Oct1 regulates trophoblast development during early mouse embryogenesis.

Oct1 (Pou2f1) is a transcription factor of the POU-homeodomain family that is unique in being ubiquitously expressed in both embryonic and adult mouse tissues. Although its expression profile suggests a crucial role in multiple regions of the developing organism, the only essential function demonstrated so far has been the regulation of cellular response to oxidative and metabolic stress. Here, we describe a loss-of-function mouse model for Oct1 that causes early embryonic lethality, with Oct1-null embryos failing to develop beyond the early streak stage. Molecular and morphological analyses of Oct1 mutant embryos revealed a failure in the establishment of a normal maternal-embryonic interface due to reduced extra-embryonic ectoderm formation and lack of the ectoplacental cone. Oct1(-/-) blastocysts display proper segregation of trophectoderm and inner cell mass lineages. However, Oct1 loss is not compatible with trophoblast stem cell derivation. Importantly, the early gastrulation defect caused by Oct1 disruption can be rescued in a tetraploid complementation assay. Oct1 is therefore primarily required for the maintenance and differentiation of the trophoblast stem cell compartment during early post-implantation development. We present evidence that Cdx2, which is expressed at high levels in trophoblast stem cells, is a direct transcriptional target of Oct1. Our data also suggest that Oct1 is required in the embryo proper from late gastrulation stages onwards.

Establishment of stem cell lines from nuclear transferred and parthenogenetically activated mouse oocytes for therapeutic cloning.

OBJECTIVE: To establish embryonic stem cell lines from nuclear transfer of somatic cell nuclei isolated from the same oocyte donor and from parthenogenetic activation. The study also evaluated the effect of the micromanipulation procedure on the outcome of somatic cell nuclear transfer in mice. DESIGN: Randomized, prospective study. SETTING: Hospital-based assisted reproductive technology laboratory. ANIMAL(S): F(1) (C57BL/6 x 129P3/J) mice. INTERVENTION(S): Metaphase II-stage oocytes were either parthenogenetically activated or nuclear transferred with cumulus cell nuclei or parthenogenetically activated after a sham-manipulation procedure. MAIN OUTCOME MEASURE(S): Embryogenesis and embryonic stem cell establishment. RESULT(S): The development rate to morula/blastocyst of nuclear transferred oocytes (27.9% +/- 5.9%) was significantly lower than that of the sham-manipulated (84.1% +/- 5.6%) or parthenogenetic (98.6% +/- 1.4%) groups. A sharp decrease in cleavage potential was obvious in the two- to four-cell transition for the nuclear transferred embryos (79.0% +/- 4.6% and 43.3% +/- 5.0%), implying incomplete nuclear reprogramming in arrested oocytes. However, the cleavage, as well as the development rate, of parthenogenetic and sham-manipulated groups did not differ significantly. The embryonic stem cell line establishment rate was higher from parthenogenetically activated oocytes (15.7%) than nuclear transferred (4.3%) or sham-manipulated oocytes (12.5%). Cell colonies from all groups displayed typical morphology of mice embryonic stem cells and could be maintained successfully with undifferentiated morphology after continuous proliferation for more than 120 passages still maintaining normal karyotype. All these cells were positive for mice embryonic stem cell markers such as Oct-4 and SSEA-1 based on immunocytochemistry and reverse transcriptase-polymerase chain reaction. The clonal origin of the ntES cell line and the parthenogenetic embryonic stem cell lines were confirmed by polymerase chain reaction analysis of the polymorphic markers. Blastocyst injection experiments demonstrated that these lines contributed to resulting chimeras and are germ-line competent. CONCLUSION(S): We report the establishment of ntES cell lines from somatic cells isolated from same individual. Our data also suggest that embryo micromanipulation procedure during the nuclear transfer procedure influences the developmental ability and embryonic stem cell establishment rate of nuclear transferred embryos.

Genetic Polymorphism of Epoxide Hydrolase and GSTM1 in Lung Cancer Susceptibility of Korean Population.

PURPOSE: Although 80~90% of patients with lung cancer are smokers, only 11% of smokers develop lung cancer. Genetic susceptibility according to the polymorphism of the epoxide hydrolase (mEPHX) gene and homozygous deletion of GSTM1 (M1 subunit of Glutathione S transferase) was studied in this case control study. MATERIALS AND METHODS: Genomic DNA from 76 subjects with lung cancer (40 squamous cell carcinoma, 13 adenocarcinoma, 10 subtype undetermined non-small cell lung cancer, and 13 small cell lung carcinoma) and 62 age- matched controls were extracted from peripheral white blood cells. PCR and RFLP (restriction fragments length polymorphism) with restriction enzyme (RsaI) and automatic sequencing were used for mEPHX genotyping (T-->C, Tyr113His) in exon 3 and (A-->G, His139Arg) in exon 4. Looking for homozygous deletions of GSTM1, multiplex PCR with primers for the GSTM1 gene and coagulation factor V gene (as positive control) were performed. RESULTS: The age distribution between the cancer and control groups were similar (63.6 7.2 vs. 61.1 7.9 years). The lung cancer group, however, had more smokers (73.3%, 44/60) than the control group (21/54, 38.9%, p<0.001). The rate of homozygous deletion of the GSTM1 gene was significantly higher in the lung cancer group (65.8%, 50/76) than in the control group (46.8%, 29/62, p<0.05), causing the relative risk of GSTM1 deletion for lung cancer as 2.19 (95% CI: 1.10~4.35, p=0.02). Among 118 subjects whose mEPHX gene polymorphisms were studied, 62 (52.5%) subjects showed genotypes with slow enzyme activity while 45 (38.1%) showed normal enzyme activity and 11 (9.3%) showed fast enzyme activity. There was no significant difference in the distribution of mEPHX gene polymorphisms between the two groups. CONCLUSION: The homozygous deletion of the GSTM1 gene was associated with high lung cancer susceptibility, whereas the mEPHX genotype showed no significant connection with risk of lung cancer in a sample Korean population.