Your search keyword '"Bramkamp M"' showing total 5 results

1. Dynamics of the Bacillus subtilis Min System.

Author

Feddersen H, Würthner L, Frey E, and Bramkamp M

Subjects

Bacillus subtilis genetics, Bacterial Proteins genetics, Cell Cycle Proteins genetics, Models, Theoretical, Bacillus subtilis physiology, Bacterial Proteins metabolism, Cell Cycle Proteins metabolism, Cell Division

Abstract

Division site selection is a vital process to ensure generation of viable offspring. In many rod-shaped bacteria, a dynamic protein system, termed the Min system, acts as a central regulator of division site placement. The Min system is best studied in Escherichia coli, where it shows a remarkable oscillation from pole to pole with a time-averaged density minimum at midcell. Several components of the Min system are conserved in the Gram-positive model organism Bacillus subtilis However, in B. subtilis, it is commonly believed that the system forms a stationary bipolar gradient from the cell poles to midcell. Here, we show that the Min system of B. subtilis localizes dynamically to active sites of division, often organized in clusters. We provide physical modeling using measured diffusion constants that describe the observed enrichment of the Min system at the septum. Mathematical modeling suggests that the observed localization pattern of Min proteins corresponds to a dynamic equilibrium state. Our data provide evidence for the importance of ongoing septation for the Min dynamics, consistent with a major role of the Min system in controlling active division sites but not cell pole areas. IMPORTANCE The molecular mechanisms that help to place the division septum in bacteria is of fundamental importance to ensure cell proliferation and maintenance of cell shape and size. The Min protein system, found in many rod-shaped bacteria, is thought to play a major role in division site selection. It was assumed that there are strong differences in the functioning and in the dynamics of the Min system in E. coli and B. subtilis Most previous attempts to address Min protein dynamics in B. subtilis have been hampered by the use of overexpression constructs. Here, functional fusions to Min proteins have been constructed by allelic exchange and state-of-the-art imaging techniques allowed to unravel an unexpected fast dynamic behavior of the B. subtilis Min system. Our data show that the molecular mechanisms leading to Min protein dynamics are not fundamentally different in E. coli and B. subtilis ., (Copyright © 2021 Feddersen et al.)

Published

2021

2. A Bacterial Dynamin-Like Protein Confers a Novel Phage Resistance Strategy on the Population Level in Bacillus subtilis.

Author

Guo L, Sattler L, Shafqat S, Graumann PL, and Bramkamp M

Subjects

Cell Membrane metabolism, Membrane Fusion, Bacillus subtilis metabolism, Bacteriophages metabolism, Dynamins metabolism

Abstract

Bacillus subtilis DynA is a member of the dynamin superfamily, involved in membrane remodeling processes. DynA was shown to catalyze full membrane fusion and it plays a role in membrane surveillance against antibiotics. We show here that DynA also provides a novel resistance mechanism against phage infection. Cells lacking DynA are efficiently lysed after phage infection and virus replication. DynA does not prevent phage infection and replication in individual cells, but significantly delays host cell lysis, thereby slowing down the release of phage progeny from the host cells. During the process, DynA forms large, almost immobile clusters on the cell membrane that seem to support membrane integrity. Single-molecule tracking revealed a shift of freely diffusive molecules within the cytosol toward extended, confined motion at the cell membrane following phage induction. Thus, the bacterial dynamins are the first anti-phage system reported to delay host cell lysis and the last line of defense of a multilayered antiviral defense. DynA is therefore providing protective effects on the population, but not on single cell level. IMPORTANCE Bacteria have to cope with myriads of phages in their natural environments. Consequently, they have evolved sophisticated systems to prevent phage infection or epidemic spreading of the infection in the population. We show here that a bacterial dynamin-like protein is involved in phage resistance. The Bacillus subtilis DynA protein delays lysis of infected bacteria and reduces spreading of the phage particles. Thus, the dynamin mediated protection is not at the level of the individual cell, but on the population level. The bacterial DynA is the last line of defense to reduce the deleterious effect of a phage infection in a bacterial community. Interestingly, dynamin-like proteins such as Mx proteins are also involved in antiviral activities in Eukaryotes. Thus, the interaction of dynamin-like proteins and viruses seem to be an evolutionary ancient process.

