Lambert Millard H, Blackburn R Kevin, Seaton Theresa D, Kassel Daniel B, Kinder Daniel S, Leesnitzer M Anthony, Bickett D Mark, Warner Janet R, Andersen Marc W, Badiang Jennifer G, Cowan David J, Gaul Michael D, Petrov Kimberly G, Rabinowitz Michael H, Wiethe Robert W, Becherer J David, McDougald Darryl L, Musso David L, Andrews Robert C, Moss Marcia L
Department of Computational Chemistry, GlaxoSmithKline Research and Development, 5 Moore Drive, RTP, NC 27709, USA.
Comb Chem High Throughput Screen. 2005 Jun;8(4):327-39. doi: 10.2174/1386207054020840.
We report a systematic analysis of the P1' and P2' substrate specificity of TNF-alpha converting enzyme (TACE) using a peptide library and a novel analytical method, and we use the substrate specificity information to design novel reverse hydroxamate inhibitors. Initial truncation studies, using the amino acid sequence around the cleavage site in precursor-TNF-alpha, showed that good turnover was obtained with the peptide DNP-LAQAVRSS-NH2. Based on this result, 1000 different peptide substrates of the form Biotin-LAQA-P1'-P2'-SSK(DNP)-NH2 were prepared, with 50 different natural and unnatural amino acids at P1' in combination with 20 different amino acids at P2'. The peptides were pooled, treated with purified microsomal TACE, and the reaction mixtures were passed over a streptavidin affinity column to remove unreacted substrate and the N-terminal biotinylated product. C-terminal cleavage products not binding to streptavidin were subjected to liquid chromatography/mass spectrometry analysis where individual products were identified and semiquantitated. 25 of the substrates were resynthesized as discrete peptides and assayed with recombinant TACE. The experiments show that recombinant TACE prefers lipophilic amino acids at the P1' position, such as phenylglycine, homophenylalanine, leucine and valine. At the P2' position, TACE can accommodate basic amino acids, such as arginine and lysine, as well as certain non-basic amino acids such as citrulline, methionine sulfoxide and threonine. These substrate preferences were used in the design of novel reverse hydroxamate TACE inhibitors with phenethyl and 5-methyl-thiophene-methyl side-chains at P1', and threonine and nitro-arginine at P2'.
我们使用肽库和一种新型分析方法,对肿瘤坏死因子-α转换酶(TACE)的P1'和P2'底物特异性进行了系统分析,并利用底物特异性信息设计了新型反向异羟肟酸酯抑制剂。使用前体肿瘤坏死因子-α切割位点周围的氨基酸序列进行的初步截短研究表明,肽DNP-LAQAVRSS-NH2具有良好的周转率。基于此结果,制备了1000种不同形式的肽底物Biotin-LAQA-P1'-P2'-SSK(DNP)-NH2,其中P1'处有50种不同的天然和非天然氨基酸,与P2'处的20种不同氨基酸组合。将这些肽混合,用纯化的微粒体TACE处理,反应混合物通过链霉亲和素亲和柱以去除未反应的底物和N端生物素化产物。不与链霉亲和素结合的C端切割产物进行液相色谱/质谱分析,鉴定并半定量单个产物。将25种底物重新合成为离散肽,并用重组TACE进行测定。实验表明,重组TACE在P1'位置更喜欢亲脂性氨基酸,如苯甘氨酸、高苯丙氨酸、亮氨酸和缬氨酸。在P2'位置,TACE可以容纳碱性氨基酸,如精氨酸和赖氨酸,以及某些非碱性氨基酸,如瓜氨酸、甲硫氨酸亚砜和苏氨酸。这些底物偏好被用于设计新型反向异羟肟酸酯TACE抑制剂,其在P1'处带有苯乙基和5-甲基噻吩甲基侧链,在P2'处带有苏氨酸和硝基精氨酸。
