Binding properties of the artificial zinc fingers coding gene Sint1

Novel activation domain derived from Che-1 cofactor coupled with the artificial protein Jazz drives utrophin upregulation

Our aim is to upregulate the expression level of the dystrophin related gene utrophin in Duchenne muscular dystrophy, thus complementing the lack of dystrophin functions. To this end, we have engineered synthetic zinc finger based transcription factors. We have previously shown that the artificial three-zinc finger protein named Jazz fused with the Vp16 activation domain, is able to bind utrophin promoter A and to increase the endogenous level of utrophin in transgenic mice. Here, we report on an innovative artificial protein, named CJ7, that consists of Jazz DNA binding domain fused to a novel activation domain derived from the regulatory multivalent adaptor protein Che-1/AATF. This transcriptional activation domain is 100 amino acids in size and it is very powerful as compared to the Vp16 activation domain. We show that CJ7 protein efficiently promotes transcription and accumulation of the acetylated form of histone H3 on the genomic utrophin promoter locus.

Synthetic zinc finger peptides: old and novel applications

In the last decade, the efforts in clarifying the interaction between zinc finger proteins and DNA targets strongly stimulated the creativity of scientists in the field of protein engineering. In particular, the versatility and the modularity of zinc finger (ZF) motives make these domains optimal building blocks for generating artificial zinc finger peptides (ZFPs). ZFPs can act as transcription modulators potentially able to control the expression of any desired gene, when fused to an appropriate effector domain. Artificial ZFPs open the possibility to re-program the expression of specific genes at will and can represent a powerful tool in basic science, biotechnology and gene therapy. In this review we will focus on old, novel and possible future applications of artificial ZFPs.Key words: synthetic zinc finger, recognition code, artificial transcription factor, chromatin modification, gene therapy.

The artificial zinc finger protein 'Blues' binds the enhancer of the fibroblast growth factor 4 and represses transcription

The design of novel genes encoding artificial transcription factors represents a powerful tool in biotechnology and medicine. We have engineered a new zinc finger-based transcription factor, named Blues, able to bind and possibly to modify the expression of fibroblast growth factor 4 (FGF-4, K-fgf), originally identified as an oncogene. Blues encodes a three zinc finger peptide and was constructed to target the 9 bp DNA sequence: 5'-GTT-TGG-ATG-3', internal to the murine FGF-4 enhancer, in proximity of Sox-2 and Oct-3 DNA binding sites. Our final aim is to generate a model system based on artificial zinc finger genes to study the biological role of FGF-4 during development and tumorigenesis.

Zinc fingers and a green thumb: manipulating gene expression in plants

Artificial transcription factors can be rapidly constructed from predefined zinc-finger modules to regulate virtually any gene. Stable, heritable up- and downregulation of endogenous genes has been demonstrated in transgenic plants. These advances promise new approaches for creating functional knockouts and conditional overexpression, and for other gene discovery and manipulation applications in plants.

Design and selection of novel Cys2His2 zinc finger proteins

Cys2His2 zinc finger proteins offer a stable and versatile framework for the design of proteins that recognize desired target sites on double-stranded DNA. Individual fingers from these proteins have a simple beta beta alpha structure that folds around a central zinc ion, and tandem sets of fingers can contact neighboring subsites of 3-4 base pairs along the major groove of the DNA. Although there is no simple, general code for zinc finger-DNA recognition, selection strategies have been developed that allow these proteins to be targeted to almost any desired site on double-stranded DNA. The affinity and specificity of these new proteins can also be improved by linking more fingers together or by designing proteins that bind as dimers and thus recognize an extended site. These new proteins can then be modified by adding other domains--for activation or repression of transcription, for DNA cleavage, or for other activities. Such designer transcription factors and other new proteins will have important applications in biomedical research and in gene therapy.

The use of zinc finger peptides to study the role of specific factor binding sites in the chromatin environment

The once ambitious goal of creating custom DNA-binding factors has been achieved. Advances in construction methodology now enable any laboratory to create site-specific binding proteins to nearly any sequence. Using predefined zinc finger modules, new proteins can be constructed in days with minimal cost and using only standard polymerase chain reaction techniques. The existing spectrum of modules can be rearranged to produce more than one billion different proteins that bind with high affinity and specificity. Artificial transcription factors based on modified zinc finger domains have recently been shown by several groups to be capable of activating or repressing transcription of a handful of endogenous genes in the chromatin environment of plant and animal cells. These proteins can also be used in a number of ways to compete with endogenous factors for specific binding sites in vivo. Zinc finger peptides are therefore useful tools in the study of gene regulation and signal transduction. A detailed description of the construction method is presented, along with a full discussion of potential caveats and future expectations.

