J. Oriol Sunyer

IgT, a primitive immunoglobulin class specialized in mucosal immunity

Teleost fish are the most primitive bony vertebrates that contain immunoglobulins. In contrast to mammals and birds, these species are devoid of immunoglobulin A (IgA) or a functional equivalent. This observation suggests that specialization of immunoglobulin isotypes into mucosal and systemic responses took place during tetrapod evolution. Challenging that paradigm, here we show that IgT, an immunoglobulin isotype of unknown function, acts like a mucosal antibody. We detected responses of rainbow trout IgT to an intestinal parasite only in the gut, whereas IgM responses were confined to the serum. IgT coated most intestinal bacteria. As IgT and IgA are phylogenetically distant immunoglobulins, their specialization into mucosal responses probably occurred independently by a process of convergent evolution.

Mucosal immunoglobulins and B cells of teleost fish

As physical barriers that separate teleost fish from the external environment, mucosae are also active immunological sites that protect them against exposure to microbes and stressors. In mammals, the sites where antigens are sampled from mucosal surfaces and where stimulation of naïve T and B lymphocytes occurs are known as inductive sites and are constituted by mucosa-associated lymphoid tissue (MALT). According to anatomical location, the MALT in teleost fish is subdivided into gut-associated lymphoid tissue (GALT), skin-associated lymphoid tissue (SALT), and gill-associated lymphoid tissue (GIALT). All MALT contain a variety of leukocytes, including, but not limited to, T cells, B cells, plasma cells, macrophages and granulocytes. Secretory immunoglobulins are produced mainly by plasmablasts and plasma cells, and play key roles in the maintenance of mucosal homeostasis. Until recently, teleost fish B cells were thought to express only two classes of immunoglobulins, IgM and IgD, in which IgM was thought to be the only one responding to pathogens both in systemic and mucosal compartments. However, a third teleost immunoglobulin class, IgT/IgZ, was discovered in 2005, and it has recently been shown to behave as the prevalent immunoglobulin in gut mucosal immune responses. The purpose of this review is to summarise the current knowledge of mucosal immunoglobulins and B cells of fish MALT. Moreover, we attempt to integrate the existing knowledge on both basic and applied research findings on fish mucosal immune responses, with the goal to provide new directions that may facilitate the development of novel vaccination strategies that stimulate not only systemic, but also mucosal immunity.

Teleost skin, an ancient mucosal surface that elicits gut-like immune responses

Skin homeostasis is critical to preserve animal integrity. Although the skin of most vertebrates is known to contain a skin-associated lymphoid tissue (SALT), very little is known about skin B-cell responses as well as their evolutionary origins. Teleost fish represent the most ancient bony vertebrates containing a SALT. Due to its lack of keratinization, teleost skin possesses living epithelial cells in direct contact with the water medium. Interestingly, teleost SALT structurally resembles that of the gut-associated lymphoid tissue, and it possesses a diverse microbiota. Thus, we hypothesized that, because teleost SALT and gut-associated lymphoid tissue have probably been subjected to similar evolutionary selective forces, their B-cell responses would be analogous. Confirming this hypothesis, we show that IgT, a teleost immunoglobulin specialized in gut immunity, plays the prevailing role in skin mucosal immunity. We found that IgT+ B cells represent the major B-cell subset in the skin epidermis and that IgT is mainly present in polymeric form in the skin mucus. Critically, we found that the majority of the skin microbiota are coated with IgT. Moreover, IgT responses against a skin parasite were mainly limited to the skin whereas IgM responses were almost exclusively detected in the serum. Strikingly, we found that the teleost skin mucosa showed key features of mammalian mucosal surfaces exhibiting a mucosa-associated lymphoid tissue. Thus, from an evolutionary viewpoint, our findings suggest that, regardless of their phylogenetic origin and tissue localization, the chief immunoglobulins of all mucosa-associated lymphoid tissue operate under the guidance of primordially conserved principles.

