Materials Research Laboratory, University of California, Santa Barbara, California 93106, United States.
J Am Chem Soc. 2013 Jan 9;135(1):377-83. doi: 10.1021/ja309590f. Epub 2012 Dec 18.
Dopa (3,4-dihydroxyphenylalanine) is recognized as a key chemical signature of mussel adhesion and has been adopted into diverse synthetic polymer systems. Dopa's notorious susceptibility to oxidation, however, poses significant challenges to the practical translation of mussel adhesion. Using a surface forces apparatus to investigate the adhesion of mussel foot protein 3 (Mfp3) "slow", a hydrophobic protein variant of the Mfp3 family in the plaque, we have discovered a subtle molecular strategy correlated with hydrophobicity that appears to compensate for Dopa instability. At pH 3, where Dopa is stable, Mfp3 slow, like Mfp3 "fast" adhesion to mica, is directly proportional to the mol % of Dopa present in the protein. At pH of 5.5 and 7.5, however, loss of adhesion in Mfp3 slow was less than half that occurring in Mfp3 fast, purportedly because Dopa in Mfp3 slow is less prone to oxidation. Indeed, cyclic voltammetry showed that the oxidation potential of Dopa in Mfp3 slow is significantly higher than in Mfp3 fast at pH of 7.5. A much greater difference between the two variants was revealed in the interaction energy of two symmetric Mfp3 slow films (E(ad) = -3 mJ/m(2)). This energy corresponds to the energy of protein cohesion which is notable for its reversibility and pH independence. Exploitation of aromatic hydrophobic sequences to protect Dopa against oxidation as well as to mediate hydrophobic and H-bonding interactions between proteins provides new insights for developing effective artificial underwater adhesives.
多巴(3,4-二羟基苯丙氨酸)被认为是贻贝黏附的关键化学特征,并已被应用于各种合成聚合物体系。然而,多巴极易氧化,这给贻贝黏附的实际转化带来了重大挑战。我们使用表面力仪研究了贻贝足蛋白 3(Mfp3)“慢”的黏附,这是斑块中 Mfp3 家族的一种疏水性蛋白变体,我们发现了一种与疏水性相关的微妙分子策略,似乎可以弥补多巴的不稳定性。在 pH 值为 3 时,多巴稳定,Mfp3 slow 与 Mfp3“快”黏附云母一样,与蛋白质中多巴的摩尔百分比成正比。然而,在 pH 值为 5.5 和 7.5 时,Mfp3 slow 的黏附损失不到 Mfp3 fast 的一半,据称这是因为 Mfp3 slow 中的多巴不易氧化。事实上,循环伏安法表明,在 pH 值为 7.5 时,Mfp3 slow 中多巴的氧化电位明显高于 Mfp3 fast。在两种变体之间的相互作用能的差异更大(E(ad) = -3 mJ/m(2))。这种能量对应于蛋白质内聚能,其显著特点是可逆性和 pH 独立性。利用芳香族疏水性序列来保护多巴免受氧化,以及介导蛋白质之间的疏水性和氢键相互作用,为开发有效的人工水下粘合剂提供了新的见解。