Insight into the primordial MHC from studies in ectothermic vertebrates.

MHC classical class I and class II genes have been identified in representative species from all major jawed vertebrate taxa, the oldest group being the cartilaginous fish, whereas no class I/II genes of any type have been detected in animals from older taxa. Among ectothermic vertebrate classes, studies of MHC architecture have been done in cartilaginous fish (sharks), bony fish (several teleost species), and amphibians (the frog Xenopus). The Xenopus MHC contains class I, class II, and class III genes, demonstrating that all of these genes were linked in the ancestor of the tetrapods, but the gene order is not the same as that in mouse/man. Studies of polyploid Xenopus suggest that MHC genes can be differentially silenced when multiple copies are present; i.e. MHC 'subregions' can be silenced. Surprisingly, in all teleosts examined to date class I and class II genes are not linked. Likewise, class III genes like the complement genes factor B (Bf) and C4 are scattered throughout the genome of teleosts. However, the presumed classical class I genes are closely linked to the 'immune' proteasome genes, LMP2 and LMP7, and to the peptide-transporter genes (TAP), implying that a true 'class I region' exists in this group. A similar type of linkage group is found in chickens and perhaps Xenopus, and thus it may reveal the ancestral organization of class I-associated genes. In cartilaginous fish, classical and non-classical class I genes have been isolated from three shark species, and class II A and B chain genes from nurse sharks. Studies of MHC linkage in sharks are being carried out to provide further understanding of the putative primordial organization of MHC Segregation studies in one shark family point to linkage of classical class I and class II genes, suggesting that the non-linkage of these genes in teleosts is a derived characteristic.

Opsonic complement component C3 in the solitary ascidian, Halocynthia roretzi.

The recent identification of two mannose-binding lectin-associated serine protease clones from Halocynthia roretzi, an ascidian, suggested the presence of a complement system in urochordates. To elucidate the structure and function of this possibly primitive complement system, we have isolated cDNA clones for ascidian C3 (AsC3) and purified AsC3 protein from body fluid. The deduced primary structure of AsC3 shows overall similarity to mammalian C3, including a typical thioester site with the His residue required for nucleophilic activation of the thioester. AsC3 has a two-subunit chain structure, and the alpha-chain is cleaved at a specific site near to the N terminus upon activation. Ascidian body fluid contains an opsonic activity which enhances phagocytosis of yeast by ascidian blood cells, and Ab against AsC3 inhibits this opsonic activity. These results indicate that the complement system played a pivotal role in innate immunity by enhancing phagocytosis before the emergence of the vertebrates and well ahead of the establishment of adaptive immunity, which is believed to have occurred at about the time of the appearance of cartilaginous fish.

Evolution of proteasome subunits delta and LMP2: complementary DNA cloning and linkage analysis with MHC in lower vertebrates.

The class II region of the mammalian MHC harbors two proteasome subunit genes, LMP2 and LMP7. These genes are induced by IFN-gamma, and their products are incorporated into proteasomes substituting for their closest relatives, the delta and X subunits, respectively. This substitution is believed to change the proteolytic specificity of proteasomes, making it more suitable for generation of peptides to be presented by class I molecules. To elucidate the phylogenetic origin of LMP2 and the linkage of its gene with the MHC, reverse transcriptase-PCR amplification of Xenopus laevis and lamprey liver mRNA was performed with primers designed to amplify both the mammalian LMP2 and delta sequences. Both LMP2 and delta were amplified from X. laevis, whereas only delta was amplified from lamprey, suggesting that delta/LMP2 gene duplication occurred after divergence of cyclostomes but before divergence of amphibians. The linkage between the LMP2 gene and the MHC was observed in a diploid Xenopus species, Xenopus tropicalis, but not in a tetraploid species, X. laevis, indicating that this linkage was established before the divergence of amphibian from higher vertebrates, but that this linkage was lost in X. laevis, probably by a gene reorganization accompanying the tetraploidization. The X. laevis LMP2 and LMP7 mRNA showed a similar tissue distribution, indicating that the genetic linkage is not required for apparently coordinated tissue-specific expression of these genes. Sequence and linkage analyses suggest that LMP2 may not play as vital a role as LMP7 in Ag presentation.