Loucif Remini
@lremini.bsky.social
PostDoc fellow in Biological Physics at the University of Geneva. PhD from University of Montpellier in statistical and computational physics
Thanks to my coauthors; Midas Segers, Andrea Parmeggiani and @ecarlon.bsky.social for this nice collaboration.
April 30, 2025 at 10:56 PM
Thanks to my coauthors; Midas Segers, Andrea Parmeggiani and @ecarlon.bsky.social for this nice collaboration.
Taken together, our results support a scenario where interphase chromatin self-organizes into alternating α/β domains.
This spatial arrangement likely reflects the combined action of passive mechanisms (e.g. bridging interactions) and active loop extrusion processes.
This spatial arrangement likely reflects the combined action of passive mechanisms (e.g. bridging interactions) and active loop extrusion processes.
April 30, 2025 at 10:54 PM
Taken together, our results support a scenario where interphase chromatin self-organizes into alternating α/β domains.
This spatial arrangement likely reflects the combined action of passive mechanisms (e.g. bridging interactions) and active loop extrusion processes.
This spatial arrangement likely reflects the combined action of passive mechanisms (e.g. bridging interactions) and active loop extrusion processes.
This memory effect is due to looped domains which introduce periodic trajectories of the chromatin organization. The auxin treatment of cells inhibes actives processes of loop extrusion due to cohesin which leads to the disorganization of the beta phase and thus of the memory effect.
April 30, 2025 at 10:53 PM
This memory effect is due to looped domains which introduce periodic trajectories of the chromatin organization. The auxin treatment of cells inhibes actives processes of loop extrusion due to cohesin which leads to the disorganization of the beta phase and thus of the memory effect.
We further analyze non-Markovian effects by computing conditional distance distributions and three-point correlations.
These analyses reveal that local chromatin structure influences distal contacts over hundreds of kilobases, with stronger memory effects in WT cells compared to Auxin-treated ones.
These analyses reveal that local chromatin structure influences distal contacts over hundreds of kilobases, with stronger memory effects in WT cells compared to Auxin-treated ones.
April 30, 2025 at 10:48 PM
We further analyze non-Markovian effects by computing conditional distance distributions and three-point correlations.
These analyses reveal that local chromatin structure influences distal contacts over hundreds of kilobases, with stronger memory effects in WT cells compared to Auxin-treated ones.
These analyses reveal that local chromatin structure influences distal contacts over hundreds of kilobases, with stronger memory effects in WT cells compared to Auxin-treated ones.
To interpret the observed scaling and spatial heterogeneity, we introduce a heterogeneous random walk model.
Despite its simplicity, it reproduces key features of the data, including the transition between intra-loop and inter-loop regimes, and the emergent microphase-separated structure
Despite its simplicity, it reproduces key features of the data, including the transition between intra-loop and inter-loop regimes, and the emergent microphase-separated structure
April 30, 2025 at 10:47 PM
To interpret the observed scaling and spatial heterogeneity, we introduce a heterogeneous random walk model.
Despite its simplicity, it reproduces key features of the data, including the transition between intra-loop and inter-loop regimes, and the emergent microphase-separated structure
Despite its simplicity, it reproduces key features of the data, including the transition between intra-loop and inter-loop regimes, and the emergent microphase-separated structure
The α phase is consistent with a crumpled globule, a metastable polymer state which is spatially compact.
The β phase has a weaker exponent, suggesting a looped organization, possibly in the form of rosette-like domains.
This interpretation is supported by experimental data and analytical modeling.
The β phase has a weaker exponent, suggesting a looped organization, possibly in the form of rosette-like domains.
This interpretation is supported by experimental data and analytical modeling.
April 30, 2025 at 10:46 PM
The α phase is consistent with a crumpled globule, a metastable polymer state which is spatially compact.
The β phase has a weaker exponent, suggesting a looped organization, possibly in the form of rosette-like domains.
This interpretation is supported by experimental data and analytical modeling.
The β phase has a weaker exponent, suggesting a looped organization, possibly in the form of rosette-like domains.
This interpretation is supported by experimental data and analytical modeling.
The scaling behavior of these phases is analyzed in detail.
We find consistent results across human and mouse data, with distinct exponents for the α and β phases.
This allows us to characterize different regimes of chromatin folding across multiple levels of genome organization.
We find consistent results across human and mouse data, with distinct exponents for the α and β phases.
This allows us to characterize different regimes of chromatin folding across multiple levels of genome organization.
April 30, 2025 at 10:41 PM
The scaling behavior of these phases is analyzed in detail.
We find consistent results across human and mouse data, with distinct exponents for the α and β phases.
This allows us to characterize different regimes of chromatin folding across multiple levels of genome organization.
We find consistent results across human and mouse data, with distinct exponents for the α and β phases.
This allows us to characterize different regimes of chromatin folding across multiple levels of genome organization.
We focus on the probability distributions of pairwise spatial distances between labeled genomic loci.
These distributions reveal a robust two-component structure, well described by a superposition of Gaussians.
This statistical signature points to the coexistence of two conformations α and β phases
These distributions reveal a robust two-component structure, well described by a superposition of Gaussians.
This statistical signature points to the coexistence of two conformations α and β phases
April 30, 2025 at 10:36 PM
We focus on the probability distributions of pairwise spatial distances between labeled genomic loci.
These distributions reveal a robust two-component structure, well described by a superposition of Gaussians.
This statistical signature points to the coexistence of two conformations α and β phases
These distributions reveal a robust two-component structure, well described by a superposition of Gaussians.
This statistical signature points to the coexistence of two conformations α and β phases
We analyze high-resolution multiplexed FISH (m-FISH) data from human and mouse cells, covering genomic scales from 5 kb to 2 Mb.
This allows us to compare and unify chromatin structural features across species and over a wide range of genomic distances.
This allows us to compare and unify chromatin structural features across species and over a wide range of genomic distances.
April 30, 2025 at 10:34 PM
We analyze high-resolution multiplexed FISH (m-FISH) data from human and mouse cells, covering genomic scales from 5 kb to 2 Mb.
This allows us to compare and unify chromatin structural features across species and over a wide range of genomic distances.
This allows us to compare and unify chromatin structural features across species and over a wide range of genomic distances.
Congratulations @ecarlon.bsky.social !!!
April 28, 2025 at 3:00 PM
Congratulations @ecarlon.bsky.social !!!