The p53 gene mutation at the splice donor site contributes to the inactivation of the p53 gene function and may play an important role in the pathogenesis, progression and therapeutic responsiveness of MDS.
To gain further insight into this "17p-syndrome," we studied 17 cases of AML and MDS with 17p deletion by whole chromosome painting (WCP) and fluorescence in situ hybridization (FISH) with probes spanning the 17p arm, including a p53 gene probe.
The results suggest that p53 mutation might occur as an early genetic event and is probably associated with rapid progression and poor survival in some MDS patients.
Consequently, this study revealed a possible relationship of RER+ phenotype accompanying an hMSH2 alteration to the development of therapy-related AML/MDS in association with TP53 mutations and specific chromosomal losses, and suggests that some patients may be predisposed to myelodysplasia after chemotherapy for their primary tumor.
The p53 mutation was not found in either MDS or ML, but a nonsense mutation (Try-557 --> stop) in exon 11 of the c-kit, which might lead to dysfunction of tyrosine kinase activity, was detected in MDS.
We conclude that antibody selection is an important variable in studying p53 in MDS regardless of the method of fixation or decalcification of BM trephine biopsies.
In addition, we investigated the relationship of apoptosis to the immunohistochemical expression of bcl-2 and p53 in these cases, and the association of apoptosis, bcl-2, and p53 with the leukemic evolution of MDS by examining sequential bone marrow samples of the same patient from the time of initial diagnosis to the time of overt leukemia.
Mutations with loss of heterozygosity of p53 are common in therapy-related myelodysplasia and acute myeloid leukemia after exposure to alkylating agents and significantly associated with deletion or loss of 5q, a complex karyotype, and a poor prognosis.
Ras mutations are the molecular abnormalities most frequently found in MDS, followed by p15 gene hypermethylation, FLT3 duplications, and p53 mutations, but none of these abnormalities are specific for MDS.
Apoptotic index and bcl-2 do not correlate with key clinical data in patients with myelodysplastic syndrome, while p53 levels show a good correlation with these data and may be a useful parameter to add to current prognostic schemes in this entity.
As p53 mutations are rare in MDS and AML, we investigated the status of the CHK2 gene by reverse transcriptase-polymerase chain reaction (RT-PCR) in patients with MDS (n=10) and patients in whom MDS had transformed into AML (n=3).
Because recent advances in molecular genetics may make it available as a routine work-up of MDS in the future, we discuss potential improvement of the IPSS by the addition of molecular analysis to the system, with particular reference to the configuration of the TP53 gene.
The following observations were made: i) the presence of p53 mutations was detected in 13 of 62 tested AML cases (21%) and in 1 of 4 tested myelodysplastic syndrome (MDS) cases by FASAY; ii) the presence of p53 mutation was shown to be a poor prognostic/predictive factor in AML (p=0.03/0.002); iii) although there is a statistically significant relationship between the presence of p53 mutation and p53 protein accumulation (p=0.05), not all samples having p53 mutation exhibited p53 protein accumulation; iv) five of 13 p53 mutations detected in the leukocytes of AML patients (38.5%) and the mutation detected in the leukocytes of the MDS patient (altogether 6/14-42.9%) were partially inactivating ts mutations.
The percentage of p53 staining in MDS (71%) was higher than that of mutated p53 (11%) but did not reach 100% of MDS cases studied, therefore the authors attempted to differentiate MDS, especially refractory anemia (RA) and AA, using a combination of p53 immunostaining, hemoglobin F (HbF) immunostaining and chromosome abnormality, because HbF of erythroblasts was reportedly observed in MDS RA but not in AA.
The percentage of p53 staining in MDS (71%) was higher than that of mutated p53 (11%) but did not reach 100% of MDS cases studied, therefore the authors attempted to differentiate MDS, especially refractory anemia (RA) and AA, using a combination of p53 immunostaining, hemoglobin F (HbF) immunostaining and chromosome abnormality, because HbF of erythroblasts was reportedly observed in MDS RA but not in AA.
These data suggest that the PPARgamma and TP53 genes may be candidates for molecular markers in pediatric MDS, and that these potentially recurrent deletions could contribute to the identification of therapeutic approaches in primary pediatric MDS.
In CD34(+) marrow cells from advanced MDS, expression of DJ-1 was up-regulated, whereas p53 levels were low, resulting in significantly greater DJ-1/p53 ratios than in patients with low-grade MDS (P = .01).
We searched the Li-Fraumeni Syndrome Registry in the Department of Genetics at the University of Texas M. D. Anderson Cancer Center (Houston, Texas) and identified 3 patients with documented germline TP53 mutations or LFS who had developed MDS during a period of 6 years (2000-2005).
Accordingly, in addition to classical oncogenic abnormalities, such as p53 abnormalities, or NRAS mutation, various molecular abnormalities, such as TET2, RPS14, or c-CBL, have been identified and/or proposed as the novel candidates for molecular basis of the development and progression of MDS.