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Christine Jacobs‐Wagner

Mechanical Engineering · Yale University  high

研究方向

方向提炼待补(distill 阶段生成)。

该校申请信息 · Yale University

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近三年论文 · 55 篇 (点击展开摘要,时间倒序)

Bactofilins are essential spatial organizers of peptidoglycan insertion in the Lyme disease spirochete <i>Borrelia burgdorferi</i>
Journal of Bacteriology · 2026 · cited 0 · doi.org/10.1128/jb.00198-26
ABSTRACT The Lyme disease spirochete Borrelia burgdorferi has a distinctive pattern of growth. Newly born cells elongate by primarily inserting peptidoglycan at mid-cell, while in longer cells, additional insertion sites form at the one-quarter and three-quarter positions along the cell length. It is not known how peptidoglycan insertion is concentrated at these locations in B. burgdorferi . In other bacteria, multi-protein complexes are known to synthesize new peptidoglycan, and are often organized by cytoskeletal proteins. We show here that B. burgdorferi ’s zonal concentration of peptidoglycan insertion requires BB0538 (BbbF) and BB0245 (BbbG), two members of the bactofilin class of cytoskeletal proteins. Bactofilin depletion redistributed peptidoglycan insertion along the cell length. Prolonged bactofilin depletion arrested growth in culture and induced extensive cell blebbing, indicating that B. burgdorferi bactofilins are essential for viability. Fluorescent protein fusions of BbbF and BbbG localized to new zones of growth before peptidoglycan insertion occurred at these sites, with BbbG localization dependent on BbbF. Our results show that BbbF and BbbG direct the spatial patterning of new peptidoglycan insertion in B. burgdorferi . IMPORTANCE The spirochetal bacterium Borrelia burgdorferi causes Lyme disease, the most prevalent vector-borne infection in North America and Europe. Cellular replication, which requires growth and division of the peptidoglycan cell wall, facilitates B. burgdorferi transmission to, and dissemination within, new hosts. Cellular replication is therefore essential for pathogenesis. Bactofilins regulate peptidoglycan-related processes in several bacteria but are typically non-essential for cellular replication. Bactofilin-encoding genes can be readily deleted in multiple bacterial species. In contrast, we show that the B. burgdorferi bactofilins BbbF and BbbG are essential for cellular viability and direct zonal peptidoglycan insertion. Our findings broaden the spectrum of known bactofilin functions and advance our understanding of how peptidoglycan insertion is regulated in this unusual, medically important spirochetal bacterium.
Explosive cytotoxicity of ruptoblasts bridges hormone surveillance and immune defense
Cell · 2026 · cited 1 · doi.org/10.1016/j.cell.2026.05.008
Current understanding of cytotoxic immunity is shaped by hematopoietic-derived cells-T cells, natural killer cells, and neutrophils. Here, we identify "ruptoblasts," a previously unknown cytotoxic glandular cell type in regenerative planarian flatworms. Ruptoblasts undergo an explosive cell death, "ruptosis," triggered by activin, a multifunctional hormone acting as an inflammatory cytokine. Excessive activin-induced through protein injection, genetic chimerism, or bacterial infection-initiates ruptosis, discharging potent diffusible cytotoxic agents capable of eliminating nearby cells, bacteria, and even mammalian cells within minutes. Ruptoblast ablation suppresses inflammation but compromises bacterial clearance, highlighting their broad-spectrum immune functions. Mechanistically distinct from known cytotoxic and cell death mechanisms, the explosive nature of ruptosis relies on endoplasmic reticulum (ER)-derived calcium and cytoskeleton-dependent signal amplification. Ruptoblast-like cells appear conserved in diverse basal bilaterians, implying an ancient evolutionary origin. These findings unveil a strategy coupling hormonal regulation with immune defense and expand the landscape of evolutionary immune innovations.
A lipid compendium of a metabolically compromised bacterium provides insights into lipid acquisition, biosynthesis, and metabolism
bioRxiv (Cold Spring Harbor Laboratory) · 2026 · cited 0 · doi.org/10.64898/2026.05.22.727245
Summary The Lyme disease agent Borrelia burgdorferi belongs to a class of metabolically compromised bacteria that cannot survive without host-derived lipids. Survival of the agent in tick and vertebrate hosts requires substantial nutrient acquisition and potential cell envelope remodeling. While prior studies identified cholesterol, cholesterol glycolipids, and phosphatidylcholines as membrane lipids in B. burgdorferi , the identity of many other membrane lipids, their origin, and their physiological relevance remain unknown. Here, we used a suite of untargeted and targeted high-resolution mass spectrometry methods to reveal a complex lipid profile of the pathogen and to identify the origin of its lipids. The analysis detected more than 500 lipids in B. burgdorferi , the majority of which are sourced from the environment. However, the bacterium selectively accumulates certain lipids while excluding others, suggesting discriminatory uptake. These include cholesteryl esters and triglycerides that are organized in foci within the pathogen. Intriguingly, the pathogen also synthesizes predominantly eukaryotic lipids such as the lysosomal bis(monoacylglycerol)phosphate and the plant glycolipid sulfoquinovosyl diacylglycerol (SQDG). The biosynthesis of the latter is carried out by enzymes that exhibit structural homology to plant oxidoreductases and galactosyltransferases, yet their closest orthologs are found in bacteria. This hints that the capability of SQDG synthesis is more widespread in spirochaetes and other bacteria. Together, the comprehensive lipid profiling we report here uncovers novel aspects of the physiology of the metabolically challenged B. burgdorferi and highlights lipid acquisition and synthesis pathways as potentially critical for pathogen survival.
Utilizing single-cell fluorescence time-lapse imaging to investigate the bactericidal mechanism of negamycin in Escherichia coli
Stanford Digital Repository · 2026 · cited 0 · doi.org/10.25740/yp945tn8200
Protein synthesis inhibitors are some of the most commonly used antibiotics in clinical settings for treating bacterial infections. While prior work has shed light on how protein synthesis inhibitors affect ribosomal translation at the molecular level, the mechanism by which translation inhibition leads to bacterial cell death remains unclear. In particular, the bactericidal protein synthesis inhibitor negamycin and its effects on cell-wide phenotypes remain understudied. Unlike the bactericidal aminoglycoside class of protein synthesis inhibitors, negamycin exhibits less acute toxicity and thus could be a clinically relevant alternative. Prior work has shown that negamycin acts primarily by binding to the 16S rRNA site on the bacterial ribosome and inducing translational miscoding. However, to my knowledge, no studies have been conducted in an in vivo context to demonstrate how negamycin impacts the cell as a whole. In this study, I utilize time-lapse imaging of fluorescently tagged Escherichia coli cells treated with negamycin to directly visualize changes in subcellular organization, membrane permeability, and protein aggregation at the single-cell level. I found that, upon treatment with negamycin at the minimum inhibitory concentration, almost all examined E. coli cells rapidly form large protein aggregates, while a few eventually undergo membrane permeabilization and changes in nucleoid and ribosome localization long after treatment. This indicates that negamycin-induced miscoding is followed by aggregation of misfolded proteins, which may contribute to other cell-wide effects and eventually cell death. The heterogeneity and timing of membrane permeabilization suggest that membrane permeabilization is not involved in the killing mechanism of negamycin.
