Engelhard M, Evans P A
Department of Biochemistry, University of Cambridge, United Kingdom.
Protein Sci. 1995 Aug;4(8):1553-62. doi: 10.1002/pro.5560040813.
Interaction with 8-anilino-1-naphthalenesulfonate (ANS) is widely used to detect molten globule states of proteins. We have found that even with stable partially folded states, the development of the fluorescence enhancements resulting from such interactions can be relatively slow and kinetically complex. This is probably because initial binding of the dye can induce subsequent changes in the protein structure, so that the ultimate resulting fluorescence enhancement is not necessarily a good, nonperturbing probe of the preexisting state of the protein. When ANS is used to study folding mechanisms the problem is compounded by the difficulty of distinguishing effects due to the development of dye interactions from those due to the changing populations of folding intermediates. Many of these complications can be avoided by experiments where the ANS is introduced only after folding has been allowed to proceed for a variable time. The initial fluorescence intensity after mixing, resulting only from rapid and therefore hopefully relatively nonperturbing interactions with the protein, can be monitored at different refolding times to provide a better reflection of the progress of the reaction, uncomplicated by dye interaction effects. Such studies of the folding of carbonic anhydrase and alpha-lactalbumin have been compared with conventional single-mix experiments and large discrepancies observed. When ANS was present throughout refolding, time-dependent changes attributed to the formation or reorganization of protein-ANS complexes were clearly superimposed on those associated with the actual progress of refolding, and the folding kinetics and population of intermediates were also substantially perturbed by the dye. Thus, it is clear that the pulse method, though cumbersome, should be used where refolding reactions are to be probed by dye binding. The results emphasize that fluorescence enhancement tends to be greatest in early intermediates, in contrast to what, for carbonic anhydrase at least, might appear to be the case from the more conventional experiments. Later intermediates in the folding of both of these proteins actually induce little fluorescence enhancement and therefore may be quite different in nature from equilibrium molten globule states.
与8-苯胺基-1-萘磺酸盐(ANS)的相互作用被广泛用于检测蛋白质的熔球态。我们发现,即使是处于稳定的部分折叠状态,这种相互作用导致的荧光增强的发展可能相对较慢且动力学复杂。这可能是因为染料的初始结合会诱导蛋白质结构的后续变化,以至于最终产生的荧光增强不一定是蛋白质先前状态的良好、无干扰的探针。当使用ANS研究折叠机制时,由于难以区分染料相互作用发展产生的影响与折叠中间体数量变化产生的影响,问题变得更加复杂。通过仅在折叠进行了可变时间后才引入ANS的实验,可以避免许多这些复杂情况。混合后的初始荧光强度仅由与蛋白质的快速且因此有望相对无干扰的相互作用产生,可以在不同的复性时间进行监测,以更好地反映反应进程,而不受染料相互作用影响的干扰。对碳酸酐酶和α-乳白蛋白折叠的此类研究已与传统的单混合实验进行了比较,并观察到了较大差异。当在整个复性过程中都存在ANS时,归因于蛋白质-ANS复合物形成或重组的时间依赖性变化明显叠加在与实际复性进程相关的变化之上,并且折叠动力学和中间体数量也受到染料的显著干扰。因此,很明显,脉冲法虽然繁琐,但在通过染料结合探测复性反应时应该使用。结果强调,与至少对于碳酸酐酶而言,从更传统的实验可能看起来的情况相反,荧光增强在早期中间体中往往最大。这两种蛋白质折叠过程中的后期中间体实际上诱导的荧光增强很小,因此其性质可能与平衡熔球态有很大不同。