TO THE EDITOR:

Chromosomal aberrations play a pivotal role in hematological neoplasms, and their identification has profound clinical implications. In many hematological malignancies, including acute myeloid leukemia (AML), the identification of recurrent genetic alterations is critical for the classification and prognostication according to the World Health Organization (WHO) and European LeukemiaNet guidelines.1,2 The isochromosome of the short arm of chromosome 7, i(7)(p10), represents a chromosomal alteration leading to the loss of the long arm (7q) and a duplication of the short arm (7p). To date, there has been only limited systematic analysis of the presence, frequency, and clinical implications of i(7)(p10) in hematological neoplasms; although recently, a patient diagnosed with AML and i(7)(p10) as sole chromosomal abnormality was described and characterized.3 In the 2022 WHO classification, a clear distinction is made between “AML, defined by differentiation” and “AML with defining genetic abnormalities.” The latter category encompasses the subtype AML with myelodysplasia-related (MR) changes with various defining cytogenetic abnormalities including monosomy 7, 7q deletion or loss of 7q due to unbalanced translocation.1 Thus, AML with i(7)(p10) is formally grouped into the AML-MR subgroup.3 

In addition to the aforementioned patient case, the Mitelman Database of Chromosome Aberrations and Gene Fusions in Cancer describes 7 other AML cases with i(7)(p10) as a sole chromosomal alteration, bringing the total number of reported cases, to our knowledge, to only 8.4 Our study aims to address this knowledge gap by systematically analyzing the frequency and occurrence of i(7)(p10) in hematological malignancies, further characterizing additional cytogenetic alterations, identify co-occuring mutations and examine potential clinical implications associated with i(7)(p10).

Diagnoses (from peripheral blood and/or bone marrow) were established based on cytomorphology, immunophenotype, cytogenetics and molecular genetics as previously published according to respective WHO classifications.1,5,6 All patients had given written informed consent to the use of genetic and clinical data according to the Declaration of Helsinki. The study was approved by our internal institutional review board. Cytogenetic and molecular genetic analyses were performed as previously described according to standard methods.7,8 SPSS (version 19.0.0) software (IBM Corporation, Armonk, NY) was used for statistical analyses. All reported P values are 2-sided and were considered significant at P ≤ .05.

Our systematic analysis of 197 467 cases send to MLL Munich Leukemia Laboratory for chromosome banding analysis between September 2005 and June 2022 revealed i(7)(p10) in 34 cases within our patient database. A striking 68% of the identified cases (23/34) were detected in patients diagnosed with AML, making this the most common entity associated with i(7)(p10). Other hematological neoplasms were diagnosed less frequently including mature B-cell neoplasms (B-NHL) in 18% of cases (6/34), myelodysplastic neoplasms in 12% (4/34), and acute lymphoblastic leukemia in 3% of cases (1/34, Figure 1A). Interestingly, i(7)(p10) was found as the sole cytogenetic abnormality in 20 of 34 cases. Almost all of these patients were diagnosed with AML (19 cases), besides 1 case of myelodysplastic neoplasms. Of the remaining cases, 10 cases exhibited additional chromosomal alterations, resulting in a complex karyotype in 5 of 10 cases. Notably, all cases with a complex karyotype were diagnosed as mature B-cell neoplasms (B-NHL). In 4 cases, i(7)(p10) was found in a subclone. Molecular genetic data were available for 18 of 34 cases, offering insights into the genetic landscape of i(7)(p10)–associated hematological neoplasms. Among these cases, DNMT3A (15/18), IDH2 (14/18), and BCOR (7/18) were revealed as the most frequently mutated genes. Because these 18 cases comprised 15 cases diagnosed with AML, further analysis focused on these patients only. Of the 15 cases, mutations in DNMT3A and IDH2 were detected in 14 cases, and BCOR and EZH2 mutations were detected in 7 and 4 cases, respectively (Figure 1B). Of note, in the remaining patient (n = 1) of our cohort not harboring an IDH2 mutation, an IDH1 mutation was detected. Interestingly, the observed pattern of co-occurring mutations in our study differed from the patterns typically associated with AML featuring IDH2 mutations: mutations in SRSF2, ASXL1, NPM1, FLT3-ITD, RUNX1, and NRAS,9,10 were absent or only rarely detected in cases with i(7)(p10) (Figure 1B).

Figure 1.

Summary of co-occurring cytogenetic alterations and comutations. (A) Occurrence of i(7)(p10) and other cytogenetic alterations. The number of cases in which i(7)(p10) was detected in the respective entities is depicted. The color indicates the presence of other cytogenetic alterations (light gray), the detection of i(7)(p10) in a subclone only (dark gray) or the presence as sole abnormality (red). (B) Number of cases with the respective comutations among the 15 AML cases with i(7)(p10). For IDH2 the mutation site is also depicted.

Figure 1.

Summary of co-occurring cytogenetic alterations and comutations. (A) Occurrence of i(7)(p10) and other cytogenetic alterations. The number of cases in which i(7)(p10) was detected in the respective entities is depicted. The color indicates the presence of other cytogenetic alterations (light gray), the detection of i(7)(p10) in a subclone only (dark gray) or the presence as sole abnormality (red). (B) Number of cases with the respective comutations among the 15 AML cases with i(7)(p10). For IDH2 the mutation site is also depicted.

