474 research outputs found
Differential Affinity and Catalytic Activity of CheZ in E. coli Chemotaxis
Push–pull networks, in which two antagonistic enzymes control the
activity of a messenger protein, are ubiquitous in signal transduction pathways.
A classical example is the chemotaxis system of the bacterium
Escherichia coli, in which the kinase CheA and the
phosphatase CheZ regulate the phosphorylation level of the messenger protein
CheY. Recent experiments suggest that both the kinase and the phosphatase are
localized at the receptor cluster, and Vaknin and Berg recently demonstrated
that the spatial distribution of the phosphatase can markedly affect the
dose–response curves. We argue, using mathematical modeling, that the
canonical model of the chemotaxis network cannot explain the experimental
observations of Vaknin and Berg. We present a new model, in which a small
fraction of the phosphatase is localized at the receptor cluster, while the
remainder freely diffuses in the cytoplasm; moreover, the phosphatase at the
cluster has a higher binding affinity for the messenger protein and a higher
catalytic activity than the phosphatase in the cytoplasm. This model is
consistent with a large body of experimental data and can explain many of the
experimental observations of Vaknin and Berg. More generally, the combination of
differential affinity and catalytic activity provides a generic mechanism for
amplifying signals that could be exploited in other two-component signaling
systems. If this model is correct, then a number of recent modeling studies,
which aim to explain the chemotactic gain in terms of the activity of the
receptor cluster, should be reconsidered
Adaptation dynamics in densely clustered chemoreceptors
In many sensory systems, transmembrane receptors are spatially organized in
large clusters. Such arrangement may facilitate signal amplification and the
integration of multiple stimuli. However, this organization likely also affects
the kinetics of signaling since the cytoplasmic enzymes that modulate the
activity of the receptors must localize to the cluster prior to receptor
modification. Here we examine how these spatial considerations shape signaling
dynamics at rest and in response to stimuli. As a model, we use the chemotaxis
pathway of Escherichia coli, a canonical system for the study of how organisms
sense, respond, and adapt to environmental stimuli. In bacterial chemotaxis,
adaptation is mediated by two enzymes that localize to the clustered receptors
and modulate their activity through methylation-demethylation. Using a novel
stochastic simulation, we show that distributive receptor methylation is
necessary for successful adaptation to stimulus and also leads to large
fluctuations in receptor activity in the steady state. These fluctuations arise
from noise in the number of localized enzymes combined with saturated
modification kinetics between localized enzymes and receptor substrate. An
analytical model explains how saturated enzyme kinetics and large fluctuations
can coexist with an adapted state robust to variation in the expression level
of the pathway constituents, a key requirement to ensure the functionality of
individual cells within a population. This contrasts with the well-mixed
covalent modification system studied by Goldbeter and Koshland in which mean
activity becomes ultrasensitive to protein abundances when the enzymes operate
at saturation. Large fluctuations in receptor activity have been quantified
experimentally. Here we clarify their mechanistic relationship with
well-studied aspects of the chemotaxis system, precise adaptation and
functional robustness.Comment: Pontius W, Sneddon MW, Emonet T (2013) Adaptation Dynamics in Densely
Clustered Chemoreceptors. PLoS Comput Biol 9(9): e1003230.
doi:10.1371/journal.pcbi.100323
Changing Cellular Location of CheZ Predicted by Molecular Simulations
In the chemotaxis pathway of the bacterium Escherichia coli, signals are carried from a cluster of receptors to the flagellar motors by the diffusion of the protein CheY-phosphate (CheYp) through the cytoplasm. A second protein, CheZ, which promotes dephosphorylation of CheYp, partially colocalizes with receptors in the plasma membrane. CheZ is normally dimeric in solution but has been suggested to associate into highly active oligomers in the presence of CheYp. A model is presented here and supported by Brownian dynamics simulations, which accounts for these and other experimental data: A minority component of the receptor cluster (dimers of CheA(short)) nucleates CheZ oligomerization and CheZ molecules move from the cytoplasm to a bound state at the receptor cluster depending on the current level of cellular stimulation. The corresponding simulations suggest that dynamic CheZ localization will sharpen cellular responses to chemoeffectors, increase the range of detectable ligand concentrations, and make adaptation more precise and robust. The localization and activation of CheZ constitute a negative feedback loop that provides a second tier of adaptation to the system. Subtle adjustments of this kind are likely to be found in many other signaling pathways
Split histidine kinases enable ultrasensitivity and bistability in two-component signaling networks
Bacteria sense and respond to their environment through signaling cascades generally referred to as two-component signaling networks. These networks comprise histidine kinases and their cognate response regulators. Histidine kinases have a number of biochemical activities: ATP binding, autophosphorylation, the ability to act as a phosphodonor for their response regulators, and in many cases the ability to catalyze the hydrolytic dephosphorylation of their response regulator. Here, we explore the functional role of “split kinases” where the ATP binding and phosphotransfer activities of a conventional histidine kinase are split onto two distinct proteins that form a complex. We find that this unusual configuration can enable ultrasensitivity and bistability in the signal-response relationship of the resulting system. These dynamics are displayed under a wide parameter range but only when specific biochemical requirements are met. We experimentally show that one of these requirements, namely segregation of the phosphatase activity predominantly onto the free form of one of the proteins making up the split kinase, is met in Rhodobacter sphaeroides. These findings indicate split kinases as a bacterial alternative for enabling ultrasensitivity and bistability in signaling networks. Genomic analyses reveal that up 1.7% of all identified histidine kinases have the potential to be split and bifunctional
