Yan Siucheong, Li Fei, Ding Keyang, Sun Hongzhe
Department of Chemistry and Open Laboratory of Chemical Biology, University of Hong Kong, Pokfulam Road, Hong Kong, PR China.
J Biol Inorg Chem. 2003 Jul;8(6):689-97. doi: 10.1007/s00775-003-0468-1. Epub 2003 Jun 21.
Several pentavalent antimony compounds have been used for the treatment of leishmaniasis for decades. However, the mechanism of these antimony drugs still remains unclear. One of their targets is thought to be trypanothione, a major low molecular mass thiol inside the parasite. We show that pentavalent antimony (Sb(V)) can be rapidly reduced to its trivalent state by trypanothione at mildly acidic conditions and 310 K ( k=4.42 M(-1) x min(-1) at pH 6.4), and that Sb(III) can be bound to trypanothione to form an Sb(III)-trypanothione complex. NMR data demonstrate that Sb(III) binds to trypanothione at the two thiolates of the cysteine residues, and that the binding is pH dependent and is strongest at biological pH with a stability constant log K=23.6 at 298 K (0.1 M NaNO(3)). The addition of low molecular monothiol ligands such as glutathione and cysteine to the Sb(III)-trypanothione complex results in the formation of a ternary complex. Thiolates from both trypanothione and monothiol bind to the Sb(III) center. The formation of the ternary complex is important, as the antileishmanial properties of the drugs are probably due to a complex between of Sb(III)-trypanothione and enzymes. Although thermodynamically stable, the complex is kinetically labile and the free and bound forms of thiolates exchange on the (1)H NMR timescale. Such a facile exchange may be crucial for the transport of Sb(III) within parasites.
几十年来,几种五价锑化合物一直用于治疗利什曼病。然而,这些锑药物的作用机制仍不清楚。其作用靶点之一被认为是锥虫硫醇,它是寄生虫体内一种主要的低分子量硫醇。我们发现,在温和酸性条件和310 K下,锥虫硫醇能将五价锑(Sb(V))迅速还原为三价态(在pH 6.4时,k = 4.42 M⁻¹×min⁻¹),并且Sb(III)能与锥虫硫醇结合形成Sb(III)-锥虫硫醇复合物。核磁共振数据表明,Sb(III)在半胱氨酸残基的两个硫醇盐处与锥虫硫醇结合,这种结合依赖于pH值,在生理pH值下最强,在298 K(0.1 M NaNO₃)时稳定常数log K = 23.6。向Sb(III)-锥虫硫醇复合物中添加低分子单硫醇配体如谷胱甘肽和半胱氨酸会导致形成三元复合物。锥虫硫醇和单硫醇的硫醇盐都与Sb(III)中心结合。三元复合物的形成很重要,因为药物的抗利什曼原虫特性可能归因于Sb(III)-锥虫硫醇与酶之间的复合物。尽管该复合物在热力学上稳定,但在动力学上不稳定,硫醇盐的游离形式和结合形式在¹H NMR时间尺度上会发生交换。这种容易的交换可能对Sb(III)在寄生虫体内的运输至关重要。