Negligible elongation of mucin glycans with Gal ß1-3 units distinguishes the laminated layer of Echinococcus multilocularis from that of Echinococcus granulosus.

The larval stages of the cestodes Echinococcus multilocularis and Echinococcus granulosus cause the important zoonoses known as larval echinococcoses. These larvae are protected by a unique, massive, mucin-based structure known as the laminated layer. The mucin glycans of the E. granulosus laminated layer are core 1- or core 2-based O-glycans in which the core Galpß1-3 residue can initiate a chain comprising one to three additional Galpß1-3 residues, a motif not known in mammalian carbohydrates. This chain can be capped with a Galpα1-4 residue, and can be ramified with GlcNAcpß1-6 residues. These, as well as the GlcNAcpß1-6 residue in core 2, can be decorated with the Galpα1-4Galpß1-4 disaccharide. Here we extend our analysis to the laminated layer of E. multilocularis, showing that the non-decorated cores, together with Galpß1-3(Galpα1-4Galpß1-4GlcNAcpß1-6)GalNAc, comprise over 96% of the glycans in molar terms. This simple laminated layer glycome is exhibited by E. multilocularis grown either in vitro or in vivo. Interestingly, all the differences with the complex laminated layer glycome found in E. granulosus may be explained in terms of strongly reduced activity in E. multilocularis of a putative glycosyltransferase catalysing the elongation with Galpß1-3. Comparative inter-species analysis of available genomic and transcriptomic data suggested a candidate for this enzyme, amongst more than 20 putative (non-core 1) Gal/GlcNAc ß1-3 transferases present in each species as a result of a taeniid-specific gene expansion. The candidate gene was experimentally verified to be transcribed at much higher levels in the larva of E. granulosus than that of E. multilocularis.

The surface carbohydrates of the Echinococcus granulosus larva interact selectively with the rodent Kupffer cell receptor.

The larvae of the cestodes belonging to the genus Echinococcus dwell primarily in mammalian liver. They are protected by the laminated layer (LL), an acellular mucin-based structure. The glycans decorating these mucins constitute the overwhelming majority of molecules exposed by these larvae to their hosts. However, their decoding by host innate immunity has not been studied. Out of 36 mammalian innate receptors with carbohydrate-binding domains, expressed as Fc fusions, only the mouse Kupffer cell receptor (KCR; CLEC4F) bound significantly to the Echinococcus granulosus LL mucins. The receptor also bound the Echinococcus multilocularis LL. Out of several synthetic glycans representing Echinococcus LL structures, the KCR bound strongly in particular to those ending in Galα1-4Galß1-3 or Galα1-4Galß1-4GlcNAc, both characteristic LL carbohydrate motifs. LL carbohydrates may be optimized to interact with the KCR, expressed only in liver macrophages, cells known to contribute to the tolerogenic antigen presentation that is characteristic of this organ.

Further structural characterization of the Echinococcus granulosus laminated layer carbohydrates: the blood-antigen P1-motif gives rise to branches at different points of the O-glycan chains.

The glycobiology of the cestodes, a class of parasitic flatworms, is still largely unexplored. An important cestode species is Echinococcus granulosus, the tissue-dwelling larval stage of which causes hydatid disease. The E. granulosus larva is protected from the host by a massive mucin-based extracellular matrix termed laminated layer (LL). We previously reported ( Díaz et al. 2009. Biochemistry 48:11678-11691) the molecular structure of the most abundant LL O-glycans, comprising up to six monosaccharide residues. These are based on Cores 1 and 2, in cases elongated by a chain of Galpß1-3 residues, which can be capped by Galpα1-4. In addition, the Core 2 GlcNAcp residue can be decorated with the Galpα1-4Galpß1-4 disaccharide. Larger glycans also detected contained additional HexNAc residues that could not be explained by the structural repertoire described above. In this work, we elucidate, by mass spectrometry (MS) and nuclear magnetic resonance (NMR), six additional glycans from the E. granulosus LL between six and eight residues in size. Their structures are related to those already described but in cases bear GlcNAcpß1-6 or Galpα1-4Galpß1-4GlcNAcpß1-6 as ramifications on the core Galpß1-3 residue. We also obtained evidence that noncore Galpß1-3 residues can be similarly ramified. Thus, the new motif together with the previous information may explain all the glycan compositions detected in the LL by MS. In addition, we show that the anti-Echinococcus monoclonal antibody E492 (Parasite Immunol 21:141, 1999) recognizes Galpα1-4Galpß1-4GlcNAcp (the blood P(1)-antigen motif). This explains the antibody's reactivity with a range of Echinococcus tissues, as the P(1)-motif is also carried on non-LL N-glycans and glycolipids from this genus.

Understanding the laminated layer of larval Echinococcus I: structure.

Echinococcus larvae are protected by a massive carbohydrate-rich acellular structure, called the laminated layer. In spite of being widely considered the crucial element of these host-parasite interfaces, the laminated layer has been historically poorly understood. In fact, it is still often called 'chitinous', 'hyaline' or 'cuticular' layer, or said to be composed of polysaccharides. However, over the past few years the laminated layer was found to be comprised of mucins bearing defined galactose-rich carbohydrates, and accompanied, in the case of Echinococcus granulosus, by calcium inositol hexakisphosphate deposits. In this review, the architecture and biosynthesis of this unusual structure is discussed at depth in terms of what is known and what needs to be discovered.