Published

2021

3. The Polar Organizing Protein PopZ Is Fundamental for Proper Cell Division and Segregation of Cellular Content in Magnetospirillum gryphiswaldense .

Author

Pfeiffer D, Toro-Nahuelpan M, Bramkamp M, Plitzko JM, and Schüler D

Subjects

Bacterial Proteins genetics, Caulobacter crescentus genetics, Cell Cycle Proteins genetics, Gene Deletion, Magnetospirillum cytology, Magnetospirillum genetics, Bacterial Proteins metabolism, Cell Cycle Proteins metabolism, Cell Division, Magnetospirillum growth & development

Abstract

Magnetotactic bacteria (MTB) are of special scientific interest due to the formation of magnetosomes, intracellular membrane-enveloped magnetite crystals arranged into a linear chain by a dedicated cytoskeleton. Magnetotaxis relies on the formation and proper inheritance of these unique magnetic organelles, both of which need to be coordinated with the segregation of other cellular content such as chromosomes or motility and chemotaxis related structures. Thus, elaborated mechanisms are required in MTB to coordinate and maintain a high level of spatial and temporal subcellular organization during cytokinesis. However, thus far, underlying mechanisms and polarity determinants such as landmark proteins remained obscure in MTB. Here, we analyzed an ortholog of the p olar o rganizing p rotein Z in the alphaproteobacterium Magnetospirillum gryphiswaldense termed PopZ Mgr We show that deletion of the popZ Mgr gene causes abnormal cell elongation, minicell formation, DNA missegregation, and impairs motility. Overproduction of PopZ Mgr results in PopZ-rich regions near the poles, which are devoid of larger macromolecules, such as ribosomes, chromosomal DNA, and polyhydroxybutyrate (PHB) granules. Using superresolution microscopy, we show that PopZ Mgr exhibits a bipolar localization pattern throughout the cell cycle, indicating that the definition of new poles in M. gryphiswaldense occurs immediately upon completion of cytokinesis. Moreover, substitution of PopZ orthologs between M. gryphiswaldense and the related alphaproteobacterium Caulobacter crescentus indicated that PopZ localization depends on host-specific cues and that both orthologs have diverged to an extent that allows only partial reciprocal functional complementation. Altogether, our results indicate that in M. gryphiswaldense , PopZ plays a critical role during cell division and segregation of cellular content. IMPORTANCE Magnetotactic bacteria (MTB) share the unique capability of magnetic navigation, one of the most complex behavioral responses found in prokaryotes, by means of magnetosomes, which act as an internal compass. Due to formation of these unique nanoparticles, MTB have emerged as a model to study prokaryotic organelle formation and cytoskeletal organization in conjunction with complex motility systems. Despite the high degree of subcellular organization required in MTB, less is known about cell-cycle-related factors or proteins responsible for spatiotemporal polarity control. Here, we investigate the function of the polar organizer PopZ in the magnetotactic alphaproteobacterium Magnetospirillum gryphiswaldense Although PopZ is widely distributed among the alphaproteobacteria, its function in MTB belonging to this class has remained unexplored. Our results suggest that in M. gryphiswaldense , PopZ has a key role during cell division and subcellular organization. Furthermore, we show that PopZ localization and function differ from other nonmagnetotactic alphaproteobacterial model organisms., (Copyright © 2019 Pfeiffer et al.)

