At chromosomal locus 17p13.1, TP53 gene encodes the wild-type p53 transcription factor, which is vital for orchestrating stress signaling and preserving genome stability. The p53 protein product has five functional regions: (a) the amino N-terminal transactivation domain (TA), (b) the proline-rich domain (PRD), (c) the central DNA-binding domain (DBD), (d) the tetramerization domain (TD), and (e) carboxy-terminal oligomerization domain (CTD) at the C-terminus (11, 20–22). (Figure 1) This tetrameric structure facilitates the sequential binding of p53 to various cofactors following stress signals such as DNA damage, replication errors or oncogene activation (13). Upon cellular stress, p53 coordinates cell cycle regulation, promotes DNA repair, and induces apoptosis, thus functioning as a critical safeguard against malignant transformation (23, 24). TP53 mutations impair the specific binding of the protein to its cofactors, leading to tumor initiation, proliferation and chemoresistance (25). These changes are predominantly attributed to missense mutations causing an amino acid change in the DBD (~75%) (9, 26, 27) with splice-site indels accounting for 9%, nonsense mutations for 7%, silent changes for 5%, and other truncating variants making up the remainder (28, 29). The mutations can cause proliferation of tumor cells via gain of function (GOF), a loss of function (LOF) or WTp53 dysfunction (13).

Under normal physiological conditions, p53 functions as a transcription factor with a short half-life and remains largely inactive due to tight regulation by the negative regulators MDM2 (Mouse Double Minute 2) and MDM4 (also known as MDMX). These proteins promote ubiquitination and subsequent proteasomal degradation of p53, maintaining its low basal levels in unstressed cells (30–32). However, upon exposure to cellular stress, such as DNA damage or oncogenic signaling (33), the p53/MDM2 interaction is disrupted leading to increase in intracellular p53 stabilization. This stabilization is further enhanced through post-translational modifications including phosphorylation, methylation and acetylation (34–38). The stabilized p53 either induces cell differentiation or activates transcription of genes leading to apoptosis and cell cycle arrest in cells with mutated or damaged DNA. Interestingly, wild-type p53 (WTp53) may be rendered dysfunctional in some cancers, including primary AML, due to overexpression of MDM2 and/or MDM4 (MDMX), which suppresses p53 activity and is associated with inferior outcomes (11). The tumor suppressor P14/ARF positively regulates p53 by inhibiting MDM2, thus preventing p53 degradation and promoting its stabilization. Low P14ARF expression has been linked to poor prognosis in several studies (39–41).

TP53 mutations appear in only 5–10% of de novo MDS/AML cases but are far more frequent in secondary AML (18%) and therapy-related AML (30%) (42–44). These mutations are often associated with complex karyotypes (CK) and monosomal karyotypes (MK) (8, 45–47), both indicative of genomic instability. TP53 mutations in MDS/AML can be monoallelic or biallelic (48). In this review, we use the term multihit TP53 as an umbrella concept encompassing classical biallelic alterations as well as functional equivalents, including multiple TP53 mutations, high variant allele frequency suggestive of copy-neutral loss of heterozygosity, or cytogenetic loss of chromosome 17p. The term biallelic TP53 is used when structural involvement of both alleles can be directly inferred. This terminology is consistent with contemporary WHO and ICC frameworks and reflects current clinical practice. Approximately 70% of the cases exhibit biallelic alterations, which typically involve a point mutation in one allele and the loss of the second allele through 17p deletion or monosomy 17. In contrast, monoallelic mutations (25-30%) usually consist of a single point mutation, frequently observed in patients with isolated 5q deletion MDS (22, 49–51). TP53 mutations may also co-occur with other mutations, commonly in TET2 (29%), SF3B1 (27%), ASXL1 (16%), and DNMT3A (16%) which can influence disease progression and treatment outcomes (48). Furthermore, chromothripsis or chromosome shattering (chromosomal rearrangement) (52) is a phenomenon involving catastrophic chromosomal rearrangements which can lead to loss of heterozygosity by inactivating the remaining TP53 allele, particularly in cases with 17p deletion (53). This process is closely linked to TP53 mutations, cell cycle dysfunction, and poor prognosis in AML patients featuring complex karyotype (53). It has been recognized that biallelic or “multihit” involvement with multiple mutations or loss of heterozygosity is seen in 44% of MDS patients with TP53 mutations (48). Conversely, in low-risk MDS, about 20% of patients harbor monoallelic mutations alongside 5q deletion. These cases tend to occur in younger individuals and have a less aggressive clinical course than biallelic mutations (54).

