Return to search

DEVELOPING A SENSE OF SELF: EXPLORING THE EVOLUTION OF IMMUNE AND ALLORECOGNITION MECHANISMS IN METAZOANS USING THE DEMOSPONGE AMPHIMEDON QUEENSLANDICA

All animals have evolved mechanisms to recognise and eliminate nonself in order to defend against invading pathogens and to prevent chimerism, the fusion between genetically distinct conspecifics. Like other metazoans, sponges are known to rely on sophisticated systems to maintain their self-integrity. As poriferans are also considered one of the most ancient extant metazoan phyla, they represent a critical comparative model for understanding the early evolution of immunity and self/nonself recognition in animals. The Toll-like receptor (TLR) signalling cascade plays a crucial role in immunity, and recent findings in the sponge Suberites domuncula suggest that its origin could predate eumetazoan cladogenesis. My genome and expressed sequence tag (EST) screens of the demosponge Amphimedon queenslandica detected homologues to most components of this pathway, supporting the notion that a primordial TLR signalling cascade emerged at the dawn of the Metazoa. The sponge also encodes a couple of putative TLR-related proteins (AmqIgTIRs) that consist of at least one extracellular immunoglobulin (Ig) and an intracellular Toll/Interleukin-1 receptor/resistance (TIR) domain. The presence of other unconventional TLRs in S. domuncula and in cnidarian representatives, implies that an ancestral TLR probably existed in the last common ancestor of all living metazoans, and independent duplication and divergence events led to the variety of forms observed in animals. Among the putative transcription factors present in Amphimedon, which are known to be activated by the TLR signalling cascade in other eumetazoans, I detected a single member of the Rel/nuclear factor-kappaB (NF-κB) family, AmqNF-κB, which is also the only Rel homology domain (RHD)-containing gene present in the sponge. This gene encodes a protein that is equipped with both a RHD and ankyrin (ANK) repeats, suggesting that the ancestral metazoan NF-κB was configured identically to contemporary vertebrate and sponge forms, and that the truncated NF-κB found in Nematostella vectensis resulted from the secondary loss of ANK. Aside from immunity, the Toll and TLR pathways contribute to a variety of biological processes in bilaterians, however their functions have only been investigated in detail in a limited number of metazoan model organisms. While studies have tested the immune role of various sponge genes, including components of the TLR cascade, no research has yet established whether they are also involved in development. Therefore, I investigated the expression of some of the immunity-related genes I isolated in Amphimedon in a developmental and immune context to shed light on the potential ancestral function(s) of the proteins they encode. Using in situ hybridisation, I demonstrate that AmqIgTIR2, AmqMyD88, AmqTollip, AmqPellino and AmqNF-ĸB are expressed during A. queenslandica early development. In contrast, the spatial and temporal expression of AmqIgTIR1 suggests it might encode a receptor that is specifically involved in the detection of metamorphic cues in larvae. A real-time quantitative PCR (qPCR) study performed on a pool of adult sponge cDNAs indicates that the expression levels of AmqIgTIR1, AmqIgTIR2, AmqMyD88 and AmqTollip are significantly affected by a nine-hour incubation in 50 µg/ml of lipopolysaccharide (LPS), and to a lesser extent by 105 colony forming units (cfu)/ml of live Vibrio harveyi. The gene expression of AmqIgTIR1 and AmqIgTIR2 suggests that they may encode proteins with antagonistic immunological functions. While AmqPellino and AmqNF-ĸB do not appear to be affected by LPS and Vibrio exposure, it is possible that these genes do not participate in the early immune response of poriferans. Together, my data indicate that the sponge genes surveyed might encode proteins that perform developmental, sensory and immunological functions, suggesting their roles could have also been multifaceted in the last common ancestor to all living metazoans. As is observed in other invertebrates, poriferans display an ontogenic shift in allorecognition; genetically different individuals can fuse during early development but, in most instances, not as adults. However, there is a limited understanding of the cellular organisation of sponge chimeras and the onset of poriferan allorecognition response. By following the fates of fluorescently tagged cells derived from genetically distinct Amphimedon larvae that are fused together at metamorphosis, I establish that there is a rapid ontogenic shift in the sponge allogeneic response about two weeks after the initiation of metamorphosis. Moreover, the molecular basis of the poriferan allorecognition system is possibly involved in creating differential cell affinities, which underlie the construction of the sponge body plan. Compatible with this scenario is the observation that cells from postlarvae that are allowed to develop for two weeks before contact do not fuse, and form a distinct boundary between genotypes. The molecules responsible for sponge cell reaggregation, the aggregation factors (AFs), have been proposed to drive the allorecognition response in poriferans. Notably, the Amphimedon genome encodes six putative AFs, of which five occur in a cluster. These findings indicate that the polymorphic variation observed in other poriferan AFs is probably the result of allelic variations of multiple genes belonging to the same family.

Identiferoai:union.ndltd.org:ADTP/279315
CreatorsMarie Gauthier
Source SetsAustraliasian Digital Theses Program
Detected LanguageEnglish

Page generated in 0.0023 seconds