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Scientists Develop a Novel Baby Machine Using Synthetic Magnetic Bacteria

May 07, 2019

The growth and division of bacteria are precisely regulated by a vital process known as the cell cycle. Just like the lifetime of a human being, a bacterial cell’s lifetime is composed of different events that occur at different stages of the cell cycle, with the size and physiology of the cell changing as the cycle proceeds. 

In normal bacterial culture, cells at different stages of the cell cycle are mixed together, so it is difficult to study separate events within the cycle. To gain insight into how the cell cycle regulates events in an orderly way, different methods have been developed to obtain synchronous cells. 

A team led by Prof. LIU Chenli at the Shenzhen Institutes of Advanced Technology (SIAT) of the Chinese Academy of Sciences created a novel microfluidic synchronizer using a synthetic magnetic bacterium to obtain populations of minimally-disturbed, normal, synchronized cells. 

Synthetic biology was applied to establish an artificial magnetic "stalk" at one pole of Escherichia coli. The inducible stalk was constructed from a chimeric fusion protein, eGFP-AIDAc that was heterologously expressed in the E. coli strain. 

This protein subsequently translocated to the cell poles, where it specifically bound to streptavidin-coated magnetic nanoparticles via biotinylated anti-eGFP antibodies. After one cell division, at most one cell pole retained a magnetic "stalk". 

One end of these synthetic magnetic bacteria can be attached to a microfluidic channel wall by using a permanent magnet. As these "mother" cells grow and divide in the flowing culture medium, "daughter" cells are born without the inducible, assembled "stalk". They are hence not affected by the magnet and are eluted and collected (Fig.). 

 

Fig. Magnetic bacteria in microfluidic channel (Image by SIAT) 

The construction of such a magnetic bacterium is not limited to E. coli strains. The inducible and modularized magnetic "stalk" can be easily assembled in a wide range of bacterial strains.

The microfluidic chip using in this study provides fine control of the micro-environment of cultured cells. Important features such as temperature, growth medium, and added chemical reagents can be adjusted easily. This novel microfluidic synchronizer reduces the consumption of culture medium and increases the concentration of synchronous cells.

The study entitled "Microfluidic Synchronizer Using a Synthetic Nanoparticle-Capped Bacterium" was published in ACS Synthetic Biology.

Contact

ZHANG Xiaomin

Shenzhen Institutes of Advanced Technology

E-mail:

Microfluidic Synchronizer Using a Synthetic Nanoparticle-Capped Bacterium

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