The prognostic and therapeutic impact of TP53 allelic status has emerged as a key modifier of response. In MDS, patients with monoallelic TP53 mutations-defined as a single mutation without 17p deletion or replacement of the allele with its mutant counterpart (termed copy neutral loss of heterozygosity or CN-LOH)-demonstrate outcomes comparable to TP53 wild-type disease, with a median overall survival of ~2.5 years and 5-year OS around 40% (48). In contrast, multi-hit TP53 alterations, characterized by loss of the second allele via deletion, CN-LOH, or a second mutation, are strongly associated with complex karyotype and poor prognosis, with a median OS of only 8.7 months and 5-year OS consistently <10%, even after intensive chemotherapy or transplant (48).

Importantly, standard molecular testing for myeloid malignancies such as NGS gene panels and cytogenetic analyses may fail to detect CN-LOH. To accurately assess TP53-mutant allele status, specialized methods capable of identifying CN-LOH are required. These include expanded gene panels specifically designed to detect TP53 LOH, single-nucleotide polymorphism (SNP) arrays, or whole-genome/exome sequencing (55, 56). Detecting a single TP53 mutation having a VAF of greater than or equal to 50% is considered to be presumptive evidence of loss of the wild-type allele or CN-LOH. However, some cases of CN-LOH with low leukemia burden could be missed (55, 57).

Precisely distinguishing between monoallelic and multihit TP53 alterations is therefore critical for prognosis and treatment planning. The current diagnostic criteria by International Consensus Classification (ICC) classify cases with 10-19% blasts with any TP53 mutation with VAF >10% as high-risk myeloid neoplasms, regardless of whether they meet classic AML or MDS thresholds. Recent updates by both the World Health Organization (WHO, 5^th edition) and ICC emphasize the poor prognosis of biallelic/multihit TP53 mutations in MDS/AML. Such cases are characterized by one or more of the following: two or more TP53 mutations each with a variant allele frequency (VAF) above 10%, VAF ≥ 50%, loss of the wild-type TP53 allele (e.g., 17p deletion or monosomy 17), or the presence of a complex karyotype (5).

Moreover, higher VAF levels have been correlated with poorer survival outcomes. A multicenter study involving 359 patients with complex karyotype MDS found that those with TP53 mutations and VAF > 40% had a median overall survival of only 0.6 years, significantly lower than those with VAF <40% (1.1 years, p=0.004). Even patients with VAF <40% had worse outcomes than TP53 wild-type patients (1.1 vs 1.5 years, p= 0.001) (8, 58). These findings highlight the prognostic impact of VAF and support its integration into future diagnostic and treatment algorithms.

Given the strong association between TP53 mutations, genomic instability, and disease evolution, clonal hematopoiesis provides important insight into early leukemogenic events in TP53-mutated MDS and AML. Clonal hematopoiesis is age-associated expansion of hematopoietic cells driven by somatic mutations. Despite small size of the clones, these mutations lead to increased fitness of mutated clones, posing an increased risk of leukemic transformation affecting 0.5-1% carriers/year, particularly TP53 and U2AF1 (59). There is convincing evidence that TP53 mutations in individuals with clonal hematopoiesis of indeterminate potential (CHIP) are associated with increased risk of hematological cancers (60–63). TP53 mutation is also seen more frequently in CHIP patients who have received prior radiotherapy or cytotoxic chemotherapy (64). Gene mutations like DNMT3A, TET2, ASXL1, SRSF2, CBL and SF3B1 with TP53 mutation are associated with higher risk of leukemia (15, 39, 65). A recent study showed TP53, NPM1 and SRSF2 as dominant mutations preceding the AML whereas DNMT3A and TET2 mutations were stable over time (61). Therefore, understanding the correlation between clonal hematopoiesis and mechanisms of progression into leukemia remains crucial to design therapies targeting TP53 mutation.

CPX-351 is a liposomal formulation of danorubicin and cytarabine approved for the treatment of therapy-related AML and AML with myelodysplasia-related changes, clinical entities in which TP53 mutations are commonly enriched. Although CPX-351 has demonstrated improved outcomes in secondary AML compared with conventional 7+3, its benefit in TP53-mutated disease appears limited (81). Patients with TP53-mutated AML treated with CPX-351 consistently show lower remission rates, early relapse, and short overall survival, particularly in the presence of multihit TP53 alterations and complex karyotypes (6, 81). Overall, outcomes in this subgroup appear comparable to those achieved with other intensive cytotoxic regimens and remain substantially inferior to those observed in TP53-wild type AML, indicating that CPX-351 does not overcome TP53-associated chemoresistance (28).

