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1. Gene expression cycles drive non-exponential bacterial growth

   https://doi.org/10.1103/24rx-sxcw  

   Cylke, Arianna; Banerjee, Shiladitya (August 2025, Physical Review Research)

   Bacterial populations typically exhibit exponential growth under resource-rich conditions, yet individual cells often deviate from this pattern. Recent work has shown that the elongation rates of and increase throughout the cell cycle (super-exponential growth), while displays a midcycle minimum (convex growth), and grows linearly. Here, we develop a single-cell model linking gene expression, proteome allocation, and mass growth to explain these diverse growth trajectories. By calibrating model parameters with experimental data, we show that DNA-proportional mRNA transcription produces near-exponential growth, whereas deviations from this proportionality yield the observed non-exponential growth patterns. Analysis of gene expression perturbations reveals that ribosome expression primarily controls dry mass growth rate, whereas cell envelope protein expression more strongly affects cell elongation rate. We show that cell-cycle-dependent transcription dynamics give rise to convex, super-exponential, and linear modes of cell elongation observed experimentally, demonstrating how the timing of cell envelope and ribosomal protein expressions drive cell-cycle-specific behaviors. These findings provide a mechanistic basis for non-exponential single-cell growth and offer insights into how bacterial cells dynamically regulate elongation rates within each generation. 

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2. The role of active mRNA-ribosome dynamics and closing constriction in daughter chromosome separation in Escherichia coli

   https://doi.org/10.1101/2025.04.05.647368  

   Amarasinghe, Chathuddasie I; Chang, Mu-Hung; Männik, Jaana; Retterer, Scott T; Lavrentovich, Maxim O; Männik, Jaan (April 2025, bioRxiv)

   Abstract The mechanisms by which two sister chromosomes separate and partition into daughter cells in bacteria remain poorly understood. A recent theoretical model has proposed that out-of-equilibrium processes associated with mRNA–ribosome (polysome) dynamics play a significant role in this process. Here we investigate the role of ribosomal dynamics on nucleoid segregation and separation inEscherichia coliusing high-throughput fluorescence microscopy in microfluidic devices. We compare our experimental observations with predictions from a reaction-diffusion model that includes the interactions among ribosomal subunits, polysomes, and chromosomal DNA. Our results show that the non-equilibrium behavior of mRNA and ribosomes causes them to aggregate at the midcell and this process contributes to the separation of the two daughter chromosomes. However, this effect is considerably weaker than that predicted by the model. Rather than relying solely on active mRNA–ribosome dynamics, our data suggest that the closing division septum via steric interactions and potentially entropic forces between two DNA strands coupled to cell elongation act as additional mechanisms to ensure faithful partitioning of the nucleoids to two daughter cells. SignificanceThe mitotic spindle separates chromosomes in eukaryotic cells, but bacteria lack this structure. It remains unclear how bacterial chromosomes partition prior to cell division. It has been hypothesized that non-equilibrium dynamics of polysomes, that is mRNA–ribosome complexes, actively drive the separation of bacterial chromosomes. Using quantitative microscopy combined with computational modeling, we show that polysome dynamics significantly contribute to chromosome segregation inEscherichia colibut this process does not constitute the sole mechanism. Our findings suggest the closing division septum via steric interactions and potentially entropic forces between two DNA strands act as additional mechanisms. 

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3. Cellular perception of growth rate and the mechanistic origin of bacterial growth law

   https://doi.org/10.1073/pnas.2201585119  

   Wu, Chenhao; Balakrishnan, Rohan; Braniff, Nathan; Mori, Matteo; Manzanarez, Gabriel; Zhang, Zhongge; Hwa, Terence (May 2022, Proceedings of the National Academy of Sciences)

   Many cellular activities in bacteria are organized according to their growth rate. The notion that ppGpp measures the cell’s growth rate is well accepted in the field of bacterial physiology. However, despite decades of interrogation and the identification of multiple molecular interactions that connects ppGpp to some aspects of cell growth, we lack a system-level, quantitative picture of how this alleged “measurement” is performed. Through quantitative experiments, we show that the ppGpp pool responds inversely to the rate of translational elongation in Escherichia coli . Together with its roles in inhibiting ribosome biogenesis and activity, ppGpp closes a key regulatory circuit that enables the cell to perceive and control the rate of its growth across conditions. The celebrated linear growth law relating the ribosome content and growth rate emerges as a consequence of keeping a supply of ribosome reserves while maintaining elongation rate in slow growth conditions. Further analysis suggests the elongation rate itself is detected by sensing the ratio of dwelling and translocating ribosomes, a strategy employed to collapse the complex, high-dimensional dynamics of the molecular processes underlying cell growth to perceive the physiological state of the whole. 

