Directed Ig class switch recombination in activated murine B cells

53BP1 Supports Immunoglobulin Class Switch Recombination Independently of Its DNA Double-Strand Break End Protection Function

Class switch recombination (CSR) is a DNA recombination reaction that diversifies the effector functions of antibodies. CSR occurs via the formation and non-homologous end joining (NHEJ) repair of programmed DNA double-strand breaks (DSBs) at the immunoglobulin heavy chain locus. The DNA repair factors 53BP1 and Rif1 promote NHEJ and CSR by protecting DSBs against resection. However, to what extent repression of DNA end resection contributes to CSR is unknown. Here, we show that B lymphocytes devoid of 53BP1-Rif1-dependent DSB end protection activity undergo robust CSR. Inactivation of specific sets of phospho-sites within 53BP1 N-terminal SQ/TQ motifs abrogates Rif1 recruitment and inhibition of resection but only mildly reduces CSR. Furthermore, mutations within 53BP1 oligomerization domain abolish CSR without substantially affecting DNA end processing. Thus, inhibition of DNA end resection does not correlate with CSR efficiency, indicating that regulation of DSB processing is not a key determinant step in CSR.

•

53BP1 oligomerization is largely dispensable for inhibition of DSB resection

•

53BP1 higher order oligomerization is a pre-requisite for CSR

•

B lymphocytes devoid of 53BP1-Rif1 DSB end protection activity undergo robust CSR

•

53BP1-mediated DSB end mobility is dispensable for CSR

Two modes of cis-activation of switch transcription by the IgH superenhancer

B cell isotype switching plays an important role in modulating adaptive immune responses. It occurs in response to specific signals that often induce different isotype (I) promoters driving transcription of switch regions, located upstream of the Ig heavy chain (IgH) constant genes. The transcribed switch regions can recombine, leading to a change of the constant gene and, consequently, of antibody isotype. Switch transcription is controlled by the superenhancer 3' regulatory region (3'RR) that establishes long-range chromatin cis-interactions with I promoters. Most stimuli induce more than one I promoter, and switch transcription can occur on both chromosomes. Therefore, it is presently unknown whether induced I promoters compete for the 3'RR on the same chromosome. Here we performed single-chromosome RT-qPCR assays to examine switch transcription monoallelically in the endogenous context. We show that there are two modes of 3'RR-mediated activation of I promoters: coactivation and competition. The nature of the inducing signal plays a pivotal role in determining the mode of activation. Furthermore, we provide evidence that, in its endogenous setting, the 3'RR has a bidirectional activity. We propose that the coactivation and competition modes mediated by the 3'RR may have evolved to cope with the different kinetics of primary immune responses.

A transcriptional serenAID: the role of noncoding RNAs in class switch recombination

During an immune response, activated B cells may undergo class switch recombination (CSR), a molecular rearrangement that allows B cells to switch from expressing IgM and IgD to a secondary antibody heavy chain isotype such as IgG, IgA or IgE. Secondary antibody isotypes provide the adaptive immune system with distinct effector functions to optimally combat various pathogens. CSR occurs between repetitive DNA elements within the immunoglobulin heavy chain (Igh) locus, termed switch (S) regions and requires the DNA-modifying enzyme activation-induced cytidine deaminase (AID). AID-mediated DNA deamination within S regions initiates the formation of DNA double-strand breaks, which serve as biochemical beacons for downstream DNA repair pathways that coordinate the ligation of DNA breaks. Myriad factors contribute to optimal AID targeting; however, many of these factors also localize to genomic regions outside of the Igh locus. Thus, a current challenge is to explain the specific targeting of AID to the Igh locus. Recent studies have implicated noncoding RNAs in CSR, suggesting a provocative mechanism that incorporates Igh-specific factors to enable precise AID targeting. Here, we chronologically recount the rich history of noncoding RNAs functioning in CSR to provide a comprehensive context for recent and future discoveries. We present a model for the RNA-guided targeting of AID that attempts to integrate historical and recent findings, and highlight potential caveats. Lastly, we discuss testable hypotheses ripe for current experimentation, and explore promising ideas for future investigations.

RPA accumulation during class switch recombination represents 5'-3' DNA-end resection during the S-G2/M phase of the cell cycle

Activation-induced cytidine deaminase (AID) promotes chromosomal translocations by inducing DNA double-strand breaks (DSBs) at immunoglobulin (Ig) genes and oncogenes in the G1 phase. RPA is a single-stranded DNA (ssDNA)-binding protein that associates with resected DSBs in the S phase and facilitates the assembly of factors involved in homologous repair (HR), such as Rad51. Notably, RPA deposition also marks sites of AID-mediated damage, but its role in Ig gene recombination remains unclear. Here, we demonstrate that RPA associates asymmetrically with resected ssDNA in response to lesions created by AID, recombination-activating genes (RAG), or other nucleases. Small amounts of RPA are deposited at AID targets in G1 in an ATM-dependent manner. In contrast, recruitment in the S-G2/M phase is extensive, ATM independent, and associated with Rad51 accumulation. In the S-G2/M phase, RPA increases in nonhomologous-end-joining-deficient lymphocytes, where there is more extensive DNA-end resection. Thus, most RPA recruitment during class switch recombination represents salvage of unrepaired breaks by homology-based pathways during the S-G2/M phase of the cell cycle.

