Structure and erythroid cell-restricted expression of a chicken cDNA encoding a novel zinc finger protein of the Cys + His class

A genetic screen in Drosophila for genes interacting with senseless during neuronal development identifies the importin moleskin

Senseless (Sens) is a conserved transcription factor required for normal development of the Drosophila peripheral nervous system. In the Drosophila retina, sens is necessary and sufficient for differentiation of R8 photoreceptors and interommatidial bristles (IOBs). When Sens is expressed in undifferentiated cells posterior to the morphogenetic furrow, ectopic IOBs are formed. This phenotype was used to identify new members of the sens pathway in a dominant modifier screen. Seven suppressor and three enhancer complementation groups were isolated. Three groups from the screen are the known genes Delta, lilliputian, and moleskin/DIM-7 (msk), while the remaining seven groups represent novel genes with previously undefined functions in neural development. The nuclear import gene msk was identified as a potent suppressor of the ectopic interommatidial bristle phenotype. In addition, msk mutant adult eyes are extremely disrupted with defects in multiple cell types. Reminiscent of the sens mutant phenotype, msk eyes demonstrate reductions in the number of R8 photoreceptors due to an R8 to R2,5 fate switch, providing genetic evidence that Msk is a component of the sens pathway. Interestingly, in msk tissue, the loss of R8 fate occurs earlier than with sens and suggests a previously unidentified stage of R8 development between atonal and sens.

Gfi-1B plays a critical role in terminal differentiation of normal and transformed erythroid progenitor cells

Growth factor independence-1B (Gfi-1B) is a transcription factor with a highly conserved transcriptional repressor snail-Gfi-1 (SNAG) domain and 6 zinc-finger domains at the N- and C-terminus, respectively. Disruption of the Gfi-1B gene is lethal in the embryo with failure to produce definitive enucleated erythrocytes. In this study, we analyzed the role of Gfi-1B in human erythropoiesis. We observed an increase of Gfi-1B expression during erythroid maturation of human primary progenitor cells. We studied the consequences of variations in Gfi-1B expression in 2 transformed cell lines (K562 and UT7 cells), as well as in primary CD36(+)/GPA(-) progenitors. A knock-down of Gfi-1B delayed the terminal differentiation of K562 and primary cells. Forced expression of Gfi-1B in UT7 and K562 cells led to an arrest of proliferation and an induction of erythroid differentiation. Enforced expression of Gfi-1B in primary cells at the colony-forming units-erythroid (CFU-E) stage led to a partial glycophorin A (GPA) induction after erythropoietin (EPO) withdrawal but failed to protect cells from apoptosis. Deletion of the SNAG repressor domain abolished Gfi-1B-induced erythroid maturation, strongly suggesting that Gfi-1B acts in the late stage of erythroid differentiation as a transcriptional repressor.

Gfi-1 oncoproteins in hematopoiesis

The family of Gfi-1 zinc finger transcriptional repressor oncoproteins consists of Gfi-1 and Gfi-1B. Recent gene targeting experiments and mutational screening in humans have revealed an essential role for Gfi-1 and Gfi-1B in hematopoiesis. Mice lacking Gfi-1 are unexpectedly neutropenic. Neutrophil differentiation is abolished and T lymphocyte differentiation is partially blocked in these mice. Heterozygous germline mutations of Gfi-1 causes severe congenital neutropenia (SCN) in humans. Ela2, whose germline mutation is the major contributor to hereditary neutropenias, is repressed in vivo by Gfi-1. Gfi-1B disruption is embryonic lethal due to a block of erythropoiesis. Gfi-1B is required for both erythroid and megakaryocyte development. The ongoing identification of repressed target genes and interacting transcriptional cofactors is helping to unravel the central contributions of these two hematopoietic factors.

