Bert J. van der Zaal

ZFN‐induced mutagenesis and gene‐targeting in Arabidopsis through Agrobacterium‐mediated floral dip transformation

Zinc-finger nucleases (ZFNs) are artificial restriction enzymes, custom designed for induction of double-strand breaks (DSBs) at a specific locus. These DSBs may result in site-specific mutagenesis or homologous recombination at the repair site, depending on the DNA repair pathway that is used. These promising techniques for genome engineering were evaluated in Arabidopsis plants using Agrobacterium-mediated floral dip transformation. A T-DNA containing the target site for a ZFN pair, that was shown to be active in yeast, was integrated in the Arabidopsis genome. Subsequently, the corresponding pair of ZFN genes was stably integrated in the Arabidopsis genome and ZFN activity was determined by PCR and sequence analysis of the target site. Footprints were obtained in up to 2% of the PCR products, consisting of deletions ranging between 1 and 200 bp and insertions ranging between 1 and 14 bp. We did not observe any toxicity from expression of the ZFNs. In order to obtain ZFN-induced gene-targeting (GT), Arabidopsis plants containing the target site and expressing the ZFN pair were transformed with a T-DNA GT construct. Three GT plants were obtained from approximately 3000 transformants. Two of these represent heritable true GT events, as determined by PCR, Southern blot analysis and sequencing of the resulting recombined locus. The third plant showed an ectopic GT event. No GT plants were obtained in a comparable number of transformants that did not contain the ZFNs. Our results demonstrate that ZFNs enhance site-specific mutagenesis and gene-targeting of Agrobacterium T-DNA constructs delivered through floral dip transformation.

Live cell imaging of repetitive DNA sequences via GFP-tagged polydactyl zinc finger proteins.

Several techniques are available to study chromosomes or chromosomal domains in nuclei of chemically fixed or living cells. Current methods to detect DNA sequences in vivo are limited to trans interactions between a DNA sequence and a transcription factor from natural systems. Here, we expand live cell imaging tools using a novel approach based on zinc finger-DNA recognition codes. We constructed several polydactyl zinc finger (PZF) DNA-binding domains aimed to recognize specific DNA sequences in Arabidopsis and mouse and fused these with GFP. Plants and mouse cells expressing PZF:GFP proteins were subsequently analyzed by confocal microscopy. For Arabidopsis, we designed a PZF:GFP protein aimed to specifically recognize a 9-bp sequence within centromeric 180-bp repeat and monitored centromeres in living roots. Similarly, in mouse cells a PZF:GFP protein was targeted to a 9-bp sequence in the major satellite repeat. Both PZF:GFP proteins localized in chromocenters which represent heterochromatin domains containing centromere and other tandem repeats. The number of PZF:GFP molecules per centromere in Arabidopsis, quantified with near single-molecule precision, approximated the number of expected binding sites. Our data demonstrate that live cell imaging of specific DNA sequences can be achieved with artificial zinc finger proteins in different organisms.

ZFN-mediated gene targeting of the Arabidopsis protoporphyrinogen oxidase gene through Agrobacterium-mediated floral dip transformation.

Previously, we showed that ZFN-mediated induction of double-strand breaks (DSBs) at the intended recombination site enhanced the frequency of gene targeting (GT) at an artificial target locus using Agrobacterium-mediated floral dip transformation. Here, we designed zinc finger nucleases (ZFNs) for induction of DSBs in the natural protoporphyrinogen oxidase (PPO) gene, which can be conveniently utilized for GT experiments. Wild-type Arabidopsis plants and plants expressing the ZFNs were transformed via floral dip transformation with a repair T-DNA with an incomplete PPO gene, missing the 5′ coding region but containing two mutations rendering the enzyme insensitive to the herbicide butafenacil as well as an extra KpnI site for molecular analysis of GT events. Selection on butafenacil yielded 2 GT events for the wild type with a frequency of 0.8 × 10−3 per transformation event and 8 GT events for the ZFNs expressing plant line with a frequency of 3.1 × 10−3 per transformation event. Molecular analysis using PCR and Southern blot analysis showed that 9 of the GT events were so-called true GT events, repaired via homologous recombination (HR) at the 5′ and the 3′ end of the gene. One plant line contained a PPO gene repaired only at the 5′ end via HR. Most plant lines contained extra randomly integrated T-DNA copies. Two plant lines did not contain extra T-DNAs, and the repaired PPO genes in these lines were transmitted to the next generation in a Mendelian fashion.