Complement diversity: a mechanism for generating immune diversity?

Unlike mammalian species, several cold-blooded species have been shown to possess multiple forms of complement components. The multiple forms of C3 characterized in several fish species can bind with different specificities to various complement-activating surfaces. Here, Oriol Sunyer, Ioannis Zarkadis and John Lambris explore the possible advantages conferred by having multiple forms of individual complement proteins in a single organism.

Evolution and diversity of the complement system of poikilothermic vertebrates

Summary: In mammals the complement system plays an important role in innate and acquired host defense mechanisms against infection and in various immunoregulatory processes. The complement system is an ancient defense mechanism that is already present in the invertebrate deuterostomes. In these species as well as in agnathans (the most primitive vertebrate species), both the alternative and lectin pathway of complement activation are already present, and the complement system appears to be involved mainly in opsonization of foreign material. With the emergence of immunoglobulins in cartilaginous fish, the classical and lytic pathways first appear. The rest of the poikilothermic species, from teleosts to reptilians, appear to contain a well‐developed complement system resembling that of homeothermic vertebrates. However, important differences remain. Unlike homeotherms, several species of poikilotherms have recently been shown to possess multiple forms of complement components (C3 and factor B) that are structurally and functionally more diverse than those of higher vertebrates. It is noteworthy that the multiple forms of C3 that have been characterized in several teleost fish are able to hind with varying efficiencies to various complement‐activating surfaces. We hypothesize that this diversity has allowed these animals to expand their innate capacity for immune recognition.

Biochemical and functional characterization of the Ebola virus VP24 protein: implications for a role in virus assembly and budding.

ABSTRACT The VP24 protein of Ebola virus is believed to be a secondary matrix protein and minor component of virions. In contrast, the VP40 protein of Ebola virus is the primary matrix protein and the most abundant virion component. The structure and function of VP40 have been well characterized; however, virtually nothing is known regarding the structure and function of VP24. Wild-type and mutant forms of VP24 were expressed in mammalian cells to gain a better understanding of the biochemical and functional nature of this viral protein. Results from these experiments demonstrated that (i) VP24 localizes to the plasma membrane and perinuclear region in both transfected and Ebola virus-infected cells, (ii) VP24 associates strongly with lipid membranes, (iii) VP24 does not contain N-linked sugars when expressed alone in mammalian cells, (iv) VP24 can oligomerize when expressed alone in mammalian cells, (v) progressive deletions at the N terminus of VP24 resulted in a decrease in oligomer formation and a concomitant increase in the formation of high-molecular-weight aggregates, and (vi) VP24 was present in trypsin-resistant virus like particles released into the media covering VP24-transfected cells. These data indicate that VP24 possesses structural features commonly associated with viral matrix proteins and that VP24 may have a role in virus assembly and budding.

Pivotal Advance: Peritoneal cavity B-1 B cells have phagocytic and microbicidal capacities and present phagocytosed antigen to CD4+ T cells

Breaking the long‐held paradigm that primary B cells are not phagocytic, several studies have demonstrated recently that B cells from fish, amphibians, and reptilians have a significant phagocytic capacity. Whether such capacity has remained conserved in certain mammalian B cell subsets is presently an enigma. Here, we report a previously unrecognized ability of PerC B‐1a and B‐1b lymphocytes to phagocytose latex beads and bacteria. In contrast, B‐2 lymphocytes had an almost negligible ability to internalize these particles. Upon phagocytosis, B‐1a and B‐1b cells were able to mature their phagosomes into phagolysosomes and displayed the ability to kill internalized bacteria. Importantly, B‐1a and B‐1b cells effectively present antigen recovered from phagocytosed particles to CD4+ T cells. However, these cells showed a much lower competence to present soluble antigen or antigen from large, noninternalized particles. B‐1 B cells presented particulate and soluble antigen to CD4+ T cells more efficiently than macrophages, whereas DCs were the most potent APCs. The novel phagocytic and microbicidal abilities identified in B‐1 B lymphocytes strengthen the innate nature that has long been attributed to these cells. In the context of adaptive immunity, we show that these innate immune processes are relevant, as they enable B‐1 B cells to present phagocytosable particulate antigen. These capacities position these cells at the crossroads that link innate with adaptive immune processes. In a broader context, these newly identified capacities of B‐1 B cells further support the previously recognized functional, developmental, and evolutionary relationships between these cells and macrophages.