Priority effects drive fungal and nematode emergence from insect larvae
FEMS Microbiology Ecology · 2025 · cited 0 · doi.org/10.1093/femsec/fiag036
Priority effects, in which species arrival history influences community assembly, are increasingly recognized to affect host-parasite systems. However, priority effects across disparate groups of parasitic organisms are poorly understood despite the wide range of taxonomic groups involved. In California oak woodland, we investigated how priority effects between two insect-parasitic fungi (Metarhizium and Beauveria) influenced emergence of nematodes from insect larvae. Field and laboratory results indicated that both fungi were common, but priority effects prevented them from co-emerging from the same larva. Metarhizium- and Beauveria-infected insects did not differ in the species composition of emerging nematodes, but larvae without fungal emergence had distinct nematode communities, with Oscheius almost always emerging without fungi. Experiments indicated that none of the commonly found nematodes (Acrobeloides, Mesorhabditis, Oscheius, and Rhabditis) were entomopathogenic, but that Oscheius could exclude Beauveria if it arrived early. This time-dependent exclusion was likely caused by a bacterium that Oscheius nematodes carried (Serratia proteamaculans). Together, these findings suggest that fungi enter insects as primary arrivers, while nematodes come as secondary arrivers to exploit fungus-killed insects, with priority effects influencing both groups. We suggest that this system is a promising natural microcosm for understanding priority effects across disparate groups in host-parasite systems.
Cross-Molecular Active Learning for the Discovery of Antimicrobial Polyacrylamides
bioRxiv (Cold Spring Harbor Laboratory) · 2025 · cited 0 · doi.org/10.1101/2025.11.07.687243
ABSTRACT Antimicrobial resistance poses an urgent and increasing threat to global health. The development of new antimicrobials is crucial. Synthetic copolymers are attractive as a potential solution, because they can be produced at scale and designed to mimic antimicrobial peptides and act as broad-spectrum antimicrobials capable of evading resistance mechanisms. This work leverages a cross-molecular machine learning pipeline, trained on antimicrobial peptides, to develop potent antimicrobial polymers to combat Escherichia coli , which were then synthesized and validated experimentally. One candidate copolymer was further characterized and shown to permeabilize the bacterial membrane, which is associated with decreased resistance. Furthermore, this copolymer demonstrated remarkable synergy in eradicating biofilm-associated E. coli when combined with a first-line clinical drug regimen, reducing the amount needed to eradicate bacteria in biofilms by three orders of magnitude. These results demonstrate promise for potentiating antibacterial activity of currently available antibiotics, treating serious and complicated infections, and combatting antimicrobial resistance.
Glycogen phase-separation drives macromolecular rearrangement and asymmetric division in E. coli
The EMBO Journal · 2025 · cited 3 · doi.org/10.1038/s44318-025-00621-y
Abstract Bacteria often experience nutrient limitation. While the exponential and stationary growth phases have been characterized in the model bacterium Escherichia coli , little is known about what happens inside individual cells during the transition between these two phases. Through quantitative cell imaging, we found that the positions of nucleoids and cell division sites become increasingly asymmetric during the transition phase. These asymmetries were accompanied by an asymmetric reorganization of protein, ribosome, and RNA probes in the cytoplasm. Results from live-cell imaging experiments, complemented with genetic and 13 C whole-cell nuclear magnetic resonance spectroscopy studies, show that preferential accumulation of the storage polymer glycogen at the old cell pole leads to the observed rearrangements and asymmetric divisions. Live-cell atomic force microscopy analysis, combined with in vitro biochemical experiments, suggests that these phenotypes are due to the propensity of glycogen to phase-separate into soft condensates in the crowded cytoplasm. Glycogen-associated differences in cell sizes between strains and future daughter cells suggest that glycogen phase-separation allows cells to store large glucose reserves that are not perceived by the cell as cytoplasmic space.
Bacterial and host enzymes modulate the pro-inflammatory response elicited by the peptidoglycan of Lyme disease agent Borrelia burgdorferi
PLoS Pathogens · 2025 · cited 7 · doi.org/10.1371/journal.ppat.1013324
The spirochete Borrelia burgdorferi causes Lyme disease. In some patients, an excessive, dysregulated proinflammatory immune response can develop in joints leading to persistent arthritis even after antibiotic therapy. In such patients, persistence of antigenic B. burgdorferi peptidoglycan (PGBb) fragments within joint tissues may contribute to immunopathogenesis pre- and post-antibiotic treatment. In live B. burgdorferi cells, the outer membrane shields the polymeric PGBb sacculus from exposure to the immune system. However, unlike most diderm bacteria, B. burgdorferi releases PGBb turnover products into its environment due to the absence of recycling activity. In this study, we identified the released PGBb fragments using a mass spectrometry-based approach. By characterizing the l,d-carboxypeptidase activity of B. burgdorferi protein BB0605 (renamed DacA), we found that PGBb turnover largely occurs at sites of PGBb synthesis. In parallel, we demonstrated that the lytic transglycosylase activity associated with BB0259 (renamed MltS) releases PGBb fragments with 1,6-anhydro bond on their N-acetylmuramyl residues. Stimulation of human cell lines with various synthetic PGBb fragments revealed that 1,6-anhydromuramyl-containing PGBb fragments are poor inducers of a NOD2-dependent immune response relative to their hydrated counterparts found in the polymeric PGBb isolated from dead bacteria. We also showed that the activity of the human N-acetylmuramyl-l-alanine amidase PGLYRP2, which reduces the immunogenicity of PGBb material, is low in joint (synovial) fluids relative to serum. Altogether, our findings suggest that MltS activity helps B. burgdorferi evade PG-based immune detection by NOD2 during growth despite shedding PGBb fragments and that PGBb-induced immunopathology likely results from host sensing of PGBb material from dead (lysed) spirochetes. Additionally, our results suggest the possibility that natural variation in PGLYRP2 activity may contribute to differences in susceptibility to PG-induced inflammation across tissues and individuals.
