Purification of mouse MEP-1, a nuclear protein which binds to the metal regulatory elements of genes encoding metallothionein.

Metal regulatory elements (MREs) shared by metallothionein (MT) gene promoters are essential for metal induction of MT genes. MEP-1, a nuclear protein which binds to these elements has been purified from heavy metal-resistant mouse L cells using footprinting, Southwestern and UV cross-linking techniques to assay its binding activity. The purification scheme, starting from crude nuclear extracts, involved a combination of heparin-Sepharose and MRE-DNA affinity chromatography. The purified protein preparation showed a single polypeptide band of 108 kDa on polyacrylamide gel electrophoresis, and 2D-gel analyses revealed the presence of a protein species migrating as a single population of approximately 110 kDa. MEP-1 does not appear to be glycosylated since it eluted with the flow-through on a Wheat Germ Sepharose column. It was retained by a zinc-Chelating Sepharose column suggesting that amino acid residues (i.e., cysteine, histidine) which have an affinity for zinc ions are exposed on the protein surface. Binding studies with the purified protein indicated that it binds specifically to MRE sequences and that the binding can be abolished by a point mutation in the MRE core consensus sequence or by the addition of the chelating agent 1,10-phenanthroline. Binding activity can be restored by the addition of zinc ions to the chelated protein. These results suggest that MEP-1 is one of the major proteins interacting with MRE sequences.     

Identification of a killer cell-specific regulatory element of the mouse perforin gene: an Ets-binding site-homologous motif that interacts with Ets-related proteins.

The gene encoding the cytolytic protein perforin is selectively expressed by activated killer lymphocytes. To understand the mechanisms underlying the cell-type-specific expression of this gene, we have characterized the regulatory functions and the DNA-protein interactions of the 5'-flanking region of the mouse perforin gene (Pfp). A region extending from residues +62 through -141, which possesses the essential promoter activity, and regions further upstream, which are able to either enhance or suppress gene expression, were identified. The region between residues -411 and -566 was chosen for further characterization, since it contains an enhancer-like activity. We have identified a 32-mer sequence (residues -491 to -522) which appeared to be capable of enhancing gene expression in a killer cell-specific manner. Within this segment, a 9-mer motif (5'-ACAGGAAGT-3', residues -505 to -497; designated NF-P motif), which is highly homologous to the Ets proto-oncoprotein-binding site, was found to interact with two proteins, NF-P1 and NF-P2. NF-P2 appears to be induced by reagents known to up-regulate the perforin message level and is present exclusively in killer cells. Electrophoretic mobility shift assay and UV cross-linking experiments revealed that NF-P1 and NF-P2 may possess common DNA-binding subunits. However, the larger native molecular mass of NF-P1 suggests that NF-P1 contains an additional non-DNA-binding subunit(s). In view of the homology between the NF-P motif and other Ets proto-oncoprotein-binding sites, it is postulated that NF-P1 and NF-P2 belong to the Ets protein family. Results obtained from the binding competition assay, nevertheless, suggest that NF-P1 and NF-P2 are related to but distinct from Ets proteins, e.g., Ets-1, Ets-2, and NF-AT/Elf-1, known to be expressed in T cells.     

The polyomavirus major capsid protein VP1 interacts with the nuclear matrix regulatory protein YY1

Polyomavirus reaches the nucleus in a still encapsidated form, and the viral genome is readily found in association with the nuclear matrix. This association is thought to be essential for viral replication. In order to identify the protein(s) involved in the virus-nuclear matrix interaction, we focused on the possible roles exerted by the multifunctional cellular nuclear matrix protein Yin Yang 1 (YY1) and by the viral major capsid protein VP1. In the present work we report on the in vivo association between YY1 and VP1. Using the yeast two-hybrid system we demonstrate that the VP1 and YY1 proteins physically interact through the D-E region of VP1 and the activation domain of YY1.     

Identification of a human protein that interacts with nuclear localization signals

Through a series of label transfer experiments, we have identified a HeLa cell nuclear protein that interacts with nuclear localization signals (NLSs). The protein has a molecular weight of 66,000 and an isoelectric point of approximately 6. It associates with a synthetic peptide that contains the SV-40 T antigen NLS peptide but not with an analogous peptide in which an asparagine is substituted for an essential lysine (un-NLS peptide). In addition to these peptides, several proteins have been tested as label donors. With the proteins, there is a correlation between nuclear localization (assayed with lysolecithin-permeabilized cells) and label transfer to the 66-kD protein. The NLS peptide (but not the un-NLS peptide) competes with the proteins in label transfer experiments, but neither wheat germ agglutinin nor ATP has an effect. These results suggest that the 66-kD protein functions as an NLS receptor in the first step of nuclear localization. In the course of this work, we have observed that the Staphylococcus aureus protein A is a strongly karyophilic protein. Its dramatic nuclear localization properties suggest that it may have multiple copies of an NLS.     

Partial purification of a nuclear protein that binds to the CCAAT box of the mouse alpha 1-globin gene.

We enriched a fraction from nuclear extracts of murine erythroleukemia cells which contains a protein able to form stable complexes with the promoter region of the alpha 1-globin gene. Binding activity, which is present in mouse brain and a variety of cultured mouse and human cell lines, is not erythroid cell specific. Binding studies with alpha-globin gene promoter deletion mutants as well as DNase I footprinting and dimethyl sulfate protection studies showed that the factor bound specifically to the CCAAT box of the alpha 1 promoter. Enriched factor preparations exhibited weak binding to the promoter region of the beta maj-globin gene. This suggests that this protein could bind differentially to these two promoters in vivo. The enriched factor may be a ubiquitous nuclear protein involved in the differential regulation of the alpha 1- and beta maj-globin genes.     

Specificity of nuclear protein binding to a CYP1A1 negative regulatory element

Primary cultures of rat epidermal keratinocytes lose the ability to respond to chemicals with the induction of CYP1A1 gene expression after approximately 15 passages. This repression is mediated by a CT-rich direct repeat negative regulatory DNA (NeRD) element present in the upstream regulatory region of the CYP1A1 gene. Competitive gel retardation analysis using keratinocyte nuclear extracts and mutant NeRD oligonucleotides revealed the presence of two specific protein-NeRD complexes and revealed the specific nucleotides important for the formation of each complex. These studies demonstrate that these two factors bind to overlapping sites within the NeRD element. Nucleotide specificity of complex A formation is similar to that of previously identified nuclear silencing factors, while that of complex B appears to represent a unique CT-rich binding factor. These results suggest that repression of CYP1A1 gene expression in high passage keratinocytes may involve the interplay between at least two specific NeRD binding factors.     

A nuclear factor requires Zn2+ to bind a regulatory MRE element of the mouse gene encoding metallothionein-1

The metal ion requirement of nuclear proteins for binding to the metal regulatory element d(MREd) of the mouse gene encoding metallothionein-1 was investigated using an in vitro exonuclease III footprinting assay. The specific DNA-binding activity of the factor was inactivated by the chelating agents, EDTA and 1,10-phenanthroline. Binding activity was restored by Zn2+, but not by Cd2+. These results show that Zn2+ ions are a required component for specific in vitro DNA binding of the MREd-binding protein.