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The first question to be asked about a purified protein is ‘Is it a glycoprotein?’

Glycoprotein bands in gels (e.g. on SDS-polyacrylamide gels) can be stained with

cationic dyes such as Alcian Blue, which bind to negatively charged glycosaminogly-

can side-chains, or by the periodic acid-Schiff reagent (PAS), where carbohydrate is

initially oxidised by periodic acid then subsequently stained with Schiff’s reagent.

However, although they are both carbohydrate specific (i.e. non-glycosylated proteins

are not stained) both methods suffer from low sensitivity. A more sensitive, and

informative, approach is to use the specific carbohydrate-binding proteins known

as lectins. Blots from SDS-PAGE, dot blots of the glycoprotein sample, or the glyco-

protein sample adsorbed onto the walls of a microtitre plate can be challenged with

enzyme-linked lectins. Lectins that bind to the glycoprotein can be identified by the

associated enzymic activity. By repeating the experiment with a range of different

lectins, one can not only confirm the presence of a glycoprotein but also identify

which sugar residues are, or are not, present. Having confirmed the presence of

glycoprotein the following procedures would normally be carried out.

• Identification of the type and amount of each monosaccharide: Release of
  monosaccharides is achieved by hydrolysis in methanolic HCl at 80C for 18 h. The
  released monosaccharide can be separated and quantified by gas chromatography.


• Protease digestion to release glycopeptide: A protease is chosen that cleaves the
  glycoprotein into peptides and glycopeptides of ideally 5–15 amino acid residues.
  Glycopeptides are then fractionated by HPLC and purified glycopeptides subjected
  to N-terminal sequence analysis to allow identification of the site of glycosylation.


• Oligosaccharide profiling: Oligosaccharide chains are released from the polypeptide
  backbone either chemically, for example by hydrazinolysis to release N-linked
  oligosaccharide, or enzymatically using peptide-N-glucosidase F (PNGase F), which cleaves
  sugars at the asparagine link, or using endo-a-N-acetylgalactosaminidase (O-glycanase),
  which cleaves O-linked glycans. These released oligosaccharides can then be separated
  either by HPLC or by high performance anion exchange chromatography (HPAEC).


• Structure analysis of each purified oligosaccharide: This requires the determination
  of the composition, sequence and nature of the linkages in each purified
  oligosaccharide. A detailed description is beyond the scope of this book, but would
  involve a mixture of complementary approaches including analysis by FAB-MS, gas
  chromatography-MS, lectin analysis following partial release of sugars and nuclear
  magnetic resonance (NMR) analysis.

8.4.5 Tertiary structure

The most commonly used method for determining protein three-dimensional structure

is X-ray crystallography. A detailed description of the theory and methodology is

beyond the scope of this book, requiring a detailed mathematical understanding of the

process and computer analysis of the extensive data that are generated. The following is

therefore a brief and idealised description of the overall process, and ignores the multitude

of pitfalls and problems inherent in determining three-dimensional structures.

• Clearly the first step must be to produce a crystal of the protein (a crystal should
  be thought of as a three-dimensional lattice of molecules). Protein crystallisation is

336 Protein structure, purification, characterisation and function analysis