Brantley R. Herrin

Dual nature of the adaptive immune system in lampreys

Jawless vertebrates use variable lymphocyte receptors (VLR) comprised of leucine-rich-repeat (LRR) segments as counterparts of the immunoglobulin-based receptors that jawed vertebrates use for antigen recognition. Highly diverse VLR genes are somatically assembled by the insertion of variable LRR sequences into incomplete germline VLRA and VLRB genes. Here we show that in sea lampreys (Petromyzon marinus) VLRA and VLRB anticipatory receptors are expressed by separate lymphocyte populations by monoallelic VLRA or VLRB assembly, together with expression of cytosine deaminase 1 (CDA1) or 2 (CDA2), respectively. Distinctive gene expression profiles for VLRA+ and VLRB+ lymphocytes resemble those of mammalian T and B cells. Although both the VLRA and the VLRB cells proliferate in response to antigenic stimulation, only the VLRB lymphocytes bind native antigens and differentiate into VLR antibody-secreting cells. Conversely, VLRA lymphocytes respond preferentially to a classical T-cell mitogen and upregulate the expression of the pro-inflammatory cytokine genes interleukin-17 (IL-17) and macrophage migration inhibitory factor (MIF). The finding of T-like and B-like lymphocytes in lampreys offers new insight into the evolution of adaptive immunity.

Antibody responses of variable lymphocyte receptors in the lamprey

Lamprey and hagfish, the living representatives of jawless vertebrates, use genomic leucine-rich-repeat cassettes for the combinatorial assembly of diverse antigen receptor genes encoding variable lymphocyte receptors of two types: VLRA and VLRB. We describe here the VLRB-bearing lineage of lymphocytes in sea lamprey. These cells responded to repetitive carbohydrate or protein determinants on bacteria or mammalian cells with lymphoblastoid transformation, proliferation and differentiation into plasmacytes that secreted multimeric antigen-specific VLRB antibodies. Lacking a thymus and the ability to respond to soluble protein antigens, lampreys seem to have evolved a B cell–like system for adaptive humoral responses.

Structure and specificity of lamprey monoclonal antibodies

Adaptive immunity in jawless vertebrates (lamprey and hagfish) is mediated by lymphocytes that undergo combinatorial assembly of leucine-rich repeat (LRR) gene segments to create a diverse repertoire of variable lymphocyte receptor (VLR) genes. Immunization with particulate antigens induces VLR-B-bearing lymphocytes to secrete antigen-specific VLR-B antibodies. Here, we describe the production of recombinant VLR-B antibodies specific for BclA, a major coat protein of Bacillus anthracis spores. The recombinant VLR-B antibodies possess 8–10 uniform subunits that collectively bind antigen with high avidity. Sequence analysis, mutagenesis, and modeling studies show that antigen binding involves residues in the β-sheets lining the VLR-B concave surface. EM visualization reveals tetrameric and pentameric molecules having a central core and highly flexible pairs of stalk-region “arms” with antigen-binding “hands.” Remarkable antigen-binding specificity, avidity, and stability predict that these unusual LRR-based monoclonal antibodies will find many biomedical uses.

Antigen Recognition by Variable Lymphocyte Receptors

Variable lymphocyte receptors (VLRs) rather than antibodies play the primary role in recognition of antigens in the adaptive immune system of jawless vertebrates. Combinatorial assembly of leucine-rich repeat (LRR) gene segments achieves the required repertoire for antigen recognition. We have determined a crystal structure for a VLR-antigen complex, VLR RBC36 in complex with the H-antigen trisaccharide from human blood type O erythrocytes, at 1.67 angstrom resolution. RBC36 binds the H-trisaccharide on the concave surface of the LRR modules of the solenoid structure where three key hydrophilic residues, multiple van der Waals interactions, and the highly variable insert of the carboxyl-terminal LRR module determine antigen recognition and specificity. The concave surface assembled from the most highly variable regions of the LRRs, along with diversity in the sequence and length of the highly variable insert, can account for the recognition of diverse antigens by VLRs.