Nonequilibrium polysome dynamics promote chromosome segregation and its coupling to cell growth in Escherichia coli
eLife · 2025 · cited 6 · doi.org/10.7554/elife.104276.3
Chromosome segregation is essential for cellular proliferation. Unlike eukaryotes, bacteria lack cytoskeleton-based machinery to segregate their chromosomal DNA (nucleoid). The bacterial ParABS system segregates the duplicated chromosomal regions near the origin of replication. However, this function does not explain how bacterial cells partition the rest (bulk) of the chromosomal material. Furthermore, some bacteria, including Escherichia coli , lack a ParABS system. Yet, E. coli faithfully segregates nucleoids across various growth rates. Here, we provide theoretical and experimental evidence that polysome production during chromosomal gene expression helps compact, split, segregate, and position nucleoids in E. coli through nonequilibrium dynamics that depend on polysome synthesis, degradation (through mRNA decay), and exclusion from the DNA meshwork. These dynamics inherently couple chromosome segregation to biomass growth across nutritional conditions. Halting chromosomal gene expression and thus polysome production immediately stops sister nucleoid migration, while ensuing polysome depletion gradually reverses nucleoid segregation. Redirecting gene expression away from the chromosome and toward plasmids causes ectopic polysome accumulations that are sufficient to drive aberrant nucleoid dynamics. Cell width enlargement experiments suggest that limiting the exchange of polysomes across DNA-free regions ensures nucleoid segregation along the cell length. Our findings suggest a self-organizing mechanism for coupling nucleoid compaction and segregation to cell growth without the apparent requirement of regulatory molecules.
Author response: Nonequilibrium polysome dynamics promote chromosome segregation and its coupling to cell growth in Escherichia coli
· 2025 · cited 2 · doi.org/10.7554/elife.104276.3.sa4
Polysome formation within the nucleoid and repulsion between these major cytoplasmic components provide a self-organizing mechanism for chromosome segregation and modulation of its timing across growth rates in Escherichia coli.
Glycogen phase separation drives macromolecular rearrangement and asymmetric division in E. coli
· 2025 · cited 0 · doi.org/10.6019/s-biad2088
Funder: Howard Hughes Medical Institute (HHMI); doi: http://dx.doi.org/10.13039/100000011
The polyadenylase PAPI is required for virulence plasmid maintenance in pathogenic bacteria
PLoS Pathogens · 2025 · cited 4 · doi.org/10.1371/journal.ppat.1012655
Many species of pathogenic bacteria harbor critical plasmid-encoded virulence factors, and yet the regulation of plasmid replication is often poorly understood despite playing a key role in plasmid-encoded gene expression. Human pathogenic Yersinia, including the plague agent Yersinia pestis and its close relative Y. pseudotuberculosis, require the type III secretion system (T3SS) virulence factor to subvert host defense mechanisms and colonize host tissues. The Yersinia T3SS is encoded on the IncFII plasmid for Yersinia virulence (pYV). Several layers of gene regulation enable a large increase in expression of Yersinia T3SS genes at mammalian body temperature. Surprisingly, T3SS expression is also controlled at the level of gene dosage. The number of pYV molecules relative to the number of chromosomes per cell, referred to as plasmid copy number, increases with temperature. The ability to increase and maintain elevated pYV plasmid copy number, and therefore T3SS gene dosage, at 37˚C is important for Yersinia virulence. In addition, pYV is highly stable in Yersinia at all temperatures, despite being dispensable for growth outside the host. Yet how Yersinia reinforces elevated plasmid replication and plasmid stability remains unclear. In this study, we show that the chromosomal gene pcnB encoding the polyadenylase PAP I is required for regulation of pYV plasmid copy number (PCN), maintenance of pYV in the bacterial population outside the host, robust T3SS activity, and Yersinia virulence in a mouse infection model. Likewise, pcnB/PAP I is required for robust expression of the Shigella flexneri T3SS that, similar to Yersinia, is encoded on a virulence plasmid whose replication is regulated by sRNA. Furthermore, Yersinia and Shigella pcnB/PAP I is required for maintaining model antimicrobial resistance (AMR) plasmids whose replication is regulated by sRNA, thereby increasing antibiotic resistance by ten-fold. These data suggest that pcnB/PAP I contributes to the spread and stabilization of sRNA-regulated virulence and AMR plasmids in bacterial pathogens, and is essential in maintaining the gene dosage required to mediate plasmid-encoded traits. Importantly pcnB/PAP I has been bioinformatically identified in many species of bacteria despite being studied in only a few species to date. Our work highlights the potential importance of pcnB/PAP I in antibiotic resistance, and shows for the first time that pcnB/PAP I promotes virulence plasmid stability in natural pathogenic hosts with a direct impact on bacterial virulence.
Nonequilibrium polysome dynamics promote chromosome segregation and its coupling to cell growth in Escherichia coli
eLife · 2025 · cited 2 · doi.org/10.7554/elife.104276.2
Abstract Chromosome segregation is essential for cellular proliferation. Unlike eukaryotes, bacteria lack cytoskeleton-based machinery to segregate their chromosomal DNA (nucleoid). The bacterial ParABS system segregates the duplicated chromosomal regions near the origin of replication. However, this function does not explain how bacterial cells partition the rest (bulk) of the chromosomal material. Furthermore, some bacteria, including Escherichia coli, lack a ParABS system. Yet, E. coli faithfully segregates nucleoids across various growth rates. Here, we provide theoretical and experimental evidence that polysome production during chromosomal gene expression helps compact, split, segregate, and position nucleoids in E. coli through out-of-equilibrium dynamics and polysome exclusion from the DNA meshwork, inherently coupling these processes to biomass growth across nutritional conditions. Halting chromosomal gene expression and thus polysome production immediately stops sister nucleoid migration while ensuing polysome depletion gradually reverses nucleoid segregation. Redirecting gene expression away from the chromosome and toward plasmids causes ectopic polysome accumulations that are sufficient to drive aberrant nucleoid dynamics. Cell width enlargement suggest that the proximity of the DNA to the membrane along the radial axis is important to limit the exchange of polysomes across DNA-free regions, ensuring nucleoid segregation along the cell length. Our findings suggest a self-organizing mechanism for coupling nucleoid segregation to cell growth.
