Hopper Erin D, Pittman Adrianne M C, Fitzgerald Michael C, Tucker Chandra L
Department of Biology and Chemistry, Duke University, Durham, North Carolina 27708, USA.
J Biol Chem. 2008 Nov 7;283(45):30493-502. doi: 10.1074/jbc.M803525200. Epub 2008 Sep 9.
Primary hyperoxaluria type I is a severe kidney stone disease caused by mutations in the protein alanine:glyoxylate aminotransferase (AGT). Many patients have mutations in AGT that are not deleterious alone but act synergistically with a common minor allele polymorphic variant to impair protein folding, dimerization, or localization. Although studies suggest that the minor allele variant itself is destabilized, no direct stability studies have been carried out. In this report, we analyze AGT function and stability using three approaches. First, we describe a yeast complementation growth assay for AGT, in which we show that human AGT can substitute for function of yeast Agx1 and that mutations associated with disease in humans show reduced growth in yeast. The reduced growth of minor allele mutants reflects reduced protein levels, indicating that these proteins are less stable than wild-type AGT in yeast. We further examine stability of AGT alleles in vitro using two direct methods, a mass spectrometry-based technique (stability of unpurified proteins from rates of H/D exchange) and differential scanning fluorimetry. We also examine the effect of known ligands pyridoxal 5'-phosphate and aminooxyacetic acid on stability. Our work establishes that the minor allele is destabilized and that pyridoxal 5'-phosphate and aminooxyacetic acid binding significantly stabilizes both alleles. To our knowledge, this is the first work that directly measures relative stabilities of AGT variants and ligand complexes. Because previous studies suggest that stabilizing compounds (i.e. pharmacological chaperones) may be effective for treatment of primary hyperoxaluria, we propose that the methods described here can be used in high throughput screens for compounds that stabilize AGT mutants.
I型原发性高草酸尿症是一种严重的肾结石疾病,由蛋白质丙氨酸:乙醛酸氨基转移酶(AGT)的突变引起。许多患者的AGT突变单独并不有害,但与常见的次要等位基因多态性变体协同作用,损害蛋白质折叠、二聚化或定位。尽管研究表明次要等位基因变体本身不稳定,但尚未进行直接的稳定性研究。在本报告中,我们使用三种方法分析AGT的功能和稳定性。首先,我们描述了一种用于AGT的酵母互补生长试验,其中我们表明人类AGT可以替代酵母Agx1的功能,并且与人类疾病相关的突变在酵母中的生长减少。次要等位基因突变体生长减少反映了蛋白质水平降低,表明这些蛋白质在酵母中比野生型AGT更不稳定。我们使用两种直接方法进一步在体外检查AGT等位基因的稳定性,一种基于质谱的技术(从H/D交换速率分析未纯化蛋白质的稳定性)和差示扫描荧光法。我们还研究了已知配体磷酸吡哆醛和氨基氧乙酸对稳定性的影响。我们的工作确定次要等位基因不稳定,并且磷酸吡哆醛和氨基氧乙酸结合显著稳定了两个等位基因。据我们所知,这是第一项直接测量AGT变体和配体复合物相对稳定性的工作。因为先前的研究表明稳定化合物(即药理学伴侣)可能对治疗原发性高草酸尿症有效,我们建议这里描述的方法可用于高通量筛选稳定AGT突变体的化合物。