Mayra Garcia-Alcala scite author profile

The classic picture of flagellum biosynthesis in Escherichia coli, inferred from population measurements, depicts a deterministic program where promoters are sequentially up-regulated and are maintained steadily active throughout exponential growth. However, complex regulatory dynamics at the single-cell level can be masked by bulk measurements. Here, we discover that in individual E. coli cells, flagellar promoters are stochastically activated in pulses. These pulses are coordinated within specific classes of promoters and comprise “on” and “off” states, each of which can span multiple generations. We demonstrate that in this pulsing program, the regulatory logic of flagellar assembly dictates which promoters skip pulses. Surprisingly, pulses do not require specific transcriptional or translational regulation of the flagellar master regulator, FlhDC, but instead appears to be essentially governed by an autonomous posttranslational circuit. Our results suggest that even topologically simple transcriptional networks can generate unexpectedly rich temporal dynamics and phenotypic heterogeneities.

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Stochastic transcriptional pulses orchestrate flagellum biosynthesis in E. coli

Kim¹,

Garcia-Alcala²,

Balleza³

et al. 2018

Preprint

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The classic picture of flagellum biosynthesis in E. coli, inferred from population measurements, describes a tightly controlled, deterministic transcriptional program. In individual E. coli cells, we discover that flagellar promoters are in fact stochastically activated in pulses. Such pulses comprise coordinated ‘on’ and ‘off’ states of promoter activity, each of which can span multiple generations. We demonstrate that this pulsing program obeys the regulatory logic of flagellar assembly, which dictates whether some promoters skip pulses. Remarkably, pulses in this transcriptional network appear to be actually governed by a post-translational circuit. Our results suggest that even topologically simple transcriptional networks can generate unexpectedly rich temporal dynamics and phenotypic heterogeneities.

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Protein Concentration Fluctuations in the High Expression Regime: Taylor’s Law and Its Mechanistic Origin

Sassi¹,

Garcia-Alcala

Aldana

et al. 2022

Phys. Rev. X

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