Clinical values of gene alterations as marker of minimal residual disease in non-M3 acute myeloid leukemia

ABSTRACT Acute myeloid leukemia (AML) is a malignant disease of the hematopoietic system. Residual leukemic cells after treatment are associated with relapse. Thus, detecting minimal residual disease (MRD) is significant. Major techniques for MRD assessment include multiparameter flow cytometry (MFC), polymerase chain reaction (PCR), and next-generation sequencing (NGS). At a molecular level, AML is the consequence of collaboration of several gene alterations. Some of these gene alterations can also be used as MRD markers to evaluate the level of residual leukemic cells by PCR and NGS. However, when as MRD markers, different gene alterations have different clinical values. This paper aims to summarize the characteristics of various MRD markers, so as to better predict the clinical outcome of AML patients and guide the treatment.


Introduction
AML is a malignant disease of myeloid hematopoietic stem/progenitor cells. With classical '7 + 3' regimens (regimens with 3 days of an anthracycline and 7 days of cytarabine) as induction therapy for AML patients, 60%-80% of younger adults and 40%-60% of older adults can achieve CR. However, even if CR or CRi is achieved, relapse is more likely in patients with detectable residual disease. MRD represents the presence of detectable leukemic cells with a sensitivity of 1:10 4 -1:10 6 , however, sensitivity in morphology-based assessments is 1:20 [1]. LSCs can drive relapse, hence the presence of residual LSCs following remission increases the possibility of AML relapse. Thus, it is increasingly important to identify residual disease far below the morphology-based 5% blast threshold [1,2]. As well as relating to prognosis and relapse, MRD is also a significant indicator in the clinical practice of AML [3,4]. Therefore, it is extremely significant to assess MRD in AML patients.

Techniques for MRD assessment
The major techniques for MRD assessment include MFC, PCR, and NGS. MFC techniques based on antigen expression patterns mainly distinguish malignant cells from normal hematopoietic cells by LAIPs which refer to the aberrant expression of markers or marker combinations on the leukemic cells which are either absent or rarely found in normal or recovering BM or normal blood [5][6][7]. Different from MFC, NGS and PCR are mainly aimed at analyzing various gene alterations in AML.

PCR
PCR methods, mainly including RT-qPCR and ddPCR, can be used to evaluate MRD. RT-qPCR can amplify leukemia-associated genetic abnormalities with a sensitivity of 10 −3 -10 −5 [8]. Markers such as NPM1 and several fusion genes, such as CBFB-MYH11, RUNX1-RUN1T1 and PML-RARA can be applied in this technology. Some studies though suggest that certain markers like FLT3, NRAS, KRAS and IDH1/2, are not ideal for several reasons which will be described later on [1, [7][8][9]. The main advantage of RT-qPCR is that it is a widely standardized method for the described targets. However, compared to MFC, RT-qPCR is only applicable in less than 40% of patients [1, 2,8]. ddPCR is a method based on water-oil emulsion droplet technology and implementing PCR data with Poisson statistics, which allows quantification of the number of target molecules in a sample [10]. ddPCR can absolutely quantify the target gene without the need for a standard curve and has higher precision, which is the most significant advantage compared to RT-qPCR [10,11]. The sensitivity of ddPCR can reach 1:100,000 and its absolute precision depends on the mean number of molecules per partition, although the cost is the method's main limitation [2]. There are also various other parameters that need to be standardized both in RT-qPCR and ddPCR, including sample processing, sample type, heparin vs. EDTA tubes for sample collecting and analytical cutoffs.

