The p53-induced Wig-1 protein binds double-stranded RNAs with structural characteristics of siRNAs and miRNAs

Wig-1 is a p53-induced zinc finger protein. Here we show that human Wig-1 binds long (>or=23 bp) dsRNAs with 5'-overhangs. The first zinc finger domain is necessary but not sufficient for this dsRNA-binding in vitro. Wig-1 also binds dsRNA in living cells via zinc fingers 1 and 2. Both zinc fingers 1 and 2 are important for Wig-1-mediated growth suppression. Moreover, Wig-1 binds 21 bp dsRNAs with 3'-protruding ends. These findings demonstrate that human Wig-1 can bind different types of dsRNAs, including dsRNAs resembling small interfering RNAs (siRNAs) and microRNAs (miRNAs), and indicate that dsRNA binding has a role in Wig-1-mediated regulation of cell growth.     

Structural organization of Staf-DNA complexes

The transactivator Staf, which contains seven contiguous zinc fingers of the C₂-H₂ type, exerts its effects on gene expression by binding to specific targets in vertebrate small nuclear RNA (snRNA) and snRNA-type gene promoters. Here, we have investigated the interaction of the Staf zinc finger domain with the optimal Xenopus selenocysteine tRNA (xtRNA^Sec) and human U6 snRNA (hU6) Staf motifs. Generation of a series of polypeptides containing increasing numbers of Staf zinc fingers tested in binding assays, by interference techniques and by binding site selection served to elucidate the mode of interaction between the zinc fingers and the Staf motifs. Our results provide strong evidence that zinc fingers 3–6 represent the minimal zinc finger region for high affinity binding to Staf motifs. Furthermore, we show that the binding of Staf is achieved through a broad spectrum of close contacts between zinc fingers 1–6 and xtRNA^Sec or optimal sites or between zinc fingers 3–6 and the hU6 site. Extensive DNA major groove contacts contribute to the interaction with Staf that associates more closely with the non-template than with the template strand. Based on these findings and the structural information provided by the solved structures of other zinc finger–DNA complexes, we propose a model for the interaction between Staf zinc fingers and the xtRNA^Sec, optimal and hU6 sites.     

A new double-stranded RNA-binding protein that interacts with PKR

We have identified a 74 kDa double-stranded (ds)RNA-binding protein that shares extensive homology with the mouse spermatid perinuclear RNA-binding (Spnr) protein. p74 contains two dsRNA-binding motifs (dsRBMs) that are essential for preferential binding to dsRNA. Previously, dsRNA-binding proteins were shown to undergo homo- and heterodimerization, raising the possibility that regulation of activity could be controlled by interactions between different family members. Homodimerization is required to activate the dsRNA-dependent protein kinase PKR, whereas heterodimerization between PKR and other dsRNA-binding proteins can inhibit kinase activity. We have found that p74 also interacts with PKR, both the wild-type enzyme and a catalytically defective mutant (K296R). While co-expression of p74 and wild-type PKR in the yeast Saccharomyces cerevisiae did not alter PKR activity, co-expression of p74 and the catalytically defective K296R mutant surprisingly resulted in abnormal morphology and cell death in transformants that maintained a high level of p74 expression. These transformants could be rescued by overexpression of the α-subunit of wild-type eukaryotic translation initiation factor 2 (eIF2α), one of the known substrates for PKR. We hypothesize that competing heterodimers between p74–K296R PKR and eIF2α–K296R PKR may control cell growth such that stabilization of the p74–K296R PKR heterodimer induces abnormal morphology and cell death.     

Multiple genes encoding zinc finger domains are expressed in human T cells

Proteins containing zinc finger domains have been implicated in developmental control of gene expression in Drosophila, Xenopus, mouse, and humans. Multiple cDNAs encoding zinc (II) finger structures were isolated from human cell lines of T-cell origin to explore whether zinc finger genes participate in the differentiation of human hematopoietic cells. Initial restriction analysis, genomic Southern blotting, and partial sequence comparisons revealed at least 30 nonoverlapping cDNAs designated cKox(1-30) encoding zinc finger motifs. Analysis of cKox1 demonstrated that Kox1 is a single-copy gene that is expressed in a variety of hematopoietic and nonhaematopoietic cell lines. cKox1 encodes 11 zinc fingers that were shown to bind zinc when expressed as a beta-gal-Kox1 fusion protein. Further analysis of the predicted amino acid sequence revealed a heptad repeat of leucines NH2-terminal to the finger region, which suggests a potential domain for homo- or heterodimer protein formation. On the basis of screening results it was estimated that approximately 70 zinc finger genes are expressed in human T cells. Zinc finger motifs are probably present in a large family of proteins with quite diverse and distinct functions. However, comparisons of individual finger regions in cKox1 with finger regions of cKox2 to cKox30 showed that some zinc fingers are highly conserved in their putative alpha-helical DNA binding region, supporting the notion of a zinc finger-specific DNA recognition code.     

Identification of ZFR, an ancient and highly conserved murine chromosome-associated zinc finger protein

In a screen for RNA binding proteins expressed during murine spermatogenesis, we cloned a novel, ancient zinc finger protein possessing a region common to a small class of RNA binding proteins. Zfr (zinc finger RNA binding) encodes a protein of 1052 amino acids with three widely spaced Cys2His2 zinc fingers. Outside of the zinc fingers, ZFR shares a region that is highly conserved between several RNA binding proteins containing copies of the double-stranded RNA binding motif. By northern blotting, Zfr is expressed at highest levels within the testis, ovary and brain. Immunohistochemistry and confocal microscopy were used to show that ZFR is highly expressed during meiosis I in males and females and is chromosome associated. Zfr is also expressed in Sertoli cells in the testis and granulosa cells in the ovary where it is localized to the nucleus. Using fluorescent in situ hybridization we mapped Zfr to chromosome 15 region A. ZFR appears to be an ancient protein, as apparent homologs exist in invertebrates (D. melanogaster) nematodes (C. elegans) and humans (H. sapiens).     