Fishing for mammalian paradigms in the teleost immune system

Recent years have witnessed a renaissance in the study of fish immune systems. Such studies have greatly expanded the knowledge of the evolution and diversification of vertebrate immune systems. Several findings in those studies have overturned old paradigms about the immune system and led to the discovery of novel aspects of mammalian immunity. Here I focus on how findings pertaining to immunity in teleost (bony) fish have led to major new insights about mammalian B cell function in innate and adaptive immunity. Additionally, I illustrate how the discovery of the most ancient mucosal immunoglobulin described thus far will help resolve unsettled paradigms of mammalian mucosal immunity.

Cloning and structure of three rainbow trout C3 molecules: a plausible explanation for their functional diversity ☆

We have previously identified and characterized three distinct trout C3 proteins (C3-1, C3-3 and C3-4) that differ in their electrophoretic mobility, glycosylation patterns, reactivity with monospecific C3 antibodies, partial amino acid sequence and binding to various complement activators. To study the structural elements that determine the observed functional differences, we have cloned and sequenced the three C3 isoforms. Comparison of the deduced amino acid sequences showed that the sequence identity/similarity of C3-3 to C3-4 is 76/81%, whereas those of C3-3 and C3-4 to C3-1 are 55/67% and 54/67%, respectively. It is interesting that the beta-chain of C3-4 contains two insertions of 65 (residues 504-569) and 23 amino acids (residues 123-146), while the beta-chain of C3-1 contains a 14-amino acid insertion (residues 143-157). The C3 convertase cleavage site (Arg-Ser) is conserved in the three trout isoforms; however, the factor I cleavage sites are Arg-Ala (for C3-1 and C3-4) and Arg-Thr (C3-3) instead of Arg-Ser at position 1281 of human C3, and Arg-Thr (C3-1, C3-3) instead of Arg-Ser for C3-4 at position 1298 of human C3. Of special interest is the absence of the His(1126) and Glu(1128) (human C3 numbering) from C3-4 and of Glu(1128) from C3-3. These residues are thought to play an important role in determining the binding specificity of the thioester-containing proteins. Accordingly, we postulate that the distinct binding reactions of the trout C3 isoforms with various complement activators could be due at least in part to the observed changes in the His and Glu residues.

Recent findings on the structure and function of teleost IgT

As key effector molecules of jawed vertebrates adaptive immune system, immunoglobulins are produced by B lymphocytes, either as a secretory form (antibody) or as a membrane form (B cell receptor). Until recently, teleost fish B cells were thought to express only two classes of immunoglobulins, IgM and IgD. In addition, IgM in these species was thought to be the only immunoglobulin isotype responding to pathogens both in systemic or mucosal compartments. However, the unexpected discovery of IgT, a new teleost immunoglobulin unearthed in 2005, has provided for new opportunities to analyze further roles of teleost immunoglobulins in these two physiologically distinct compartments. The smoke about the potential function of IgT has cleared recently with the finding that this immunoglobulin appears to be specialized in gut mucosal immunity. Significantly, the new capability of measuring not only IgM but also IgT responses will greatly facilitate the evaluation and understanding of fish immune responses as well as the protective effects of fish vaccines. The purpose of this review is to summarize the molecular characterization of new IgT orthologs and subtypes in teleosts, as well as to describe the new findings concerning the protein structure of IgT, the B cells producing it, and its role in mucosal immunity.