Mismatch repair proteins MSH2, MLH1, and EXO1 are important for class-switch recombination events occurring in B cells that lack nonhomologous end joining

In the absence of core nonhomologous end-joining (NHEJ) factors, Ab gene class-switch recombination (CSR) uses an alternative end-joining (A-EJ) pathway to recombine switch (S) region DNA breaks. Previous reports showing decreased S-junction microhomologies in MSH2-deficient mice and an exonuclease 1 (EXO1) role in yeast microhomology-mediated end joining suggest that mismatch repair (MMR) proteins might influence A-EJ-mediated CSR. We have directly investigated whether MMR proteins collectively or differentially influence the A-EJ mechanism of CSR by analyzing CSR in mice deficient in both XRCC4 and individual MMR proteins. We find CSR is reduced and that Igh locus chromosome breaks are reduced in the MMR/XRCC4 double-deficient B cells compared with B cells deficient in XRCC4 alone, suggesting MMR proteins function upstream of double-strand break formation to influence CSR efficiency in these cells. Our results show that MLH1, EXO1, and MSH2 are all important for efficient A-EJ-mediated CSR, and we propose that MMR proteins convert DNA nicks and point mutations into dsDNA breaks for both C-NHEJ and A-EJ pathways of CSR. We also find Mlh1-XRCC4(-) B cells have an increased frequency of direct S junctions, suggesting that MLH1 proteins may have additional functions that influence A-EJ-mediated CSR.

Increased targeting of donor switch region and IgE in Sgamma1-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, Sgamma1 (10 kb), in mice can result in the accumulation of mutations and short-range intra-S recombination in the donor Smu 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 Sgamma1, might provide a sufficient sink for AID protein to titrate away AID from other accessible sites within or outside the Ig locus.

Switch region identity plays an important role in Ig class switch recombination

Ig class switch recombination (CSR) is regulated through long-range intrachromosomal interactions between germline transcript promoters and enhancers to initiate transcription and create chromatin accessible to activation-induced deaminase attack. CSR occurs between switch (S) regions that flank Cmu and downstream C(H) regions and functions via an intrachromosomal deletional event between the donor Smicro region and a downstream S region. It is unclear to what extent S region primary sequence influences differential targeting of CSR to specific isotypes. We address this issue in this study by generating mutant mice in which the endogenous Sgamma3 region was replaced with size-matched Sgamma1 sequence. B cell activation conditions are established that support robust gamma3 and gamma1 germline transcript expression and stimulate IgG1 switching but suppress IgG3 CSR. We found that the Sgamma1 replacement allele engages in micro-->gamma3 CSR, whereas the intact allele is repressed. We conclude that S region identity makes a significant contribution to CSR. We propose that the Sgamma1 region is selectively targeted for CSR following the induction of an isotype-specific factor that targets the S region and recruits CSR machinery.

Replacement of Igamma3 germ-line promoter by Igamma1 inhibits class-switch recombination to IgG3

Class-switch recombination (CSR) enables IgM-producing B cells to switch to the production of IgG, IgE, and IgA. The process requires germ-line (GL) transcription that initiates from promoters upstream of switch (S) sequences and is regulated by the 3' regulatory region (3'RR) located downstream of the Ig heavy chain (IgH) locus. How the 3'RR effect its long-range activation is presently unclear. We generated a mouse line in which Igamma3 GL promoter was replaced by Igamma1. We found that GL transcription could initiate from the inserted Igamma1 promoter and was induced by increased concentrations of IL-4 and that the transcripts were normally spliced. However, when compared with GL transcripts derived from the endogenous Igamma1 promoter in the same stimulation conditions, those from the inserted Igamma1 promoter were less abundant. CSR to Cgamma3 was abrogated both in vivo and in vitro. The results strongly suggest that the endogenous Igamma1 promoter insulates the inserted Igamma1 from the long-range activating effect of the 3'RR. The implications of our findings are discussed in light of the prominent models of long-distance activation in complex loci.

Requirement of Non-canonical Activity of Uracil DNA Glycosylase for Class Switch Recombination

Activation-induced cytidine deaminase (AID) and uracil DNA glycosylase (UNG) are required for class switch recombination (CSR). AID is involved in the DNA cleavage step of CSR, but the precise role of UNG is not yet understood. Mutations and deletions are footprints of abortive DNA cleavage in the immunoglobulin switch region in splenic B cells stimulated to undergo CSR. However, a UNG deficiency did not reduce the number of such footprints, indicating UNG is dispensable for the DNA cleavage step. Mutagenesis experiments revealed that the role of UNG in CSR depends on its WXXF motif. This motif is also essential for the interaction of UNG with the HIV viral peptide Vpr, which recruits UNG to the HIV particle. Furthermore, exogenous Vpr had a dominant-negative effect on CSR. These results suggest that UNG is recruited to the CSR machinery through its WXXF motif by a Vpr-like host factor and plays a novel non-canonical role in a CSR step that follows DNA cleavage.

