Brad G. Magor

Evolution of effectors and receptors of innate immunity.

The bony fishes are derived from one of the earliest divergent vertebrate lineages to have both innate and acquired immune systems. They are considered by some to be an ideal model to study the underpinnings of immune systems precisely because of their phylogenetic position and the fact that their adaptive immune systems have not been elaborated to the extent seen in mammals. By the same token, examination of innate immune systems in invertebrates and early chordates can provide insight into how homologous systems operate in fish and higher vertebrates. Herein, we provide an overview of the molecular evidence that we hope helps clarify the evolutionary relationships of innate immune molecules identified in bony fishes. The innate immune systems being considered include select chemokines (CC and CXC chemokines and their receptors), cytokines (IL-1, IL-8, interferons, TGF-beta, TNF-alpha), acute phase proteins (SAA, SAP, CRP, alpha2M, and the complement components--C3-C9, MASP, MBL, Bf), NK cell receptors, and molecules upstream and downstream of the Toll signaling pathways.

A toll-like receptor (TLR) gene that is up-regulated in activated goldfish macrophages.

An expressed sequence tag screen of a macrophage activation factor and lipopolysaccharide (LPS) stimulated goldfish macrophage subtractive library generated several transcripts of a putative teleost homologue of the toll-like receptor (TLR) family. The full-length TLR cDNA was sequenced and is predicted to encode a type I transmembrane protein with an extracellular domain containing leucine rich repeats and a cytoplasmic tail encoding a toll/interleukin-1 receptor domain. These findings indicate that the gene identified is the first teleost homologue of the TLR family reported. Constitutive expression of TLR was observed in unstimulated macrophages and was also observed in goldfish spleen and kidney but not in heart and liver tissues. A significant up-regulation of the TLR mRNA in cultured macrophages following treatments with each of bacterial LPS, heat-killed Aeromonas salmonicida, and live Mycobacterium chelonei was observed after 3 and 6 h post-stimulation, though with different kinetics from each other. A relative decline in TLR expression was observed after 24 h, but expression levels were still higher than that of unstimulated cells. Thus pathogen-derived factors appear to differentially modulate the expression of TLR in goldfish macrophages, which undoubtedly contributes to the orchestration and/or induction of functional immune responses in fish.

An evolutionarily conserved program of B-cell development and activation in zebrafish

Teleost fish are among the most ancient vertebrates possessing an adaptive immune system with B and T lymphocytes that produce memory responses to pathogens. Most bony fish, however, have only 2 types of B lymphocytes, in contrast to the 4 types available to mammals. To better understand the evolution of adaptive immunity, we generated transgenic zebrafish in which the major immunoglobulin M (IgM(+)) B-cell subset expresses green fluorescence protein (GFP) (IgM1:eGFP). We discovered that the earliest IgM(+) B cells appear between the dorsal aorta and posterior cardinal vein and also in the kidney around 20 days postfertilization. We also examined B-cell ontogeny in adult IgM1:eGFP;rag2:DsRed animals, where we defined pro-B, pre-B, and immature/mature B cells in the adult kidney. Sites of B-cell development that shift between the embryo and adult have previously been described in birds and mammals. Our results suggest that this developmental shift occurs in all jawed vertebrates. Finally, we used IgM1:eGFP and cd45DsRed;blimp1:eGFP zebrafish to characterize plasma B cells and investigate B-cell function. The IgM1:eGFP reporter fish are the first nonmammalian B-cell reporter animals to be described. They will be important for further investigation of immune cell evolution and development and host-pathogen interactions in zebrafish.

The cellular context of AID expressing cells in fish lymphoid tissues.

It has long been held that the cold-blooded vertebrates lack mammalian-like germinal centers, though they do have affinity maturation and the immunoglobulin mutator activation-induced cytidine deaminase or AID. Using AID as a marker of sites of somatic hypermutation, we have identified discrete cell clusters of up to several thousand cells, in the spleen and kidney of channel catfish (Ictalurus punctatus), which may be primordial germinal centers. In situ hybridization revealed that AID expressing cells are interspersed or surrounded by a population of pigmented CSF1-R expressing cells called melano-macrophages. Significantly, melano-macrophages or associated reticular cells have been previously noted for their ability to retain soluble antigen on or near their surface for several weeks following vaccination. Laser capture microdissection and RT-PCR were used to establish that these cell clusters also contained cells expressing Ig heavy chain transcripts as well as transcripts of TcRbeta and the putative CD4 homologue of fish. These observations, coupled with past work showing that mutations develop in B-cell lineages in fishes, allow us to develop a model for how affinity maturation may have evolved in early gnathostome vertebrates.