NGS
MRD detection by NGS is based on measuring all mutations [12]. NGS, via allowing parallel and repeated sequencing of millions of small DNA fragments can evaluate a few gene or an entire genome [13]. Main NGS technologies include WGS, WES, and Targetedgene sequencing [14]. Since most clinically relevant mutations are known for myeloid malignant, targeted sequencing is a common detection method at present [12]. NGS is widely used in myeloid malignancies in clinical practice by introducing a variety of commercially available panels which can cover between 25 and more than 50 relevant genes/hotspots, such as the Illumina TruSight Myeloid panel, the Human Myeloid Neoplasms QIASeq DNA Panel and so on. Among most AML patients, more than one recurrent somatic mutation can be detected by using comprehensive myeloid gene panels [12,15]. RTq-PCR/ddPCR belong to single-gene methods for MRD assessment and are subject to false negative results due to clonal evolution because AML patients can relapse with different mutations from those in diagnosis. In contrast, NGS can assess multiple genes simultaneously and allow the tracking of distinct mutational patterns, therefore false negative results caused by clonal evolution can be avoided [15,16]. Nevertheless, the sensitivity of NGS could be limited by the sequencing error rate. This limitation can be overcome by errorcorrected sequencing, one of NGS techniques in hemato-oncology, which is based on barcoding the individual DNA molecules used for NGS library preparation, as this technique circumvents the standard NGS sensitivity of 1% VAF [2,7,8,12,15]. VAF (mutant sequencing reads / total sequencing reads) depends on allele coverage, thus for the purpose of detecting the often rather low VAFs of mutations at early relapse, high levels of coverage are necessary [15]. Moreover, factors that need to be standardized for NGS include the sequencing platform, the library preparation protocol, the choice of clinically relevant genes to be targeted, depth of coverage required and data analysis pipeline and variant calling algorithms [7]. In general, NGS is relatively easy to perform, sensitive and applicable to specific subgroups. However, in addition to the limited sensitivity and specificity, and statistical and computational challenges, the disadvantage of NGS-based MRD is the inability to distinguish between residual leukemia and clonal hematopoiesis [8,17].

Markers in MRD assessment
The occurrence of AML is the result of many factors. At the molecular level, AML is the consequence of collaboration between at least three broad classes of gene alterations [18]. On one hand, these gene alterations work together to cause AML, on the other hand, some of them could be used as markers to assess MRD in order to better monitor the progress of the disease and provide a reference for the selection of treatment options.

Class I gene alterations
Class I gene alterations, including FLT3, KIT and RASassociated signaling pathway, could activate signal transduction pathways and enhance proliferation with survival advantages of hematopoietic stem cells [18,19].