Pathways that suppress programmed DNA breaks from progressing to chromosomal breaks and translocations

Guarding the genome against internal and external assaults requires the coordinated interaction of multiple cellular networks to sense, respond to, and repair breaks in chromosomal DNA. Both external factors such as ionizing radiation or internal events like oxidative damage can cause DNA double stranded breaks (DSBs). DSBs are also part of the normal lymphocyte developmental program where they are an integral element of the mechanisms that generate a diverse immune repertoire in the context of V(D)J and immunoglobulin heavy chain (IgH) class switch recombination (CSR). DSBs initiate a cascade of cellular events that direct cells to pause and properly repair potentially lethal chromosomal breaks. Errors in the repair of both general and lymphocyte-specific DSBs can lead to oncogenic chromosomal translocations . Here, we review recent advances in understanding factors and protein complexes involved in the response to DNA DSBs with a focus on the B lymphocyte specific process of CSR.

Class switch recombination: an emerging mechanism

Class switch recombination (CSR) has been the least well understood of the Ig gene DNA rearrangements. The discovery that activation-induced deaminase (AID) is a pivotal player in CSR as well as somatic hypermutation (SHM) and its variant, gene conversion, represents a sea change in our understanding of these processes. The recognition that AID directly deaminates ssDNA has provided a springboard toward the emergence of a model that explains the initiation of these events. Nonhomologous end joining (NHEJ), the main pathway for the repair of double-strand breaks in mammalian cells plays a key role in the resolution of CSR transactions. Mediators of general double-strand break repair are also involved in CSR and are mutated in several immunodeficiency diseases. A global picture of the mechanism of CSR is emerging and is providing new insights toward understanding the genetic events that underlie B cell cancers.

Mechanism and control of V(D)J recombination versus class switch recombination: similarities and differences

V(D)J recombination is the process by which the variable region exons encoding the antigen recognition sites of receptors expressed on B and T lymphocytes are generated during early development via somatic assembly of component gene segments. In response to antigen, somatic hypermutation (SHM) and class switch recombination (CSR) induce further modifications of immunoglobulin genes in B cells. CSR changes the IgH constant region for an alternate set that confers distinct antibody effector functions. SHM introduces mutations, at a high rate, into variable region exons, ultimately allowing affinity maturation. All of these genomic alteration processes require tight regulatory control mechanisms, both to ensure development of a normal immune system and to prevent potentially oncogenic processes, such as translocations, caused by errors in the recombination/mutation processes. In this regard, transcription of substrate sequences plays a significant role in target specificity, and transcription is mechanistically coupled to CSR and SHM. However, there are many mechanistic differences in these reactions. V(D)J recombination proceeds via precise DNA cleavage initiated by the RAG proteins at short conserved signal sequences, whereas CSR and SHM are initiated over large target regions via activation-induced cytidine deaminase (AID)-mediated DNA deamination of transcribed target DNA. Yet, new evidence suggests that AID cofactors may help provide an additional layer of specificity for both SHM and CSR. Whereas repair of RAG-induced double-strand breaks (DSBs) involves the general nonhomologous end-joining DNA repair pathway, and CSR also depends on at least some of these factors, CSR requires induction of certain general DSB response factors, whereas V(D)J recombination does not. In this review, we compare and contrast V(D)J recombination and CSR, with particular emphasis on the role of the initiating enzymes and DNA repair proteins in these processes.

ATM is required for efficient recombination between immunoglobulin switch regions

Ataxia telangiectasia mutated (ATM) kinase is critical for initiating the signaling pathways that lead to cell cycle checkpoints and DNA double strand break repair. In the absence of ATM, humans and mice show a primary immunodeficiency that includes low serum antibody titers, but the role of ATM in antigen-driven immunoglobulin gene diversification has not been defined. Here, we show that although ATM is dispensable for somatic hypermutation, it is required for efficient class switch recombination (CSR). The defect in CSR is not due to alterations in switch region transcription, accessibility, DNA damage checkpoint protein recruitment, or short-range intra-switch region recombination. Only long-range inter-switch recombination is defective, indicating an unexpected role for ATM in switch region synapsis during CSR.

Antibody class switch recombination: roles for switch sequences and mismatch repair proteins

Mechanisms and targeting of antibody class switch DNA recombination are reviewed. Particular emphasis is on the roles for the DNA sequences comprising switch (S) regions, including the S-region tandem repeats, and on the roles of proteins that are involved in both DNA mismatch repair and in class switch recombination.

H2AX is required for recombination between immunoglobulin switch regions but not for intra-switch region recombination or somatic hypermutation

Changes in chromatin structure induced by posttranslational modifications of histones are important regulators of genomic function. Phosphorylation of histone H2AX promotes DNA repair and helps maintain genomic stability. Although B cells lacking H2AX show impaired class switch recombination (CSR), the precise role of H2AX in CSR and somatic hypermutation (SHM) has not been defined. We show that H2AX is not required for SHM, suggesting that the processing of DNA lesions leading to SHM is fundamentally different from CSR. Impaired CSR in H2AX-/- B cells is not due to alterations in switch region transcription, accessibility, or aberrant joining. In the absence of H2AX, short-range intra-switch region recombination proceeds normally while long-range inter-switch region recombination is impaired. Our results suggest a role for H2AX in regulating the higher order chromatin remodeling that facilitates switch region synapsis.

