t(7;12)(q36;p13) MNX1/ETV6

2016-08-01 Adriana Zamecnikova , Adriana Zamecnikova Affiliation

1.Kuwait Cancer Control Center, Department of Hematology, Kuwait; annaadria@yahoo.com
2.Afdeling Klinische Genetica, Erasmus MC, Dr. Molewaterplein 50, 3015 GE Rotterdam, The Netherlands
3.MRC Molecular Haematology Unit, Institute of Molecular Medicine, Oxford, UK
4.Genetics, Dept Medical Information, University of Poitiers, CHU Poitiers Hospital, F-86021 Poitiers, France

Abstract

Review on t(7;12)(q36;p13), with data on clinics, and the genes involved.

Clinics and Pathology

Phenotype stem cell origin

Almost exclusively present in acute myeloid leukemia (AML) ) of various subtypes: 13 AML not specified cases (Hagemeijer et al., 1979; Wlodarska et al., 1998; Tosi et al., 2000; Slater et al., 2001; Simmons et al., 2002; Tosi et al., 2003; Ballabio et al., 2009; Wildenhain et al., 2010), 8 M0 (Tosi et al., 2000; Tosi et al., 2003; von Bergh et al., 2006; Ballabio et al., 2009; Park et al., 2009; Wildenhain et al., 2010), 2 M1 (Tosi et al., 2000; Slater et al., 2001), 7 M2 (Raimondi et al., 1999; Satake et al., 1999; von Bergh et al., 2006; Hauer et al., 2008), 1 M3 (Slater et al., 2001; Wildenhain et al., 2010; ), 3 M4 (Hagemeijer et al., 1981; Tosi et al., 2000; Naiel et al., 2013), 3 M5 (Tosi et al.;1998; Park et al., 2009; von Bergh et al., 2006), 1 M6 (Satake et al., 1999) and 2 M7 (Taketani et al., 2008; Naiel et al., 2013). Four cases of acute lymphoblastic leukemia (ALL) (Andreasson et al., 2000; Tosi et al., 2000; von Bergh et al., 2006) as well as 2 acute biphenotypic leukaemia patients were reported (Park et al., 2009; Naiel et al., 2013) (Data from Naiel et al., 2013). The case that was reported previously as myelodysplastic syndrome (Tosi et al.; 1998), revealed a revised diagnosis as AML (Ballabio et al., 2009).

Epidemiology

At least 47 reported cases with chromosomal translocation and/or the fusion transcript (sex ratio 19M/28F; the incidence is low (3%) in overall paediatric AML, but significant in infant AML (Neil et al., 2013; Tosi et al., 2015); extremely rare in infant ALL and older children. The translocation may be overlooked, and therefore underestimated; the estimated incidence of this translocation is approximately one third of AML paediatric patients with age between 0-2 years (von Bergh et al., 2006; Tosi et al.,2015).

Clinics

WBC range 8-230 x 10⁹/L, median 12 x10 ⁹/L; organomegaly, central nervous system involvement in 7 of 12 cases (Tosi et al., 2015).

Prognosis

Inferior outcome with the standard induction therapy with probabilities of 3 years event free survival of 0-14 % and overall survival of 0-28 % (von Berg et al., 2006; Tosi et al., 2015). From the recently published data on the clinical outcome: only 5 patients are alive (1 after 22 months post BMT (Slater et al., 2001); 1 relapsed twice, but alive after 2 years after BMT (Simons et al., 2002); 1 after chemotherapy and 1 after BMT. It appears to be that the only long time survival is a paediatric patient with acute megakaryocytic leukaemia alive after 5 years, treated with chemotherapy (Taketani et al., 2008). The remaining 18 patients died during induction chemotherapy, infection or relapse (Data from Tosi et al., 2015).

Cytogenetics

Cytogenetics morphological

Not always visible by chromosome banding techniques alone; may also be misdiagnosed as del(12)(p13) and/or del(7q), thus fluorescence in situ hybridization (FISH) analysis has to be done for its identification.

Cytogenetics molecular

Detectable by dual colour FISH. A cosmid cocktail or YAC 964c10 shows a split signal on the der(12) and der(7). Also the commercial probe LSI TEL/AML1 (ES) for the detection of the t(12;21) shows a split signal on the der(7) and the der(12) in the t(7;12) cases since the breakpoint in these cases falls within the first three exons, which are contained in this probe. FISH using the PAC clone RP5-1121A15 mapping to 7q36 shows a split signal on the der(7) and der(12).

Top Left: example of FISH performed on bone marrow metaphase from a patient with t(7;12)(q36;p13). Dual colour FISH using whole chromosome paint specific for chromosome 7 (in green) and chromosome 12 (in red) shows the reciprocal translocation. The arrow indicates the der(7) and the arrowhead indicates the der(12) - Sabrina Tosi; Right: Example of double colour FISH performed on bone marrow metaphase from a patient with t(7;12)(q36;p13). The PAC clone 1121A15 for the breakpoint region at chromosome band 7q36 (in green) and a cosmid cocktail for ETV6 at chromosome band 12p13 (in red) show one green signal for the normal chromosome 7, one red signal for the normal chromosome 12 and two fusion signals at both the derivative chromosomes 7 and 12 - Anne RM von Bergh and H. Berna Beverloo.

