Inferring reaction network structure from single-cell, multiplex data, using toric systems theory

Wang, Shu; Lin, Jia-Ren; Sontag, Eduardo D.; Sorger, Peter K.

doi:10.1101/731018

Cited by 11 publications

(20 citation statements)

References 45 publications

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“…For some applications, it might be more sensible to fix a desired length scale for computing the curvature. [47] and specific manifolds have been proposed to model reaction networks [48], which may be applicable to scRNAseq data. These proposed manifolds can be validated or improved using knowledge of the intrinsic geometry of scRNAseq datasets.…”

Section: Discussionmentioning

confidence: 99%

“…Unlike the Klein bottle parameterization of image patches however, no definitive analytical form has been established for scRNAseq datasets. Recent work has suggested the use of hyperbolic geometry to model branching cell differentiation trajectories [47] and specific manifolds have been proposed to model reaction networks [48], which may be applicable to scRNAseq data. These proposed manifolds can be validated or improved using knowledge of the intrinsic geometry of scRNAseq datasets.…”

Section: Discussionmentioning

confidence: 99%

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Computing the Riemannian curvature of image patch and single-cell RNA sequencing data manifolds using extrinsic differential geometry

Sritharan

Wang

Hormoz

2021

Preprint

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Most high-dimensional datasets are thought to be inherently low-dimensional, that is, datapoints are constrained to lie on a low-dimensional manifold embedded in a high-dimensional ambient space. Here we study the viability of two approaches from differential geometry to estimate the Riemannian curvature of these low-dimensional manifolds. The intrinsic approach relates curvature to the Laplace-Beltrami operator using the heat-trace expansion, and is agnostic to how a manifold is embedded in a high-dimensional space. The extrinsic approach relates the ambient coordinates of a manifold’s embedding to its curvature using the Second Fundamental Form and the Gauss-Codazzi equation. Keeping in mind practical constraints of real-world datasets, like small sample sizes and measurement noise, we found that estimating curvature is only feasible for even simple, low-dimensional toy manifolds, when the extrinsic approach is used. To test the applicability of the extrinsic approach to real-world data, we computed the curvature of a well-studied manifold of image patches, and recapitulated its topological classification as a Klein bottle. Lastly, we applied the approach to study single-cell transcriptomic sequencing (scRNAseq) datasets of blood, gastrulation, and brain cells, revealing for the first time the intrinsic curvature of scRNAseq manifolds.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Computing the Riemannian curvature of image patch and single-cell RNA sequencing data manifolds using extrinsic differential geometry

Sritharan

Wang

Hormoz

2021

Preprint

Self Cite

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“…Given a desired network motif and a physical system, we need to use measurements of the system to determine if the actual, active network of the system matches the intended design. There have been many network reconstruction algorithms developed for natural and synthetic biological networks [39], [40], [24], [41], [42], [43], [44], [45]. Historically, the approach to discovering network interactions has involved direct perturbation of biochemical species or components in a network [41], [45], [46].…”

Section: Introductionmentioning

confidence: 99%

“…At the single cell level, the reconstruction problem for biological networks introduces challenges of inferring non-linear stochastic models from noisy data [48], [49], [44]. In [48], the authors show that by comparing average abundances, molecule lifetimes, covariances, and magnitude of step, they can map pairwise interaction dynamics, even when the rest of the system is completely unspecified.…”

Section: Introductionmentioning

confidence: 99%

Data-Driven Network Models for Genetic Circuits From Time-Series Data with Incomplete Measurements

Yeung

Yuan

et al. 2021

Preprint

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Synthetic biological gene networks are typically conceptualized and visualized as static graphs with nodal and edge dynamics that are time invariant. This conceptualization of biological programming stands in stark contrast to the transient nature of biological dynamics, which are driven by labile biomolecules. Here we demonstrate the use of dynamical structure function theory to evaluate and visualize network dynamics within synthetic biological circuits. We introduce the theory of dynamical structure functions as a tool for understanding network dynamics in synthetic gene networks. We show in particular, that canonical biological crosstalk and resource loading effects in synthetic biology can be quantified directly using dynamical structure functions from simulation and experimental data. We illustrate the importance of knowing these loading effects through several example systems, showing that crosstalk imbalance in feed-forward loops can explain circuit failure or performance limitations. Finally, we show how dynamical structure functions can be used to diagnose crosstalk and network imbalance to explain failure modes in two types of synthetic biocircuits: an in vitro genelet repressilator and an E. coli based transcriptional event detector. We show that dynamical structure functions can be used as a form of inverse modeling, to pinpoint biological parts within a complex biological circuit that need revision or improvement.

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“…A mechanistic understanding of dynamic cellular processes is at the core of multiple areas of research including molecular cell biology, physiology, biophysics, and bioengineering [1][2][3][4][5][6]. Although analytical tools have improved the breadth and depth with which intra-or extra-cellular biochemical processes are explored [7][8][9], the vast majority of available data is limited to experiments that probe cue-response relationships with a specified set of inputs and outputs.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised logic-based mechanism inference for network-driven biological processes

Prugger

Einkemmer

Harris

et al. 2020

Preprint

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Modern analytical techniques enable researchers to collect data about cellular states, before and after perturbations. These states can be characterized using analytical techniques, but the inference of regulatory interactions that explain and predict changes in these states remains a challenge. Here we present a generalizable unsupervised approach to generate parameter-free, logic-based mechanistic hypotheses of cellular processes, described by multiple discrete states. Our algorithm employs a Hamming-distance based approach to formulate, test, and identify, the best mechanism that links two states. Our approach comprises two steps. First, a model with no prior knowledge except for the mapping between initial and attractor states is built. Second, we employ biological constraints to improve model fidelity. Our algorithm automatically recovers the relevant dynamics for the explored models and recapitulates all aspects of the original models biochemical species concentration dynamics. We then conclude by placing our results in the context of ongoing work in the field and discuss how our approach could be used to infer mechanisms of signaling, gene-regulatory, and any other input-output processes describable by logic-based mechanisms.

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Inferring reaction network structure from single-cell, multiplex data, using toric systems theory

Cited by 11 publications

References 45 publications

Computing the Riemannian curvature of image patch and single-cell RNA sequencing data manifolds using extrinsic differential geometry

Computing the Riemannian curvature of image patch and single-cell RNA sequencing data manifolds using extrinsic differential geometry

Data-Driven Network Models for Genetic Circuits From Time-Series Data with Incomplete Measurements

Unsupervised logic-based mechanism inference for network-driven biological processes

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