Mihály Koltai scite author profile

BackgroundSignaling networks in eukaryotes are made up of upstream and downstream subnetworks. The upstream subnetwork contains the intertwined network of signaling pathways, while the downstream regulatory part contains transcription factors and their binding sites on the DNA as well as microRNAs and their mRNA targets. Currently, most signaling and regulatory databases contain only a subsection of this network, making comprehensive analyses highly time-consuming and dependent on specific data handling expertise. The need for detailed mapping of signaling systems is also supported by the fact that several drug development failures were caused by undiscovered cross-talk or regulatory effects of drug targets. We previously created a uniformly curated signaling pathway resource, SignaLink, to facilitate the analysis of pathway cross-talks. Here, we present SignaLink 2, which significantly extends the coverage and applications of its predecessor.DescriptionWe developed a novel concept to integrate and utilize different subsections (i.e., layers) of the signaling network. The multi-layered (onion-like) database structure is made up of signaling pathways, their pathway regulators (e.g., scaffold and endocytotic proteins) and modifier enzymes (e.g., phosphatases, ubiquitin ligases), as well as transcriptional and post-transcriptional regulators of all of these components. The user-friendly website allows the interactive exploration of how each signaling protein is regulated. The customizable download page enables the analysis of any user-specified part of the signaling network. Compared to other signaling resources, distinctive features of SignaLink 2 are the following: 1) it involves experimental data not only from humans but from two invertebrate model organisms, C. elegans and D. melanogaster; 2) combines manual curation with large-scale datasets; 3) provides confidence scores for each interaction; 4) operates a customizable download page with multiple file formats (e.g., BioPAX, Cytoscape, SBML). Non-profit users can access SignaLink 2 free of charge at http://SignaLink.org.ConclusionsWith SignaLink 2 as a single resource, users can effectively analyze signaling pathways, scaffold proteins, modifier enzymes, transcription factors and miRNAs that are important in the regulation of signaling processes. This integrated resource allows the systems-level examination of how cross-talks and signaling flow are regulated, as well as provide data for cross-species comparisons and drug discovery analyses.

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Secondary bacterial flagellar system improves bacterial spreading by increasing the directional persistence of swimming

Bubendorfer

Koltai

Roßmann

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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As numerous bacterial species, Shewanella putrefaciens CN-32 possesses a complete secondary flagellar system. A significant subpopulation of CN-32 cells induces expression of the secondary system under planktonic conditions, resulting in formation of one, sometimes two, filaments at lateral positions in addition to the primary polar flagellum. Mutant analysis revealed that the single chemotaxis system primarily or even exclusively addresses the main polar flagellar system. Cells with secondary filaments outperformed their monopolarly flagellated counterparts in spreading on soft-agar plates and through medium-filled channels despite having lower swimming speed. While mutant cells with only polar flagella navigate by a "run-reverse-flick" mechanism resulting in effective cell realignments of about 90°, wild-type cells with secondary filaments exhibited a range of realignment angles with an average value of smaller than 90°. Mathematical modeling and computer simulations demonstrated that the smaller realignment angle of wild-type cells results in the higher directional persistence, increasing spreading efficiency both with and without a chemical gradient. Taken together, we propose that in S. putrefaciens CN-32, cell propulsion and directional switches are mainly mediated by the polar flagellar system, while the secondary filament increases the directional persistence of swimming and thus of spreading in the environment.bacterial motility | cell reorientation | CheY | lateral flagella T he ability to actively explore and exploit the environment provides a major advantage for all kinds of organisms, including bacteria (1, 2). Among bacteria, flagella are common and efficient organelles of locomotion that consist of long, helical, proteinaceous filaments extending from the cell's surface and are rotated by a membrane-embedded motor to which they are attached by the flexible hook structure. The majority of flagellar motors function in a bidirectional fashion and can rotate either counterclockwise (CCW) or clockwise (CW) (3, 4). Most bacterial species navigate using a random walk that originates from an alternation of straight runs and cell reorientations. In the absence of gradients, such random walk results in a uniform spreading in the environment. In gradients of environmental stimuli, bacterial random walk becomes biased, whereby cells use temporal comparisons of the stimulus strength to suppress reorientations while swimming in a favorable direction. This behavior is controlled by one or more chemotaxis systems, which transduce environmental stimuli to control flagellar motors (5). Signals perceived by an array of sensor proteins are converted into the phosphorylation state of a soluble signal-transmitting protein, CheY. Phosphorylated CheY can directly interact with the flagellar motor and induce a switch in rotation or a motor break. In peritrichously flagellated bacteria with several filaments, such as the paradigm system of Escherichia coli, CCW rotation leads to formation of a flagellar bundle that drives ...

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Mihály Koltai

SignaLink 2 – a signaling pathway resource with multi-layered regulatory networks

Secondary bacterial flagellar system improves bacterial spreading by increasing the directional persistence of swimming

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