Scatter Search Applied to the Inference of a Development Gene Network

Abdol, Amir Masoud; Cicin-Sain, Damjan; Kaandorp, Jaap A.; Crombach, Anton

doi:10.3390/computation5020022

Cited by 6 publications

(4 citation statements)

References 51 publications

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“…A major challenge in broader application of gene circuits is the high computational expense of inferring the free parameters from time series data. Currently, the approach for inferring parameter values (Chu et al 1999; Reinitz and Sharp 1995; Kozlov et al 2012; Abdol et al 2017) is to solve (“integrate”) the ODEs to obtain trajectories, compare with experimental trajectories, and refine parameters using global optimization techniques such as SA. This procedure is slow and expensive because it requires performing multidimensional optimization on a complicated cost function χ2({T,h,R,λ}) with many local minima and each function evaluation involves solving a system of ODEs.…”

Section: Discussionmentioning

confidence: 99%

“…One approach to speeding up the inference procedure has been to explore different global optimization methods such as evolutionary algorithms (Kozlov and Samsonov 2009; Kozlov et al 2012) and scatter search (Abdol et al 2017). Alternative global optimization methods do not circumvent the problem of high computational cost since each cost function evaluation still involves the solution of coupled ODEs.…”

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confidence: 99%

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Classification-Based Inference of Dynamical Models of Gene Regulatory Networks

Fehr¹,

Handzlik

Manu

et al. 2019

G3 Genes|Genomes|Genetics

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Cell-fate decisions during development are controlled by densely interconnected gene regulatory networks (GRNs) consisting of many genes. Inferring and predictively modeling these GRNs is crucial for understanding development and other physiological processes. Gene circuits, coupled differential equations that represent gene product synthesis with a switch-like function, provide a biologically realistic framework for modeling the time evolution of gene expression. However, their use has been limited to smaller networks due to the computational expense of inferring model parameters from gene expression data using global non-linear optimization. Here we show that the switch-like nature of gene regulation can be exploited to break the gene circuit inference problem into two simpler optimization problems that are amenable to computationally efficient supervised learning techniques. We present FIGR (Fast Inference of Gene Regulation), a novel classification-based inference approach to determining gene circuit parameters. We demonstrate FIGR’s effectiveness on synthetic data generated from random gene circuits of up to 50 genes as well as experimental data from the gap gene system of Drosophila melanogaster, a benchmark for inferring dynamical GRN models. FIGR is faster than global non-linear optimization by a factor of 600 and its computational complexity scales much better with GRN size. On a practical level, FIGR can accurately infer the biologically realistic gap gene network in under a minute on desktop-class hardware instead of requiring hours of parallel computing. We anticipate that FIGR would enable the inference of much larger biologically realistic GRNs than was possible before.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Classification-Based Inference of Dynamical Models of Gene Regulatory Networks

Fehr¹,

Handzlik

Manu

et al. 2019

G3 Genes|Genomes|Genetics

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“…If high-performance computing facilities are available, it remains our preferred fitting method. Several alternatives, mostly based on evolutionary computation and scatter search, have been proposed to reduce computational cost [1,32,59,74]. Until recently, however, none of these alternatives were able to match the robustness and reliability of pLSA on our particular problem.…”

Section: Reverse-engineering With Gene Circuitsmentioning

confidence: 99%

Life’s Attractors Continued: Progress in Understanding Developmental Systems Through Reverse Engineering and In Silico Evolution

Crombach¹,

Jaeger

2021

Evolutionary Systems Biology

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We present a progress report on our efforts to establish a new research program for evolutionary systems biology, based on reverse-engineering and in silico evolution. The aim is a mechanistic understanding of the genotype-phenotype map and its evolution. Our review focuses on the case study of the gap gene network in dipteran insects (flies and midges). This network is the top regulatory tier of the segmentation gene hierarchy, generating a pattern of overlapping expression domains that subdivide the embryo during early embryogenesis. It is one of the best-understood developmental regulatory networks today. We have studied this system in a comparative way, across three species: the vinegar fly, Drosophila melanogaster, the scuttle fly, Megaselia abdita, and the moth midge, Clogmia albipunctata. In this context, we discuss methodological challenges concerning data processing and model-fitting, consider different functional decompositions of the gap gene network, and highlight novel insights into network evolution by compensatory developmental system drift. Finally, we discuss the prospect of simulating the phylogenesis of the gap gene network using in silico evolution. We conclude by arguing that our case study is a first step towards a more systematic empirical investigation into the principles of network evolution.

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“…The values of the free parameters define the regulatory influences among the genes in the network. Gene circuits do not presuppose any particular scheme of regulatory interactions, but instead determine it by estimating the values of the parameters from quantitative data using global nonlinear optimization techniques [17][18][19][20]. Gene circuits infer not only the topology of the GRN but also the type, either activation or repression, and strength of interactions.…”

Section: Introductionmentioning

confidence: 99%

Data-driven modeling predicts gene regulatory network dynamics during the differentiation of multipotential hematopoietic progenitors

Handzlik

Manu

2022

PLoS Comput Biol

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Cellular differentiation during hematopoiesis is guided by gene regulatory networks (GRNs) comprising transcription factors (TFs) and the effectors of cytokine signaling. Based largely on analyses conducted at steady state, these GRNs are thought to be organized as a hierarchy of bistable switches, with antagonism between Gata1 and PU.1 driving red- and white-blood cell differentiation. Here, we utilize transient gene expression patterns to infer the genetic architecture—the type and strength of regulatory interconnections—and dynamics of a twelve-gene GRN including key TFs and cytokine receptors. We trained gene circuits, dynamical models that learn genetic architecture, on high temporal-resolution gene-expression data from the differentiation of an inducible cell line into erythrocytes and neutrophils. The model is able to predict the consequences of gene knockout, knockdown, and overexpression experiments and the inferred interconnections are largely consistent with prior empirical evidence. The inferred genetic architecture is densely interconnected rather than hierarchical, featuring extensive cross-antagonism between genes from alternative lineages and positive feedback from cytokine receptors. The analysis of the dynamics of gene regulation in the model reveals that PU.1 is one of the last genes to be upregulated in neutrophil conditions and that the upregulation of PU.1 and other neutrophil genes is driven by Cebpa and Gfi1 instead. This model inference is confirmed in an independent single-cell RNA-Seq dataset from mouse bone marrow in which Cebpa and Gfi1 expression precedes the neutrophil-specific upregulation of PU.1 during differentiation. These results demonstrate that full PU.1 upregulation during neutrophil development involves regulatory influences extrinsic to the Gata1-PU.1 bistable switch. Furthermore, although there is extensive cross-antagonism between erythroid and neutrophil genes, it does not have a hierarchical structure. More generally, we show that the combination of high-resolution time series data and data-driven dynamical modeling can uncover the dynamics and causality of developmental events that might otherwise be obscured.

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Scatter Search Applied to the Inference of a Development Gene Network

Cited by 6 publications

References 51 publications

Classification-Based Inference of Dynamical Models of Gene Regulatory Networks

Classification-Based Inference of Dynamical Models of Gene Regulatory Networks

Life’s Attractors Continued: Progress in Understanding Developmental Systems Through Reverse Engineering and In Silico Evolution

Data-driven modeling predicts gene regulatory network dynamics during the differentiation of multipotential hematopoietic progenitors

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