Dimeric Structure of the Transmembrane Domain of Glycophorin A in Lipidic and Detergent Environments

Mineev, K.S.; Bocharov, Eduard V.; Volynsky, Pavel E.; Goncharuk, Marina V.; Tkach, Elena N.; Ermolyuk, Yaroslav S.; Schulga, Alexey; Chupin, Vladimir; Maslennikov, Innokentiy; Efremov, Roman G.; Arseniev, Alexander S.

doi:10.32607/20758251-2011-3-2-90-98

Cited by 37 publications

(56 citation statements)

References 35 publications

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“…Its transmembrane (TM) dimer structure was determined by solution nuclear magnetic resonance (NMR) spectroscopy in detergent micelles (PDB ID: 1AFO) [194] and in lipid bicelles (PDB ID: 2KPE, 2KPF) [195]. GpA has long been a model protein to investigate structure and stability of membrane protein dimers in different membrane environments [196,197] as well as a popular target of membrane simulations [72,74,75,119,123,187,198].…”

Section: Recent Membrane and Membrane Protein Simulations Using Enmentioning

confidence: 99%

Molecular dynamics simulations of biological membranes and membrane proteins using enhanced conformational sampling algorithms

Mori

Miyashita²,

et al. 2016

Biochimica et Biophysica Acta (BBA) - Biomembranes

116

108

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This paper reviews various enhanced conformational sampling methods and explicit/implicit solvent/membrane models, as well as their recent applications to the exploration of the structure and dynamics of membranes and membrane proteins. Molecular dynamics simulations have become an essential tool to investigate biological problems, and their success relies on proper molecular models together with efficient conformational sampling methods. The implicit representation of solvent/membrane environments is reasonable approximation to the explicit all-atom models, considering the balance between computational cost and simulation accuracy. Implicit models can be easily combined with replica-exchange molecular dynamics methods to explore a wider conformational space of a protein. Other molecular models and enhanced conformational sampling methods are also briefly discussed. As application examples, we introduce recent simulation studies of glycophorin A, phospholamban, amyloid precursor protein, and mixed lipid bilayers and discuss the accuracy and efficiency of each simulation model and method. This article is part of a Special Issue entitled: Membrane Proteins. Guest Editors: J.C. Gumbart and Sergei Noskov.

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Section: Recent Membrane and Membrane Protein Simulations Using Enmentioning

confidence: 99%

Molecular dynamics simulations of biological membranes and membrane proteins using enhanced conformational sampling algorithms

Mori

Miyashita²,

et al. 2016

Biochimica et Biophysica Acta (BBA) - Biomembranes

116

108

View full text Add to dashboard Cite

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“…). Nine of these are RTKs (ErbB1‐4 , FGFR3 , PDGFR , VEGFR2 , EphA1‐2 ), three are immunoreceptors (lymphoid/myeloid receptor signaling module (DAP12) , the ζ chain (ζζ) , Toll‐like receptor 3 (TLR3) ), one belongs to the APLPs (APP ), and one belongs to the GP family (GpA , ). Two similar homodimer structures exist of the GpA‐TMD and the APP‐TMD (http://www.rcsb.org/pdb/search/structidSearch.do?structureId=1AFO and http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2KPF/http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2KPE for the GpA and http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2LOH and http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2LZ3 for the APP), which in each case have been solved by different groups, while two different homodimer structures have been solved of the ErbB1‐TMD (http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2M20 and http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2M0B ) and the ErbB2‐TMD (http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2JWA and http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2N2A ).…”

Section: Single‐pass Tmds and Their Structuresmentioning

confidence: 99%

“…The GpA‐TMD homodimers, solved in DPC micelles and DMPC bicelles by two different groups (http://www.rcsb.org/pdb/search/structidSearch.do?structureId=1AFO in DPC micelles , and http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2KPE and http://www.rcsb.org/pdb/search/structidSearch.do?structureId=2KPF in DPC micelles and DMPC bicelles, respectively ) have very similar backbone structures. Only a small deviation in the last helical turn is immediately apparent, giving a variation in the helical C‐terminal distances of 2.5 Å between the structures solved in DPC.…”

Section: Structural Quality Of the Tmd Structuresmentioning

confidence: 99%

“…As discussed, the overall quality of the available structures appears limited, and, in addition, the oligomeric state of the protein is not always clearly defined. The homodimeric state of most of the TMDs has mainly been confirmed under the applied conditions by acquisition of interhelical NOEs , sometimes in combination with cross‐linking experiments or with the detection of size changes as estimated from backbone relaxation rates or ultracentrifugation . Interhelical NOEs obtained in filter‐based experiments should preferably be compared to background reference spectra of the protein in the absence of unlabeled protein to avoid misinterpretation of strong intramolecular peaks leaking through the filter due to imperfect isotope labeling , but it is rarely clear if these have been acquired.…”

