Search for the Most ‘primitive’ Membranes and Their Reinforcers: A Review of the Polyprenyl Phosphates Theory

ABSTRACT The majority of the 90 capsule types made by the gram-positive pathogen Streptococcus pneumoniae are assembled by a block-type mechanism similar to that utilized by the Wzy-dependent O antigens and capsules of gram-negative bacteria. In this mechanism, initiation of repeat unit formation occurs by the transfer of a sugar to a lipid acceptor. In S. pneumoniae, this step is catalyzed by CpsE, a protein conserved among the majority of capsule types. Membranes from S. pneumoniae type 2 strain D39 and Escherichia coli containing recombinant Cps2E catalyzed incorporation of [14C]Glc from UDP-[14C]Glc into a lipid fraction in a Cps2E-dependent manner. The Cps2E-dependent glycolipid product from both membranes was sensitive to mild acid hydrolysis, suggesting that Cps2E was catalyzing the formation of a polyprenyl pyrophosphate Glc. Addition of exogenous polyprenyl phosphates ranging in size from 35 to 105 carbons to D39 and E. coli membranes stimulated Cps2E activity. The stimulation was due, in part, to utilization of the exogenous polyprenyl phosphates as an acceptor. The glycolipid product synthesized in the absence of exogenous polyprenyl phosphates comigrated with a 60-carbon polyprenyl pyrophosphate Glc. When 10 or 100 μM UMP was added to reaction mixtures containing D39 membranes, Cps2E activity was inhibited 40% and 80%, respectively. UMP, which acted as a competitive inhibitor of UDP-Glc, also stimulated Cps2E to catalyze the reverse reaction, with synthesis of UDP-Glc from the polyprenyl pyrophosphate Glc. These data indicated that Cps2E was catalyzing the addition of Glc-1-P to a polyprenyl phosphate acceptor, likely undecaprenyl phosphate.

Download Full-text

Polyprenyl phosphates as coenzymes in protein and oligosaccharide glycosylation

Philosophical Transactions of the Royal Society of London Series B Biological Sciences ◽

10.1098/rstb.1978.0089 ◽

1978 ◽

Vol 284 (1002) ◽

pp. 559-568 ◽

Cited By ~ 7

Keyword(s):

En Bloc ◽

Plant Kingdom ◽

Green Plants ◽

Dolichyl Phosphate ◽

Membrane Bound ◽

Sugar Derivatives ◽

Polyprenyl Phosphates ◽

Algal Cellulose

Partly saturated polyprenols of the dolichol type occur in all branches of the plant kingdom although in green plants they are quantitatively minor compared with the shorter polyprenols of the ficaprenol and betulaprenol type. Nevertheless, in all members of the plant kingdom so far studied it is the dolichyl phosphates that function in glycosyl transfer. In yeasts, dolichyl phosphate mannose is primarily an intermediate in the O-mannosylation of some membrane-bound proteins. Further mannosylation of the mannoprotein does not involve dolichyl phosphate. Yeast membrane preparations also catalyse the sequential transfer from the appropriate nucleoside diphosphate sugar of N -acetylglucosaminyl phosphate, N -acetylglucosamine, several mannose residues and several glucose residues to dolichyl monophosphate to form a dolichyl diphosphate oligosaccharide. The oligosaccharide is then transferred en bloc to protein to form an N-glycosidically linked glycoprotein. The transfer of mannose and glucose to the dolichyl diphosphate oligosaccharide is probably via dolichyl monophosphate sugar derivatives. Tunicamycin inhibits specifically the transfer of JV-acetylglucosamine phosphate which in turn blocks protein N-glycosylation. Evidence for corresponding processes in O- and N-glycosylation of proteins of hyphal fungi is also available but much less well established. The N-glycosylation of proteins by membrane preparations of green plants appears to occur by a process very similar to that found in yeast. In addition, the biosynthesis of β1-3 and β1-4 linked oligoglucans and also of an algal cellulose primer (a glucoprotein) via dolichyl phosphate glucose has been reported. Possible consequences of these phenomena are discussed.

Download Full-text