Your search keyword '"Meindlhumer, S. (author)"' showing total 4 results

1. Directing Min protein patterns with advective bulk flow

Author

Meindlhumer, S. (author), Brauns, Fridtjof (author), Finžgar, Jernej Rudi (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Frey, Erwin (author), Meindlhumer, S. (author), Brauns, Fridtjof (author), Finžgar, Jernej Rudi (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), and Frey, Erwin (author)

Abstract

The Min proteins constitute the best-studied model system for pattern formation in cell biology. We theoretically predict and experimentally show that the propagation direction of in vitro Min protein patterns can be controlled by a hydrodynamic flow of the bulk solution. We find downstream propagation of Min wave patterns for low MinE:MinD concentration ratios, upstream propagation for large ratios, but multistability of both propagation directions in between. Whereas downstream propagation can be described by a minimal model that disregards MinE conformational switching, upstream propagation can be reproduced by a reduced switch model, where increased MinD bulk concentrations on the upstream side promote protein attachment. Our study demonstrates that a differential flow, where bulk flow advects protein concentrations in the bulk, but not on the surface, can control surface-pattern propagation. This suggests that flow can be used to probe molecular features and to constrain mathematical models for pattern-forming systems., BN/Cees Dekker Lab

Published

2023

2. Dynamin A as a one-component division machinery for synthetic cells

Author

De Franceschi, N. (author), Barth, R. (author), Meindlhumer, S. (author), Fragasso, A. (author), Dekker, C. (author), De Franceschi, N. (author), Barth, R. (author), Meindlhumer, S. (author), Fragasso, A. (author), and Dekker, C. (author)

Abstract

Membrane abscission, the final cut of the last connection between emerging daughter cells, is an indispensable event in the last stage of cell division and in other cellular processes such as endocytosis, virus release or bacterial sporulation. However, its mechanism remains poorly understood, impeding its application as a cell-division machinery for synthetic cells. Here we use fluorescence microscopy and fluorescence recovery after photobleaching measurements to study the in vitro reconstitution of the bacterial protein dynamin A inside liposomes. Upon external reshaping of the liposomes into dumbbells, dynamin A self-assembles at the membrane neck, resulting in membrane hemi-scission and even full scission. Dynamin A proteins constitute a simple one-component division machinery capable of splitting dumbbell-shaped liposomes, marking an important step towards building a synthetic cell., Green Open Access added to TU Delft Institutional Repository 'You share, we take care!' - Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public., BN/Cees Dekker Lab

Published

2023

3. Quantitative analysis of surface wave patterns of Min proteins

Author

Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), and Dekker, C. (author)

Abstract

The Min protein system is arguably the best-studied model system for biological pattern formation. It exhibits pole-to-pole oscillations in E. coli bacteria as well as a variety of surface wave patterns in in vitro reconstitutions. Such Min surface wave patterns pose particular challenges to quantification as they are typically only semi-periodic and non-stationary. Here, we present a methodology for quantitatively analysing such Min patterns, aiming for reproducibility, user-independence, and easy usage. After introducing pattern-feature definitions and image-processing concepts, we present an analysis pipeline where we use autocorrelation analysis to extract global parameters such as the average spatial wavelength and oscillation period. Subsequently, we describe a method that uses flow-field analysis to extract local properties such as the wave propagation velocity. We provide descriptions on how to practically implement these quantification tools and provide Python code that can directly be used to perform analysis of Min patterns., BN/Cees Dekker Lab

Published

2022

4. Quantitative analysis of surface wave patterns of Min proteins

Author

Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), and Dekker, C. (author)

Abstract

The Min protein system is arguably the best-studied model system for biological pattern formation. It exhibits pole-to-pole oscillations in E. coli bacteria as well as a variety of surface wave patterns in in vitro reconstitutions. Such Min surface wave patterns pose particular challenges to quantification as they are typically only semi-periodic and non-stationary. Here, we present a methodology for quantitatively analysing such Min patterns, aiming for reproducibility, user-independence, and easy usage. After introducing pattern-feature definitions and image-processing concepts, we present an analysis pipeline where we use autocorrelation analysis to extract global parameters such as the average spatial wavelength and oscillation period. Subsequently, we describe a method that uses flow-field analysis to extract local properties such as the wave propagation velocity. We provide descriptions on how to practically implement these quantification tools and provide Python code that can directly be used to perform analysis of Min patterns., BN/Cees Dekker Lab

Published

2022