Characterization of growth inhibitory factors for mouse monocytic leukemia cells

TRA1, a Novel mRNA Highly Expressed in Leukemogenic Mouse Monocytic Sublines But Not in Nonleukemogenic Sublines

Mouse monocytic Mm-A, Mm-P, Mm-S1, and Mm-S2 cells are sublines of mouse monocytic and immortalized Mm-1 cells derived from spontaneously differentiated, mouse myeloblastic M1 cells. Although these subline cells retain their monocytic characteristics in vitro, Mm-A and Mm-P cells are highly leukemogenic to syngeneic SL mice and athymic nude mice, whereas Mm-S1 and Mm-S2 cells are not or are only slightly leukemogenic. To better understand the molecular mechanisms of these levels of leukemogenicity, we investigated putative leukemogenesis-associated genes or oncogenes involved in the maintenance of growth, especially in vivo, by means of differential mRNA display. We isolated a fragment clone (15T01) from Mm-P cells. The mRNA probed with 15T01 was expressed at high levels in leukemogenic Mm-P and Mm-A cells but not in nonleukemogenic Mm-S1 and Mm-S2 cells. The gene corresponding to 15T01, named TRA1, was isolated from an Mm-P cDNA library. The longest open reading frame of the TRA1 clone predicts a peptide containing 204 amino acids with a calculated molecular weight of 23,049 D. The predicted TRA1 protein is cysteine-rich and contains multiple cysteine doublets. A putative normal counterpart gene, named NOR1, was also isolated from a normal mouse kidney cDNA library and sequenced. NOR1 cDNA predicts a peptide containing 234 amino acids. The sequence of 201 amino acids from the C-terminal NOR1 was completely identical to that of TRA1, whereas the remaining N-terminal amino acids (33 amino acids) were longer than that (3 amino acids) of TRA1 and the N-terminus of NOR1 protein contained proline-rich sequence. A similarity search against current nucleotide and protein sequence databases indicated that the NOR1/TRA1 gene(s) is conserved in a wide range of eukaryotes, because apparently homologous genes were identified in Caenorhabditis elegans and Saccharomyces cerevisiae genomes. Northern blotting using TRA1-specific and NOR1-specific probes indicated that TRA1 mRNA is exclusively expressed in leukemogenic but not in nonleukemogenic Mm sublines and normal tissues and also indicated that NOR1 mRNA is expressed in normal tissues, especially in kidney, lung, liver, and bone marrow cells but not in any Mm sublines. After leukemogenic Mm-P cells were induced to differentiate into normal macrophages by sodium butyrate, the normal counterpart, NOR1, was expressed, whereas the TRA1 level decreased. Furthermore, transfection of TRA1 converted nonleukemogenic Mm-S1 cells into leukemogenic cells. These results indicate that the TRA1 gene is associated at least in part with the leukemogenesis of monocytic Mm sublines.

Genistein exhibits preferential cytotoxicity to a leukemogenic variant but induces differentiation of a non-leukemogenic variant of the mouse monocytic leukemia Mm cell line

Mouse leukemia Mm-A and Mm-S2 cells are subclones of mouse monocytic leukemia Mm cells, Mm-A cells having much higher leukemogenicity than Mm-S2 cells. The growth-inhibitory effects of several protein kinase inhibitors on leukemogenic Mm-A and non-leukemogenic Mm-S2 cells were examined. Most inhibitors of protein serine/threonine kinases inhibited the growth of Mm-A and Mm-S2 cells similarly, but some protein tyrosine kinase inhibitors exhibited differential inhibitory effects on Mm-A and Mm-S2 cells. Genistein inhibited growth of Mm-A cells more effectively than that of Mm-S2 cells, but another inhibitor of tyrosine kinase, herbimycin A, preferentially inhibited growth of non-leukemogenic Mm-S2 cells. Genistein induced or enhanced several differentiation markers of Mm-S2 cells, such as cell spreading, immunophagocytosis, nitroblue tetrazolium (NBT) reduction and lysozyme activity in a dose-dependent manner, but herbimycin A did not. Genistein was cytotoxic to Mm-A cells rather than inducing cell differentiation. Genistein has effects on several other cellular events as well as inhibition of tyrosine kinases. However, it effectively inhibited protein tyrosine phosphorylation in Mm-A cells and its decrease of tyrosine phosphorylation was closely associated with its inhibition of cell growth. Thus, a genistein-sensitive tyrosine kinase(s) may play an important role in the growth and/or survival of leukemogenic Mm-A cells.

Interleukin 4 potentiates the antiproliferative effect of 1 alpha, 25-dihydroxyvitamin D3 on mouse monocytic leukemia cells but antagonizes the antiproliferative effects of interferon alpha, beta and interleukin 6

Mouse monocytic leukemia Mm cells are a line of spontaneously differentiated cells obtained from mouse myeloblastic leukemia M1 cells. The effect of interleukin 4(IL-4) on the proliferation of Mm cells in the presence or absence of growth inhibitory substances was investigated. In semi-solid agar culture, IL-4 markedly inhibited colony formation by Mm cells, reducing the number of colonies to 50% of that in control cultures at concentration of 3 U/ml. In contrast, IL-4 did not inhibit colony formation by the parent M1 cells. In liquid culture, IL-4 alone inhibited the proliferation of Mm cells only slightly. However, a combination of IL-4 and 1 alpha,25-dihydroxyvitamin D3 (VD3), which alone did not inhibit growth significantly, markedly inhibited the growth of Mm cells. This combination also increased the lysozyme activity of Mm cells significantly. On the other hand, IL-4 suppressed the antiproliferative effects of interferon alpha, beta and IL-6, which are growth inhibitory cytokines for these Mm cells. These results indicate that IL-4 can modulate the growth of monocytic leukemia Mm cells and that its modulatory effects depend on growth inhibitory substances.