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Cell size is a significant factor impacting cellular design, function, and fitness. There exists some internal coordination by which cells double their masses before division, thus, achieving homeostasis. Coordination between cell growth and proliferation depends on the checkpoints in between cell cycle phases. Loss of coordination or failure in the checkpoint mechanism can drive the cell to uncontrolled growth and loss of cellular function. Like dividing cells that coordinate cellular growth,...
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Cell sizes vary widely among and within organisms. Bacterial cells range between 1-10 micrometers (μm)and are considerably smaller than most eukaryotic cells. The smallest bacteria are 0.1 μm in diameter—about a thousand times smaller than eukaryotic cells, which typically range from 10-100 μm.
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Most vertebrate cells grow in vitro attached to a substrate as a monolayer, called adherent cultures. The flasks and plates used to grow cells are chemically treated to facilitate cell attachment. However, a few cell types, such as hematopoietic cells, can grow in a suspension. In contrast to adherent cultures, suspension cultures can grow in non-treated cultureware using magnetic stirrers or spinner flasks to agitate the culture media
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Related Experiment Video

Updated: Mar 16, 2026

An Efficient and Flexible Cell Aggregation Method for 3D Spheroid Production
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Growth: A Model for Establishing Cell Size and Shape.

Yee-Hung Mark Chan1

  • 1Department of Biology, San Francisco State University, 1600 Holloway Ave., San Francisco, CA 94132, USA.

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|August 25, 2016
PubMed
Summary
This summary is machine-generated.

Bacterial shape and size are determined by the relative growth of cell surface area and volume. A new model explains bacterial morphogenesis and cell-cycle timing.

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Area of Science:

  • Microbiology
  • Cell Biology
  • Biophysics

Background:

  • Bacterial shape is crucial for survival and function.
  • Understanding the mechanisms governing bacterial cell size and shape is fundamental in microbiology.
  • Previous models have not fully captured the interplay between surface area and volume growth.

Purpose of the Study:

  • To investigate the relationship between cell surface area and volume growth in rod-like bacteria.
  • To develop a predictive model for bacterial morphogenesis based on relative growth rates.
  • To explore the implications of this model for cell-cycle timing.

Main Methods:

  • Experimental observation of bacterial growth.
  • Quantitative analysis of cell surface area and volume.
  • Development and validation of a mathematical relative-growth model.

Main Results:

  • Relative growth rates of cell surface area and volume are identified as critical factors in determining bacterial shape and size.
  • The developed relative-growth model accurately predicts the dimensions of rod-like bacteria.
  • The model provides insights into the coordination of growth processes.

Conclusions:

  • The relative-growth model offers a unified framework for understanding bacterial morphogenesis and cell-cycle regulation.
  • This work advances our comprehension of fundamental bacterial cell biology.
  • The findings have potential applications in synthetic biology and understanding bacterial physiology.