Nucleotide levels regulate germline proliferation through modulating GLP-1/Notch signaling in C. elegans

In this study, Chi et al. researched the link between known nutrient-sensing systems and reproductive programs. Using a model system in C. elegans, they show that a Notch signaling pathway senses the level of uridine/thymidine and controls germline proliferation, delineating a previously unknown nucleotide-sensing mechanism for controlling reproductivity.

Animals alter their reproductive programs to accommodate changes in nutrient availability, yet the connections between known nutrient-sensing systems and reproductive programs are underexplored, and whether there is a mechanism that senses nucleotide levels to coordinate germline proliferation is unknown. We established a model system in which nucleotide metabolism is perturbed in both the nematode Caenorhabditis elegans (cytidine deaminases) and its food (Escherichia coli); when fed food with a low uridine/thymidine (U/T) level, germline proliferation is arrested. We provide evidence that this impact of U/T level on the germline is critically mediated by GLP-1/Notch and MPK-1/MAPK, known to regulate germline mitotic proliferation. This germline defect is suppressed by hyperactivation of glp-1 or disruption of genes downstream from glp-1 to promote meiosis but not by activation of the IIS or TORC1 pathways. Moreover, GLP-1 expression is post-transcriptionally modulated by U/T levels. Our results reveal a previously unknown nucleotide-sensing mechanism for controlling reproductivity.

Negative supercoiling creates single-stranded patches of DNA that are substrates for AID-mediated mutagenesis

Antibody diversification necessitates targeted mutation of regions within the immunoglobulin locus by activation-induced cytidine deaminase (AID). While AID is known to act on single-stranded DNA (ssDNA), the source, structure, and distribution of these substrates in vivo remain unclear. Using the technique of in situ bisulfite treatment, we characterized these substrates—which we found to be unique to actively transcribed genes—as short ssDNA regions, that are equally distributed on both DNA strands. We found that the frequencies of these ssDNA patches act as accurate predictors of AID activity at reporter genes in hypermutating and class switching B cells as well as in Escherichia coli. Importantly, these ssDNA patches rely on transcription, and we report that transcription-induced negative supercoiling enhances both ssDNA tract formation and AID mutagenesis. In addition, RNaseH1 expression does not impact the formation of these ssDNA tracts indicating that these structures are distinct from R-loops. These data emphasize the notion that these transcription-generated ssDNA tracts are one of many in vivo substrates for AID.

Creating an effective antibody-mediated immune response relies on processes that create antibodies of high affinity and of different functions in order to clear pathogens. Activation-induced cytidine deaminase (AID) is an essential B cell–specific factor that is known to initiate these processes by deaminating dC on single-stranded DNA of actively transcribed genes. AID has also been implicated in deaminating dC at non-antibody genes, resulting in the disregulation of genes that may lead to B cell–related cancers. Until now, it has remained unknown what the source, structure, and distribution of the single-stranded DNA is that AID acts upon. By using a novel assay that allows direct detection of single-stranded DNA within intact cell nuclei, we observed patches of single-stranded DNA that are strongly correlated to the preferred activity of AID. Furthermore, we find that the activity of AID and single-stranded DNA patch formation can be enhanced by negative supercoiling of the DNA, which is a typical consequence of transcription. These findings allow us to better understand how AID is recruited to and mutates antibody genes as well as other genes implicated in cancers of B cell origin.

Detection of chromatin-associated single-stranded DNA in regions targeted for somatic hypermutation

After encounter with antigen, the antibody repertoire is shaped by somatic hypermutation (SHM), which leads to an increase in the affinity of antibodies for the antigen, and class-switch recombination (CSR), which results in a change in the effector function of antibodies. Both SHM and CSR are initiated by activation-induced cytidine deaminase (AID), which deaminates deoxycytidine to deoxyuridine in single-stranded DNA (ssDNA). The precise mechanism responsible for the formation of ssDNA in V regions undergoing SHM has yet to be experimentally established. In this study, we searched for ssDNA in mutating V regions in which DNA–protein complexes were preserved in the context of chromatin in human B cell lines and in primary mouse B cells. We found that V regions that undergo SHM were enriched in short patches of ssDNA, rather than R loops, on both the coding and noncoding strands. Detection of these patches depended on the presence of DNA-associated proteins and required active transcription. Consistent with this, we found that both DNA strands in the V region were transcribed. We conclude that regions of DNA that are targets of SHM assemble protein–DNA complexes in which ssDNA is exposed, making it accessible to AID.

