Ali A. Zarrin

IgH class switching and translocations use a robust non-classical end-joining pathway.

Immunoglobulin variable region exons are assembled in developing B cells by V(D)J recombination. Once mature, these cells undergo class-switch recombination (CSR) when activated by antigen. CSR changes the heavy chain constant region exons (Ch) expressed with a given variable region exon from Cμ to a downstream Ch (for example, Cγ, Cε or Cα), thereby switching expression from IgM to IgG, IgE or IgA. Both V(D)J recombination and CSR involve the introduction of DNA double-strand breaks and their repair by means of end joining. For CSR, double-strand breaks are introduced into switch regions that flank Cμ and a downstream Ch, followed by fusion of the broken switch regions. In mammalian cells, the ‘classical’ non-homologous end joining (C-NHEJ) pathway repairs both general DNA double-strand breaks and programmed double-strand breaks generated by V(D)J recombination. C-NHEJ, as observed during V(D)J recombination, joins ends that lack homology to form ‘direct’ joins, and also joins ends with several base-pair homologies to form microhomology joins. CSR joins also display direct and microhomology joins, and CSR has been suggested to use C-NHEJ. Xrcc4 and DNA ligase IV (Lig4), which cooperatively catalyse the ligation step of C-NHEJ, are the most specific C-NHEJ factors; they are absolutely required for V(D)J recombination and have no known functions other than C-NHEJ. Here we assess whether C-NHEJ is also critical for CSR by assaying CSR in Xrcc4- or Lig4-deficient mouse B cells. C-NHEJ indeed catalyses CSR joins, because C-NHEJ-deficient B cells had decreased CSR and substantial levels of IgH locus (immunoglobulin heavy chain, encoded by Igh) chromosomal breaks. However, an alternative end-joining pathway, which is markedly biased towards microhomology joins, supports CSR at unexpectedly robust levels in C-NHEJ-deficient B cells. In the absence of C-NHEJ, this alternative end-joining pathway also frequently joins Igh locus breaks to other chromosomes to generate translocations.

An evolutionarily conserved target motif for immunoglobulin class-switch recombination

Immunoglobulin H class-switch recombination (CSR) occurs between switch regions and requires transcription and activation-induced cytidine deaminase (AID). Transcription through mammalian switch regions, because of their GC-rich composition, generates stable R-loops, which provide single-stranded DNA substrates for AID. However, we show here that the Xenopus laevis switch region Sμ, which is rich in AT and not prone to form R-loops, can functionally replace a mouse switch region to mediate CSR in vivo. X. laevis Sμ–mediated CSR occurred mostly in a region of AGCT repeats targeted by the AID–replication protein A complex when transcribed in vitro. We propose that AGCT is a primordial CSR motif that targets AID through a non-R-loop mechanism involving an AID–replication protein A complex.

Mechanisms promoting translocations in editing and switching peripheral B cells

Variable, diversity and joining gene segment (V(D)J) recombination assembles immunoglobulin heavy or light chain (IgH or IgL) variable region exons in developing bone marrow B cells, whereas class switch recombination (CSR) exchanges IgH constant region exons in peripheral B cells. Both processes use directed DNA double-strand breaks (DSBs) repaired by non-homologous end-joining (NHEJ). Errors in either V(D)J recombination or CSR can initiate chromosomal translocations, including oncogenic IgH locus (Igh) to c-myc (also known as Myc) translocations of peripheral B cell lymphomas. Collaboration between these processes has also been proposed to initiate translocations. However, the occurrence of V(D)J recombination in peripheral B cells is controversial. Here we show that activated NHEJ-deficient splenic B cells accumulate V(D)J-recombination-associated breaks at the lambda IgL locus (Igl), as well as CSR-associated Igh breaks, often in the same cell. Moreover, Igl and Igh breaks are frequently joined to form translocations, a phenomenon associated with specific Igh–Igl co-localization. Igh and c-myc also co-localize in these cells; correspondingly, the introduction of frequent c-myc DSBs robustly promotes Igh–c-myc translocations. Our studies show peripheral B cells that attempt secondary V(D)J recombination, and determine a role for mechanistic factors in promoting recurrent translocations in tumours.

Internal IgH class switch region deletions are position-independent and enhanced by AID expression

Ig heavy chain class switch recombination (CSR) involves a recombination/deletion mechanism that exchanges the expressed CH gene with a downstream CH gene. CSR is mediated by highly repetitive switch (S) region sequences and requires the activation-induced deaminase (AID). The S region 5′ of the Cμ gene (Sμ) can undergo high-frequency internal deletions in normal B cells and B cell lines activated for CSR, although the relationship of these deletions and CSR has not been elucidated. In this study, we introduced constitutively transcribed Sμ or Sγ2b regions into a pro-B cell line that can be activated for AID expression, CSR, and endogenous Sμ deletions. We find that randomly integrated S region transcription units in these cells also undergo increased levels of internal rearrangements after cellular activation, indicating that the deletion process is independent of location within the Ig heavy chain locus and potentially AID-promoted. To test the latter issue, we generated hybridomas from wild-type and AID-deficient activated B cells and assayed them for internal Sμ deletions and S region mutations. These studies demonstrated that efficient intra-S region recombination depends on AID expression and that internal S region deletions are accompanied by frequent mutations, indicating that most S region deletions occur by the same mechanism as CSR.

