#07 - Bottom‐Up Assembly of Functional Intracellular Synthetic Organelles by Droplet‐Based Microfluidics

#07 - Bottom‐Up Assembly of Functional Intracellular Synthetic Organelles by Droplet‐Based Microfluidics

Oskar Staufer (Max Planck Institute for Medical Research, Heidelberg)

Monday, 30 Nov 21:15 - 22:00 CET

Access to the BigBlueButton rooom for this Mini Talk via the lists for Monday and Tuesday.

Please make yourself familiar with BigBlueButton before you join the Mini Talk - read the instructions.

Abstract

Title: Bottom‐Up Assembly of Functional Intracellular Synthetic Organelles by Droplet‐Based Microfluidics

Author(s): Oskar Staufera

Affiliations: aMax Planck Institute for Medical Research, Heidelberg

Abstract: Bottom‐up synthetic biology has directed most efforts toward the construction of artificial compartmentalized systems that recreate living cell functions in their mechanical, morphological, or metabolic characteristics. However, bottom‐up synthetic biology also offers great potential to study subcellular structures like organelles. Because of their intricate and complex structure, these key elements of eukaryotic life forms remain poorly understood. I will present the controlled assembly of lipid enclosed, organelle‐like architectures by droplet‐based microfluidics. Three types of giant unilamellar vesicles (GUVs)‐based synthetic organelles (SOs) functioning within natural living cells will be presented: (A) synthetic peroxisomes supporting cellular stress‐management, mimicking an organelle innate to the host cell by using analogous enzymatic modules; (B) synthetic endoplasmic reticulum (ER) as intracellular light‐responsive calcium stores involved in intercellular calcium signalling, mimicking an organelle innate to the host cell but utilizing a fundamentally different mechanism; and (C) synthetic magnetosomes providing eukaryotic cells with a magnetotactic sense, mimicking an organelle that is not natural to the host cell but transplanting its functionality from other branches of the phylogenetic tree. Microfluidic assembly of functional SOs paves the way for high‐throughput generation of versatile intracellular structures implantable into living cells. This in‐droplet SO design supports and expands cellular functionalities in translational nanomedicine.

Go to Editor View