Open access journal of the Ferrata-Storti Foundation, a non-profit organization
Articles

Variable outcome and methylation status according to CEBPA mutant type in double-mutated acute myeloid leukemia patients and the possible implications for treatment

Department of Haematology, UCL Cancer Institute, London
MRC Human Genetics Unit and Edinburgh Cancer Research Centre, MRC Institute of Genetics and Molecular Medicine, University of Edinburgh, Edinburgh
Department of Haematology, UCL Cancer Institute, London
Medical Genomics, UCL Cancer Institute, London
Centre for Trials Research, Cardiff University, UK
Centre for Trials Research, Cardiff University, UK
Department of Haematology, UCL Cancer Institute, London
Department of Haematology, UCL Cancer Institute, London
Vol. 103 No. 1 (2018): January, 2018 https://doi.org/10.3324/haematol.2017.173096

Abstract

Although CEBPA double-mutated (CEBPADM) acute myeloid leukemia is considered to be a favorable-risk disease, relapse remains a major cause of treatment failure. Most CEBPADM patients have a classic biallelic mutant combination with an N-terminal mutation leading to production of p30 protein plus a C-terminal loss-of-function in-frame indel mutation (CEBPAClassic-DM), but approximately one-third of cases have one or more non-classic mutations, with diverse combinations reported, and there is little information on the consequences of such mutants. We evaluated outcome in a cohort of 104 CEBPADM patients, 79 CEBPAClassic-DM and 25 with non-classic mutants, and found that the latter may have poorer survival (5-year overall survival 64% vs. 46%; P=0.05), particularly post relapse (41% vs. 0%; P=0.02). However, for this analysis, all non-classic cases were grouped together, irrespective of mutant combination. As CEBPADM cases have been reported to be hypermethylated, we used methylation profiling to assess whether this could segregate the different mutants. We developed a CEBPAClassic-DM methylation signature from a preliminary cohort of 10 CEBPADM (including 8 CEBPAClassic-DM) and 30 CEBPA wild-type (CEBPAWT) samples, and independently validated the signature in 17 CEBPAClassic-DM cases. Assessment of the signature in 16 CEBPADM cases with different non-classic mutant combinations showed that only 31% had a methylation profile equivalent to CEBPAClassic-DM whereas for 69% the profile was either intermediate between CEBPAClassic-DM and CEBPAWT or equivalent to CEBPAWT. These results suggest that CEBPADM cases with non-classic mutants may be functionally different from those with CEBPAClassic-DM mutants, and should not automatically be included in the same prognostic group. (AML12 is registered under ISRCTN17833622 and AML15 under ISRCTN17161961).

Introduction

The CEBPA gene encodes CCAAT/enhancer binding protein-α (C/EBPα), a basic leucine zipper (bZIP) transcription factor that is essential for hematopoietic stem cell regulation and myeloid development.21 The gene is mutated in approximately 8% of acute myeloid leukemia (AML) patients with intermediate-risk cytogenetics, and presence of biallelic double mutations (CEBPA) in the absence of an FLT3 internal tandem duplication (FLT3) is associated with a favorable prognosis.93 In the current risk-adapted therapy strategies for AML,1210 these patients are classified as good-risk and therefore not usually considered for consolidation of first remission by allogeneic transplantation.1311

Mutations occur throughout the single exon gene but predominate at the N and C termini.14 N-terminal mutations are nearly always frameshift or nonsense mutations causing increased translation from an internal ATG start site and production of a truncated p30 protein that retains the same reading-frame as the full-length p42 protein but lacks the first transactivation domain (TAD1). The most common C-terminal mutations are in-frame indels in the bZIP DNA binding domain (DBD) or leucine zipper domain (LZD) that lead to loss of the ability to bind to DNA or dimerize, classified here as C-terminal loss-of-function (C-LOF). However, many other mutations have also been reported, including missense mutations in the DBD or LZD, missense mutations and in-frame indels in the mid-region, and frameshift or nonsense mutations in the mid-region or C-terminus. Some also present as homozygous alterations due to chromosome 19 uniparental disomy.1615 The most common combination of mutations is an N-terminal frameshift on one allele plus a C-terminal in-frame indel on the other allele that together are predicted to lead to complete loss of normal p42 C/EBPα activity,14 hereafter called the classic CEBPA combination (CEBPA). This combination was identified in 204 of 305 CEBPA cases (67%) with defined mutants reported in six studies containing 20 or more CEBPA cases.1917863 The remaining 101 cases had multiple different mutant combinations with diverse consequences: 54 (18% of total CEBPA) would be predicted to produce just p30 due to the presence of a mid-region or C-terminal truncation, 12 (4%) would only produce a classic C-LOF protein, 19 (6%) p30 plus a C-terminal missense mutant, 5 (2%) just a C-missense mutant, and 11 (4%) other mutant combinations.

Understanding the consequence of the different types of CEBPA mutants is needed as this may impact on clinical outcome, but there is limited information available on the specific mutations. CEBPA cases have gene expression profiles that are significantly different from single-mutated (CEBPA) and wild-type (CEBPA) cases.73 However, recent data suggest that CEBPA cases with non-classic combinations may not always cluster with other CEBPA cases,207 with 3 of 7 such cases classified as negative for the CEBPA expression profile in one report.20 Furthermore, genotype stratification according to expression profiling may be confounded by CEBPA cases with completely silenced CEBPA expression (CEBPA) due to methylation of the CEBPA promoter as these cases cluster together with CEBPA cases.21 CEBPA cases also form distinct epigenetic clusters with a markedly hypermethylated profile.2322 But although CEBPA cases also have a hypermethylated profile, this segregates from the CEBPA cluster and, interestingly, they appear to be associated with a biologically distinct subtype of AML with a poor prognosis.242221 Potential methylation differences according to the underlying combination of CEBPA mutants, however, have not been reported.

