Your search keyword '"Perchuk, Barrett S."' showing total 9 results

1. A DNA Damage-Induced, SOS-Independent Checkpoint Regulates Cell Division in Caulobacter crescentus.

Author

Modell, Joshua W., Kambara, Tracy K., Perchuk, Barrett S., and Laub, Michael T.

Subjects

CAULOBACTER crescentus, CELL division, DNA damage, DNA replication, TRANSCRIPTION factors, CELLS, BACTERIA

Abstract

: A study of the bacterium Caulobacter crescentus reveals an SOS-independent DNA damage response pathway that acts via a novel cell division inhibitor, DidA, to suppress septum synthesis. [ABSTRACT FROM AUTHOR]

Published

2014

2. Regulated proteolysis of a transcription factor complex is critical to cell cycle progression in Caulobacter crescentus.

Author

Gora, Kasia G., Cantin, Amber, Wohlever, Matthew, Joshi, Kamal K., Perchuk, Barrett S., Chien, Peter, and Laub, Michael T.

Subjects

CELL cycle, PROTEOLYSIS, CAULOBACTER crescentus, PROTEOLYTIC enzymes, GENE expression, MORPHOGENESIS, CELL division

Abstract

Cell cycle transitions are often triggered by the proteolysis of key regulatory proteins. In Caulobacter crescentus, the G1- S transition involves the degradation of an essential DNA-binding response regulator, CtrA, by the ClpXP protease. Here, we show that another critical cell cycle regulator, SciP, is also degraded during the G1- S transition, but by the Lon protease. SciP is a small protein that binds directly to CtrA and prevents it from activating target genes during G1. We demonstrate that SciP must be degraded during the G1- S transition so that cells can properly activate CtrA-dependent genes following DNA replication initiation and the reaccumulation of CtrA. These results indicate that like CtrA, SciP levels are tightly regulated during the Caulobacter cell cycle. In addition, we show that formation of a complex between CtrA and SciP at target promoters protects both proteins from their respective proteases. Degradation of either protein thus helps trigger the destruction of the other, facilitating a cooperative disassembly of the complex. Collectively, our results indicate that ClpXP and Lon each degrade an important cell cycle regulator, helping to trigger the onset of S phase and prepare cells for the subsequent programmes of gene expression critical to polar morphogenesis and cell division. [ABSTRACT FROM AUTHOR]

Published

2013

3. Spatial tethering of kinases to their substrates relaxes evolutionary constraints on specificity.

Author

Capra, Emily J., Perchuk, Barrett S., Ashenberg, Orr, Seid, Charlotte A., Snow, Hana R., Skerker, Jeffrey M., and Laub, Michael T.

Subjects

CELLULAR signal transduction, PHOSPHOTRANSFERASES, MICROBIAL genetics, BACTERIOPHAGES, CROSSTALK

Abstract

Signal transduction proteins are often multi-domain proteins that arose through the fusion of previously independent proteins. How such a change in the spatial arrangement of proteins impacts their evolution and the selective pressures acting on individual residues is largely unknown. We explored this problem in the context of bacterial two-component signalling pathways, which typically involve a sensor histidine kinase that specifically phosphorylates a single cognate response regulator. Although usually found as separate proteins, these proteins are sometimes fused into a so-called hybrid histidine kinase. Here, we demonstrate that the isolated kinase domains of hybrid kinases exhibit a dramatic reduction in phosphotransfer specificity in vitro relative to canonical histidine kinases. However, hybrid kinases phosphotransfer almost exclusively to their covalently attached response regulator domain, whose effective concentration exceeds that of all soluble response regulators. These findings indicate that the fused response regulator in a hybrid kinase normally prevents detrimental cross-talk between pathways. More generally, our results shed light on how the spatial properties of signalling pathways can significantly affect their evolution, with additional implications for the design of synthetic signalling systems. [ABSTRACT FROM AUTHOR]

Published

2012

4. Direct and adaptor-mediated substrate recognition by an essential AAA+ protease.

Author

Chien, Peter, Perchuk, Barrett S., Laub, Michael T., Sauer, Robert T., and Baker, Tania A.

