Expression of an anti-RNA autoantibody in a mouse model of SLE increases neutrophil and monocyte numbers as well as IFN-I expression.

Systemic lupus erythematosus (SLE) is an autoimmune disease characterized by the presence of antinucleic acid autoantibodies, high levels of circulating type I interferon (IFN-I), and an IFN-I-dependent elevated expression of activating FcγR. Increases in neutrophils and monocytes are often observed in clinical SLE, but how these contribute to autoantibody and IFN-I production is poorly understood. Here, we analyzed SLE pathogenesis in 564Igi mice, an SLE-model strain carrying gene-targeted heavy and light chain antibody genes encoding an anti-RNA autoantibody in a C57BL/6 background. Similar to human SLE patients, 564Igi mice produce anti-RNA autoantibodies and expanded neutrophil and monocyte populations. These myeloid cells produced IFN-I and exhibit increased FcγRIV expression induced via an IFN-I autocrine loop. A direct effect of IFN-I on 56 Igi BM B cells and neutrophils was supported by their upregulation of "IFN-I signature genes". In addition, 564Igi developing B cells showed upregulated TLR7 resulting in IgG2a/2b class switch recombination and autoantibody production. Our results indicate that the production of anti-RNA autoantibody is sufficient to induce an increase of BM, blood, and spleen IFN-I-producing neutrophils, and suggest a mechanism by which autoantibody and IFN-I contribute to SLE by activating B lymphocytes, neutrophils, and monocyte effector cells in vivo.

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.

Translocation of an antibody transgene requires AID and occurs by interchromosomal switching to all switch regions except the mu switch region.

Immunoglobulin (Ig) class switch recombination (CSR) occurs most often by intrachromosomal recombinations between switch (S) regions located on a single chromosome, but it can also occur by interchomosomal recombinations between Ig heavy chain (Igh) S regions located on chomosomal homologs. Interchromosomal recombinations have also been found between chromosomes that are not homologs; examples are Igh/c-myc and Igh/transgene translocations. Most, but not all, studies have indicated that activation-induced cytidine deaminase (AID) is important in Igh/c-myc translocations. The role of AID has not been determined for Igh/transgene translocations. We now show that the majority of Igh/transgene translocations between non-homologs from an Ig transgenic mouse are dependent on AID, but we also find a small number of these translocations that can occur in the absence of AID. Surprisingly, our results also indicate that, although Sγ switch sequences in the endogenous Igh locus participate in chromosomal translocations with the non-homolog transgene-bearing chromosome, Sµ switch sequences do not. This contrasts with the fact that both endogenous Sµ and Sγ sequences participate in intrachromosomal CSR. Our findings suggest the operation of a regulatory mechanism that can differentially control the accessibility of Sµ and Sγ regions for non-homolog translocations even when both are accessible for intrachromosomal recombination.

Shifts in targeting of class switch recombination sites in mice that lack mu switch region tandem repeats or Msh2.

The mechanisms that target class switch recombination (CSR) to antibody gene switch (S) regions are unknown. Analyses of switch site locations in wild-type mice and in mice that lack the Smu tandem repeats show shifts indicating that a 4-5-kb DNA domain (bounded upstream by the Imu promoter) is accessible for switching independent of Smu sequences. This CSR-accessible domain is reminiscent of the promoter-defined domains that target somatic hypermutation. Within the 4-5-kb CSR domain, the targeting of S site locations also depends on the Msh2 mismatch repair protein because Msh2-deficient mice show an increased focus of sites to the Smu tandem repeat region. We propose that Msh2 affects S site location because sequences with few activation-induced cytidine deaminase targets generate mostly switch DNA cleavages that require Msh2-directed processing to allow CSR joining.

Class switch recombination efficiency and junction microhomology patterns in Msh2-, Mlh1-, and Exo1-deficient mice depend on the presence of mu switch region tandem repeats.

The Msh2 mismatch repair (MMR) protein is critical for class switch recombination (CSR) events that occur in mice that lack the Smu tandem repeat (SmuTR) region (SmuTR(-/-) mice). The pattern of microhomology among switch junction sites in Msh2-deficient mice is also dependent on the presence or absence of SmuTR sequences. It is not known whether these CSR effects reflect an individual function of Msh2 or the function of Msh2 within the MMR machinery. In the absence of the SmuTR sequences, Msh2 deficiency nearly ablates CSR. We now show that Mlh1 or Exo1 deficiencies also eliminate CSR in the absence of the SmuTR. Furthermore, in SmuTR(-/-) mice, deficiencies of Mlh1 or Exo1 result in increased switch junction microhomology as has also been seen with Msh2 deficiency. These results are consistent with a CSR model in which the MMR machinery is important in processing DNA nicks to produce double-stranded breaks, particularly in sequences where nicks are infrequent. We propose that double-stranded break paucity in MMR-deficient mice leads to increased use of an alternative joining pathway where microhomologies are important for CSR break ligation. Interestingly, when the SmuTR region is present, deficiency of Msh2 does not lead to the increased microhomology seen with Mlh1 or Exo1 deficiencies, suggesting that Msh2 might have an additional function in CSR. It is also possible that the inability to initiate MMR in the absence of Msh2 results in CSR junctions with less microhomology than joinings that occur when MMR is initiated but then proceeds abnormally due to Mlh1 or Exo1 deficiencies.

