ABC transporters (also known as traffic ATPases) form a large family of proteins responsible for the translocation of a variety of compounds across membranes of both prokaryotes and eukaryotes. The recently completed Escherichia coli genome sequence revealed that the largest family of paralogous E. coli proteins is composed of ABC transporters. Many eukaryotic proteins of medical significance belong to this family, such as the cystic fibrosis transmembrane conductance regulator (CFTR), the P-glycoprotein (or multidrug-resistance protein) and the heterodimeric transporter associated with antigen processing (Tap1-Tap2). Here we report the crystal structure at 1.5 A resolution of HisP, the ATP-binding subunit of the histidine permease, which is an ABC transporter from Salmonella typhimurium. We correlate the details of this structure with the biochemical, genetic and biophysical properties of the wild-type and several mutant HisP proteins. The structure provides a basis for understanding properties of ABC transporters and of defective CFTR proteins.
Key Points Delivery of ZFNs and donor templates results in high levels of gene correction in human CD34+ cells from multiple sources, including SCD BM. Modified CD34+ cells are capable of engrafting immunocompromised NSG mice and produce cells from multiple lineages.
Gene knockout is the most powerful tool for determining gene function or permanently modifying the phenotypic characteristics of a cell. Existing methods for gene disruption are limited by their efficiency, time to completion, and/or the potential for confounding off-target effects. Here, we demonstrate a rapid single-step approach to targeted gene knockout in mammalian cells, using engineered zinc-finger nucleases (ZFNs). ZFNs can be designed to target a chosen locus with high specificity. Upon transient expression of these nucleases the target gene is first cleaved by the ZFNs and then repaired by a natural-but imperfect-DNA repair process, nonhomologous end joining. This often results in the generation of mutant (null) alleles. As proof of concept for this approach we designed ZFNs to target the dihydrofolate reductase (DHFR) gene in a Chinese hamster ovary (CHO) cell line. We observed biallelic gene disruption at frequencies >1%, thus obviating the need for selection markers. Three new genetically distinct DHFR ؊/؊ cell lines were generated. Each new line exhibited growth and functional properties consistent with the specific knockout of the DHFR gene. Importantly, target gene disruption is complete within 2-3 days of transient ZFN delivery, thus enabling the isolation of the resultant DHFR ؊/؊ cell lines within 1 month. These data demonstrate further the utility of ZFNs for rapid mammalian cell line engineering and establish a new method for gene knockout with application to reverse genetics, functional genomics, drug discovery, and therapeutic recombinant protein production.genetic engineering ͉ zinc-finger proteins T he use of gene knockouts in basic research, functional genomics, and industrial cell line engineering is severely limited by an absence of methods for rapid targeting and disruption of an investigator-specified gene. Early approaches to somatic cell gene disruption used genome-wide nontargeted methods, including ionizing radiation and chemical-induced mutagenesis (1, 2) whereas more recent methods used targeted homologous recombination (HR) (3). However, the Ͼ1,000-fold lower frequency of the targeted HR event relative to random integration in most mammalian cell lines (beyond mouse ES cells) can necessitate screening thousands of clones and take several months to identify a biallelic targeted gene knockout. Strategies including positive and negative marker selection and promoter-trap can boost efficiencies considerably, although these approaches present their own technical challenges and are not always successful in achieving high efficiency targeting (4, 5). Although advances with adeno-associated viral delivery strategies continue to improve the efficiency of knockouts (6, 7), the frequency is still very low and the time required to achieve biallelic gene knockout remains a barrier to its routine adoption. Here, we present a general solution for rapid gene knockout in mammalian cells.The repair of double strand DNA breaks (DSB) in mammalian cells occurs via the distinct mechanisms of homol...
We have mapped conserved regions of enhanced DNase I accessibility within the endogenous chromosomal locus of vascular endothelial growth factor A (VEGF-A). Synthetic zinc finger protein (ZFP) transcription factors were designed to target DNA sequences contained within the DNase I-hypersensitive regions. These ZFPs, when fused to either VP16 or p65 transcriptional activation domains, were able to activate expression of the VEGF-A gene as assayed by mRNA accumulation and VEGF-A protein secretion through a range exceeding that induced by hypoxic stress. Importantly, multiple splice variants of VEGF-A mRNA with defined physiological functions were induced by a single engineered ZFP transcription factor. We present evidence for an enhanced activation of VEGF-A gene transcription by ZFP transcription factors fused to VP16 and p65 targeted to two distinct chromosomal sites >500 base pairs upstream or downstream of the transcription start site. Our strategy provides a novel approach for dissecting the requirements for gene regulation at a distance without altering the DNA sequence of the endogenous target locus.
Gene therapy with genetically modified human CD34+ hematopoietic stem cells (HSCs) may be safer using targeted integration (TI) of transgenes into a genomic ‘safe harbor’ site than random viral integration. We demonstrate that temporally optimized delivery of zinc finger nuclease mRNA via electroporation and adeno associated virus (AAV) 6 delivery of donor constructs in human HSCs approaches clinically relevant levels of TI into the AAVS1 safe harbor locus. Up to 58% Venus-positive HSCs with 6–16% human cell marking were observed following engraftment into mice. In HSCs from patients with X-linked chronic granulomatous disease (X-CGD), caused by mutations in the gp91phox subunit of the NADPH oxidase, TI of a gp91phox transgene into AAVS1 in resulted in ~15% gp91phox expression and increased NADPH oxidase activity in ex vivo–derived neutrophils. In mice transplanted with corrected HSCs, 4–11% of human cells in the bone marrow expressed gp91phox. This method for TI into AAVS1 may be broadly applicable to correction of other monogenic diseases.
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