Identification of Ssm1b, a novel modifier of DNA methylation, and its expression during mouse embryogenesis.

The strain-specific modifier Ssm1 is responsible for the strain-dependent methylation of particular E. coli gpt-containing transgenic sequences. Here, we identify Ssm1 as the KRAB-zinc finger (ZF) gene 2610305D13Rik located on distal chromosome 4. Ssm1b is a member of a gene family with an unusual array of three ZFs. Ssm1 family members in C57BL/6 (B6) and DBA/2 (D2) mice have various amino acid changes in their ZF domain and in the linker between the KRAB and ZF domains. Ssm1b is expressed up to E8.5; its target transgene gains partial methylation by this stage as well. At E9.5, Ssm1b mRNA is no longer expressed but by then its target has become completely methylated. By contrast, in D2 embryos the transgene is essentially unmethylated. Methylation during B6 embryonic development depends on Dnmt3b but not Mecp2. In differentiating B6 embryonic stem cells methylation spreads from gpt to a co-integrated neo gene that has a similarly high CpG content as gpt, but neo alone is not methylated. In adult B6 mice, Ssm1b is expressed in ovaries, but in other organs only other members of the Ssm1 family are expressed. Interestingly, the transgene becomes methylated when crossed into some, but not other, wild mice that were kept outbred in the laboratory. Thus, polymorphisms for the methylation patterns seen among laboratory inbred strains are also found in a free-living population. This may imply that mice that do not have the Ssm1b gene may use another member of the Ssm1 family to control the potentially harmful expression of certain endogenous or exogenous genes.

Ssm1b expression and function in germ cells of adult mice and in early embryos.

Ssm1b (Strain-specific modifier of DNA methylation 1b) is a Krüppel-associated box (KRAB) zinc finger gene that promotes CpG methylation in the mouse transgene HRD (Heavy chain enhancer, rearrangement by deletion). We report here that Ssm1b expression and concomitant HRD methylation are also present in the male and female germ cells of adult mice. Ssm1b is expressed in both diploid (2N) and haploid (1N) oocytes, as well as in 1N spermatids and spermatozoa, but not in 2N spermatogonia. Interestingly, Ssm1b mRNA is not detected in any other adult mouse organ examined, although Ssm1-family mRNAs are highly expressed in the heart. Reflecting strain specificity, Ssm1b expression and HRD methylation are not observed in early-stage C3H/HeJ mouse embryos; however, an Ssm1b-like gene that closely resembles an Ssm1b-like gene previously found in wild-derived mice is expressed in cultured embryonic stem cells derived from C3H/HeJ embryos, suggesting that culture conditions affect its expression. Collectively, this work demonstrates that HRD methylation by Ssm1b is more temporally restricted during spermatogenesis compared to oogenesis, and is altered when embryonic stem cells are cultured from C3H/HeJ inner cell mass cells.

Preimplantation expression of the somatic form of Dnmt1 suggests a role in the inheritance of genomic imprints.

BACKGROUND: Identical DNA methylation differences between maternal and paternal alleles in gametes and adults suggest that the inheritance of genomic imprints is strictly due to the embryonic maintenance of DNA methylation. Such maintenance would occur in association with every cycle of DNA replication, including those of preimplantation embryos. RESULTS: The expression of the somatic form of the Dnmt1 cytosine methyltransferase (Dnmt1s) was examined in cleavage-stage preimplantation mouse embryos. Low concentrations of Dnmt1s are found in 1-, 2-, 4-, and 8-cell embryos, as well as in morulae and blastocysts. Dnmt1s is present in the cytoplasm at all stages, and in the nuclei of all stages except the 1-cell, pronuclear-stage embryo. The related oocyte-derived Dnmt1o protein is also present in nuclei of 8-cell embryos, along with embryo-synthesized Dnmt1s. Dnmt1s protein expressed in 1-cell and 2-cell embryos is derived from the oocyte, whereas the embryo synthesizes its own Dnmt1s from the 2-cell stage onward. CONCLUSION: These observations suggest that Dnmt1s provides maintenance methyltransferase activity for the inheritance of methylation imprints in the early mouse embryo. Moreover, the ability of Dnmt1o and Dnmt1s proteins synthesized at the same time to substitute for one another's maintenance function, but the lack of functional interchange between oocyte- and embryo-synthesized Dnmt1 proteins, suggests that the developmental source is the critical determinant of Dnmt1 function during preimplantation development.

Targeting of the activation-induced cytosine deaminase is strongly influenced by the sequence and structure of the targeted DNA.

