Targets of somatic hypermutation within immunoglobulin light chain genes in zebrafish

Marianes, Alexis E.; Zimmerman, Anastasia M.

doi:10.1111/j.1365-2567.2010.03358.x

Cited by 28 publications

(30 citation statements)

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“…Although fishes lack conventional class switch (Stavnezer and Amemiya 2004), fish AID has similar biochemical functions and deaminates cytosine, thus inducing point mutations; it even mediates class switch in mouse B cells (Barreto et al 2005). The mutational pattern observed in Ig sequences from catfish (Yang et al 2006), zebrafish (Marianes et al 2011), and also in nurse shark (Diaz et al 1999) reminds actually the one described in mammals, with a preference for transitions but no major bias for mutation of G:C or A:T pairs (Diaz et al 2001). …”

Section: Selected Distinctive Features Of Fish Immune Repertoiressupporting

confidence: 56%

“…In contrast, the distribution of mutations focused on CDRs in immunoglobulin kappa-like light chain in medaka suggested selection and affinity maturation; additionally, the dS/dN ratio was consistent with an antigen-driven selection in 5 out of 13 mutated sequences (Magadán-Mompó et al 2013). In zebrafish, the expansion of VJC clonal lineages with an increased frequency of mutation might also suggest selection of B cells expressing hypermutated Ig (Marianes et al 2011). …”

Section: Selected Distinctive Features Of Fish Immune Repertoiresmentioning

confidence: 99%

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Unique Features of Fish Immune Repertoires: Particularities of Adaptive Immunity Within the Largest Group of Vertebrates

Magadán

Sunyer

Boudinot

2015

Results and Problems in Cell Differentiation

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Fishes (i.e., teleost fishes) are the largest group of vertebrates. Although their immune system is based on the fundamental receptors, pathways, and cell types found in all groups of vertebrates, fishes show a diversity of particular features that challenge some classical concepts of immunology. In this chapter, we discuss the particularities of fish immune repertoires from a comparative perspective. We examine how allelic exclusion can be achieved when multiple Ig loci are present, how isotypic diversity and functional specificity impact clonal complexity, how loss of the MHC class II molecules affects the cooperation between T and B cells, and how deep sequencing technologies bring new insights about somatic hypermutation in the absence of germinal centers. The unique coexistence of two distinct B-cell lineages respectively specialized in systemic and mucosal responses is also discussed. Finally, we try to show that the diverse adaptations of immune repertoires in teleosts can help in understanding how somatic adaptive mechanisms of immunity evolved in parallel in different lineages across vertebrates.

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Section: Selected Distinctive Features Of Fish Immune Repertoiressupporting

confidence: 56%

Section: Selected Distinctive Features Of Fish Immune Repertoiresmentioning

confidence: 99%

Unique Features of Fish Immune Repertoires: Particularities of Adaptive Immunity Within the Largest Group of Vertebrates

Magadán

Sunyer

Boudinot

2015

Results and Problems in Cell Differentiation

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“…Rainbow trout IgM+ and IgT+ B cells undergo splenic clonal expansion in response to systemic viral infection (Castro et al, 2013). Although teleost B cells do not class switch, SHM of immunoglobulin genes is evident in zebrafish (Marianes and Zimmerman, 2011; Jiang et al, 2011) and channel catfish (Yang et al, 2006). Additionally, affinity maturation has been measured in rainbow trout, although antibody affinities increase marginally compared to the logarithmic increases that are measured in mammals (Cain et al, 2002; Kaattari et al, 2002; Ye et al, 2011).…”

Section: Zebrafish B Cellsmentioning

confidence: 99%

Perspectives on antigen presenting cells in zebrafish

Lewis

Cid

Traver

2014

Developmental & Comparative Immunology

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Antigen presentation is a critical step in the activation of naïve T lymphocytes. In mammals, dendritic cells (DCs), macrophages, and B lymphocytes can all function as antigen presenting cells (APCs). Although APCs have been identified in zebrafish, it is unclear if they fulfill similar roles in the initiation of adaptive immunity. Here we review the characterization of zebrafish macrophages, DCs, and B cells and evidence of their function as true APCs. Finally, we discuss the conservation of APC activity in vertebrates and the use of zebrafish to provide a new perspective on the evolution of these functions.

