While eukaryotic cells have a myriad
of membrane-bound organelles enabling the isolation of different chemical
environments, prokaryotic cells lack these defined reaction vessels.
Biomolecular condensates—organelles that lack a membrane—provide
a strategy for cellular organization without a physical barrier while
allowing for the dynamic, responsive organization of the cell. It
is well established that intrinsically disordered protein domains
drive condensate formation via liquid–liquid phase separation;
however, the role of globular protein domains on intracellular phase
separation remains poorly understood. We hypothesized that the overall
charge of globular proteins would dictate the formation and concentration
of condensates and systematically probed this hypothesis with supercharged
proteins and nucleic acids in
E. coli
. Within this
study, we demonstrated that condensates form via electrostatic interactions
between engineered proteins and RNA and that these condensates are
dynamic and only enrich specific nucleic acid and protein components.
Herein, we propose a simple model for the phase separation based on
protein charge that can be used to predict intracellular condensate
formation. With these guidelines, we have paved the way to designer
functional synthetic membraneless organelles with tunable control
over globular protein function.
Circadian oscillators are posttranslationally regulated and affect gene expression in autotrophic cyanobacteria. Oscillations are controlled by phosphorylation of the KaiC protein, which is modulated by the KaiA and KaiB proteins. However, it remains unclear how time information is transmitted to transcriptional output. We show reconstruction of the KaiABC oscillator in the noncircadian bacterium Escherichia coli. This orthogonal system shows circadian oscillations in KaiC phosphorylation and in a synthetic transcriptional reporter. Coexpression of KaiABC with additional native cyanobacterial components demonstrates a minimally sufficient set of proteins for transcriptional output from a native cyanobacterial promoter in E. coli. Together, these results demonstrate that a circadian oscillator is transplantable to a heterologous organism for reductive study as well as wide-ranging applications.
Phase separation provides intracellular organization and underlies a variety of cellular processes. These biomolecular condensates exhibit distinct physical and material properties. Current strategies for engineering condensate formation include using intrinsically disordered domains and altering protein surface charge by chemical supercharging or site-specific mutagenesis. We propose adding to this toolbox designer peptide tags that provide several potential advantages for engineering protein phase separation in bacteria. Herein, we demonstrate the use of short cationic peptide tags for sequestration of proteins of interest into bacterial condensates and provide a foundational study for their development as tools for condensate engineering. Using a panel of GFP variants, we demonstrate how cationic tag and globular domain charge contribute to intracellular phase separation in E. coli and observe that the tag can affect condensate disassembly at a given net charge near the phase separation boundary. We showcase the broad applicability of these tags by appending them onto enzymes and demonstrating that the sequestered enzymes remain catalytically active.
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