The FLP enzyme catalyzes recombination between specific target sequences in DNA. Here we use FLP to temporally and spatially control gene expression in the nematode C. elegans. Transcription is blocked by the presence of an “off cassette” between the promoter and the coding region of the desired product. The “off cassette” is composed of a transcriptional terminator flanked by FLP recognition targets (FRT). This sequence can be excised by FLP recombinase to bring together the promoter and the coding region. We have introduced two fluorescent reporters into the system: a red reporter for promoter activity prior to FLP expression and a green reporter for expression of the gene of interest after FLP expression. The constructs are designed using the multisite Gateway system, so that promoters and coding regions can be quickly mixed and matched. We demonstrate that heat-shock-driven FLP recombinase adds temporal control on top of tissue specific expression provided by the transgene promoter. In addition, the temporal switch is permanent, rather than acute, as is usually the case for heat-shock driven transgenes. Finally, FLP expression can be driven by a tissue specific promoter to provide expression in a subset of cells that can only be addressed as the intersection of two available promoters. As a test of the system, we have driven the light chain of tetanus toxin, a protease that cleaves the synaptic vesicle protein synaptobrevin. We show that we can use this to inactivate synaptic transmission in all neurons or a subset of neurons in a FLP-dependent manner.
Zinc finger nucleases (ZFNs) are hybrid proteins that have been developed as targetable cleavage reagents for double-stranded DNA, both in vitro and in vivo. This protocol describes the design and construction of new DNA-binding domains comprised of zinc fingers (ZFs) directed at selected DNA sequences. Because the ZFNs must dimerize to cut DNA, they are designed in pairs for any new site. The first step is choosing a DNA segment of interest and searching it for sequences that can be recognized by combinations of existing ZFs. The second step is the construction of coding sequences for the selected ZF sets. Third, these coding sequences are linked to that of the nonspecific cleavage domain from the FokI restriction endonuclease in a cloning vector of choice. Finally, the ZFNs are expressed in Escherichia coli, partially purified, and tested in vitro for cleavage of the target sequences to which they were designed. If all goes smoothly, design, construction and cloning can be completed in about two weeks, with expression and testing completed in one additional week.
Zinc-finger nucleases are chimeric proteins consisting of engineered zinc-finger DNA-binding motifs attached to an endonuclease domain. These proteins can induce site-specific DNA double-strand breaks in genomic DNA, which are then substrates for cellular repair mechanisms. Here, we demonstrate that engineered zinc-finger nucleases function effectively in somatic cells of the nematode Caenorhabditis elegans. Although gene-conversion events were indistinguishable from uncut DNA in our assay, nonhomologous end joining resulted in mutations at the target site. A synthetic target on an extrachromosomal array was targeted with a previously characterized nuclease, and an endogenous genomic sequence was targeted with a pair of specifically designed nucleases. In both cases, Ϸ20% of the target sites were mutated after induction of the corresponding nucleases. Alterations in the extrachromosomal targets were largely products of end-filling and blunt ligation. By contrast, alterations in the chromosomal target were mostly deletions. We interpret these differences to reflect the abundance of homologous templates present in the extrachromosomal arrays versus the paucity of such templates for repair of chromosomal breaks. In addition, we find evidence for the involvement of error-prone DNA synthesis in both homologous and nonhomologous pathways of repair. DNA ligase IV is required for efficient end joining, particularly of blunt ends. In its absence, a secondary end-joining pathway relies more heavily on microhomologies in producing deletions.DNA repair ͉ gene targeting ͉ nematodes ͉ nonhomologous end joining T he ability to make targeted double-strand breaks in chromosomal DNA has several important uses. It allows the detailed study of DNA repair mechanisms; it leads to localized mutagenesis at the break site; and it enhances the efficiency of targeted gene replacement through homologous recombination. We have been exploring the capabilities of one class of targetable cleavage reagents, the zinc-finger nucleases (ZFNs).ZFNs are chimeric proteins composed of DNA-binding Cys 2 His 2 zinc fingers fused to the nonspecific nuclease domain of the restriction enzyme FokI (1). Each finger makes contact primarily with a separate DNA triplet (2, 3). Natural and artificial zinc fingers have been characterized that bind to all 5Ј-GNN-3Ј, many ANN and CNN, and some TNN triplets (4-7). Furthermore, the modular nature of the zinc fingers allows them to be joined in essentially arbitrary combinations. Typically, three zinc fingers are combined to bind to a specific 9-bp DNA sequence with the nanomolar affinity required to be biologically useful, but additional fingers can be incorporated to confer increased specificity (8-11). Zinc-finger fusions to various functional domains have been used to create artificial transcription factors and DNA-modifying proteins (12,13).When attached to the FokI nuclease domain, zinc fingers can direct cleavage to specific DNA sequences. The nuclease domain must dimerize to cleave DNA (14), and because the di...