Sequence dependence of chromosomal R-loops at the immunoglobulin heavy-chain Smu class switch region.

The mechanism by which the cytidine deaminase activation-induced deaminase (AID) acts at immunoglobulin heavy-chain class switch regions during mammalian class switch recombination (CSR) remains unclear. R-loops have been proposed as a basis for this targeting. Here, we show that the difference between various forms of the Smu locus that can or cannot undergo CSR correlates well with the locations and detectability of R-loops. The Smu R-loops can initiate hundreds of base pairs upstream of the core repeat switch regions, and the area where the R-loops initiate corresponds to the zone where the AID mutation frequency begins to rise, despite a constant density of WRC sites in this region. The frequency of R-loops is 1 in 25 alleles, regardless of the presence of the core Smu repeats, again consistent with the initiation of most R-loops upstream of the core repeats. These findings explain the surprisingly high levels of residual CSR in B cells from mice lacking the core Smu repeats but the marked reduction in CSR in mice with deletions of the region upstream of the core Smu repeats. These studies also provide the first analysis of how R-loop formation in the eukaryotic chromosome depends on the DNA sequence.

Ig class switching: targeting the recombinational mechanism.

Recent studies have provided insights into the mechanisms involved in targeting antibody gene class switch recombination (CSR) to various switch DNA regions located upstream of constant region genes. Targeting appears to involve sequence motifs that are favored for deoxycytosine deamination by the activation-induced deaminase enzyme that is required for CSR, together with transcription (and in some cases R-loop formation) to provide the single-stranded DNA needed for activation-induced deaminase activity. There is also another poorly understood mechanism that limits CSR to a specific length of DNA downstream of the switch-region transcriptional promoter.

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.

Accelerated Systemic Autoimmunity in the Absence of Somatic Hypermutation in 564Igi: A Mouse Model of Systemic Lupus with Knocked-In Heavy and Light Chain Genes.

564Igi mice have knocked-in immunoglobulin (Ig) heavy (H) and light (L) chain genes that encode an autoantibody recognizing RNA. Previously, we showed that these mice produce pathogenic IgG autoantibodies when activation-induced deaminase (AID) is expressed in pre-B and immature B cells but not when it is expressed only in mature B cells. AID has two functions; it is necessary for somatic hypermutation (SHM) and class switch recombination (CSR). To determine the role of each of these functions in the generation of pathogenic autoantibodies, we generated 564Igi mice that carry a mutant AID-encoding gene, Aicda (AicdaG23S), which is capable of promoting CSR but not SHM. We found that 564Igi AicdaG23S mice secreted class-switched antibodies (Abs) at levels approximately equal to 564Igi mice. However, compared to 564Igi mice, 564Igi Aicda G23S mice had increased pathogenic IgG Abs and severe systemic lupus erythematosus-like disease, including, glomerulonephritis, and early death. We suggest that in 564Igi mice SHM by AID changes Ig receptors away from self reactivity, thereby mitigating the production of autoantibody, providing a novel mechanism of tolerance.

Mice lacking Sµ tandem repeats maintain RNA polymerase patterns but exhibit histone modification pattern shifts linked to class switch site locations.

Antibody switching involves class switch recombination (CSR) events between switch (S) regions located upstream of heavy chain constant (C) genes. Mechanisms targeting CSR to S-regions are not clear. Deletion of Sµ tandem repeat (SµTR) sequences causes CSR to shift into downstream regions that do not undergo CSR in WT B-cells, including the Cµ-region. We now find that, in SµTR(-/-) B cells, Sµ chromatin histone modification patterns also shift downstream relative to WT and coincide with SµTR(-/-) CSR locations. Our results suggest that histone H3 acetylation and methylation are involved in accessibility of switch regions and that these modifications are not dependent on the underlying sequence, but may be controlled by the location of upstream promoter or regulatory elements. Our studies also show RNA polymerase II (RNAPII) loading increases in the Eµ/Iµ region in stimulated B cells; these increases are independent of SµTR sequences. Longer Sµ deletions have been reported to eliminate increases in RNAPII density, therefore we suggest that sequences between Iµ and Sµ (possibly the Iµ splicing region as well as G-tracts that are involved in stable RNA:DNA complex formation during transcription) might control the RNAPII density increases.

p21 is dispensable for AID-mediated class switch recombination and mutagenesis of immunoglobulin genes during somatic hypermutation.

