Marchand Alexandre, Winther Anne-Marie Lund, Holm Peter Joakim, Olesen Claus, Montigny Cedric, Arnou Bertrand, Champeil Philippe, Clausen Johannes D, Vilsen Bente, Andersen Jens Peter, Nissen Poul, Jaxel Christine, Møller Jesper Vuust, le Maire Marc
Commissariat à l'Energie Atomique (CEA), Institut de Biologie et de Technologies de Saclay, SBSM, URA CNRS 2096, Laboratoire de Recherche Associé, 17V University of Paris-Sud, Gif sur Yvette, France.
J Biol Chem. 2008 May 23;283(21):14867-82. doi: 10.1074/jbc.M710165200. Epub 2008 Mar 20.
In recent years crystal structures of the sarcoplasmic reticulum Ca(2+)-ATPase (SERCA1a), stabilized in various conformations with nucleotide and phosphate analogs, have been obtained. However, structural analysis of mutant forms would also be valuable to address key mechanistic aspects. We have worked out a procedure for affinity purification of SERCA1a heterologously expressed in yeast cells, producing sufficient amounts for crystallization and biophysical studies. We present here the crystal structures of two mutant forms, D351A and P312A, to address the issue whether the profound functional changes seen for these mutants are caused by major structural changes. We find that the structure of P312A with ADP and AlF(4)(-) bound (3.5-A resolution) and D351A with AMPPCP or ATP bound (3.4- and 3.7-A resolution, respectively) deviate only slightly from the complexes formed with that of wild-type ATPase. ATP affinity of the D351A mutant was very high, whereas the affinity for cytosolic Ca(2+) was similar to that of the wild type. We conclude from an analysis of data that the extraordinary affinity of the D351A mutant for ATP is caused by the electrostatic effects of charge removal and not by a conformational change. P312A exhibits a profound slowing of the Ca(2+)-translocating Ca(2)E1P-->E2P transition, which seems to be due to a stabilization of Ca(2)E1P rather than a destabilization of E2P. This can be accounted for by the strain that the Pro residue induces in the straight M4 helix of the wild type, which is removed upon the replacement of Pro(312) with alanine in P312A.
近年来,已获得用核苷酸和磷酸盐类似物稳定在各种构象的肌浆网Ca(2+)-ATP酶(SERCA1a)的晶体结构。然而,对突变体形式进行结构分析对于解决关键的机制问题也将是有价值的。我们已经制定出一种程序,用于亲和纯化在酵母细胞中异源表达的SERCA1a,从而获得足以用于结晶和生物物理研究的量。我们在此展示两种突变体形式D351A和P312A的晶体结构,以解决这些突变体所观察到的深刻功能变化是否由主要结构变化引起的问题。我们发现,结合ADP和AlF(4)(-)的P312A(分辨率为3.5埃)以及结合AMPPCP或ATP的D351A(分辨率分别为3.4埃和3.7埃)的结构与野生型ATP酶形成的复合物仅有轻微偏差。D351A突变体对ATP的亲和力非常高,而对胞质Ca(2+)的亲和力与野生型相似。我们通过数据分析得出结论,D351A突变体对ATP的非凡亲和力是由电荷去除的静电效应引起的,而非构象变化。P312A表现出Ca(2+)转运的Ca(2)E1P→E2P转变显著减慢,这似乎是由于Ca(2)E1P的稳定而非E2P的不稳定。这可以通过脯氨酸残基在野生型笔直的M4螺旋中诱导的张力来解释,在P312A中用丙氨酸取代Pro(312)后这种张力消除。