Long-term expression of a transferred gene in Epstein-Barr virus transformed human B cells

Delivering a gene into the Epstein-Barr virus (EBV)-transformed B cells is useful in studying effects of the gene on B-cell functions. However, although people have been able to efficiently transfer genes into and get them expressed in B-lympho blastoid cells for a time probably long enough to kill the cells using vectors harbouring oriP, the expression time of the delivered gene is not long enough in order to study the gene function in B cells. To solve this problem, we constructed an adeno-associated virus (AAV) plasmid pAGX(+) based on plasmids pSub201 and pRc/CMV. We developed and packaged recombinant AAV (rAAV) expression vectors containing an antisense or a sense DNA fragment of 6A8 cDNA encoding a human alpha-mannosidase, or an antisense fragment of 5D4 cDNA encoding a human cell membrane protein, or EYFP DNA. EBV-transformed B cell SKW6 and 3D5 were transduced with those rAAV or the mock. Transduction with the rAAV-EYFP showed an infection frequency of 64 +/- 3.5% and 58 +/- 6.2% for SKW6 and 3D5 cell, respectively. Genomic polymerase chain reaction (PCR) for neoR gene indicated an integration of the transferred gene into the host DNA. After being cultured and propagated for over 12 months, the cells were detected for the expression of the transferred gene. The RT-PCR, enzymatic assay and Con A binding test demonstrated an inhibition of 6A8 alpha-mannosidase in both SKW6 and 3D5 cells transduced with the antisense 6A8 DNA. Immunofluorescence staining with monoclonal antibodies (MoAb) 5D4 showed a reduction of the 5D4 protein expression on both the cells transduced with the antisense 5D4 DNA. The DNA fragmentation assay showed a resistance of the cells with 6A8 alpha-mannosidase inhibition to apoptosis induction by anti-Fas antibody. The data indicate that the AAV vector pAGX(+) can efficiently introduce genes into EBV-transformed B cells and the delivered gene can be expressed in the cells for more than 12 months which may be long enough for the study of gene functions in B cells.

DNA recognition by Cys2His2 zinc finger proteins

Cys2His2 zinc fingers are one of the most common DNA-binding motifs found in eukaryotic transcription factors. These proteins typically contain several fingers that make tandem contacts along the DNA. Each finger has a conserved beta beta alpha structure, and amino acids on the surface of the alpha-helix contact bases in the major groove. This simple, modular structure of zinc finger proteins, and the wide variety of DNA sequences they can recognize, make them an attractive framework for attempts to design novel DNA-binding proteins. Several studies have selected fingers with new specificities, and there clearly are recurring patterns in the observed side chain-base interactions. However, the structural details of recognition are intricate enough that there are no general rules (a "recognition code") that would allow the design of an optimal protein for any desired target site. Construction of multifinger proteins is also complicated by interactions between neighboring fingers and the effect of the intervening linker. This review analyzes DNA recognition by Cys2His2 zinc fingers and summarizes progress in generating proteins with novel specificities from fingers selected by phage display.

Advances in zinc finger engineering

Recently developments have been made in engineering sequence-specific zinc finger DNA-binding proteins. Advances in this area will soon make it routine to target proteins to specific DNA sequences associated with any given gene. The primary interest is in the regulation of gene expression using customised transcription factors. However, modular catalytic domains are also being developed in order to engineer chimaeric proteins with customised restriction enzyme, methylase and integrase activity.

The artificial zinc finger coding gene 'Jazz' binds the utrophin promoter and activates transcription

Up-regulation of utrophin gene expression is recognized as a plausible therapeutic approach in the treatment of Duchenne muscular dystrophy (DMD). We have designed and engineered new zinc finger-based transcription factors capable of binding and activating transcription from the promoter of the dystrophin-related gene, utrophin. Using the recognition 'code' that proposes specific rules between zinc finger primary structure and potential DNA binding sites, we engineered a new gene named 'Jazz' that encodes for a three-zinc finger peptide. Jazz belongs to the Cys2-His2 zinc finger type and was engineered to target the nine base pair DNA sequence: 5'-GCT-GCT-GCG-3', present in the promoter region of both the human and mouse utrophin gene. The entire zinc finger alpha-helix region, containing the amino acid positions that are crucial for DNA binding, was specifically chosen on the basis of the contacts more frequently represented in the available list of the 'code'. Here we demonstrate that Jazz protein binds specifically to the double-stranded DNA target, with a dissociation constant of about 32 nM. Band shift and super-shift experiments confirmed the high affinity and specificity of Jazz protein for its DNA target. Moreover, we show that chimeric proteins, named Gal4-Jazz and Sp1-Jazz, are able to drive the transcription of a test gene from the human utrophin promoter.

Design of novel sequence-specific DNA-binding proteins

The design and selection of DNA-binding proteins or individual domains capable of novel sequence recognition continues to make great strides. Recent studies have also highlighted the role of the non-DNA-contacting portions of the protein and the optimal assembly of the domains. For the first time, it appears that it is possible to produce proteins capable of targeting any gene with an 18 base pair recognition domain. A variety of applications are being explored, such as targeted transcriptional regulation, recombination and viral integration. These proteins will probably find diverse applications in gene therapy, functional genomics, and agriculture.