In order to investigate potential differences between CEBPA mutant combinations, we evaluated clinical outcome in 104 CEBPA cases (79 CEBPA and 25 with non-classic mutants) and observed that the non-classic cases may have a lower overall survival (OS). However, the number of cases was relatively small and all cases with a non-classic mutant were included in this group, irrespective of the mutant type. We therefore investigated whether methylation profiling of samples from double-mutated patients could assist in segregating the different mutant combinations.

Methods

Patient cohorts

The patients investigated were younger adults entered into the UK MRC AML10, AML12 and AML15 trials. Informed patient consent was obtained in accordance with the Declaration of Helsinki, and ethical approval for tissue use from the Wales Research Ethics Committee 3. Clinical outcome was evaluated in 104 CEBPA patients, all under 60 years of age, and methylation profiling was performed on 135 patients: 132 (98%) of them under 60 years of age (Online Supplementary Figure S1). Selected tests were performed on a further 82 samples with specific cytogenetic and molecular abnormalities.

Therapy, clinical end points and statistical methods

Details of clinical protocols, end points and statistical methods are defined in the Online Supplementary Appendix.

Methylation arrays and data processing

DNA was bisulfite-converted using the EZ DNA Methylation-Gold Kit (Zymo Research, California, USA) and random samples checked by methylation-specific PCR to ensure efficient conversion (see the Online Supplementary Appendix). Methylation profiling was performed using the Illumina Infinium HumanMethylation27 (n=40, cohort 1) and HumanMethylation450 (n=95, cohort 2) BeadChip arrays (Illumina Inc., California, USA). Details of data processing are given in the Online Supplementary Appendix. Derived β values were expressed as the percentage methylation at a given CpG probe. Selected CpG sites were further analyzed using pyrosequencing assays (see the Online Supplementary Appendix).

Unsupervised analysis of patient methylation profiles

In a given sample, probes were defined as methylated if the β value was more than 0.3, unmethylated if 0.3 or under.25 Samples were clustered based on their β values at probes displaying significant variation (variable probes), as previously defined.2625 They were defined as variable if methylated in 1 sample or more plus unmethylated in 1 sample or more. CpG islands (CGIs) were located as previously defined;27 their methylation levels were derived by calculating the mean β value of probes at these locations. Hierarchical clustering was performed using the Euclidian distance of β values and Ward algorithm in R.

Derivation and analysis of CEBPA signature

A methylation signature of CEBPA genotype was derived from variably methylated CpGs in cohort 1. Signature CpGs were selected as the top 25 ranked probes based on the mean rank of P-values of Wilcoxon tests and the absolute median difference in β value between CEBPA and CEBPA samples. Probes were included in the analysis if more than 90% of samples and 2 or more CEBPA and 2 or more CEBPA samples had observable data. Methylation signatures of CEBPA and CEBPA samples were then defined as the median β values observed at these 25 probes. Samples were scored relative to these signatures by calculating the Euclidian distance between the signatures and their profiles at signature probes.

Mutant CEBPA level and confirmation of biallelic status

Mutant CEBPA level was quantified as previously described6 or approximated from the sequence chromatogram (average height of ≥5 peaks). Monoallelic/biallelic status was investigated by sequencing clones derived from full-length CEBPA amplicons as previously described.6

Results

Clinical outcome in CEBPADM cases according to mutant type

Of the 104 CEBPA cases evaluated, 79 had classic and 25 had non-classic mutants (Table 1 and Online Supplementary Table S1). The latter included 4 patients predicted to produce p30 plus a C-terminal missense mutant, 8 with combinations predicted to produce just p30, and 13 with different combinations predicted to produce just a C-LOF protein. There was no difference in the baseline characteristics between the classic and non-classic cases, including white cell count, sex, World Health Organization (WHO) performance status, and AML type (de novo or secondary), although the non-classic cases were older (median 35 vs. 47 years; P=0.001) (Online Supplementary Table S2). All classic cases had intermediate-risk cytogenetics compared to 89% of the non-classic cases (P=0.05). There was no significant difference in the incidence of FLT3, NPM1, IDH1, WT1, TET2 and GATA2 mutations between the groups, although the non-classic cases had more IDH2 mutations (1% vs. 20%, P=0.003; all IDH2) and DNMT3A mutations (3% vs. 16%, P=0.03). Median follow up was 9.5 years (range: 0.1–22 years). Neither the proportion of transplanted patients, the type of transplant, nor the stage of transplantation differed between the groups (Online Supplementary Table S2).

Table 1.CEBPA genotype of investigated cohorts.

CEBPA cases had a slightly higher but statistically non-significantly different complete remission (CR) rate to non-classic cases (95% vs. 88%, P=0.2) (Table 2). In univariate analysis, there was no significant difference in relapse-free survival or relapse rate (RR). However, there was a trend towards a lower OS in the non-classic cases (64% vs. 46% at 5 years, P=0.05) (Figure 1A), which was largely due to the worse outcome post-relapse in the non-classic cases. The proportion of relapsing patients who achieved a second remission did not differ between the groups (61% vs. 55%), but 5-year survival post relapse was 41% versus 0% (P=0.02) (Figure 1B), and 59% versus 0% from second remission (P=0.004) (Figure 1C). The survival differences were not, however, statistically different in multivariate analysis (Table 2), but this is not surprising given the small group sizes. Although the significantly higher proportion of DNMT3A-mutated cases in the non-classic group could have contributed to their worse outcome, as both these mutations and FLT3 adversely impact on the favorable outcome associated with CEBPA AML,286 the trend towards a lower OS in the non-classic cases was still present when patients with these mutations were excluded (70% vs. 53%; Hazard Ratio 1.95, 95% confidence intervals 0.95–4.01; P=0.08) (Figure 1D).

