RT Journal Article
SR Electronic
T1 A mixture of innate cryoprotectants is key for freeze tolerance and cryopreservation of a drosophilid fly larva
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 2021.12.15.472769
DO 10.1101/2021.12.15.472769
A1 Lukáš Kučera
A1 Martin Moos
A1 Tomáš Štětina
A1 Jaroslava Korbelová
A1 Petr Vodrážka
A1 Lauren Des Marteaux
A1 Robert Grgac
A1 Petr Hůla
A1 Jan Rozsypal
A1 Miloš Faltus
A1 Petr Šimek
A1 Radislav Sedlacek
A1 Vladimír Koštál
YR 2022
UL http://biorxiv.org/content/early/2022/01/13/2021.12.15.472769.abstract
AB Insects that naturally tolerate internal freezing produce complex mixtures of multiple cryoprotectants (CPs). Better knowledge on composition of these mixtures, and on mechanisms of how the individual CPs interact, could inspire development of laboratory CP formulations optimized for cryopreservation of cells and other biological material. Here we identify and quantify (using high resolution mass spectrometry) a range of putative CPs in larval tissues of a subarctic fly, Chymomyza costata that survives long-term cryopreservation in liquid nitrogen. The CPs (proline, trehalose, glutamine, asparagine, glycine betaine, glycerophosphoethanolamine, glycerophosphocholine, and sarcosine) accumulate in hemolymph in a ratio of 313:108:55:26:6:4:3:0.5 mmol.L-1. Using calorimetry, we show that the artificial mixtures, mimicking the concentrations of major CPs’ in hemolymph of freeze-tolerant larvae, suppress the melting point of water and significantly reduce the ice fraction. We demonstrate in a bioassay that mixtures of CPs administered through the diet act synergistically rather than additively to enable cryopreservation of otherwise freeze-sensitive larvae. Using MALDI-MSI, we show that during slow extracellular freezing trehalose becomes concentrated in partially dehydrated hemolymph where it stimulates transition to the amorphous glass phase. In contrast, proline moves to the boundary between extracellular ice and dehydrated hemolymph and tissues where it likely forms a layer of dense viscoelastic liquid. We propose that amorphous glass and viscoelastic liquids may protect macromolecules and cells from thermomechanical shocks associated with freezing and transfer into and out of liquid nitrogen.Summary statement The composition of natural cryoprotectant mixture of the extremely freeze-tolerant insect is revealed. Components of the mixture work in synergy and behave differently during organismal freezing and cryopreservation.Competing Interest StatementThe authors have declared no competing interest.