Section: Are We Missing Out On the Dynamic Oligomeric State? How To Smentioning

confidence: 99%

“…Nine of these are RTKs (ErbB1-4 [15,[58][59][60][61][62], FGFR3 [63], PDGFR [64], VEGFR2 [23], EphA1-2 [65,66]), three are immunoreceptors (lymphoid/myeloid receptor signaling module (DAP12) [67], the f chain (ff) [68], Toll-like receptor 3 (TLR3) [69]), one belongs to the APLPs (APP [70,71]), and one belongs to the GP family (GpA [33], [72]). Two similar homodimer structures exist of the GpA-TMD and the APP-TMD (1AFO [33] and 2KPF/2KPE [72] for the GpA and 2LOH [71] and 2LZ3 [70] for the APP), which in each case have been solved by different groups, while two different homodimer structures have been solved of the ErbB1-TMD (2M20 [15] and 2M0B [62]) and the ErbB2-TMD (2JWA [58] and 2N2A [61]). The TMD homodimer structures all consist of two main a-helices harboring 23-38 residues each, and include the regions bioinformatically predicted to be the TMD [57].…”

Section: Homodimeric Tmd Structuresmentioning

confidence: 99%

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Understanding single‐pass transmembrane receptor signaling from a structural viewpoint—what are we missing?

2016

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Single‐pass transmembrane receptors are involved in essential processes of both physiological and pathological nature and represent more than 1300 proteins in the human genome. Despite the high biological relevance of these receptors, the mechanisms of the signal transductions they facilitate are incompletely understood. One major obstacle is the lack of structures of the transmembrane domains that connect the extracellular ligand‐binding domains to the intracellular signaling platforms. Over a period of almost 20 years since the first structure was reported, only 21 of these receptors have become represented by a transmembrane domain structure. This scarceness stands in strong contrast to the significance of these transmembrane α‐helices for receptor functionality. In this review, we explore the properties and qualities of the current set of structures, as well as the methodological difficulties associated with their characterization and the challenges left to be overcome. Without an increased and focused effort to bring this class of proteins on par with the remaining membrane protein field, a serious lag in their biological understanding looms. Design of pharmaceutical agents, prediction of mutational affects in relation to disease, and deciphering of functional mechanisms require high‐resolution structural information, especially when dealing with a domain carrying so much functionality in so few residues.

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More than the sum of the parts: Toward full‐length receptor tyrosine kinase structures

2019

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Intercellular communication governs complex physiological processes ranging from growth and development to the maintenance of cellular and organ homeostasis. In nearly all metazoans, receptor tyrosine kinases (RTKs) are central players in these diverse and fundamental signaling processes. Aberrant RTK signaling is at the root of many developmental diseases and cancers and it remains a key focus of targeted therapies, several of which have achieved considerable success in patients. These therapeutic advances in targeting RTKs have been propelled by numerous genetic, biochemical, and structural studies detailing the functions and molecular mechanisms of regulation and activation of RTKs. The latter in particular have proven to be instrumental for the development of new drugs, selective targeting of mutant forms of RTKs found in disease, and counteracting ensuing drug resistance. However, to this day, such studies have not yet yielded high‐resolution structures of intact RTKs that encompass the extracellular and intracellular domains and the connecting membrane‐spanning transmembrane domain. Technically challenging to obtain, these structures are instrumental to complete our understanding of the mechanisms by which RTKs are activated by extracellular ligands and of the effect of pathological mutations that do not directly reside in the catalytic sites of tyrosine kinase domains. In this review, we focus on the recent progress toward obtaining such structures and the insights already gained by structural studies of the subdomains of the receptors that belong to the epidermal growth factor receptor, insulin receptor, and platelet‐derived growth factor receptor RTK families. © 2019 IUBMB Life, 71(6):706–720, 2019

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Dimeric Structure of the Transmembrane Domain of Glycophorin A in Lipidic and Detergent Environments

Cited by 37 publications

References 35 publications

Molecular dynamics simulations of biological membranes and membrane proteins using enhanced conformational sampling algorithms

Molecular dynamics simulations of biological membranes and membrane proteins using enhanced conformational sampling algorithms

Understanding single‐pass transmembrane receptor signaling from a structural viewpoint—what are we missing?

More than the sum of the parts: Toward full‐length receptor tyrosine kinase structures

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