Table 2.Outcome according to CEBPADM mutant combination.

Figure 1.Clinical outcome in CEBPADM patients according to mutant combination. (A) Overall survival in the total cohort of 104 CEBPADM patients. (B) Survival post relapse in the 39 patients who relapsed. (C) Survival from second remission in the 23 relapsed patients who achieved a second remission. (D) Overall survival in the total cohort excluding patients with FLT3ITD and DNMT3A mutations.

Development of a CEBPAClassic-DM methylation signature

The clinical evaluation grouped all non-classic cases together in order to obtain an adequate number of patients for analysis, but this cohort, therefore, included patients with many mutant combinations predicted to have differing functional consequences. In order to explore potential methods for discriminating between these combinations, we investigated the impact of mutant type on methylation profiles. A preliminary cohort of samples from 40 normal karyotype (NK) FLT3NPM1 patients were investigated using the Illumina Infinium HumanMethylation27 array: 10 were CEBPA and 30 were CEBPA (Methylation cohort 1) (Table 1), approximating the relative proportions of such cases in NK FLT3NPM1 patients in our earlier study.6 The array data were validated by pyrosequencing assays at four differentially methylated CpG sites (Online Supplementary Figure S2). Most CpG sites analyzed showed little variation in methylation levels across the whole cohort, but unsupervised cluster analysis according to levels of the most variably methylated probes revealed two main clusters. All 10 CEBPA samples, including two non-classic cases, fell in the cluster of 16 samples with significantly higher levels of mean CGI methylation (Figure 2A), and the mean level of CGI methylation was significantly different between CEBPA and CEBPA samples (Figure 2B).

Figure 2.Methylation profile of the preliminary cohort of 40 samples. (A) Unsupervised cluster analysis of the cohort. Each column represents one patient. Genotype is given in the upper panel. Samples were clustered based on their methylation levels at 7679 variable probes, and the heatmap in the middle panel shows the variable CpG probes located within CpG islands (CGIs). The latter were used to calculate the mean % CpG methylation shown in the lower panel; red and blue bars indicate a predominantly hyper- or hypo-methylated profile, respectively. (B) The mean level CGI methylation for CEBPAWT and CEBPAClassic-DM samples. CGI methylation levels were calculated from all autosomal CGI probes. ***P<0.001 (Wilcoxon test). (C) Supervised cluster analysis showing the derived CEBPAClassic-DM signature (left) and the CEBPAWT signature (right). Samples are ordered according to their level of similarity to the CEBPAClassic-DM signature using Euclidian distance. (Bottom) Distance scores indicating the distance from the CEBPAClassic-DM (green circles) and CEBPAWT (white circles) signatures; the lower the y-axis value, the more closely the sample matches that particular signature.

A supervised approach was then used to create CEBPA and CEBPA methylation signatures based on the 25 most differentially methylated sites between the CEBPA and CEBPA samples (Figure 2C and Online Supplementary Table S3). Two distance scores were calculated for each sample based on the Euclidian distance between their methylation levels at these signature probes and the median profile of the CEBPA and CEBPA samples. This confirmed that, when assessed according to their distance scores, the CEBPA samples formed a distinct group that were clearly separate from the CEBPA samples (Figure 3A).

Figure 3.Analysis of the methylation profiles of the samples according to their distances from the derived CEBPAClassic-DM and CEBPAWT methylation signatures. Difference between the distance scores (CEBPAClassic-DM - CEBPAWT) compared with the distance from the CEBPAClassic-DM (MUT) signature of (A) the preliminary cohort and (B) the CEBPAClassic-DM and CEBPAWT cases in the follow-up cohort. (C) Criteria derived for CEBPAClassic-DM using mean±2Standard Deviation (SD) of the distance scores of all 24 CEBPAClassic-DM cases.

The CEBPA methylation signature was validated with samples from a further 17 CEBPA and 26 CEBPA cases (Methylation cohort 2) (Table 1) using the HumanMethylation450 array. Sixteen of the 17 CEBPA cases (94%) fell in the same cluster in unsupervised analysis, with a relatively more hypermethylated profile, and all CEBPA cases fell in the hypomethylated cluster (Online Supplementary Figure S3). Using supervised analysis according to the derived CEBPA and CEBPA signatures, the same 16 CEBPA cases had a methylation profile that was closest to the CEBPA signature with a wide difference between the two signatures (Figures 3B and 4), indicating that their profile was equivalent to the CEBPA cases in cohort 1. Further analysis of the one CEBPA case that fell closer to the CEBPA group indicated that the mutations were biallelic but only approximately half of the cells in the sample carried mutations; mean mutant level was 28% for the pair, which was the lowest mean level of all 25 CEBPA cases (median 44%; range: 28–50%). The methylation profile of this case could, therefore, have been affected by the presence of a significant proportion of non-leukemic cells and it was excluded from further analyses. Using the distance scores (mean±2SD) for CEBPA cases in cohort 1, tests showed that these scores classified CEBPA and CEBPA genotypes in the second cohort with 95% accuracy, 88% sensitivity, and 100% specificity. The distance scores of the 24 CEBPA cases from the combined cohorts were then used to define a CEBPA quadrant that segregated all CEBPA cases from CEBPA cases (Figure 3C).