Author response: Nonequilibrium polysome dynamics promote chromosome segregation and its coupling to cell growth in Escherichia coli
· 2025 · cited 0 · doi.org/10.7554/elife.104276.2.sa0
Chromosome segregation is essential for cellular proliferation. Unlike eukaryotes, bacteria lack cytoskeleton-based machinery to segregate their chromosomal DNA (nucleoid). The bacterial ParABS system segregates the duplicated chromosomal regions near the origin of replication. However, this function does not explain how bacterial cells partition the rest (bulk) of the chromosomal material. Furthermore, some bacteria, including Escherichia coli, lack a ParABS system. Yet, E. coli faithfully segregates nucleoids across various growth rates. Here, we provide theoretical and experimental evidence that polysome production during chromosomal gene expression helps compact, split, segregate, and position nucleoids in E. coli through out-of-equilibrium dynamics and polysome exclusion from the DNA meshwork, inherently coupling these processes to biomass growth across nutritional conditions. Halting chromosomal gene expression and thus polysome production immediately stops sister nucleoid migration while ensuing polysome depletion gradually reverses nucleoid segregation. Redirecting gene expression away from the chromosome and toward plasmids causes ectopic polysome accumulations that are sufficient to drive aberrant nucleoid dynamics. Cell width enlargement suggest that the proximity of the DNA to the membrane along the radial axis is important to limit the exchange of polysomes across DNA-free regions, ensuring nucleoid segregation along the cell length. Our findings suggest a self-organizing mechanism for coupling nucleoid segregation to cell growth.
Time-resolved phenotyping at subcellular resolution reveals shared principles and key trade-offs across antimicrobial peptide activities
bioRxiv (Cold Spring Harbor Laboratory) · 2025 · cited 1 · doi.org/10.1101/2025.04.10.648262
ABSTRACT Cationic antimicrobial peptides are a large family of host defense molecules with diverse sequences and structures. Here, we present a computational and experimental pipeline for time-resolved quantification of both membrane-permeabilizing and intracellular effects in Escherichia coli . Applying this pipeline to 12 diverse natural peptides and synthetic peptidomimetics uncovers shared antimicrobial activities, but with different kinetics, forming two classes. With class I peptides, growth arrest is abrupt and predominantly coupled with inner membrane permeabilization and ribosome/DNA reorganization. However, membrane permeabilization leads to rapid peptide absorption by the first exposed bacterial cells, resulting in low efficacy against dense populations. With class II peptides, ribosome/DNA reorganization and growth inhibition occur more gradually, as inner membrane permeabilization is either absent or delayed. This is offset by slower intracellular peptide uptake and greater efficacy against high cell densities. These kinetic differences reveal functional trade-offs between classes that have major immunological and therapeutic implications.
Time-resolved phenotyping at subcellular resolution reveals shared principles and key trade-offs across antimicrobial peptide activities
· 2025 · cited 0 · doi.org/10.6019/s-biad1823
Bactofilins are essential spatial organizers of peptidoglycan insertion in the Lyme disease spirochete <i>Borrelia burgdorferi</i>
bioRxiv (Cold Spring Harbor Laboratory) · 2025 · cited 0 · doi.org/10.1101/2025.04.09.647816
ABSTRACT The Lyme disease spirochete Borrelia burgdorferi has a distinctive pattern of growth. Newly-born cells elongate by primarily inserting peptidoglycan at mid-cell, while in longer cells, additional insertion sites form at the one-quarter and three-quarter positions along the cell length. It is not known how peptidoglycan insertion is concentrated at these locations in B. burgdorferi. In other bacteria, multi-protein complexes are known to synthesize new peptidoglycan and are often organized by cytoskeletal proteins. We show here that B. burgdorferi ’s zonal concentration of peptidoglycan insertion requires BB0538 (BbbA) and BB0245 (BbbB), two members of the bactofilin class of cytoskeletal proteins. Bactofilin depletion redistributes peptidoglycan insertion along the cell length. Prolonged bactofilin depletion arrested growth in culture and induced extensive cell blebbing, indicating that B. burgdorferi bactofilins are essential for viability. Fluorescent protein fusions of BbbA and BbbB localized to areas of peptidoglycan insertion, with BbbB accumulation preceding peptidoglycan insertion at these sites. Similar to peptidoglycan insertion, BbbB localization was disrupted upon depletion of BbbA. Our results show that BbbB relies on BbbA for its localization, and that together, BbbA and BbbB direct the spatial patterning of new peptidoglycan insertion in B. burgdorferi . IMPORTANCE The spirochetal bacterium Borrelia burgdorferi causes Lyme disease, the most prevalent vector-borne infection in North America and Europe. Cellular replication, which requires growth and division of the peptidoglycan cell wall, facilitates B. burgdorferi transmission to, and dissemination within, new hosts. Cellular replication is therefore essential for pathogenesis. Bactofilins regulate peptidoglycan-related processes in several bacteria. However, these functions are typically non-essential for cellular replication, as bactofilin-encoding genes can be readily deleted in multiple bacterial species. In contrast, we show that the B. burgdorferi bactofilins BbbA and BbbB are essential for cellular viability and direct zonal peptidoglycan insertion. Our findings broaden the spectrum of known bactofilin functions and advance our understanding of how peptidoglycan insertion is regulated in this unusual, medically important spirochete bacterium.
Explosive cytotoxicity of ‘ruptoblasts’ bridges hormonal surveillance and immune defense
bioRxiv (Cold Spring Harbor Laboratory) · 2025 · cited 1 · doi.org/10.1101/2025.03.28.645876
Current understanding of cytotoxic immunity is shaped by hematopoietic-derived cells - T cells, natural killer cells, and neutrophils. Here, we identify 'ruptoblasts', a previously unknown cytotoxic glandular cell type in regenerative planarian flatworms. Ruptoblasts undergo an explosive cell death, 'ruptosis', triggered by activin, a multifunctional hormone that also acts as an inflammatory cytokine. Excessive activin - induced through protein injection, genetic chimerism, or bacterial infection - initiates ruptosis, discharging potent diffusible cytotoxic agents capable of eliminating any nearby cells, bacteria, and even mammalian cells within minutes. Ruptoblast ablation suppresses inflammation but compromises bacterial clearance, highlighting their broad-spectrum immune functions. Mechanistically distinct from known cytotoxic mechanisms, the explosive nature of ruptosis relies on intracellular calcium and dynamic cytoskeletal reorganization. Ruptoblast-like cells appear conserved in diverse basal bilaterians, implying an ancient evolutionary origin. These findings unveil a widespread strategy coupling hormonal regulation with immune defense and expand the landscape of evolutionary immune innovations.
