Short-term results with imatinib mesylate (Gleevec; Novartis Pharmaceuticals, Hanover, NJ) for chronic-phase chronic myelogenous leukemia (CML) are extremely encouraging, with greater than 95% hematologic and 83% major cytogenetic responses in previously untreated patients.1 Long-term experience with interferon-α therapy suggests that only those patients achieving major cytogenetic responses experience significant survival benefits.2 Therefore, serial cytogenetic monitoring of imatinib mesylate–treated patients is imperative so that individuals not attaining major cytogenetic responses may be referred for potentially curative allogeneic marrow transplantation or investigative therapies before progressing to accelerated or blastic phases. Although repetitive bone marrow aspirations for cytogenetics are an effective technique to evaluate response, this method is time consuming, costly, and unpleasant for patients. Several investigators have reported that peripheral blood fluorescence in situ hybridization (FISH) for the BCR-ABL translocation, with its ease of procurement, sensitivity, and quantifiable nature may be a more convenient, yet accurate, method of serial monitoring.3 4The specificity of peripheral blood FISH, however, results in its major limitation; an inability to detect acquisition of additional cytogenetic abnormalities. We report a case where FISH could have led to false reassurances of successful imatinib mesylate treatment.

A 55-year-old man presented with leukocytosis and a hypercellular marrow without dysplasia or blast forms. Peripheral blood karyotype analysis revealed 46, XY,-5, del(6)(q23), t(9;22)(q34;q11.2), +mar and FISH for the BCR-ABL translocation was positive. Interferon therapy for one year yielded only a partial hematologic response. Imatinib mesylate resulted in a rapid complete hematologic response. Marrow FISH at 6 and 10 months demonstrated no evidence of the BCR-ABL translocation in 500 examined cells each time, suggesting a complete cytogenetic response. In contrast, marrow karyotyping yielded 46, XY, der(5)ins(5;5)(p15;q22q12)del(5)(q31q35), del(6)(q23) in 2 of 21 metaphases (6 months) and 7 of 20 metaphases (10 months), with the remaining cells normal. No Philadelphia chromosome–positive (Ph+) clones were identified.

Braziel et al5 recently reported a 14-month experience with imatinib mesylate therapy among interferon refractory/intolerant CML patients. Eighteen of 19 patients achieved a complete hematologic remission and 6 patients achieved a complete cytogenetic response. Two patients showed evidence of clonal evolution in clones possessing the Ph+, and 2 developed trisomy 8 independent of the Ph+ clone. The authors commented that they had observed trisomy 8 as the sole abnormality, independent of the Ph+clone, in 3 other patients enrolled on phase 1 trials with imatinib mesylate. Additional cases of cytogenetic abnormalities distinct from the Ph+ clone have rarely been reported following hydroxyurea6 and interferon7 8 therapies. The acquisition of these cytogenetic abnormalities may represent the changing natural history of CML, treatment-related effects (although doubtful since imatinib mesylate would not be expected to be leukemogenic), or a manifestation of an underlying stem-cell defect which produces both Ph+and Ph clones.

These observations of clonal cytogenetic evolution and cytogenetic polyclonality (ie, a separate non-Ph+ clone) have important implications for monitoring responses to imatinib mesylate therapy. It is possible that myelodysplastic subclones may be masked by a more dominant Ph+ clone and that selective inhibition of the Ph+ clone by imatinib mesylate may permit polyclonal emergence. Because peripheral blood FISH analysis is specific for theBCR-ABL translocation, these cases would go undetected if FISH alone were used to monitor long-term response. Thus, false reassurances of successful imatinib mesylate treatment might be drawn and patients not referred for alternate therapies. These cases support a role for monitoring algorithms that include periodic bone-marrow karyotyping of CML patients responding to imatinib mesylate therapy to exclude unrecognized coexisting myelodysplastic clones and/or clonal evolution in the absence of Ph+ cells.

1
Druker
 
B
STI571 (Gleevec/Glivec, imatinib) versus interferon + cytarabine as initial therapy for patients with CML: results of a randomized study [abstract].
Proc Am Soc Clin Oncol.
21
2002
1a
2
Kantarjian
 
HM
Smith
 
TL
O'Brien
 
S
et al
Prolonged survival in chronic myelogenous leukemia after cytogenetic response to interferon therapy.
Ann Intern Med.
122
1995
254
261
3
DeWald
 
GW
Wyatt
 
WA
Juneau
 
AL
et al
Highly sensitive fluorescence in situ hybridization method to detect double BCR/ABL fusion and monitor response to therapy in chronic myeloid leukemia.
Blood.
91
1998
3357
3365
4
LeGouill
 
S
Talmant
 
P
Milpied
 
N
et al
Fluorescence in situ hybridization on peripheral blood specimens is a reliable method to evaluate cytogenetic response in chronic myeloid leukemia.
J Clin Oncol.
18
2000
1533
1538
5
Braziel
 
RM
Launder
 
TM
Druker
 
BJ
et al
Hematopathologic and cytogenetic findings in imatinib mesylate-treated chronic myelogenous leukemia patients: 14 months' experience.
Blood.
100
2002
435
441
6
Flamm
 
MJ
Murty
 
VVVS
Rao
 
PH
Nichols
 
GL
Coexistence of independent myelodysplastic and Philadelphia chromosome positive clones in a patient with hydroxyurea.
Leuk Res.
26
2002
417
420
7
Ariyama
 
T
Inazawa
 
J
Uemura
 
Y
et al
Clonal origin of Philadelphia chromosome negative cells with trisomy 8 appearing during the course of alpha-interferon therapy for Ph positive chronic myelocytic leukemia.
Cancer Genet Cytogenet.
81
1995
20
23
8
Fayad
 
L
Kantarjian
 
H
O'Brien
 
S
et al
Emergence of new clonal abnormalities following interferon-alpha induced complete cytogenetic response in patients with chronic myeloid leukemia: report of three cases.
Leukemia.
11
1997
767
771
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