Hypomethylating agents azacitidine and decitabine are the standard first-line treatments for elderly AML patients and those with high-risk MDS (HR-MDS). Azacitidine is a cytidine analog that after incorporation into DNA acts as a noncompetitive inhibitor of DNA methyltransferase 1 (DNMT1) (88). In the AZA-001 phase III trial, azacitidine was compared with conventional care regimens (best supportive care, low-dose cytarabine, or intensive chemotherapy) in patients with higher-risk myelodysplastic syndromes. Azacitidine significantly prolonged overall survival (median 24.5 vs 15.0 months; HR 0.58), delayed progression to acute myeloid leukemia and was associated with higher rates of hematologic response compared with conventional care (89). In the VIALE-A trial, which compared azacitidine plus venetoclax with azacitidine alone in previously untreated AML patients ineligible for intensive chemotherapy, azacitidine monotherapy was associated with median overall survival of 9.6 months and a composite complete remission (CRc) rate of 28.3% in the overall study population. However, outcomes in the TP53-mutated subgroup were particularly poor, with no observed remissions (CRc 0%) and a median overall survival of approximately 5–6 months, highlighting limited clinical benefit of single agent azacitidine in this high-risk molecular subset (90).

Decitabine, a deoxycytidine analog, functions by causing widespread hypomethylation, restoring expression of silenced tumor suppressors, and induction of DNA damage. Decitabine is currently FDA-approved for the treatment of MDS. However, it has not received FDA approval for AML, as a large randomized international phase III trial comparing decitabine with supportive care and low-dose cytarabine in elderly AML patients demonstrated improved complete remission rates but no statistically significant benefit in overall survival (91). In contrast, decitabine is approved by the European Medicines Agency and is recommended by the NCCN guidelines. Despite the lack of FDA approval, it continues to be used off-label for AML in the United States (92). The clinical trial with 10-day decitabine reported a 100% response rate (21/21) among TP53 mutated cases treated with 10-day decitabine regimen compared to 41% (32/78) in TP53 wild-type patients (p < 0.001) (75). Median overall survival was 12.7 months in patients with TP53 mutations and 15.4 months in those with wild-type TP53 (p = 0.79) (75). Importantly, these findings were derived from a non-randomized, single-institution study and have not been consistently reproduced in subsequent trial. For example, in a single institution phase II trial comparing 5-day and 10-day decitabine (DAC) regimens in TP53-mutated AML, response rates (29% vs 47%, p = 0.40) and overall survival (5.5 vs 4.9 months; p = 0.55) were not significantly different between regimens (93). A separate phase 3 trial demonstrated superior complete remission (CR) rates with decitabine (17.8%) compared to standard care (7.8%) in older AML patients with poor/intermediate-risk cytogenetics (p = 0.001). Median overall survival also favored decitabine (7.7 months vs. 5.0 months), although the difference did not reach statistical significance (91). Notably, reduction in TP53 variant allele frequency (VAF <5%) during HMA treatment has been associated with improved survival and is increasingly used as a prognostic biomarker, particularly in patients bridged to allo-HSCT (58, 94, 95). Although baseline VAF does not consistently predict response, VAF ≥ 40% has been linked to inferior outcomes (median OS 4.1 vs 7.7 months with HMA therapy) (94, 95). While a 10-day monthly decitabine regimen (DEC10) has produced encouraging blast clearance but mutation reduction responses are not durable, necessitating consolidating strategies such as transplantation (75).

Venetoclax, a BCL-2 inhibitor, promotes apoptosis by targeting anti-apoptotic proteins in leukemic blasts (96, 97). It was initially promising in the TP53-mutated AML, as BCL-2 dependence was thought to be independent of p53 function (98, 99). Venetoclax in combination with low intensity therapies (HMA or low dose cytarabine) gained regulatory approval for older or unfit patients with AML in 2022 (90). Subsequent studies showed limited benefit of venetoclax in TP53-mutated patients, especially those with multi-hit TP53 alterations. In a prospective phase trial evaluation 10-day decitabine plus venetoclax in elderly AML, TP53-mutated patients had a median OS of only 5.3 months, significantly shorter than TP53 wild-type patients (19.4 months; HR 4.67, p<0.00001), with lower MRD clearance and higher early mortality (100). A large retrospective analysis of 238 patients with newly diagnosed TP53 mutation AML receiving venetoclax-based therapy found no significant difference in OS (6.6 vs 5.7 months, p= 0.4) or relapse free-survival (4.7 vs 3.5 month; p=0.43) when compared to non-venetoclax-based regimens (101).

