Animal ice-binding (antifreeze) proteins and glycolipids: an overview with emphasis on physiological function

Duman, John G.

doi:10.1242/jeb.116905

Cited by 135 publications

(89 citation statements)

References 171 publications

(174 reference statements)

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“…Note that the experiments described here were done using only DAFP-1 and trehalose in water, whereas hemolymph is a very complex system. These results suggest that trehalose also functions as a physiological antifreeze activity enhancer, working in cooperation with certain other solutes in the winter hemolymph to depress the freezing and supercooling points to sufficiently lower temperatures for D. canadensis wintering (39,40).…”

Section: Resultsmentioning

confidence: 90%

Antifreeze proteins govern the precipitation of trehalose in a freezing-avoiding insect at low temperature

Wen

Wang

Duman

et al. 2016

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

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The remarkable adaptive strategies of insects to extreme environments are linked to the biochemical compounds in their body fluids. Trehalose, a versatile sugar molecule, can accumulate to high levels in freeze-tolerant and freeze-avoiding insects, functioning as a cryoprotectant and a supercooling agent. Antifreeze proteins (AFPs), known to protect organisms from freezing by lowering the freezing temperature and deferring the growth of ice, are present at high levels in some freeze-avoiding insects in winter, and yet, paradoxically are found in some freeze-tolerant insects. Here, we report a previously unidentified role for AFPs in effectively inhibiting trehalose precipitation in the hemolymph (or blood) of overwintering beetle larvae. We determine the trehalose level (29.6 ± 0.6 mg/mL) in the larval hemolymph of a beetle, Dendroides canadensis, and demonstrate that the hemolymph AFPs are crucial for inhibiting trehalose crystallization, whereas the presence of trehalose also enhances the antifreeze activity of AFPs. To dissect the molecular mechanism, we examine the molecular recognition between AFP and trehalose crystal interfaces using molecular dynamics simulations. The theory corroborates the experiments and shows preferential strong binding of the AFP to the fast growing surfaces of the sugar crystal. This newly uncovered role for AFPs may help explain the long-speculated role of AFPs in freeze-tolerant species. We propose that the presence of high levels of molecules important for survival but prone to precipitation in poikilotherms (their body temperature can vary considerably) needs a companion mechanism to prevent the precipitation and here present, to our knowledge, the first example. Such a combination of trehalose and AFPs also provides a novel approach for cold protection and for trehalose crystallization inhibition in industrial applications.T rehalose is a multifunctional nonreducing disaccharide, occurring naturally in all kingdoms (1-4). In addition to being an energy and carbon source, this sugar protects cells and proteins against injuries in extreme environments (1, 2, 4), prevents osteoporosis (5), alleviates certain diseases (6), and acts as a signal molecule in plants (7). Due to its bioprotective properties, trehalose is a potentially useful protectant of cells and proteins in numerous applications (2,8). Its practical use, however, can be impaired by the fact that this sugar is prone to crystallization, in particular, when its aqueous solution is under fluctuating low temperatures. For example, the crystallization of trehalose dihydrate during the freeze-drying processes or from solutions at low temperatures would significantly jeopardize its ability to protect biomolecules (8-10). In comparison with other common sugars including sucrose, trehalose has a high propensity to crystallize at low temperature, forming trehalose dihydrate crystals. This propensity is due to: (i) the solubility of trehalose in water decreases dramatically or exponentially as temperature decreases (few data at...