Alternative Adaptive Immunity in Jawless Vertebrates

Jawless vertebrates use variable lymphocyte receptors (VLRs) that are generated by RAG-independent combinatorial assembly of leucine-rich repeat cassettes for Ag recognition, instead of the Ig-based Ag receptors used by jawed vertebrates. The VLR genes encode for crescent-shaped proteins that use variable β-strands and a C-terminal loop to bind to Ags rather than the six CDR loops used by BCRs and TCRs. VLR mAbs have been isolated recently, which enabled the structure of VLR–Ag complexes to be defined. The jawless vertebrate adaptive immune system has many similarities to the Ig-based system of jawed vertebrates, including the compartmentalized development of B-like and T-like lymphocyte lineages that proliferate and differentiate into VLR-secreting plasmacytes and proinflammatory cytokine-producing cells in response to Ags. The definition of common features of the VLR-based and Ig-based systems offers fresh insight into the evolution of adaptive immunity.

Trem-Like Transcript 2 Is Expressed on Cells of the Myeloid/Granuloid and B Lymphoid Lineage and Is Up-Regulated in Response to Inflammation

The triggering receptor expressed on myeloid cells (TREM) gene cluster encodes a group of transmembrane proteins that are emerging as important components in innate and adaptive immunity. In both mice and humans, the TREM gene cluster encodes eight receptors; only four of these, however, are direct homologs: TREM-1, TREM-2, TREM-like transcript 1 (TLT1), and TLT2. Of the transmembrane receptors encoded by the four conserved genes within this cluster, TLT2 has not been studied previously. Data presented in this study demonstrate that TLT2 is expressed early in B cell development in conjunction with B220 and is detected on all developing mouse B cell populations as well as B cells in the periphery. TLT2 expression on B cells in the periphery exhibits a distinct hierarchy with the highest detectable levels observed on B1 B cells in the peritoneum. The overall gradation of TLT2 expression on B cells is: B1 > marginal zone/transitional 2 > transitional 1 > follicular. Additionally, TLT2 expression was observed on mouse neutrophils throughout the body. Although monocytes were not observed to express TLT2, resident peritoneal and lung macrophages do express TLT2, suggesting that it is up-regulated in association with terminal differentiation of monocytes. Finally, both neutrophils and macrophages were observed to up-regulate TLT2 expression in vivo in response to inflammatory stimuli, whereas TLT2 expression on B cells remained unchanged. In conclusion, the data suggest that TLT2 may be involved in the innate immune response based on its expression profile and the fact that it is up-regulated in response to inflammation.

The B Cell Coreceptor CD22 Associates with AP50, a Clathrin-Coated Pit Adapter Protein, Via Tyrosine-Dependent Interaction

The B cell coreceptor CD22 plays an important role in regulating signal transduction via the B cell Ag receptor. Studies have shown that surface expression of CD22 can be modulated in response to binding of ligand (i.e., mAb). Thus, it is possible that alterations in the level of CD22 expression following binding of natural ligand(s) may affect its ability to modulate the Ag receptor signaling threshold at specific points during B cell development and differentiation. Therefore, it is important to delineate the physiologic mechanism by which CD22 expression is controlled. In the current study, yeast two-hybrid analysis was used to demonstrate that CD22 interacts with AP50, the medium chain subunit of the AP-2 complex, via tyrosine-based internalization motifs in its cytoplasmic domain. This interaction was further characterized using yeast two-hybrid analysis revealing that Tyr843 and surrounding amino acids in the cytoplasmic tail of CD22 comprise the primary binding site for AP50. Subsequent studies using transfectant Jurkat cell lines expressing wild-type or mutant forms of CD22 demonstrated that either Tyr843 or Tyr863 is sufficient for mAb-mediated internalization of CD22 and that these motifs are involved in its interaction with the AP-2 complex, as determined by coprecipitation of α-adaptin. Finally, experiments were performed demonstrating that treatment of B cells with either intact anti-Ig Ab or F(ab′)2 blocks ligand-mediated internalization of CD22. In conclusion, these studies demonstrate that internalization of CD22 is dependent on its association with the AP-2 complex via tyrosine-based internalization motifs.

