RG-II purification and analyses: RG-II was purified from wine (w1RGII) and analysed alongside a previously purified wine RGII sample (w2RGII) and apple juice RG-II (aRGII) by agarose gel electrophoresis (ref), thin layer chromatography (TLC) of RG-II degradation products after growth with the RG-II utilising bacterium B. thetaiotaomicron and mass spectrometry (MS) using FITDOG-MS approach (for w1RGII and w2RGII) (ref). RG-II from all sources shared many features based on staining, migration properties and degradation products. FITDOG-MS analyses however revealed a small amount of mass peaks likely representing unique modifications in w1RGII and w2RGII. w2RGII degradation products including meXyl-Fuc and meFuc also showed slightly weaker staining compared to w1RGII and aRGII. aRGII was used for subsequent experiments based on availability and more clarity around its composition from the current and previous studies.
Expanding the RG-II oligosaccharide (RGDO) producing library: Several genetically modified B. thetaiotaomicron mutants capable of generating and secreting RGDOs had been produced from previous studies through the deletion of specific RG-II degrading enzymes (by allelic exchange (Ndeh et al., 2017)) especially those targeting side chain A. To expand the RGDO library, mostly side-chain B enzymes were targeted including the L-arabinofuranosidase/glucuronidase enzyme BT0996, methylfocusidase BT0984, rhamnosidase BT1019 and L-arabinopyranosidase BT0983. An apiosidase mutant ΔBT1012 had been generated earlier but its RGDO products had not been characterised. Cloning experiments to generate recombinant knockout plasmid constructs for allelic exchange experiments were successful for all genes except BT0983 which failed. Conjugation experiments were only successful for BT0984 after several attempts and trialling different stocks of the conjugating strain E. coli s17 lambda phage. The BT0984 knockout construct was finally conjugated into B. thetaiotaomicron wild type and ΔBT01012 strains yielding two new B. thetaiotaomicron deletion mutant strains namely ΔBT0984 and ΔBT0984/BT1012.
Generating and characterising RGDOs: To generate RGDOs, several RDGO generating B. thetaiotaomicron mutant strains including ΔBT0984, ΔBT0984/BT1012, ΔBT1012, ΔBT0986, ΔBT0997, ΔBT1003, ΔBT1010, were independently cultured with aRGII and product profiles analysed by TLC to identify new RDGOs. RDGOs were successfully detected for all strains compared to wild type B. thetaiotaomicron. ΔBT0984, ΔBT0984/BT1012 and ΔBT1012 strains also produced more than one unique RDGO each. At least one from each of the latter mutants was successfully purified by size exclusion chromatography on a Biogel P2 resin. Atleast seven sugars were purified including ΔBT0984oligoI, ΔBT0984oligoII, ΔBT0984/BT1012oligoI, ΔBT0984/BT1012oligoII, ΔBT1012, ΔBT0997 and ΔBT0986, and subjected to mass spectrometry (MALDI TOF). Analyses of the MS data has so far detected mass peaks for the new sugar ΔBT0984oligoI and the previously characterised sugar ΔBT0997oligo. NMR studies on BT0984oligo has successfully confirmed anomeric H1 signals for various monosaccharide components and the structure of the sugar.