A role for Mlh3 in somatic hypermutation

Somatic hypermutation (SHM) and class switch recombination (CSR) allow B cells to make high affinity antibodies of various isotypes. Both processes are initiated by activation-induced cytidine deaminase (AID) to generate dG:dU mismatches in the immunoglobulin genes that are resolved differently in SHM and CSR to introduce point mutations and recombination, respectively. The MutL homolog MLH3 has been implicated in meiosis and DNA mismatch repair (MMR). Since it interacts with MLH1, which plays a role in SHM and CSR, we examined these processes in Mlh3-deficient mice. Although deficiencies in other MMR proteins result in defects in SHM, Mlh3(-/-) mice exhibited an increased frequency of mutations in their immunoglobulin variable regions, compared to wild type littermates. Alterations of mutation spectra were observed in the Jh4 flanking region in Mlh3(-/-) mice. Nevertheless, Mlh3(-/-) mice were able to switch to IgG3 or IgG1 with similar frequencies to control mice. This is the first instance where a loss of a DNA repair protein has a positive impact on the rate of SHM, suggesting that Mlh3 normally inhibits the accumulation of mutations in SHM.

Complex regulation of somatic hypermutation by cis-acting sequences in the endogenous IgH gene in hybridoma cells

To create high-affinity antibodies, B cells target a high rate of somatic hypermutation (SHM) to the Ig variable-region genes that encode the antigen-binding site. This mutational process requires transcription and is triggered by activation-induced cytidine deaminase (AID), which converts deoxycytidine to deoxyuridine. Mistargeting of AID to non-Ig genes is thought to result in the malignant transformation of B cells, but the mechanism responsible for targeting SHM to certain DNA regions and not to others is largely unknown. Cis-acting elements have been proposed to play a role in directing the hypermutation machinery, but the motifs required for targeting SHM have been difficult to identify because many of the candidate elements, such as promoters or enhancers, are also required for transcription of Ig genes. Here we describe a system in cultured hybridoma cells in which transcription of the endogenous heavy-chain Ig gene continues in the absence of the core intronic enhancer (Emu) and its flanking matrix attachment regions (MARs). When AID is expressed in these cells, SHM occurred at the WT frequency even when Emu and the MARs were absent together. Interestingly, SHM occurred at less than the WT frequency when Emu or the MARs were individually absent. Our results suggest that these intronic regulatory elements can exert a complex influence on SHM that is separable from their role in regulating transcription.

The epigenetic stability of the locus control region-deficient IgH locus in mouse hybridoma cells is a clonally varying, heritable feature

Cis-acting elements such as enhancers and locus control regions (LCRs) prevent silencing of gene expression. We have shown previously that targeted deletion of an LCR in the immunoglobulin heavy-chain (IgH) locus creates conditions in which the immunoglobulin micro heavy chain gene can exist in either of two epigenetically inherited states, one in which micro expression is positive and one in which micro expression is negative, and that the positive and negative states are maintained by a cis-acting mechanism. As described here, the stability of these states, i.e., the propensity of a cell to switch from one state to the other, varied among subclones and was an inherited, clonal feature. A similar variation in stability was seen for IgH loci that both lacked and retained the matrix attachment regions associated with the LCR. Our analysis of cell hybrids formed by fusing cells in which the micro expression had different stabilities indicated that stability was also determined by a cis-acting feature of the IgH locus. Our results thus show that a single-copy gene in the same chromosomal location and in the presence of the same transcription factors can exist in many different states of expression.

