Philadelphia chromosome-positive acute myeloid leukemia (Ph+ AML) is a rare condition, and its additional genetic abnormalities remain largely unclear.^1,2 Here, we describe a case of Ph+ AML with extra chromosomal changes. Using RNA sequencing, we identified a novel fusion gene, GMPS::ARHGEF26-AS1. Both genes involved are related to GMP biological functions.

A 53-year-old woman presented with gum swelling and pain, which slightly improved after taking oral cefixime. Her complete blood count showed a white blood cell count of 53.84 × 10⁹/L, hemoglobin at 79 g/L, and a platelet count of 79 × 10⁹/L. Bone marrow aspiration revealed that myeloblasts made up 75.5% of the cells, while promyelocytes accounted for 15.5% (Figure 1a). Bone marrow biopsy demonstrated markedly hypercellular marrow (around 90% cellularity) with diffuse proliferation of abnormal cells comprising about 90% of nucleated cells. These abnormal cells were small to medium in size, with moderate cytoplasm and oval to irregular nuclei containing finely dispersed chromatin. Special stains showed negative Prussian blue staining (indicating no iron deposition), MF-1 grade reticulin fibrosis (World Health Organization Classification), and Masson’s trichrome staining indicating grade 0 collagen fibrosis. Flow cytometry revealed that about 95.46% of nucleated cells were abnormal, strongly expressing CD34; expressing CD117, CD13, CD33, CD123, and HLA-DR; partially expressing CD56; weakly expressing CD38 and CD9; and showing no expression of CD7, CD15, CD64, CD11b, CD22, CD5, CD2, CD20, CD19, CD10, CD4, CD14, CD36, intracellular MPO, TDT, cytoplasmic CD79a, cytoplasmic CD3, or surface CD3. The immunophenotype was most compatible with AML-M1/M5, with a strong preference for M5. Karyotype analysis showed 45, XX, der(3), der(5) t(3; 5)(q26; q11), -7, t(9; 22)(q34; q11.2) [20] (Figure 1b). Molecular testing detected the BCR::ABL1 (p190) fusion gene by PCR. Targeted next-generation sequencing with a 56-gene panel (Supplementary Table 1) identified an SF3B1 gene mutation (c.2098A > G, VAF 50.9%). The diagnosis was Ph+ AML. Induction chemotherapy with the IA regimen (idarubicin 10 mg day 1, 20 mg days 2-3; cytarabine 200 mg days 1-7) was given along with dasatinib. Four weeks later, bone marrow aspiration showed hypocellular marrow with 25.5% of myeloblasts and 10% promonocytes, indicating non-remission. She then underwent re-induction with the HEA regimen (homoharringtonine 4 mg days 1-7, etoposide 0.1 days 1-5, cytarabine 200 mg days 1-7). Sadly, she died of cardiac arrest shortly after entering myelosuppression.

Total RNA was isolated from the bone marrow mononuclear cells collected during the initial diagnostic evaluation. Transcriptome sequencing was then conducted. Using the STAR-fusion software, we identified a novel GMPS::ARHGEF26-AS1 fusion gene (Figures 1c-e), along with the BCR::ABL1 fusion and an additional novel ABL1::MIF fusion. These findings were further confirmed using a second software tool, SOAPfuse (see Supplementary Figures 1-5).

  The human guanosine monophosphate synthase (GMPS) gene is located at chromosome 3q25.31 and belongs to the glutamine aminotransferase family. In the de novo synthesis of GMP, GMPS catalyzes the final step, which involves aminating xanthosine
5‘ monophosphate to GMP. GMP is then further phosphorylated to produce guanosine triphosphate (GTP). GTP plays a role in various essential biochemical processes. It serves as a primer for DNA replication, supplies guanine nucleotides for RNA transcription, and functions as an energy source in the tricarboxylic acid cycle. GMPS is also known to perform other non-catalytic roles.³

The role of GMPS in leukemia has not been well explored. Pegram et al.⁴ reported the first leukemia-related fusion gene involving GMPS, namely MLL::GMPS. The patient described was a boy with a history of neuroblastoma who developed therapy-related AML (FAB M4 subtype) at the age of 13 after undergoing multiple rounds of chemotherapy and radiotherapy. The study identified two distinct fusion patterns for MLL::GMPS: exon 7 or exon 8 of MLL fused with GMPS at position 150 of the full-length 2212-bp cDNA (accession: NM_003875). Additionally, experimental results showed that GMPS mRNA and protein levels were significantly higher in leukemia cell lines (such as HL60 and U937) and transformed lymphoblastoid cells compared to non-transformed quiescent cells.⁵

