David J. VanDyke scite author profile

SummaryRecently, the flagellin proteins of Methanococcus maripaludis were found to harbour an N-linked tetrasaccharide composed of N-acetylgalactosamine, di-acetylated glucuronic acid, an acetylated and acetamidino-modified mannuronic acid linked to threonine, and a novel terminal sugar [(5S)-2-acetamido-2,4-dideoxy-5-O-methyl-a-L-erythro-hexos-5-ulo-1,5-pyranose]. To identify genes involved in the assembly and attachment of this glycan, in-frame deletions were constructed in putative glycan assembly genes. Successful deletion of genes encoding three glycosyltransferases and an oligosaccharyltransferase (Stt3p homologue) resulted in flagellins of decreased molecular masses as evidenced by immunoblotting, indicating partial or completely absent glycan structures. Deletion of the oligosaccharyltransferase or the glycosyltransferase responsible for the transfer of the second sugar in the chain resulted in flagellins that were not assembled into flagella filaments, as evidenced by electron microscopy. Deletions of the glycosyltransferases responsible for the addition of the third and terminal sugars in the glycan were confirmed by mass spectrometry analysis of purified flagellins from these mutants. Although flagellated, these mutants had decreased motility as evidenced by semi-swarm plate analysis with the presence of each additional sugar improving movement capabilities.

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A novel N-linked flagellar glycan from Methanococcus maripaludis

Kelly

Logan

Jarrell

et al. 2009

Carbohydrate Research

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Sweet to the extreme: protein glycosylation in Archaea

Yurist-Doutsch

Chaban

VanDyke

et al. 2008

Molecular Microbiology

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SummaryPost-translational modifications account for much of the biological diversity generated at the proteome level. Of these, glycosylation is the most prevalent. Long thought to be unique to Eukarya, it is now clear that both Bacteria and Archaea are also capable of N-glycosylation, namely the covalent linkage of oligosaccharides to select target asparagine residues. However, while the eukaryal and bacterial Nglycosylation pathways are relatively well defined, little is known of the parallel process in Archaea. Of late, however, major advances have been made in describing the process of archaeal N-glycosylation. Such efforts have shown, as is often the case in archaeal biology, that protein N-glycosylation in Archaea combines particular aspects of the eukaryal and bacterial pathways along with traits unique to this life form. For instance, while the oligosaccharides of archaeal glycoproteins include nucleotideactivated sugars formed by bacterial pathways, the lipid carrier on which such oligosaccharides are assembled is the same as used in eukaryal Nglycosylation. By contrast, transfer of assembled oligosaccharides to their protein targets shows Archaea-specific properties. Finally, addressing N-glycosylation from an archaeal perspective is providing new general insight into this event, as exemplified by the solution of the first crystal structure of an oligosaccharide transferase from an archaeal source.

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Identification of a Putative Acetyltransferase Gene, MMP0350, Which Affects Proper Assembly of both Flagella and Pili in the ArchaeonMethanococcus maripaludis

VanDyke

et al. 2008

J Bacteriol

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Glycosylation is a posttranslational modification utilized in all three domains of life. Compared to eukaryotic and bacterial systems, knowledge of the archaeal processes involved in glycosylation is limited. Recently, Methanococcus voltae flagellin proteins were found to have an N-linked trisaccharide necessary for proper flagellum assembly. Current analysis by mass spectrometry of Methanococcus maripaludis flagellin proteins also indicated the attachment of an N-glycan containing acetylated sugars. To identify genes involved in sugar biosynthesis in M. maripaludis, a putative acetyltransferase was targeted for in-frame deletion. Deletion of this gene (MMP0350) resulted in a flagellin molecular mass shift to a size comparable to that expected for underglycosylated or completely nonglycoslyated flagellins, as determined by immunoblotting. Assembled flagellar filaments were not observed by electron microscopy. Interestingly, the deletion also resulted in defective pilus anchoring. Mutant cells with a deletion of MMP0350 had very few, if any, pili attached to the cell surface compared to a nonflagellated but piliated strain. However, pili were obtained from culture supernatants of this strain, indicating that the defect was not in pilus assembly but in stable attachment to the cell surface. Complementation of MMP0350 on a plasmid restored pilus attachment, but it was unable to restore flagellation, likely because the mutant ceased to make detectable flagellin. These findings represent the first report of a biosynthetic gene involved in flagellin glycosylation in archaea. Also, it is the first gene to be associated with pili, linking flagellum and pilus structure and assembly through posttranslational modifications.

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Archaeal signal peptidases

Chaban

VanDyke

et al. 2007

Microbiology

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Signal peptidases are vital enzymes in the protein secretion pathway. In Archaea, type I signal peptidase, responsible for the cleavage of secretory signal peptides from the majority of secreted proteins, and prepilin peptidase-like signal peptidase, responsible for processing signal peptides from prepilin-like proteins like the preflagellins and various sugar-binding proteins, have been identified. In addition, the archaeal signal peptide peptidase, responsible for degradation of signal peptides after their removal from precursor proteins, has been characterized. These enzymes seem to have a mosaic of eukaryal and bacterial characteristics, and also possess unique archaeal traits. In this review, the most current knowledge with regard to these enzymes is summarized, including their cellular function, catalytic mechanism and distribution and conservation among archaeal species. Comparisons are drawn of these enzymes to their bacterial and eukaryal counterparts, and unique archaeal features highlighted.

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David J. VanDyke

Identification of genes involved in the assembly and attachment of a novel flagellin N‐linked tetrasaccharide important for motility in the archaeon Methanococcus maripaludis

A novel N-linked flagellar glycan from Methanococcus maripaludis

Sweet to the extreme: protein glycosylation in Archaea

Identification of a Putative Acetyltransferase Gene, MMP0350, Which Affects Proper Assembly of both Flagella and Pili in the ArchaeonMethanococcus maripaludis

Archaeal signal peptidases

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