The influence of transcriptional orientation on endogenous switch region function

Immunoglobulin heavy chain (IgH) class switch recombination (CSR) takes place between large switch (S) regions that precede exons of the constant region. The precise functions of the S region are controversial, although transcription of the S region targets CSR. We have tested the effects of deletion, inversion and replacement of the endogenous 12-kilobase S(gamma1) region on CSR in vivo. Here we show that S(gamma1) is required for CSR, that CSR is effected by a 1-kilobase sequence that generates a G-rich transcript, and that inversion of S(gamma1) or the G-rich sequence decreases CSR. We conclude that S(gamma1) function is dependent on orientation and lacks an absolute requirement for common S region motifs. We propose that single-stranded DNA stabilized by transcription-dependent, higher order structures is a primary substrate of CSR.

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 C(H) gene with a downstream C(H) gene. CSR is mediated by highly repetitive switch (S) region sequences and requires the activation-induced deaminase (AID). The S region 5' of the C mu gene (S mu) 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 S mu or S gamma 2b regions into a pro-B cell line that can be activated for AID expression, CSR, and endogenous S mu 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 S mu 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 switch recombination to IgG1 in DNA-PKcs-deficient B cells

To assess the role of the DNA-PKcs nonhomologous DNA end-joining (NHEJ) protein in Ig heavy chain class switch recombination (CSR), we assayed CSR ability of DNA-PKcs-deficient (DP-T) B cells generated via complementation of DP-T mice with Ig heavy chain and light chain knock-in transgenes (DP-T/HC/LC mice). DP-T/HC/LC mice were severely deficient for all serum IgH isotypes except IgM and, unexpectedly, IgG1. Upon appropriate stimulation, DP-T/HC/LC B cells showed normal proliferation, germline C(H) gene transcription, and AID induction, indicating that DNA-PKcs deficiency did not affect cellular events upstream to CSR. Yet, in vitro activated DP-T/HC/LC B cells again underwent switching only to IgG1 and, like wild-type cells, frequently underwent CSR to gamma1 on both chromosomes. We conclude that DNA-PKcs is required for CSR to most C(H) genes but that CSR to gamma1 occurs via a DNA-PKcs-independent mechanism.

The AID enzyme induces class switch recombination in fibroblasts

The switch of the immunoglobulin isotype from IgM to IgG, IgE or IgA is mediated by class switch recombination (CSR). CSR changes the immunoglobulin heavy chain constant region (CH) gene from Cmu to one of the other CH genes. Somatic hypermutation introduces massive numbers of point mutations in the immunoglobulin variable (V) region gene, giving rise to immunoglobulin with higher affinity. Activation-induced cytidine deaminase (AID), a putative RNA-editing cytidine deaminase, is expressed strictly in activated B cells and is indispensable in both CSR and somatic hypermutation. But the exact function of AID is unknown. Here we show that ectopic expression of AID induces CSR in an artificial switch construct in fibroblasts at a level comparable to that in stimulated B cells. Sequences around recombination junctions in the artificial substrate have features similar to endogenous CSR junctions. Furthermore, AID-induced CSR in fibroblasts is dependent on transcription of the target S region, as shown in endogenous CSR in B cells. The results show that AID is the only B-cell-specific factor required for initiation of the CSR reaction in the activated locus.

Activation-induced deaminase (AID)-directed hypermutation in the immunoglobulin Smu region: implication of AID involvement in a common step of class switch recombination and somatic hypermutation

Somatic hypermutation (SHM) and class switch recombination (CSR) cause distinct genetic alterations at different regions of immunoglobulin genes in B lymphocytes: point mutations in variable regions and large deletions in S regions, respectively. Yet both depend on activation-induced deaminase (AID), the function of which in the two reactions has been an enigma. Here we report that B cell stimulation which induces CSR but not SHM, leads to AID-dependent accumulation of SHM-like point mutations in the switch mu region, uncoupled with CSR. These findings strongly suggest that AID itself or a single molecule generated by RNA editing function of AID may mediate a common step of SHM and CSR, which is likely to be involved in DNA cleavage.

AID is required to initiate Nbs1/gamma-H2AX focus formation and mutations at sites of class switching

Class switch recombination (CSR) is a region-specific DNA recombination reaction that replaces one immunoglobulin heavy-chain constant region (Ch) gene with another. This enables a single variable (V) region gene to be used in conjunction with different downstream Ch genes, each having a unique biological activity. The molecular mechanisms that mediate CSR have not been defined, but activation-induced cytidine deaminase (AID), a putative RNA-editing enzyme, is required for this reaction. Here we report that the Nijmegen breakage syndrome protein (Nbs1) and phosphorylated H2A histone family member X (gamma-H2AX, also known as gamma-H2afx), which facilitate DNA double-strand break (DSB) repair, form nuclear foci at the Ch region in the G1 phase of the cell cycle in cells undergoing CSR, and that switching is impaired in H2AX-/- mice. Localization of Nbs1 and gamma-H2AX to the Igh locus during CSR is dependent on AID. In addition, AID is required for induction of switch region (S mu)-specific DNA lesions that precede CSR. These results place AID function upstream of the DNA modifications that initiate CSR.

