Evidence for Rate-dependent Filtering of Global Extrinsic Noise by Biochemical Reactions in Mammalian Cells

Overview

Journal Mol Syst Biol

Specialty Molecular Biology

Date 2020 May 15

PMID 32407587

Citations 3

Authors

Jiegen Wu

Xu Han

Haotian Zhai

Tingyu Yang

Yihan Lin

Affiliations

Soon will be listed here.

Abstract

Recent studies have revealed that global extrinsic noise arising from stochasticity in the intracellular biochemical environment plays a critical role in heterogeneous cell physiologies. However, it remains largely unclear how such extrinsic noise dynamically influences downstream reactions and whether it could be neutralized by cellular reactions. Here, using fluorescent protein (FP) maturation as a model biochemical reaction, we explored how cellular reactions might combat global extrinsic noise in mammalian cells. We developed a novel single-cell assay to systematically quantify the maturation rate and the associated noise for over a dozen FPs. By exploiting the variation in the maturation rate for different FPs, we inferred that global extrinsic noise could be temporally filtered by maturation reactions, and as a result, the noise levels for slow-maturing FPs are lower compared to fast-maturing FPs. This mechanism is validated by directly perturbing the maturation rates of specific FPs and measuring the resulting noise levels. Together, our results revealed a potentially general principle governing extrinsic noise propagation, where timescale separation allows cellular reactions to cope with dynamic global extrinsic noise.

Citing Articles

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Evidence for rate-dependent filtering of global extrinsic noise by biochemical reactions in mammalian cells.

Wu J, Han X, Zhai H, Yang T, Lin Y Mol Syst Biol. 2020; 16(5):e9335.

PMID: 32407587 PMC: 7224485. DOI: 10.15252/msb.20199335.

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