Promoter analysis of the auxin-regulated tobacco glutathione S-transferase genes Nt103-1 and Nt103-35

We have analysed the promoter regions of two closely related auxin-regulated glutathione S-transferase genes. All active deletion constructs tested showed expression of the reporter gene β-glucuronidase (gusA) in root tips of young seedlings and newly developing lateral roots. Auxin treatment greatly enhanced the level of expression. The Nt103-1 promoter region −370/−276 was found to be necessary, at least as a quantitative element to confer auxin-responsiveness to a reporter gene, and sequences responsible for the auxin-responsiveness must be located downstream of −370. The region −651/−370 contains sequence information necessary for uninduced expression. The Nt103-35 promoter manifested its auxin-responsiveness within the −504/−310 region. Electrophoretic mobility shift analysis, using nuclear extracts from tobacco leaves and suspension cells, identified a factor binding to a sequence (ap103, TGAGTCT) at position −560 of the Nt103-1 promoter, which shows homology to the mammalian AP-1 site. A second factor was found to bind a sequence (as103, ATAGCTAAGTGCTTACG) with homology to the CaMV 35S promoter as-1 element. The as103 element is present in both promoters and positioned around −360, so within the region determined to be indispensable for the response to auxin. A third factor was found binding to the −276/−190 region of both promoters. Combined, these data point to the relevance of a 90 bp region for auxin-induced activity of both tobacco genes. The ASF-1 like factor binding to the as103 element within this region might be involved in mediating the auxin response.

Agrobacterium-Mediated T-DNA Transfer and Integration by Minimal VirD2 Consisting of the Relaxase Domain and a Type IV Secretion System Translocation Signal

The VirD2 protein of Agrobacterium tumefaciens is essential for processing and transport of the T-DNA. It has at least three functional domains: a relaxase domain at the N terminus, a bipartite nuclear localization signal (NLS), and a sequence called omega at the C terminus. We confirm here that deletions of the C-terminal part of VirD2 led to lack of transfer of T-DNA but, for the first time, we report that virulence is restored when these truncations are supplemented at the C terminus by a short translocation signal from the VirF protein. The lack of virulence of C-terminal deletions suggests that the C-terminal part contains all or part of the translocation signal of VirD2. Using a novel series of mutant VirD2 proteins, the C-terminal half of VirD2 was further investigated. We demonstrate that the C-terminal 40 amino acids of VirD2, which include the NLS and omega, contain all or part of the translocation domain necessary for transport of VirD2 into plant cells, while another element is present in the middle of the protein. The finding that a type IV secretion system transport signal at the C terminus of VirD2 is necessary for virulence provides evidence for the role of VirD2 as a pilot protein driving translocation of the T-strand.

Engineering zinc finger protein transcription factors to downregulate the epithelial glycoprotein-2 promoter as a novel anti-cancer treatment

Zinc finger protein transcription factors (ZFP‐TFs) are emerging as powerful novel tools for the treatment of many different diseases. ZFPs are DNA‐binding motifs and consist of modular zinc finger domains. Each domain can be engineered to recognize a specific DNA triplet, and stitching six domains together results in the recognition of a gene‐specific sequence. Inhibition of gene expression can be achieved by fusing a repressor domain to these DNA‐binding motifs. In this study, we engineered ZFP‐TFs to downregulate the activity of the epithelial glycoprotein‐2 (EGP‐2) promoter. The protein EGP‐2 is overexpressed in a wide variety of cancer types and EGP‐2 downregulation has been shown to result in a decreased oncogenic potential of tumor cells. Therefore, downregulation of EGP‐2 expression by ZFP‐TFs provides a novel anti‐cancer therapeutic. Using a straightforward strategy, we engineered a 3‐ZFP that could bind a 9 bp sequence within the EGP‐2 promoter. After the addition of a repressor domain, this 3‐ZFP‐TF could efficiently downregulate EGP‐2 promoter activity by 60%. To demonstrate the flexibility of this technology, we coupled an activation domain to the engineered ZFP, resulting in a nearly 200% increase in EGP‐2 promoter activity. To inhibit the endogenous EGP‐2 promoter, we engineered 6‐ZFP‐TFs. Although none of the constructed ZFP‐TFs could convincingly modulate the endogenous promoter, efficient and specific inhibition of the exogenous promoter was observed. Overall, ZFP‐TFs are versatile bi‐directional modulators of gene expression and downregulation of EGP‐2 promoter activity using ZFP‐TFs can ultimately result in a novel anti‐cancer treatment.

