Role of Transcription in the Temporal Control of Development in Caulobacter crescentus

ABSTRACT Transport of RsaA, the crystalline S-layer subunit protein of Caulobacter crescentus, is mediated by a type I secretion mechanism. Two proteins have been identified that play the role of the outer membrane protein (OMP) component in the RsaA secretion machinery. The genes rsaF a and rsaF b were identified by similarity to the Escherichia coli hemolysin secretion OMP TolC by using the C. crescentus genome sequence. The rsaF a gene is located several kilobases downstream of the other transporter genes, while rsaF b is completely unlinked. An rsaF a knockout had ∼56% secretion compared to wild-type levels, while the rsaF b knockout reduced secretion levels to ∼79%. When expression of both proteins was eliminated, there was no RsaA secretion, but a residual level of ∼9% remained inside the cell, suggesting posttranslational autoregulation. Complementation with either of the individual rsaF genes by use of a multicopy vector, which resulted in 8- to 10-fold overexpression of the proteins, did not restore RsaA secretion to wild-type levels, indicating that both rsaF genes were required for full-level secretion. However, overexpression of rsaFa (with normal rsaF b levels) in concert with overexpression of rsaA resulted in a 28% increase in RsaA secretion, indicating a potential for significantly increasing expression levels of an already highly expressing type I secretion system. This is the only known example of type I secretion requiring two OMPs to assemble a fully functional system.

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The role of host protein YajQ in the temporal control of transcription in bacteriophage 6

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.0807489105 ◽

2008 ◽

Vol 105 (41) ◽

pp. 15956-15960 ◽

Cited By ~ 17

Author(s):

X. Qiao ◽

Y. Sun ◽

J. Qiao ◽

L. Mindich

Keyword(s):

Host Protein ◽

Temporal Control

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Role of the GGDEF regulator PleD in polar development of Caulobacter crescentus

Molecular Microbiology ◽

10.1046/j.1365-2958.2003.03401.x ◽

2003 ◽

Vol 47 (6) ◽

pp. 1695-1708 ◽

Cited By ~ 188

Author(s):

Phillip Aldridge ◽

Ralf Paul ◽

Patrick Goymer ◽

Paul Rainey ◽

Urs Jenal

Keyword(s):

Caulobacter Crescentus ◽

Polar Development

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097 An important role of TRPV3 in the temporal control of intracellular acidification in corneoptosis, a unique cell death process of keratinocytes

Journal of Investigative Dermatology ◽

10.1016/j.jid.2021.08.100 ◽

2021 ◽

Vol 141 (10) ◽

pp. S165

Author(s):

T. Matsui ◽

N. Kadono-Maekubo ◽

Y. Suzuki ◽

Y. Furuichi ◽

K. Shiraga ◽

...

Keyword(s):

Cell Death ◽

Death Process ◽

Temporal Control ◽

Intracellular Acidification ◽

Cell Death Process ◽

Unique Cell

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A toxin-antitoxin system associated transcription factor of Caulobacter crescentus can influence cell cycle-regulated gene expression during the SOS response

10.1101/2020.07.22.216945 ◽

2020 ◽

Author(s):

Koyel Ghosh ◽

Kamilla Ankær Brejndal ◽

Clare L. Kirkpatrick

Keyword(s):

