Model-driven Experimental Design Workflow Expands Understanding of Regulatory Role of Nac in

Overview

Journal NAR Genom Bioinform

Publisher Oxford University Press

Specialty Biology

Date 2023 Jan 23

PMID 36685725

Authors

Joon Young Park

Sang-Mok Lee

Ali Ebrahim

Zoe K Scott-Nevros

Jaehyung Kim

Laurence Yang

Anand Sastry

Sang Woo Seo

Bernhard O Palsson

Donghyuk Kim

Affiliations

Soon will be listed here.

Abstract

The establishment of experimental conditions for transcriptional regulator network (TRN) reconstruction in bacteria continues to be impeded by the limited knowledge of activating conditions for transcription factors (TFs). Here, we present a novel genome-scale model-driven workflow for designing experimental conditions, which optimally activate specific TFs. Our model-driven workflow was applied to elucidate transcriptional regulation under nitrogen limitation by Nac and NtrC, in . We comprehensively predict alternative nitrogen sources, including cytosine and cytidine, which trigger differential activation of Nac using a model-driven workflow. In accordance with the prediction, genome-wide measurements with ChIP-exo and RNA-seq were performed. Integrative data analysis reveals that the Nac and NtrC regulons consist of 97 and 43 genes under alternative nitrogen conditions, respectively. Functional analysis of Nac at the transcriptional level showed that Nac directly down-regulates amino acid biosynthesis and restores expression of tricarboxylic acid (TCA) cycle genes to alleviate nitrogen-limiting stress. We also demonstrate that both TFs coherently modulate α-ketoglutarate accumulation stress due to nitrogen limitation by co-activating amino acid and diamine degradation pathways. A systems-biology approach provided a detailed and quantitative understanding of both TF's roles and how nitrogen and carbon metabolic networks respond complementarily to nitrogen-limiting stress.

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