In B cells, activation-induced cytidine deaminase (AID) induces somatic hypermutation (SHM) at rearranged immunoglobulin (Ig) variable (V) regions. Previous studies have shown that both monoubiquitination of proliferating cell nuclear antigen (PCNA) and translesional DNA polymerase activity are important for inducing mutagenesis during SHM. Regulation of PCNA ubiquitination by p21, also known as Cdkn1a and p21(Cip1/Waf1), is an important mechanism that controls mutation loads in mammalian cells. In this study, we have assessed whether p21 has an in vivo function in regulating mutagenesis in B cells by analyzing SHM frequency in p21-deficient mice. Our results show that p21 is dispensable for SHM. This suggests that, during SHM of Ig genes, p21 does not act to regulate mutagenesis load. We also show that p21 transcript levels are the same in both wildtype and AID-deficient B cells during B cell activation, and that AID-mediated class switch recombination (CSR) is not affected by p21 deficiency; thereby indicating that p21 regulation in B cells is not altered by AID-induced DNA damage and that p21 has no affect on AID-dependent Ig gene diversification. Our results suggest that regulation of p21 in activated B cells is probably more important for maintaining proper cell cycle progression as opposed to promoting SHM of Ig genes.

Activation-induced cytidine deaminase-dependent DNA breaks in class switch recombination occur during G1 phase of the cell cycle and depend upon mismatch repair.

Ab class switching occurs by an intrachromosomal recombination and requires generation of double-strand breaks (DSBs) in Ig switch (S) regions. Activation-induced cytidine deaminase (AID) converts cytosines in S regions to uracils, which are excised by uracil DNA glycosylase (UNG). Repair of the resulting abasic sites would yield single-strand breaks (SSBs), but how these SSBs are converted to DSBs is unclear. In mouse splenic B cells, we find that AID-dependent DSBs occur in Smu mainly in the G(1) phase of the cell cycle, indicating they are not created by replication across SSBs. Also, G(1) phase cells express AID, UNG, and mismatch repair (MMR) proteins and possess UNG activity. We find fewer S region DSBs in MMR-deficient B cells than in wild-type B cells, and still fewer in MMR-deficient/SmuTR(-/-) B cells, where targets for AID are sparse. These DSBs occur predominantly at AID targets. We also show that nucleotide excision repair does not contribute to class switching. Our data support the hypothesis that MMR is required to convert SSBs into DSBs when SSBs on opposite strands are too distal to form DSBs spontaneously.

Class switch recombination and somatic hypermutation in early mouse B cells are mediated by B cell and Toll-like receptors.

Activation-induced cytidine deaminase (AID) is required for immunoglobulin (Ig) gene class switch recombination (CSR), somatic hypermutation (SHM), and somatic hyperconversion. In general, high AID expression is found in mature B cells that are responding to antigens. However, AID expression and SHM have also been detected in developing B cells from transgenic mice that have a limited Ig repertoire. Here we demonstrate that AID expression, ongoing CSR, and active SHM occur in developing B cells from wild-type mice. Further, our results suggest that somatic variants arising from developing B cells in the bone marrow further diversify in the spleen of unimmunized mice. AID expression in developing B cells is T cell independent but involves engagement of B cell receptors and Toll-like receptors. Early AID expression can increase the preimmune repertoire of developing B cells, may provide an innate population of IgG- and IgA-expressing cells, and could be involved in receptor editing of self-reactive immature B cells.

S-S synapsis during class switch recombination is promoted by distantly located transcriptional elements and activation-induced deaminase.

Molecular mechanisms underlying synapsis of activation-induced deaminase (AID)-targeted S regions during class switch recombination (CSR) are poorly understood. By using chromosome conformation capture techniques, we found that in B cells, the Emicro and 3'Ealpha enhancers were in close spatial proximity, forming a unique chromosomal loop configuration. B cell activation led to recruitment of the germline transcript (GLT) promoters to the Emicro:3'Ealpha complex in a cytokine-dependent fashion. This structure facilitated S-S synapsis because Smicro was proximal to Emicro and a downstream S region was corecruited with the targeted GLT promoter to Emicro:3'Ealpha. We propose that GLT promoter association with the Emicro:3'Ealpha complex creates an architectural scaffolding that promotes S-S synapsis during CSR and that these interactions are stabilized by AID. Thus, the S-S synaptosome is formed as a result of the self-organizing transcription system that regulates GLT expression and may serve to guard against spurious chromosomal translocations.

