HIV-1整合酶及其抑制剂的研究进展

HIV-1整合酶是由HIV病毒pol基因编码的分子量为32KD的蛋白质,是HIV病毒复制的必需酶之一,它催化病毒DNA整合入宿主染色体DNA。人类细胞中没有HIV 整合酶的类似物[1],理论上抑制整合酶对人体副作用很小。因此HIV-1整合酶成为继HIV-1蛋白酶,逆转录酶后治疗艾滋病的富有吸引力和合理的靶标。本文综述了HIV整合酶结构,抑制剂的研究以及以HIV-1 整和酶为靶点治疗AIDS方法的最新研究进展。     

Broadly distributed nucleophilic reactivity of proteins coordinated with specific ligand binding activity

Covalent nucleophile-electrophile interactions have been established to be important for recognition of substrates by several enzymes. Here, we employed an electrophilic amidino phosphonate ester (EP1) to study the nucleophilic reactivity of the following proteins: albumin, soluble epidermal growth factor receptor (sEGFR), soluble CD4 (sCD4), calmodulin, casein, alpha-lactalbumin, ovalbumin, soybean trypsin inhibitor and HIV-1 gp120. Except for soybean trypsin inhibitor and alpha-lactalbumin, these proteins formed adducts with EP1 that were not dissociated by denaturing treatments. Despite their negligible proteolytic activity, gp120, sEGFR and albumin reacted irreversibly with EP1 at rates comparable to the serine protease trypsin. The neutral counterpart of EP1 reacted marginally with the proteins, indicating the requirement for a positive charge close to the electrophilic group. Prior heating resulted in altered rates of formation of the EP1-protein adducts accompanied by discrete changes in the fluorescence emission spectra of the proteins, suggesting that the three-dimensional protein structure governs the nucleophilic reactivity. sCD4 and vasoactive intestinal peptide (VIP) containing phosphonate groups (EP3 and EP4, respectively) reacted with their cognate high-affinity binding proteins gp120 and calmodulin, respectively, at rates exceeding the corresponding reactions with EP1. Reduced formation of EP3-gp120 adducts and EP4-calmodulin adducts in the presence of sCD4 and VIP devoid of the phosphonate groups was evident, suggesting that the nucleophilic reactivity is expressed in coordination with non-covalent recognition of peptide determinants. These observations suggest the potential of EPs for specific and covalent targeting of proteins, and raise the possibility of nucleophile-electrophile pairing as a novel mechanism stabilizing protein-protein complexes.