Abstract
Microbacterium nematophilum causes a deleterious infection of the C. elegans hindgut initiated by adhesion to rectal and anal cuticle. C. elegans bus-2 mutants, which are resistant to M. nematophilum and also to the formation of surface biofilms by Yersinia sp., carry genetic lesions in a putative glycosyltransferase containing conserved domains of core-1 beta1,3-galactosyltransferases. bus-2 is predicted to act in the synthesis of core-1 type O-glycans. This observation implies that the infection requires the presence of host core-1 O-glycoconjugates and is therefore carbohydrate-dependent. Chemical analysis reported here reveals that bus-2 is indeed deficient in core-1 O-glycans. These mutants also exhibit a new subclass of O-glycans whose structures were determined by high performance tandem mass spectrometry; these are highly fucosylated and have a novel core that contains internally linked GlcA. Lectin studies showed that core-1 glycans and this novel class of O-glycans are both expressed in the tissue that is infected in the wild type worms. In worms having the bus-2 genetic background, core-1 glycans are decreased, whereas the novel fucosyl O-glycans are increased in abundance in this region. Expression analysis using a red fluorescent protein marker showed that bus-2 is expressed in the posterior gut, cuticle seam cells, and spermatheca, the first two of which are likely to be involved in secreting the carbohydrate-rich surface coat of the cuticle. Therefore, in the bus-2 background of reduced core-1 O-glycans, the novel fucosyl glycans likely replace or mask remaining core-1 ligands, leading to the resistance phenotype. There are more than 35 Microbacterium species, some of which are pathogenic in man. This study is the first to analyze the biochemistry of adhesion to a host tissue by a Microbacterium species.
Highlights
Caenorhabditis elegans is a genetically and developmentally well characterized organism that has been used as a model to study host-pathogen interactions
C. elegans mutants that are resistant to crystal toxin are defective in the bre gene family [5, 6], one of which is a homolog of Drosophila melanogaster egghead and encodes a GDP-Man:Glc-Cer-1,4-mannosyltransferase, another encodes a UDP-GalNAc:1,4N-acetylgalactosaminyltransferase, and a third encodes is a homolog of Drosophila brainiac and encodes a UDP-GlcNAc:Man N-acetylglucosaminyl transferase
To summarize results the nucleic acid stain SYTO Green 13 was used to visually confirm that the bus-2 mutant had no detectable bacterial colonization in the rectal region compared with its parent strain N2 Bristol, as shown previously [11] and in Fig. 1, verifying the bus phenotype
Summary
The initial PCR amplification used a forward primer corresponding to the bus-2 gene and a reverse primer corresponding to the poly(A) tail of bus-2 in addition to the polycistronic region of the pENTRY::mCherry plasmid, creating a 6.7-kb product This was followed by the amplification of the 2.1-Kb mCherry region of the pENTRY plasmid and the amplification of both products to create a fusion PCR product of 8.8 Kb. Plasmids used were as follows: Bus-2 SpeI forward (GGA CTA GTC CCA CTT TGG TAG CTG ATA TCT CAG), Bus-2 pENTRY RFP reverse (GGT GAA AGT AGG ATG AGA CAG CGG CAA AAA AAT CCA TCA AGA TCG CCA CC), polycistRFP forward (CCG CTG TCT CAT CCT ACT TTC ACC; polycistronic construct as Cheung et al [25]), polycistRFP reverse D (TCG ACG TTT CCC GTT GAA TAT G), Bus-2 A* forward (CAT CAA CTG ATA AGT TGT TGA TAT TGT TG), and polycistRFP reverse D* Transgene eEx677 together with unc-119(ϩ) into bus-2 and unc-119 mutants, rescuing both phenotypes
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