Filtern
Erscheinungsjahr
Dokumenttyp
- Wissenschaftlicher Artikel (212)
- Preprint (9)
- Postprint (8)
- Monographie/Sammelband (4)
- Sonstiges (1)
Schlagworte
- Amazon rainforest (2)
- Complex networks (2)
- channel (2)
- complex networks (2)
- diffusion (2)
- droughts (2)
- prediction (2)
- space-dependent diffusivity (2)
- 3D medical image analysis (1)
- African climate (1)
- Chaotic System (1)
- Escherichia-coli (1)
- Event synchronization (1)
- Extreme precipitation (1)
- Hypothesis Test (1)
- India (1)
- Indian summer monsoon (1)
- Partial wavelet coherence (1)
- Phase Synchronization (1)
- Planetary Rings (1)
- Plio-Pleistocene (1)
- Rainfall patterns (1)
- Statistical and Nonlinear Physics (1)
- Surrogate Data (1)
- Synchronization (1)
- Teleconnection patterns (1)
- Time-varying Delay (1)
- Wavelets (1)
- algorithms (1)
- anatomical connectivity (1)
- bifurcation analysis (1)
- bifurcations (1)
- climate-driven evolution (1)
- cluster-analysis (1)
- complex systems (1)
- cortical network (1)
- dynamical cluster (1)
- dynamical transitions (1)
- functional connectivity (1)
- high-frequency force (1)
- inference (1)
- intermittency (1)
- low-frequency force (1)
- mean residence time (1)
- models (1)
- mutual information (1)
- noise (1)
- nonlinear dynamics (1)
- nonlinear time series analysis (1)
- pQCT (1)
- patient immobilization (1)
- period doubling (1)
- proteasome (1)
- protein translocation (1)
- ratchets (1)
- recognition (1)
- recurrence plot (1)
- series (1)
- statistical physics (1)
- stochastic process (1)
- stochastic resonance (1)
- synchronization (1)
- topological community (1)
- trabecular bone (1)
- unferring cellular networks (1)
- variables (1)
- vibrational resonance (1)
- Æ Recurrence Plots (1)
Institut
- Institut für Physik und Astronomie (234) (entfernen)
This paper discusses translocation features of the 20S proteasome in order to explain typical proteasome length distributions. We assume that the protein transport depends significantly on the fragment length with some optimal length which is transported most efficiently. By means of a simple one-channel model, we show that this hypothesis can explain both the one- and the three-peak length distributions found in experiments. A possible mechanism of such translocation is provided by so-called fluctuation-driven transport.