KIT
c-KIT is common in CBF-AML (about ∼20%), which is associated with a higher incidence of relapse [32,36]. KITmut is rarely used as a marker of MRD, but it is associated with MRD. Especially mutations at exon 17 have inferior prognostic impact in patients with RUNX1-RUNX1T1, rather than in patients with CBFB-MYH11, and are related to the presence of MRD. At EOT, KITmut is associated with higher RUNX1-RUNX1T1 transcript levels, higher levels of reduction and the lower proportion of achievement of MRDneg [32,[36][37][38][39].
3.1.3 RAS-associated signaling pathway RAS mutations are accounted for 15%-40% in AML, which have no impact on survival or remission and can be lost as the disease progresses [40,41]. Ishida et al. support that RAS pathway mutations, which are highly unstable at relapse, should be chosen as a target with caution [42]. However, when monitoring MRD by NGS [36,43], NRAS mutation is associated with moderate to high positive predictive value, and KRAS mutation is related to high negative predictive value and can be used to evaluate the efficiency of NGS panel.
3.2.1 RUNX1-RUNX1T1 and CBFB-MYH11 in CBF-AML AML with chromosomal translocation t (8;21) or chromosomal rearrangement inv (16;16), corresponding to the RUNX1-RUNX1T1 or CBFB-MYH11 fusion genes are known as CBF-AML, which accounts for about 15% of adult AML [44]. CBF-AML belongs to a favorable risk category as per 2017 ELN risk stratification, however about 40% of these patients can relapse [45]. Thus, it is significant to identify patients who may relapse, in which RUNX1-RUNX1T1 and CBFB-MYH11 play an important role as MRD markers.
MFC, PCR and FISH can be applied in detecting residual leukemia cells carrying RUNX1-RUNX1T1 and CBFB-MYH11 fusion genes. Researchers found that the concordance rate was 67% between FCM and RT-qPCR [46], 63.7% between FACS-FISH and RT-PCR, and 64.3% between FACS-FISH and FC [47]. Furthermore, various MRD techniques are complementary. The combined use of these different MRD techniques can predict the prognosis and relapse more accurately [46][47][48]. For example, Ouyang et al. [48] carried on research about CBF-AML and found that RT-qPCR levels between 0.1% and 10% failed to differentiate the risk of relapse, however, MFC positivity could identify individuals with higher relapse risk after induction therapy in this group of patients.
3.2.1.1 RUNX1-RUNX1T1. RUNX1-RUNX1T1 as an MRD marker is with less controversy. At various stages of leukemia treatment, its transcript levels, log reduction and conversion from MRDneg to MRDpos hold critical significance (shown in Figure 1(A)).
After induction therapy, presence of <100 copies in BM and <1000 copies in PB were prognostic, which can identify 47% of patients with a CIR of 7% (representing 15% of all relapsing patients) and identify 78% of patients with a CIR of 15% (compared with 50% in the remaining 22%), respectively [49]. Moreover, a cut-off level of about 2-3 log reduction was with prognostic value. Patients whose copies were beyond this threshold, including pediatric patients, were associated with lower CIR and superior OS [37,49,50].
During follow-up period, >500 RUNX1-RUNX1T1 copies in BM and >100 copies in PB could discriminate patients with a higher risk of relapse and shorter survival [49]. Research showed a lower cut-off value: MRD transcript level ≤150 in BM and ≤50 in PB. There were two reasons, differences in material that was used and in sensitivity of the MRD assays. Further, they also reported that in both BM and PB, achievement of MRDneg and repetitive MRDneg can predict a lower rate of relapse. For patients converted from MRDneg to MRDpos, the rate of relapse was 24% in BM and 64% in PB [37]. Nonetheless, there was no analysis between the above patients and those who had not converted from MRD negative to MRD positive.
RUNX1-RUNX1T1 as an MRD marker is also commonly applied to monitor transplant patients. From Qin YZ's study, more than 12 months after allo-HSCT, <4 log reduction can accurately predict relapse [53]. However, some researchers believe that PCR-MRD following allo-HSCT was more predictive of relapse rather than MRD before transplantation, for the reason that in their research before allo-HSCT there was no direct correlation between MRD level and relapse. One of the limitations of this single-center study was the small numbers of patients [54].
Further, treatment regimens have an impact on MRD for RUNX1-RUNX1T1. There were greater MRD log reductions in transcripts of patients given GO [49]. Dasatinib treatment was associated with lower RUNX1-RUNX1T1 transcript levels and stronger MRD reduction, as well as with achievement of MRDneg at EOT [37]. Compared to the standard dose group (60 mg/m 2 /d), MRD log reduction was faster and deeper, and the percentage of patients that achieved a 3 log reduction was higher in the high dose daunorubicin group (90 mg/m 2 /d) [55].
Besides, it could also indicate treatment strategies. Research showed that CBF-AML patients with low levels of RT-PCR (between 0.01 and 0.05) at the conclusion of induction/consolidation chemotherapy, benefited most from maintenance HMA, particularly those who had a reduction in the RT-PCR within the first 2 cycles of HMA therapy [56]. Its MRD could also direct IFN-α treatment for AML patients with t(8;21) who were MRD positive after allo-HSCT [57].
After induction therapy, PB transcript levels, PB log reduction(<1 vs. ≥1) and BM copy number (>100) were significant. In terms of PB transcript levels, which was the most prognostic factor, CIR and survival rate from CR were 21% and 89% for patients with a transcript level of <10 copies, whereas they were 56% and 45% for patients with a level of 10-500 copies, 100% and 67% for patients with a level of >500 copies [49]. While BM log reduction levels had little to do with RFS [49,58]. For pediatric patients, similarly with RUNX1-RUNX1T1, <2 log reduction in CBFB-MYH11 transcript level, after the first and second cycle of ICE, was associated with higher CIR [50].
During follow-up, the persistence of inv (16) has been described in patients in long-term remission [58]. CBFB-MYH11 copies > 50 in BM and > 10 in PB were associated with a higher rate of relapse and shorter survival from CR [49]. In another study, the follow-up time period was defined as more than 4 weeks after completion of the last consolidation cycle. It was reported that among 14 patients who relapsed, none of them achieved PCRneg in BM during follow-up, and 13 of them had persistently higher copy ratios. For patients who converted from PCRneg to PCRpos with CBFB-MYH11 copy ratios greater than 10, the median time to relapse was 6 months, for those with CBFB-MYH11 copy ratios of less than 10, the median time was 21 months and for ≥ 1 log rise in PCR levels imminent relapse was predicted [61].
Before transplant, CBFB-MYH11 expression levels can be used as a marker to identify high-risk patients: patients with preMRD > 0.2% before HLA-MSDT can predict a higher CIR, lower LFS and OS [62]. At the time of allo-HSCT, MRD by RT-PCR ≥ 1% was associated with inferior OS and LFS, but it was not related to increased relapse incidence. On day + 100 after allo-HSCT, although patients who were MRDpos (transcript ratio > 0.001%) had a higher incidence of relapse (27.6% vs. 9.7%), there was no statistical significance [63]. However, another study, in which a cut-off value of 0.2% was used in CBFB/MYH11-positive AML, reported that a post-transplant MRD level higher than 0.2% can predict a higher CIR and lower LFS [62]. In Tang's research, the 3-year CIR and LFS were 8.6% vs. 43.2% and 71.7% vs. 44.5% for patients with a 3-log MRD reduction at each of the first 3 months after transplantation and without a 3-log MRD reduction at least once in the first 3 months, respectively [54].