Examination of Msh6- and Msh3-deficient mice in class switching reveals overlapping and distinct roles of MutS homologues in antibody diversification

Somatic hypermutation and class switch recombination (CSR) contribute to the somatic diversification of antibodies. It has been shown that MutS homologue (Msh)6 (in conjunction with Msh2) but not Msh3 is involved in generating A/T base substitutions in somatic hypermutation. However, their roles in CSR have not yet been reported. Here we show that Msh6^−/− mice have a decrease in CSR, whereas Msh3^−/− mice do not. When switch regions were analyzed for mutations, deficiency in Msh6 was associated with an increase in transition mutations at G/C basepairs, mutations at RGYW/WRCY hotspots, and a small increase in the targeting of G/C bases. In addition, Msh6^−/− mice exhibited an increase in the targeting of recombination sites to GAGCT/GGGGT consensus repeats and hotspots in Sγ3 but not in Sμ. In contrast to Msh2^−/− mice, deficiency in Msh6 surprisingly did not change the characteristics of Sμ-Sγ3 switch junctions. However, Msh6^−/− mice exhibited a change in the positioning of Sμ and Sγ3 junctions. Although none of these changes were seen in Msh3^−/− mice, they had a higher percentage of large inserts in their switch junctions. Together, our data suggest that MutS homologues Msh2, Msh3, and Msh6 play overlapping and distinct roles during antibody diversification processes.

The role of activation-induced cytidine deaminase in antibody diversification, immunodeficiency, and B-cell malignancies

Before exposure to antigen, antibodies with a wide diversity of antigen-binding sites are created by V(D)J rearrangement. After exposure to antigen, further diversification is accomplished by means of somatic hypermutation of the antibody variable region genes and class-switch recombination between the heavy-chain mu constant region and the downstream gamma, epsilon, and alpha constant region. The variable region mutations are responsible for the affinity maturation of the antibody response, whereas class-switch recombination enables the antibodies to be distributed throughout the body and to carry out different effector functions. Both somatic mutation and class switching require an enzyme called activation-induced cytidine deaminase (AID) that converts deoxycytidines to deoxyuracils on single-stranded DNA. Genetic defects of AID in human subjects result in hyper-IgM syndrome type 2. The analysis of both mutant mice and immunodeficient patients has led to a better understanding of the mechanism of action and role of AID in immunity, as well as in the malignant transformation of B cells.

Use of a simple, general targeting vector for replacing the DNA of the heavy chain constant region in mouse hybridoma cells

It is often necessary to modify the constant region of the immunoglobulin (Ig) heavy chain in order to produce Ig with optimal properties. In the case of Ig production by mouse hybridoma cells, it is possible to modify the Ig heavy chain (IgH) locus by gene targeting to achieve the desired changes. DNA segments from the JH-S micro region and from the region 3' of Calpha are normally present in the functional IgH gene of all hybridomas, regardless of the heavy chain class which is expressed. Consequently, these DNA segments could in principle serve as 5' and 3' homology regions to create a "universal" targeting vector for replacing the constant region exons in the IgH locus of any hybridoma cell. The practicality of this vector design has been uncertain. That is, the extent of the chromosomal DNA which would be replaced by a universal targeting vector would be as little as 5 kb (in a cell producing the alpha heavy chain) and as much as 180 kb (in a micro -producing cell), and it has been uncertain whether it would be practical to generate such long chromosomal deletions by gene targeting. Using a vector of this design, we found (a) that correctly targeted recombinant cells lacking the 180 kb DNA segment occurred at a low but usable frequency, (b) that these recombinants expressed the modified IgH locus at the same rate as the original hybridoma and (c) that IgH expression in these cell lines was stable. Our results thus indicate that this vector design is suitable for modifying IgH loci expressing any heavy chain, provided that an efficient selection or screening for targeted recombinants is available.

