A. Cork

Philadelphia chromosome-positive adult acute leukemia with monosomy of chromosome number seven: A subgroup with poor response to therapy

Thirty-four adult patients were seen at the University of Texas M. D. Anderson Hospital and Tumor Institute at Houston, Texas between 1969 and 1980 with acute leukemia (AL) and a deleted G-group chromosome that was shown by Giemsa banding to be a Philadelphia (Ph1) chromosome t(9;22) in 21 patients. Fourteen had the Ph1 chromosome as the sole abnormality, 12 had the Ph1 chromosome and loss of one chromosome of the C-group (identified by Giemsa banding analysis as number 7 in eight patients), while eight had the Ph1 chromosome and other changes. These three groups were similar in sex, age distribution and hematologic parameters. The median age of 40 was lower than usually seen in AL. The distribution of the morphologic subtypes was similar to that seen at this institution, with 50% being acute myeloblastic, 12% acute myelomonocytic, 20% lymphoblastic and 18% acute undifferentiated. The complete remission rate with chemotherapy was low: 25% in the Ph1 +/- 7, 50% in the Ph1 +/other group and 43% in the Ph1 +/other group. Median survival time was 8 months for the Ph1 +/- 7 group, 5.5 months for the Ph1 +/other group and 9.0 months for the Ph1 +/alone group. These patients with Ph1 + AL had higher white blood cell counts, increased extramedullary disease and poorer responses to therapy than usual for patients with AL. The deletion of chromosome 7 and the acquisition of the Ph1 chromosome identifies a group of patients with characteristics similar to all the patients with Ph1 + AL but a poor response to therapy and short remission duration.

DNA aneuploidy in adult acute leukemia

Using flow cytometric techniques, we determined DNA ploidy levels in the bone marrow of 318 successive adult patients with newly diagnosed acute leukemia. Overall, 26% exhibited DNA stem line abnormalities, usually with a 10%-15% DNA excess, regardless of morphologic diagnosis. DNA aneuploidy was seen most frequently in patients with a hyperdiploid chromosome number and karyotype instability (50%), but was also present in a third of patients with chromosomal translocations and in 20% of patients with a normal diploid karyotype. Thus, among 73 patients with DNA aneuploidy, quantitatively concordant karyotype abnormalities were observed in almost 40% of patients; the discrepancy between DNA content and chromosome number in the remaining patients may reflect differences in the cell cycle position of target cells in G1/0 phase or mitosis, respectively. Cytogenetics affected treatment outcome in acute myelogenous leukemia (AML) with more favorable short- and long-term prognosis among patients with translocations compared with those with numeric abnormalities. The presence of an abnormal DNA stem line, among AML patients with translocations, identified a favorable subgroup with significantly longer remission duration and survival (25 and 26 months versus 18 and 13 months, respectively). In addition, the prognostic implications of DNA aneuploidy in AML were age-dependent, in that favorable effects among patients with translocations and unfavorable effects among those with numeric abnormalities or diploid karyotypes were most obvious in young and not in older patients (greater than or equal to 40 years). In adults with ALL, DNA aneuploidy was associated with shorter survival (15 versus 39 months in the diploid group), an observation that is distinctly at variance with recent findings in childhood ALL. Our results indicated that DNA flow cytometry was complementary to standard cytogenetics for the detection of genomic abnormalities; and DNA aneuploidy emerged, like in children but not in adults with ALL, as a new favorable prognostic feature in a subgroup of adults with AML, the biologic basis of which remains to be determined.

Granulocyte-Colony Stimulating Factor, Granulocyte-Macrophage Colony Stimulating Factor, PIXY-321, Stem Cell Factor, Interleukin-3, and Interleukin-7: Receptor Binding and Effects on Clonogenic Proliferation in Acute Lymphoblastic Leukemia

Cytokines are frequently used after chemotherapy of leukemias and solid tumors to augment recovery of normal hematopoiesis. While the regulation of normal and leukemic myelopoiesis is well investigated, little is known about effects of cytokines on growth and differentiation of lymphoblastic leukemia. In this study, we investigated the expression of receptors for G-CSF, GM-CSF, SCF, IL-3, and IL-7 on acute lymphoblastic leukemia (ALL) blasts and the effects of these growth factors (GF) on ALL blast colony formation. The binding of fluorescence-tagged cytokines to receptors on ALL blasts was studied by flow-cytometry in 27 cases of ALL (24 precursor B-ALL, 3 T-ALL). Receptor-binding for myeloid-associated GF was observed in the majority of precursor B-ALL (G-CSF = 100%, GM-CSF = 65%, IL-3 = 83%, SCF = 74%), but not in T-ALL. Binding of labelled IL-7 was detected in both precursor B- (92%) and T-ALL (100%). The presence of receptors for SCF in ALL was confirmed by polymerase chain reaction for c-kit mRNA in 19/21 cases tested. Expression of receptors for G-CSF, GM-CSF, IL-3, and SCF was not associated with expression of myeloid antigens, or with specific cytogenetic abnormalities. The effects of these GF on clonogenic cells were tested in the ALL blast colony assay and varied between samples, but all cytokines were able to increase clonogenic growth. The GM-CSF/IL-3 fusion molecule PIXY-321 was most effective in promoting colony growth. In some cases inhibition of colony formation was found. We conclude that ALL blast cells have receptors not only for IL-7, but also for G-CSF, GM-CSF, SCF, and IL-3. ALL precursors can respond to these GF with changes in their clonogenic growth indicating the presence of functional receptors. Results may have implications for therapeutic approaches combining cytokines and chemotherapy.