NPM1
AML with NPM1 mutation occurs in approximately 30% of adult AML patients and 60% of adult AML patients with normal karyotype, which is the most common subtype and represents a favorable outcome [64,65]. NPM1 mutation as a molecular characteristic for AML is an ideal marker to assess MRD (shown in Figure 1(C)).
After double induction therapy, compared with patients with refractory diseases, NPM1 transcript level, which can be considered as a considerable prognostic marker for remission duration and OS, was significantly lower for patients who achieved CR (61 vs.1542 NPM1mut/10 4 ABL copies). Also, for patients who achieved RNA-based RQ-PCR negative, which was defined as no detectable NPM1 m transcript, the 4-year CIR was 6.5% in contrast to 55.3% [66]. MRD log reduction is also a significant predictor with a cut-off value of 4 log reduction being confirmed [67,68]. Besides, among patients with a > 4 log reduction in PB-MRD, the risk of relapse was similar between patients with a positive PB-or BM-MRD and patients with both MRD negative [68].
Research established two cut-off levels of absolute NPM1 m ratio of 0.01 and of 3 log reduction, which displayed low sensitivities of 32% and 22%, but high specificities of 92% and 100%. In multivariate analysis with age and ELN risk stratification after consolidation, the NPM1 m ratio and kinetics exceeding the established cut-off levels were the only prognostic variables for CIR and OS [69]. From other studies, thresholds of 1 log change in VAF, 3 log reduction or 0.01% of NPM1 m/ABL ratio also had statistical significance [70][71][72].
During follow up, in Schnittge's study [73], 1227 samples were divided into different sub cohorts, and follow-up period was divided into four time intervals (interval 1/2/3/4 for MRD assessments between day18-60, 61-120, 121-365, > 365 after begin of therapy, respectively). The first cohort was evaluated during and after intensive first-line therapy. The second cohort was evaluated during second-line chemotherapy after relapse or persistence of leukemia. The NPM1/ABL1 mutation thresholds of 0.01% in the first cohort and 0.1% in the second cohort can be successfully applied to distinguish patients with longer and shorter survival. When the molecular prediction of relapse was analyzed, based on their data, they reported that sampling intervals of 42 days would allow one to early predict 75% of all relapses. In another study, researchers observed that sensitivity, specificity and both positive and negative predictive value of a cut-off NPM1 m ratio of 1 were 100%within 100 days, for patients with values below this cut-off, none of them relapsed. In contrast, all patients with values higher than this cut-off relapsed with a median time of 58 days [69].
Shayegi thought that at lower MRD levels, the allogeneic graft is able to repress leukemia, but after crossing a certain MRD burden, the graft-versus-leukemia reaction is no longer sufficient for preventing relapse [74]. Thus, among patients who received transplantation, NPM1 MRD is a critical marker. A MRD cut-off value of 0.01% before transplantation has prognostic value [72,73]. Bill defined MRDneg by ddPCR as NPM1 m burden ≤ 0.01% or < 3 positive droplets in three wells. They observed that pre-transplant MRDpos can predict for higher 2-year CIR and lower OS compared to pre-transplant MRDneg (CIR:64.7 vs. 6.0%; OS:38.8 vs. 71.7%, respectively). In their research, they found a phenomenon that at the time of allo-HSCT, MRDpos patients were less often in CR1 and more frequently in CR2. This could indicate that patients who have experienced relapse before, might be more difficult to get into a deep molecular response in a later CR [75]. A threshold of 0.02% also had prognostic significance both before and after transplantation in Delsing's study, but their limitation was the small number of samples [76]. However, according to Kayser [77], pre-transplant NPM1 MRD level > 1% (less than 100 copies of mutated NPM1/10 4 ABL1 copies) by RT-qPCR was an independent prognostic factor for poor survival. After allo-HSCT, an effect of NPM1 m level on survival could be shown for samples analyzed between 61-120 and 121-365 days` [73].
As mentioned above, risk stratification for AML patients with NPM1 can be done according to its specific MRD thresholds. But some scholars hold the opposite opinion [78]. They concluded that the binary presence or absence of an NPM1 mutation, combined with MRD levels following induction therapy, should continue to be used in therapeutic management rather than stratification according to the NPM1mut level. One reason was that the prognostic impact of the NPM1mut level is largely, albeit not entirely, due to the concomitant FLT3-ITD mutations. In fact, the level of NPM1 MRD is closely related to therapy. For patients with a <4 PB-MRD log reduction between NPM1 m base line level and NPM1 m MRD at CR/CRp or for patients with MRDpos (>0.01%) after consolidation therapy, DFS and OS were significantly improved by allo-HSCT. This benefit was not observed in patients with a >4 log reduction in PB-MRD or MRDneg [68,72]. However, between the NPM1 positive and negative cohorts with azacitidine therapy, there was no OS difference, which suggested a limited therapeutic impact of HMA in NPM1 positive AML [79]. Both after induction therapy and at EOT, compared to control arm, an NPM1 m MRDneg (<0.1%) was more frequently observed in patients treated with GO [80].

