Relative Rates of Surface and Volume Synthesis Set Bacterial Cell Size

Harris, Leigh K.; Theriot, Julie A.

doi:10.1016/j.cell.2016.05.045

Cited by 218 publications

(458 citation statements)

References 51 publications

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“…We used time-lapse imaging to measure cell size and cell cycle timing in SSB-GFP M. smegmatis cells. Several studies recently developed a division adder model (also called an incremental model) of cell size control, in which bacteria add a constant length (Δ l bd ) from birth to division regardless of birth size (Figures 2A, S2D&S4; STAR Methods) [6, 8, 20–23]. Because Δ l bd is not correlated to birth length, we found that M. smegmatis is consistent with this aspect of the division adder model (Figure 2B) [4, 6, 19].…”

Section: Resultsmentioning

confidence: 99%

A Parallel Adder Coordinates Mycobacterial Cell-Cycle Progression and Cell-Size Homeostasis in the Context of Asymmetric Growth and Organization

et al. 2017

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Summary In model bacteria, such as E. coli and B. subtilis, regulation of cell cycle progression and cellular organization achieves consistency in cell size, replication dynamics, and chromosome positioning [1–3]. Mycobacteria elongate and divide asymmetrically, giving rise to significant variation in cell size and elongation rate among closely related cells [4, 5]. Given the physical asymmetry of mycobacteria, the models that describe coordination of cellular organization and cell cycle progression in model bacteria are not directly translatable [1, 2, 6–8]. Here we used time-lapse microscopy and fluorescent reporters of DNA replication and chromosome positioning to examine the coordination of growth, division, and chromosome dynamics at a single-cell level in Mycobacterium smegmatis (M. smegmatis) and Mycobacterium bovis Bacillus Calmette–Guérin (BCG). By analyzing chromosome and replisome localization, we demonstrated that chromosome positioning is asymmetric and proportional to cell size. Furthermore, we found that cellular asymmetry is maintained throughout the cell cycle and is not established at division. Using measurements and stochastic modeling of mycobacterial cell size and cycle timing in both slow and fast growth conditions, we found that well-studied cell size control models are insufficient to explain the mycobacterial cell cycle. Instead, we showed that mycobacterial cell cycle progression is regulated by an unprecedented mechanism involving parallel adders (i.e. constant growth increments) that start at replication initiation. Together, these adders enable mycobacterial populations to regulate cell size, growth, and heterogeneity in the face of varying environments.

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Section: Resultsmentioning

confidence: 99%

A Parallel Adder Coordinates Mycobacterial Cell-Cycle Progression and Cell-Size Homeostasis in the Context of Asymmetric Growth and Organization

et al. 2017

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“…This scenario is referred to as the incremental or adder model. Recent work proposed a similar model, in which a constant surface area is added between birth and division (Harris and Theriot, 2016). Clearly, these models are different than Donachie’s – yet they both stem from empirical findings.…”

Section: Challenging Donachie’s Modelmentioning

confidence: 99%

Is cell size a spandrel?

Amir

2017

eLife

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All organisms control the size of their cells. We focus here on the question of size regulation in bacteria, and suggest that the quantitative laws governing cell size and its dependence on growth rate may arise as byproducts of a regulatory mechanism which evolved to support multiple DNA replication forks. In particular, we show that the increase of bacterial cell size during Lenski’s long-term evolution experiments is a natural outcome of this proposal. This suggests that, in the context of evolution, cell size may be a 'spandrel'DOI: http://dx.doi.org/10.7554/eLife.22186.001

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“…Recent studies have investigated the mechanism of cell size control via inhibition of biosynthesis [4,10]. When cells were exposed to sub-lethal dosage of a cell wall biosynthesis inhibitor, their surface-to-volume ratio changed to a new steady-state value in a dose-dependent manner [10].…”

Section: Introductionmentioning

confidence: 99%

Invariance of Initiation Mass and Predictability of Cell Size in Escherichia coli

et al. 2017

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Summary It is generally assumed that the allocation and synthesis of total cellular resources in microorganisms are uniquely determined by the growth conditions. Adaptation to a new physiological state leads to a change in cell size via reallocation of cellular resources. However, it has not been understood how cell size is coordinated with biosynthesis and robustly adapts to physiological states. We show that cell size in Escherichia coli can be predicted for any steady-state condition by projecting all biosynthesis into three measurable variables representing replication initiation, replication-division cycle, and the global biosynthesis rate. These variables can be decoupled by selectively controlling their respective core biosynthesis using CRISPR interference and antibiotics, verifying our predictions that different physiological states can result in the same cell size. We performed extensive growth inhibition experiments, and discovered that cell size at replication initiation per origin, namely the initiation mass or “unit cell,” is remarkably invariant under perturbations targeting transcription, translation, ribosome content, replication kinetics, fatty acid and cell-wall synthesis, cell division, and cell shape. Based on this invariance and balanced resource allocation, we explain why the total cell size is the sum of all unit cells. These results provide an overarching framework with quantitative predictive power over cell size in bacteria.

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Relative Rates of Surface and Volume Synthesis Set Bacterial Cell Size

Cited by 218 publications

References 51 publications

A Parallel Adder Coordinates Mycobacterial Cell-Cycle Progression and Cell-Size Homeostasis in the Context of Asymmetric Growth and Organization

A Parallel Adder Coordinates Mycobacterial Cell-Cycle Progression and Cell-Size Homeostasis in the Context of Asymmetric Growth and Organization

Is cell size a spandrel?

Invariance of Initiation Mass and Predictability of Cell Size in Escherichia coli

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