Subjects

PROTEOLYTIC enzymes, PROTEOLYSIS, CELL cycle, GENE expression, CYTOLOGY

Abstract

Regulated proteolysis is required to execute many cellular programs. In Caulobactercrescentus, timely degradation of the master regulator CtrA by ClpXP protease is essential for cell-cycle progression and requires the colocalization of CtrA and RcdA. Here, we establish a biochemical framework to understand regulated proteolysis in C. crescentus and show that RcdA is not an adaptor for CtrA degradation. CtrA is rapidly degraded without RcdA and is recognized with an affinity comparable with the best CIpXP substrates. In contrast, SspBα, the α-proteobacterial homolog of SspB, functions as an adaptor to enhance degradation of specific substrates. Cargo-free SspBα is also itself a substrate of CIpXP-mediated proteolysis. Thus, our analysis (i) reveals the consequences of both direct and adaptor-stimulated recognition in mediating substrate specificity in vitro, (ii) reveals a potential regulatory role of controlled adaptor stability, and (iii) suggests that cell-cycle regulation of CtrA stability depends on repression of its intrinsic degradation rather than adaptor-mediated enhancement. [ABSTRACT FROM AUTHOR]

Published

2007

5. Regulation of the bacterial cell cycle by an integrated genetic circuit.

Author

Biondi, Emanuele G., Reisinger, Sarah J., Skerker, Jeffrey M., Arif, Muhammad, Perchuk, Barrett S., Ryan, Kathleen R., and Laub, Michael T.

Subjects

FUNGUS-bacterium relationships, MICROBIAL genetics, CHEMICAL reactions, NUCLEIC acids, CELL cycle, CELL proliferation

Abstract

How bacteria regulate cell cycle progression at a molecular level is a fundamental but poorly understood problem. In Caulobacter crescentus, two-component signal transduction proteins are crucial for cell cycle regulation, but the connectivity of regulators involved has remained elusive and key factors are unidentified. Here we identify ChpT, an essential histidine phosphotransferase that controls the activity of CtrA, the master cell cycle regulator. We show that the essential histidine kinase CckA initiates two phosphorelays, each requiring ChpT, which lead to the phosphorylation and stabilization of CtrA. Downregulation of CckA activity therefore results in the dephosphorylation and degradation of CtrA, which in turn allow the initiation of DNA replication. Furthermore, we show that CtrA triggers its own destruction by promoting cell division and inducing synthesis of the essential regulator DivK, which feeds back to downregulate CckA immediately before S phase. Our results define a single integrated circuit whose components and connectivity can account for the cell cycle oscillations of CtrA in Caulobacter. [ABSTRACT FROM AUTHOR]

Published

2006

6. A phosphorelay system controls stalk biogenesis during cell cycle progression in Caulobacter crescentus.

Author

Biondi, Emanuele G., Skerker, Jeffrey M., Arif, Muhammad, Prasol, Melanie S., Perchuk, Barrett S., and Laub, Michael T.

Subjects

DEVELOPMENTAL biology, MORPHOGENESIS, CELL cycle, CELLS, ORIGIN of life, GENOMES, DNA microarrays, CELLULAR signal transduction

Abstract

A fundamental question in developmental biology is how morphogenesis is coordinated with cell cycle progression. In Caulobacter crescentus, each cell cycle produces morphologically distinct daughter cells, a stalked cell and a flagellated swarmer cell. Construction of both the flagellum and stalk requires the alternative sigma factor RpoN (σ54). Here we report that a σ54-dependent activator, TacA, is required for cell cycle regulated stalk biogenesis by collaborating with RpoN to activate gene expression. We have also identified the first histidine phosphotransferase in C. crescentus, ShpA, and show that it too is required for stalk biogenesis. Using a systematic biochemical technique called phosphotransfer profiling we have identified a multicomponent phosphorelay which leads from the hybrid histidine kinase ShkA to ShpA and finally to TacA. This pathway functions in vivo to phosphorylate and hence, activate TacA. Finally, whole genome microarrays were used to identify candidate members of the TacA regulon, and we show that at least one target gene, staR, regulates stalk length. This is the first example of a general method for identifying the connectivity of a phosphorelay and can be applied to any organism with two-component signal transduction systems. [ABSTRACT FROM AUTHOR]

Published

2006

7. Two-Component Signal Transduction Pathways Regulating Growth and Cell Cycle Progression in a Bacterium: A System-Level Analysis.

Author

Skerker, Jeffrey M., Prasol, Melanie S., Perchuk, Barrett S., Biondi, Emanuele G., and Laub, Michael T.

Subjects

MICROBIAL genetics, FUNGUS-bacterium relationships, GENE expression, ORIGIN of life, BACTERIAL cell walls, CELL membranes

