Klotzsch Enrico, Smith Michael L, Kubow Kristopher E, Muntwyler Simon, Little William C, Beyeler Felix, Gourdon Delphine, Nelson Bradley J, Vogel Viola
Department of Materials, Eidgenössische Technische Hochschule Zurich, CH-8093 Zürich, Switzerland.
Proc Natl Acad Sci U S A. 2009 Oct 27;106(43):18267-72. doi: 10.1073/pnas.0907518106. Epub 2009 Oct 13.
Rather than maximizing toughness, as needed for silk and muscle titin fibers to withstand external impact, the much softer extracellular matrix fibers made from fibronectin (Fn) can be stretched by cell generated forces and display extraordinary extensibility. We show that Fn fibers can be extended more than 8-fold (>700% strain) before 50% of the fibers break. The Young's modulus of single fibers, given by the highly nonlinear slope of the stress-strain curve, changes orders of magnitude, up to MPa. Although many other materials plastically deform before they rupture, evidence is provided that the reversible breakage of force-bearing backbone hydrogen bonds enables the large strain. When tension is released, the nano-sized Fn domains first contract in the crowded environment of fibers within seconds into random coil conformations (molten globule states), before the force-bearing hydrogen bond networks that stabilize the domain's secondary structures are reestablished within minutes (double exponential). The exposure of cryptic binding sites on Fn type III modules increases steeply upon stretching. Thus fiber extension steadily up-regulates fiber rigidity and cryptic epitope exposure, both of which are known to differentially alter cell behavior. Finally, since stress-strain relationships cannot directly be measured in native extracellular matrix (ECM), the stress-strain curves were correlated with stretch-induced alterations of intramolecular fluorescence resonance energy transfer (FRET) obtained from trace amounts of Fn probes (mechanical strain sensors) that can be incorporated into native ECM. Physiological implications of the extraordinary extensibility of Fn fibers and contraction kinetics are discussed.
与丝绸和肌肉肌联蛋白纤维承受外部冲击所需的最大化韧性不同,由纤连蛋白(Fn)制成的软得多的细胞外基质纤维可以被细胞产生的力拉伸,并表现出非凡的延展性。我们表明,在50%的纤维断裂之前,Fn纤维可以延伸超过8倍(>700%应变)。单根纤维的杨氏模量由应力-应变曲线的高度非线性斜率给出,变化几个数量级,高达兆帕。尽管许多其他材料在破裂前会发生塑性变形,但有证据表明,承载力的主链氢键的可逆断裂使得能够产生大应变。当张力释放时,纳米级的Fn结构域首先在几秒钟内在纤维的拥挤环境中收缩成无规卷曲构象(熔球状态),然后在几分钟内(双指数)重新建立稳定结构域二级结构的承载氢键网络。Fn III型模块上隐蔽结合位点的暴露在拉伸时急剧增加。因此,纤维延伸会稳定地上调纤维刚性和隐蔽表位暴露,这两者都已知会不同程度地改变细胞行为。最后,由于无法直接在天然细胞外基质(ECM)中测量应力-应变关系,因此将应力-应变曲线与从可掺入天然ECM的痕量Fn探针(机械应变传感器)获得的拉伸诱导的分子内荧光共振能量转移(FRET)变化相关联。讨论了Fn纤维非凡延展性和收缩动力学的生理意义。