Figure 4.Analysis of the follow-up cohort of 95 samples. Supervised analysis according to the CEBPAClassic-DM and CEBPAWT methylation signatures. Patient CEBPA genotype is given above the heatmap. (Bottom) Distance scores indicating the distance from the CEBPAClassic-DM (green circles) and CEBPAWT (white circles) signatures; the lower the y-axis value, the more closely the sample matches that particular signature.

Investigation of the CEBPAClassic-DM methylation signature in other good-risk patients

In order to examine whether the CEBPA methylation signature could simply reflect ‘good-risk’ disease or be due to a lack of C/EBPα expression, methylation levels at three differentially methylated CpG sites from the signature were quantified by pyrosequencing using samples from 21 patients with inv(16) and 19 with t(8;21), both associated with down-regulated C/EBPα expression,3129 and 42 with NPM1FLT3. KHNYN and VAMP5 were more hypermethylated in the CEBPA signature, while LY9 was more hypomethylated. Each subgroup differed significantly from the 24 CEBPA cases at two of the three sites (Online Supplementary Figure S4). A composite methylation score was calculated for each sample; it was statistically significantly different from the CEBPA cases for all three subgroups (Figure 5), indicating that the methylation profile was a distinct feature of the mutant proteins that lead to total loss of normal C/EBPα function rather than absence of C/EBPα per se.

Figure 5.Methylation levels in other good-risk groups compared to the CEBPAClassic-DM cases. A composite methylation score was calculated by summing the difference between the % methylation for samples and the median for the 24 CEBPAClassic-DM cases (excluding the outlier) for three differentially methylated CpG sites: KHNYN, VAMP5 and LY9. Mean values±95% confidence intervals are shown. The CEBPAClassic-DM and CEBPAWT results were β values from the arrays; results for the three comparative groups were obtained by pyrosequencing. Significance refers to difference from the CEBPAClassic-DM group. ***P≤0.001.

Investigation of non-classic CEBPADM and CEBPASM mutants

Having established that CEBPA cases have a methylation profile that is distinct from CEBPA cases, profiles of 14 CEBPA cases with a variety of different non-classic combinations were investigated using the HumanMethylation450 array (Methylation cohort 2) (Table 1). On unsupervised analysis, 9 (64%) were hypermethylated and 5 (36%) hypomethylated (Online Supplementary Figure S3). To assess their impact on the CEBPA methylation signatures, these 14 cases and the 2 non-classic cases from the initial cohort were considered according to the predicted functional consequence of the combination.

Six cases were predicted to produce just p30 protein, with a classic N plus null mutant (mid-region or C-terminal frameshift/nonsense) combination. Only 1 fulfilled the CEBPA criteria; 4 fell outside this quadrant but were still distinct from CEBPA cases, and 1 grouped with the CEBPA cases (Figure 6A). Three cases were predicted to just give rise to classic C-LOF proteins without p30 (2 homozygous classic C, 1 compound heterozygous with a classic C plus C-frameshift combination). Two fulfilled the CEBPA criteria and 1 was intermediate between CEBPA and CEBPA. The 7 cases with missense mutations were also highly variable. Three had a classic N plus C-missense combination; none fulfilled the CEBPA criteria, 2 were intermediate between the signatures, and 1 grouped with CEBPA cases. Mutant levels were indicative of 80% or more mutated cells in all 3 cases; 2 were biallelic by cloning but no full-length amplicons could be obtained in 1 case. Similarly, only 1 of the 3 homozygous C-missense cases fell in the CEBPA quadrant, the other 2 were equivalent to CEBPA cases. The remaining case was compound heterozygous with a classic C and C-missense combination, and this did fulfil the CEBPA criteria.

Figure 6.Supervised analysis of CEBPADM cases with non-classic mutations and CEBPASM cases. Difference between the distance scores (CEBPAClassic-DM - CEBPAWT) compared with the distance from the CEBPAClassic-DM (MUT) signature for (A) CEBPADM cases with a non-classic mutant. (B) CEBPASM cases.

These results suggest that the functional consequence of double-mutated cases producing at least 1 non-classic mutant protein can be highly variable and difficult to predict. Of note, when outcome was assessed in the non-classic cases according to their methylation profile, there was a suggestion that those that fulfilled the CEBPA methylation criteria were less likely to relapse, with only 1 of 4 cases (25%) relapsing compared to 7 of 10 cases (70%) that fell outside the CEBPA quadrant (5-year RR 25% vs. 54%, respectively). These numbers were too small for meaningful statistical analysis, and the results do not necessarily indicate a causal link between the methylation pattern and outcome. They do suggest, however, that the methylation pattern could be a useful biomarker, and thereby act as a surrogate for response and selection of therapy.

Methylation cohort 2 also included 38 CEBPA cases with a wide range of classic and non-classic mutants (Table 1). On unsupervised analysis, 31 (82%) were in the hypomethylated cluster, with no apparent segregation between the CEBPA and CEBPA cases (Online Supplementary Figure S3). On supervised analysis, all except 2 cases were equivalent to CEBPA cases, with no obvious grouping according to the type of mutant (Figures 4 and 6B). The remaining 2 cases fell in or close to the CEBPA quadrant; both had a classic C mutation. It is possible that the CEBPA allele had been silenced in these cases, but RNA samples were not available to check this.

