Isolation of a novel macrophage-specific gene by differential cDNA analysis.

To analyze myelomonocytic differentiation we have used the approach of differential cDNA analysis to isolate novel genes that are preferentially expressed in mature macrophages. Differential screening of a macrophage cDNA library led to the identification of a novel cDNA that showed macrophage lineage- and differentiation stage-specific expression. Transcripts from the gene, which we have termed Mpg-1, are found at a high level in mature human and murine macrophages and at a moderate level in certain myelomonocytic cell lines. The expression of Mpg-1 was found to increase when murine fetal liver hematopoietic progenitor cells were induced to differentiate into macrophages. An Mpg-1-specific transcript was not detected in a wide variety of other tissues and cell lines. The DNA sequence of Mpg-1 (4,214 bp) was obtained from a series of overlapping cDNA, 3' rapid amplification of cDNA ends (RACE), and genomic clones. Primer extension analysis predicted the existence of multiple transcription start sites, ranging from 26 to 117 bp upstream of the 5' proximal ATG of the open reading frame. The predicted 669-amino acid, Mpg-1-encoded protein has potential glycosylation and phosphorylation sites in addition to a signal sequence. The core protein is predicted to have a molecular weight of 71 to 74 kD. Computer-assisted local similarity searches indicate that Mpg-1 is a novel gene that may share a distant ancestry to perforin, a lytic protein found in cytotoxic T lymphocytes and natural killer cells.

Stage-specific expression of intracisternal A-particle sequences in murine myelomonocytic leukemia cell lines and normal myelomonocytic differentiation.

The levels of intracisternal A-particle (IAP) mRNA were analyzed in a variety of myelomonocytic leukemia cell lines, peritoneally derived macrophages, and normal hemopoietic progenitors induced to differentiate. In both normal and leukemic cells, the highest level of IAP message was found in cells at an intermediate stage of myelomonocytic differentiation, namely, the promyelomonocyte. These results indicate that IAP sequence transcription is regulated differentially during myelomonocytic cell development and that in general, the expression pattern is preserved in leukemic cell lines in vitro. In addition, Northern (RNA) analysis detected only type I IAP transcripts as the major IAP message and the expressed IAP subtypes varied in certain cell lines. This is the first comprehensive study of IAP expression in the myelomonocytic lineage and provides a useful system to study the biology of IAPs.

Transformation of murine myelomonocytic cells by myc: point mutations in v-myc contribute synergistically to transforming potential.

The v-myc oncogenes of chicken retroviruses (including MC29) bear point mutations relative to chicken c-myc. These mutations result in several amino acid differences in the encoded proteins. We have used recombinant murine retroviruses containing various myc alleles to analyse the myelomonocytic transforming potential of the myc oncogene. The myc alleles used were MC29 v-myc, chicken c-myc, chimeric genes combining 5' sections of v- or c-myc with 3' sections of c- or v-myc, and mouse c-myc. The same retroviral vector (based on the genome of Moloney leukemia virus) was used for each allele and the genes were translated from genomic message. By infecting the primary mouse tissues, bone marrow, peritoneal-derived macrophages and mixed embryonic tissue with the recombinant viruses, variation was found in the transforming efficacy of these alleles: v-myc was most effective, followed by the two chimeric genes, whereas c-myc (chicken or mouse) was least effective in eliciting myelomonocytic transformation. Viral gag sequences were not necessary for this transformation. In each case, the transformed monocytes were growth factor-dependent and non-immortal. However, v-myc transformed monocytes (though not monocytes transformed by other myc alleles) were able to progress to an immortal, growth factor-independent phenotype. Our results indicate that v-myc is far more effective than c-myc in eliciting myelomonocytic transformation; that this is due to combinatorial effects of 5' and 3' mutations in the v-myc gene; and that secondary events in addition to these mutations are required for transformation of myelomonocytic cells to an immortal, tumorigenic phenotype.