Department of Molecular Microbiology and Immunology, Oregon Health Sciences University, 3181 SW Sam Jackson Park Road, Portland, Oregon 97239, USA.
Virology. 2013 Dec;447(1-2):95-103. doi: 10.1016/j.virol.2013.08.023. Epub 2013 Sep 21.
During HIV-1 morphogenesis, the precursor Gag protein is processed to release capsid (CA) proteins that form the mature virus core. In this process, the CA proteins assemble a lattice in which N-terminal domain (NTD) helices 1-3 are critical for multimer formation. Mature core assembly requires refolding of the N-terminus of CA into a β-hairpin, but the precise contribution of the hairpin core morphogenesis is unclear. We found that mutations at isoleucine 15 (I15), between the β-hairpin and NTD helix 1 are incompatible with proper mature core assembly. However, a compensatory mutation of histidine 12 in the β-hairpin to a tyrosine was selected by long term passage of an I15 mutant virus in T cells. The tyrosine does not interact directly with residue 15, but with NTD helix 3, supporting a model in which β-hairpin folding serves to align helix 3 for mature NTD multimerization.
在 HIV-1 形态发生过程中,前体 Gag 蛋白被加工释放衣壳 (CA) 蛋白,形成成熟病毒核心。在这个过程中,CA 蛋白组装成晶格,其中 N 端结构域 (NTD) 螺旋 1-3 对于多聚体形成至关重要。成熟核心组装需要 CA 的 N 端重新折叠成 β-发夹,但β-发夹核心形态发生的确切贡献尚不清楚。我们发现,位于 β-发夹和 NTD 螺旋 1 之间的异亮氨酸 15 (I15) 的突变与适当的成熟核心组装不兼容。然而,通过在 T 细胞中对 I15 突变病毒进行长期传代,β-发夹中的组氨酸 12 突变为酪氨酸被选择。酪氨酸不会直接与残基 15 相互作用,而是与 NTD 螺旋 3 相互作用,支持β-发夹折叠用于成熟 NTD 多聚化的模型。