Discussion

Molecular genotyping is increasingly used to risk stratify patients with AML, but clinical application of this information needs to be accurate and robust for optimal patient therapy. This is particularly important for good-risk patients such as those with biallelic CEBPA mutations, where the current recommendation is not to proceed to transplantation in first remission, as for some patients this could lead to undertreatment. Identifying those who are at greater risk of relapse and poorer survival may, therefore, guide patient management. Very limited information is available on the impact of the different CEBPA mutations, with all CEBPA cases currently being classified as good-risk, irrespective of the underlying mutant. However, mutations identified in approximately one-third of CEBPA patients do not conform to the classic combination of N-terminal frameshift or nonsense mutation plus C-terminal in-frame indel. As many of the other mutations are unique and of unknown functional consequence, determining their significance is challenging, particularly in view of the multiple functions attributed to C/EBPα.21

Although we had access to a database of 2162 patients with known CEBPA genotype and available clinical data from three consecutive UK MRC trials of younger adult patients with AML, 67% with intermediate-risk cytogenetics, we were still able to evaluate long-term outcome in a cohort of only 79 CEBPA cases and 25 CEBPA cases with at least one non-classic mutant. The results suggested that the non-classic cases may have a poorer outcome; in particular, none of these cases survived after relapse. These results may be influenced by differences in the coincident mutations in the two groups. The majority of recurrent mutations with known prognostic significance in AML are uncommon in CEBPA cases,32 and for many of them their impact in this subgroup is, therefore, not well defined. Both FLT3 and DNMT3A mutations adversely impact on the favorable outcome of CEBPA AML.286 But even when patients with these mutations were excluded from the analysis, OS for the non-classic cases was still worse. The incidence of GATA2 mutations was non-significantly lower in the non-classic cases, but although one study reported that they are associated with better OS,33 most studies, including our own, observed no difference.3534 There was a non-significantly higher incidence of TET2 mutations in the non-classic cases, but their impact is unclear, with only one study reported specifically for CEBPA AML that showed a worse OS but not event-free survival in TET2 cases.33 Clearly, many more cases would need to be analyzed in order to take into account coincident mutations other than FLT3 and DNMT3A mutations.

A wide range of non-classic mutations was observed and, for the outcome analysis, sufficient patient numbers could only be obtained by grouping all the non-classic patients together, which precluded evaluation of specific mutant combinations. We, therefore, sought alternative methods of assessment and, as CEBPA patients have a distinct hypermethylated profile,2322 investigated whether genome-wide methylation profiling could provide information on the more broad-spectrum functional consequence of different mutants. We confirmed the relatively hypermethylated profile associated with a CEBPA genotype in a preliminary cohort and then derived methylation signatures for CEBPA and CEBPA cases using the 25 most differentially methylated CpG sites. These were validated in an independent cohort of samples, with 16 of the 17 CEBPA cases studied clearly separating from the CEBPA cases. The remaining case contained a significant proportion of non-mutated cells, which provided indirect evidence that the signatures reflected CEBPA genotype. The signatures were a distinct feature of mutant C/EBPα and could not simply be attributed to a lack of C/EBPα, as they were not replicated in samples from patients with core-binding factor leukemias that are associated with downregulation of CEBPA expression. Presence of at least a minimal level of C/EBPα activity is thought to be necessary for the development of leukemia as Cebpa−/ mice with totally absent C/EBPα accumulate immature myeloid progenitors but do not develop AML,3736 and AML patients have not been reported with mutations leading to complete absence of C/EBPα. These results, therefore, suggest that it is the functionally aberrant C/EBPα protein that underlies the hypermethylated profile detected in the CEBPA cases.

The CEBPA cases provided a framework for assessing the methylation profiles of mutant combinations with at least one non-classic mutant. Only 31% had a methylation profile equivalent to CEBPA, 25% were equivalent to CEBPA, and 44% were intermediate between the two. Similar heterogeneity has been reported for gene expression profiles of non-classic cases, with 3 of 7 such cases segregating from cases with classical mutants.20 This variability is not surprising considering the diversity of the mutant combinations. Although the p30 isoform is thought to play an important role in allowing commitment of the leukemic stem cell to the myeloid lineage,38 the mechanism by which it promotes AML is not clearly defined. It has a lower affinity for some C/EBP sites than p42 and induces multiple genes that are not affected by p42,4139 and this may have influenced the methylation profile. Knock/in mice expressing just N-terminal mutant developed leukemia but more slowly than the N+C combination.4238 This presumably reflects the additional influence of an aberrant C-terminally mutated protein that might not bind to DNA but can still bind to other C/EBP interacting proteins, such as PU.1 and the SWI/SNF complex. Classic C-terminal mutants are associated with hyperproliferation due to loss of cell-cycle regulation and a block in myeloid differentiation.43 Although knock/in mice with classic C mutant alone do develop leukemia, it is with slower latency than the N+C and mutant N mice.42 Since these mutants may still bind and potentially sequester other interacting factors, it has been suggested that this could limit the ability of other C/EBPs to rescue the effect of the aberrant C/EBPα,2 as shown for C/EBPβ in the C/EBPα-deficient situation.4544 This more global cellular impact of the C-terminal mutants may have a greater consequence for signaling events downstream of C/EBPα, which may, therefore, be reflected in the methylation profile.

The methylation profiles did not group according to the predicted functional consequence of the mutant, whether N- or C-terminally mutated. For example, considerable variability was observed for the cases with a C-missense mutation. Of the three classic N plus C-missense combinations assayed, 1 case had a methylation profile equivalent to CEBPA and 2 cases had intermediate profiles. Two homozygous C-missense cases grouped with CEBPA cases, whereas another homozygous C-missense case grouped with the CEBPA cases. In the 51 cases documented with C-missense mutations in the COSMIC database (http://cancer.sanger.ac.uk/cosmic), most mutations are unique, reported in 1 (n=27, 53%) or 2 (n=9, 18%) patients, and only two residues (R297 and R300) are recorded as being variably mutated in 5 patients. Critical amino acids at the bZIP/DNA interface have been identified from the C/EBPα crystal structure, but many additional hydrogen bonds and van der Waals contacts are implicated in the stabilization of these interactions.46 Thus, predicting the functional consequence of these mutants is difficult.