WT1
The expression of WT1 can be detected in about 75%-100% of adult AML patients and is associated with different molecular factors like FLT3, NPM1, PML-RARA, fusion genes in CBF-AML and so on [81,82].
There is a lot of support and opposition to the application of WT1 in MRD detection. On one hand, due to lack of sensitivity and specificity, WT1 is not suggested to be used as an MRD marker unless there is no other MRD marker, especially if NGS and/or digital PCR are not routinely available [1, [7][8][9]83]. Moreover, the prognostic effect of WT1 levels could be misunderstood depending on the distribution of the collaborative mutations [82]. For patients who undergo transplantation, the accuracy and reproducibility of molecular monitoring of WT1 transcripts are affected by the limited regulation of engraftment after allo-HSCT and hematopoietic recovery after intensive chemotherapy [84]. On the other hand, the supporting views are as follows: firstly, WT1 is helpful to improve the reliability of MRD-based prognostic stratification, when there are other MRD markers are present like FLT3-ITD or NMP1 [81,85], or when combining with FCM [86]. Secondly, the expression of WT1 can indicate therapy: those who not achieve MRD negativity after 6 cycles of HMA are considered as candidates for an alternative therapy [87]. Thirdly, WT1 mRNA level can reflect tumor burden [88]. Many researches confirmed that the MRD level of WT1 and its kinetics could distinguish individuals with higher risk to a poor prognosis; like a 2 log reduction after induction and consolidation therapy [81,89,90], or 250 copies/104 ABL before and after transplantation [84,91,92].

TP53
TP53 mutations account for <10% of de novo AML, 20%-37% of secondary AML/therapy-related AML, and are associated with a complex karyotype [93][94][95]. TP53 mutations are a poor prognostic factor, irrespective of the molecular MRD status [17]. Residual TP53 mutations not only can contribute to chemoresistance but also should be included as part of the mutation clearance assessment at CR [16,93,96]. At the time of allo-SCT, TP53 clearance can predict better outcomes in patients who had frontline hypomethylating agent therapy [97].

EVI1
EVI1 is a transcription factor locating on chromosome 3 (3q26.2) [98]. Aberrant expression of EVI1 is present in 8%-10% of AML cases [99]. The overexpression of EVI1 and EVI1 + has a harmful impact on outcome [98][99][100], and a leukemic clone with EVI1 upregulation is persistent in BM follow-up [101]. About 20% of AML with EVI1 overexpression are associated with a normal karyotype and two-thirds of these patients do not have any conventional molecular markers for MRD [102]. The combined MDS-EVI1/EVI1 gene may serve as an alternative MRD marker in AML, especially in samples where other specific markers are lacking [103], but there are some limitations for the usage of EVI1in MRD monitoring. First, quantification of EVI1 expression is complex, because EVI1 has various splice variants and 5 alternative mRNA 5'-ends [104,105]. Second, the magnitude of reduction in EVI1 expression levels between diagnosis and follow-up is not sufficient to allow sensitive detection of MRD. Besides, since high EVI1 overexpression is associated with adverse cytogenetic abnormalities, the distinction between the pejorative influence of EVI1 overexpression by itself and EVI1 overexpression as part of a larger set of unfavorable abnormalities remains challenging [106].

Class III gene alterations
Class III are those alterations that promote epigenetic modifications of chromatin in a large area and affect further transcription factors or components of the transcriptional co-activation complexes [18,19].