The ARHGEF26-AS1 (ARHGEF26 antisense RNA 1) gene is located on chromosome 3q25.2. ARHGEF26-AS1 functions as an antisense RNA of ARHGEF26. The ARHGEF26 gene is a member of the Rho guanine nucleotide exchange factor (Rho) family, and its role is to regulate the activity of Rho GTPases. When bound to GDP, Rho GTPase remains inactive. ARHGEF26 facilitates the release of GDP from Rho GTPase and promotes GTP binding, thereby activating the Rho GTPase. ARHGEF26 is involved in modulating cell membrane deformation and other regulatory functions.⁶

Current studies on ARHGEF26-AS1 in cancer mainly focuses on solid tumors. This lncRNA has been shown to be an independent predictor of overall survival in patients with colorectal cancer and has demonstrated significant correlations with clinical prognosis in intrahepatic cholangiocarcinoma and colorectal cancer.^7,8 Furthermore, a prognostic model proposed by Maimaiti et al.⁹, which included ARHGEF26-AS1 along with eight other autophagy-related lncRNAs, indicated promise for improving the diagnosis and treatment of low-grade glioma.

This is the first report describing the GMPS::ARHGEF26-AS1 fusion gene. Notably, both partner genes are related to GTP-related biological functions. As a result, this fusion could disrupt key survival pathways in cells and may contribute to treatment resistance. In addition, the GMPS::ARHGEF26-AS1 fusion preserves only the first exon of GMPS and incorporates the ARHGEF26-AS1 antisense RNA, suggesting its likely role as a non-coding RNA. In recent years, the role of non-coding genes in forming fusion genes has drawn increasing attention, and this fusion represents a new example. Informed consent was obtained from the patient.¹⁰

Informed Consent: Informed consent was obtained from the patient.

Authorship Contributions: Concept- Z.S., H.Z.; Supervision- H.Z.; Materials- X.L., H.Z.; Data Collection or Processing- X.L., H.Z.; Analysis and/or Interpretation- X.L.; Writing- X.L.; Critical Review- Z.S., H.Z.

Conflict of Interest: No conflict of interest was declared by the authors.

Funding: The study was supported by Clinical medicine + X Grant of the Affiliated Hospital of Qingdao University [QDFY+X2021045].

Supplementary: https://www.balkanmedicaljournal.org/img/files/balkan-2025.2025-4-64-supplemantry.pdf

REFERENCES

1. Arber DA, Orazi A, Hasserjian R, et al. The 2016 revision to the World Health Organization classification of myeloid neoplasms and acute leukemia. 2016;127:2391-2405.
2. Min GJ, Kim HJ, Yoon JH, et al. Impact of an Additional chromosome on the clinical outcomes of hematopoietic stem cell transplantation in philadelphia chromosome-positive acute myeloid leukemia in adults. Biol Blood Marrow Transplant. 2018;24:1621-1628.
3. Ballut L, Violot S, Kumar S, Aghajari N, Balaram H. GMP synthetase: allostery, structure, and function. 2023;13:1379.
4. Pegram LD, Megonigal MD, Lange BJ, et al. t(3;11) translocation in treatment-related acute myeloid leukemia fuses MLL with the GMPS (GUANOSINE 5J MONOPHOSPHATE SYNTHETASE) gene. Blood. 2000;96:4360-4362.
5. Hirst M, Haliday E, Nakamura J, Lou L. Human GMP synthetase. Protein purification, cloning, and functional expression of cDNA. J Biol Chem. 1994;269:23830-23837.
6. Ellerbroek SM, Wennerberg K, Arthur WT, et al. SGEF, a RhoG guanine nucleotide exchange factor that stimulates macropinocytosis. Mol Biol Cell. 2004;15:3309-3319.
7. Gao Z, Fu P, Yu Z, Zhen F, Gu Y. Comprehensive analysis of lncRNA-miRNA- mRNA network ascertains prognostic factors in patients with colon cancer. Technol Cancer Res Treat. 2019;18:1533033819853237.
8. Zhou D, Gao B, Yang Q, Kong Y, Wang W. Integrative analysis of ceRNA network reveals functional lncRNAs in intrahepatic cholangiocarcinoma. Biomed Res. 2019;2019:2601271.
9. Maimaiti A, Tuerhong M, Wang Y, et al. An innovative prognostic model based on autophagy-related long noncoding RNA signature for low-grade glioma. Mol Cell Biochem. 2022;477:1417-1438.
10. Han C, Sun LY, Wang WT, Sun YM, Chen YQ. Non-coding RNAs in cancers with chromosomal rearrangements: the signatures, causes, functions and implications. J Mol Cell Biol. 2019;11:886-898.