Class switch recombination was specifically targeted to immunoglobulin (Ig)G4 or IgA in Hodgkin's disease-derived cell lines

In T cell-dependent immune responses, class switch recombination occurs in germinal centres. There is now evidence that Hodgkin/Reed-Sternberg cells are derived from germinal centre B cells. Cytokines specifically determine the direction of class switching, i.e the isotype of the new antibodies. We performed restriction analyses and polymerase chain reaction on the immunoglobulin heavy chain loci for five Hodgkin's disease-derived B-cell lines and one Hodgkin's disease-derived T-cell line in order to analyse class switch recombination. In all the B-cell lines, class switch recombination had been targeted to Calpha4 or Calpha1/2. This showed that cell-line precursors had undergone class switching, probably under the influence of TH2 or TH3 cell-derived cytokines. Deletions comprising several constant region genes were observed in cell lines L428, L1236, L591 and KMH2. Karyotype analyses of two of these revealed translocational breakpoints within the immunoglobulin heavy chain gene locus. Our data support the view that a chromosomal instability may occur during class switch recombination in Hodgkin/Reed-Sternberg cells causing chromosomal breaks. Thus, as in other germinal centre B cell-derived lymphomas, the immunoglobulin gene locus may be frequently involved in structural chromosomal aberrations in Hodgkin's disease.

The mu switch region tandem repeats are important, but not required, for antibody class switch recombination

Class switch DNA recombinations change the constant (C) region of the antibody heavy (H) chain expressed by a B cell and thereby change the antibody effector function. Unusual tandemly repeated sequence elements located upstream of H chain gene exons have long been thought to be important in the targeting and/or mechanism of the switch recombination process. We have deleted the entire switch tandem repeat element (S(mu)) from the murine (mu) H chain gene. We find that the S(mu) tandem repeats are not required for class switching in the mouse immunoglobulin H-chain locus, although the efficiency of switching is clearly reduced. Our data demonstrate that sequences outside of the S(mu) tandem repeats must be capable of directing the class switch mechanism. The maintenance of the highly repeated S(mu) element during evolution appears to reflect selection for a highly efficient switching process rather than selection for a required sequence element.

Evidence for class-specific factors in immunoglobulin isotype switching

Immunoglobulin class switch recombination (SR) occurs by a B cell-specific, intrachromosomal deletional process between switch regions. We have developed a plasmid-based transient transfection assay for SR to test for the presence of transacting switch activities. The plasmids are novel in that they lack a eukaryotic origin of DNA replication. The recombination activity of these switch substrates is restricted to a subset of B cell lines that support isotype switching on their endogenous loci and to mitogen-activated normal splenic B cells. The factors required for extrachromosomal plasmid recombination are constitutively expressed in proliferating splenic B cells and in B cell lines capable of inducibly undergoing immunoglobulin SR on their chromosomal genes. These studies suggest that mitogens that induce switching on the chromosome induce accessibility rather than switch recombinase activity. Finally, we provide evidence for two distinct switching activities which independently mediate mu-->alpha and mu-->gamma3 SR.

Normal isotype switching in B cells lacking the I mu exon splice donor site: evidence for multiple I mu-like germline transcripts

Ig class switch recombination (CSR) in activated B cells is preceded by the generation of "switch" transcripts from the heavy chain constant region (CH) genes targeted for rearrangement. Switch transcripts include a sterile "I" exon spliced onto the first CH exon. Targeted mutations disrupting the expression or splicing of I exons severely hamper CSR to all tested CH loci, except mu. However, all mu switch transcript mutations tested so far have left the I mu exon splice donor site intact. To test the possibility that the residual CSR activity in I mu mutants could be due to splicing of a truncated I mu exon, we generated new mutants specifically lacking the I mu splice donor site. Surprisingly, normal CSR was observed in the I mu splice donor mutants even in the absence of detectable spliced I mu transcripts. In a search for potential alternative sources of switch-like transcripts in the mu locus, we identified two novel exons which map just upstream of the Smu region and splice onto the C mu 1 exon. Their expression is detectable from early B cell developmental stages, and, at least in hybridomas, it does not require the Emu enhancer. These studies highlight a unique structure for the mu locus I exon region, with multiple nested switch transcript-like exons mapping upstream of Smu. We propose that all of these transcripts directly contribute to mu class switching activity.

The Ig heavy chain intronic enhancer core region is necessary and sufficient to promote efficient class switch recombination

The intronic IgH enhancer E(mu), which consists of the core enhancer (cE(mu) flanked by 5' and 3' matrix attachment regions (MAR), has been implicated in the control of IgH locus recombination and transcription. Both cE(mu) and the MAR are required to enhance transcription of an IgH transgene. To elucidate the regulatory functions of cE(mu) versus its associated MAR in IgH class switch recombination (CSR), we have assayed ES cell lines which have targeted deletions of these elements, both individually and in combination, by the Rag-2-deficient blastocyst complementation method. Mutant B cells from chimeric mice were activated in culture and the influence of the mutations on CSR was assessed by analysis of B cell hybridomas. We find that the cE(mu) is necessary and sufficient for providing the functions of E(mu) required for efficient CSR at the IgH locus. However, the 5' and 3' MAR sequences, as well as the known I(mu) transcription start sites and the bulk of I(mu) coding sequences, were dispensable for the process.

