Naohiro Hori

A dyad oct-binding sequence functions as a maintenance sequence for the unmethylated state within the H19/Igf2-imprinted control region.

DNA methylation of an imprinted control region (ICR) directs the allele-specific and reciprocal expression of the mouse H19 and the insulin-like growth factor 2 (Igf2) genes, mediated by controlling enhancer access. The ICR shows enhancer blocking activity through CTCF binding to an unmethylated sequence. The unmethylated state of the maternal ICR is maintained throughout development after establishment in the germ line; however, little is known of the molecular mechanisms that regulate DNA methylation. Hence, in this study we show that a dyad Oct-binding sequence (DOS) in the ICR mediates the demethylation of low-density methylation but not hypermethylation and is required to maintain the unmethylated state against the tendency for de novo methylation within the ICR in the embryonic carcinoma cell line P19. Furthermore, we also reveal that the unmethylated state of at least one CTCF-binding site within the ICR is under the control of DOS. Our results suggest that the ICR, as a CTCF-dependent insulator, requires DOS as well as CTCF-binding sites and that DOS maintains the maternal specific unmethylated state of the ICR at postimplantation stages.

Ataxia-telangiectasia without immunodeficiency: Novel point mutations within and adjacent to the phosphatidylinositol 3-kinase-like domain

Ataxia-telangiectasia (AT) is an autosomal recessive disorder characterized by progressive ataxia, telangiectasia, sinopulmonary infections, hypersensitivity to ionizing radiation, and combined immunodeficiency. Recently, the AT gene (ATM) was cloned and shown to be mutated in AT patients. In this report, mutation analysis of ATM was performed in a 24-year-old AT patient without immunodeficiency. ATM amplified with reverse transcriptase-polymerase chain reaction (RT-PCR) was screened with a ribonuclease (RNase) cleavage assay and auto-sequenced. This patient, a compound heterozygote, showed two mutations in ATM: one missense mutation leading to a Leu2656Pro substitution and the other to the truncation at codon 3047 (Arg-->ter). The latter mutation is within the phosphatidylinositol 3-kinase (PI 3-kinase)-like domain and the former is outside but close to the domain. The particular phenotype in our patient, no immunodeficiency, suggests incomplete functional loss of ATM protein. The clinical spectrum of AT caused by ATM mutations may be broader than previously thought. Further analysis of patients with similar phenotypes will make the relation between ATM genotype and phenotype clear.

Induction of DNA Demethylation Depending on Two Sets of Sox2 and Adjacent Oct3/4 Binding Sites (Sox-Oct Motifs) within the Mouse H19/Insulin-like Growth Factor 2 (Igf2) Imprinted Control Region

Background: Cis-acting sequences regulate region-specific DNA demethylation. Results: DNA demethylation of a fragment from the mouse H19/Igf2 imprinted control region requires two Sox-Oct motifs, one of which is methylation-sensitive. Conclusion: The Sox-Oct motif functions to induce DNA demethylation in P19 cells. Significance: The Sox-Oct motif might be a key element to induce region-specific DNA demethylation as well as activate transcription in undifferentiated cells. DNA demethylation is used to establish and maintain an unmethylated state. The molecular mechanisms to induce DNA demethylation at a particular genomic locus remain unclear. The mouse H19/insulin-like growth factor 2 (Igf2) imprinted control region (ICR) is a methylation state-sensitive insulator that regulates transcriptional activation of both genes. The unmethylated state of the ICR established in female germ cells is maintained during development, resisting the wave of genome-wide de novo methylation. We previously demonstrated that a DNA fragment (fragment b) derived from this ICR-induced DNA demethylation when it was transfected into undifferentiated mouse embryonal carcinoma cell lines. Moreover, two octamer motifs within fragment b were necessary to induce this DNA demethylation. Here, we demonstrated that both octamer motifs and their flanking sequences constitute Sox-Oct motifs (SO1 and SO2) and that the SO1 region, which requires at least four additional elements, including the SO2 region, contributes significantly to the induction of high-frequency DNA demethylation as a Sox-Oct motif. Moreover, RNAi-mediated inhibition of Oct3/4 expression in P19 cells resulted in a reduced DNA demethylation frequency of fragment b but not of the adenine phosphoribosyltransferase gene CpG island. The Sox motif of SO1 could function as a sensor for a hypermethylated state of the ICR to repress demethylation activity. These results indicate that Sox-Oct motifs in the ICR determine the cell type, DNA region, and allele specificity of DNA demethylation. We propose a link between the mechanisms for maintenance of the unmethylated state of the H19/Igf2 ICR and the undifferentiated cell-specific induction of DNA demethylation.