From a clinical perspective, risk management requires evaluation of all the available information, and the data presented here suggest that CEBPA patients with a non-classic mutation should not automatically be included in the same favorable-risk prognostic group as CEBPA cases; it might be appropriate to consider them for allogeneic transplantation in first remission. Ultimately, this can only be proven by analysis of clinical trial outcomes and, with the increasing availability of large data sets using targeted next-generation sequencing panels, such analysis may be feasible in the future. This will also promote a better understanding of the mutational background of classic and non-classic CEBPA cases and whether there are differences that impact on their prognosis. Our studies also raise the possibility that methylation profiling may identify those non-classic cases that behave in a similar manner to classic mutants; although we cannot directly attribute a causal link between the methylation pattern and chemosensitivity, and further studies are required before this is introduced into clinical practice.

Acknowledgments

The authors would like to thank Kerra Pearce at UCL Genomics for technical assistance.

Footnotes

  • Check the online version for the most updated information on this article, online supplements, and information on authorship & disclosures: www.haematologica.org/content/103/1/91
  • FundingThis work was supported by Leukaemia and Lymphoma Research, now called Bloodwise, the UK Medical Research Council and Cancer Research UK, and was undertaken at UCL, which receives a proportion of funding from the Department of Health’s NIHR Biomedical Research Centre’s funding scheme.
  • Received May 19, 2017.
  • Accepted October 10, 2017.