IgH class switching exploits a general property of two DNA breaks to be joined in cis over long chromosomal distances.

Significance During an immune response, B lymphocytes generate different classes of antibodies better suited to protect against particular pathogens by making two chromosomal cuts that are joined to replace one type of antibody gene with a different one. These cuts happen in widely separated segments of the chromosome that must be physically adjacent to be joined. We have asked how this happens. The surprising answer is that genes and gene segments lying certain distances apart on any chromosome may actually be packaged such that both are frequently touching or nearly touching and, if broken, can be efficiently joined by general processes that repair breaks in all our genes. The joining mechanisms we describe also may contribute to genetic deletions in cancers. Antibody class switch recombination (CSR) in B lymphocytes joins two DNA double-strand breaks (DSBs) lying 100–200 kb apart within switch (S) regions in the immunoglobulin heavy-chain locus (IgH). CSR-activated B lymphocytes generate multiple S-region DSBs in the donor Sμ and in a downstream acceptor S region, with a DSB in Sμ being joined to a DSB in the acceptor S region at sufficient frequency to drive CSR in a large fraction of activated B cells. Such frequent joining of widely separated CSR DSBs could be promoted by IgH-specific or B-cell–specific processes or by general aspects of chromosome architecture and DSB repair. Previously, we found that B cells with two yeast I-SceI endonuclease targets in place of Sγ1 undergo I-SceI–dependent class switching from IgM to IgG1 at 5–10% of normal levels. Now, we report that B cells in which Sγ1 is replaced with a 28 I-SceI target array, designed to increase I-SceI DSB frequency, undergo I-SceI–dependent class switching at almost normal levels. High-throughput genome-wide translocation sequencing revealed that I-SceI–generated DSBs introduced in cis at Sμ and Sγ1 sites are joined together in T cells at levels similar to those of B cells. Such high joining levels also occurred between I-SceI–generated DSBs within c-myc and I-SceI– or CRISPR/Cas9-generated DSBs 100 kb downstream within Pvt1 in B cells or fibroblasts, respectively. We suggest that CSR exploits a general propensity of intrachromosomal DSBs separated by several hundred kilobases to be frequently joined together and discuss the relevance of this finding for recurrent interstitial deletions in cancer.

Evolutionarily Conserved Paired Immunoglobulin-like Receptor α (PILRα) Domain Mediates Its Interaction with Diverse Sialylated Ligands

Background: PILRα is an inhibitory receptor predominantly expressed in myeloid cells. Results: NPDC1 and COLEC12 are novel PILRα ligands. PILRα arginine residues 133 (mouse) and 126 (human) are critical contact residues. Conclusion: PILRα/ligand interactions involve a conserved domain in PILRα and a sialylated protein domain in the ligand. Significance: PILRα interacts with various ligands to alter myeloid cell function. Paired immunoglobulin-like receptor (PILR) α is an inhibitory receptor that recognizes several ligands, including mouse CD99, PILR-associating neural protein, and Herpes simplex virus-1 glycoprotein B. The physiological function(s) of interactions between PILRα and its cellular ligands are not well understood, as are the molecular determinants of PILRα/ligand interactions. To address these uncertainties, we sought to identify additional PILRα ligands and further define the molecular basis for PILRα/ligand interactions. Here, we identify two novel PILRα binding partners, neuronal differentiation and proliferation factor-1 (NPDC1), and collectin-12 (COLEC12). We find that sialylated O-glycans on these novel PILRα ligands, and on known PILRα ligands, are compulsory for PILRα binding. Sialylation-dependent ligand recognition is also a property of SIGLEC1, a member of the sialic acid-binding Ig-like lectins. SIGLEC1 Ig domain shares ∼22% sequence identity with PILRα, an identity that includes a conserved arginine localized to position 97 in mouse and human SIGLEC1, position 133 in mouse PILRα and position 126 in human PILRα. We observe that PILRα/ligand interactions require conserved PILRα Arg-133 (mouse) and Arg-126 (human), in correspondence with a previously reported requirement for SIGLEC1 Arg-197 in SIGLEC1/ligand interactions. Homology modeling identifies striking similarities between PILRα and SIGLEC1 ligand binding pockets as well as at least one set of distinctive interactions in the galactoxyl-binding site. Binding studies suggest that PILRα recognizes a complex ligand domain involving both sialic acid and protein motif(s). Thus, PILRα is evolved to engage multiple ligands with common molecular determinants to modulate myeloid cell functions in anatomical settings where PILRα ligands are expressed.