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For IDH2 mutations, typical hot spots are known, in which almost all mutations are located, mainly comprising the sites Arg140 and Arg172.10-12 Within our subset of cases harboring IDH2 mutations, the p.Arg172Lys mutation site dominated in 12 out of 14 (86%) cases. In contrast, p.Arg140Leu, the usually more common IDH2 mutation site, was present in 2 of 14 (14%) cases only. We compared this prevalence of p.Arg172Lys with a control cohort of 60 cases of AML with IDH2 mutation but without i(7)(p10). In fact, only 8 out of 60 (13%) cases with p.Arg172Lys were detected, the majority (52/60, 87%) included the p.Arg140Leu mutation site (86% vs 13%; P < .001). Of note, only 1 of the 60 cases of IDH2-mutated AML without i(7)(p10), showed a monosomy 7 or a del(7q) due to an unbalanced translocation. None of the cases had del(7q) as an isolated abnormality, which underlines the specific association of IDH2 mutation with i(7)(p10). Analysis of the variant allele frequency (VAF) of IDH2 mutations compared with the VAF of comutations revealed that IDH2 was always present in the main clone, although the median IDH2 VAF in AML cases with i(7)(p10) was slightly lower than in AML cases without i(7)(p10) (38.3% vs 45.9%, not statistically significant). We further assessed clinical attributes of IDH2–mutated AML cases with and without i(7)(p10). This revealed a predominance of females (13/14, 93% vs 29/60, 48%; P < .001) and patients were notably younger than their counterparts without i(7)(p10), with an average age of 63 years compared with 72 years (P = .015). Further, the white blood count was found to be significantly lower (median 2.2∗103 μL vs 8.8∗103 μL; P < .001) while no differences were detected regarding blast count and other blood parameters (supplemental Table 1). The analysis of the overall survival did not reveal a statistically significant difference between patients with i(7)(p10) and those with IDH2-mutated AML without i(7)(p10) (37 months vs 14 months; P = .402).

Our patient cohort clearly demonstrates a predominant association of i(7)(p10) with IDH1/2 mutated AML. Of special interest is the presence of i(7)(p10) as a sole abnormality in the vast majority of AML cases, suggesting a role of i(7)(p10) in pathogenesis of this AML subtype. AML with i(7)(p10) meets formal definition of the WHO–defined AML-MR subtype ,1 and a recent report concluded that i(7)(p10) should be grouped within this specific category.3 This previously described patient case also harbored an IDH2 mutation in addition to i(7)(p10), which was similar to 14 of our 15 cases.3,IDH mutations are of special clinical interest since they are the target of inhibitors, such as ivosidenib (IDH1) and enasidenib (IDH2), both Food and Drug Administration (FDA)-approved for AML-treatment with IDH mutations.13-15 Because IDH2 mutations in our patient cohort were always detected in the main clone, these patients are potentially suitable for targeted therapy. Interestingly, a previous report characterizing myeloid malignancies with isolated 7q deletion revealed a high frequency of mutations in ASXL1, TET2, RUNX1 and SRSF2 which were very infrequent or even completely absent in the i(7)(p10) cohort, further distinguishing cases with i(7)(p10) from other cases with 7q loss.16 This is also underlined by differences in sex predominance (females 37% vs 93%) and age (72 vs 63 years) in the del(7q) and i(7)(p10) cohort.16 

Although the numbers of patients are still small, to our knowledge, here we characterized the largest cohort by far with this rare cytogenetic alteration and provide clear evidence that the analyzed patient cohort stands out as a distinct group with defining characteristics (Figure 2; supplemental Table 2), including (1) the single aberration i(7)(p10) as most characteristic feature, (2) the frequency of IDH2 mutations at the rather rare site p.Arg172Lys, (3) the predominance of females and (4) younger age of patients that are affected by IDH2-mutated AML with i(7)(p10). Additionally, the association with IDH2/1 mutations and the lack of other AML defining alterations offers therapeutic strategies (targeted therapy with IDH inhibitors) for patients with this rare cytogenetic alteration. These characteristics as well as low frequencies of mutations defining AML-MR suggest that one should be cautious with classifying AML cases with i(7)(p10) as AML-MR. Understanding the functional consequences of i(7)(p10) and its effects on hematological malignancies will be a next step in elucidating the biology of this chromosomal abnormality.

Figure 2.

Summary of characteristic features of cases with the cytogenetic abnormality i(7)(p10). Graphical summary of genetic and clinical features observed for the 34 patients with i(7)(p10).

Figure 2.

Summary of characteristic features of cases with the cytogenetic abnormality i(7)(p10). Graphical summary of genetic and clinical features observed for the 34 patients with i(7)(p10).

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The study has been approved by the internal review board of the MLL Munich Leukemia Laboratory. This study contains only laboratory data from a large cohort of patients. No clinical trial was performed.

Acknowledgments: The authors thank all coworkers at the MLL Munich Leukemia Laboratory for their dedicated work. The authors also thank all physicians for providing samples and caring for patients as well as collecting data.

Contribution: A.S. and C.H. designed the study; A.S. interpreted the data; A.S., C.K., and K.H. wrote the manuscript; A.S. and C.H. were responsible for chromosome banding and fluorescence in situ hybridization analyses; M.M. was responsible for molecular and bioinformatic analyses; W.K. was responsible for immunophenotyping; T.H. was responsible for cytomorphologic analyses; and all authors read and contributed to the final version of the manuscript.

Conflict-of-interest disclosure: C.H., W.K., and T.H. declare part ownership of Munich Leukemia Laboratory (MLL). A.S., K.H., C.K., and M.M. are employed by the MLL.

Correspondence: Anna Stengel, MLL Munich Leukemia Laboratory, Max-Lebsche-Platz 31, 81377 München, Germany; email: anna.stengel@mll.com.

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Author notes

Original data are available on request from corresponding author, Anna Stengel (anna.stengel@mll.com).

The full-text version of this article contains a data supplement.

Supplemental data