Activation-induced deaminase (AID) initiates immunoglobulin somatic hypermutation (SHM). Since in vitro AID was shown to deaminate cytosines on single-stranded DNA or the nontranscribed strand, it remained a puzzle how in vivo AID targets both DNA strands equally. Here we investigate the roles of transcription and DNA sequence in cytosine deamination. Strikingly different results are found with different substrates. Depending on the target sequence, the transcribed DNA strand is targeted as well as or better than the nontranscribed strand. The preferential targeting is not related to the frequency of AID hot spots. Comparison of cytosine deamination by AID and bisulfite shows different targeting patterns suggesting that AID may locally unwind the DNA. We conclude that somatic hypermutation on both DNA strands is the natural outcome of AID action on a transcribed gene; furthermore, the DNA sequence or structure and topology play major roles in targeting AID in vitro and in vivo. On the other hand, the lack of mutations in the first approximately 100 nucleotides and beyond about 1 to 2 kb from the promoter of immunoglobulin genes during SHM must be due to special conditions of transcription and chromatin in vivo.

DNA methylation precedes chromatin modifications under the influence of the strain-specific modifier Ssm1.

Ssm1 is responsible for the mouse strain-specific DNA methylation of the transgene HRD. In adult mice of the C57BL/6 (B6) strain, the transgene is methylated at essentially all CpGs. However, when the transgene is bred into the DBA/2 (D2) strain, it is almost completely unmethylated. Strain-specific methylation arises during differentiation of embryonic stem (ES) cells. Here we show that Ssm1 causes striking chromatin changes during the development of the early embryo in both strains. In undifferentiated ES cells of both strains, the transgene is in a chromatin state between active and inactive. These states are still observed 1 week after beginning ES cell differentiation. However, 4 weeks after initiating differentiation, in B6, the transgene has become heterochromatic, and in D2, the transgene has become euchromatic. HRD is always expressed in D2, but in B6, it is expressed only in early embryos. The transgene is already more methylated in B6 ES cells than in D2 ES cells and becomes increasingly methylated during development in B6, until essentially all CpGs in the critical guanosine phosphoribosyl transferase core are methylated. Clearly, DNA methylation of HRD precedes chromatin compaction and loss of expression, suggesting that the B6 form of Ssm1 interacts with DNA to cause strain-specific methylation that ultimately results in inactive chromatin.

Changes in RNA polymerase II progression influence somatic hypermutation of Ig-related genes by AID.

Somatic hypermutation (SHM) of Ig genes is initiated by the activation-induced cytidine deaminase (AID), and requires target gene transcription. We previously proposed that AID may associate with the RNA polymerase II (Pol). Here, to determine aspects of the transcription process required for SHM, we knocked-in a transcription terminator into an Ig gene variable region in DT40 chicken B cell line. We found that the human ß-globin terminator was an efficient inhibitor of downstream transcription in these cells. The terminator reduced mutations downstream of the poly(A) signal, suggesting that the process of transcription is essential for efficient SHM and that AID has better access to its target when Pol is in the elongating rather than terminating mode. Mutations upstream of the poly(A) site were almost doubled in the active terminator clones compared with an inactivated terminator, and this region showed more single-stranded DNA, indicating that Pol pausing assists SHM. Moreover, the nontranscribed DNA strand was the preferred SHM target upstream of the active terminator. Pol pausing during poly(A) site recognition may facilitate persistence of negative supercoils, exposing the coding single strand and possibly allowing the nascent RNA intermittent reannealing with the template strand, for prolonged access of AID.

The pattern of somatic hypermutation of Ig genes is altered when p53 is inactivated.

Mice with a deletion of the p53 gene have normal antibody titers against sheep red blood cells and normal switching to all Ig isotypes. In older mice (11 and 16 weeks old) the somatic hypermutation (SHM) frequencies are progressively reduced. In young mice (8 weeks old) with p53 deletion, the SHM frequencies are normal. However, the mutation pattern is changed in all p53-/- mice: mutations at A are increased. Surprisingly, deletion of the Ung2 gene in addition to the deletion of p53 corrected the A mutation frequencies to those of control mice. Known interactions of p53 protein with several proteins involved in error-prone BER during SHM may explain these findings. There is no indication that the absence of p53 affects the function of AID. Inactivation of p21 does not alter SHM, supporting the idea that the p53 protein is involved in SHM by its direct association with the SHM process. There is no significant change of mutations at T. Thus, the hypermutability at A is strand-biased (transcription? replication?). The translesion polymerase pol eta has so far been found to be the sole mutator at A and T in mice. However, the pattern in p53-/- mice is compatible with the possible inhibition by p53 of another translesion polymerase, pol iota, which in the absence of p53 may be recruited to error-prone repair of abasic sites in SHM.

