Polysialic acid
Polysialic acid is an unusual posttranslational modification that occurs on neural cell adhesion molecules. Polysialic acid is considerably anionic. This strong negative charge gives this modification the ability to change the protein's surface charge and binding ability. In the synapse, polysialation of NCAM prevents its ability to bind to NCAMs on the adjacent membrane.
Structure
Polysialic acid is polymer of linearly repeating monomer units of α2,8- and α2,9-glycosidic linked sialic acid residues. Sialic acid refers to carboxylated 9-carbon sugars, 2-keto-3-dexoxy-D-glycero-nononic acids. An unusual property of this sugar is that it often polymerizes into polySia. This is accomplished by attaching the monomers to the nonreducing end of the glycan. This mostly consists of Neu5Ac subunits. It is polyanionic and bulky, meaning there is little ability to reach its central molecules. polySia is useful in signaling in vertebrates and on the cell surface of few glycoproteins and glycolipids causing modifications, and it has been recently found that the function of polySia relates almost directly to its degree of polymerization. The number of units can range from 8 to greater than 400. This vast range causes differences in the polySia's ability to adhere different cells, assist in cellular migration, synapse formation, and regulate adhesion in nerve cells by modeling and formating them. polySia's most prominent role is in post-translational modifications in a few proteins, with the main one being NCAM. polySia links to adhesion molecules causing their adhesive properties to be subdued allowing for the detailed control of cell migration and cell to cell relations. This is caused by polySia's bulky and polyanionic properties.The human body produces polySia naturally and attaches it to a various number of proteins. This is done by linking polySia on the α2,3- or α2,6- terminal of the glycoprotein. O-linked glycosylation through threonine or N-linked glycosylation through asparagine is employed. This polySia linkage is found in proteins such as NCAM, E-selectin ligand 1, C–C chemokine receptor type 7, synaptic cell adhesion molecule-1, neuropilin-2, the CD36 scavenger receptor found in the milk of humans, and the α-subunit of the voltage-sensitive sodium channel. The synthesis of polySia is enzymatically formed by α2,8-sialyltransferase in a Type II transmembrane protein located on the Golgi Apparatus membrane. ST8Sia does this by adding sialic acids to the terminal end of the glycan through the CMP-sialic acid donor at various lengths depending on necessity. The length is controlled extensively by the expression of polysialyltransferase enzymes, once again controlling the function of polySia.
Discovery and methods of detection
polySia was discovered in E. coli K-235 by Barry and Goebel in 1957. E. coli is an encapsulated, gram-negative bacteria in which Barry and Goebel studied, pinpointing polySia, which they called colominic acid. Following this discovery, multiple other bacterial capsules abundant in glycans were found to contain polySia. This included Neisseia meningitidis serogroups B and C in 1975. This was done by the use of a horse anti-polySia polyclonal antibody, being one of the first effective immunochemical probes. This was revolutionary as the anti-polySia antibodies were used to find polySia on proteins and cells. Mannheimia haemolytica A2, Moraxella nonliquifaciens, and E. coli K92 were found in 2013. Due to the capsule containing polySia, many scientists have tried to generate vaccines for these specific bacteria, notoriously difficult to target. However, their successes have been numbered as α2,8-polySia is naturally produced by humans. Another issue is that polySia found in bacteria does not produce a solid or consistent immune response.Another method of polySia detection relies on molecular labeling with fluorescence. This process, started in 1998, involves exposing α2→8-linked N-acylneuraminic acid to periodate oxidation causing the terminals to be oxidized and in between untouched. If C9 compounds are observed after this exposure it indicates the presence of polySia. The way these can be numbered is by anion exchange chromatography after periodate oxidation with the label 1,2-diamino-4,5-methylenedioxybenzene on C7 and C9. It is known that there are many different structures of polySia and these were difficult to recognize and detect until this fluorescent labeling, making it very advantageous.