William L Zeile, Fangliang Zhang, Richard B Dickinson, Daniel L Purich
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引用次数: 31
摘要
单核增生李斯特菌在肌动蛋白为基础的运动过程中形成右手螺旋火箭尾轨迹,这一立体化学特征与actitoclampin的亲和调节,夹丝伸长模型一致[Dickinson and Purich, 2002: biophystj . 82:605-617]。在这种机制中,右旋扭矩是由末端跟踪分子马达产生的,每个马达都由一个丝的倒钩端和夹紧蛋白组成,这些蛋白会不断地跟踪其丝伴侣的右旋螺旋。相比之下,扭矩不是那些模型(例如,弹性推进,弹性布朗棘轮,系绳棘轮和插入聚合模型)的预测属性,要求在每个单体添加步骤期间/之后长丝倒钩端离开/脱离运动物体的表面。螺旋轨迹也解释了为什么李斯特菌在与李斯特菌火箭尾部的螺旋周期性相匹配的长度尺度上经历纵轴旋转。
Listeria's right-handed helical rocket-tail trajectories: mechanistic implications for force generation in actin-based motility.
Listeria monocytogenes forms right-handed helical rocket tail trajectories during actin-based motility in cell-free extracts, and this stereochemical feature is consistent with actoclampin's affinity-modulated, clamped-filament elongation model [Dickinson and Purich, 2002: Biophys J 82:605-617]. In that mechanism, right-handed torque is generated by an end-tracking molecular motor, each comprised of a filament barbed end and clamping protein that processively traces the right-handed helix of its filament partner. By contrast, torque is not a predicted property of those models (e.g., elastic propulsion, elastic Brownian ratchet, tethered ratchet, and insertional polymerization models) requiring filament barbed ends to depart/detach from the motile object's surface during/after each monomer-addition step. Helical trajectories also explain why Listeria undergoes longitudinal-axis rotation on a length-scale matching the helical periodicity of Listeria's rocket tails.
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