Dynamical crossover from motor-dominated to drag-dominated transport in a minimal active transport network
Abstract
Motor-driven intracellular transport is often described in terms of motor activity, but macroscopic transport also depends on how effectively motor-generated force is converted into coherent motion. Motivated by cytoplasmic streaming, a minimal active transport network is examined in which motor-driven transport competes with an effective slip-related dissipative resistance. The model is not intended as a quantitative reconstruction of Nitella cytoplasmic streaming, but as a minimal system for isolating the relation between motor activity, resistance, and transport output. A controlled scan over γSlip and αm, with three independent seeds per condition, shows that increasing γSlip strongly suppresses mean transport speed while leaving the motor-bound fraction nearly unchanged. The mean load and motor force remain finite in the high-γSlip regime, indicating that motors remain mechanically active even when transport is suppressed. The dependence of transport speed on αm progressively disappears with increasing γSlip: the motor dominance ratio decreases from R≈1.69 to R≈1.01, and the corresponding velocity difference decreases from 1.9~μm/s to 0.003~μm/s. These results indicate a dynamical crossover from motor-dominated to drag-dominated transport. The minimal model provides a compact physical scenario in which active force generation persists while its contribution to net transport is suppressed by increased effective dissipative resistance.
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