Abstract

Two-component signal transduction systems, comprised of histidine kinases and their response regulator substrates, are the predominant means by which bacteria sense and respond to extracellular signals. These systems allow cells to adapt to prevailing conditions by modifying cellular physiology, including initiating programs of gene expression, catalyzing reactions, or modifying protein-protein interactions. These signaling pathways have also been demonstrated to play a role in coordinating bacterial cell cycle progression and development. Here we report a system-level investigation of two-component pathways in the model organism Caulobacter crescentus. First, by a comprehensive deletion analysis we show that at least 39 of the 106 two-component genes are required for cell cycle progression, growth, or morphogenesis. These include nine genes essential for growth or viability of the organism. We then use a systematic biochemical approach, called phosphotransfer profiling, to map the connectivity of histidine kinases and response regulators. Combining these genetic and biochemical approaches, we identify a new, highly conserved essential signaling pathway from the histidine kinase CenK to the response regulator CenR, which plays a critical role in controlling cell envelope biogenesis and structure. Depletion of either cenK or cenR leads to an unusual, severe blebbing of cell envelope material, whereas constitutive activation of the pathway compromises cell envelope integrity, resulting in cell lysis and death. We propose that the CenK-CenR pathway may be a suitable target for new antibiotic development, given previous successes in targeting the bacterial cell wall. Finally, the ability of our in vitro phosphotransfer profiling method to identify signaling pathways that operate in vivo takes advantage of an observation that histidine kinases are endowed with a global kinetic preference for their cognate response regulators. We propose that this system-wide selectivity insulates two-component pathways from one another, preventing unwanted cross-talk. [ABSTRACT FROM AUTHOR]

Published

2005

8. Two-Component Signal Transduction Pathways Regulating Growth and Cell Cycle Progression in a Bacterium: A System-Level Analysis.

Author

Skerker, Jeffrey M, Prasol, Melanie S, Perchuk, Barrett S, Biondi, Emanuele G, and Laub, Michael T

Subjects

CELL cycle, HISTIDINE kinases, CELLULAR signal transduction, CELL growth, LYSIS, BACTERIAL cell walls, QUORUM sensing

Abstract

Two-component signal transduction systems, comprised of histidine kinases and their response regulator substrates, are the predominant means by which bacteria sense and respond to extracellular signals. These systems allow cells to adapt to prevailing conditions by modifying cellular physiology, including initiating programs of gene expression, catalyzing reactions, or modifying protein–protein interactions. These signaling pathways have also been demonstrated to play a role in coordinating bacterial cell cycle progression and development. Here we report a system-level investigation of two-component pathways in the model organism Caulobacter crescentus. First, by a comprehensive deletion analysis we show that at least 39 of the 106 two-component genes are required for cell cycle progression, growth, or morphogenesis. These include nine genes essential for growth or viability of the organism. We then use a systematic biochemical approach, called phosphotransfer profiling, to map the connectivity of histidine kinases and response regulators. Combining these genetic and biochemical approaches, we identify a new, highly conserved essential signaling pathway from the histidine kinase CenK to the response regulator CenR, which plays a critical role in controlling cell envelope biogenesis and structure. Depletion of either cenK or cenR leads to an unusual, severe blebbing of cell envelope material, whereas constitutive activation of the pathway compromises cell envelope integrity, resulting in cell lysis and death. We propose that the CenK–CenR pathway may be a suitable target for new antibiotic development, given previous successes in targeting the bacterial cell wall. Finally, the ability of our in vitro phosphotransfer profiling method to identify signaling pathways that operate in vivo takes advantage of an observation that histidine kinases are endowed with a global kinetic preference for their cognate response regulators. We propose that this system-wide selectivity insulates two-component pathways from one another, preventing unwanted cross-talk. Histidine kinases and their (sensory) response regulators are screened for in C. crescentus. Follow-up experiments determine several essential components, including one pair critical for cell envelope biogenesis and structure. [ABSTRACT FROM AUTHOR]

Published

2005

9. Evolving a robust signal transduction pathway from weak cross-talk.

Author

Siryaporn, Albert, Perchuk, Barrett S, Laub, Michael T, and Goulian, Mark

Subjects

GENETIC transduction, ROBUST control, PHOSPHORYLATION, GENETIC mutation, PHOSPHATASES

Abstract

We have evolved a robust two-component signal transduction pathway from a sensor kinase (SK) and non-partner response regulator (RR) that show weak cross-talk in vitro and no detectable cross-talk in vivo in wild-type strains. The SK, CpxA, is bifunctional, with both kinase and phosphatase activities for its partner RR. We show that by combining a small number of mutations in CpxA that individually increase phosphorylation of the non-partner RR OmpR, phosphatase activity against phospho-OmpR emerges. The resulting circuit also becomes responsive to input signal to CpxA. The effects of combining these mutations in CpxA appear to reflect complex intragenic interactions between multiple sites in the protein. However, by analyzing a simple model of two-component signaling, we show that the behavior can be explained by a monotonic change in a single parameter controlling protein-protein interaction strength. The results suggest one possible mode of evolution for two-component systems with bifunctional SKs whereby the remarkable properties and competing reactions that characterize these systems can emerge by combining mutations of the same effect. [ABSTRACT FROM AUTHOR]

Published

2010