DNA/polysome phase separation and cell width confinement couple nucleoid segregation to cell growth in Escherichia coli
· 2025 · cited 1 · doi.org/10.6019/s-biad1658
<i>Borrelia burgdorferi</i> loses essential genetic elements and cell proliferative potential during stationary phase in culture but not in the tick vector
Journal of Bacteriology · 2025 · cited 4 · doi.org/10.1128/jb.00457-24
ABSTRACT The Lyme disease agent Borrelia burgdorferi is a polyploid bacterium with a segmented genome in which both the chromosome and over 20 distinct plasmids are present in multiple copies per cell. This pathogen can survive for at least 9 months in its tick vector in an apparent dormant state between blood meals, without losing cell proliferative capability when re-exposed to nutrients. Cultivated B. burgdorferi cells grown to stationary phase or resuspended in nutrient-limited media are often used to study the effects of nutrient deprivation. However, a thorough assessment of the spirochete’s ability to recover from nutrient depletion has been lacking. Our study shows that starved B. burgdorferi cultures rapidly lose cell proliferative ability. Loss of genetic elements essential for cell proliferation contributes to the observed proliferative defect in stationary phase. The gradual decline in copies of genetic elements is not perfectly synchronized between chromosomes and plasmids, generating cells that harbor one or more copies of the essential chromosome but lack all copies of one or more non-essential plasmids. This phenomenon likely contributes to the well-documented issue of plasmid loss during in vitro cultivation of B. burgdorferi . In contrast, B. burgdorferi cells from ticks starved for 14 months showed no evidence of reduced cell proliferative ability or plasmid loss. Beyond their practical implications for studying B. burgdorferi , these findings suggest that the midgut of the tick vector offers a unique environment that supports the maintenance of B. burgdorferi ’s segmented genome and cell proliferative potential during periods of tick fasting. IMPORTANCE Borrelia burgdorferi causes Lyme disease, a prevalent tick-borne illness. B. burgdorferi must survive long periods (months to a year) of apparent dormancy in the midgut of the tick vector between blood meals. Resilience to starvation is a common trait among bacteria. However, this study reveals that, in laboratory cultures, B. burgdorferi poorly endures starvation and rapidly loses viability. This decline is linked to a gradual loss of genetic elements required for cell proliferation. These results suggest that the persistence of B. burgdorferi in nature is likely shaped more by unique environmental conditions in the midgut of the tick vector than by an innate ability of this bacterium to endure nutrient deprivation.
DNA/polysome phase separation and cell width confinement couple nucleoid segregation to cell growth in Escherichia coli
eLife · 2025 · cited 4 · doi.org/10.7554/elife.104276.1
Abstract Chromosome segregation is essential for cellular proliferation. Unlike eukaryotes, bacteria lack cytoskeleton-based machinery to segregate their chromosomal DNA (nucleoid). The bacterial ParABS system segregates the duplicated chromosomal regions near the origin of replication. However, this function does not explain how bacterial cells partition the rest (bulk) of the chromosomal material. Furthermore, some bacteria, including Escherichia coli, lack a ParABS system. Yet, E. coli faithfully segregates nucleoids across various growth rates. Here, we provide theoretical and experimental evidence that polysome production during chromosomal gene expression helps compact, split, segregate, and position nucleoids in E. coli through phase separation, inherently coupling these processes to biomass growth across nutritional conditions. Halting polysome formation immediately stops sister nucleoid migration while ensuing polysome depletion gradually reverses nucleoid segregation. Redirecting gene expression away from the chromosome and toward plasmids arrests nucleoid segregation and causes ectopic polysome accumulations that drive aberrant nucleoid dynamics. Cell width perturbations show that radial confinement of polysomes and nucleoids spatially controls their phase separation to ensure that nucleoids split along the cell width and segregate along the cell length. Our findings suggest a built-in mechanism for coupling chromosome segregation to cell growth and highlight the importance of cell width regulation in nucleoid segregation.
Nonequilibrium polysome dynamics promote chromosome segregation and its coupling to cell growth in Escherichia coli
eLife · 2025 · cited 2 · doi.org/10.7554/elife.104276
Chromosome segregation is essential for cellular proliferation. Unlike eukaryotes, bacteria lack cytoskeleton-based machinery to segregate their chromosomal DNA (nucleoid). The bacterial ParABS system segregates the duplicated chromosomal regions near the origin of replication. However, this function does not explain how bacterial cells partition the rest (bulk) of the chromosomal material. Furthermore, some bacteria, including Escherichia coli , lack a ParABS system. Yet, E. coli faithfully segregates nucleoids across various growth rates. Here, we provide theoretical and experimental evidence that polysome production during chromosomal gene expression helps compact, split, segregate, and position nucleoids in E. coli through nonequilibrium dynamics that depend on polysome synthesis, degradation (through mRNA decay), and exclusion from the DNA meshwork. These dynamics inherently couple chromosome segregation to biomass growth across nutritional conditions. Halting chromosomal gene expression and thus polysome production immediately stops sister nucleoid migration, while ensuing polysome depletion gradually reverses nucleoid segregation. Redirecting gene expression away from the chromosome and toward plasmids causes ectopic polysome accumulations that are sufficient to drive aberrant nucleoid dynamics. Cell width enlargement experiments suggest that limiting the exchange of polysomes across DNA-free regions ensures nucleoid segregation along the cell length. Our findings suggest a self-organizing mechanism for coupling nucleoid compaction and segregation to cell growth without the apparent requirement of regulatory molecules.
Author response: DNA/polysome phase separation and cell width confinement couple nucleoid segregation to cell growth in Escherichia coli
· 2025 · cited 0 · doi.org/10.7554/elife.104276.1.sa0
Chromosome segregation is essential for cellular proliferation. Unlike eukaryotes, bacteria lack cytoskeleton-based machinery to segregate their chromosomal DNA (nucleoid). The bacterial ParABS system segregates the duplicated chromosomal regions near the origin of replication. However, this function does not explain how bacterial cells partition the rest (bulk) of the chromosomal material. Furthermore, some bacteria, including Escherichia coli, lack a ParABS system. Yet, E. coli faithfully segregates nucleoids across various growth rates. Here, we provide theoretical and experimental evidence that polysome production during chromosomal gene expression helps compact, split, segregate, and position nucleoids in E. coli through phase separation, inherently coupling these processes to biomass growth across nutritional conditions. Halting polysome formation immediately stops sister nucleoid migration while ensuing polysome depletion gradually reverses nucleoid segregation. Redirecting gene expression away from the chromosome and toward plasmids arrests nucleoid segregation and causes ectopic polysome accumulations that drive aberrant nucleoid dynamics. Cell width perturbations show that radial confinement of polysomes and nucleoids spatially controls their phase separation to ensure that nucleoids split along the cell width and segregate along the cell length. Our findings suggest a built-in mechanism for coupling chromosome segregation to cell growth and highlight the importance of cell width regulation in nucleoid segregation.
