Stressmann Maja, Kitao Satoshi, Griffith Marilyn, Moresoli Christine, Bravo León A, Marangoni Alejandro G
Departments of Biology, University of Waterloo, Waterloo, Ontario N2L 3G1, Canada.
Plant Physiol. 2004 May;135(1):364-76. doi: 10.1104/pp.103.038158. Epub 2004 Apr 30.
During cold acclimation, winter rye (Secale cereale) plants accumulate pathogenesis-related proteins that are also antifreeze proteins (AFPs) because they adsorb onto ice and inhibit its growth. Although they promote winter survival in planta, these dual-function AFPs proteins lose activity when stored at subzero temperatures in vitro, so we examined their stability in solutions containing CaCl2, MgCl2, or NaCl. Antifreeze activity was unaffected by salts before freezing, but decreased after freezing and thawing in CaCl2 and was recovered by adding a chelator. Ca2+ enhanced chitinase activity 3- to 5-fold in unfrozen samples, although hydrolytic activity also decreased after freezing and thawing in CaCl2. Native PAGE, circular dichroism, and Trp fluorescence experiments showed that the AFPs partially unfold after freezing and thawing, but they fold more compactly or aggregate in CaCl2. Ruthenium red, which binds to Ca(2+)-binding sites, readily stained AFPs in the absence of Ca2+, but less stain was visible after freezing and thawing AFPs in CaCl2. We conclude that the structure of AFPs changes during freezing and thawing, creating new Ca(2+)-binding sites. Once Ca2+ binds to those sites, antifreeze activity, chitinase activity and ruthenium red binding are all inhibited. Because free Ca2+ concentrations are typically low in the apoplast, antifreeze activity is probably stable to freezing and thawing in planta. Ca2+ may regulate chitinase activity if concentrations are increased locally by release from pectin or interaction with Ca(2+)-binding proteins. Furthermore, antifreeze activity can be easily maintained in vitro by including a chelator during frozen storage.
在冷驯化过程中,冬黑麦(Secale cereale)植株会积累病程相关蛋白,这些蛋白也是抗冻蛋白(AFPs),因为它们能吸附在冰上并抑制其生长。尽管这些双功能抗冻蛋白在植物体内能促进冬季存活,但在体外零下温度储存时会失去活性,因此我们研究了它们在含有氯化钙、氯化镁或氯化钠的溶液中的稳定性。在冷冻前,盐对抗冻活性没有影响,但在氯化钙中冷冻和解冻后抗冻活性降低,添加螯合剂后可恢复。在未冷冻的样品中,钙离子使几丁质酶活性提高了3至5倍,不过在氯化钙中冷冻和解冻后水解活性也降低了。天然聚丙烯酰胺凝胶电泳、圆二色性和色氨酸荧光实验表明,抗冻蛋白在冷冻和解冻后会部分展开,但在氯化钙中它们会折叠得更紧密或聚集。与钙离子结合位点结合的钌红,在没有钙离子的情况下能很容易地使抗冻蛋白染色,但在氯化钙中对冷冻和解冻后的抗冻蛋白染色可见度较低。我们得出结论,抗冻蛋白的结构在冷冻和解冻过程中发生变化,产生了新的钙离子结合位点。一旦钙离子与这些位点结合,抗冻活性、几丁质酶活性和钌红结合都会受到抑制。由于质外体中游离钙离子浓度通常较低,抗冻活性在植物体内可能对冷冻和解冻稳定。如果钙离子浓度因果胶释放或与钙离子结合蛋白相互作用而局部升高,钙离子可能会调节几丁质酶活性。此外,在冷冻储存期间加入螯合剂,抗冻活性在体外可以很容易地保持。