Functional characterization of the promoter for the gene encoding human eosinophil peroxidase

The molecular basis for commitment of progenitors to the eosinophil lineage and mechanisms by which eosinophil-specific genes are expressed and regulated during differentiation is unknown. Expression of eosinophil peroxidase (EPO) is restricted to the eosinophil lineage. To understand the mechanisms involved in transcriptional regulation of EPO gene expression, we clone the region of the EPO gene upstream of the transcriptional start site and analyzed the cis-acting elements required for EPO promoter activity in an eosinophil-inducible leukemic cell line, HL-60-C15. The 5'-flanking region of the EPO gene containing 1.5 kilobases of sequence upstream of the transcriptional start site was subcloned into the promoterless pXP2-luciferase vector. The EPO-pXP2 construct and 5' deletion mutants were electroporated into HL-60-C15 cells and luciferase reporter activity assessed. The -1.5-kilobase EPO-pXP2 promoter construct reproducibly expressed > 120-fold more luciferase activity than did promoterless pXP2, and a 12-fold (90%) decrease in promoter activity was obtained when sequences between -122 and -45 base pairs (bp) were deleted. The specificity of the EPO promoter for the eosinophil lineage was analyzed by transfecting the EPO-pXP2 constructs and deletion mutants into HL-60-C15 cells and the parental HL-60 line; EPO promoter activity was 8-10-fold less in the HL-60 parental line, suggesting lineage specific elements in the -122 to -45 bp region. To further characterize regulatory sequences important for promoter activity, we performed linker-scanning analysis on the -122 to -45 bp region and identified a number of positively and negatively acting elements in the promoter. DNase I footprinting was performed with HL-60-C15, HL-60, and HeLa nuclear extracts to identify nuclear proteins that may bind to the functional elements; these experiments identified three protected regions of the EPO promoter which correspond to the functional segments defined by linker-scanning analysis and which contain consensus, potential binding sites for Egr-1, H4TF-1, PuF, CTCF, UBP-1, and GaEII transcription factors. Further study of EPO promoter regulation should elucidate unique transcriptional features of eosinophil gene regulation in granulocyte development.

Charcot-Leyden crystal protein distribution in basophils and its absence in mast cells that differentiate from human umbilical cord blood precursor cells cultured in murine fibroblast culture supernatants or in recombinant human c-kit ligand

Suspension cultures of human umbilical cord blood mononuclear cells supplemented with c-kit ligand-containing additives give rise to a mixture of cells belonging to several lineages. Among those that differentiate in quantity are mature basophils, immature mast cells, and neutrophilic myelocytes. We used an ultrastructural immunogold method to detect the Charcot-Leyden crystal (CLC) protein, an eosinophil- and basophil-specific protein, to study cells that were obtained at sequential times from 3 to 14 weeks in culture. Basophils (and eosinophils, which were present in smaller numbers) labeled for the CLC protein; mast cells did not. The labeled basophil subcellular sites included formed intragranular, cytoplasmic and nuclear CLCs, cytoplasmic particle-filled and homogeneously dense granules, cytoplasm, nucleus, plasma membrane, and cytoplasmic and Golgi area vesicles. Individual basophil ultrastructural phenotypes similar to those associated with stimulated release and recovery reactions showed the expected variations in the gold-labeled subcellular compartments. Macrophages also were labeled for CLC protein within endocytotic-lysosomal structures; neutrophilic myelocytes did not contain CLC protein. On the basis of findings reported here, the combined ultrastructural morphology and immunogold phenotyping of cells differentiating in c-kit ligand-supplemented cultures allows accurate lineage assignment of the developing cells.

Expression of mRNA for the GATA-binding proteins in human eosinophils and basophils: potential role in gene transcription

The expression of the hematopoietic transcription factors GATA-1, GATA-2, and GATA-3 was studied in eosinophils and basophils. Eosinophils express mRNA for GATA-1, GATA-2, and GATA-3. Basophils express GATA-2 and GATA-3. Treatment of HL-60 eosinophilic sublines with either interleukin-5 or butyric acid increased the expression of GATA-1 mRNA concomitant with the expression of eosinophil-specific genes, whereas levels of GATA-2 mRNA remained relatively constant. The presence of mRNA for these proteins in eosinophils and basophils suggests that gene transcription in these lineages may be regulated by GATA-binding proteins.