Bacterial cells respond to the changes in their chemical environment (chemotaxis) by binding of the chemical ligand to membrane receptors, activating the multi-protein receptor signaling complex, and generating a diffusible intracellular signal that ultimately regulates the rotation of the flagella motor. The chemotactic signaling pathway in E. coli has emerged as the best-characterized signal transduction network in biology. All the protein components responsible for excitation and adaptation have been identified and characterized, and their soluble domain structures determined to atomic resolution. There have also been numerous mutagenesis, chemical cross-linking and GFP-tagging studies on chemotaxis signaling. However, the structures of the basic signaling unit consisting of the receptor, the kinase CheA and coupling protein CheW, that are essential to understand the molecular mechanism of the signal transduction remain elusive. The studies described in this proposal are targeted to obtaining high resolution structures of the ternary receptor signaling complex, as well as structures of its higher order assembly in intact cells, primarily by high resolution three-dimensional cryo- electron microscopy. We will also characterize the conformational changes of the complex upon receptor activation/inactivation using both structural methods and functional assays. These structures, combining with functional and biochemical analysis, are expected to provide a detailed understanding on how minute external chemical signals are transmitted to the histidine kinase and amplified through a large assembly of signaling complexes within the native cells. These results will also provide a foundation for generating computational models of receptor signaling systems, since the E. coli chemotaxis has been an ideal model system for understanding the molecular mechanisms of signal transduction and signal processing in general.

Public Health Relevance

The mechanism of stimulus-response coupling in bacterial chemotaxis has emerged as a paradigm for understanding the principles of intracellular signal transduction both in bacterial and eukaryotic cells. E. coli chemotaxis is also a representative of the highly conserved """"""""two-component systems"""""""" that control processes ranging from cell differentiation and development to circadian rhythms and pathogenesis in prokaryotes including both eubacterial and archaeal species. These systems all contain two central enzymes, a histidine protein kinase and a response regulator that mediates phosphor relay signal transduction networks in microorganisms and plants. In addition, bacterial chemotaxis response is crucial for colonization and infection, and the signal transduction systems that mediate such responses are potential targets for antimicrobial drug development. A deeper understanding of the mechanism of signaling in bacterial chemotaxis is therefore of great interests for many areas of biology and medicine. Our proposed efforts for a comprehensive and integrated structural and functional analysis of chemotaxis receptor signaling complexes and complex arrays will provide insight into receptor-kinase interaction, signaling complex formation, sensory cluster formation and conformation coupling, and contribute to a better understanding of the signal transduction and signal processing in general.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
1R01GM085043-01A1
Application #
7730460
Study Section
Biochemistry and Biophysics of Membranes Study Section (BBM)
Program Officer
Flicker, Paula F
Project Start
2009-08-17
Project End
2014-07-31
Budget Start
2009-08-17
Budget End
2010-07-31
Support Year
1
Fiscal Year
2009
Total Cost
$281,792
Indirect Cost
Name
University of Pittsburgh
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213
Himes, Benjamin A; Zhang, Peijun (2018) emClarity: software for high-resolution cryo-electron tomography and subtomogram averaging. Nat Methods 15:955-961
Cassidy, C Keith; Himes, Benjamin A; Luthey-Schulten, Zaida et al. (2018) CryoEM-based hybrid modeling approaches for structure determination. Curr Opin Microbiol 43:14-23
Perilla, Juan R; Zhao, Gongpu; Lu, Manman et al. (2017) CryoEM Structure Refinement by Integrating NMR Chemical Shifts with Molecular Dynamics Simulations. J Phys Chem B 121:3853-3863
Alvarez, Frances J D; He, Shaoda; Perilla, Juan R et al. (2017) CryoEM structure of MxB reveals a novel oligomerization interface critical for HIV restriction. Sci Adv 3:e1701264
Merg, Andrea D; Boatz, Jennifer C; Mandal, Abhishek et al. (2016) Peptide-Directed Assembly of Single-Helical Gold Nanoparticle Superstructures Exhibiting Intense Chiroptical Activity. J Am Chem Soc :
Liu, Chuang; Perilla, Juan R; Ning, Jiying et al. (2016) Cyclophilin A stabilizes the HIV-1 capsid through a novel non-canonical binding site. Nat Commun 7:10714
Yeom, Jihyeon; Yeom, Bongjun; Chan, Henry et al. (2015) Chiral templating of self-assembling nanostructures by circularly polarized light. Nat Mater 14:66-72
Zhao, Gongpu; Zhang, Peijun (2014) CryoEM analysis of capsid assembly and structural changes upon interactions with a host restriction factor, TRIM5?. Methods Mol Biol 1087:13-28
Schirra Jr, Randall T; Zhang, Peijun (2014) Correlative fluorescence and electron microscopy. Curr Protoc Cytom 70:12.36.1-10
Hickey, Robert J; Koski, Jason; Meng, Xin et al. (2014) Size-controlled self-assembly of superparamagnetic polymersomes. ACS Nano 8:495-502

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