CCAAT/enhancer binding protein-β (C/EBP-β), a pivotal regulator of the TATA-less promoter in the rat catalase gene

The rat catalase gene carries a TATA‐less promoter and its transcriptional mechanism is interesting because of downregulation in liver injury. We characterized the core element in the promoter and found that C/EBP‐β binding downstream of the transcription initiation site plays a crucial role for transcription. The multiple complexes binding to the promoter were composed of homodimers and heterodimers of C/EBP‐β isoforms. Transduction of the C/EBP‐β gene showed complete reconstitution of multiple binding complexes in HeLa cells, similar to normal liver. Furthermore, C/EBP‐β was observed to bind to the endogenous catalase promoter. These data suggest that multiple complex formation of C/EBP‐β regulates transcription in the TATA‐less catalase promoter.

Quantitative analysis of phagosome formation and maturation using an Escherichia coli probe expressing a tandem fluorescent protein

Phagosome formation and maturation are essential innate immune mechanisms to engulf and digest foreign particles. To analyze these processes quantitatively, we established a specific Escherichia coli probe expressing a tandem fluorescent protein, comprising glutathione S-transferase fused with monomeric Cherry (mCherry) and monomeric Venus (mVenus). We demonstrated that mVenus was more susceptible to bleaching in an acidic environment than mCherry, and that the mVenus:mCherry fluorescence intensity ratio can be used to monitor phagosomal pH changes during maturation. Using this probe, we revealed that synaptosomal-associated protein of 23 kDa, a plasma membrane soluble N-ethylmaleimide-sensitive factor attachment protein receptor protein, actively regulated phagocytosis of E. coli and subsequent phagosome maturation in macrophages. Our results indicated that this probe has the potential to be a powerful tool in understanding the molecular mechanisms of phagosome formation and maturation.

Fate of methylated/unmethylated H19 imprinting control region after paternal and maternal pronuclear injection

The paternal-allele-specific methylation of the Igf2/H19 imprinting control region (ICR) is established during gametogenesis and maintained throughout development. To elucidate the requirement of the germline passage in the maintenance of the imprinting methylation, we established a system introducing a methylated or unmethylated ICR-containing DNA fragment (ICR-F) into the paternal or maternal genome by microinjecting into the paternal or maternal pronucleus of fertilized eggs, and traced the methylation pattern in the ICR-F. When the ICR-F was injected in a methylated form, it was demethylated approximately to half degree at blastocyst stage but was almost completely remethylated at 3 weeks of age. In the case of the unmethylated form, the ICR-F remained unmethylated at the blastocyst stage, but was almost half-methylated at 3 weeks of age. Interestingly, the paternally injected ICR-F was highly methylated compared with maternally injected ICR-F at 3 weeks of age, partially mimicking the endogenous methylation pattern. Moreover, introduction of mutations in the CTCF (CCCTC binding factor) binding sites of the ICR-F, which are known to be important for the maintenance of hypomethylated maternal ICR, induced hypermethylation of the mutated ICR-F in both paternal and maternal pronuclear injected 3-week-old mice. Our results suggest the presence of a protection-against-methylation activity of the CTCF binding site in establishing the preferential paternal methylation during post-fertilization development and the importance of germline passage in the maintenance of the parental specific methylation at H19 ICR.