An extrachromosomal switch recombination substrate reveals kinetics and substrate requirements of switch recombination in primary murine B cells

Ig class switch recombination occurs in B lymphocytes upon activation, and is targeted to distinct switch (S) regions by cytokine-mediated induction of switch transcripts spanning the entire S region and the adjacent constant region gene segments. Using a novel type of switch recombination substrate, constructed according to the intron-exon structure of the IgH locus, but with heterologous elements, we here have tested the structural requirements for targeting and the kinetics of switch recombination in activated primary murine B cells. When transfected at various times after activation, up to 10% of the transfected B cells perform recombination of the substrate within 12 h. Switch recombination in primary B cells is restricted to the first 72 h after onset of activation, then rapidly decreases to background levels, as obtained in plasmacytoma cells or with substrates carrying no S region sequences. In terms of structural requirements, switch recombination is targeted to any transcription unit that contains an intronic S region and depends on processing of the primary transcript by splicing.

Human immunoglobulin (Ig)M+IgD+ peripheral blood B cells expressing the CD27 cell surface antigen carry somatically mutated variable region genes: CD27 as a general marker for somatically mutated (memory) B cells

Immunoglobulin (Ig)M+IgD+ B cells are generally assumed to represent antigen-inexperienced, naive B cells expressing variable (V) region genes without somatic mutations. We report here that human IgM+IgD+ peripheral blood (PB) B cells expressing the CD27 cell surface antigen carry mutated V genes, in contrast to CD27-negative IgM+IgD+ B cells. IgM+IgD+CD27(+) B cells resemble class-switched and IgM-only memory cells in terms of cell phenotype, and comprise approximately 15% of PB B lymphocytes in healthy adults. Moreover, a very small population (<1% of PB B cells) of highly mutated IgD-only B cells was detected, which likely represent the PB counterpart of IgD-only tonsillar germinal center and plasma cells. Overall, the B cell pool in the PB of adults consists of approximately 40% mutated memory B cells and 60% unmutated, naive IgD+CD27(-) B cells (including CD5(+) B cells). In the somatically mutated B cells, VH region genes carry a two- to threefold higher load of somatic mutation than rearranged Vkappa genes. This might be due to an intrinsically lower mutation rate in kappa light chain genes compared with heavy chain genes and/or result from kappa light chain gene rearrangements in GC B cells. A common feature of the somatically mutated B cell subsets is the expression of the CD27 cell surface antigen which therefore may represent a general marker for memory B cells in humans.

Efficient Recombination of a Switch Substrate Retrovector in CD40-Activated B Lymphocytes: Implications for the Control of CH Gene Switch Recombination

Maturing B lymphocytes possess a recombination activity that switches the class of heavy chain Ig. The nature of the recombination activity, its molecular requirements and regulation remain elusive questions about B lymphocyte biology and development. Class switch recombination is controlled by cytokine response elements that are required to differentially activate CH gene transcription before their subsequent recombination. Here, we show that cultures of purified murine and human B cells, stimulated only by CD40 receptor engagement, possess a potent switch recombination activity. CD40 ligand-stimulated murine and human B lymphocytes were infected with recombinant retroviruses containing Sμ and Sγ2b sequences. Chromosomally integrated switch substrate retrovectors (SSRs), harboring constitutively transcribed S sequences, underwent extensive recombinations restricted to their S sequences with structural features akin to endogenous switching. SSR recombination commenced 4 days postinfection (5 days poststimulation) with extensive switch sequence recombination over the next 2 to 3 days. In contrast, endogenous Sγ2b and Sγ1 sequences did not undergo appreciable switch recombination upon CD40 signaling alone. As expected, IL-4 induced endogenous Sμ to Sγ1 switching, while endogenous Sμ to Sγ2b fusions remained undetectable. Surprisingly, IL-4 enhanced the onset of SSR recombination in CD40-stimulated murine B cells, with S-S products appearing only 2 days postinfection and reaching a maximum within 2 to 3 days. The efficiency of switch recombination with SSRs ressembles that seen for endogenous CH class switching.

Organization of the equine immunoglobulin heavy chain constant region genes; III. Alignment of c mu, c gamma, c epsilon and c alpha genes

Previous restriction analysis of cloned equine DNA and genomic DNA of equine peripheral blood mononuclear cells had indicated the existence of one c epsilon, one c alpha and up to six c gamma genes in the haploid equine genome. The c epsilon and c alpha genes have been aligned on a 30 kb DNA fragment in the order 5' c epsilon-c alpha 3'. Here we describe the alignment of the equine c mu and c gamma genes by deletion analysis of one IgM, four IgG and two equine light chain expressing heterohybridomas. This analysis establishes the existence of six c gamma genes per haploid genome. The genomic alignment of the cH-genes is 5' c mu/(/) c gamma 1/(/) c gamma 2/(/) c gamma 3/(/) c gamma 4/(/) c gamma 5/(/) c gamma 6/(/) c epsilon-c alpha 3', naming the c gamma genes according to their position relative to c mu. For three of the c gamma genes the corresponding IgG isotypes could be identified as IgGa for c gamma 1, IgG(T) for c gamma 3 and IgGb for c gamma 4.

