Strategies for carbohydrate model building, refinement and validation

Agirre, Jon

doi:10.1107/s2059798316016910

Cited by 58 publications

(72 citation statements)

References 101 publications

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“…Asparagine (Asn)‐linked glycosylation is the most common type of N‐glycosylation of eukaryotic proteins, and it is also found in viruses, including HIV and Ebola . Agirre reports that the fraction of Asn‐linked glycosylation in the PDB as of 2013 is 5.5% (and increasing) .…”

Section: Introductionmentioning

confidence: 99%

Current developments in Coot for macromolecular model building of Electron Cryo‐microscopy and Crystallographic Data

2020

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Coot is a tool widely used for model building, refinement, and validation of macromolecular structures. It has been extensively used for crystallography and, more recently, improvements have been introduced to aid in cryo‐EM model building and refinement, as cryo‐EM structures with resolution ranging 2.5–4 A are now routinely available. Model building into these maps can be time‐consuming and requires experience in both biochemistry and building into low‐resolution maps. To simplify and expedite the model building task, and minimize the needed expertise, new tools are being added in Coot. Some examples include morphing, Geman‐McClure restraints, full‐chain refinement, and Fourier‐model based residue‐type‐specific Ramachandran restraints. Here, we present the current state‐of‐the‐art in Coot usage.

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Section: Introductionmentioning

confidence: 99%

Current developments in Coot for macromolecular model building of Electron Cryo‐microscopy and Crystallographic Data

2020

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“…The last decade saw the introduction of new experimental techniques that have almost doubled the structural throughput of glycoproteins. About 10% of the structures deposited annually contain carbohydrates but, while those covalently-linked accounted for ~2.5% of the total in the early 2000Õs, this number has increased to ~5% since 2010 [1]. It is apparent that the structural biology community has been caught off-guard; a number of communications have raised issues on the way carbohydrates are represented in structural databases [2][3][4], with numerous problems affecting nomenclature, structure and conformation which, in combination, may affect more than 30% of the glyco-related structural data deposited in the Protein Data Bank (PDB).…”

Section: Introductionmentioning

confidence: 99%

“…D-mannopyranose is encoded as two three-letter codes, MAN (a-anomer) and BMA (b-anomer). Some dictionary generation programs may produce an improbable high-energy conformer as starting coordinates, or create torsion restraints that lock it into that, or other high-energy conformation [1]. Model building and refinement programs do not take conformational preferences into account, which has a deleterious knock-on effect on other aspects of the model, from interactions to linkage torsions.…”

Section: Introductionmentioning

confidence: 99%

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Carbohydrate 3D structure validation

Joosten

Lütteke

2017

Current Opinion in Structural Biology

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Glycoproteins and protein-carbohydrate complexes in the worldwide Protein Data Bank (wwPDB) can be an excellent source of information for glycoscientists. Unfortunately, a rather large number of errors and inconsistencies is found in the glycan moieties of these 3D structures. This review illustrates frequent problems of carbohydrate moieties in wwPDB entries, such as nomenclature issues, incorrect N-glycan core structures, missing or erroneous linkages, or poor glycan geometry, and describes the carbohydrate-specific validation tools that are designed to identify such problems. Recommendations how to avoid these issues or how to rectify incorrect structures are also given.

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“…The overall glycan geometry was validated using programs including PDB CArbohydrate REsidue check (pdb-care; http:// www.glycosciences.de/tools/pdb-care/), CArbohydrate Ramachandran Plot (carp; http://www.glycosciences.de/tools/carp/) and Privateer (Agirre et al, 2015;Agirre, 2017). Glycans were built into the initial models for the 3.9 and 3.5 Å resolution IOMA-10-1074-BG505 crystal structures using 2F o À F c maps calculated with model phases and using composite-annealed OMIT maps calculated with phases from which the model was omitted (Adams et al, 2010).…”

Section: Glycan Interpretation and Refinementmentioning

confidence: 99%

X-ray and EM structures of a natively glycosylated HIV-1 envelope trimer

Gristick

Wang

Björkman

2017

Acta Crystallogr D Struct Biol

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The structural and biochemical characterization of broadly neutralizing anti-HIV-1 antibodies (bNAbs) has been essential in guiding the design of potential vaccines to prevent infection by HIV-1. While these studies have revealed critical mechanisms by which bNAbs recognize and/or accommodate N-glycans on the trimeric envelope glycoprotein (Env), they have been limited to the visualization of high-mannose glycan forms only, since heterogeneity introduced from the presence of complex glycans makes it difficult to obtain high-resolution structures. 3.5 and 3.9 Å resolution crystal structures of the HIV-1 Env trimer with fully processed and native glycosylation were solved, revealing a glycan shield of high-mannose and complex-type N-glycans that were used to define the complete epitopes of two bNAbs. Here, the refinement of the N-glycans in the crystal structures is discussed and comparisons are made with glycan densities in glycosylated Env structures derived by single-particle cryo-electron microscopy.

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Strategies for carbohydrate model building, refinement and validation

Cited by 58 publications

References 101 publications

Current developments in Coot for macromolecular model building of Electron Cryo‐microscopy and Crystallographic Data

Current developments in Coot for macromolecular model building of Electron Cryo‐microscopy and Crystallographic Data

Carbohydrate 3D structure validation

X-ray and EM structures of a natively glycosylated HIV-1 envelope trimer

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