Localized egg-cell expression of effector proteins for targeted modification of the Arabidopsis genome

Targeted modification of the genome is an important genetic tool, which can be achieved via homologous, non-homologous or site-specific recombination. Although numerous efforts have been made, such a tool does not exist for routine applications in plants. This work describes a simple and useful method for targeted mutagenesis or gene targeting, tailored to floral-dip transformation in Arabidopsis, by means of specific protein expression in the egg cell. Proteins stably or transiently expressed under the egg apparatus-specific enhancer (EASE) were successfully localized to the area of the egg cell. Moreover, a zinc-finger nuclease expressed under EASE induced targeted mutagenesis. Mutations obtained under EASE control corresponded to genetically independent events that took place specifically in the germline. In addition, RAD54 expression under EASE led to an approximately 10-fold increase in gene targeting efficiency, when compared with wild-type plants. EASE-controlled gene expression provides a method for the precise engineering of the Arabidopsis genome through temporally and spatially controlled protein expression. This system can be implemented as a useful method for basic research in Arabidopsis, as well as in the optimization of tools for targeted genetic modifications in crop plants.     

Identification of a prx1 limb enhancer

Mice with a loss of function of prx1, a paired-related homeobox gene formerly called Mhox, showed craniofacial defects, limb shortening, and incompletely penetrant spina bifida. To investigate the mechanisms that regulate prx1 expression, we analyzed a 2.4-kb prx1 genomic flanking region in transgenic mice. This region of the prx1 gene contains an enhancer element that directs expression of a LacZ reporter gene in limb bud mesenchyme and a subset of craniofacial mesenchyme. Deletional analysis in transgenic founders identified a necessary 530-bp core element. Comparison of this core element with human Prx1 sequence showed two highly conserved cassettes that also contained a prx recognition element. Moreover, transgene expression was diminished in posterior handplate of prx1; prx2 double mutant mice. Our data reveal that the prx1 limb enhancer is proximally located within the prx1 gene and suggest that prx1 may have an autoregulatory function in limb mesenchyme.     

Combination of the ALCR/alcA ethanol switch and GAL4/VP16-UAS enhancer trap system enables spatial and temporal control of transgene expression in Arabidopsis

The experimental control of gene expression in specific tissues or cells at defined time points is a useful tool for the analysis of gene function. GAL4/VP16-UAS enhancer trap lines can be used to selectively express genes in specific tissues or cells, and an ethanol-inducible system can help to control the time of expression. In this study, the combination of the two methods allowed the successful regulation of gene expression in both time and space. For this purpose, a binary vector, 962-UAS::GUS, was constructed in which the ALCR activator and β-glucuronidase (GUS) reporter gene were placed under the control of upstream activator sequence (UAS) elements and the alcA response element, respectively. Three different GAL4/VP16-UAS enhancer trap lines of Arabidopsis were transformed, resulting in transgenic plants in which GUS activity was detected only on ethanol induction and exclusively in the predicted tissues of the enhancer trap lines. As a library of different enhancer trap lines with distinct green fluorescent protein (GFP) patterns exist, transformation with a similar vector, in which GUS is replaced by another gene, would enable the control of the time and place of transgene expression. We have constructed two vectors for easy cloning of the gene of interest, one with a polylinker site and one that is compatible with the GATEWAY™ vector conversion system. The method can be extended to other species when enhancer trap lines become available.     

Comparison of diverged Hoxc8 early enhancer activities reveals modification of regulatory interactions at conserved cis-acting elements

The Hoxc8 early enhancer that controls the initiation and establishment of Hoxc8 expression in the developing mouse embryo is found in different vertebrate lineages including mammals, birds and fish. Mouse and Fugu Hoxc8 early enhancers (200 bp) have diverged in the composition of elements located towards the 3' region. However, they share cis-acting elements A-E located in the 5' region. Mutations at these elements in the context of the mouse Hoxc8 early enhancer affect reporter gene expression in the posterior neural tube, somites and lateral plate mesoderm of day 9.5 mouse embryos. Here, we demonstrate that mutations introduced at the same elements but in the context of the Fugu Hoxc8 early enhancer had different consequences on the reporter gene expression in transgenic mouse embryos. Furthermore, in contrast to the mouse enhancer the Fugu enhancer does not utilize elements D and E in achieving posterior neural tube and somite expression. These results suggest that the diverged sequences prevent regulatory interactions at conserved cis-acting elements. We propose that divergent sequences modify regulatory interactions at conserved elements by providing a "contextual change". Our finding that the enhancer elements do not act in a unitary fashion but function in the context of the surrounding sequence brings a new dimension to the study of cis-regulatory evolution.     

Molecular analysis of the distal enhancer of the mouse alpha-fetoprotein gene.

The mouse alpha-fetoprotein (AFP) gene is transcribed at high levels in the visceral endoderm of the yolk sac and fetal liver and at much lower rates in the endoderm of the fetal gut. Expression of the gene in vivo requires the presence of at least one of three enhancers which lie in its 5' flanking region. In this report, we establish that the most distal AFP enhancer directed consistent expression of a linked AFP minigene in all three endodermal tissues in transgenic mice. The enhancer is composed of three domains, each of which is essential for full enhancer function by transient transfection assays. DNase I footprinting identified three regions of the enhancer which are protected by human hepatoma nuclear extracts, one of which corresponded to a consensus site for HNF-3 binding. Site-directed mutations in this site caused a 10-fold reduction in enhancer function by transient transfection. In transgenic mice, however, the mutation resulted in sporadic expression of the transgene, dependent on the site of integration. A similar acquisition of position-dependent sporadic expression of the transgene was observed with a mutation in a second protein binding site, despite the fact that this mutation had very little effect on enhancer function as assessed by transient transfection. These studies underscore the value of examining the functions of specific protein binding sites in vivo.     

The indeterminate gametophyte1 gene of maize encodes a LOB domain protein required for embryo Sac and leaf development

Angiosperm embryo sac development begins with a phase of free nuclear division followed by cellularization and differentiation of cell types. The indeterminate gametophyte1 (ig1) gene of maize (Zea mays) restricts the proliferative phase of female gametophyte development. ig1 mutant female gametophytes have a prolonged phase of free nuclear divisions leading to a variety of embryo sac abnormalities, including extra egg cells, extra polar nuclei, and extra synergids. Positional cloning of ig1 was performed based on the genome sequence of the orthologous region in rice. ig1 encodes a LATERAL ORGAN BOUNDARIES domain protein with high similarity to ASYMMETRIC LEAVES2 of Arabidopsis thaliana. A second mutant allele of ig1 was identified in a noncomplementation screen using active Mutator transposable element lines. Homozygous ig1 mutants have abnormal leaf morphology as well as abnormal embryo sac development. Affected leaves have disrupted abaxial-adaxial polarity and fail to repress the expression of meristem-specific knotted-like homeobox (knox) genes in leaf primordia, causing a proliferative, stem cell identity to persist in these cells. Despite the superficial similarity of ig1-O leaves and embryo sacs, ectopic knox gene expression cannot be detected in ig1-O embryo sacs.