Attracting AID to targets of somatic hypermutation.

The process of somatic hypermutation (SHM) of immunoglobulin (Ig) genes requires activation-induced cytidine deaminase (AID). Although mistargeting of AID is detrimental to genome integrity, the mechanism and the cis-elements responsible for targeting of AID are largely unknown. We show that three CAGGTG cis-elements in the context of Ig enhancers are sufficient to target SHM to a nearby transcribed gene. The CAGGTG motif binds E47 in nuclear extracts of the mutating cells. Replacing CAGGTG with AAGGTG in the construct without any other E47 binding site eliminates SHM. The CA versus AA effect requires AID. CAGGTG does not enhance transcription, chromatin acetylation, or overall target gene activity. The other cis-elements of Ig enhancers alone cannot attract the SHM machinery. Collectively with other recent findings, we postulate that AID targets all genes expressed in mutating B cells that are associated with CAGGTG motifs in the appropriate context. Ig genes are the most highly mutated genes, presumably because of multiple CAGGTG motifs within the Ig genes, high transcription activity, and the presence of other cooperating elements in Ig enhancers.

Abnormal regulation of DNA methyltransferase expression in cloned mouse embryos.

Cloning by somatic cell nuclear transfer is inefficient. This is evident in the significant attrition in the number of surviving cloned offspring at virtually all stages of embryonic and fetal development. We find that cloned preimplantation mouse embryos aberrantly express the somatic form of the Dnmt1 DNA (cytosine-5) methyltransferase, the expression of which is normally prevented by a posttranscriptional mechanism. Additionally, the maternal oocyte-derived Dnmt1o isoform undergoes little or none of its expected translocation to embryonic nuclei at the eight-cell stage. Such defects in the regulation of Dnmt1s and Dnmt1o expression and cytoplasmic-nuclear trafficking may prevent clones from completing essential early developmental events. Furthermore, aberrant Dnmt1 localization and expression may contribute to the defects in DNA methylation and the developmental abnormalities seen in cloned mammals.

Conservation of Dnmt1o cytosine methyltransferase in the marsupial Monodelphis domestica.

Imprinted genes have been identified in both eutherian mammals and in marsupials. In eutherian species, there is a conservation of the imprinting process, both in terms of the genes imprinted and the epigenetic inheritance mechanism. In the mouse, the inheritance of gametic methylation patterns depends on an oocyte-derived isoform of the Dnmt1 (cytosine-5)-methyltransferase protein, Dnmt1o, which functions during preimplantation development to maintain methylation patterns on imprinted alleles. To determine if this component of genomic imprinting is also found in marsupials, Dnmt1 isoforms were examined in somatic cells and germ cells of the South American opossum Monodelphis domestica. There is a Dnmt1o protein in Monodelphis oocytes that is synthesized, as in the mouse, from a different transcript than the somatic Dnmt1 protein. Thus, an essential component of imprinting in eutherian mammals is found in a marsupial species, suggesting that marsupials and eutherian mammals imprint their genes with the same methylation-dependent mechanism.

Dynamics of Dnmt1 methyltransferase expression and intracellular localization during oogenesis and preimplantation development.

The imprinting of mammalian genes depends on the maintenance of DNA methylation patterns during pre- and postimplantation development. Dnmt1o is a variant form of the somatically expressed Dnmt1 cytosine methyltransferase that is synthesized and stored in the oocyte cytoplasm and trafficks to the eight-cell nucleus during preimplantation development, where it maintains DNA methylation patterns on alleles of imprinted genes. Transcripts encoding Dnmt1 are present in preimplantation embryos, suggesting that Dnmt1 protein is also expressed in the preimplantation embryo, and may account for maintenance methylation at preimplantation stages other than the eight-cell embryo. However, using an antibody that detects Dnmt1, but not Dnmt1o, no Dnmt1 protein was detected on immunoblots or by immunocytochemical staining in wildtype preimplantation embryos. Moreover, Dnmt1 protein produced in the oocyte from a modified Dnmt1 allele, Dnmt1(1s/1o), trafficked to nuclei of eight-cell embryos, but not to nuclei of other stages. The highly restricted nuclear localization patterns of oocyte-derived Dnmt1o and Dnmt1 during preimplantation development add further support to the notion that DNA methyltransferases other than Dnmt1 are required for maintaining imprints during preimplantation development.