Abstract
Genomes are spatially assembled into chromosome territories (CT) within the nucleus of living cells. Recent evidences have suggested associations between three-dimensional organization of CTs and the active gene clusters within neighboring CTs. These gene clusters are part of signaling networks sharing similar transcription factor or other downstream transcription machineries. Hence, presence of such gene clusters of active signaling networks in a cell type may regulate the spatial organization of chromosomes in the nucleus. However, given the probabilistic nature of chromosome positions and complex transcription factor networks (TFNs), quantitative methods to establish their correlation is lacking. In this paper, we use chromosome positions and gene expression profiles in interphase fibroblasts and describe methods to capture the correspondence between their spatial position and expression. In addition, numerical simulations designed to incorporate the interacting TFNs, reveal that the chromosome positions are also optimized for the activity of these networks. These methods were validated for specific chromosome pairs mapped in two distinct transcriptional states of T-Cells (naïve and activated). Taken together, our methods highlight the functional coupling between topology of chromosomes and their respective gene expression patterns.
Highlights
The genetic material in eukaryotic cells has a multiscale three dimensional organization within the nucleus [1]
In this work we propose methods to probe the correspondence between the chromosome positions and global gene expression program
While chromosomes have been found to be radially distributed from the nuclear centroid according to their gene density [39,40,41], our methods were able to assess a further layer of three dimensional organization, in which the relative chromosome positions correlated with gene expression
Summary
The genetic material (chromatin) in eukaryotic cells has a multiscale three dimensional organization within the nucleus [1]. Imaging methods using whole chromosome probes (FISH) reveal the spatial dimension to genome organization in eukaryotic cells. These methods have suggested that chromatin is organized into well-defined chromosome territories (CT), in a tissue specific non-random manner [4,5,6,7]. These chromosome positions remain largely conserved during the interphase in proliferating cells [8,9,10]. Methods to describe the correlations between threedimensional architecture of chromosome positions [25,26] and global gene expression as well as TFNs is largely unexplored
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