Activation-induced cytidine deaminase structure and functions: A species comparative view

In the ten years since the discovery of activation-induced cytidine deaminase (AID) there has been considerable effort to understand the mechanisms behind this enzymes ability to target and modify immunoglobulin genes leading to somatic hypermutation and class switch recombination. While the majority of research has focused on mouse and human models of AID function, work on other species, from lamprey to rabbit and sheep, has taught us much about the scope of functions of the AID mutator. This review takes a species-comparative approach to what has been learned about the AID mutator enzyme and its role in humoral immunity.

Evolution of transcriptional enhancers in the immunoglobulin heavy-chain gene: functional characteristics of the zebrafish Eμ3′ enhancer

Past studies of the channel catfish immunoglobulin heavy-chain (IgH) locus indicates that it lacks an Eμ enhancer in the JH–Cμ1 intron but does have an enhancer, termed Eμ3′, in the μ–δ intergenic region. The positioning of the catfish enhancer downstream of the μ-chain exons is predicted to be unfavorable for antibody-affinity maturation in catfish, and would also have been an impediment to the evolution of class switch recombination, had it existed in early tetrapods. To determine if this downstream enhancer is a general feature of teleost fish, we have identified the location of the transcriptional enhancer in the zebrafish IgH locus. We find that zebrafish, like catfish, only have an Eμ3′-like enhancer that has cross-species activity, but which is B-cell-specific in its activity. A 300-bp region of the zebrafish enhancer shares sequence homology with the core of the catfish Eμ3′, although there has been loss and gain of specific octamer enhancer motifs. Mutagenesis studies demonstrate that the zebrafish IgH enhancer depends on a pair of E-box motifs that are found in the enhancer core. Similarly spaced E-box motifs appear to exist in the Eμ3′ enhancer regions of other teleost fish, suggesting this is a common feature among fish IgH enhancers. We discuss how this distal positioning of the enhancer may influence affinity maturation in extant teleosts as well as the evolution of this process in the early tetrapods.

Consecutive interactions with HSP90 and eEF1A underlie a functional maturation and storage pathway of AID in the cytoplasm.

Methot et al. identify a mechanism for cytoplasmic retention of activation-induced deaminase (AID) in cells. Interactions of AID with Hsp90 and eEF1A proteins, both of which stabilize AID, promote sequential folding and retention of functional AID in the cytoplasm. Inhibition of the translation elongation factor eEF1A blocks its interaction with AID, which then accumulates in the nucleus, increasing class switch recombination and the generation of chromosomal translocation byproducts.

Transcriptional regulation of teleost Aicda genes. Part 1 - suppressors of promiscuous promoters.

In order to better understand antibody affinity maturation in fishes we sought to identify gene regulatory elements that could drive expression of activated B-cell specific fluorescent reporter transgenes in zebrafish. Specifically the promoter and several non-coding regions of the channel catfish (Ictalurus punctatus) and zebrafish (Danio rerio) were tested for transcriptional activity using a dual luciferase reporter system in transfected fish leukocytes and two mammalian cell lines that constitutively express Aicda (activation-induced cytidine deaminase). The promoters of both fish Aicda genes were as transcriptionally active as an SV40 promoter control in all cell lines tested, regardless of the cells ability to express Aicda. Coupling of a putative intron 1 enhancer or a region 10 kb upstream of the zebrafish promoter effectively silenced transcription from the fish Aicda promoter. Paradoxically these suppressor elements enhanced transcription when they were coupled to the mouse Aicda intron 1 enhancer. The results are considered in context of similar observations for Aicda transcriptional regulation in mice and in light of recent evidence that Aicda is utilized for epigenetic reprogramming of several non-lymphoid cell types.

The Minor MHC Class I Gene UDA of Ducks Is Regulated by Let-7 MicroRNA

In many nonmammalian vertebrates, the genomic organization of the MHC class I region leads to biased expression of a single classical MHC class I gene coevolving with TAP transporters, whereas class I genes are poorly expressed. This contrasts to the three codominantly expressed classical MHC class I genes in humans and mice. In a sequenced haplotype from White Pekin duck, Anas platyrhynchos, there is one predominantly expressed MHC class I, UAA, although they have five MHC class I genes in the complex, arranged TAP1-TAP2-UAA-UBA-UCA-UDA-UEA. The UAA gene, situated proximal to the TAP2 gene, is expressed at levels 10-fold greater than that of another expressed gene, UDA. Three duck MHC class I genes (UBA, UCA, and UEA) are predicted to be partially or completely inactivated by promoter defects, introduction of in-frame stop codon, or the lack of a polyadenylation signal. In this study, we confirm that UBA, UCA, and UEA are indeed inactivated through genetic defects at the promoter, whereas UAA and UDA have functionally equivalent promoters. To examine promoter accessibility, we performed bisulfite sequencing and show that none of the MHC class I promoters are inactivated by methylation. We determine that UDA is differentially regulated through its 3′ untranslated region. Namely, expression of UDA is downregulated by let-7 microRNA, whereas the predominantly expressed MHC class I UAA is not. Regulation of UDA by let-7 microRNA suggests that the lower expression level is maintained for its function in immunity.