The Late-Stage Steps of Burkholderia cenocepacia Protein O-Linked Glycan Biosynthesis Are Conditionally Essential

Periplasmic O -linked protein glycosylation is a highly conserved process observed across the Burkholderia genus. Within Burkholderia, protein glycosylation requires the five gene cluster known as the O - g lycosylation c luster (OGC, ogcXABEI ) which facilitates the construction of the O -linked trisaccharide attached to periplasmic proteins. Previous studies have reported conflicting results regarding the essentiality of ogcA and ogcX , predicted to be involved in the last steps in O -linked glycan biosynthesis. Within this work, we aimed to dissect the impact of the loss of ogcA and ogcX on Burkholderia cenocepacia viability. We demonstrate that the loss of ogcA or ogcX appears detrimental if glycosylation is initiated leading to marked phenotypic effects. Proteomic analysis supports that the loss of ogcA / ogcX both blocks glycosylation and drives pleotropic effects in the membrane proteome, resulting in the loss of membrane integrity. Consistent with this, strains lacking ogcA and ogcX exhibit increased sensitivity to membrane stressors including antibiotics and demonstrate marked changes in membrane permeability. These effects are consistent with fouling of the undecaprenyl pool due to dead-end O -linked glycan intermediates, and consistent with this, we show that modulation of the undecaprenyl pool through the overexpression of undecaprenyl pyrophosphate synthase (UppS) as well as early-stage OGC biosynthesis genes ( ogcI and ogcB ) impacts B. cenocepacia viability. These findings demonstrate disrupting O -linked glycan biosynthesis or transport appears to dramatically impact B. cenocepacia viability, supporting the assignment of ogcA and ogcX as conditionally essential.