Apparent simplicity and emergent robustness in the control of the Escherichia coli cell cycle
· 2025 · cited 0 · doi.org/10.6019/s-biad1605
Bacterial and host enzymes modulate the inflammatory response produced by the peptidoglycan of the Lyme disease agent
· 2025 · cited 0 · doi.org/10.6019/s-biad1573
Bacterial and host enzymes modulate the inflammatory response produced by the peptidoglycan of the Lyme disease agent
bioRxiv (Cold Spring Harbor Laboratory) · 2025 · cited 2 · doi.org/10.1101/2025.01.08.631998
The spirochete Borrelia burgdorferi causes Lyme disease. In some patients, an excessive, dysregulated proinflammatory immune response can develop in joints leading to persistent arthritis even after antibiotic therapy. In such patients, persistence of antigenic B. burgdorferi peptidoglycan (PG Bb ) fragments within joint tissues may contribute to immunopathogenesis pre- and post-antibiotic treatment. In live B. burgdorferi cells, the outer membrane shields the polymeric PG Bb sacculus from exposure to the immune system. However, unlike most diderm bacteria, B. burgdorferi releases PG Bb turnover products into its environment due to the absence of recycling activity. In this study, we identified the released PG Bb fragments using a mass spectrometry-based approach. By characterizing the L,D-carboxypeptidase activity of B. burgdorferi protein BB0605 (renamed DacA), we found that PG Bb turnover largely occurs at sites of PG Bb synthesis. In parallel, we demonstrated that the lytic transglycosylase activity associated with BB0259 (renamed MltS) releases PG Bb fragments with 1,6-anhydro bond on their N -acetylmuramyl residues. Stimulation of human cell lines with various synthetic PG Bb fragments revealed that 1,6-anhydromuramyl-containing PG Bb fragments are poor inducers of a NOD2-dependent immune response relative to their hydrated counterparts found in the polymeric PG Bb isolated from dead bacteria. We also showed that the activity of the human N -acetylmuramyl-L-alanine amidase PGLYRP2, which reduces the immunogenicity of PG Bb material, is low in joint (synovial) fluids relative to serum. Altogether, our findings suggest that MltS activity helps B. burgdorferi evade PG-based immune detection by NOD2 during growth despite shedding PG Bb fragments and that PG Bb -induced immunopathology likely results from host sensing of PG Bb material from dead (lysed) spirochetes. Additionally, our results suggest the possibility that natural variation in PGLYRP2 activity may contribute to differences in susceptibility to PG-induced inflammation across tissues and individuals. Author summary During bacterial infection, the presence of peptidoglycan– a polymeric element of bacterial cell walls–triggers a host inflammatory response. Although generally protective during acute phases, inflammation, when chronic, can contribute to disease development. Recent work has suggested that the persistence of pro-inflammatory peptidoglycan derived from the Lyme disease spirochete Borrelia burgdorferi in joints may contribute to persistent arthritis in some patients despite appropriate antibiotic therapy. Interestingly, B. burgdorferi sheds peptidoglycan turnover products into the environment during growth. Here, we show that these shed products from live spirochetes are poor effectors of an immune response by the human NOD2 immune receptor due to the formation of an anhydro bond on the N -acetyl-muramic residue during peptidoglycan hydrolysis by a B. burgdorferi lytic transglycosylase. We also show that human N -acetylmuramyl-L-alanine amidase activity, which abrogates the NOD2-dependent response to the immunogenic peptidoglycan isolated from lysed B. burgdorferi cells, is low in human joint fluids relative to serum. Based on our findings, we propose that immunopathogenesis by peptidoglycan material more likely derives from lysed spirochetes (killed by an immune attack or antibiotics) than live ones and that the level of human peptidoglycan hydrolytic enzymes across tissues and individuals influences susceptibility to chronic inflammation.
Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
eLife · 2024 · cited 4 · doi.org/10.7554/elife.97465.3
Defining the cellular factors that drive growth rate and proteome composition is essential for understanding and manipulating cellular systems. In bacteria, ribosome concentration is known to be a constraining factor of cell growth rate, while gene concentration is usually assumed not to be limiting. Here, using single-molecule tracking, quantitative single-cell microscopy, and modeling, we show that genome dilution in Escherichia coli cells arrested for DNA replication limits total RNA polymerase activity within physiological cell sizes across tested nutrient conditions. This rapid-onset limitation on bulk transcription results in sub-linear scaling of total active ribosomes with cell size and sub-exponential growth. Such downstream effects on bulk translation and cell growth are near-immediately detectable in a nutrient-rich medium, but delayed in nutrient-poor conditions, presumably due to cellular buffering activities. RNA sequencing and tandem-mass-tag mass spectrometry experiments further reveal that genome dilution remodels the relative abundance of mRNAs and proteins with cell size at a global level. Altogether, our findings indicate that chromosome concentration is a limiting factor of transcription and a global modulator of the transcriptome and proteome composition in E. coli . Experiments in Caulobacter crescentus and comparison with eukaryotic cell studies identify broadly conserved DNA concentration-dependent scaling principles of gene expression.
Author response: Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
· 2024 · cited 1 · doi.org/10.7554/elife.97465.3.sa4
<i>Borrelia burgdorferi</i> loses essential genetic elements and cell proliferative potential during stationary phase in culture but not in the tick vector
bioRxiv (Cold Spring Harbor Laboratory) · 2024 · cited 1 · doi.org/10.1101/2024.10.28.620338
Abstract The Lyme disease agent Borrelia burgdorferi is a polyploid bacterium with a segmented genome in which both the chromosome and over 20 distinct plasmids are present in multiple copies per cell. This pathogen can survive at least nine months in its tick vector in an apparent dormant state between blood meals, without losing cell proliferative capability when re-exposed to nutrients. Cultivated B. burgdorferi cells grown to stationary phase or resuspended in nutrient-limited media are often used to study the effects of nutrient deprivation. However, a thorough assessment of the spirochete’s ability to recover from nutrient depletion has been lacking. Our study shows that starved B. burgdorferi cultures rapidly lose cell proliferative. Loss of genetic elements essential for cell proliferation contributes to the observed proliferative defect in stationary phase. The gradual decline in copies of genetic elements is not perfectly synchronized between chromosomes and plasmids, generating cells that harbor one or more copies of the essential chromosome but lack all copies of one or more non-essential plasmids. This phenomenon likely contributes to the well-documented issue of plasmid loss during in vitro cultivation of B. burgdorferi . In contrast, B. burgdorferi cells from ticks starved for 14 months showed no evidence of reduced cell proliferative ability or plasmid loss. Beyond their practical implications for studying B. burgdorferi , these findings suggest that the midgut of the tick vector offers a unique environment that supports the maintenance of B. burgdorferi ’s segmented genome and cell proliferative potential during periods of tick fasting. Importance Borrelia burgdorferi causes Lyme disease, a prevalent tick-borne illness. B. burgdorferi must survive long periods (months to a year) of apparent dormancy in the midgut of the tick vector between blood meals. Resilience to starvation is a common trait among bacteria. However, this study reveals that in laboratory cultures, B. burgdorferi poorly endures starvation and rapidly loses viability. This decline is linked to a gradual loss of genetic elements required for cell proliferation. These results suggest that the persistence of B. burgdorferi in nature is likely shaped more by unique environmental conditions in the midgut of the tick vector than by a general innate ability of this bacterium to endure nutrient deprivation.