IDH1 and IDH2
IDH1 and IDH2 mutations are accounted for about 9%-23% of AML, and often coexist with other genes, like NPM1, FLT3 and so on [107,108]. Some studies have confirmed that IDH mutations are a reliable and effective marker for MRD assessment [107,109,110]. PCR is more sensitive and convenient than NGS for detecting IDH mutations [107,111,112]. In the context of using IDH inhibitors, mutation clearance and kinetics by NGS are associated with clinical response rate [113,114]. However, the predictive/prognostic role of IDH mutations which may be influenced either by the clinical context or by concomitant mutations including FLT3, NPM1 and DNMT3A [108,115], and the possibility of being lost as disease progresses [1, [7][8][9], hinder its application in MRD detection. Some researchers though think that IDH1/2 may be useful when used in combination with a second MRD marker [1].

DTA mutations
DTA mutations, including DNMT3A, TET2 and ASXL1, are associated with CHIP and often initiate mutations that remain in subclinical states for long periods. DTA mutations are not associated with an increased risk of relapse [116,117], but they often persist after induction therapy with a lower probability of clearance (especially DNMT3A and TET2) [16,118].
After transplantation, as late relapse can occur after the re-evolution of persistent pre-leukemic clones, monitoring CHIP lesions in MRD evaluation can have potential benefits on post-graft response and long-term relapse [119]. Although using DNMT3A as MRD marker does not predict the outcome, in the following contexts, DNMT3A monitoring may be beneficial in MRD assessment: after allo-HSCT, monitoring DNMT3A by ddPCR can enhance routine qPCR-based MRD techniques in tracing leukemia dynamics [120]; DNMT3A can only be used as a biomarker for those patients in whom DNMT3A mutation is lost after therapy [121].
However, there are some negative opinions about the role of DTA mutations in MRD detection. Studies have shown that removal of DTA mutations or CHIPrelated mutations that might be considered as pre-leukemic cell identification markers [93], can improve the ability of mutation clearance or MRD to predict the outcomes [116,122]. Meanwhile, DTA mutations are age-related and it were not correlated with an increased relapse rate [116].

MLL-PTD
MLL rearrangements (MLLr) account for 3%-4% of patients with AML and can give rise to 82 known genetic fusions, in which the following 8 are the most common: PTD, AF4, AF6, AF9, AF10, ENL, ELL and EPS15 [123,124]. Monitoring MLL expression and its kinetics by PCR, including PTD, AF9 and other fusions, is conducive to identify high risk of relapse and to direct therapies or intervention [125][126][127][128]. In 80% of patients exhibiting MLL-PTD, the expression of the transcript was high enough to be used as an MRD follow-up tool [129]. MLL-PTD also may be useful when used in combination with a second MRD marker and the expression of MLL gene is more specific and sensitive than WT1 or FCM-MRD [125]. However, occasional loss or gain of MLL-PTD at time of relapse, hinder its use in MRD monitoring [1, 11,129].

Characteristic of MRD markers
As mentioned above, an applicable MRD marker needs at least one of the following conditions (shown as supporting points in Table 1): ①Expression level should be enough to be detected and be stable or persist; ②Have a proportional or inverse relationship between its expression and disease burden; ③Can enhance, complement, or evaluate other MRD technologies; ④Helpful for risk stratification; ⑤Can indicate next steps of therapy; ⑥Could be served as a valuable surrogate endpoint; ⑦Have unique characteristics of gene structure, which can serve as a longitudinal signature; ⑧May be useful when used in combination with a second MRD marker.
However, there are some limitations about some molecular alterations on MRD monitoring, like (shown as opposing points in Table 1): ①Lack of sensitivity or specificity; ②Expression level is age-related; ③Interference with the ability of mutation clearance or MRD to predict the outcomes; ④The prognostic effect of some molecular alterations could be affected by collaborative mutations or cytogenetic abnormalities and clinical context; ⑤Expression is unstable or complex; ⑥Insensitive technology; ⑦The prognostic significance of some mutations is not clear.

Conclusion
MRD plays a critical role in prognosis and treatment for AML. Different subtypes of AML can choose different MRD detection methods. FCM is suitable for most AML patients (more than 85%) [2], but it still has some limitations. The combined application of different MRD detection techniques can improve the detection ability of MRD. Besides, it is very important to select applicable MRD markers according to different molecular characteristic of AML, but every molecular alteration has advantages and limitations, which is the dispute whether it can be used as a good MRD marker. Thus, we need further study and research in order to better guide clinical treatment and improve prognosis.

Disclosure statement
No potential conflict of interest was reported by the author(s).