Cobos Eva S, Pisabarro M Teresa, Vega M Cristina, Lacroix Emmanuel, Serrano Luis, Ruiz-Sanz Javier, Martinez Jose C
Department of Physical Chemistry and Institute of Biotechnology, Faculty of Sciences, University of Granada, 18071, Spain.
J Mol Biol. 2004 Sep 3;342(1):355-65. doi: 10.1016/j.jmb.2004.06.078.
SH3 domains are molecular-recognition modules that function by interacting with proteins containing sequences in polyproline II (PPII) conformation. The main limitation in designing short-ligand peptides to interact with these domains is the preservation of this helical arrangement, for which a high content of proline is needed. We have overcome this limitation by using a protein scaffold provided by the avian pancreatic polypeptide (APP), a natural hormone of 36 amino acid residues. The APP protein contains a PPII stretch packed against an alpha-helix. We have designed a structure in which some residues of the APP PPII helix are replaced by a sequence motif, named RP1, which interacts with the SH3 domain of the Abelson tyrosine kinase (Abl-SH3). This design, which we call APP-RP1, is folded and, as shown by circular dichroism, has a structural content similar to that of natural APP (APP-WT). The stability of both miniproteins has been compared by unfolding experiments; the designed APP-RP1 is almost 20 deg. C more stable than the wild-type and has a higher Gibbs energy function. This increase in stability has an entropic origin. Isothermal titration calorimetry and fluorescence spectroscopy show that the thermodynamics of the binding of the APP-RP1 molecule to Abl-SH3 is comparable to that of the shorter RP1 peptide. Furthermore, the mutation by Tyr of two proline residues in APP-RP1, which are essential for the binding of some linear peptides to Abl-SH3, demonstrates the effectiveness of the scaffold in enhancing the variability in the design of high-affinity and high-specificity ligands for any SH3 domain. The application of this strategy may help in the design of ligands for other polyproline-recognition domains such as WW, PX or EVH1, and even for the in vivo application of these miniproteins.
SH3结构域是一种分子识别模块,其功能是通过与含有多聚脯氨酸II(PPII)构象序列的蛋白质相互作用来实现的。设计与这些结构域相互作用的短配体肽的主要限制在于保持这种螺旋排列,而这需要高含量的脯氨酸。我们通过使用禽胰多肽(APP)提供的蛋白质支架克服了这一限制,APP是一种由36个氨基酸残基组成的天然激素。APP蛋白包含一个与α螺旋紧密堆积的PPII片段。我们设计了一种结构,其中APP的PPII螺旋的一些残基被一个名为RP1的序列基序取代,该基序与阿贝尔森酪氨酸激酶(Abl-SH3)的SH3结构域相互作用。我们将这种设计称为APP-RP1,它能够折叠,并且如圆二色性所示,其结构含量与天然APP(APP-WT)相似。通过展开实验比较了两种微型蛋白质的稳定性;设计的APP-RP1比野生型稳定近20℃,并且具有更高的吉布斯能量函数。这种稳定性的增加源于熵。等温滴定量热法和荧光光谱表明,APP-RP1分子与Abl-SH3结合的热力学与较短的RP1肽相当。此外,将APP-RP1中对一些线性肽与Abl-SH3结合至关重要的两个脯氨酸残基突变为酪氨酸,证明了该支架在增强针对任何SH3结构域的高亲和力和高特异性配体设计中的变异性方面的有效性。这种策略的应用可能有助于设计针对其他多聚脯氨酸识别结构域(如WW、PX或EVH1)的配体,甚至有助于这些微型蛋白质的体内应用。
