Structures of Merkel Cell Polyomavirus VP1 Complexes Define a Sialic Acid Binding Site Required for Infection

Neu, Ursula; Hengel, Holger; Blaum, Bärbel S.; Schowalter, Rachel M.; Macejak, Dennis G.; Gilbert, Michel; Wakarchuk, Warren W.; Imamura, Akira; Ando, Hiromune; Kiso, Makoto; Arnberg, Niklas; Garcea, Robert L.; Peters, Thomas; Buck, Christopher B.; Stehle, Thilo

doi:10.1371/journal.ppat.1002738

Cited by 81 publications

(107 citation statements)

References 58 publications

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“…The I-strand is split into two parts named I and I=. As is typical for polyomavirus VP1 structures, rather poor electron density was observed for the CDloops at the base of the HPyV6 and HPyV7 pentamers (25,26,(28)(29)(30)(31)(32). This loop is flexible and assumes different conformations even in the context of the intact virion (25,26,28).…”

Section: Resultsmentioning

confidence: 99%

“…The presence and roles of VP2 and VP3 seem to differ among polyomavirus species (27). All known structures of polyomavirus VP1 show extended and structurally variable surface loops that emanate from a conserved ␤-sheet core structure formed by strands B, I, D, and G and strands C, H, E, and F (25,26,(28)(29)(30)(31)(32)(33)(34)(35). These surface loops, named BC-, DE-, HI-, and EF-loops after the ␤-strands connected by them, are chiefly responsible for viral antigenicity.…”

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confidence: 99%

“…For each virus, they form a unique virus-host interaction platform that determines host range, cell tropism, viral spread, and pathogenicity. Engagement of sialylated glycan motifs during cell attachment and entry is a common feature of the better-studied orthopolyomaviruses (28)(29)(30)(32)(33)(34)(35)(36). In contrast, the routes of infection, transmission, cell tropism, receptor specificity, and entry pathways of wukipolyomaviruses remain largely mysterious.…”

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confidence: 99%

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Structure Analysis of the Major Capsid Proteins of Human Polyomaviruses 6 and 7 Reveals an Obstructed Sialic Acid Binding Site

Stroh

Neu

Blaum

et al. 2014

J Virol

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Human polyomavirus 6 (HPyV6) and HPyV7 are commonly found on human skin. We have determined the X-ray structures of their major capsid protein, VP1, at resolutions of 1.8 and 1.7 Å, respectively. In polyomaviruses, VP1 commonly determines antigenicity as well as cell-surface receptor specificity, and the protein is therefore linked to attachment, tropism, and ultimately, viral pathogenicity. The structures of HPyV6 and HPyV7 VP1 reveal uniquely elongated loops that cover the bulk of the outer virion surfaces, obstructing a groove that binds sialylated glycan receptors in many other polyomaviruses. In support of this structural observation, interactions of VP1 with ␣2,3-and ␣2,6-linked sialic acids could not be detected in solution by nuclear magnetic resonance spectroscopy. Single-cell binding studies indicate that sialylated glycans are likely not required for initial attachment to cultured human cells. Our findings establish distinct antigenic properties of HPyV6 and HPyV7 capsids and indicate that these two viruses engage nonsialylated receptors. IMPORTANCE Eleven new human polyomaviruses, including the skin viruses HPyV6 and HPyV7, have been identified during the last decade.In contrast to better-studied polyomaviruses, the routes of infection, cell tropism, and entry pathways of many of these new viruses remain largely mysterious. Our high-resolution X-ray structures of major capsid proteins VP1 from HPyV6 and from HPyV7 reveal critical differences in surface morphology from those of all other known polyomavirus structures. A groove that engages specific sialic acid-containing glycan receptors in related polyomaviruses is obstructed, and VP1 of HPyV6 and HPyV7 does not interact with sialylated compounds in solution or on cultured human cells. A comprehensive comparison with other structurally characterized polyomavirus VP1 proteins enhances our understanding of molecular determinants that underlie receptor specificity, antigenicity, and, ultimately, pathogenicity within the polyomavirus family and highlight the need for structure-based analysis to better define phylogenetic relationships within the growing polyomavirus family and perhaps also for other viruses.