Bottom FISH using commercially available LSI TEL (12p13) Break-apart (Vysis, Abott, USA) probe showing juxtaposition of telomeric sequences (split red signal) to der(7) chromosome and a 2 fusion (one of them smaller appearing), 1 red signal pattern on interphase cells (A). The juxtaposition of disrupted TEL sequences to 7q36.3 may be visualized by Vysis LSI ETV6 (TEL)/RUNX1 (AML1) dual color translocation probe and SureFISH 7q36.3SHH probe (red signal) (Agilent Technologies, US) revealing the fusion signal on der(7) chromosome and the remaining TEL sequences (green) on der(12) chromosome (visualisation of 7q36.3 on derivative chromosome 12 might be impaired due to the small size of the translocated fragments) (B). To screen for t(7;12)(q36;p13) in infants with MLL-negative AML, commercially available Vysis LSI ETV6 (TEL) break-apart probe can be used to confirm the breakage of the ETV6 gene on 12p13, showing the split signal on der(7) chromosome and the truncated fusion signal on der(12) (Figure 1A). Visualization of 7q36.3 sequences may be done by SureFISH 7q36.3SHH probe (Agilent Technologies, US) alone or with combination of Vysis LSI ETV6 (TEL)/RUNX1 (AML1) dual color translocation probe (Figure 1B) - Adriana Zamecnikova, Soad Al Bahar.

Additional anomalies

Accompanied by the presence of an extra chromosome in the majority of cases: +19 mostly, occurring in 38 out of 47 cases (+19 alone in 22 cases, in association with +8 in 8, +13 in 2, +22 in 3 and with +X,+8 in 3), while +8 as a sole numerical anomaly was found in 2 patients (Data from Naiel et al., 2013).

Variants

To date, three-way complex translocations were found in 3 patients, characterized as: t(5;7;12)(q31;q36;p13), t(1;7;12)(q25;q36;p13) (Park et al., 2009) and t(7;12;16)(q36;p13;q12) (Naiel et al., 2013).

Genes Involved and Proteins

Gene name

MNX1 (homeo box HB9)

Location

7q36.3

Note

HLXB9 mutation are found in patients with Currarino syndrome

Dna rna description

3 exons, 2061 bp mRNA

Protein description

403 AA; Homeobox protein HB9; Highly expressed in CD34+ bone marrow cells; Possibly involved in the regulation of growth and differentiation of progenitor cells.

Gene name

ETV6 (ets variant 6)

Location

12p13.2

Dna rna description

9 exons; alternate splicing

Protein description

contains a Helix-Loop-Helix and ETS DNA binding domains; wide expression; nuclear localisation; ETS-related transcription factor

Result of the Chromosomal Anomaly

Description

5 HLXB9 - 3 ETV6. The breakpoints on chromosome 12 disrupting the ETV6 gene are consistently at the 5? end of ETV6, between exons 1 and 3, however chromosome 7 breakpoints are scattered in regions proximal to the HLXB9 (Homeobox HB9, MNX1) gene, suggesting that HLXB9 gene is translocated to the der(12) without its disruption (Tosi et al., 2015).

Note

The t(7;12) is heterogeneous at the molecular level. The presence of an HLXB9/ETV6 fusion transcript has been identified only in approximately 50 % of described patients (Beverloo et al., 2001; Simmons et al., 2002; Von Bergh et al., 2006; Taketani et al., 2008; Ballabio et al., 2009; Wildenhain et al., 2010).

Description

N-terminal HLXB9, including its polyalanine repeat region, is fused to a large C-terminal part of the ETV6 protein including its HLH domain and ETS domain; the homeobox domain of HLXB9 is not retained in the fusion protein; the reciprocal transcript is not expressed.

Oncogenesis

The pathogenic mechanisms arising from t(7;12)(q36;p13) are not fully understood. As the presence of an HLXB9/ETV6 fusion transcript has been shown only in approximately 50% of patients and the reciprocal ETV6/HLXB9 transcript has never been observed, it is unclear if generation of a fusion gene is involved in leukemogenesis, at least in some cases. In addition, the presence of a HLXB9/ETV6 protein has not been confirmed to date, thus the production of a fusion protein is still debatable (Tosi et al., 2915). While the role of a chimeric protein as an oncogenic trigger is unclear, the observation of highly increased HLXB9 expression in t(7;12)-positive patients suggests that ectopic expression of HLXB9 might promote oncogenesis (Von Bergh et al., 2006; Ballabio et al., 2009). Alternatively, it is possible that ETV6 is the only contributor to leukaemogenesis and its disruption alone might activate oncogenesis. Furthermore, as the t(7;12) has been found associated with deletions of 12p and/or a gene(s) at 7q36, it is likely that inactivation of ETV6 and/or a gene(s) at 7q36 might contribute to the malignant phenotype (Neiel., et al. 2013).