Artificial transcription factor-mediated regulation of gene expression

The transcriptional regulation of endogenous genes with artificial transcription factors (TFs) can offer new tools for plant biotechnology. Three systems are available for mediating site-specific DNA recognition of artificial TFs: those based on zinc fingers, TALEs, and on the CRISPR/Cas9 technology. Artificial TFs require an effector domain that controls the frequency of transcription initiation at endogenous target genes. These effector domains can be transcriptional activators or repressors, but can also have enzymatic activities involved in chromatin remodeling or epigenetic regulation. Artificial TFs are able to regulate gene expression in trans, thus allowing them to evoke dominant mutant phenotypes. Large scale changes in transcriptional activity are induced when the DNA binding domain is deliberately designed to have lower binding specificity. This technique, known as genome interrogation, is a powerful tool for generating novel mutant phenotypes. Genome interrogation has clear mechanistic and practical advantages over activation tagging, which is the technique most closely resembling it. Most notably, genome interrogation can lead to the discovery of mutant phenotypes that are unlikely to be found when using more conventional single gene-based approaches.

Involvement of Rad52 in T-DNA circle formation during Agrobacterium tumefaciens-mediated transformation of Saccharomyces cerevisiae

Agrobacterium tumefaciens cells carrying a tumour inducing plasmid (Ti‐plasmid) can transfer a defined region of transfer DNA (T‐DNA) to plant cells as well as to yeast. This process of Agrobacterium‐mediated transformation (AMT) eventually results in the incorporation of the T‐DNA in the genomic DNA of the recipient cells. All available evidence indicates that T‐strand transfer closely resembles conjugal DNA transfer as found between Gram‐negative bacteria. However, where conjugal plasmid DNA transfer starts via relaxase‐mediated processing of a single origin of transfer (oriT), the T‐DNA is flanked by two imperfect direct border repeats which are both substrates for the Ti‐plasmid encoded relaxase VirD2. Yeast was used as a model system to investigate the requirements of the recipient cell for the formation of T‐DNA circles after AMT. It was found that, despite the absence of self‐homology on the T‐DNA, the homologous repair proteins Rad52 and Rad51 are involved in T‐DNA circle formation. A model is presented involving the formation of T‐DNA concatemers derived from T‐strands by a process of strand‐transfer catalysed by VirD2. These concatemers are then resolved into T‐DNA circles by homologous recombination in the recipient cell.

Zinc finger artificial transcription factor–based nearest inactive analogue/nearest active analogue strategy used for the identification of plant genes controlling homologous recombination

In previous work, we selected a particular transcription factor, designated VP16-HRU, from a pool of zinc finger artificial transcription factors (ZF-ATFs) used for genome interrogation. When expressed in Arabidopsis thaliana under control of the ribosomal protein S5A promoter, the RPS5A::VP16-HRU construct led to a 200- to 300-fold increase in the frequency of somatic intrachromosomal homologous recombination (iHR). Because the expression of each ZF-ATF leads to a large number of transcriptional changes, we designed a strategy employing a collection of structurally similar ZF-ATFs to filter out the transcriptional changes relevant to the phenotype by deep sequencing. In that manner, 30 transcripts were found to be consistently induced in plants with enhanced homologous recombination (HR). For 25 of the cognate genes, their effect on the HR process was assessed using cDNA/gDNA expression constructs. For three genes, ectopic expression indeed led to enhanced iHR frequencies, albeit much lower than the frequency observed when a HR-inducing ZF-ATF was present. Altogether, our data demonstrate that despite the large number of transcriptional changes brought about by individual ZF-ATFs, causal changes can be identified. In our case, the picture emerged that a natural regulatory switch for iHR does not exist but that ZF-ATFs-like VP16-HRU act as an ectopic master switch, orchestrating the timely expression of a set of plant genes that each by themselves only have modest effects, but when acting together support an extremely high iHR frequency.

Increase in the capacities of the cytochrome and alternative respiratory pathways in tobacco cells caused by 2,4-D and kinetin

Summary Addition of 2,4-D (2.2 pM) to a 2,4-D dependent cell suspension culture of Nicotiana tabacum L. var. White Burley that was starved for 2,4-D for 5 days did not result in an increase in oxygen uptake before the start of cell division. Within 3 h after addition of 2,4-D an increase in the capacity of both the cytochrome and alternative respiratory pathways was observed. This indicates an increase in number or size of the mitochondria rather than a specific stimulation of one of the pathways. The increase was not mediated by ethylene and the alternative pathway did not become engaged. At a concentration supraoptimal for the induction of cell division, 2,4-D not only increased the capacities but it enhanced total oxygen uptake as well, albeit transient. After addition of kinetin no cell division occurred, but it induced an increase in the respiratory capacities after 17 h.