This manuscript reports a detailed study on the ability of poly(vinyl alcohol) to act as a biomimetic surrogate for antifreeze(glyco)proteins, with a focus on the specific property of ice-recrystallization inhibition (IRI). Despite over 40 years of study, the underlying mechanisms that govern the action of biological antifreezes are still poorly understood, which is in part due to their limited availability and challenging synthesis. Poly(vinyl alcohol) (PVA) has been shown to display remarkable ice recrystallization inhibition activity despite its major structural differences to native antifreeze proteins. Here, controlled radical polymerization is used to synthesize well-defined PVA, which has enabled us to obtain the first quantitative structure-activity relationships, to probe the role of molecular weight and comonomers on IRI activity. Crucially, it was found that IRI activity is "switched on" when the polymer chain length increases from 10 and 20 repeat units. Substitution of the polymer side chains with hydrophilic or hydrophobic units was found to diminish activity. Hydrophobic modifications to the backbone were slightly more tolerated than side chain modifications, which implies an unbroken sequence of hydroxyl units is necessary for activity. These results highlight that, although hydrophobic domains are key components of IRI activity, the random inclusion of addition hydrophobic units does not guarantee an increase in activity and that the actual polymer conformation is important.
There is an urgent need to understand the behavior of the novel coronavirus
(SARS-COV-2), which is the causative agent of COVID-19, and to develop point-of-care
diagnostics. Here, a glyconanoparticle platform is used to discover that
N
-acetyl neuraminic acid has affinity toward the SARS-COV-2 spike
glycoprotein, demonstrating its glycan-binding function. Optimization of the particle
size and coating enabled detection of the spike glycoprotein in lateral flow and showed
selectivity over the SARS-COV-1 spike protein. Using a virus-like particle and a
pseudotyped lentivirus model, paper-based lateral flow detection was demonstrated in
under 30 min, showing the potential of this system as a low-cost detection platform.
Ice binding proteins
modulate ice nucleation/growth and have huge
(bio)technological potential. There are few synthetic materials that
reproduce their function, and rational design is challenging due to
the outstanding questions about the mechanisms of ice binding, including
whether ice binding is essential to reproduce all their macroscopic
properties. Here we report that nanoparticles obtained by polymerization-induced
self-assembly (PISA) inhibit ice recrystallization (IRI) despite their
constituent polymers having no apparent activity. Poly(ethylene glycol),
poly(dimethylacrylamide), and poly(vinylpyrrolidone) coronas
were all IRI-active when assembled into nanoparticles. Different core-forming
blocks were also screened, revealing the core chemistry had no effect.
These observations show ice binding domains are not essential for
macroscopic IRI activity and suggest that the size, and crowding,
of polymers may increase the IRI activity of “non-active”
polymers. It was also discovered that poly(vinylpyrrolidone)
particles had ice crystal shaping activity, indicating this polymer
can engage ice crystal surfaces, even though on its own it does not
show any appreciable ice recrystallization inhibition. Larger (vesicle)
nanoparticles are shown to have higher ice recrystallization inhibition
activity compared to smaller (sphere) particles, whereas ice nucleation
activity was not found for any material. This shows that assembly
into larger structures can increase IRI activity and that increasing
the “size” of an IRI does not always lead to ice nucleation.
This nanoparticle approach offers a platform toward ice-controlling
soft materials and insight into how IRI activity scales with molecular
size of additives.
Understanding the ice recrystallisation inhibition (IRI) activity of antifreeze biomimetics is crucial to the development of the next generation of cryoprotectants. In this work, we bring together molecular dynamics simulations and quantitative experimental measurements to unravel the microscopic origins of the IRI activity of poly(vinyl)alcohol (PVA)—the most potent of biomimetic IRI agents. Contrary to the emerging consensus, we find that PVA does not require a “lattice matching” to ice in order to display IRI activity: instead, it is the effective volume of PVA and its contact area with the ice surface which dictates its IRI strength. We also find that entropic contributions may play a role in the ice-PVA interaction and we demonstrate that small block co-polymers (up to now thought to be IRI-inactive) might display significant IRI potential. This work clarifies the atomistic details of the IRI activity of PVA and provides novel guidelines for the rational design of cryoprotectants.
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