Structural and dynamical analysis of biological networks

Klein, Cecilia C.; Marino, Andrea; Sagot, Marie‐France; Milreu, Paulo Vieira; Brilli, Matteo

doi:10.1093/bfgp/els030

Cited by 28 publications

(26 citation statements)

References 144 publications

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“…Therefore, to interrogate the role of individual TFs within the network, we leveraged principles of graph theory to identify critical nodes, defined by different measures of centrality. For example, degree centrality is the most straightforward measure, reporting how many edges are connected to a node (in this case, how many genes a given TF connects to) (Klein et al, 2012). Here, degree centrality scoring in the MEP_0 cluster GRN configuration successfully recognized key TFs associated with erythrocyte differentiation; Gata1, Gata2, and Klf1, as above, in addition to Nfe2 (Andrews et al, 1993) and Ztbt7a (Norton et al, 2017) (Figure 3F; Figure S2B).…”

Section: Application Of Celloracle To Infer Grn Configurations In Hemmentioning

confidence: 75%

“…This analysis revealed that CellOracleinferred GRN configurations resemble a scale-free network, whose degree distribution follows a power law (Figure S2A). This configuration is characteristic of biological networks, defined by the presence of hub nodes serving as bridges between small degree nodes, supporting a robust network structure, in contrast to random networks (Klein et al, 2012). Many hub nodes are visible within CellOracle-inferred GRN configurations; for example, for the configuration inferred for the megakaryocyte erythrocyte progenitor (MEP) cluster, network modules and hubs can be distinguished ( Figure 3E).…”

Section: Application Of Celloracle To Infer Grn Configurations In Hemmentioning

confidence: 79%

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CellOracle: Dissecting cell identity via network inference and in silico gene perturbation

Kamimoto

Hoffmann

Morris

2020

Preprint

130

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Here, we present CellOracle, a computational tool that integrates single-cell transcriptome and epigenome profiles to infer gene regulatory networks (GRNs), critical regulators of cell identity. Leveraging inferred GRNs, we simulate gene expression changes in response to transcription factor (TF) perturbation, enabling network configurations to be interrogated in silico, facilitating their interpretation. We validate the efficacy of CellOracle to recapitulate known regulatory changes across hematopoiesis, correctly predicting the outcomes of well-characterized TF perturbations. Integrating CellOracle analysis with lineage tracing of direct reprogramming reveals distinct network configurations underlying different reprogramming failure modes.Furthermore, analysis of GRN reconfiguration along successful reprogramming trajectories identifies new factors to enhance target cell yield, uncovering a role for the AP-1 subunit Fos, with the hippo signaling effector, Yap1. Together, these results demonstrate the efficacy of CellOracle to infer and interpret cell-type-specific GRN configurations, at high-resolution, promoting new mechanistic insights into the regulation and reprogramming of cell identity.

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Section: Application Of Celloracle To Infer Grn Configurations In Hemmentioning

confidence: 75%

Section: Application Of Celloracle To Infer Grn Configurations In Hemmentioning

confidence: 79%

CellOracle: Dissecting cell identity via network inference and in silico gene perturbation

Kamimoto

Hoffmann

Morris

2020

Preprint

130

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“…For example, a close link between residue fluctuations (B‐factors) of a given protein and the average shortest path length to a residue from all others has been established . The network approach has enabled the study of specific proteins and has helped reveal interesting features not directly evident from the structure or sequence homology . For example, interaction conservation was utilized in phylogenetic analysis of remote homologs of the TIM barrel fold to reveal loop‐based conserved interactions near the active site .…”

Section: Introductionmentioning

confidence: 99%

In silico mutational studies of Hsp70 disclose sites with distinct functional attributes

Özbaykal

Atılgan

2015

Proteins

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The Mutation-Minimization Method (MuMi) to study the local response of proteins to point mutations has been introduced here. The heat shock protein Hsp70 as the test system since it displays features that have been studied in great detail has been used here. It has many conserved residues, serves several different functions on each of its domains, and displays interdomain allostery. For the analysis of spatial arrangement of residues within the protein, the network properties of the wild type (WT) protein as well as its all single alanine residue mutants using MuMi has been investigated. The measures to express the amount of change from the WT structure upon mutation and compare these deviations to find potential critical sites have been proposed. The functional significance of the potential sites to the parameter that uncovers them has been mapped. It was found that sites directly involved in binding were sensitive to mutations and were characterized by large displacements. On the other hand, sites that steer large conformational changes typically had increased reachability upon alanine mutations occurring elsewhere in the protein. Finally, residues that control communication within and between domains reside on the largest number of paths connecting pairs of residues in the protein.

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“…For instance, the fate decision mechanism in a bacteriophage life cycle [1], the chemotaxis process in Escherichia coli [2], and segmental polarization in Drosophila melanogaster [3] were shown to be robust against noisy environments. It is more interesting that the dynamics of a biological network can be highly related to its structural characteristics [4]. In particular, many recent studies have shown that a feedback loop (FBL), a circular chain of interactions, can play an important role in controlling the robustness or susceptibility of networks [5, 6].…”

Section: Introductionmentioning

confidence: 99%

Properties of Boolean dynamics by node classification using feedback loops in a network

Kwon

2016

BMC Syst Biol

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BackgroundBiological networks keep their functions robust against perturbations. Many previous studies through simulations or experiments have shown that feedback loop (FBL) structures play an important role in controlling the network robustness without fully explaining how they do it. Hence, there is a pressing need to more rigorously analyze the influence of FBL structures on network robustness.ResultsIn this paper, I propose a novel node classification notion based on the FBL structures involved. More specifically, I classify a node as a no-FBL-in-upstream (NFU) or no-FBL-in-downstream (NFD) node if no feedback loop is involved with any upstream or downstream path of the node, respectively. Based on those definitions, I first prove that every NFU node is eventually frozen in Boolean dynamics. Thus, NFU nodes converge to a fixed value determined by the upstream source nodes. Second, I prove that a network is robust against an arbitrary state perturbation subject to a non-source NFD node. This implies that a network state eventually sustains the attractor despite a perturbation subject to a non-source NFD node. Inspired by this result, I further propose a perturbation-sustainable probability that indicates how likely a perturbation effect is to be sustained through propagations. I show that genes with a high perturbation-sustainable probability are likely to be essential, disease, and drug-target genes in large human signaling networks.ConclusionTaken together, these results will promote understanding of the effects of FBL on network robustness in a more rigorous manner.Electronic supplementary materialThe online version of this article (doi:10.1186/s12918-016-0322-z) contains supplementary material, which is available to authorized users.

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Structural and dynamical analysis of biological networks

Cited by 28 publications

References 144 publications

CellOracle: Dissecting cell identity via network inference and in silico gene perturbation

CellOracle: Dissecting cell identity via network inference and in silico gene perturbation

In silico mutational studies of Hsp70 disclose sites with distinct functional attributes

Properties of Boolean dynamics by node classification using feedback loops in a network

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