Developmental specificity of immunoglobulin heavy chain switch region recombination activities

To understand the regulation of enzymes that carry out immunoglobulin heavy chain class switch recombination, we have assayed recombination of extrachromosomal substrates carrying switch region sequences in cell lines representing different stages of lymphoid cell development. Both pre-B and mature B cell lines supported switch substrate recombination, but B cell lines derived from later stages of cell development did not. Recombination did not occur in an erythroid or a macrophage line. Most recombination junctions in the substrates recovered from transfection of pre-B and B cells mapped to heterogeneous sites within the S mu and Sgamma regions, as do chromosomal switch junctions. Some recombination did occur in T cell lines, but most recombination junctions involved an upstream promoter and did not map preferentially to S regions. Culture of the pre-B cell lines PD31 and 70Z/3 with LPS increased recombination two-fold, to levels approaching those observed in LPS-cultured primary B cells. These results show that the full complement of factors necessary for switch recombination is present only in cells representing a limited spectrum of B cell development and that LPS, which can activate resting splenic B cells to carry out chromosomal recombination, can also stimulate recombination activity in immortalized pre-B cell lines.

Influence of Gm allotype on the IgG subclass response to streptococcal M protein and outer membrane proteins of Moraxella catarrhalis

The IgG antibody response to streptococcal M protein is distributed between the IgG1 and IgG3 subclasses, however individual sera vary with respect to the relative amounts of these two subclasses. The basis of this variation was investigated. Sera were also analysed for IgG subclass antibodies to the outer membrane proteins (OMP) of Moraxella catarrhalis, as these have also been reported to have a major IgG3 component. The mean percentage of IgG3 was higher in the antibody response to OMP and there was less variability between sera for this antigen than was seen for M protein. Non-specific binding of IgG3 in ELISA, which has been reported for some bacterial proteins (including M protein of some serotypes) was excluded as an explanation for the apparent IgG3 bias of these antibodies. The relative amount of IgG3 antibody to the two antigens showed a positive correlation, suggesting that some individuals tended to make a greater IgG3 response to unrelated antigens. Serial bleeds from two individuals maintained a relatively constant subclass profile over several months, suggesting that time since infection did not play a major role in determining the proportion of IgG1 and IgG3. Gm allotypes for the sera were determined, and found to correlate with both total serum IgG3 concentrations and with IgG subclass composition of specific antibodies. Mean serum IgG3 concentrations were highest in sera typed as Gm(fb/fb) homozygous and lowest in sera typed as Gm(ag/ag) homozygous. Similarly, in the M protein-specific antibodies, the mean percentage of IgG3 was much lower in the Gm(ag/ag) sera than in the Gm(fb/fb) homozygous sera. Sera which typed as Gm(fb/ag) heterozygous were not significantly different from the Gm(fb/fb) homozygous sera for either total serum IgG3 or for M protein-specific IgG3. Moreover, both Gm(fb/fb) homozygous and Gm(fb/ag) heterozygous sera included samples in which IgG1 was the predominant antibody subclass and the percentage of IgG3 was very low. In contrast to the M protein-specific antibodies, for the OMP-specific antibodies there was no correlation between Gm phenotype and the proportion of IgG3. The data suggest that Gm allotype may influence the IgG subclass composition of antibody responses to bacterial surface protein, but that other factors are also likely to be involved.

A class switch control region at the 3' end of the immunoglobulin heavy chain locus

We replaced the IgH 3' enhancer (3'EH) region with a neomycin resistance gene in ES cells and generated chimeric mice in which all mature lymphocytes were either heterozygous (3'EH+/-) or homozygous (3'EH-/-) for the mutation. In vitro activated 3'EH-/- B cells responded similarly to 3'EH+/- B cells with respect to proliferation and secretion of IgM and IgG1 but were specifically deficient in IgG2a, IgG2b, IgG3, and IgE secretion. These isotype deficiencies correlated with a deficiency in accumulation of transcripts from and class switching to affected CH genes. In vivo, chimeric mice containing only 3'EH-/- B cells were deficient in serum IgG2a and IgG3. We propose that the 3'EH-/- mutation disrupts the activity of a regulatory region that influences heavy chain class switching to several different CH genes that lie as far as 100 kb upstream of the mutation.

Mu switch region deletion is associated with both T cell independent and T cell dependent responses

Isotype switching is a process by which immunoglobulin variable gene regions initially proximal to and expressed with the mu constant region gene (C mu) can rearrange downstream to other constant region genes. Thus the same antigen binding site can be expressed with each of the other constant region isotypes and perform the full panoply of effector functions. Although isotype switching is thought to involve highly reiterated 'switch site' sequences located 5' to constant region genes, the exact role of these switch sites is unknown. It has been reported that prior to switching, the 'donor' switch site 5' of C mu occasionally undergoes deletions, but it is not known whether this is an adventitious event or one which predisposes to or prevents isotype switching. Since T cell independent (TI) immune responses are dominated by IgM while T cell dependent (TD) responses are associated with switching to IgG, we have examined the state of the mu switch site in 51 IgM-producing hybridomas isolated from a variety of TI and TD responses. Although more hybridomas from the TI responses studied exhibited S mu deletions, deletion of S mu also occurred in hybridomas isolated from TD responses. Analysis of a well-characterized clonally related subset of IgM hybridomas also revealed that mu switch region deletion can be associated with the productive allele.