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“…Primary immunization can, thus, lead to increased immunogen sensitivity [1], enhanced in vivo [2][3][4][5][6] and in vitro [6][7][8] antibody responsiveness, expansion of antigen-sensitive precursor pools [9] and, most importantly, anamestic responses to pathogens [4,5,10,11] and immunoprophylaxis [4,[12][13][14]. Anamestic features absent from teleost responses include isotype switching [15] (although they possess multiple isotypes [16]), relatively modest somatic mutaCorrespondence: Dr. Stephen L. Kaattari e-mail: kaattari@vims.edu tion [17][18][19] and affinity maturation [20][21][22] as compared with the IgG responses of mammals. Intriguingly, characteristics of teleost memory B cells (MBCs) [9] parallel those associated with a class of mammalian MBCs.…”

mentioning

confidence: 99%

Differential compartmentalization of memory B cells versus plasma cells in salmonid fish

Kaattari

2013

Eur J Immunol

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The disposition of teleost memory and plasma cells (PCs) has essentially been unexplored. As the organization of the teleost immune system differs significantly from that of mammals (i.e. no bone marrow or lymph nodes, hematopoietic anterior kidney), this disposition could be essential in understanding how comparable functions are achieved. To address this question, the primary and secondary antibody-secreting cell, B memory cell, and antibody responses to T-independent and T-dependent antigens were analyzed in trout. Although the TI and TD antibody responses did not differ substantively from one another, the secondary responses to both were significantly prolonged compared with the primary responses. Logarithmic increases in titer and affinity were achieved for both antigens during the primary, with only modest increases during the secondary response. Antibody-secreting cells, both PCs and plasmablasts, quantitatively paralleled antibody production, with antibody-secreting cells skewing to the hematopoietic anterior kidney for both antigens. However, the enhanced antigen-inducible response of immune fish (indicative of the memory pool) skewed to the peripheral blood and spleen. This pattern of memory versus PC disposition parallels that observed in mammals even though the organization of the respective immune systems differs considerably. Keywords: Anterior kidney r Memory cells r Plasma cells r Trout IntroductionTeleost memory has been defined by the development of a differentially heightened responsive state to antigen, albeit lacking in a number of mammalian features. Primary immunization can, thus, lead to increased immunogen sensitivity [1], enhanced in vivo [2][3][4][5][6] and in vitro [6][7][8] antibody responsiveness, expansion of antigen-sensitive precursor pools [9] and, most importantly, anamestic responses to pathogens [4,5,10,11] and immunoprophylaxis [4,[12][13][14]. Anamestic features absent from teleost responses include isotype switching [15] (although they possess multiple isotypes [16]), relatively modest somatic mutaCorrespondence: Dr. Stephen L. Kaattari e-mail: kaattari@vims.edu tion [17][18][19] and affinity maturation [20][21][22] as compared with the IgG responses of mammals. Intriguingly, characteristics of teleost memory B cells (MBCs) [9] parallel those associated with a class of mammalian MBCs. Recent evidence reveals that human MBCs can include unswitched, mutated IgM + cells [23]; nonmutated, CD27 + IgM + cells [24], those induced by T-independent (TI) antigens [25,26], preimmune diversified repertoires [27] (as has recently been posed for the catfish [19]), or arise independently of GCs [27,28]. Together, these previous studies prompt a renewed focus on the critical elements of μ specific memory, both in teleosts and mammals. For example, perhaps the requisites for exceptionally high-titered, extensively mutated, high-affinity responses in * These authors contributed equally to this work. [32][33][34], which home to their respective hematopoietic tissues, even though the organs ...

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Targets of somatic hypermutation within immunoglobulin light chain genes in zebrafish

Cited by 28 publications

References 50 publications

Unique Features of Fish Immune Repertoires: Particularities of Adaptive Immunity Within the Largest Group of Vertebrates

Unique Features of Fish Immune Repertoires: Particularities of Adaptive Immunity Within the Largest Group of Vertebrates

Perspectives on antigen presenting cells in zebrafish

Differential compartmentalization of memory B cells versus plasma cells in salmonid fish

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