Borrelia burgdorferi loses essential genetic elements and cell proliferative potential during stationary phase in culture but not in the tick vector.
· 2024 · cited 0 · doi.org/10.6019/s-biad1428
Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
eLife · 2024 · cited 1 · doi.org/10.7554/elife.97465.2
Abstract Defining the cellular factors that drive growth rate and proteome composition is essential for understanding and manipulating cellular systems. In bacteria, ribosome concentration is known to be a constraining factor of cell growth rate, while gene concentration is usually assumed not to be limiting. Here, using single-molecule tracking, quantitative single-cell microscopy, and modeling, we show that genome dilution in Escherichia coli cells arrested for DNA replication limits total RNA polymerase activity within physiological cell sizes across tested nutrient conditions. This rapid-onset limitation on bulk transcription results in sub-linear scaling of total active ribosomes with cell size and sub-exponential growth. Such downstream effects on bulk translation and cell growth are near-immediately detectable in a nutrient-rich medium, but delayed in nutrient-poor conditions, presumably due to cellular buffering activities. RNA sequencing and tandem-mass-tag mass spectrometry experiments further reveal that genome dilution remodels the relative abundance of mRNAs and proteins with cell size at a global level. Altogether, our findings indicate that chromosome concentration is a limiting factor of transcription and a global modulator of the transcriptome and proteome composition in E. coli. Experiments in Caulobacter crescentus and comparison with eukaryotic cell studies identify broadly conserved DNA concentration-dependent scaling principles of gene expression.
Author response: Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
· 2024 · cited 0 · doi.org/10.7554/elife.97465.2.sa0
Defining the cellular factors that drive growth rate and proteome composition is essential for understanding and manipulating cellular systems. In bacteria, ribosome concentration is known to be a constraining factor of cell growth rate, while gene concentration is usually assumed not to be limiting. Here, using single-molecule tracking, quantitative single-cell microscopy, and modeling, we show that genome dilution in Escherichia coli cells arrested for DNA replication limits total RNA polymerase activity within physiological cell sizes across tested nutrient conditions. This rapid-onset limitation on bulk transcription results in sub-linear scaling of total active ribosomes with cell size and sub-exponential growth. Such downstream effects on bulk translation and cell growth are near-immediately detectable in a nutrient-rich medium, but delayed in nutrient-poor conditions, presumably due to cellular buffering activities. RNA sequencing and tandem-mass-tag mass spectrometry experiments further reveal that genome dilution remodels the relative abundance of mRNAs and proteins with cell size at a global level. Altogether, our findings indicate that chromosome concentration is a limiting factor of transcription and a global modulator of the transcriptome and proteome composition in E. coli. Experiments in Caulobacter crescentus and comparison with eukaryotic cell studies identify broadly conserved DNA concentration-dependent scaling principles of gene expression.
The polyadenylase PAPI is required for virulence plasmid maintenance in pathogenic bacteria
bioRxiv (Cold Spring Harbor Laboratory) · 2024 · cited 2 · doi.org/10.1101/2024.10.11.617751
Abstract Many species of pathogenic bacteria harbor critical plasmid-encoded virulence factors, and yet the regulation of plasmid replication is often poorly understood despite playing a critical role in plasmid-encoded gene expression. Human pathogenic Yersinia , including the plague agent Y. pestis and its close relative Y. pseudotuberculosis , require the type III secretion system (T3SS) virulence factor to subvert host defense mechanisms and colonize host tissues. The Yersinia T3SS is encoded on the IncFII p lasmid for Y ersinia v irulence (pYV). Several layers of gene regulation enables a large increase in expression of Yersinia T3SS genes at mammalian body temperature. Surprisingly, T3SS expression is also controlled at the level of gene dosage. The number of pYV molecules relative to the number of chromosomes per cell, referred to as plasmid copy number, increases with temperature. The ability to increase and maintain elevated pYV plasmid copy number, and therefore T3SS gene dosage, at 37°C is important for Yersinia virulence. In addition, pYV is highly stable in Yersinia at all temperatures, despite being dispensable for growth outside the host. Yet how Yersinia reinforces elevated plasmid replication and plasmid stability remains unclear. In this study, we show that the chromosomal gene pcnB encoding the polyadenylase PAP I is required for regulation of pYV plasmid copy number (PCN), maintenance of pYV in the bacterial population outside the host, robust T3SS activity, and Yersinia virulence in a mouse infection model. Likewise, pcnB /PAP I is also required for robust expression of the Shigella flexneri virulence plasmid-encoded T3SS. Furthermore, Yersinia and Shigella pcnB /PAP I is required for maintaining normal PCN of model antimicrobial resistance (AMR) plasmids whose replication is regulated by sRNA, thereby increasing antibiotic resistance by ten-fold. These data suggest that pcnB /PAP I contributes to the spread and stabilization of virulence and AMR plasmids in bacterial pathogens, and is essential in maintaining the gene dosage required to mediate plasmid-encoded traits. Importantly pcnB /PAP I has been bioinformatically identified in many species of bacteria despite being studied in only a few species to date. Our work highlights the potential importance of pcnB /PAP I in antibiotic resistance, and shows for the first time that pcnB /PAP I reinforces PCN and virulence plasmid stability in natural pathogenic hosts with a direct impact on bacterial virulence. Author Summary Many pathogens carry extrachromosomal DNA elements known as plasmids, which encode genes that confer bacterial virulence or antimicrobial resistance (AMR). Acquisition of these plasmids by bacteria can lead to the emergence of new pathogenic traits and the spread of AMR, yet the mechanisms by which plasmids are retained in bacterial populations particularly in the absence of selective pressure remain incompletely understood. Here we show that the major bacterial polyadenylase enzyme PAP I, encoded by the pcnB gene, is critical for the human pathogen Yersinia pseudotuberculosis to maintain its native virulence plasmid as well as AMR plasmids. Very little is known about the process of polyadenylation in bacteria, or the post-transcriptional addition of adenosine residues to the 3’ end of transcripts. This study represents the first demonstration that PAP I-mediated polyadenylation contributes to bacterial pathogenesis.