Published

2019

4. Novel Chromosome Organization Pattern in Actinomycetales -Overlapping Replication Cycles Combined with Diploidy.

Author

Böhm K, Meyer F, Rhomberg A, Kalinowski J, Donovan C, and Bramkamp M

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Cell Division genetics, Chromosome Segregation, Corynebacterium glutamicum growth & development, Replication Origin, Chromosomes, Bacterial genetics, Chromosomes, Bacterial metabolism, Corynebacterium glutamicum genetics, DNA Replication, Diploidy

Abstract

Bacteria regulate chromosome replication and segregation tightly with cell division to ensure faithful segregation of DNA to daughter generations. The underlying mechanisms have been addressed in several model species. It became apparent that bacteria have evolved quite different strategies to regulate DNA segregation and chromosomal organization. We have investigated here how the actinobacterium Corynebacterium glutamicum organizes chromosome segregation and DNA replication. Unexpectedly, we found that C. glutamicum cells are at least diploid under all of the conditions tested and that these organisms have overlapping C periods during replication, with both origins initiating replication simultaneously. On the basis of experimental data, we propose growth rate-dependent cell cycle models for C. glutamicum IMPORTANCE Bacterial cell cycles are known for few model organisms and can vary significantly between species. Here, we studied the cell cycle of Corynebacterium glutamicum , an emerging cell biological model organism for mycolic acid-containing bacteria, including mycobacteria. Our data suggest that C. glutamicum carries two pole-attached chromosomes that replicate with overlapping C periods, thus initiating a new round of DNA replication before the previous one is terminated. The newly replicated origins segregate to midcell positions, where cell division occurs between the two new origins. Even after long starvation or under extremely slow-growth conditions, C. glutamicum cells are at least diploid, likely as an adaptation to environmental stress that may cause DNA damage. The cell cycle of C. glutamicum combines features of slow-growing organisms, such as polar origin localization, and fast-growing organisms, such as overlapping C periods., (Copyright © 2017 Böhm et al.)

Published

2017

5. The Antituberculosis Drug Ethambutol Selectively Blocks Apical Growth in CMN Group Bacteria.

Author

Schubert K, Sieger B, Meyer F, Giacomelli G, Böhm K, Rieblinger A, Lindenthal L, Sachs N, Wanner G, and Bramkamp M

Subjects

Cell Wall metabolism, Antitubercular Agents pharmacology, Cell Wall drug effects, Corynebacterium glutamicum drug effects, Corynebacterium glutamicum growth & development, Ethambutol pharmacology, Mycobacterium phlei drug effects, Mycobacterium phlei growth & development

Abstract

Members of the genus Mycobacterium are the most prevalent cause of infectious diseases. Mycobacteria have a complex cell envelope containing a peptidoglycan layer and an additional arabinogalactan polymer to which a mycolic acid bilayer is linked; this complex, multilayered cell wall composition (mAGP) is conserved among all CMN group bacteria. The arabinogalactan and mycolic acid synthesis pathways constitute effective drug targets for tuberculosis treatment. Ethambutol (EMB), a classical antituberculosis drug, inhibits the synthesis of the arabinose polymer. Although EMB acts bacteriostatically, its underlying molecular mechanism remains unclear. Here, we used Corynebacterium glutamicum and Mycobacterium phlei as model organisms to study the effects of EMB at the single-cell level. Our results demonstrate that EMB specifically blocks apical cell wall synthesis, but not cell division, explaining the bacteriostatic effect of EMB. Furthermore, the data suggest that members of the family Corynebacterineae have two dedicated machineries for cell elongation (elongasome) and cytokinesis (divisome)., Importance: Antibiotic treatment of bacterial pathogens has contributed enormously to the increase in human health. Despite the apparent importance of antibiotic treatment of bacterial infections, surprisingly little is known about the molecular functions of antibiotic actions in the bacterial cell. Here, we analyzed the molecular effects of ethambutol, a first-line antibiotic against infections caused by members of the genus Mycobacterium We find that this drug selectively blocks apical cell growth but still allows for effective cytokinesis. As a consequence, cells survive ethambutol treatment and adopt a pneumococcal cell growth mode with cell wall synthesis only at the site of cell division. However, combined treatment of ethambutol and beta-lactam antibiotics acts synergistically and effectively stops cell proliferation., (Copyright © 2017 Schubert et al.)

Published

2017