Chronic myeloid leukaemia (CML) is a clonal stem cell disorder characterized by increased proliferation of myeloid lineage. CML is the commonest adult leukaemia in India and the annual incidence ranges from 0.8–2.2/100,000 population in males and 0.6–1.6/100,000 population in females in India1. The median age of diagnosis is 38-40 years. This is a decade earlier than the median incidence in the western world. Though CML is predominantly a disease affecting adults, a minority of patients are children and young adults. CML is the first cancer in which a consistent chromosomal abnormality the Philadelphia chromosome was described by Nowell in 1962. This abnormality was later shown to be due to translocation involving t(9;22) (q34;q11.2) and involved the fusion of genes breakpoint cluster region (BCR) and the Tyrosine Kinasehuman homologue of the Abelson Murine leukaemia Virus (ABL). During the reciprocal translocation a segment of ABL gene (9q34) is moved into one of at least 3 well characterized breakpoints of the BCR gene in 22q1123. This results in two fusion genes BCR-ABL and ABL-BCR. Of this, the ABL –BCR has no identified role in pathogenesis of CML.The BCR-ABL fusion gene is in frame and is translated leading to formation of an oncoprotein which is a constitutively active tyrosine kinase. Primarily three different fusion transcripts have been characterized resulting in fusion of BCR exon1 9 (e1), exons13/14 (b2/b3) and exons1-19 (e19) to ABL4. Very rarely exon6 and exon 8 are involved in BCR-ABL translocations. By contrast, the breakpoint in ABL occurs almost invariably upstream in ABL exon2 (a2) though occasionally it can occur downstream of exon2 (a3). These results in tyrosine kinase proteins of 185/190, 210 and 230 kilo Dalton sizes respectively. The 210 kilodalton protein (p210) is called the Major transcript or ‘M’ and the 185/190 Kilodalton is called the minor transcript or ‘m’. The knowledge about the fusion transcript is important when doing molecular monitoring of minimal residual disease after treatment with tyrosine kinase inhibitors.The major modality of treatment of CML inhibitors of the tyrosine kinase, the commonest used is Imatinib. These are chemical competitive inhibitors of ATP which is required for phosphorylation of tyrosine residues of downstream proteins in the signaling pathways of ABLtyrosine kinase. Newer 2nd generation tyrosine kinase inhibitors like Nilotinib and Dasatinib are used in patients resistant to Imatinib. These newer drugs have brought clinical and haematological remissions almost all patients and molecular remissions in about a third of patients. However, it has not resulted in a drug free cure of the disease. The patients have to be on long term monitoring while on therapy5–9.In this issue Anand et al10 have reported on the cytogenetic and molecular analyses of CMLpatients from north India. There are very few studies from India comparing cytogenetics and molecular data in CMLpatients in India. Cytogenetic facilities are scarce in India and restricted to predominantly academic institutes. Having a baseline karyotyping in CML is essential and additional karyotypic abnormalities predict an advanced stage of the disease and a poorer response to Imatinib. The progress in CML have brought in a paradigm shift in management of many cancers and newer approach to targeting cancers.
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