调节性F结构域在肝细胞核因子-4α配体特异性中的作用。

Role of regulatory F-domain in hepatocyte nuclear factor-4alpha ligand specificity.

作者信息

Petrescu Anca D, Hertz Rachel, Bar-Tana Jacob, Schroeder Friedhelm, Kier Ann B

机构信息

Department of Physiology and Pharmacology, Texas A&M University, Texas Veterinary Medical Center, College Station 77843-4467, USA.

出版信息

J Biol Chem. 2005 Apr 29;280(17):16714-27. doi: 10.1074/jbc.M405906200. Epub 2005 Feb 28.

DOI:10.1074/jbc.M405906200

PMID:15741159

Abstract

The F-domain of rat HNF-4alpha1 has a crucial impact on the ligand binding affinity, ligand specificity and secondary structure of HNF-4alpha. (i) Fluorescent binding assays indicate that wild-type, full-length HNF-4alpha (amino acids 1-455) has high affinity (Kd=0.06-12 nm) for long chain fatty acyl-CoAs (LCFA-CoA) and low affinity (Kd=58-296 nm) for unesterified long chain fatty acids (LCFAs). LCFA-CoA binding was due to close molecular interaction as shown by fluorescence resonance energy transfer (FRET) from full-length HNF-4alpha tryptophan (FRET donor) to bound cis-parinaroyl-CoA (FRET acceptor), which yielded an intermolecular distance of 33 A, although no FRET to cis-parinaric acid was detected. (ii) Deleting the N-terminal A-D-domains, comprising the AF1 and DNA binding functions, only slightly affected affinities for LCFA-CoAs (Kd=0.9-4 nm) and LCFAs (Kd=93-581 nm). (iii) Further deletion of the F-domain robustly reduced affinities for LCFA-CoA and reversed ligand specificity (i.e. high affinity for LCFAs (Kd=1.5-32 nm) and low affinity for LCFA-CoAs (Kd=54-302 nm)). No FRET from HNF-4alpha-E (amino acids 132-370) tryptophan (FRET donor) to bound cis-parinaroyl-CoA (FRET acceptor) was detected, whereas an intermolecular distance of 28 A was calculated from FRET between HNF-4alpha-E and cis-parinaric acid. (iv) Circular dichroism showed that LCFA-CoA, but not LCFA, altered the secondary structure of HNF-4alpha only when the F-domain was present. (v) cis-Parinaric acid bound to HNF-4alpha with intact F-domain was readily displaceable by S-hexadecyl-CoA, a nonhydrolyzable thioether analogue of LCFA-CoAs. Truncation of the F-domain significantly decreased cis-parinaric acid displacement. Hence, the C-terminal F-domain of HNF-4alpha regulated ligand affinity, ligand specificity, and ligand-induced conformational change of HNF-4alpha. Thus, characteristics of F-domain-truncated mutants may not reflect the properties of full-length HNF-4alpha.

摘要

大鼠肝细胞核因子4α1（HNF-4α1）的F结构域对HNF-4α的配体结合亲和力、配体特异性和二级结构具有关键影响。（i）荧光结合分析表明，野生型全长HNF-4α（氨基酸1 - 455）对长链脂肪酰辅酶A（LCFA-CoA）具有高亲和力（解离常数Kd = 0.06 - 12纳米），而对未酯化的长链脂肪酸（LCFA）具有低亲和力（Kd = 58 - 296纳米）。LCFA-CoA结合是由于紧密的分子相互作用，如通过从全长HNF-4α色氨酸（荧光共振能量转移供体）到结合的顺式-杷荏酸辅酶A（荧光共振能量转移受体）的荧光共振能量转移（FRET）所示，其产生的分子间距离为33埃，尽管未检测到与顺式-杷荏酸的FRET。（ii）删除包含AF1和DNA结合功能的N端A - D结构域，仅对LCFA-CoA（Kd = 0.9 - 4纳米）和LCFA（Kd = 93 - 581纳米）的亲和力有轻微影响。（iii）进一步删除F结构域会显著降低对LCFA-CoA的亲和力，并逆转配体特异性（即对LCFA具有高亲和力（Kd = 1.5 - 32纳米），对LCFA-CoA具有低亲和力（Kd = 54 - 302纳米））。未检测到从HNF-4α-E（氨基酸132 - 370）色氨酸（荧光共振能量转移供体）到结合的顺式-杷荏酸辅酶A（荧光共振能量转移受体）的FRET，而根据HNF-4α-E与顺式-杷荏酸之间的FRET计算出分子间距离为28埃。（iv）圆二色性表明，只有当F结构域存在时，LCFA-CoA而非LCFA才会改变HNF-4α的二级结构。（v）与具有完整F结构域的HNF-4α结合的顺式-杷荏酸很容易被S-十六烷基辅酶A取代，S-十六烷基辅酶A是LCFA-CoA的一种不可水解的硫醚类似物。F结构域的截短显著降低了顺式-杷荏酸的取代。因此，HNF-4α的C端F结构域调节HNF-4α的配体亲和力、配体特异性和配体诱导的构象变化。因此，F结构域截短突变体的特性可能无法反映全长HNF-4α的特性。

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调节性F结构域在肝细胞核因子-4α配体特异性中的作用。

Role of regulatory F-domain in hepatocyte nuclear factor-4alpha ligand specificity.

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