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Section: Resultsmentioning

confidence: 90%

Antifreeze proteins govern the precipitation of trehalose in a freezing-avoiding insect at low temperature

Wen

Wang

Duman

et al. 2016

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

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“…The control of ice nucleation is essential to engineer the porous morphology of the scaffolds. The antifreezing substances such as anti freezing proteins and salts like zirconium acetates are the important class of materials which controls the ice nucleation by the exposure of hydrophobic residues on ice nuclei (Duman, 2015;Mizrahy, Dolev, Guy, & Braslavsky, 2013). The pore structure is mainly controlled by the ice nucleation, which is influenced by various parameters such as solution viscosity, concentration of the solute, growth velocity of ice crystals and pH.…”

Section: Results and Discussion 31 Scanning Electron Microscopymentioning

confidence: 99%

Surface stiffening and enhanced photoluminescence of ion implanted cellulose – polyvinyl alcohol – silica composite

Shanthini

Sakthivel

Menon

et al. 2016

Carbohydrate Polymers

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Novel Cellulose (Cel) reinforced polyvinyl alcohol (PVA)-Silica (Si) composite which has good stability and in vitro degradation was prepared by lyophilization technique and implanted using N 3+ ions of energy 24 keV in the fluences of 1 × 10 15 , 5 × 10 15 and 1 × 10 16 ions/cm 2 . SEM analysis revealed the formation of microstructures, and improved the surface roughness on ion implantation. In addition to these structural changes, the implantation significantly modified the luminescent, thermal and mechanical properties of the samples. The elastic modulus of the implanted samples has increased by about 50 times compared to the pristine which confirms that the stiffness of the sample surface has increased remarkably on ion implantation. The photoluminescence of the native cellulose has improved greatly due to defect site, dangling bonds and hydrogen passivation. Electric conductivity of the ion implanted samples was improved by about 25%. Hence, low energy ion implantation tunes the mechanical property, surface roughness and further induces the formation of nano structures. MG63 cells seeded onto the scaffolds reveals that with the increase in implantation fluence, the cell attachment, viability and proliferation have improved greatly compared to pristine. The enhancement of cell growth of about 59% was observed in the implanted samples compared to pristine. These properties will enable the scaffolds to be ideal for bone tissue engineering and imaging applications.

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“…13,25 At first sight, it seems as if fishes are well protected from freezing in sea water of À1. 9 C, while insects remain at risk in their natural habitats.…”

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“…Insect AFPs from freezetolerant species exhibit much lower TH values than their counterparts from freeze-avoiding species. 25 A combination of low daylight exposure and low temperature triggers the production of AFPs in cold-adapted overwintering plants with typical TH values of 0.1-0.5 C. 31,35 Plant IBPs are also very effective inhibitors of ice recrystallization [ Fig. 1(e)].…”

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confidence: 99%

Interaction of ice binding proteins with ice, water and ions

et al. 2016

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Articles you may be interested inExplicit-water theory for the salt-specific effects and Hofmeister series in protein solutions J. Chem. Phys. 144, 215101 (2016) Ice binding proteins (IBPs) are produced by various cold-adapted organisms to protect their body tissues against freeze damage. First discovered in Antarctic fish living in shallow waters, IBPs were later found in insects, microorganisms, and plants. Despite great structural diversity, all IBPs adhere to growing ice crystals, which is essential for their extensive repertoire of biological functions. Some IBPs maintain liquid inclusions within ice or inhibit recrystallization of ice, while other types suppress freezing by blocking further ice growth. In contrast, ice nucleating proteins stimulate ice nucleation just below 0 C. Despite huge commercial interest and major scientific breakthroughs, the precise working mechanism of IBPs has not yet been unraveled. In this review, the authors outline the state-of-the-art in experimental and theoretical IBP research and discuss future scientific challenges. The interaction of IBPs with ice, water and ions is examined, focusing in particular on ice growth inhibition mechanisms.

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Animal ice-binding (antifreeze) proteins and glycolipids: an overview with emphasis on physiological function

Cited by 135 publications

References 171 publications

Antifreeze proteins govern the precipitation of trehalose in a freezing-avoiding insect at low temperature

Antifreeze proteins govern the precipitation of trehalose in a freezing-avoiding insect at low temperature

Surface stiffening and enhanced photoluminescence of ion implanted cellulose – polyvinyl alcohol – silica composite

Interaction of ice binding proteins with ice, water and ions

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