References

  1. Friedman AD. C/EBPalpha in normal and malignant myelopoiesis. Int J Hematol. 2015; 101(4):330-341. PubMedhttps://doi.org/10.1007/s12185-015-1764-6Google Scholar
  2. Ohlsson E, Schuster MB, Hasemann M, Porse BT. The multifaceted functions of C/EBPalpha in normal and malignant haematopoiesis. Leukemia. 2016; 30(4):767-775. Google Scholar
  3. Wouters BJ, Lowenberg B, Erpelinck-Verschueren CA, van Putten WL, Valk PJ, Delwel R. Double CEBPA mutations, but not single CEBPA mutations, define a subgroup of acute myeloid leukemia with a distinctive gene expression profile that is uniquely associated with a favorable outcome. Blood. 2009; 113(13):3088-3091. PubMedhttps://doi.org/10.1182/blood-2008-09-179895Google Scholar
  4. Dufour A, Schneider F, Metzeler KH. Acute myeloid leukemia with biallelic CEBPA gene mutations and normal karyotype represents a distinct genetic entity associated with a favorable clinical outcome. J Clin Oncol. 2010; 28(4):570-577. PubMedhttps://doi.org/10.1200/JCO.2008.21.6010Google Scholar
  5. Pabst T, Eyholzer M, Fos J, Mueller BU. Heterogeneity within AML with CEBPA mutations; only CEBPA double mutations, but not single CEBPA mutations are associated with favourable prognosis. Br J Cancer. 2009; 100(8):1343-1346. PubMedhttps://doi.org/10.1038/sj.bjc.6604977Google Scholar
  6. Green CL, Koo KK, Hills RK, Burnett AK, Linch DC, Gale RE. Prognostic significance of CEBPA mutations in a large cohort of younger adult patients with acute myeloid leukemia: impact of double CEBPA mutations and the interaction with FLT3 and NPM1 mutations. J Clin Oncol. 2010; 28(16):2739-2747. PubMedhttps://doi.org/10.1200/JCO.2009.26.2501Google Scholar
  7. Taskesen E, Bullinger L, Corbacioglu A. Prognostic impact, concurrent genetic mutations, and gene expression features of AML with CEBPA mutations in a cohort of 1182 cytogenetically normal AML patients: further evidence for CEBPA double mutant AML as a distinctive disease entity. Blood. 2011; 117(8):2469-2475. PubMedhttps://doi.org/10.1182/blood-2010-09-307280Google Scholar
  8. Fasan A, Haferlach C, Alpermann T. The role of different genetic subtypes of CEBPA mutated AML. Leukemia. 2014; 28(4):794-803. PubMedhttps://doi.org/10.1038/leu.2013.273Google Scholar
  9. Li HY, Deng DH, Huang Y. Favorable prognosis of biallelic CEBPA gene mutations in acute myeloid leukemia patients: a meta-analysis. Eur J Haematol. 2015; 94(5):439-448. Google Scholar
  10. Dohner H, Estey EH, Amadori S. Diagnosis and management of acute myeloid leukemia in adults: recommendations from an international expert panel, on behalf of the European LeukemiaNet. Blood. 2010; 115(3):453-474. PubMedhttps://doi.org/10.1182/blood-2009-07-235358Google Scholar
  11. O’Donnell MR, Abboud CN, Altman J. Acute myeloid leukemia. J Natl Comp Cancer Network. 2012; 10(8):984-1021. Google Scholar
  12. Ofran Y, Rowe JM. Genetic profiling in acute myeloid leukaemia–where are we and what is its role in patient management. Br J Haematol. 2013; 160(3):303-320. PubMedhttps://doi.org/10.1111/bjh.12135Google Scholar
  13. Cornelissen JJ, Gratwohl A, Schlenk RF. The European LeukemiaNet AML Working Party consensus statement on allogeneic HSCT for patients with AML in remission: an integrated-risk adapted approach. Nat Rev Clin Oncol. 2012; 9(10):579-590. PubMedhttps://doi.org/10.1038/nrclinonc.2012.150Google Scholar
  14. Nerlov C. C/EBPalpha mutations in acute myeloid leukaemias. Nat Rev Cancer. 2004; 4(5):394-400. PubMedhttps://doi.org/10.1038/nrc1363Google Scholar
  15. Fitzgibbon J, Smith LL, Raghavan M. Association between acquired uniparental disomy and homozygous gene mutation in acute myeloid leukemias. Cancer Res. 2005; 65(20):9152-9154. PubMedhttps://doi.org/10.1158/0008-5472.CAN-05-2017Google Scholar
  16. Wouters BJ, Sanders MA, Lugthart S. Segmental uniparental disomy as a recurrent mechanism for homozygous CEBPA mutations in acute myeloid leukemia. Leukemia. 2007; 21(11):2382-2384. PubMedhttps://doi.org/10.1038/sj.leu.2404795Google Scholar
  17. Shih LY, Liang DC, Huang CF. AML patients with CEBPalpha mutations mostly retain identical mutant patterns but frequently change in allelic distribution at relapse: a comparative analysis on paired diagnosis and relapse samples. Leukemia. 2006; 20(4):604-609. PubMedhttps://doi.org/10.1038/sj.leu.2404124Google Scholar
  18. Benthaus T, Schneider F, Mellert G. Rapid and sensitive screening for CEBPA mutations in acute myeloid leukaemia. Br J Haematol. 2008; 143(2):230-239. PubMedhttps://doi.org/10.1111/j.1365-2141.2008.07328.xGoogle Scholar
  19. Behdad A, Weigelin HC, Elenitoba-Johnson KS, Betz BL. A clinical grade sequencing-based assay for CEBPA mutation testing: report of a large series of myeloid neoplasms. J Mol Diag. 2015; 17(1):76-84. PubMedhttps://doi.org/10.1016/j.jmoldx.2014.09.007Google Scholar
  20. Lavallee VP, Krosl J, Lemieux S. Chemo-genomic interrogation of CEBPA mutated AML reveals recurrent CSF3R mutations and subgroup sensitivity to JAK inhibitors. Blood. 2016; 127(24):3054-3061. PubMedhttps://doi.org/10.1182/blood-2016-03-705053Google Scholar
  21. Wouters BJ, Jorda MA, Keeshan K. Distinct gene expression profiles of acute myeloid/T-lymphoid leukemia with silenced CEBPA and mutations in NOTCH1. Blood. 2007; 110(10):3706-3714. PubMedhttps://doi.org/10.1182/blood-2007-02-073486Google Scholar
  22. Figueroa ME, Lugthart S, Li Y. DNA methylation signatures identify biologically distinct subtypes in acute myeloid leukemia. Cancer Cell. 2010; 17(1):13-27. PubMedhttps://doi.org/10.1016/j.ccr.2009.11.020Google Scholar
  23. Genomic and epigenomic landscapes of adult de novo acute myeloid leukemia. New Engl J Med. 2013; 368(22):2059-2074. PubMedhttps://doi.org/10.1056/NEJMoa1301689Google Scholar
  24. Figueroa ME, Wouters BJ, Skrabanek L. Genome-wide epigenetic analysis delineates a biologically distinct immature acute leukemia with myeloid/T-lymphoid features. Blood. 2009; 113(12):2795-2804. PubMedhttps://doi.org/10.1182/blood-2008-08-172387Google Scholar
