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Oligosaccharide Assembly01:24

Oligosaccharide Assembly

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Protein glycosylation starts in the ER lumen and continues in the Golgi apparatus. Glycosyltransferases catalyze the addition of sugar molecules or glycosylation of proteins. Usually, these enzymes add sugars to the hydroxyl groups of selected serine or threonine residues to form O-linked glycans or the amino groups of asparagine residues to form N-linked glycans. Different positions on the same polypeptide chain can contain differently linked glycans.
Multiple sugar molecules that may or may...
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Protein Glycosylation01:25

Protein Glycosylation

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Glycosylation, the most common post-translational modification for proteins, serves diverse functions. Adding sugars to proteins makes the proteins more resistant to proteolytic digestion. Glycosylated proteins can act as markers and receptors to promote cell-cell adhesion. Additionally, they have many essential quality control functions in the cell, such as correct protein folding and facilitating transport of misfolded proteins to the cytosol, which can be degraded.
Glycosylation occurs in...
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Protein Complexes with Interchangeable Parts01:57

Protein Complexes with Interchangeable Parts

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Groups of proteins may form a complex where each protein in this complex has a different role in the overall execution of the complex’s function. Often some of the proteins in the complex can be replaced by a closely related variant to give a complex that contains many of the same components yet is functionally distinct.
The SCF ubiquitin ligase is a protein complex of five individual proteins. This complex attaches ubiquitin to other target proteins to mark them for degradation. In order...
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Evolution of Microbial Genome01:08

Evolution of Microbial Genome

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Microbial genome evolution is a highly dynamic process shaped by continual gene gain and loss across species and strains. This genomic flexibility allows microorganisms to adapt rapidly to environmental pressures and interactions with other organisms. Central to understanding this diversity is the distinction between the core and pan genomes.The core genome comprises the genes shared by all sampled strains of a species, representing essential functions needed for fundamental cellular processes.
56
Gene Evolution - Fast or Slow?02:05

Gene Evolution - Fast or Slow?

8.4K
The genomes of eukaryotes are punctuated by long stretches of sequence which do not code for proteins or RNAs. Although some of these regions do contain crucial regulatory sequences, the vast majority of this DNA serves no known function. Typically, these regions of the genome are the ones in which the fastest change, in evolutionary terms, is observed, because there is typically little to no selection pressure acting on these regions to preserve their sequences.
In contrast, regions which code...
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Proteoglycans01:05

Proteoglycans

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Glycans, a class of complex heterogeneous molecules, can be covalently attached to proteins to form glycosylated proteins that regulate various physiological and pathological processes. Glycosylated proteins or glycoproteins comprise N-linked and O-linked oligosaccharides. O-glycosylation is the most common type of protein glycosylation. Here, glycans attach to the oxygen atom of the hydroxyl groups of Serine or Threonine residues. O-linked glycosylation occurs later in protein processing,...
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Related Experiment Video

Updated: Apr 12, 2026

Generation of Null Mutants to Elucidate the Role of Bacterial Glycosyltransferases in Bacterial Motility
12:29

Generation of Null Mutants to Elucidate the Role of Bacterial Glycosyltransferases in Bacterial Motility

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Glycan variation and evolution in the eukaryotes.

Anthony P Corfield1, Monica Berry2

  • 1Mucin Research Group, University of Bristol, School of Clinical Sciences, Bristol Royal Infirmary, Bristol, BS2 8HW, UK.

Trends in Biochemical Sciences
|May 25, 2015
PubMed
Summary
This summary is machine-generated.

This review explores the diverse evolution of eukaryotic glycans, including N- and O-glycans, and their variations across species. It highlights similarities and differences in glycosylation patterns within major eukaryotic groups.

Keywords:
eukaryotesevolutionglycanglycosylationglycosyltransferasemolecular mimicry

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Glycan Node Analysis: A Bottom-up Approach to Glycomics
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Glycan Node Analysis: A Bottom-up Approach to Glycomics
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Area of Science:

  • Glycoscience and Evolutionary Biology
  • Comparative analysis of eukaryotic molecular structures

Background:

  • Glycans, or oligosaccharides, are crucial molecules with diverse biological roles.
  • Understanding glycan evolution provides insights into eukaryotic diversification and function.

Purpose of the Study:

  • To document the evolutionary trajectory of common glycan structures in eukaryotes.
  • To illustrate the extensive diversity of oligosaccharides across eukaryotic organisms.
  • To compare and contrast glycosylation patterns within major eukaryotic clades.

Main Methods:

  • Comprehensive literature review focusing on glycan structures and their evolution.
  • Comparative analysis of N- and O-glycans, glycosphingolipids, glycosaminoglycans, GPI anchors, sialic acids, and cytoplasmic/nuclear glycans.
  • Examination of evolutionary aspects including inter/intraspecies variations, molecular mimicry, and viral adaptations.

Main Results:

  • Detailed documentation of common glycan structures and their evolutionary paths in eukaryotes.
  • Illustration of significant oligosaccharide diversity, including N- and O-glycans, glycosphingolipids, and more.
  • Identification of conserved and divergent glycosylation features across Deuterostomia, Fungi, Viridiplantae, Nematoda, and Arthropoda.

Conclusions:

  • Eukaryotic glycan structures exhibit remarkable evolutionary diversity and complexity.
  • Comparative analysis reveals conserved and divergent glycosylation strategies across major eukaryotic lineages.
  • Glycan evolution is shaped by factors like glycosyltransferase specificity, molecular mimicry, and viral interactions.