Wadhwa M S, Collard W T, Adami R C, McKenzie D L, Rice K G
Division of Medicinal Chemistry, College of Pharmacy, University of Michigan, Ann Arbor 48109, USA.
Bioconjug Chem. 1997 Jan-Feb;8(1):81-8. doi: 10.1021/bc960079q.
Cationic peptides possessing a single cysteine, tryptophan, and lysine repeat were synthesized to define the minimal peptide length needed to mediate transient gene expression in mammalian cells. The N-terminal cysteine in each peptide was either alkylated or oxidatively dimerized to produce peptides possessing lysine chains of 3, 6, 8, 13, 16, 18, 26, and 36 residues. Each synthetic peptide was studied for its ability to condense plasmid DNA and compared to polylysine19 and cationic lipids to establish relative in vitro gene transfer efficiency in HepG2 and COS7 cells. Peptides with lysine repeats of 13 or more bound DNA tightly and produced condensates that decreased in mean diameter from 231 to 53 nm as lysine chain length increased. In contrast, peptides possessing 8 or fewer lysine residues were similar to polylysine19, which bound DNA weakly and produced large (0.7-3 microns) DNA condensates. The luciferase expression was elevated 1000-fold after HepG2 cells were transfected with DNA condensates prepared with alkylated Cys-Trp-Lys18 (AlkCWK18) versus polylysine19. The gene transfer efficiencies of AlkCWK18 and cationic lipids were equivalent in HepG2 cells but different by 10-fold in COS 7 cells. A 40-fold reduction in particle size and a 1000-fold amplification in transfection efficiency for AlkCWK18 DNA condensates relative to polylysine19 DNA condensates suggest a contribution from tryptophan that leads to enhanced gene transfer properties for AlkCWK18. Tryptophan-containing cationic peptides result in the formation of small DNA condensates that mediate efficient nonspecific gene transfer in mammalian cells. Due to their low toxicity, these peptides may find utility as carriers for nonspecific gene delivery or may be developed further as low molecular weight DNA condensing agents used in targeted gene delivery systems.
合成了具有单个半胱氨酸、色氨酸和赖氨酸重复序列的阳离子肽,以确定介导哺乳动物细胞中瞬时基因表达所需的最小肽长度。每个肽的N端半胱氨酸要么被烷基化,要么被氧化二聚化,以产生具有3、6、8、13、16、18、26和36个残基的赖氨酸链的肽。研究了每种合成肽凝聚质粒DNA的能力,并与聚赖氨酸19和阳离子脂质进行比较,以确定其在HepG2和COS7细胞中的相对体外基因转移效率。赖氨酸重复序列为13个或更多的肽紧密结合DNA,并产生凝聚物,随着赖氨酸链长度的增加,其平均直径从231纳米减小到53纳米。相比之下,具有8个或更少赖氨酸残基的肽与聚赖氨酸19相似,后者与DNA结合较弱,并产生大的(0.7-3微米)DNA凝聚物。用烷基化的Cys-Trp-Lys18(AlkCWK18)制备的DNA凝聚物转染HepG2细胞后,荧光素酶表达提高了1000倍,而聚赖氨酸19则不然。AlkCWK18和阳离子脂质在HepG2细胞中的基因转移效率相当,但在COS 7细胞中相差10倍。相对于聚赖氨酸19 DNA凝聚物,AlkCWK18 DNA凝聚物的粒径降低了40倍,转染效率提高了1000倍,这表明色氨酸有助于提高AlkCWK18的基因转移特性。含色氨酸的阳离子肽导致形成小的DNA凝聚物,介导哺乳动物细胞中的高效非特异性基因转移。由于其低毒性,这些肽可作为非特异性基因递送的载体,或可进一步开发为用于靶向基因递送系统的低分子量DNA凝聚剂。
