Occurrence polysaccharide biosynthesis

The present article focuses on the occurrence and characterization of derivatives of 5,7-diamino-3,5,7,9-tetradeoxynon-2-ulosonic acids and presents experimental approaches used to identify them and to elucidate the structures of the bacterial polysaccharides that contain the nonulosonic acids. Recent data on the biosynthesis of these sugars and their role in immune recognition and epitope specificity of bacterial glycopolymers are discussed. 

A similar position exists with most other polysaccharides. In general, the same chemical structures, produced by prokaryotes and eukaryotes are unlikely to be related in terms of their biosynthesis. Within the eukaryotes, evolutionary relationships may well exist where similar polymers are found in species that are known, from other evidence, to be closely related. Likewise, the present-day pattern of occurrence of a polymer such as chitin may well suggest that a single t3q>e of mechanism exists for its synthesis and that this has persisted in some phyla, but has been lost during the evolution of others. Where a polysaccharide seems to reappear after an evolutionary gap, there is always a question as to whether this is a re-emergence of the old synthetic pathway, or the acquisition of a new one. It should not be forgotten that the relative simplicity of polysaccharide structure does make the latter quite possible, in principle at least. 

Undecaprenol (bactoprenol) from Salmonella contains eleven isoprene units, and two irons and nine cis double bonds In the form of undecaprenyl phosphate, it acts as a carrier of carbohydrate residues in the biosynthesis of bacterial antigenic polysaccharides synthesis of Murein (see) also depends on undecaprenyl phosphate. In eukaryotes the Dolichol phosphates (see) function in the transfer of carbohydrate residues in the synthesis of glycoproteins and glycoli-pids. Probably the long lipid chains of these P serve to anchor them in membranes, while the phosphate group acts as a carrier by protruding into the cytoplasm. It is not known whether all P. function as carbohydrate carriers. The structural relationship between solanesol and plastoquinone-9 and ubiquinone-9, and the joint occurrence of these compounds suggest a precursor role for P. Biosynthesis of P. proceeds from mevalonic acid and the conformation of all double bonds is predetermined in early precursors. 

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