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Structure Analysis of the Major Capsid Proteins of Human Polyomaviruses 6 and 7 Reveals an Obstructed Sialic Acid Binding Site

Stroh

Neu

Blaum

et al. 2014

J Virol

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“…VP1 is the major polyomavirus capsid protein, and a collection of available VP1 structures from different polyomaviruses shows that the protein adopts a jelly roll fold and assembles into a homopentamer around a central cavity (24)(25)(26)(27)(28)(29)(30)(31). While the pentameric core structure is conserved in all VP1 proteins, these structures from different polyomaviruses exhibit substantial differences in the sequence, length, and conformation of their surface-exposed loops.…”

mentioning

confidence: 99%

“…While the pentameric core structure is conserved in all VP1 proteins, these structures from different polyomaviruses exhibit substantial differences in the sequence, length, and conformation of their surface-exposed loops. These highly variable regions contain the sites for receptor engagement (25)(26)(27)29) as well as antibody binding (21)(22)(23)32). All human polyomavirus VP1 structures known to date engage glycans terminating in 5-N-acetyl neuraminic acid (Neu5Ac) as receptors (27,(29)(30)(31), with, in some cases, drastically different interactions taking place.…”

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confidence: 99%

Crystallographic and Glycan Microarray Analysis of Human Polyomavirus 9 VP1 Identifies N -Glycolyl Neuraminic Acid as a Receptor Candidate

Khan

Liu

Neu

et al. 2014

J Virol

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Human polyomavirus 9 (HPyV9) is a closely related homologue of simian B-lymphotropic polyomavirus (LPyV). In order to define the architecture and receptor binding properties of HPyV9, we solved high-resolution crystal structures of its major capsid protein, VP1, in complex with three putative oligosaccharide receptors identified by glycan microarray screening. Comparison of the properties of HPyV9 VP1 with the known structure and glycan-binding properties of LPyV VP1 revealed that both viruses engage short sialylated oligosaccharides, but small yet important differences in specificity were detected. Surprisingly, HPyV9 VP1 preferentially binds sialyllactosamine compounds terminating in 5-N-glycolyl neuraminic acid (Neu5Gc) over those terminating in 5-N-acetyl neuraminic acid (Neu5Ac), whereas LPyV does not exhibit such a preference. The structural analysis demonstrated that HPyV9 makes specific contacts, via hydrogen bonds, with the extra hydroxyl group present in Neu5Gc. An equivalent hydrogen bond cannot be formed by LPyV VP1. IMPORTANCEThe most common sialic acid in humans is 5-N-acetyl neuraminic acid (Neu5Ac), but various modifications give rise to more than 50 different sialic acid variants that decorate the cell surface. Unlike most mammals, humans cannot synthesize the sialic acid variant 5-N-glycolyl neuraminic acid (Neu5Gc) due to a gene defect. Humans can, however, still acquire this compound from dietary sources. The role of Neu5Gc in receptor engagement and in defining viral tropism is only beginning to emerge, and structural analyses defining the differences in specificity for Neu5Ac and Neu5Gc are still rare. Using glycan microarray screening and high-resolution protein crystallography, we have examined the receptor specificity of a recently discovered human polyomavirus, HPyV9, and compared it to that of the closely related simian polyomavirus LPyV. Our study highlights critical differences in the specificities of both viruses, contributing to an enhanced understanding of the principles that underlie pathogen selectivity for modified sialic acids.

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Metabolisches Glykoengineering mit N‐Acyl‐Seiten‐ ketten‐modifizierten Mannosaminen

2016

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Beim metabolischen Glykoengineering (MGE) werden Zellen und Tiere mit nichtnatürlichen Derivaten von Monosacchariden behandelt. Diese werden nach ihrer Aufnahme ins Zytosol metabolisiert und anschließend auf neusynthetisierten Glykokonjugaten exprimiert. MGE wurde zuerst für sialylierte Glykane realisiert, mit N‐Acyl‐modifizierten Mannosaminen als Vorstufen für nichtnatürliche Sialinsäuren. Voraussetzung ist die Promiskuität der Enzyme des Roseman‐Warren‐Biosyntheseweges. Diese tolerieren spezifische Modifikationen der N‐Acyl‐Seitenkette von Mannosaminderivaten, z. B. Elongation mit Methylen‐Gruppen (aliphatische Modifikationen) oder Einfügen reaktiver Gruppen (bioorthogonale Modifikationen). Nichtnatürliche Sialinsäuren werden in Glykokonjugate von Zellen und Organen integriert. MGE hat faszinierende biologische Konsequenzen für die behandelten Zellen (aliphatisches MGE) und ermöglicht die Visualisierung der Topographie und Dynamik der sialylierten Glykane in vitro, ex vivo und in vivo (bioorthogonales MGE).

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Structures of Merkel Cell Polyomavirus VP1 Complexes Define a Sialic Acid Binding Site Required for Infection

Cited by 81 publications

References 58 publications

Structure Analysis of the Major Capsid Proteins of Human Polyomaviruses 6 and 7 Reveals an Obstructed Sialic Acid Binding Site

Structure Analysis of the Major Capsid Proteins of Human Polyomaviruses 6 and 7 Reveals an Obstructed Sialic Acid Binding Site

Crystallographic and Glycan Microarray Analysis of Human Polyomavirus 9 VP1 Identifies N -Glycolyl Neuraminic Acid as a Receptor Candidate

Metabolisches Glykoengineering mit N‐Acyl‐Seiten‐ ketten‐modifizierten Mannosaminen

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