Our data demonstrates that ASPP2κ plays a distinctive role as an antiapoptotic regulator of the TP53 checkpoint, rendering cells to a more aggressive phenotype as evidenced by proliferation and apoptosis rates - and ASPP2κ expression results in acquisition of genomic mutations, a first initiating step in leukemogenesis.
Although the precise role of the p53 point mutation in leukemogenesis remains to be clarified, the establishment of an NK leukemia cell line with a p53 point mutation could be valuable in the study of leukemogenesis.
While the NF1 and TP53 TSGs follow the Knudson two-hit paradigm and undergo biallelic inactivation, there is increasing evidence that inactivation of a single allele of TSG such as RUNX1, PU.1 and RPS14 (haploinsufficiency) can also contribute to leukemogenesis.
We show that five TRP53 mutants do not accelerate lymphomagenesis on a TRP53-deficient background but strongly synergize with c-MYC overexpression in a manner that distinguishes the hot spot <i>Trp53</i> mutations.
We conclude that, (1) p53 mutations are infrequent at diagnosis but tend to be associated with poor clinical outcome; (2) RAS and p21 mutations may not be involved in the pathogenesis of T-ALL; (3) not only frequent alterations of p16 and p15 genes but also methylation of p16 gene are involved in initiating the leukemogenesis of T-ALLs, and (4) these 5 genes are independently involved in T-ALL.
The genetic mechanisms underlying FA-associated leukemogenesis appear to be independent of N-ras and p53 mutations, which are relatively frequent events in myeloid tumors associated with other hematologic disorders.
These observations suggest that the p53 gene alteration may play an important role in lymphomagenesis and/or disease progression in some types of B-cell lymphoma.
The high frequency of p53 mutation in NHL B cell lines and the relatively low frequency of p53 mutations in fresh lymphoma tissue suggests that p53 gene alteration may play a role in lymphomagenesis and/or disease progression in a subset of B cell lymphomas and that the p53 mutation conveys a proliferative advantage on lymphoma cells that permits their in vitro growth.
Collectively, these results show that mutations of p53 gene in BLV-infected cattle with lymphosarcoma can potentially alter its physiological function and may play an important role in BLV-induced leukemogenesis.
The genetic mechanisms underlying the genesis of low-grade mucosa-associated lymphoid tissue (MALT) lymphomas and their transformation into high-grade lymphoma are poorly understood. p53 inactivation, commonly caused by mutation and allele loss, has been shown to play an important role in the early development and/or the late disease progression of many human tumors including lymphoid malignancies and, thus, may also be important in MALT lymphomagenesis.
However, in Tp53 deficient mice, Setd4 deletion did not delay the radiation-induced lymphomagenesis although it accelerated the spontaneous T-lymphomagenesis in non-irradiated mice.
In order to evaluate the role of p53 mutations in the multistep process of leukemogenesis we studied 61 patients with myelodysplastic syndromes using single-strand conformation polymorphism analysis of polymerase chain reaction products as well as direct sequencing.
Rearrangements involving the 1p36 chromosomal region occur frequently in NHL, suggesting the existence of tumor suppressor gene(s) that are important in lymphomagenesis. p73 is closely related to the tumor suppressor p53 and maps to the chromosome 1p36 region.