Sha R S, Kane C D, Xu Z, Banaszak L J, Bernlohr D A
Department of Biochemistry, Medical School, University of Minnesota, St. Paul 55108.
J Biol Chem. 1993 Apr 15;268(11):7885-92.
The crystal structure of the adipocyte lipid-binding protein (ALBP) with coordinated fatty acid shows the hydrophobic ligand bound within a water-filled central cavity with its carboxyl group engaged in a hydrogen bonding network involving, at least in part, the functional groups of residues R126 and Y128. We produced mutant forms of ALBP which altered these amino acids, expressed these in Escherichia coli as glutathione S-transferase (GST) fusion proteins, and examined their ligand-binding properties using the fluorescent fatty acids cis-parinaric acid (c-PA) and 12-(9-anthroyloxy)-oleate (12-AO). The wild-type and all mutated forms of GST-ALBP displayed similar binding affinities for 12-AO, with Kd,app values ranging from 0.5 to 2.4 microM. The binding affinity of ALBP forms R126Q and Y128W for c-PA were reduced about 30-50-fold in comparison to GST-ALBP, while that for the double mutation R126L + Y128F was below the limits of detection. To determine if the hydrogen bonding system functioned in situ, Chinese hamster ovary (CHO) cell transfectants expressing wild-type ALBP demonstrated a moderate (1.5-2-fold) increase in the total rate of [3H]oleate uptake and trafficking into the esterified lipid pools over that of untransfected cells, while the rate of [3H]oleate uptake of the transfected CHOs expressing the R126L + Y128F mutation was identical to that of the control CHOs. In summary, these results suggest that the primary factor contributing to binding affinity of ALBP for fatty acids such as c-PA or oleic acid both in vitro and in situ is the hydrogen bonding network involving at least R126, Y128, and the lipid carboxyl group. However, a ligand with sufficiently large hydrophobic character such as 12-AO can bind in the absence of a functional carboxylate hydrogen bonding network, presumably due to stabilizing entropic interactions with other cavity atoms.
脂肪细胞脂质结合蛋白(ALBP)与配位脂肪酸的晶体结构显示,疏水配体结合在充满水的中央腔内,其羧基参与了一个氢键网络,该网络至少部分涉及残基R126和Y128的官能团。我们制备了改变这些氨基酸的ALBP突变形式,将其作为谷胱甘肽S-转移酶(GST)融合蛋白在大肠杆菌中表达,并使用荧光脂肪酸顺式-十八碳四烯酸(c-PA)和12-(9-蒽氧基)-油酸酯(12-AO)检测它们的配体结合特性。GST-ALBP的野生型和所有突变形式对12-AO表现出相似的结合亲和力,表观解离常数(Kd,app)值范围为0.5至2.4 microM。与GST-ALBP相比,ALBP的R126Q和Y128W形式对c-PA的结合亲和力降低了约30至50倍,而双突变R126L + Y128F的结合亲和力低于检测限。为了确定氢键系统在原位是否起作用,表达野生型ALBP的中国仓鼠卵巢(CHO)细胞转染子显示,与未转染细胞相比,[3H]油酸摄取和转运到酯化脂质池中的总速率适度增加(1.5至2倍),而表达R126L + Y128F突变的转染CHO细胞的[3H]油酸摄取速率与对照CHO细胞相同。总之,这些结果表明,在体外和原位,导致ALBP对c-PA或油酸等脂肪酸结合亲和力的主要因素是至少涉及R126、Y128和脂质羧基的氢键网络。然而,具有足够大疏水特性的配体,如12-AO,在没有功能性羧酸盐氢键网络的情况下也能结合,推测是由于与其他腔原子的稳定熵相互作用。