Highly cited references

Pubmed ID	Year	Title	Citations
29569294	2018	Acute myeloid leukemia (AML) with t(7;12)(q36;p13) is associated with infancy and trisomy 19: Data from Nordic Society for Pediatric Hematology and Oncology (NOPHO-AML) and review of the literature.	7
18940475	2008	MNX1-ETV6 fusion gene in an acute megakaryoblastic leukemia and expression of the MNX1 gene in leukemia and normal B cell lines.	6

Article Bibliography

Pubmed ID	Last Year	Title	Authors
292969	1979	Bone marrow karyotypes of children with nonlymphocytic leukemia.	Hagemeijer A et al
10914938	2000	Cytogenetic and FISH studies of a single center consecutive series of 152 childhood acute lymphoblastic leukemias.	Andreasson P et al
19212340	2009	Ectopic expression of the HLXB9 gene is associated with an altered nuclear position in t(7;12) leukaemias.	Ballabio E et al
11454678	2001	Fusion of the homeobox gene HLXB9 and the ETV6 gene in infant acute myeloid leukemias with the t(7;12)(q36;p13).	Beverloo HB et al
6944153	1981	Cytogenetic follow-up of patients with nonlymphocytic leukemia. II. Acute nonlymphocytic leukemia.	Hagemeijer A et al
17960638	2008	Graft versus leukemia effect after haploidentical HSCT in a MLL-negative infant AML with HLXB9/ETV6 rearrangement.	Hauer J et al
24216708	2013	A Novel Three-Colour Fluorescence in Situ Hybridization Approach for the Detection of t(7;12)(q36;p13) in Acute Myeloid Leukaemia Reveals New Cryptic Three Way Translocation t(7;12;16).	Naiel A et al
19446746	2009	Three-way complex translocations in infant acute myeloid leukemia with t(7;12)(q36;p13): the incidence and correlation of a HLXB9 overexpression.	Park J et al
10572083	1999	Chromosomal abnormalities in 478 children with acute myeloid leukemia: clinical characteristics and treatment outcome in a cooperative pediatric oncology group study-POG 8821.	Raimondi SC et al
10400416	1999	Chromosome abnormalities and MLL rearrangements in acute myeloid leukemia of infants.	Satake N et al
12454746	2002	Cytogenetic and molecular heterogeneity of 7q36/12p13 rearrangements in childhood AML.	Simmons HM et al
11417477	2001	t(7;12)(q36;p13) and t(7;12)(q32;p13)--translocations involving ETV6 in children 18 months of age or younger with myeloid disorders.	Slater RM et al
18940475	2008	MNX1-ETV6 fusion gene in an acute megakaryoblastic leukemia and expression of the MNX1 gene in leukemia and normal B cell lines.	Taketani T et al
9523197	1998	Identification of new partner chromosomes involved in fusions with the ETV6 (TEL) gene in hematologic malignancies.	Tosi S et al
11066076	2000	t(7;12)(q36;p13), a new recurrent translocation involving ETV6 in infant leukemia.	Tosi S et al
12939747	2003	Heterogeneity of the 7q36 breakpoints in the t(7;12) involving ETV6 in infant leukemia.	Tosi S et al
26605042	2015	Paediatric acute myeloid leukaemia with the t(7;12)(q36;p13) rearrangement: a review of the biological and clinical management aspects.	Tosi S et al
20596032	2010	Expression of cell-cell interacting genes distinguishes HLXB9/TEL from MLL-positive childhood acute myeloid leukemia.	Wildenhain S et al
9454771	1998	Fluorescence in situ hybridization characterization of new translocations involving TEL (ETV6) in a wide spectrum of hematologic malignancies.	Wlodarska I et al
16646086	2006	High incidence of t(7;12)(q36;p13) in infant AML but not in infant ALL, with a dismal outcome and ectopic expression of HLXB9.	von Bergh AR et al

Summary

Fusion gene

MNX1/ETV6 MNX1 (7q36.3) ETV6 (12p13.2) M|MNX1/ETV6 MNX1 (7q36.3) ETV6 (12p13.2) M t(7;12)(q36;p13)|MNX1/ETV6 MNX1 (7q36.3) ETV6 (12p13.2) TIC

Citation

Adriana Zamecnikova ; Adriana Zamecnikova

t(7;12)(q36;p13) MNX1/ETV6

Atlas Genet Cytogenet Oncol Haematol. 2016-08-01

Online version: http://atlasgeneticsoncology.org/haematological/1177/tumors-explorer/meetings/favicon/favicon-32x32.png

Historical Card

2003-12-01 t(7;12)(q36;p13) MNX1/ETV6 by Anne RM von Bergh,Anne RM von Bergh Affiliation

Afdeling Klinische Genetica, Erasmus MC, Dr. Molewaterplein 50, 3015 GE Rotterdam, The Netherlands

2001-06-01 t(7;12)(q36;p13) MNX1/ETV6 by Sabrina Tosi Affiliation

MRC Molecular Haematology Unit, Institute of Molecular Medicine, Oxford, UK

2000-04-01 t(7;12)(q36;p13) MNX1/ETV6 by Jean-Loup Huret Affiliation

Genetics, Dept Medical Information, University of Poitiers, CHU Poitiers Hospital, F-86021 Poitiers, France