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4. Energy allocation theory for bacterial growth control in and out of steady state

   https://doi.org/10.1098/rspa.2024.0219  

   Cylke, Arianna; Serbanescu, Diana; Banerjee, Shiladitya (October 2024, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences)

   Efficient allocation of energy resources to key physiological functions allows living organisms to grow and thrive in diverse environments and adapt to a wide range of perturbations. To quantitatively understand how unicellular organisms utilize their energy resources in response to changes in growth environment, we introduce a theory of dynamic energy allocation that describes cellular growth dynamics by partitioning metabolizable energy into key physiological functions: growth, division, cell shape regulation, energy storage and loss through dissipation. By optimizing the energy flux for growth, we develop the equations governing the time evolution of cell morphology and growth rate in diverse environments. The resulting model accurately captures experimentally observed dependencies of bacterial cell size on growth rate, superlinear scaling of metabolic rate with cell size and predicts nutrient-dependent trade-offs between energy expended for growth, division and shape maintenance. By calibrating model parameters with experimental data for the model organismEscherichia coli, our model describes bacterial growth control in dynamic conditions, particularly during nutrient shifts and osmotic shocks. Integrating both the mechanical properties of the cell and underlying biochemical regulation, our model predicts the driving factors behind a wide range of observed morphological and growth phenomena with minimal added complexity. 

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5. Bacterial Homologs of Progestin and AdipoQ Receptors (PAQRs) Affect Membrane Energetics Homeostasis but Not Fluidity

   https://doi.org/10.1128/jb.00583-21  

   Melchionna, Maddison V.; Gullett, Jessica M.; Bouveret, Emmanuelle; Shrestha, Him K.; Abraham, Paul E.; Hettich, Robert L.; Alexandre, Gladys (April 2022, Journal of Bacteriology)

   Galperin, Michael Y. (Ed.)

   ABSTRACT Membrane potential homeostasis is essential for cell survival. Defects in membrane potential lead to pleiotropic phenotypes, consistent with the central role of membrane energetics in cell physiology. Homologs of the progestin and AdipoQ receptors (PAQRs) are conserved in multiple phyla of Bacteria and Eukarya . In eukaryotes, PAQRs are proposed to modulate membrane fluidity and fatty acid (FA) metabolism. The role of bacterial homologs has not been elucidated. Here, we use Escherichia coli and Bacillus subtilis to show that bacterial PAQR homologs, which we name “TrhA,” have a role in membrane energetics homeostasis. Using transcriptional fusions, we show that E. coli TrhA (encoded by yqfA ) is part of the unsaturated fatty acid biosynthesis regulon. Fatty acid analyses and physiological assays show that a lack of TrhA in both E. coli and B. subtilis (encoded by yplQ ) provokes subtle but consistent changes in membrane fatty acid profiles that do not translate to control of membrane fluidity. Instead, membrane proteomics in E. coli suggested a disrupted energy metabolism and dysregulated membrane energetics in the mutant, though it grew similarly to its parent. These changes translated into a disturbed membrane potential in the mutant relative to its parent under various growth conditions. Similar dysregulation of membrane energetics was observed in a different E. coli strain and in the distantly related B. subtilis . Together, our findings are consistent with a role for TrhA in membrane energetics homeostasis, through a mechanism that remains to be elucidated. IMPORTANCE Eukaryotic homologs of the progestin and AdipoQ receptor family (PAQR) have been shown to regulate membrane fluidity by affecting, through unknown mechanisms, unsaturated fatty acid (FA) metabolism. The bacterial homologs studied here mediate small and consistent changes in unsaturated FA metabolism that do not seem to impact membrane fluidity but, rather, alter membrane energetics homeostasis. Together, the findings here suggest that bacterial and eukaryotic PAQRs share functions in maintaining membrane homeostasis (fluidity in eukaryotes and energetics for bacteria with TrhA homologs). 

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