The zinc-finger proto-oncogene Gfi-1b is essential for development of the erythroid and megakaryocytic lineages

Gfi-1 and Gfi-1b are novel proto-oncogenes identified by retroviral insertional mutagenesis. By gene targeting, we establish that Gfi-1b is required for the development of two related blood lineages, erythroid and megakaryocytic, in mice. Gfi-1b(-/-) embryonic stem cells fail to contribute to red cells of adult chimeras. Gfi-1b(-/-) embryos exhibit delayed maturation of primitive erythrocytes and subsequently die with failure to produce definitive enucleated erythrocytes. The fetal liver of mutant mice contains erythroid and megakaryocytic precursors arrested in their development. Myelopoiesis is normal. Therefore, Gfi-1b is an essential transcriptional regulator of erythroid and megakaryocyte development.

A house fly gene homologous to the zinc finger proto-oncogene Gfi-1

Gfi-1 was first cloned from rats (and subsequently from mice, chickens, and humans) and was found to be a 55-kDa protein that bound to DNA in a sequence-specific manner to act as a transcriptional repressor and proto-oncogene. Using PCR, a Gfi-1 homologous cDNA (mdGfi-1) was cloned from the house fly, Musca domestica. Comparison of the mdGfi-1-deduced amino acid sequence with those of vertebrates indicates only moderate overall homology (40.9-43.0% identity). However, these proteins are highly conserved when the zinc finger domains are compared, with mdGfi-1 having 81.0-82.2% identity to the vertebrate homologues. Within each of the six zinc finger domains there are three amino acids that are predicted to contact the DNA and these amino acids are 100% identical for all six domains for all species. Given that Gfi-1 is highly conserved from insects to vertebrates suggests this may be an important transcription factor in many taxa.

Cytokine-induced changes in chromatin structure and in vivo footprints in the inducible NOS promoter

Transcription of the human inducible nitric oxide synthase (iNOS) gene is regulated by inflammatory cytokines in a tissue-specific manner. To determine whether differences in cytokine-induced mRNA levels between pulmonary epithelial cells (A549) and hepatic biliary epithelial cells (AKN-1) result from different protein or DNA regulatory mechanisms, we identified cytokine-induced changes in DNase I-hypersensitive (HS) sites in 13 kb of the iNOS 5'-flanking region. Data showed both constitutive and inducible HS sites in an overlapping yet cell type-specific pattern. Using in vivo footprinting and ligation-mediated PCR to detect potential DNA or protein interactions, we examined one promoter region near -5 kb containing both constitutive and cytokine-induced HS sites. In both cell types, three in vivo footprints were present in both control and cytokine-treated cells, and each mapped within a constitutive HS site. The remaining footprint appeared only in response to cytokine treatment and mapped to an inducible HS site. These studies, performed on chromatin in situ, identify a portion of the molecular mechanisms regulating transcription of the human iNOS gene in both lung- and liver-derived epithelial cells.

The zinc finger protein Gfi-1 can enhance STAT3 signaling by interacting with the STAT3 inhibitor PIAS3

STAT factors act as signal transducers of cytokine receptors and transcriptionally activate specific target genes. The recently discovered protein PIAS3 binds directly to STAT3 and blocks transcriptional activation. Here, we present experimental evidence implementing the zinc finger protein Gfi-1 as a new regulatory factor in STAT3-mediated signal transduction. The interaction between the two proteins first became evident in a yeast two-hybrid screen but was also seen in coprecipitation experiments from eukaryotic cells. Moreover, we found that both Gfi-1 and PIAS3 colocalize in a characteristic nuclear dot structure. While PIAS3 exerts a profound inhibitory effect on STAT3-mediated transcription of target promoters, Gfi-1 can overcome the PIAS3 block and significantly enhances STAT3-mediated transcriptional activation. In primary T cells, Gfi-1 was able to amplify IL-6-dependent T-cell activation. As Gfi-1 is a known, dominant proto-oncogene, our findings bear particular importance for the recently described ability of STAT3 to transform cells malignantly and offer an explanation of the oncogenic potential of Gfi-1 in T lymphocytes.