Cobaleda C, García-Sastre A, Villar E
Departamento de Bioquímica y Biología Molecular, Facultad de Biología, Universidad de Salamanca, Spain.
Biochem J. 1994 Jun 1;300 ( Pt 2)(Pt 2):347-54. doi: 10.1042/bj3000347.
The kinetics of fusion between Newcastle disease virus and erythrocyte ghosts has been investigated with the octadecyl Rhodamine B chloride assay [Hoekstra, De Boer, Klappe, and Wilschut (1984) Biochemistry 23, 5675-5681], and the data from the dequenching curves were fitted by non-linear regression to currently used kinetic models. We used direct computer-assisted fitting of the dequenching curves to the mathematical equations. Discrimination between models was performed by statistical analysis of different fits. The experimental data fit the exponential model previously published [Nir, Klappe, and Hoekstra (1986) Biochemistry 25, 2155-2161] but we describe for the first time that the best fit was achieved for the sum of two exponential terms: A1[1-exp(-k1t)]+A2[1-exp(-k2t)]. The first exponential term represents a fast reaction and the second a slow dequenching reaction. These findings reveal the existence of two independent, but simultaneous, processes during the fusion assay. In order to challenge the model and to understand the meaning of both equation, fusion experiments were carried out under different conditions well known to affect viral fusion (changes in pH, temperature and ghost concentration, and the presence of disulphide-reducing agents or inhibitors of viral neuraminidase activity), and the same computer fitting scheme was followed. The first exponential equation represents the viral protein-dependent fusion process itself, because it is affected by the assay conditions. The second exponential equation accounts for a nonspecific reaction, because it is completely independent of the assay conditions and hence of the viral proteins. An interpretation of this second process is discussed in terms of probe transfer between vesicles.
已使用十八烷基罗丹明B氯化物测定法[Hoekstra、De Boer、Klappe和Wilschut(1984年)《生物化学》23卷,5675 - 5681页]研究了新城疫病毒与红细胞血影之间的融合动力学,来自去淬灭曲线的数据通过非线性回归拟合到当前使用的动力学模型。我们使用计算机直接辅助将去淬灭曲线拟合到数学方程。通过对不同拟合的统计分析来区分模型。实验数据符合先前发表的指数模型[Nir、Klappe和Hoekstra(1986年)《生物化学》25卷,2155 - 2161页],但我们首次描述,对于两个指数项之和:A1[1 - exp(-k1t)] + A2[1 - exp(-k2t)]能实现最佳拟合。第一个指数项代表快速反应,第二个代表缓慢的去淬灭反应。这些发现揭示了在融合测定过程中存在两个独立但同时发生的过程。为了检验该模型并理解两个方程的意义,在已知会影响病毒融合的不同条件下(pH、温度和血影浓度的变化,以及二硫键还原剂或病毒神经氨酸酶活性抑制剂的存在)进行了融合实验,并遵循相同的计算机拟合方案。第一个指数方程代表病毒蛋白依赖性融合过程本身,因为它受测定条件影响。第二个指数方程解释的是一个非特异性反应,因为它完全独立于测定条件,因此也独立于病毒蛋白。本文根据囊泡之间的探针转移对这第二个过程进行了讨论。