Rescue of embryonic lethality in mdmx null mice by loss of p53 suggests a non-overlapping pathway with MDM2 to regulate p53

The tumor suppressor p53 is mutated in over 50% of human sporadic tumors originating from diverse tissues. p53 responds to DNA damage and cell stress by activating the transcription of a variety of target genes, the protein products of which then initiate either growth arrest or apoptosis. ^ A p53 target with a particularly intriguing function is the oncogene MDM2. MDM2 functions, in part, by binding to and inhibiting p53's activity. Overexpression of MDM2, by gene amplification, has been found in 30% of human sarcomas harboring a wild type p53, indicating that an increase in MDM2 levels is sufficient for p53 inactivation. Mice carrying a homozygous null allele for mdm2 exhibit an early embryonic lethality that is completely rescued in a p53-null background. These data indicate that MDM2's only critical function in early mouse embryogenesis is the negative regulation of p53. ^ The mdmx gene is the first additional member of the mdm2 gene family to be isolated. MDMX, like MDM2, contains a RING-finger domain, ATP binding domain and a p53 binding domain, which retains the ability to bind and inhibit p53 transactivation in vitro. However, mdmx does not appear to be transcriptionally regulated by p53. We have cloned and characterized the murine mdmx genomic locus from a mouse 129 genomic library. The mdmx gene contains 11 exons, spans approximately 37 Kb of DNA, and is located on mouse chromosome 1. The genomic organization of the mdmx gene is identical to that of mdm2 except at the 5′ end of the gene near the p53 responsive element. Northern expression analysis of mdmx transcripts during mouse embryogenesis and in adult tissues revealed constitutive and ubiquitous expression throughout adult tissues and embryonic development. To determine the in vivo function of MDMX, mice carrying a null allele of mdmx have been generated. Mdmx homozygous null mice are early embryonic lethal. Mdmx null mice do not develop beyond 9.5 dpc and can be discerned by gross dissection as early as 7.5 dpc. Utilizing TUNEL and BrdU assays on 7.5 dpc histological sections we have determined that the mutant embryos are dying due to increased levels of growth arrest, but not apoptosis. Surprisingly, Mdmx homozygous null mice are viable in a p53 null background, indicating that MDMX is also very important in the negative regulation of p53. ^

GENETIC EVENTS PREDISPOSING TO WILMS' TUMOR

Wilms' tumor (WT) is a childhood embryonic tumor of the kidney. In some cases, WT has been associated with a chromosome deletion in the region 11p13. The majority of WT cases, however, have normal karyotypes with no discernable deletions or rearrangements of chromosome 11.^ To study the genetic events predisposing to the development of WT, I have used a number of gene markers specific for chromosome 11. Gene probes for human catalase and apolipoprotein A1 were localized to chromosome 11 by in situ hybridization. A number of other probes previously mapped to chromosome 11 were also used. Nine WT patients who were heterozygous for at least one 11p marker were shown to lose heterozygosity in their tumor DNA. Gene dosage experiments demonstrated that two chromosomes 11 were present although loss of heterozygosity had occurred in all but two cases. By using gene probes from the short and long arms of chromosome 11, I discerned that loss of heterozygosity was due to somatic recombination in four cases, chromosome deletion in two cases, and chromosome loss and reduplication or somatic recombination in these cases. Examination of DNAs from the parents of six of these patients indicated that the alleles that were lost in tumor tissues were alleles inherited from the mother. In sporadic WT cases one would expect the loss of alleles to be random. These data suggest that the loss of alleles resulting in the development of WT is not a random event, however, the significance of this is not known. ^