Abstract
The intracellular environment is known to be a crowded and inhomogeneous space. Such an in vivo environment differs from a well-diluted, homogeneous environment for biochemical reactions. However, the effects of both crowdedness and the inhomogeneity of environment on the behavior of a mobile particle have not yet been investigated sufficiently. As described in this paper, we constructed artificial reaction spaces with fractal models, which are assumed to be non-reactive solid obstacles in a reaction space with crevices that function as operating ranges for mobile particles threading the space. Because of the homogeneity of the structures of artificial reaction spaces, the models succeeded in reproducing the physiological fractal dimension of solid structures with a smaller number of non-reactive obstacles than in the physiological condition. This incomplete compatibility was mitigated when we chose a suitable condition of a perimeter-to-area ratio of the operating range to our model. Our results also show that a simulation space is partitioned into convenient reaction compartments as an in vivo environment with the exact amount of solid structures estimated from TEM images. The characteristics of these compartments engender larger mean square displacement of a mobile particle than that of particles in smaller compartments. Subsequently, the particles start to show confined particle-like behavior. These results are compatible with our previously presented results, which predicted that a physiological environment would produce quick response and slow exhaustion reactions.
Highlights
The intracellular environment is highly crowded with sub-cellular components
Results show that the df values of physiological non-reactive obstacles (NRO) outline and the operating www.frontiersin.org range for a mobile particle were close to particular fractal models: the diffusion limited aggregation (DLA) model and the invasion percolation (IP) model
We found that a cluster–cluster aggregation model (CCA) is a better candidate as a representative model for the physiological environment when we consider the effect of noises or modifications dependent on the variation threshold definition
Summary
The intracellular environment is highly crowded with sub-cellular components. Those organella and polymers can be visualized using electron microscopic techniques. We demonstrated the crowding level and the characteristics of the intracellular environment based on investigation of the fractal dimension (df) of transmission electron microscope (TEM) images (Hiroi et al, 2011a,b). We explained the effect of the in vivo environment to the molecular behaviors following the transformation of the properties of biochemical reaction processes. We showed that if NRO exist as a large, smooth cluster in the reaction space, those NRO do not affect the behavior of a mobile particle in the same way with randomly spread NRO. The total volumes in those two conditions are equal
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