Fluorescence Microscopy Evidence for Quasi-Permanent Attachment of Antifreeze Proteins to Ice Surfaces

Pertaya, Natalya; Marshall, Christopher B.; Diprinzio, C.L.; Wilen, Larry; Thomson, Erik S.; Wettlaufer, J. S.; Davies, Peter L.; Braslavsky, Ido

doi:10.1529/biophysj.106.096297

Cited by 110 publications

(148 citation statements)

References 63 publications

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“…These surface densities correspond to distances between GFP-TmAFP molecules ranging from 6 nm to 18 nm. These values of surface density are higher than those previously reported for AFGP and type III AFP (9,22).…”

Section: Resultscontrasting

confidence: 76%

“…2C, green line), indicating that the GFP-TmAFP molecules bound to the ice crystal remained adsorbed over the course of the medium exchange process. We estimated the density of the GFP-TmAFP molecules on the ice surfaces from measurements of fluorescence intensity in the solution and at the ice surfaces, as described previously (22). We found surface densities ranging from 3,000 to 25,000 molecules per square micrometer, depending on the concentration in solution, plane of adsorption examined, and time allowed for accumulation.…”

Section: Resultsmentioning

confidence: 99%

“…. The last set of data points represents the fluorescence intensity of GFP-TmAFPs adsorbed on the ice surface (Ice) and is calculated from the two first datasets, Solution and Edge, respectively, using the equation Ice = Edge − Const × Solution, where Const is a fitting parameter, which reflects the contribution of GFP-TmAFPs in solution into the fluorescence at the edge of the ice crystal (22). Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Thus, the authors concluded that the binding of these proteins to the ice surface was weak. In contrast to the above results, Pertaya et al (22), who used fish AFP type III (23) tagged with green fluorescent protein (GFP) and the technique of fluorescence recovery after photobleaching (FRAP), found the binding of AFPs to ice surfaces to be irreversible. Nevertheless, these experiments did not directly address the question of the influence of AFPs in solution on the FH activity.…”

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confidence: 80%

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Microfluidic experiments reveal that antifreeze proteins bound to ice crystals suffice to prevent their growth

Celik

Drori

Pertaya-Braun

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Antifreeze proteins (AFPs) are a subset of ice-binding proteins that control ice crystal growth. They have potential for the cryopreservation of cells, tissues, and organs, as well as for production and storage of food and protection of crops from frost. However, the detailed mechanism of action of AFPs is still unclear. Specifically, there is controversy regarding reversibility of binding of AFPs to crystal surfaces. The experimentally observed dependence of activity of AFPs on their concentration in solution appears to indicate that the binding is reversible. Here, by a series of experiments in temperature-controlled microfluidic devices, where the medium surrounding ice crystals can be exchanged, we show that the binding of hyperactive Tenebrio molitor AFP to ice crystals is practically irreversible and that surface-bound AFPs are sufficient to inhibit ice crystal growth even in solutions depleted of AFPs. These findings rule out theories of AFP activity relying on the presence of unbound protein molecules.thermal hysteresis | ice structuring proteins A ntifreeze proteins (AFPs) are found in a variety of coldadapted organisms, where they serve as inhibitors of ice crystal growth and recrystallization (1, 2). These proteins are a subset of an expanding group of identified proteins, whose salient feature is ice binding (3, 4). AFPs are characterized by their ability to cause a temperature difference (hysteresis) in the melting and freezing of ice and are classified as hyperactive or moderately active according to the magnitude of their freezing hysteresis (FH) activity (5). The FH activity is defined as the difference between the melting temperature of ice crystals and the nonequilibrium freezing temperature at which rapid crystal growth commences. Although the FH activity has been investigated for more than four decades, the actual mechanism of action of AFPs is still not clear. This is partly because the interactions between molecules of AFPs, water, and ice at the ice-water interface are difficult to study experimentally due to the delicate, transitory nature of the ice-water interface.FH activity is thought to be due to an adsorption-inhibition mechanism that states that AFPs bind to ice surfaces and allow ice crystal growth only in surface regions between the bound AFP molecules (6, 7). This patchy growth pattern causes increased local microcurvature of the ice front that leads to larger surface energy, making the transformation of water into ice less energetically favorable and thus reducing the freezing temperature (GibbsThompson effect). It has been argued that the binding of AFPs to ice surfaces must be irreversible, because AFP desorption would result in rapid crystal growth in the areas where the AFP molecules have been desorbed from the ice surface (6,8). This theory has been criticized for assuming that the ice-water interface is sharp, contrary to the experimental evidence that the transitions from an ordered solid phase to a liquid phase at the ice-water interfaces are gradual and occur over seve...

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Section: Resultscontrasting

confidence: 76%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 80%

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Microfluidic experiments reveal that antifreeze proteins bound to ice crystals suffice to prevent their growth

Celik

Drori

Pertaya-Braun

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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“…The experimental cell used in the fluorescence microscopy experiments was the same as that used in the nanoliter osmometer experiments, except that the samples were sandwiched between two cover glasses rather than placed in immersion oil. The cover glasses were sealed together with polydimethylsiloxane (Sylgard 184, Dow Corning Corp.) which was prepared with a ratio of 1∶10 [vol/vol] between the curing agent and the base (41). The sandwiched cover glass was placed on a metal plate to control its temperature.…”

Section: Methodsmentioning

confidence: 99%

Superheating of ice crystals in antifreeze protein solutions

Celik

Graham

Mok

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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It has been argued that for antifreeze proteins (AFPs) to stop ice crystal growth, they must irreversibly bind to the ice surface. Surface-adsorbed AFPs should also prevent ice from melting, but to date this has been demonstrated only in a qualitative manner. Here we present the first quantitative measurements of superheating of ice in AFP solutions. Superheated ice crystals were stable for hours above their equilibrium melting point, and the maximum superheating obtained was 0.44°C. When melting commenced in this superheated regime, rapid melting of the crystals from a point on the surface was observed. This increase in melting temperature was more appreciable for hyperactive AFPs compared to the AFPs with moderate antifreeze activity. For each of the AFP solutions that exhibited superheating, the enhancement of the melting temperature was far smaller than the depression of the freezing temperature. The present findings clearly show that AFPs adsorb to ice surfaces as part of their mechanism of action, and this absorption leads to protection of ice against melting as well as freezing.Gibbs-Thomson effect | ice recrystallization | irreversible binding | melting hysteresis | thermal hysteresis

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Antifreeze Proteins by Solid-state NMR: Methods and Applications

Siemer

2014

eMagRes

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Fluorescence Microscopy Evidence for Quasi-Permanent Attachment of Antifreeze Proteins to Ice Surfaces

Cited by 110 publications

References 63 publications

Microfluidic experiments reveal that antifreeze proteins bound to ice crystals suffice to prevent their growth

Microfluidic experiments reveal that antifreeze proteins bound to ice crystals suffice to prevent their growth

Superheating of ice crystals in antifreeze protein solutions

Antifreeze Proteins by Solid-state NMR: Methods and Applications

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