Positive and negative transcriptional states of a variegating immunoglobulin heavy chain (IgH) locus are maintained by a cis-acting epigenetic mechanism

Analyses of transgene expression have defined essential components of a locus control region (LCR) in the J(H)-C(mu) intron of the IgH locus. Targeted deletion of this LCR from the endogenous IgH locus of hybridoma cells results in variegated expression, i.e., cells can exist in two epigenetically inherited states in which the Ig(mu) H chain gene is either active or silent; the active or silent state is typically transmitted to progeny cells through many cell divisions. In principle, cells in the two states might differ either in their content of specific transcription factors or in a cis-acting feature of the IgH locus. To distinguish between these mechanisms, we generated LCR-deficient, recombinant cell lines in which the Ig(mu) H chain genes were distinguished by a silent mutation and fused cells in which the mu gene was active with cells in which mu was silent. Our analysis showed that both parental active and silent transcriptional states were preserved in the hybrid cell, i.e., that two alleles of the same gene in the same nucleus can exist in two different states of expression through many cell divisions. These results indicate that the expression of the LCR-deficient IgH locus is not fully determined by the cellular complement of transcription factors, but is also subject to a cis-acting, self-propagating, epigenetic mark. The methylation inhibitor, 5-azacytidine, reactivated IgH in cells in which this gene was silent, suggesting that methylation is part of the epigenetic mark that distinguishes silent from active transcriptional states.

Variegated expression of the endogenous immunoglobulin heavy-chain gene in the absence of the intronic locus control region

The expression of chromosomally integrated transgenes usually varies greatly among independent transfectants. This variability in transgene expression has led to the definition of locus control regions (LCRs) as elements which render expression consistent. Analyses of expression in single cells revealed that the expression of transgenes which lack an LCR is often variegated, i.e., on in some cells and off in others. In many cases, transgenes which show variegated expression were found to have inserted near the centromere. These observations have suggested that the LCR prevents variegation by blocking the inhibitory effect of heterochromatin and other repetitive-DNA-containing structures at the insertion site and have raised the question of whether the LCR plays a similar role in endogenous genes. To address this question, we have examined the effects of deleting the LCR from the immunoglobulin heavy-chain locus of a mouse hybridoma cell line in which expression of the immunoglobulin mu heavy-chain gene is normally highly stable. Our analysis of mu expression in single cells shows that deletion of this LCR resulted in variegated expression of the mu gene. That is, in the absence of the LCR, expression of the mu gene in the recombinant locus could be found in either of two epigenetically maintained, metastable states, in which transcription occurred either at the normal rate or not at all. In the absence of the LCR, the on state had a half-life of approximately 100 cell divisions, while the half-life of the off state was approximately 40,000 cell divisions. For recombinants with an intact LCR, the half-life of the on state exceeded 50,000 cell divisions. Our results thus indicate that the LCR increased the stability of the on state by at least 500-fold.

Role of the intronic elements in the endogenous immunoglobulin heavy chain locus. Either the matrix attachment regions or the core enhancer is sufficient to maintain expression

High level expression in mice of transgenes derived from the immunoglobulin heavy chain (IgH) locus requires both the core enhancer (Emu) and the matrix attachment regions (MARs) that flank Emu. The need for both elements implies that they each perform a different function in transcription. While it is generally assumed that expression of the endogenous IgH locus has similar requirements, it has been difficult to assess the role of these elements in expression of the endogenous heavy chain gene, because B cell development and IgH expression are strongly interdependent and also because the locus contains other redundant activating elements. We have previously described a gene-targeting approach in hybridoma cells that overcomes the redundancy problem to yield a stable cell line in which expression of the IgH locus depends strongly on elements in the MAR-Emu-MAR segment. Using this system, we have found that expression of the endogenous mu gene persists at substantially (approximately 50%) normal levels in recombinants which retain either the MARs or Emu. That is, despite the dissimilar biochemical activities of these two elements, either one is sufficient to maintain high level expression of the endogenous locus. These findings suggest new models for how the enhancer and MARs might collaborate in the initiation or maintenance of transcription.