Literature DB >> 9306405

The antifreeze potential of the spruce budworm thermal hysteresis protein.

M G Tyshenko1, D Doucet, P L Davies, V K Walker.   

Abstract

Antifreeze proteins (AFP) inhibit ice growth by surface adsorption that results in a depression of the freezing point below the melting point. The maximum level of this thermal hysteresis shown by the four structurally unrelated fish AFP is approximately 1.5 degrees C. In contrast, hemolymph and crude extracts from insects can have 5 degrees to 10 degrees C of thermal hysteresis. Based on the isolation, cloning, and expression of a thermal hysteresis protein (THP) from spruce budworm (Choristoneura fumiferana), the vastly greater activity is attributable to a 9 kDa protein. This novel, threonine- and cysteine-rich THP has striking effects on ice crystal morphology, both before and during freezing. It is also 10 to 30 times more active than any known fish AFP, offering the prospect of superior antifreeze properties in cryoprotective applications.

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Year:  1997        PMID: 9306405     DOI: 10.1038/nbt0997-887

Source DB:  PubMed          Journal:  Nat Biotechnol        ISSN: 1087-0156            Impact factor:   54.908


  23 in total

1.  Type II fish antifreeze protein accumulation in transgenic tobacco does not confer frost resistance.

Authors:  K D Kenward; J Brandle; J McPherson; P L Davies
Journal:  Transgenic Res       Date:  1999-04       Impact factor: 2.788

2.  Modeling Pseudomonas syringae ice-nucleation protein as a beta-helical protein.

Authors:  S P Graether; Z Jia
Journal:  Biophys J       Date:  2001-03       Impact factor: 4.033

3.  Expression of an insect (Dendroides canadensis) antifreeze protein in Arabidopsis thaliana results in a decrease in plant freezing temperature.

Authors:  Tao Huang; Jessie Nicodemus; Daniel G Zarka; Michael F Thomashow; Michael Wisniewski; John G Duman
Journal:  Plant Mol Biol       Date:  2002-10       Impact factor: 4.076

4.  Computational study on the function of water within a beta-helix antifreeze protein dimer and in the process of ice-protein binding.

Authors:  Zuoyin Yang; Yanxia Zhou; Kai Liu; Yuhua Cheng; Ruozhuang Liu; Guangju Chen; Zongchao Jia
Journal:  Biophys J       Date:  2003-10       Impact factor: 4.033

5.  Expression of biologically active recombinant antifreeze protein His-MpAFP149 from the desert beetle (Microdera punctipennis dzungarica) in Escherichia coli.

Authors:  Liming Qiu; Yan Wang; Jing Wang; Fuchun Zhang; Ji Ma
Journal:  Mol Biol Rep       Date:  2009-06-28       Impact factor: 2.316

6.  Increased gene dosage augments antifreeze protein levels in transgenic Drosophila melanogaster.

Authors:  B P Duncker; P L Davies; V K Walker
Journal:  Transgenic Res       Date:  1999-02       Impact factor: 2.788

7.  A theoretical model of a plant antifreeze protein from Lolium perenne.

Authors:  M J Kuiper; P L Davies; V K Walker
Journal:  Biophys J       Date:  2001-12       Impact factor: 4.033

8.  Isolation and characterization of a novel antifreeze protein from carrot (Daucus carota).

Authors:  M Smallwood; D Worrall; L Byass; L Elias; D Ashford; C J Doucet; C Holt; J Telford; P Lillford; D J Bowles
Journal:  Biochem J       Date:  1999-06-01       Impact factor: 3.857

9.  Towards a green hydrate inhibitor: imaging antifreeze proteins on clathrates.

Authors:  Raimond Gordienko; Hiroshi Ohno; Vinay K Singh; Zongchao Jia; John A Ripmeester; Virginia K Walker
Journal:  PLoS One       Date:  2010-02-11       Impact factor: 3.240

10.  Interfacial adsorption of antifreeze proteins: a neutron reflection study.

Authors:  Hai Xu; Shiamalee Perumal; Xiubo Zhao; Ning Du; Xiang-Yang Liu; Zongchao Jia; Jian R Lu
Journal:  Biophys J       Date:  2008-01-30       Impact factor: 4.033
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