Independent control of immunoglobulin switch recombination at individual switch regions evidenced through Cre-loxP-mediated gene targeting

We have employed a method based on the Cre-loxP recombination system of bacteriophage P1 to generate a mouse strain in which the JH segments and the intron enhancer in the IgH locus are deleted. By analysis of immunoglobulin isotype switch recombination in heterozygous mutant B cells activated by lipopolysaccharide plus interleukin-4, we show that, on the mutant chromosome, switch recombination at the mu gene switch region is strongly suppressed, whereas the switch region of the gamma 1 gene is efficiently rearranged. These data demonstrate an independent control of switch recombination at individual switch regions and suggest that, in the process of switch recombination, the alignment of the recombining strands occurs independently of and probably after the introduction of double-strand breaks into the switch regions involved.

Evidence for a human IgG1 class switch program

In activated murine B lymphocytes, immunoglobulin class switch recombination occurs as a highly regulated process which is targeted to distinct switch regions. Here we present first evidence that in human B lymphocytes, switch recombination is targeted to distinct switch regions as well. In a panel of clonally unrelated IgG1-expressing human B cells, immortalized by Epstein-Barr virus (EBV) transformation, seven out of nine cells show switch recombination between S mu and S gamma 1 on both alleles, the active and inactive one. The remaining cells show no switch recombination on the inactive IgH locus. The very strong correlation of switch recombination on both alleles of IgG1-expressing cells proves that class switch recombination to IgG1 is not random but directed in human B lymphocytes.

DNA binding sites 5' of the IgG1 switch region comprising IL4 inducibility and B cell specificity

Immunoglobulin class switch recombination is directed to the same switch region on both chromosomes of a B cell by an as yet unknown mechanism. The cytokine interleukin 4 (IL4) targets recombination in activated B lymphocytes to the gamma 1 switch region (s gamma 1). Here we report two DNA-binding-proteins which bind to a sequence 5' of s gamma 1. One protein is B cell specific, while binding of the other one is induced by IL4. These two proteins bind to a region 700 bp upstream of the putative promoter region of the gamma 1 germline transcripts and may be involved in the process of recombination and/or transcription.

The murine IgG1/IgE class switch program

Immunoglobulin class switching is controlled by cytokines. Thus, interleukin-4 (IL-4) directs class switching to both IgG1 and IgE. Consistent with this are the results reported here on restriction endonuclease analysis of active and inactive alleles of the IgH locus in IgE-producing cells. In cells that were stimulated in vitro by lipopolysaccharide and IL-4 the silent alleles preferentially switched to gamma 1, whereas in cells that were stimulated by antigen in vivo both active and inactive alleles switched to epsilon. Thirty percent of the recombined switch regions (S mu/S epsilon) contain S gamma 1 sequences, which we interpret as footprints of a previous switch to gamma 1. Since this percentage is a minimum estimate, between 30% and 100% of switching to epsilon must occur sequentially via gamma 1.

The response of B cells in spleen, Peyer's patches, and lymph nodes to LPS and IL-4

The vast majority of B lymphocytes in the Peyer's patches (PP) and lymph nodes (LN) are memory cells or activated cells. Hence, in comparison to B lymphocytes in the spleen (SP), most B cells in these lymphoid organs have already encountered antigen. To further examine the ability of B cells in these peripheral lymphoid organs to respond to mitogens and interleukins in vitro, we have analyzed the ability of these cells (as compared to splenic B cells) to respond to LPS and LPS plus IL-4. Our results indicate that B cells from PPs and LNs proliferate poorly to LPS during the first 3 days of culture. In contrast, at later times, PP and LN B cells show enhanced proliferation as compared to splenic B cells. Furthermore, the addition of Interleukin-4 (IL-4) changes the proliferative activity of B cells from PPs and LNs, had only a minimal effect on splenic B cells. Hence, high doses of IL-4 (100 units/ml) enhance the proliferative rate of B cells from PPs and LNs early after activation, and have a suppressive effect at later times. The enhanced response of cells in PPs and LNs is further manifested by the presence of larger numbers of sIgG1+ cells 4 days after activation with LPS plus IL-4 and at 5 days these cells also secrete proportionally more IgG1 than splenic B cells. Enhanced IgG1 secretion is reflected in the methylation pattern of the s gamma 1 switch region of these cells. In cells from PP and LN cultured with LPS plus IL-4, most alleles containing the s gamma 1 region are demethylated or partly deleted, reflecting activation of this region of the Ig gene complex. In contrast, in splenic B cells, half the alleles remain in germline configuration. Our results suggest the presence of larger numbers of "preactivated" B cells in PPs and LNs as compared to spleen. These cells more rapidly secrete Ig following stimulation with LPS plus IL-4 in the absence of significant proliferation.