Condensation by DNA looping facilitates transfer of large DNA molecules into mammalian cells

Experimental studies of complete mammalian genes and other genetic domains are impeded by the difficulty of introducing large DNA molecules into cells in culture. Previously we have shown that GST–Z2, a protein that contains three zinc fingers and a proline-rich multimerization domain from the polydactyl zinc finger protein RIP60 fused to glutathione S-transferase (GST), mediates DNA binding and looping in vitro. Atomic force microscopy showed that GST–Z2 is able to condense 130–150 kb bacterial artificial chromosomes (BACs) into protein–DNA complexes containing multiple DNA loops. Condensation of the DNA loops onto the Z2 protein–BAC DNA core complexes with cationic lipid resulted in particles that were readily transferred into multiple cell types in culture. Transfer of total genomic linear DNA containing amplified DHFR genes into DHFR^– cells by GST–Z2 resulted in a 10-fold higher transformation rate than calcium phosphate co-precipitation. Chinese hamster ovarian cells transfected with a BAC containing the human TP53 gene locus expressed p53, showing native promoter elements are active after GST–Z2-mediated gene transfer. Because DNA condensation by GST–Z2 does not require the introduction of specific recognition sequences into the DNA substrate, condensation by the Z2 domain of RIP60 may be used in conjunction with a variety of other agents to provide a flexible and efficient non-viral platform for the delivery of large genes into mammalian cells.     

Structure and DNA binding characteristics of the three‐Cys2His2 domain of mouse testis zinc finger protein

The C‐terminal three‐Cys₂His₂ zinc‐finger domain (TZD) of mouse testis zinc‐finger protein binds to the 5′‐TGTACAGTGT‐3′ at the Aie1 (aurora‐C) promoter with high specificity. Interestingly, the primary sequence of TZD is unique, possessing two distinct linkers, TGEKP and GAAP, and distinct residues at presumed DNA binding sites at each finger, especially finger 3. A K_d value of ～10^?8 M was obtained from surface plasmon resonance analysis for the TZD‐DNA complex. NMR structure of the free TZD showed that each zinc finger forms a typical ββα fold. On binding to DNA, chemical shift perturbations and the R₂ transverse relaxation rate in finger 3 are significantly smaller than those in fingers 1 and 2, which indicates that the DNA binding affinity in finger 3 is weaker. Furthermore, the shift perturbations between TZD in complex with the cognate DNA and its serial mutants revealed that both ADE7 and CYT8, underlined in 5′‐ATATGTACAGTGTTAT‐3′, are critical in specific binding, and the DNA binding in finger 3 is sequence independent. Remarkably, the shift perturbations in finger 3 on the linker mutation of TZD (GAAP mutated to TGEKP) were barely detected, which further indicates that finger 3 does not play a critical role in DNA sequence‐specific recognition. The complex model showed that residues important for DNA binding are mainly located on positions ?1, 2, 3, and 6 of α‐helices in fingers 1 and 2. The DNA sequence and nonsequence‐specific bindings occurring simultaneously in TZD provide valuable information for better understanding of protein–DNA recognition. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

GLI3 encodes a 190-kilodalton protein with multiple regions of GLI similarity.

The GLI oncogene, discovered by virtue of its amplification in human tumors, encodes a sequence-specific DNA-binding protein containing five zinc fingers. We have now characterized one member of a family of GLI-related zinc finger genes. A previously identified fragment of GLI3 genomic DNA was used to localize GLI3 to chromosome 7p13 and to isolate cDNA clones. Sequence analysis of these clones and identification of the GLI3 protein by using polyclonal antisera demonstrated that GLI3 encodes a protein of 1,596 amino acids and an apparent molecular mass of 190 kilodaltons. Amino acid sequence comparison with GLI demonstrated seven regions of similarity (53 to 88% identity), with the zinc fingers representing the most similar region. Furthermore, when produced in vitro, the GLI3 protein bound specifically to genomic DNA fragments containing GLI-binding sites. Amino acid sequence comparison with the product of another member of the GLI family, the Drosophila segment polarity gene cubitus interruptus Dominant, revealed additional similarity that was not shared with GLI. These studies suggest that the GLI-related genes encode a family of DNA-binding proteins with related target sequence specificities. In addition, sequence similarity aside from the zinc finger region suggests that other aspects of function are shared among the members of this gene family.     

Subsets of the zinc finger motifs in dsRBP-ZFa can bind double-stranded RNA

dsRBP-ZFa is a Xenopus zinc finger protein that binds dsRNA and RNA-DNA hybrids with high affinity and in a sequence-independent manner. The protein consists of a basic N-terminal region with seven C2H2 zinc finger motifs and an acidic C-terminal region that is not required for binding. The last four zinc finger motifs, and the linkers that join them, are nearly identical repeats, while the first three motifs and their linkers are each unique. To identify which regions of the protein are involved in nucleic acid binding, we examined the ability of five protein fragments to bind dsRNA and RNA-DNA hybrids. Our studies reveal that a fragment encompassing the three N-terminal, unique zinc finger motifs and another encompassing the last three of the nearly identical motifs have binding properties similar to the full-length protein. Since these two fragments do not share zinc finger motifs of the same sequence, dsRBP-ZFa must contain more than one type of zinc finger motif capable of binding dsRNA. As with the full-length protein, ssRNA and DNA do not significantly compete for dsRNA binding by the fragments.