Nonequilibrium polysome dynamics promote chromosome segregation and its coupling to cell growth in <i>Escherichia coli</i>
bioRxiv (Cold Spring Harbor Laboratory) · 2024 · cited 2 · doi.org/10.1101/2024.10.08.617237
ABSTRACT Chromosome segregation is essential for cellular proliferation. Unlike eukaryotes, bacteria lack cytoskeleton-based machinery to segregate their chromosomal DNA (nucleoid). The bacterial ParABS system segregates the duplicated chromosomal regions near the origin of replication. However, this function does not explain how bacterial cells partition the rest (bulk) of the chromosomal material. Furthermore, some bacteria, including Escherichia coli , lack a ParABS system. Yet, E. coli faithfully segregates nucleoids across various growth rates. Here, we provide theoretical and experimental evidence that polysome production during chromosomal gene expression helps compact, split, segregate, and position nucleoids in E. coli through out-of-equilibrium dynamics and polysome exclusion from the DNA meshwork, inherently coupling these processes to biomass growth across nutritional conditions. Halting chromosomal gene expression and thus polysome production immediately stops sister nucleoid migration while ensuing polysome depletion gradually reverses nucleoid segregation. Redirecting gene expression away from the chromosome and toward plasmids causes ectopic polysome accumulations that are sufficient to drive aberrant nucleoid dynamics. Cell width enlargement suggest that the proximity of the DNA to the membrane along the radial axis is important to limit the exchange of polysomes across DNA-free regions, ensuring nucleoid segregation along the cell length. Our findings suggest a self-organizing mechanism for coupling nucleoid segregation to cell growth.
Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
· 2024 · cited 0 · doi.org/10.6019/s-biad1350
Coupling of cell growth modulation to asymmetric division and cell cycle regulation in Caulobacter crescentus
· 2024 · cited 0 · doi.org/10.6019/s-biad1327
Synthesis of a Borrelia burgdorferi-Derived Muropeptide Standard Fragment Library
Molecules · 2024 · cited 5 · doi.org/10.3390/molecules29143297
The interplay between the human innate immune system and bacterial cell wall components is pivotal in understanding diseases such as Crohn’s disease and Lyme arthritis. Lyme disease, caused by Borrelia burgdorferi, is the most prevalent tick-borne illness in the United States, with a substantial number of cases reported annually. While antibiotic treatments are generally effective, approximately 10% of Lyme disease cases develop persistent arthritis, suggesting a dysregulated host immune response. We have previously identified a link between the immunogenic B. burgdorferi peptidoglycan (PG) and Lyme arthritis and showed that this pathogen sheds significant amounts of PG fragments during growth. Here, we synthesize these PG fragments, including ornithine-containing monosaccharides and disaccharides, to mimic the unique composition of Borrelia cell walls, using reproducible and rigorous synthetic methods. This synthetic approach allows for the modular preparation of PG derivatives, providing a diverse library of well-defined fragments. These fragments will serve as valuable tools for investigating the role of PG-mediated innate immune response in Lyme disease and aid in the development of improved diagnostic methods and treatment strategies.
Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
eLife · 2024 · cited 14 · doi.org/10.7554/elife.97465
Defining the cellular factors that drive growth rate and proteome composition is essential for understanding and manipulating cellular systems. In bacteria, ribosome concentration is known to be a constraining factor of cell growth rate, while gene concentration is usually assumed not to be limiting. Here, using single-molecule tracking, quantitative single-cell microscopy, and modeling, we show that genome dilution in Escherichia coli cells arrested for DNA replication limits total RNA polymerase activity within physiological cell sizes across tested nutrient conditions. This rapid-onset limitation on bulk transcription results in sub-linear scaling of total active ribosomes with cell size and sub-exponential growth. Such downstream effects on bulk translation and cell growth are near-immediately detectable in a nutrient-rich medium, but delayed in nutrient-poor conditions, presumably due to cellular buffering activities. RNA sequencing and tandem-mass-tag mass spectrometry experiments further reveal that genome dilution remodels the relative abundance of mRNAs and proteins with cell size at a global level. Altogether, our findings indicate that chromosome concentration is a limiting factor of transcription and a global modulator of the transcriptome and proteome composition in E. coli . Experiments in Caulobacter crescentus and comparison with eukaryotic cell studies identify broadly conserved DNA concentration-dependent scaling principles of gene expression.
Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
eLife · 2024 · cited 3 · doi.org/10.7554/elife.97465.1
Abstract Defining the cellular factors that drive growth rate and proteome composition is essential for understanding and manipulating cellular systems. In bacteria, ribosome concentration is known to be a constraining factor of cell growth rate, while gene concentration is usually assumed not to be limiting. Here, using single-molecule tracking, quantitative single-cell microscopy, and modeling, we show that genome dilution in Escherichia coli cells arrested for DNA replication results in a decrease in the concentration of active RNA polymerases and ribosomes. The resulting sub-linear scaling of total active RNA polymerases and ribosomes with cell size leads to sub-exponential growth, even within physiological cell sizes. Cell growth rate scales proportionally with the total number of active ribosomes in a DNA concentration-dependent manner. Tandem-mass-tag mass spectrometry experiments further reveal that a decrease in DNA-to-cell-volume ratio proportionally remodels the composition of the proteome with cell size independently of the environment. Altogether, our findings indicate that genome concentration is an important driver of exponential cell growth and a global modulator of proteome composition in E. coli. Comparison with studies on eukaryotic cells suggests DNA concentration-dependent scaling principles of gene expression across domains of life.
Author response: Genome concentration limits cell growth and modulates proteome composition in Escherichia coli
· 2024 · cited 0 · doi.org/10.7554/elife.97465.1.sa4
Defining the cellular factors that drive growth rate and proteome composition is essential for understanding and manipulating cellular systems. In bacteria, ribosome concentration is known to be a constraining factor of cell growth rate, while gene concentration is usually assumed not to be limiting. Here, using single-molecule tracking, quantitative single-cell microscopy, and modeling, we show that genome dilution in Escherichia coli cells arrested for DNA replication results in a decrease in the concentration of active RNA polymerases and ribosomes. The resulting sub-linear scaling of total active RNA polymerases and ribosomes with cell size leads to sub-exponential growth, even within physiological cell sizes. Cell growth rate scales proportionally with the total number of active ribosomes in a DNA concentration-dependent manner. Tandem-mass-tag mass spectrometry experiments further reveal that a decrease in DNA-to-cell-volume ratio proportionally remodels the composition of the proteome with cell size independently of the environment. Altogether, our findings indicate that genome concentration is an important driver of exponential cell growth and a global modulator of proteome composition in E. coli. Comparison with studies on eukaryotic cells suggests DNA concentration-dependent scaling principles of gene expression across domains of life.