More than half of Caenorhabditis elegans pre-mRNAs lose their original 59 ends in a process termed ''trans-splicing'' in which the RNA extending from the transcription start site (TSS) to the site of trans-splicing of the primary transcript, termed the ''outron,'' is replaced with a 22-nt spliced leader. This complicates the mapping of TSSs, leading to a lack of available TSS mapping data for these genes. We used growth at low temperature and nuclear isolation to enrich for transcripts still containing outrons, applying a modified SAGE capture procedure and high-throughput sequencing to characterize 59 termini in this transcript population. We report from this data both a landscape of 59-end utilization for C. elegans and a representative collection of TSSs for 7351 trans-spliced genes. TSS distributions for individual genes were often dispersed, with a greater average number of TSSs for trans-spliced genes, suggesting that trans-splicing may remove selective pressure for a single TSS. Upstream of newly defined TSSs, we observed well-known motifs (including TATAA-box and SP1) as well as novel motifs. Several of these motifs showed association with tissue-specific expression and/or conservation among six worm species. Comparing TSS features between trans-spliced and non-trans-spliced genes, we found stronger signals among outron TSSs for preferentially positioning of flanking nucleosomes and for downstream Pol II enrichment. Our data provide an enabling resource for both experimental and theoretical analysis of gene structure and function in C. elegans. [Supplemental material is available for this article.]In most organisms, the locations of transcription start sites (TSSs) can be determined by establishing the sequences of mRNA 59 ends. For a subset of single-cell eukaryotes and animals, however, a processing event known as ''trans-splicing'' obscures the locations of the TSSs (Sutton and Boothroyd 1986;Krause and Hirsh 1987;Lasda and Blumenthal 2011). Trans-splicing is an efficient process that results in removal of the 59 end of the pre-mRNA, replacing it with a short 59 leader that is then retained on the mature mRNA. The removed sequence (between the TSS and the first active 39 splice site in the newly transcribed mRNA precursor) is called the ''outron' ' (Conrad et al. 1991). Trans-splicing is a spliceosomecatalyzed process that can be thought of as a surrogate use of a mobile 59 splice site contained on a short (usually ;100 nt) RNA called an SL RNA. SL RNAs are present in the nucleus in the form of Sm protein-bound small nuclear ribonucleoprotein particles (snRNPs), where the 59 22 nt forms the SL exon, with the 39 portion serving as ''intron.' ' Caenorhabditis elegans has been a valuable model system for studying a variety of aspects of gene expression (including transsplicing) (Krause and Hirsh 1987;Lasda and Blumenthal 2011). Approximately 70% of C. elegans genes are subject to trans-splicing (Allen et al. 2011;Lasda and Blumenthal 2011). C. elegans has two types of trans-splicing, each with a distin...
Expanded triplet repeats have been identified as the genetic basis for a growing number of neurological and skeletal disorders. To examine the contribution of double-strand break repair to CAG⅐CTG repeat instability in mammalian systems, we developed zinc finger nucleases (ZFNs) that recognize and cleave CAG repeat sequences. Engineered ZFNs use a tandem array of zinc fingers, fused to the FokI DNA cleavage domain, to direct double-strand breaks (DSBs) in a site-specific manner. We first determined that the ZFNs cleave CAG repeats in vitro. Then, using our previously described tissue culture assay for identifying modifiers of CAG repeat instability, we found that transfection of ZFN-expression vectors induced up to a 15-fold increase in changes to the CAG repeat in human and rodent cell lines, and that longer repeats were much more sensitive to cleavage than shorter ones. Analysis of individual colonies arising after treatment revealed a spectrum of events consistent with ZFN-induced DSBs and dominated by repeat contractions. We also found that expressing a dominant-negative form of RAD51 in combination with a ZFN, dramatically reduced the effect of the nuclease, suggesting that DSB-induced repeat instability is mediated, in part, through homology directed repair. These studies identify a ZFN as a useful reagent for characterizing the effects of DSBs on CAG repeats in cells.DNA repair ͉ gene targeting ͉ triplet repeat instability ͉ zinc finger nucleases
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