Determination of lymphoid cell fate is dependent on the expression status of the IL‐7 receptor

Signaling through the IL‐7 receptor (IL‐7R) is necessary for the development of the earliest B‐ and T‐lineage cells. IL‐7R is first expressed on common lymphoid progenitor cells and is not detected on primitive common myeloid progenitors. In this study, we show that enforced expression of IL‐7R on multipotential stem cells does not influence lymphoid versus myeloid cell fate. T cell development was compatible with sustained IL‐7R expression; however, we observed a near complete block in B cell development at the onset of B‐lineage commitment. Unlike pre‐proB cells from control animals, developmentally‐arrested IL‐7R+B220+cd19−NK1.1−Ly‐6C− cells failed to express EBF and Pax5. These results suggest that transient downregulation of IL‐7R signaling is a necessary event for induction of EBF and Pax5 expression and B‐lymphocyte commitment.

Definition of a third VLR gene in hagfish

Significance The jawless vertebrates (hagfish and lampreys) possess an alternative adaptive immune system in which variable lymphocyte receptors (VLRs) constructed of leucine-rich repeats are used to recognize foreign antigens. Three VLR genes have been identified in lampreys (VLRA, VLRB, and VLRC), but only two (VLRA and VLRB) have been found in hagfish. Here, we identified and characterized a third hagfish VLR gene. Our analysis indicates that the third hagfish VLR is the ortholog of lamprey VLRA, while the previously identified hagfish “VLRA” is the counterpart of lamprey VLRC. The demonstration of three orthologous VLR genes in hagfish and lampreys suggests that this anticipatory receptor system evolved in a common ancestor of the two jawless vertebrate lineages ∼480 Mya. Jawless vertebrates (cyclostomes) have an alternative adaptive immune system in which lymphocytes somatically diversify their variable lymphocyte receptors (VLR) through recombinatorial use of leucine-rich repeat cassettes during VLR gene assembly. Three types of these anticipatory receptors in lampreys (VLRA, VLRB, and VLRC) are expressed by separate lymphocyte lineages. However, only two VLR genes (VLRA and VLRB) have been found in hagfish. Here we have identified a third hagfish VLR, which undergoes somatic assembly to generate sufficient diversity to encode a large repertoire of anticipatory receptors. Sequence analysis, structural comparison, and phylogenetic analysis indicate that the unique hagfish VLR is the counterpart of lamprey VLRA and the previously identified hagfish “VLRA” is the lamprey VLRC counterpart. The demonstration of three orthologous VLR genes in both lampreys and hagfish suggests that this anticipatory receptor system evolved in a common ancestor of the two cyclostome lineages around 480 Mya.

Expression of the Adaptor Protein Hematopoietic Src Homology 2 is Up-Regulated in Response to Stimuli That Promote Survival and Differentiation of B Cells

Analysis of hematopoietic Src homology 2 (HSH2) protein expression in mouse immune cells demonstrated that it is expressed at low levels in resting B cells but not T cells or macrophages. However, HSH2 expression is up-regulated within 6–12 h in response to multiple stimuli that promote activation, differentiation, and survival of splenic B cells. HSH2 expression is increased in response to anti-CD40 mAb, the TLR ligands LPS and CpG DNA, and B lymphocyte stimulator (BLyS), a key regulator of peripheral B cell survival and homeostasis. Stimulation of B cells with anti-CD40 mAb, LPS, CpG DNA, or BLyS has previously been shown to induce activation of NF-κB. In agreement with this finding, up-regulation of HSH2 expression in response to these stimuli is blocked by inhibitors of NF-κB activation and is potentiated by stimulation with PMA, suggesting that HSH2 expression is dependent on NF-κB activation. In contrast to CD40, BAFF receptor, TLR4, and TLR9 mediated signaling, stimulation of splenic B cells via the BCR was not observed to induce expression of HSH2 unless the cells had been stimulated previously through CD40. Finally, HSH2 expression is down-regulated in splenic B cells in response to stimulation with IL-21, which has been shown to induce apoptosis, even in the presence of anti-CD40 mAb, LPS, or CpG DNA. IL-21 stimulation also results in down-regulation of antiapoptotic proteins such as Bcl-xL and up-regulation of proapoptotic proteins like Bim. Therefore, HSH2 expression is coordinately up-regulated with known antiapoptotic molecules and directly correlates with B cell survival.