavioural response of spot prawns to SLICE® feed pellet exposure and acute exposure to EMB through sediment over ten, 30 and 45-day durations. Measurable amounts of EMB was detected in the marine sediment near five farm sites during the field survey and was found to persist between treatment periods. Male and transitional stage spot prawns captured near farm sites attained a greater size and had better body condition compared to reference sites, indicating prawns may benefit from direct or indirect farm food subsidies. However, at several farm sites the size distribution of prawns changed over the sampling period, a trend not observed at reference sites, demonstrating that farm activity may alter prawn population dynamics. Laboratory results indicated that only prawns that had been starved prior to exposure would initially consume SLICE® pellets, but feeding rates declined with subsequent exposures. Depressed consumption rates was not a residual effect of EMB, but rather an aversion to the SLICE® pellet diet as prawns resumed feeding when offered a preferred diet. Sediment EMB exposures to doses 808 µg kg-1 and greater increased prawn mortality, largely due to the inability of molting individuals to successfully complete ecdysis. Exposed individuals accumulated EMB in their abdomen tissue with levels increasing with exposure dose. Prawns exposed to EMB through sediment at concentrations 1419 and 3330 µg kg-1 displayed a significant reduction in olfactory detection and orientation behaviours to food stimuli. This research highlights that spot prawns may avoid SLICE® pellets for preferential food sources, and that only short term EMB exposure 50 to 200 magnitude greater than levels present in the marine environment elicited a measurable response in spot prawn mortality rates, molting success and behaviour. However, preliminary trends in the field survey data indicate that there may be population differences occurring in spot prawns inhabiting areas near treating salmon farms that are not observed in reference populations. These results signify the inherent pitfalls in current management policy that base decisions on short-term acute toxicity laboratory exposure results that may not be indicative of the response of marine populations near active salmon farms to long-term chronic EMB exposure. / Graduate / 0792 / 0329 / 0768

Ecotoxicology

Fisheries

Aquaculture

Sea lice

Emamectin benzoate

Spot prawn

Influence of seasonally variable hypoxia on epibenthic communities in a coastal ecosystem, British Columbia, Canada

Chu, Jackson Wing Four

25 April 2016

Natural cycles of environmental variability and long-term deoxygenation in the ocean impose oxygen deficiency (hypoxia) on marine communities. My research exploits a naturally occurring hypoxia cycle in Saanich Inlet, British Columbia, Canada where I combined spatial surveys with remotely operated vehicles, ecological time-series from the subsea cabled observatory VENUS, and lab-based respirometry experiments to examine the influence of seasonally variable oxygen conditions on epibenthic communities. In situ oxygen thresholds established for dozens of fish and invertebrate species in this system show they naturally occur in lower oxygen levels than what general lethal and sublethal thresholds would predict. Expansion of hypoxic waters induced a loss of community structure which was previously characterized by disjunct distributions among species. Communities in variable hypoxia also have scale-dependent structure across a range of time scales but are primarily synchronized to a seasonal oscillation between two phases. Time-series revealed timing of diurnal movement in the slender sole Lyopsetta exilis and reproductive behavior of squat lobster Munida quadrispina in the hypoxia cycle. Hypoxia-induced mortality of sessile species slowed the rate of community recovery after deoxygenation. The 10-year oxygen time-series from VENUS, revealed a significant increase in the annual low-oxygen period in Saanich Inlet and that deoxygenation has occurred in this system since 2006. Differences in the critical oxygen thresholds (O2crit) and standard metabolic rates of key species (spot prawn Pandalus platyceros, slender sole, and squat lobster) determined the lowest in situ oxygen at which populations occurred and explained disproportionate shifts in distributions and community respiration. Finally, a meta-analysis on global O2crit reported for crustaceans showed that hypoxia tolerance differs among major ocean basins. Long-term trends of deoxygenation suggest a future regime shift may occur when the duration at which a system remains below critical oxygen levels exceeds the time needed for communities to recover. Species-specific traits will determine the critical threshold and the nature of the community response in systems influenced by variable states of oxygen deficiency. However, oceanographic and evolutionary history provides context when determining the regional response of benthic communities influenced by rapidly changing environments. / Graduate / 0329 / 0416 / 0433 / jwfchu@gmail.com

oceanography

hypoxia

benthic ecology

marine biology

remotely operated vehicles

deep sea biology

marine ecology

ocean networks canada

VENUS

cabled observatory

ecological time-series

ecophysiology

slender sole Lyopsetta exilis

squat lobster Munida quadrispina

spot prawn Pandalus platyceros

respirometry

oxygen

critical oxygen tension