  25. Sproul D, Kitchen RR, Nestor CE. Tissue of origin determines cancer-associated CpG island promoter hypermethylation patterns. Genome Biol. 2012; 13(10):R84. PubMedhttps://doi.org/10.1186/gb-2012-13-10-r84Google Scholar
  26. Sproul D, Nestor C, Culley J. Transcriptionally repressed genes become aberrantly methylated and distinguish tumors of different lineages in breast cancer. Proc Natl Acad Sci USA. 2011; 108(11):4364-4369. PubMedhttps://doi.org/10.1073/pnas.1013224108Google Scholar
  27. Illingworth RS, Gruenewald-Schneider U, Webb S. Orphan CpG islands identify numerous conserved promoters in the mammalian genome. PLoS Gen. 2010; 6(9):e1001134. Google Scholar
  28. Gale RE, Lamb K, Allen C, El-Sharkawi D, Stowe C, Jenkinson S. Simpson’s Paradox and the Impact of Different DNMT3A Mutations on Outcome in Younger Adults With Acute Myeloid Leukemia. J Clin Oncol. 2015; 33(18):2072-2083. PubMedhttps://doi.org/10.1200/JCO.2014.59.2022Google Scholar
  29. Pabst T, Mueller BU, Harakawa N. AML1-ETO downregulates the granulocytic differentiation factor C/EBPalpha in t(8;21) myeloid leukemia. Nat Med. 2001; 7(4):444-451. PubMedhttps://doi.org/10.1038/86515Google Scholar
  30. Ptasinska A, Assi SA, Martinez-Soria N. Identification of a dynamic core transcriptional network in t(8;21) AML that regulates differentiation block and self-renewal. Cell Rep. 2014; 8(6):1974-1988. PubMedhttps://doi.org/10.1016/j.celrep.2014.08.024Google Scholar
  31. Helbling D, Mueller BU, Timchenko NA. CBFB-SMMHC is correlated with increased calreticulin expression and suppresses the granulocytic differentiation factor CEBPA in AML with inv(16). Blood. 2005; 106(4):1369-1375. PubMedhttps://doi.org/10.1182/blood-2004-11-4392Google Scholar
  32. Papaemmanuil E, Gerstung M, Bullinger L. Genomic Classification and Prognosis in Acute Myeloid Leukemia. New Engl J Med. 2016; 374(23):2209-2221. PubMedhttps://doi.org/10.1056/NEJMoa1516192Google Scholar
  33. Grossmann V, Haferlach C, Nadarajah N. CEBPA double-mutated acute myeloid leukaemia harbours concomitant molecular mutations in 76.8% of cases with TET2 and GATA2 alterations impacting prognosis. Br J Haematol. 2013; 161(5):649-658. PubMedhttps://doi.org/10.1111/bjh.12297Google Scholar
  34. Green CL, Tawana K, Hills RK. GATA2 mutations in sporadic and familial acute myeloid leukaemia patients with CEBPA mutations. Br J Haematol. 2013; 161(5):701-705. PubMedhttps://doi.org/10.1111/bjh.12317Google Scholar
  35. Theis F, Corbacioglu A, Gaidzik VI. Clinical impact of GATA2 mutations in acute myeloid leukemia patients harboring CEBPA mutations: a study of the AML study group. Leukemia. 2016; 30(11):2248-2250. Google Scholar
  36. Heath V, Suh HC, Holman M. C/EBPalpha deficiency results in hyperproliferation of hematopoietic progenitor cells and disrupts macrophage development in vitro and in vivo. Blood. 2004; 104(6):1639-1647. PubMedhttps://doi.org/10.1182/blood-2003-11-3963Google Scholar
  37. Zhang P, Iwasaki-Arai J, Iwasaki H. Enhancement of hematopoietic stem cell repopulating capacity and self-renewal in the absence of the transcription factor C/EBP alpha. Immunity. 2004; 21(6):853-863. PubMedhttps://doi.org/10.1016/j.immuni.2004.11.006Google Scholar
  38. Kirstetter P, Schuster MB, Bereshchenko O. Modeling of C/EBPalpha mutant acute myeloid leukemia reveals a common expression signature of committed myeloid leukemia-initiating cells. Cancer Cell. 2008; 13(4):299-310. PubMedhttps://doi.org/10.1016/j.ccr.2008.02.008Google Scholar
  39. Cleaves R, Wang QF, Friedman AD. C/EBPalphap30, a myeloid leukemia oncoprotein, limits G-CSF receptor expression but not terminal granulopoiesis via site-selective inhibition of C/EBP DNA binding. Oncogene. 2004; 23(3):716-725. PubMedhttps://doi.org/10.1038/sj.onc.1207172Google Scholar
  40. Geletu M, Balkhi MY, Peer Zada AA. Target proteins of C/EBPalphap30 in AML: C/EBPalphap30 enhances sumoylation of C/EBPalphap42 via up-regulation of Ubc9. Blood. 2007; 110(9):3301-3309. PubMedhttps://doi.org/10.1182/blood-2007-01-071035Google Scholar
  41. Wang C, Chen X, Wang Y, Gong J, Hu G. C/EBPalphap30 plays transcriptional regulatory roles distinct from C/EBPalphap42. Cell Res. 2007; 17(4):374-383. PubMedGoogle Scholar
  42. Bereshchenko O, Mancini E, Moore S. Hematopoietic stem cell expansion precedes the generation of committed myeloid leukemia-initiating cells in C/EBPalpha mutant AML. Cancer Cell. 2009; 16(5):390-400. PubMedhttps://doi.org/10.1016/j.ccr.2009.09.036Google Scholar
  43. Kato N, Kitaura J, Doki N. Two types of C/EBPalpha mutations play distinct but collaborative roles in leukemogenesis: lessons from clinical data and BMT models. Blood. 2011; 117(1):221-233. PubMedhttps://doi.org/10.1182/blood-2010-02-270181Google Scholar
  44. Jones LC, Lin ML, Chen SS. Expression of C/EBPbeta from the C/ebpalpha gene locus is sufficient for normal hematopoiesis in vivo. Blood. 2002; 99(6):2032-2036. PubMedhttps://doi.org/10.1182/blood.V99.6.2032Google Scholar
  45. Hirai H, Zhang P, Dayaram T. C/EBPbeta is required for ‘emergency’ granulopoiesis. Nat Immunol. 2006; 7(7):732-739. PubMedhttps://doi.org/10.1038/ni1354Google Scholar
  46. Miller M, Shuman JD, Sebastian T, Dauter Z, Johnson PF. Structural basis for DNA recognition by the basic region leucine zipper transcription factor CCAAT/enhancer-binding protein alpha. J Biol Chem. 2003; 278(17):15178-15184. PubMedhttps://doi.org/10.1074/jbc.M300417200Google Scholar

Article Information

Vol. 103 No. 1 (2018): January, 2018 : Articles
 
DOI
https://doi.org/10.3324/haematol.2017.173096
Pubmed
29025912
Pubmed Central
PMC5777194
 
Published
2018-01-01
Published By
Ferrata Storti Foundation, Pavia, Italy
Print ISSN
0390-6078
Online ISSN
1592-8721
 

Article Usage

Online Views
1020
PDF Downloads
273

Statistics from Altmetric.com

No Data
Navigate
For Authors
For Reviewers
For Advertisers
Education
Privacy
More
Copyright © 2024 by the Ferrata Storti Foundation | Web design → | Development →
ISSN 0390-6078 print | ISSN 1592-8721 online