Sequence transfers between variable regions in a mouse antibody transgene can occur by gene conversion.

Different vertebrate species show widely differing usage of somatic hyperconversion (SHC) as a mechanism for diversifying expressed Ab V genes. The basis for the differing levels of SHC in different species is not known. Although no clear evidence for SHC has been found in normal mouse B cells, transgenic mice carrying high-copy numbers of a gene construct designed to optimize detection of SHC have previously been shown to exhibit sequence transfers that resemble gene conversion events. However, these transgene sequence transfers could reflect multistep or reciprocal DNA recombination events rather than gene conversions. We now find in low-copy number transgenic mice that transgene sequence transfers can exhibit the unidirectional sequence information movement that is a hallmark of gene conversion. This indicates that gene conversion between V region sequences can occur in mouse B cells; we propose that the lack of efficient SHC contributions to Ab diversification in normal mice may be due, at least in part, to the particular pattern of V gene recombinational accessibility that occurs in differentiating mouse B cells.

Gene conversion-like sequence transfers in a mouse antibody transgene: antigen selection allows sensitive detection of V region interactions based on homology.

Gene conversion is important for antibody diversification in chickens, rabbits and cows. In mice, however, conversion events appear to be infrequent among endogenous antibody genes. DNA sequence transfer events that resemble gene conversions have been reported for a mouse H chain transgene (VVC(mu)) that contains two closely spaced homologous VDJ segments. Surprisingly, these reported VVC(mu) sequence transfers were found frequently among mouse B cells responding to immunization. Transgene sequence transfers could be occurring at high frequency in responding VVC(mu) B cells or could be occurring at lower frequency with subsequent amplification by preferential antigen selection. To distinguish these possibilities, we have analyzed a second transgene (InVVC(mu)) that is identical to VVC(mu) except that the two VDJ regions have been exchanged in position. We find that transgene sequence transfers are much less frequent among responding B cells in InVVC(mu) mice, demonstrating the importance of selection in the frequent transgene conversions observed in VVC(mu) mice. These results suggest that mice, like other species, can use gene conversion to diversify antibodies. Such diversification events are apparently infrequent, however, and might only be detected among endogenous Ig genes with a favorable arrangement of V genes and an antigenic stimulation that selects cells with conversions. For both VVC(mu) and InVVC(mu) mice, conversion-like sequence transfers are strongly correlated with somatic hypermutation. Based on these results, we hypothesize that, in mice, gene conversions represent infrequent alternative reactions of a homology-based DNA repair process that is central in the somatic hypermutational mechanism.

Gene conversion-like sequence transfers between transgenic antibody V genes are independent of RAD54.

Homology-based Ig gene conversion is a major mechanism for Ab diversification in chickens and the Rad54 DNA repair protein plays an important role in this process. In mice, although gene conversion appears to be rare among endogenous Ig genes, Ab H chain transgenes undergo isotype switching and gene conversion-like sequence transfer processes that also appear to involve homologous recombination or gene conversion. Furthermore, homology-based DNA repair has been suggested to be important for somatic mutation of endogenous mouse Ig genes. To assess the role of Rad54 in these mouse B cell processes, we have analyzed H chain transgene isotype switching, sequence transfer, and somatic hypermutation in mice that lack RAD54. We find that Rad54 is not required for either transgene switching or transgene hypermutation. Furthermore, even transgene sequence transfers that are known to require homology-based recombinations are Rad54 independent. These results indicate that mouse B cells must use factors for promoting homologous recombination that are distinct from the Rad54 proteins important in homology-based chicken Ab gene recombinations. Our findings also suggest that mouse H chain transgene sequence transfers might be more closely related to an error-prone homology-based somatic hypermutational mechanism than to the hyperconversion mechanism that operates in chicken B cells.

The Smu tandem repeat region is critical for Ig isotype switching in the absence of Msh2.

Deficiencies of the Msh2 protein or the Smu tandem repeat (SmuTR) sequences each reduce isotype switching in mice by about 2- to 3-fold. We find that switching in mice deficient for both Msh2 and SmuTR is nearly ablated. We propose that the SmuTR provides closely spaced cleavage sites that can undergo switch recombination independent of Msh2, whereas cleavages in sequences flanking the SmuTR require Msh2 processing to allow recombinational joining. We also find that changes in Smu sequences alter the focus of switch junctions within Sgamma sequences, indicating that sequences of switch regions act together in the choice of switch recombination junctions. These findings help to explain the conservation of tandemly repeated switch regions associated with heavy chain constant genes in species capable of switching.