Antifreeze protein-induced superheating of ice inside Antarctic notothenioid fishes inhibits melting during summer warming

Significance Antarctic notothenioid fishes are protected from freezing by antifreeze proteins (AFPs) that bind to invading ice crystals and inhibit their growth. Paradoxically, accumulation of AFP-stabilized ice could be lethal. Whether and how fishes eliminate internal ice is unknown; one hypothesis is that it melts during summer warming episodes. However, prior in vitro evidence indicates that AFPs also inhibit melting. Our study establishes that pronounced melting inhibition occurs in vivo (i.e., superheated ice occurs inside notothenioid fishes). Our long-term temperature record of a high-latitude Antarctic fish habitat indicates that summer warming does not overcome AFP-induced superheating to reliably rid fishes of ice. Evolution of the life-saving AFPs exacts a cost: the risk of lifelong accumulation of damaging internal ice crystals. Antifreeze proteins (AFPs) of polar marine teleost fishes are widely recognized as an evolutionary innovation of vast adaptive value in that, by adsorbing to and inhibiting the growth of internalized environmental ice crystals, they prevent death by inoculative freezing. Paradoxically, systemic accumulation of AFP-stabilized ice could also be lethal. Whether or how fishes eliminate internal ice is unknown. To investigate if ice inside high-latitude Antarctic notothenioid fishes could melt seasonally, we measured its melting point and obtained a decadal temperature record from a shallow benthic fish habitat in McMurdo Sound, Antarctica. We found that AFP-stabilized ice resists melting at temperatures above the expected equilibrium freezing/melting point (eqFMP), both in vitro and in vivo. Superheated ice was directly observed in notothenioid serum samples and in solutions of purified AFPs, and ice was found to persist inside live fishes at temperatures more than 1 °C above their eqFMP for at least 24 h, and at a lower temperature for at least several days. Field experiments confirmed that superheated ice occurs naturally inside wild fishes. Over the long-term record (1999–2012), seawater temperature surpassed the fish eqFMP in most summers, but never exceeded the highest temperature at which ice persisted inside experimental fishes. Thus, because of the effects of AFP-induced melting inhibition, summer warming may not reliably eliminate internal ice. Our results expose a potentially antagonistic pleiotropic effect of AFPs: beneficial freezing avoidance is accompanied by melting inhibition that may contribute to lifelong accumulation of detrimental internal ice crystals.

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