Functional analysis of the human RAG 2 promoter.

Recombination activating genes RAG1 and RAG2 are essential components of V(D)J recombination, a process that generates the specific antigen receptors in lymphocytes. To understand the mechanisms underlying the lineage and developmental regulation of transcription of RAG2, we have characterized the human RAG2 exon 1A promoter. In this study, a series of deletion constructs were used to isolate the promoter while a linker scanning approach was taken to assess functionally relevant cis elements within the promoter. Two regulatory domains were identified. The -140 to -123 region is critical for promoter activity in all cell lines tested. Mutations to the putative Ets (-122 to -118) or to the C/EBP (-137 to -129) consensus core sequences did abrogate promoter activity, although specific DNA/protein interactions remained, as determined by EMSA. The -69 to -48 region demonstrates lineage specific promoter activity. Mutations to an overlapping, BSAP-myb-Ikaros-myb site (-65 to -39) resulted in differential promoter activity in human B and T cells. EMSA analysis of this region showed a B cell specific protein complex. Transfection of BSAP into cell lines trans-activates the human RAG2 promoter. We conclude that transcriptional regulation of the human RAG2 gene is complex, involving both tissue specific and ubiquitous factors, and both proximal and distal regulatory elements.

Increased Targeting of Donor Switch Region and IgE in Sγ1-Deficient B Cells

Ab class switch recombination involves a recombination between two repetitive DNA sequences known as switch (S) regions that vary in length, content, and density of the repeats. Abs expressed by B cells are diversified by somatic hypermutation and class switch recombination. Both class switch recombination and somatic hypermutation are initiated by activation-induced cytidine deaminase (AID), which preferentially recognizes certain hot spots that are far more enriched in the S regions. We found that removal of the largest S region, Sγ1 (10 kb), in mice can result in the accumulation of mutations and short-range intra-S recombination in the donor Sμ region. Furthermore, elevated levels of IgE were detected in trinitrophenol-OVA–immunized mice and in anti-CD40 plus IL-4–stimulated B cells in vitro. We propose that AID availability and targeting in part might be regulated by its DNA substrate. Thus, prominently transcribed S regions, such as Sγ1, might provide a sufficient sink for AID protein to titrate away AID from other accessible sites within or outside the Ig locus.

Differential utilization of T cell receptor TCRα/TCRδ locus variable region gene segments is mediated by accessibility

T cell receptor (TCR) variable region exons are assembled from germline V, (D), and J gene segments, each of which is flanked by recombination signal (RS) sequences that are composed of a conserved heptamer, a spacer of 12 or 23 bp, and a characteristic nonamer. V(D)J recombination only occurs between V, D, and J segments flanked by RS sequences that contain, respectively, 12(12-RS)- and 23(23-RS)-bp spacers (12/23 rule). Additional mechanisms can restrict joining of 12/23 RS matched segments beyond the 12/23 rule (B12/23). The TCRδ locus is contained within the TCRα locus; TCRα variable region exons are encoded by TRAV and TRAJ segments and those of TCRδ by TRDV, TRDD, and TRDJ segments. On the basis of the 12/23 rule, both TRAV and TRDV gene segments are compatible to rearrange with TRDD gene segments; however, TRAV-to-TRDD joins are not observed in vivo. Absence of TRAV-to-TRDD rearrangement might be explained either by B12/23 restriction or by differential accessibility of the TRDV versus TRAV gene segments for rearrangement to TRDD. We used in vitro substrate analysis to reveal that both TRAV and TRDV 23-RSs mediate rearrangements to the 5′TRDD1 12-RS, demonstrating that B12/23 restriction does not explain these rearrangement biases. However, targeted replacement of TRDD1 and its 12-RSs with TRAJ38 and its 12-RS showed that TRDV gene segments rearrange with the ectopic TRAJ38, whereas TRAV segments do not. Our results demonstrate that sorting of TRAV and TRDV gene segments is determined by differential locus accessibility during T cell development.

Analysis of mice lacking DNaseI hypersensitive sites at the 5' end of the IgH locus.

The 5′ end of the IgH locus contains a cluster of DNaseI hypersensitive sites, one of which (HS1) was shown to be pro-B cell specific and to contain binding sites for the transcription factors PU.1, E2A, and Pax5. These data as well as the location of the hypersensitive sites at the 5′ border of the IgH locus suggested a possible regulatory function for these elements with respect to the IgH locus. To test this notion, we generated mice carrying targeted deletions of either the pro-B cell specific site HS1 or the whole cluster of DNaseI hypersensitive sites. Lymphocytes carrying these deletions appear to undergo normal development, and mutant B cells do not exhibit any obvious defects in V(D)J recombination, allelic exclusion, or class switch recombination. We conclude that deletion of these DNaseI hypersensitive sites does not have an obvious impact on the IgH locus or B cell development.