Paroxysmal nocturnal hemoglobinuria (PNH) and the stable phase of chronic myelogenous leukemia (CML) are the two hematological conditions known to be associated with low levels of leukocyte alkaline phosphatase (LAP) activity in peripheral blood polymorphonuclear cells (PMN). LAP mRNA levels were determined in PMN from PNH and CML patients by RNA blotting analysis. In CML, LAP mRNA is undetectable, suggesting either decreased transcription or rapid degradation of the message. Contrarily, in PNH normal or high levels of LAP mRNA are present. This latter finding supports the concept of a deficit in the anchorage of the protein to the plasma membrane through the glycolipid pathway, even though other post-transcriptional mechanisms could be involved.
A prototypic “immediate early” gene, c-fos, has been extensively investigated in relation to the differentiation and activation of myelomonocytic cells. The c-fos gene product is associated in transcriptional complexes with the c-jun product. These protooncogenes are part of the regulatory network of gene expression. The present study was designed to investigate expression of the c-jun protooncogene in human circulating myelomonocytic cells. We found that c-jun is constitutively expressed in normal monocytes and granulocytes, whereas low levels of transcripts are found in lymphocytes. Acute myelogenous leukemia (AML) samples of French-American-British Cooperative Group (FAB) subtypes 1 through 4 express appreciable levels of this protooncogene. Normal phytohemagglutinin (PHA)-activated lymphocytes express high levels of c-jun. Expression in normal myelomonocytic cells is detectable even after 18 hours of culture. The c-jun transcripts in myelomonocytic cells have a half-life of approximately 20 minutes and are superinduced by cycloheximide, which affects both the degradation rate of mRNA and the transcriptional activity of the c-jun gene. Functional activation of monocytes and granulocytes with phorbol esters, lipopolysaccharide, and tumor necrosis factor (TNF) increase c- jun expression. This induction is rapid, transient, and does not require intervening protein synthesis. Runoff experiments showed that in freshly isolated untreated monocytes, the c-jun gene is constitutively transcribed, and that induction by lipopolysaccharide is at least in part at the transcriptional level. Moreover, lipopolysaccharide (LPS) treatment reduced the degradation rate of c- jun transcripts, prolonging the half-life to approximately two hours. Expression of c-jun in resting and activated monocytes and granulocytes suggests that this protooncogene may play a role in the differentiation and activation of cells belonging to the myelomonocytic lineage.
The A-myb gene encodes a transcription factor that is related both functionally and structurally to the v-myb oncogene. Following our observations that A-myb is expressed in a restricted subset of normal mature human B lymphocytes, with the phenotype CD38+, CD39-, slgM-, we have now investigated the pattern of A-myb expression in neoplastic B cells representating the whole spectrum of B-cell differentiation and compared it to that of c-myb and B-myb. In a panel of 32 B-cell lines, A-myb was very strongly expressed in most Burkitt's lymphoma (BL) cell lines, but weak or negative in 2 pre-B acute lymphoblastic leukemia (ALL), 4 non-Hodgkin's lymphoma (NHL), 6 Epstein-Barr virus- immortalized lymphoblastoid cell lines, and 6 myeloma lines. Protein expression paralleled that of the RNA. We have also investigated A-myb expression in 49 fresh cases of B leukemias. Among 24 ALL, 6 were of the null and 11 of the common type and all these were negative for A- myb expression; on the other hand, all 7 B-ALL cases (slg+), as well as one fresh BL case with bone marrow infiltration, expressed A-myb. A-myb was undetectable in 4 prolymphocytic leukemias (PLL) but was strongly expressed in 5/20 (25%) of chronic lymphocytic leukemia (CLL) samples. In the latter A-myb did not correlate with phenotype or clinical stage. Finally, we have studied the progression of one case of CLL into Richter's syndrome and have found that the Richter's cells expressed about 25-fold less A-myb RNA than the CLL cells from the same patient. The pattern of c-myb and B-myb was clearly distinct from that of A-myb. C-myb and B-myb were expressed in all neoplastic groups, except in CLL cells. Thus, A-myb expression, unlike that of c-myb and B-myb, is restricted to a subset of B-cell neoplasias (in particular BL and slg+B- ALL) representative of a specific stage of B-cell differentiation. This expression may in part reflect expression of A-myb by the normal germinal center B cells that are the normal counterpart of these transformed B cells. The data presented strongly support a role for this transcription factor in B-cell differentiation and perhaps in B- cell transformation in some neoplasias.
The levels of leukocyte alkaline phosphatase (LAP) messenger RNA (mRNA) are evaluated in B and T lymphocytes, monocytes, and polymorphonuclear cells (PMNs), and this transcript is found to be present only in PMNs. Precursors of the myelomonocytic pathway, represented by leukemic cells isolated from several cases of chronic myelogenous leukemia (CML) in its stable and blastic phase and acute myelogenous leukemia (AML), are devoid of LAP transcript. These data support the notion that LAP is a marker of the granulocyte terminal differentiation. Despite the absence of LAP mRNA in both the myeloid and the lymphoid precursors, nuclear run-on experiments show constitutive transcription of the LAP gene in leukemic cells obtained from AML, CML, as well as acute lymphoblastic leukemia (ALL) and B-cell chronic lymphocytic leukemia (B-CLL). In CML and in chronic myelo-monocytic leukemia (CMML) PMNs, granulocyte colony- stimulating factor (G-CSF) specifically accumulates LAP mRNA without showing a substantial increase in the rate of transcription of the LAP gene. Once increased by G-CSF, LAP mRNA is very stable, showing a half- life of more than 4 hours in the presence of actinomycin-D. G-CSF is suggested to play a pivotal role in the modulation of LAP transcript in PMNs.
Direct and indirect evidence strongly indicates that the proto-oncogene c-myb plays an important role in the regulation of both the proliferation and differentiation of hematopoietic cells. In addition, recent data suggest that the structurally related B-myb gene is also necessary for the proliferation of these cells. To help understand the relationship between these two related gene products during proliferation and differentiation of myeloid cells, we have studied in parallel the regulated expression of c-myb and B-myb RNAs and proteins in human myeloid cells that were either growth-arrested or induced to differentiate along different pathways. For this purpose, we have produced a polyclonal antibody directed against a fragment of the recombinant B-myb protein. We have thus been able to detect the B-myb protein in human cell lines and have found it to be a 93-kD protein localized in the nucleus. We have chosen two models to study the expression of both c-myb and B-myb mRNAs and proteins during myeloid proliferation and differentiation. One of the models was the HL-60 cell line, which can be induced to differentiate towards the monocytic pathway with either phorbol ester (phorbol myristate acetate) or vitamin D3 and towards the granulocytic pathway with either dimethyl sulfoxide or retinoic acid. In addition, we have studied another recently established human leukemic cell line, called GF-D8, which is strictly dependent on granulocyte-macrophage colony-stimulating factor (GM-CSF) for proliferation. The results show that the expression of B- myb RNA and protein closely correlates with proliferation in all experimental setups studied, whereas the c-myb protein levels do not always do so. We observed that the c-myb protein levels decreased well before the decrease of B-myb protein and of proliferation itself during differentiation toward monocytes. Such a difference was not present during granulocytic differentiation, in which c-myb levels decreased, if anything, later than those of B-myb and proliferation. Most striking was the finding that high levels of c-myb RNA and protein, but not of B- myb, were present in the GF-D8 cell line, even after growth arrest by GM-CSF deprivation. These data suggest that B-myb may function solely in the regulation of cellular proliferation, whereas c-myb has additional functions, for example, in the maintenance of an undifferentiated state.
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