Bcl-x and Bax regulate mouse primordial germ cell survival and apoptosis during embryogenesis.

Restricted germ cell loss through apoptosis is initiated in the fetal gonad around embryonic day 13.5 (E13.5) as part of normal germ cell development. The mechanism of this germ cell attrition is unknown. We show that Bcl-x plays a crucial role in maintaining the survival of mouse germ cells during gonadogenesis. A bcl-x hypomorphic mouse was generated through the introduction of a neomycin (neo) gene into the promoter of the bcl-x gene by homologous recombination. Mice that contained two copies of the hypomorphic allele had severe reproductive defects attributed to compromised germ cell development. Males with two mutant alleles lacked spermatogonia and were sterile; females showed a severely reduced population of primordial and primary follicles and exhibited greatly impaired fertility. Primordial germ cells (PGCs) in bcl-x hypomorph mice migrated to the genital ridge by E12.5 but were depleted by E15.5, a time when Bcl-x and Bax were present. Two additional bcl-x transcripts were identified in fetal germ cells more than 300 bp upstream of previously reported start sites. Insertion of a neo cassette led to a down-regulation of the bcl-x gene at E12.5 in the hypomorph. Bax was detected by immunohistochemistry in germ cells from bcl-x hypomorph and control testes at E12.5 and E13.5. Bcl-x function was restored, and animals of both genders were fertile after removal of the neo selection cassette using Cre-mediated recombination. Alternatively, the loss of Bcl-x function in the hypomorph was corrected by the deletion of both copies of the bax gene, resulting in a restoration of germ cell survival. These findings demonstrate that the balance of Bcl-x and Bax control PGC survival and apoptosis.

Genomic architecture and transcriptional activation of the mouse and human tumor susceptibility gene TSG101: common types of shorter transcripts are true alternative splice variants.

The functional inactivation of the tumor susceptibility gene tsg101 in mouse NIH3T3 cells leads to cell transformation and the formation of metastatic tumors in nude mice. We cloned, mapped and sequenced the mouse tsg101 gene and further identified a processed pseudogene that is 98% identical to the tsg101 cDNA. Based on Northern blot analysis, tsg101 is expressed ubiquitously in mouse tissues. A comparison of the coding region of the mouse tsg101 gene with the human TSG101 cDNA revealed that both the mouse and human gene encode ten additional highly conserved amino acids at the N-terminus. Based on the mouse tsg101 genomic structure, we predicted four additional introns within the human TSG101 gene. Their location was confirmed using PCR and sequencing analysis. The presence of these so far unidentified introns now explains published data on aberrantly spliced mRNA products that were frequently observed in primary breast tumors. We show that a majority of shorter TSG101 transcripts are not the result of aberrant splicing events, but represent a fraction of true alternative splice variants. Finally, we examined tsg101 expression patterns during different stages of mammary gland development and in different transgenic mouse models for breast tumorigenesis.