Venetoclax has been studied in combination with intensive chemotherapy regimens such as FLAG-Ida and 7+3. In a phase 1b trial, 34 patients with newly diagnosed AML received standard 7+3 induction (daunorubicin plus cytarabine) alongside venetoclax administered for escalating durations (8, 11, or 14 days) (102). The combination was well tolerated in fit adults up to 75 years of age, with no induction mortality, and achieved high efficacy (composite complete remission in 85.3% of patients and MRD negativity in 86%). Responses were consistent across most ELN 2022 risk groups, with the notable exception of the TP53-mutated subgroup (5 of 34 patients), where remission durability and survival outcomes remained poor (102).

Similarly, a recent study of intensive chemotherapy plus venetoclax (NCT03214562), 138 AML patients (77 newly diagnosed, 61 relapsed/refractory) receiving FLAG-IDA (Fludarabine, cytarabine, granulocyte colony-stimulating factor (G-CSF), and idarubicin) plus venetoclax achieved a 97% overall response rate, with 95% of patients attaining a composite complete remission and 90% clearing measurable residual disease by flow cytometry (86). Two-thirds remained alive and event-free at three years. Importantly, the study reported six newly diagnosed patients harboring TP53 mutations (two with VAFs < 5%; one bi-allelic with VAFs 20% and 22%; and three with VAFs 17%, 34% and 54%), all achieved an MRD-negative CRc, but remissions were short with median duration of response 8 months. Five of six subsequently relapsed and died, with median overall survival of 13 months (86). These results highlight that even the most active regimens may offer only transient benefit in multi-hit TP53-mutated AML, underscoring the urgent need for novel strategies in this high-risk subgroup.

Allogeneic hematopoietic stem cell transplant (allo-HSCT) remains the only potentially curative option for patients with TP53-mutated AML and MDS. However, outcomes are poor, with relapse and mortality rates significantly higher, up to 80-90% compared to TP53 wild-type patients (103–105). In a recent retrospective analysis of 240 patients with TP53-mutated AML or MDS undergoing allogeneic HSCT from matched related, matched unrelated, or haploidentical donors, TP53 variant allele frequency (VAF) with cytogenetic features stratified post-transplant outcomes (106). TP53 VAF and cytogenetics were the strongest predictors of outcome, defining three prognostic groups: patients with TP53 VAF ≥50% had a 2-year PFS of 3%; those with TP53 VAF <50% and complex cytogenetics or del(5q)/del(7q) had a 2-year PFS of 22%; and patients with TP53 VAF <50% without these abnormalities achieved a favorable 2-year PFS of 60% (106). Such data suggests that TP53-mutated AML/MDS should not be treated as a single high-risk entity.

Several barriers limit transplant success in this population (1): Older age and comorbidities often necessitate reduced-intensity conditioning compromising MRD clearance (107) (2); Outcomes are influenced more by baseline TP53 status than by mutational burden at remission (108) (3); Rapid disease progression in TP53-mutated AML often negates the graft-versus leukemia (GVL) effect, diminishing transplant efficacy (109). Importantly, data suggest that patients transplanted in CR may derive significant benefit, with reduced relapse and mortality risk (110). In a prospective study comparing allogeneic SCT with donor versus no-donor control group in patients with high-risk MDS (111), overall survival was significantly higher at four years in patients with a donor compared to those without (37% vs 15%), and disease-related mortality was lower (37% vs 73%). Notably, the survival advantage became evident only after the second year, reflecting early transplant-related mortality (111). Therefore, early identification of the transplant-eligible patients achieving deep remissions remain critical goals.

Given the limited efficacy of current treatments, novel therapies targeting TP53-mutated AML/MDS are under active investigation and may serve as effective bridging or maintenance strategies after transplant. A schematic overview of emerging therapeutic strategies in TP53-mutated AML/MDS is shown in Figure 2.

Targeted therapies.

Therapeutic approaches in TP53-mutated AML/MDS include:

Table 2 below highlights selected targeted therapies in TP53-mutated AML and MDS.