Antifreeze Fish Inspire New Cryoprotectants for Human Cells and Tissues
Whether it’s the dark, suffocating deep sea or the scalding, bubbling thermal pools, life finds a way to call it home. So, it isn’t a surprise that fish living in the freezing cold waters of the Arctic and Antarctic could provide the inspiration for a new generation of cryoprotectant molecules.
The fish, and other cold-temperature extremophiles, produce proteins that can recognise and bind to ice as it is forming, acting like an anti-freeze. Ice crystals can do a lot of damage to the body, from causing proteins to clump together to weakening the structures that hold tissue together.
This led Professor Matthew Gibson, at Warwick University in the United Kingdom, to attempt to recreate the abilities of ice-binding proteins using synthetic polymers. These have the advantage of being easier to adjust or ‘tune’ to suit their purpose and to manufacture at scale.
‘We can make it a bit more tuneable as you’ve got literally thousands of different monomers you could use to make a polymer,’ he said. ‘Our aim was, if we can mimic some of those properties, to apply these to improve or change how we freeze cells.’
Through the CRYOSTEM project, Prof. Gibson tested these polymers by adding them to samples of bone marrow stem cells, which are often frozen when being transported for a transplant. The current system involves adding solvents to protect the cells when freezing. However, it isn’t ideal. A significant proportion of the cells do not survive and the solvent itself can affect them.
Prof. Gibson has been able to show that his polymers can decrease the amount of solvent needed for cryopreservation, reducing the damage done to the cells. This approach could also help biomedical research, allowing scientists to more reliably store and thaw a wider range of cells in the laboratory.
He is now expanding this work through the ICE PACK project to apply cryoprotectant polymers to the growing field of biologic treatments. Traditional pharmaceuticals are typically small molecules that can be put into a tablet form and will be stable in the medicine cabinet for months. Now, more and more of the modern best-selling drugs are proteins, such as antibodies to treat arthritis or cancer, which need to be stored much more carefully.
More delicate still are cell-based therapies like CAR T cells, which are modified immune cells used to treat cancer. At the moment, cell-based therapies are rare and very expensive, but in the future, they may become more common.
‘They have quite a complex process, where they’re collected from the donor and then they need modifying, freezing and shipping,’ said Prof. Gibson. ‘Anything you can do to make sure they’re protected as best as they can, or make the cold chain easier, is going to have a really big (effect on) patient outcome.’
The ultimate dream
Zoom out from individual proteins or cells and the picture becomes even more complicated.
‘Ice can form inside and outside the cell. Depending on where the ice forms, it is disruptive to cellular structures or extra-cellular structures – for example, the extra-cellular matrix in which the cells are embedded,’ said Professor Ilja Voets at Eindhoven University of Technology in the Netherlands.
The challenge of freezing samples of tissue is another area where analogues of ice-binding proteins could help. As part of the PROTECT project, Prof. Voets is particularly interested in the freezing and thawing of heart cells and tissue. Currently, only about half of the cells are useable after freezing when studying cultures in the laboratory. This becomes even more difficult when studying tissue samples.
‘Typically, the preservation conditions are optimal for one cell type (within the heart tissue), but not for the other types, or not for the tissue as a whole,’ she said. It is a big challenge but the ice-binding protein analogues don’t have to preserve the tissue perfectly to be useful. ‘There’s a very strong regenerative ability of tissues. So in some cases, if the damage is modest, then the tissue can repair itself and it can still be used.’
Voets is using very high-resolution microscopy to understand how different types of ice-binding protein analogues are able to prevent ice formation. This will help to create improved versions that can reduce freeze injury to tissue.
The potential to reliably bank your own tissue samples, to be thawed if needed in the future, is ‘one of the ultimate dreams’, Voets said.
‘Say someone has an infarct (a region of dead cells), you will be able to transplant heart tissue from that very specific patient because you have banked it. That’ll be fantastic, and it could lower the risk of rejection as well. There’s a lot of things that we could gain from being able to bank more types of cells and tissues.’
‘Our cultural imagery of frozenness is about to change.’
A technological fix
Advances in cryopreservation are already making an impact on society. Some companies, mostly in the US, offer egg-freezing services as a perk to employees who want to delay having a child. This essentially defers the decision-making of how to align the competing needs of professional advancement and childcare, says Professor Thomas Lemke, from Goethe University in Germany. ‘This is what is often called a technological fix for a societal problem,’ he said.
This technological fix places further burden on the individual to adapt so that society doesn’t need to change. Prof. Lemke said there is a real danger that it could become a societal expectation. Cryopreservation could become the ultimate insurance policy. Private companies already offer banking for umbilical cord blood, which is rich in stem cells. Perhaps in the future, we will also be able to bank heart tissue.
Prof. Lemke is studying the societal impacts of this ‘suspended life’, as he calls it, across Europe through the CRYOSOCIETIES project. He is examining how cryopreservation practices have developed and how they influence our decision-making.
Whereas societies have often associated coldness with death, cryopreservation creates new opportunities from medical care to biodiversity.
‘It’s no longer the state of non-transformation, of remaining inert. But rather, it mobilises things and it opens up options,’ said Prof. Lemke. ‘Our cultural imagery of frozenness is about to change.’
The research in this article was funded by the EU’s European Research Council. If you liked this article, please consider sharing it on social media.