Endres Dan, Miyahara Masaki, Moisant Paul, Zlotnick Adam
Department of Mathematics and Statistics, University of Central Oklahoma, Edmond 73034, USA.
Protein Sci. 2005 Jun;14(6):1518-25. doi: 10.1110/ps.041314405.
The capsids of spherical viruses may contain from tens to hundreds of copies of the capsid protein(s). Despite their complexity, these particles assemble rapidly and with high fidelity. Subunit and capsid represent unique end states. However, the number of intermediate states in these reactions can be enormous-a situation analogous to the protein folding problem. Approaches to accurately model capsid assembly are still in their infancy. In this paper, we describe a sail-shaped reaction landscape, defined by the number of subunits in each species, the predicted prevalence of each species, and species stability. Prevalence can be calculated from the probability of synthesis of a given intermediate and correlates well with the appearance of intermediates in kinetics simulations. In these landscapes, we find that only those intermediates along the leading edge make a significant contribution to assembly. Although the total number of intermediates grows exponentially with capsid size, the number of leading-edge intermediates grows at a much slower rate. This result suggests that only a minute fraction of intermediates needs to be considered when describing capsid assembly.
球形病毒的衣壳可能包含数十到数百个衣壳蛋白拷贝。尽管结构复杂,但这些颗粒能快速且高度精确地组装。亚基和衣壳代表独特的终态。然而,这些反应中的中间态数量可能极为庞大——这一情况类似于蛋白质折叠问题。准确模拟衣壳组装的方法仍处于起步阶段。在本文中,我们描述了一种帆状反应景观,由每个物种中的亚基数量、每个物种的预测丰度以及物种稳定性定义。丰度可根据给定中间体的合成概率计算得出,并且与动力学模拟中中间体的出现情况密切相关。在这些景观中,我们发现只有前沿的那些中间体对组装有显著贡献。尽管中间体的总数随衣壳大小呈指数增长,但前沿中间体的数量增长速度要慢得多。这一结果表明,在描述衣壳组装时只需考虑极小一部分中间体。