Transcription‐ and translation‐dependent changes in membrane dynamics in bacteria: testing the transertion model for domain formation

Cell cycle events have been proposed to be triggered by the formation of membrane domains in the process of coupled transcription, translation and insertion (‘transertion’) of nascent membrane and exported proteins. Disruption of domain structure should lead to changes in membrane dynamics. Membrane...

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Published in:Molecular microbiology 1999-06, Vol.32 (6), p.1173-1182
Main Authors: Binenbaum, Zoya, Parola, Abraham H., Zaritsky, Arieh, Fishov, Itzhak
Format: Article
Language:English
Subjects:
Bacillus subtilis
Bacillus subtilis - drug effects
Bacillus subtilis - genetics
Bacillus subtilis - physiology
Bacillus subtilis - ultrastructure
Bacterial Proteins - antagonists & inhibitors
Cell Membrane - ultrastructure
DNA, Bacterial - antagonists & inhibitors
Escherichia coli
Escherichia coli - drug effects
Escherichia coli - genetics
Escherichia coli - physiology
Escherichia coli - ultrastructure
Models, Biological
Nucleic Acid Synthesis Inhibitors - pharmacology
Protein Biosynthesis
Protein Synthesis Inhibitors - pharmacology
RNA, Bacterial - antagonists & inhibitors
Transcription, Genetic
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Summary:Cell cycle events have been proposed to be triggered by the formation of membrane domains in the process of coupled transcription, translation and insertion (‘transertion’) of nascent membrane and exported proteins. Disruption of domain structure should lead to changes in membrane dynamics. Membrane viscosity of Escherichia coli and Bacillus subtilis decreased after inhibition of protein synthesis by chloramphenicol or puromycin, or of RNA initiation by rifampicin, but not after inhibition of RNA elongation by streptolydigin or amino acid starvation of a stringent strain. The decrease caused by inhibitors of protein synthesis was prevented by streptolydigin if added simultaneously, but was not reversed if added later. The drug‐induced decrease in membrane viscosity is energy dependent: it did not happen in KCN‐treated cells. All treatments decreasing membrane viscosity also induced nucleoid compaction and fusion. Inhibition of macromolecular synthesis without membrane perturbation caused nucleoids to expand. Changes in membrane dynamics were also displayed during a nutritional shift‐down transition that causes imbalance in macromolecular syntheses. The results are consistent with the transertion model, predicting dissipation of membrane domains by termination of protein synthesis or detachment of polysomes from DNA; domain structure is conserved if the transertion process is ‘frozen’.
ISSN:0950-382X
1365-2958
DOI:10.1046/j.1365-2958.1999.01426.x