Gene Expression ◽

Cell Cycle ◽

Dna Damage ◽

Transcription Factor ◽

Caulobacter Crescentus ◽

Sos Response ◽

Cell Cycle Gene ◽

Regulated Gene Expression ◽

Cell Cycle Gene Expression

AbstractToxin-antitoxin (TA) systems are widespread in bacterial chromosomes but their functions remain enigmatic. Although many are transcriptionally upregulated by stress conditions, it is unclear what role they play in cellular responses to stress and to what extent the role of a given TA system homologue varies between different bacterial species. In this work we investigate the role of the DNA damage-inducible TA system HigBA of Caulobacter crescentus in the SOS response and discover that in addition to the toxin HigB affecting cell cycle gene expression through inhibition of the master regulator CtrA, HigBA possesses a transcription factor third component, HigC, which both auto-regulates the TA system and acts independently of it. Through HigC, the system exerts downstream effects on antibiotic (ciprofloxacin) resistance and cell cycle gene expression. HigB and HigC had inverse effects on cell cycle gene regulation, with HigB reducing and HigC increasing the expression of CtrA-dependent promoters. Neither HigBA nor HigC had any effect on formation of persister cells in response to ciprofloxacin. Rather, their role in the SOS response appears to be as transcriptional and post-transcriptional regulators of cell cycle-dependent gene expression, transmitting the status of the SOS response as a regulatory input into the cell cycle control network via CtrA.ImportanceAlmost all bacteria respond to DNA damage by upregulating a set of genes that helps them to repair and recover from the damage, known as the SOS response. The set of genes induced during the SOS response varies between species, but frequently includes toxin-antitoxin systems. However, it is unknown what the consequence of inducing these systems is, and whether they provide any benefit to the cells. We show here that the DNA damage-induced TA system HigBA of the asymmetrically dividing bacterium Caulobacter crescentus affects the cell cycle regulation of this bacterium. HigBA also has a transcription factor encoded immediately downstream of it, named here HigC, which controls expression of the TA system and potentially other genes as well. Therefore, this work identifies a new role for TA systems in the DNA damage response, distinct from non-specific stress tolerance mechanisms which had been proposed previously.

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Tad pili play a dynamic role in Caulobacter crescentus surface colonization

10.1101/526160 ◽

2019 ◽

Author(s):

Matteo Sangermani ◽

Isabelle Hug ◽

Nora Sauter ◽

Thomas Pfohl ◽

Urs Jenal

Keyword(s):

Caulobacter Crescentus ◽

Optical Trap ◽

Natural Environments ◽

Surface Attachment ◽

Surface Colonization ◽

Bacterial Surface ◽

Controlled Flow ◽

Mechanical Sensing

ABSTRACTBacterial surface attachment is mediated by rotary flagella and filamentous appendages called pili. Here, we describe the role of Tad pili during surface colonization of Caulobacter crescentus. Using an optical trap and microfluidic controlled flow conditions as a mimic of natural environments, we demonstrate that Tad pili undergo repeated cycles of extension and retraction. Within seconds after establishing surface contact, pili reorient cells into an upright position promoting walking-like movements against the medium flow. Pili-mediated positioning of the flagellated pole close to the surface facilitates motor-mediated mechanical sensing and promotes anchoring of the holdfast, an adhesive substance that affords long-term attachment. We present evidence that the second messenger c-di-GMP regulates pili dynamics during surface encounter in distinct ways, promoting increased activity at intermediate levels and retraction of pili at peak concentrations. We propose a model, in which flagellum and Tad pili functionally interact and together impose a ratchet-like mechanism that progressively drives C. crescentus cells towards permanent surface attachment.

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Robust surface-to-mass coupling and turgor-dependent cell width determine bacterial dry-mass density

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2021416118 ◽

2021 ◽

Vol 118 (32) ◽

pp. e2021416118

Author(s):

Enno R. Oldewurtel ◽

Yuki Kitahara ◽

Sven van Teeffelen

Keyword(s):

Single Cell ◽

Caulobacter Crescentus ◽

Mass Density ◽

Turgor Pressure ◽

Cell Mass ◽

Dry Mass ◽

Model Organisms ◽

Cell Width ◽

Dependent Cell

During growth, cells must expand their cell volumes in coordination with biomass to control the level of cytoplasmic macromolecular crowding. Dry-mass density, the average ratio of dry mass to volume, is roughly constant between different nutrient conditions in bacteria, but it remains unknown whether cells maintain dry-mass density constant at the single-cell level and during nonsteady conditions. Furthermore, the regulation of dry-mass density is fundamentally not understood in any organism. Using quantitative phase microscopy and an advanced image-analysis pipeline, we measured absolute single-cell mass and shape of the model organisms Escherichia coli and Caulobacter crescentus with improved precision and accuracy. We found that cells control dry-mass density indirectly by expanding their surface, rather than volume, in direct proportion to biomass growth—according to an empirical surface growth law. At the same time, cell width is controlled independently. Therefore, cellular dry-mass density varies systematically with cell shape, both during the cell cycle or after nutrient shifts, while the surface-to-mass ratio remains nearly constant on the generation time scale. Transient deviations from constancy during nutrient shifts can be reconciled with turgor-pressure variations and the resulting elastic changes in surface area. Finally, we find that plastic changes of cell width after nutrient shifts are likely driven by turgor variations, demonstrating an important regulatory role of mechanical forces for width regulation. In conclusion, turgor-dependent cell width and a slowly varying surface-to-mass coupling constant are the independent variables that determine dry-mass density.

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