Molecular Science
Winter spiders hide powerful antifreeze
January 12, 2026
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A Clubiona spider, part of a group of winter-active species that remain unfrozen and active in cold temperatures [Credit: Ond艡ej Mich谩lek, Masaryk University].
On a cold winter day in Kingston, Ontario a small spider inside a birdhouse was doing something most people would not expect. It was moving, alive, active, and unfrozen.
That quiet observation helped launch new research from Queen鈥檚 University showing that winter-active spiders make an unusually powerful antifreeze protein that lets them survive subzero temperatures and keep hunting when other insects shut down.
The study, recently published in , reveals that spiders from the genus Clubiona produce a 鈥渉yperactive鈥 antifreeze protein with a unique structure. The finding sheds new light on how animals evolve to survive extreme cold and could have implications for agriculture and biotechnology.
A winter mystery
The discovery began not in a lab, but in the backyard of Queen鈥檚 researcher (Biomedical and Molecular Sciences). He had installed a birdhouse hoping to attract chickadees. Instead, he found spider cocoons tucked inside during winter.
The birdhouse in Kingston where Queen鈥檚 researcher Dr. Peter Davies first noticed winter-active spiders sheltering inside.
鈥淲hen I gently poked them, the spiders moved,鈥 says Dr. Davies. 鈥淚f an insect or spider is active in winter, that usually means it has some kind of antifreeze.鈥
Dr. Davies and Queen鈥檚 researcher (Biomedical and Molecular Sciences) have spent decades studying antifreeze proteins in insects and fish. These proteins prevent ice crystals from growing inside the body, which would otherwise be fatal.
Spiders were known to have antifreeze activity as far back as the late 1970s. What had never been done was to identify the protein itself and understand how it works.
鈥淭hat was the missing piece,鈥 says Dr. Graham. 鈥淣o one had taken the next step to look at the structure and behaviour of the spider antifreeze.鈥
A protein that stops ice cold
To study the spiders, the team partnered with Czech researcher Dr. Stanislav Pek谩r, who studies winter-active spiders in European orchards. Live spiders cannot be shipped across borders, so the specimens were freeze-dried before arriving in Kingston.
From there, the work moved into the lab.
鈥淲e literally start with a spider slurry,鈥 says Dr. Graham. 鈥淭hen we purify the antifreeze protein using ice itself.鈥
The process relies on the protein鈥檚 defining feature. Antifreeze proteins stick to ice, while other proteins do not. By repeatedly freezing and melting the sample, the team was able to isolate the antifreeze protein in pure form.
Under the microscope, the effect was dramatic.
鈥淲ith no antifreeze, ice grows as you cool it,鈥 says Dr. Davies. 鈥淲ith this protein present, the ice just stops growing.鈥
The spider antifreeze was classified as 鈥渉yperactive鈥 because it works far more efficiently than antifreeze proteins found in fish. While fish only need protection down to about minus two degrees Celsius, land-dwelling insects and spiders can face temperatures below minus 30.
鈥淭hese spiders need something much more potent,鈥 says Dr. Davies. 鈥淎nd that鈥檚 exactly what they have.鈥
A new fold, evolved from scratch
The study also revealed that the spider antifreeze protein has a unique shape, known as a beta-solenoid fold. While it shares some functional features with antifreeze proteins in insects, it is structurally distinct.
Rather than allowing ice to form inside the body, the protein acts early, blocking ice crystals at the moment they begin to grow. The spiders also produce several slightly different versions of the protein, known as isoforms. Working together, these versions interfere with ice growth in multiple directions, making freezing far less likely.
鈥淭hat mix seems to work better than a single version,鈥 says Dr. Davies. 鈥淚t鈥檚 nature using a team approach.鈥
Spiders as winter pest control
Beyond survival, winter activity gives these spiders an ecological advantage. In orchards, Clubiona spiders remain active when insect pests are dormant and vulnerable.
鈥淪piders are among the most important natural enemies of orchard pests,鈥 says Dr. Davies. 鈥淚f they can hunt all winter, that鈥檚 a big benefit.鈥
The research supports the idea that protecting spider populations could reduce the need for pesticides, especially if growers use products that target insects without harming spiders.
Dr. Graham adds that spiders often go unnoticed because they work quietly in the background. 鈥淚f you see spiders around, it usually means they鈥檙e doing something useful,鈥 she says.
Why evolution keeps repeating itself
One of the most intriguing findings is how often antifreeze proteins have evolved independently across the animal kingdom.
鈥淲e see this again and again,鈥 says Dr. Davies. 鈥淔ish, insects, spiders. Different proteins, same function.鈥
The repeated evolution suggests that extreme cold has been a powerful force shaping life on Earth, especially during past ice ages. It also highlights how energy-intensive antifreeze production is, with organisms only maintaining it when they truly need it.
As the climate warms, that balance may shift.
鈥淚f the ice disappears, the selective pressure disappears too,鈥 says Dr. Graham. 鈥淧roducing antifreeze takes energy, and evolution doesn鈥檛 waste energy.鈥
For now, though, winter-active spiders continue their cold-weather work, quietly patrolling orchards and backyards alike.
鈥淒on鈥檛 squish them,鈥 says Dr. Davies. 鈥淭hey鈥檙e on our side.鈥
