Abstract
Surface (S)-layer proteins are model systems for studying protein glycosylation in bacteria and simultaneously hold promises for the design of novel, glyco-functionalized modules for nanobiotechnology due to their 2D self-assembly capability. Understanding the mechanism governing S-layer glycan biosynthesis in the Gram-positive bacterium Paenibacillus alvei CCM 2051T is necessary for the tailored glyco-functionalization of its S-layer. Here, the putative oligosaccharyl:S-layer protein transferase WsfB from the P. alvei S-layer glycosylation gene locus is characterized. The enzyme is proposed to catalyze the final step of the glycosylation pathway, transferring the elongated S-layer glycan onto distinct tyrosine O-glycosylation sites. Genetic knock-out of WsfB is shown to abolish glycosylation of the S-layer protein SpaA but not that of other glycoproteins present in P. alvei CCM 2051T, confining its role to the S-layer glycosylation pathway. A transmembrane topology model of the 781-amino acid WsfB protein is inferred from activity measurements of green fluorescent protein and phosphatase A fused to defined truncations of WsfB. This model shows an overall number of 13 membrane spanning helices with the Wzy_C domain characteristic of O-oligosaccharyl:protein transferases (O-OTases) located in a central extra-cytoplasmic loop, which both compares well to the topology of OTases from Gram-negative bacteria. Mutations in the Wzy_C motif resulted in loss of WsfB function evidenced in reconstitution experiments in P. alvei ΔWsfB cells. Attempts to use WsfB for transferring heterologous oligosaccharides to its native S-layer target protein in Escherichia coli CWG702 and Salmonella enterica SL3749, which should provide lipid-linked oligosaccharide substrates mimicking to some extent those of the natural host, were not successful, possibly due to the stringent function of WsfB. Concluding, WsfB has all features of a bacterial O-OTase, making it the most probable candidate for the oligosaccharyl:S-layer protein transferase of P. alvei, and a promising candidate for the first O-OTase reported in Gram-positives.
Highlights
Bacterial oligosaccharyl:protein transferases (OTases) play a key role in the biosynthesis of glycoproteins, which, in turn, are frequent mediators of interactions between bacterial cells and their environments
Concluding, WsfB has all features of a bacterial O-OTase, making it the most probable candidate for the oligosaccharyl:S-layer protein transferase of P. alvei, and a promising candidate for the first O-OTase reported in Gram-positives
The function of WsfB is confined to the S-layer protein glycosylation pathway, as was expected from its coding sequence being located within the slg gene locus
Summary
Bacterial oligosaccharyl:protein transferases (OTases) play a key role in the biosynthesis of glycoproteins, which, in turn, are frequent mediators of interactions between bacterial cells and their environments. A wellknown example is the highly reduced ability of Campylobacter jejuni to colonize mouse intestines when it is deficient in its general protein N-glycosylation system by mutation of either the N-OTase PglB or the prominent glycosylation target PglE [1]. PglB has been identified as the N-OTase of Campylobacter jejuni, glycosylating more than 50 proteins at the Asp/Glu-X-Asn-X-Ser/Thr consensus site [5]. Homologues of PglL in Vibrio cholerae and Burkholderia thailandensis have been shown to be O-OTases [8]. In all of these cases, glycosylation is a membrane-associated process, with the involvement of a lipid-linked oligosaccharide substrate anchored to the cytoplasmic membrane and an OTase as
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