Doctor of Philosophy
dissertationThe chemotaxis signaling pathway of Escherichia coli is the best studied signal transduction mechanism in biology. Better understanding of this signal-processing machinery at the molecular level will foster new therapies for pathogenic infections and new designs of highly specific and sensitive biosensors. A sensory adaptation system plays a critical role in this chemotactic behavior. Sensory adaptation is regulated by covalent modifications of the chemoreceptors, mediated by CheR and CheB enzymes. This PhD research project explores the sensory adaptation mechanism of the serine receptor (Tsr) in E. coli. In this study, I showed that all adaptation sites of Tsr, including the fifth unorthodox site, worked in a similar way to regulate Tsr signal output. I also found that site 5 (Tsr-E502) and site 3 (Tsr-Q311) have differential signaling effects, mainly due to their different localizations on the methylation helices. Finally, I discovered unexpected signaling effects of CheR and CheB, the two adaptation enzymes. In summary, this thesis provides important insights into the sensory adaptation system and receptor input-output control in bacterial chemotaxis
Robust Signal Processing in Living Cells
Cellular signaling networks have evolved an astonishing ability to function reliably and with high fidelity in uncertain environments. A crucial prerequisite for the high precision exhibited by many signaling circuits is their ability to keep the concentrations of active signaling compounds within tightly defined bounds, despite strong stochastic fluctuations in copy numbers and other detrimental influences. Based on a simple mathematical formalism, we identify topological organizing principles that facilitate such robust control of intracellular concentrations in the face of multifarious perturbations. Our framework allows us to judge whether a multiple-input-multiple-output reaction network is robust against large perturbations of network parameters and enables the predictive design of perfectly robust synthetic network architectures. Utilizing the Escherichia coli chemotaxis pathway as a hallmark example, we provide experimental evidence that our framework indeed allows us to unravel the topological organization of robust signaling. We demonstrate that the specific organization of the pathway allows the system to maintain global concentration robustness of the diffusible response regulator CheY with respect to several dominant perturbations. Our framework provides a counterpoint to the hypothesis that cellular function relies on an extensive machinery to fine-tune or control intracellular parameters. Rather, we suggest that for a large class of perturbations, there exists an appropriate topology that renders the network output invariant to the respective perturbations
Mathematical analysis of the Escherichia coli chemotaxis signalling pathway
We undertake a detailed mathematical analysis of a recent nonlinear ordinary differential equation (ODE) model describing the chemotactic signalling cascade within an {\it Escherichia coli} cell. The model includes a detailed description of the cell signalling cascade and an average approximation of the receptor activity. A steady-state stability analysis reveals the system exhibits one positive real steady-state which is shown to be asymptotically stable. Given the occurrence of a negative feedback between phosphorylated CheB (CheB-P) and the receptor state, we ask under what conditions, the system may exhibit oscillatory type behaviour. A detailed analysis of parameter space reveals that whilst variation in kinetic rate parameters within known biological limits is unlikely to lead to such behaviour, changes in the total concentration of the signalling proteins does. We postulate that experimentally observed overshoot behaviour can actually be described by damped oscillatory dynamics and consider the relationship between overshoot amplitude, total cell protein concentration and the magnitude of the external ligand stimulus. Model reductions of the full ODE model allow us to understand the link between phosphorylation events and the negative feedback between CheB-P and receptor methylation, as well as elucidate why some mathematical models exhibit overshoot and others do not. Our manuscript closes by discussing intercell variability of total protein concentration as means of ensuring the overall survival of a population as cells are subjected to different environments
Genetics of bacterial chemotaxis
Journal ArticleMany types of motile bacteria are capable of detecting and responding to changes in their environment. Phototactic, chemotactic and thermotactic movements in bacteria are similar to more complex behaviours seen in higher organisms, and constitute useful model systems for investigating the molecular events underlying sensory transduction phenomena. The best-studied of these systems is the chemotactic behaviour of Escherichia coli and Salmonella typhimurium. Extensive genetic and biochemical analyses of the chemotaxis machinery in these organisms has led to an intriguing picture of how bacteria detect and process sensory information. At the molecular level, the chemotactic apparatus of bacteria has proven to be surprisingly sophisticated, although many of the mechanistic details are still poorly understood
Auxiliary phosphatases in two-component signal transduction
Signal termination in two-component systems occurs by loss of the phosphoryl group from the response regulator protein. This review explores our current understanding of the structures, catalytic mechanisms and means of regulation of the known families of phosphatases that catalyze response regulator dephosphorylation. The CheZ and CheC/CheX/FliY families, despite different overall structures, employ identical catalytic strategies using an amide side chain to orient a water molecule for in-line attack of the aspartyl phosphate. Spo0E phosphatases contain sequence and structural features that suggest a strategy similar to the chemotaxis phosphatases but the mechanism used by the Rap phosphatases is not yet elucidated. Identification of features shared by phosphatase families may aid in identification of currently unrecognized classes of response regulator phosphatases
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