TY  - JOUR
A1  - Javanainen, Matti
A1  - Martinez-Seara, Hector
A1  - Metzler, Ralf
A1  - Vattulainen, Ilpo
T1  - Diffusion of Integral Membrane Proteins in Protein-Rich Membranes
JF  - The journal of physical chemistry letters
N2  - The lateral diffusion of embedded proteins along lipid membranes in protein-poor conditions has been successfully described in terms of the Saffman-Delbruck (SD) model, which predicts that the protein diffusion coefficient D is weakly dependent on its radius R as D proportional to ln(1/R). However, instead of being protein-poor, native cell membranes are extremely crowded with proteins. On the basis of extensive molecular simulations, we here demonstrate that protein crowding of the membrane at physiological levels leads to deviations from the SD relation and to the emergence of a stronger Stokes-like dependence D proportional to 1/R. We propose that this 1/R law mainly arises due to geometrical factors: smaller proteins are able to avoid confinement effects much better than their larger counterparts. The results highlight that the lateral dynamics in the crowded setting found in native membranes is radically different from protein-poor conditions and plays a significant role in formation of functional multiprotein complexes.
Y1  - 2017
U6  - https://doi.org/10.1021/acs.jpclett.7b01758
SN  - 1948-7185
VL  - 8
SP  - 4308
EP  - 4313
PB  - American Chemical Society
CY  - Washington
ER  - 
TY  - GEN
A1  - Javanainen, Matti
A1  - Martinez-Seara, Hector
A1  - Metzler, Ralf
A1  - Vattulainen, Ilpo Tapio
T1  - Diffusion of Proteins and Lipids in Protein-Rich Membranesa
T2  - Biophysical journal
Y1  - 2018
U6  - https://doi.org/10.1016/j.bpj.2017.11.3009
SN  - 0006-3495
SN  - 1542-0086
VL  - 114
IS  - 3
SP  - 551A
EP  - 551A
PB  - Cell Press
CY  - Cambridge
ER  - 
TY  - JOUR
A1  - Jeon, Jae-Hyung
A1  - Monne, Hector Martinez-Seara
A1  - Javanainen, Matti
A1  - Metzler, Ralf
T1  - Anomalous diffusion of phospholipids and cholesterols in a lipid bilayer and its origins
JF  - Physical review letters
N2  - Combining extensive molecular dynamics simulations of lipid bilayer systems of varying chemical compositions with single-trajectory analyses, we systematically elucidate the stochastic nature of the lipid motion. We observe subdiffusion over more than 4 orders of magnitude in time, clearly stretching into the submicrosecond domain. The lipid motion depends on the lipid chemistry, the lipid phase, and especially the presence of cholesterol. We demonstrate that fractional Langevin equation motion universally describes the lipid motion in all phases, including the gel phase, and in the presence of cholesterol. The results underline the relevance of anomalous diffusion in lipid bilayers and the strong effects of the membrane composition.
Y1  - 2012
U6  - https://doi.org/10.1103/PhysRevLett.109.188103
SN  - 0031-9007
VL  - 109
IS  - 18
PB  - American Physical Society
CY  - College Park
ER  - 
TY  - JOUR
A1  - Javanainen, Matti
A1  - Hammaren, Henrik
A1  - Monticelli, Luca
A1  - Jeon, Jae-Hyung
A1  - Miettinen, Markus S.
A1  - Martinez-Seara, Hector
A1  - Metzler, Ralf
A1  - Vattulainen, Ilpo
T1  - Anomalous and normal diffusion of proteins and lipids in crowded lipid membranes
JF  - Faraday discussions
N2  - Lateral diffusion plays a crucial role in numerous processes that take place in cell membranes, yet it is quite poorly understood in native membranes characterized by, e.g., domain formation and large concentration of proteins. In this article, we use atomistic and coarse-grained simulations to consider how packing of membranes and crowding with proteins affect the lateral dynamics of lipids and membrane proteins. We find that both packing and protein crowding have a profound effect on lateral diffusion, slowing it down. Anomalous diffusion is observed to be an inherent property in both protein-free and protein-rich membranes, and the time scales of anomalous diffusion and the exponent associated with anomalous diffusion are found to strongly depend on packing and crowding. Crowding with proteins also has a striking effect on the decay rate of dynamical correlations associated with lateral single-particle motion, as the transition from anomalous to normal diffusion is found to take place at macroscopic time scales: while in protein-poor conditions normal diffusion is typically observed in hundreds of nanoseconds, in protein-rich conditions the onset of normal diffusion is tens of microseconds, and in the most crowded systems as large as milliseconds. The computational challenge which results from these time scales is not easy to deal with, not even in coarse-grained simulations. We also briefly discuss the physical limits of protein motion. Our results suggest that protein concentration is anything but constant in the plane of cell membranes. Instead, it is strongly dependent on proteins' preference for aggregation.
Y1  - 2013
U6  - https://doi.org/10.1039/c2fd20085f
SN  - 1359-6640
VL  - 161
IS  - 1
SP  - 397
EP  - 417
PB  - Royal Society of Chemistry
CY  - Cambridge
ER  - 
TY  - JOUR
A1  - Jeon, Jae-Hyung
A1  - Javanainen, Matti
A1  - Martinez-Seara, Hector
A1  - Metzler, Ralf
A1  - Vattulainen, Ilpo
T1  - Protein Crowding in Lipid Bilayers Gives Rise to Non-Gaussian Anomalous Lateral Diffusion of Phospholipids and Proteins
JF  - Physical review : X, Expanding access
N2  - Biomembranes are exceptionally crowded with proteins with typical protein-to-lipid ratios being around 1:50 - 1:100. Protein crowding has a decisive role in lateral membrane dynamics as shown by recent experimental and computational studies that have reported anomalous lateral diffusion of phospholipids and membrane proteins in crowded lipid membranes. Based on extensive simulations and stochastic modeling of the simulated trajectories, we here investigate in detail how increasing crowding by membrane proteins reshapes the stochastic characteristics of the anomalous lateral diffusion in lipid membranes. We observe that correlated Gaussian processes of the fractional Langevin equation type, identified as the stochastic mechanism behind lipid motion in noncrowded bilayer, no longer adequately describe the lipid and protein motion in crowded but otherwise identical membranes. It turns out that protein crowding gives rise to a multifractal, non-Gaussian, and spatiotemporally heterogeneous anomalous lateral diffusion on time scales from nanoseconds to, at least, tens of microseconds. Our investigation strongly suggests that the macromolecular complexity and spatiotemporal membrane heterogeneity in cellular membranes play critical roles in determining the stochastic nature of the lateral diffusion and, consequently, the associated dynamic phenomena within membranes. Clarifying the exact stochastic mechanism for various kinds of biological membranes is an important step towards a quantitative understanding of numerous intramembrane dynamic phenomena.
Y1  - 2016
U6  - https://doi.org/10.1103/PhysRevX.6.021006
SN  - 2160-3308
VL  - 6
PB  - American Physical Society
CY  - College Park
ER  -