David J. Peterson

Structure and function of selectable and non-selectable transgenes in maize after introduction by particle bombardment

Zea mays transformants produced by particle bombardment of embryogenic suspension culture cells of the genotype A188 × B73 and selected on kanamycin or bialaphos were characterized with respect to transgene integration, expression, and inheritance. Selection on bialaphos, mediated by thebar orpat genes, was more efficient than selection on kanamycin, mediated by thenptII gene. Most transformants contained multicopy, single locus, transgene insertion events. A transgene expression cassette was more likely to be rearranged if expression of that gene was not selected for during callus growth. Not all plants regenerated from calli representing single transformation events expressed the transgenes, and a non-selectable gene (uidA) was expressed in fewer plants than was the selectable transgene. Mendelian inheritance of transgenes consistent with transgene insertion at a single locus was observed for approximately two thirds of the transformants assessed. Transgene expression was typically, but not always, predictable in progeny plants-transgene silencing, as well as poor transgene transmission to progeny, was observed in some plant lines in which the parent plants had expressed the transgene.

Commercial production of aprotinin in transgenic maize seeds

The development of genetic transformation technology for plants has stimulated an interest in using transgenic plants as a novel manufacturing system for producing different classes of proteins of industrial and pharmaceutical value. In this regard, we report the generation and characterization of transgenic maize lines producing recombinant aprotinin. The transgenic aprotinin lines recovered were transformed with the aprotinin gene using the bar gene as a selectable marker. The bar and aprotinin genes were introduced into immature maize embryos via particle bombardment. Aprotinin gene expression was driven by the maize ubiquitin promoter and protein accumulation was targeted to the extracellular matrix. One line that showed a high level of aprotinin expression was characterized in detail. The protein accumulates primarily in the embryo of the seed. Southern blot analysis showed that the line had at least 20 copies of the bar and aprotinin genes. Further genetic analysis revealed that numerous plants derived from this transgenic line had a large range of levels of expression of the aprotinin gene (0–0.069%) of water-soluble protein in T2 seeds. One plant lineage that showed stable expression after 4 selfing generations was recovered from the parental transgenic line. This line showed an accumulation of the protein in seeds that was comparable to the best T2 lines, and the recombinant aprotinin could be effectively recovered and purified from seeds. Biochemical analysis of the purified aprotinin from seeds revealed that the recombinant aprotinin had the same molecular weight, N-terminal amino acid sequence, isoelectric point, and trypsin inhibition activity as native aprotinin. The demonstration that the recombinant aprotinin protein purified from transgenic maize seeds has biochemical and functional properties identical to its native counterpart provides a proof-of-concept example for producing new generation products for the pharmaceutical industry.

Engineering herbicide-resistant maize using chimeric RNA/DNA oligonucleotides

Maize plants resistant to imidazolinone herbicides were engineered through targeted modification of endogenous genes using chimeric RNA/DNA oligonucleotides. A precise single-point mutation was introduced into genes encoding acetohydroxyacid synthase (AHAS), at a position known to confer imidazolinone resistance. Phenotypically normal plants from the converted events (C0) were regenerated from resistant calli and grown to maturity. Herbicide leaf painting confirmed the resistance phenotype in C0 plants and demonstrated the anticipated segregation pattern in C1 progeny. DNA cloning and sequencing of the targeted region in resistant calli and derived C0 and C1 plants confirmed the expected mutation. These results demonstrate that oligonucleotide-mediated gene manipulation can be applied to crop improvement. This approach does not involve genomic integration of transgenes. Since the new trait is obtained through modifying a gene within its normal chromosomal context, position effects, transgene silencing, or other concerns that arise as part of developing transgenic events are avoided.

The maize caffeic acid O-methyltransferase gene promoter is active in transgenic tobacco and maize plant tissues

The pattern of expression directed by the promoter of the maize caffeic acid O-methyltransferase (COMT) gene was studied by histochemical and fluorometric β-glucuronidase (GUS) analysis in transgenic maize and tobacco plants. The COMT promoter directs GUS expression to the xylem and the other tissues undergoing lignification, and it responds to wounding and to elicitors. In transgenic maize plants, expression of GUS corresponds to the pattern of expression of the endogenous COMT gene as determined by northern analysis and in situ hybridization. The pattern in transgenic tobacco plants clearly shows that the maize promoter sequence is recognized by tobacco transcriptional factors, in spite of the anatomical differences and the evolutionary distance between these two species. The results suggest that the most significant promoter signals that induce the specific expression of the lignin COMT are conserved in different species.

Mesoporous Silica Nanoparticle-Mediated Intracellular Cre Protein Delivery for Maize Genome Editing via loxP Site Excision,

A recombinase protein loaded into mesoporous silica nanoparticles was delivered through the biolistic method to maize tissues, leading to site-specific recombination. The delivery of proteins instead of DNA into plant cells allows for a transient presence of the protein or enzyme that can be useful for biochemical analysis or genome modifications. This may be of particular interest for genome editing, because it can avoid DNA (transgene) integration into the genome and generate precisely modified “nontransgenic” plants. In this work, we explore direct protein delivery to plant cells using mesoporous silica nanoparticles (MSNs) as carriers to deliver Cre recombinase protein into maize (Zea mays) cells. Cre protein was loaded inside the pores of gold-plated MSNs, and these particles were delivered by the biolistic method to plant cells harboring loxP sites flanking a selection gene and a reporter gene. Cre protein was released inside the cell, leading to recombination of the loxP sites and elimination of both genes. Visual selection was used to select recombination events from which fertile plants were regenerated. Up to 20% of bombarded embryos produced calli with the recombined loxP sites under our experimental conditions. This direct and reproducible technology offers an alternative for DNA-free genome-editing technologies in which MSNs can be tailored to accommodate the desired enzyme and to reach the desired tissue through the biolistic method.

Gene Transfer Mediated by Site-Specific Recombination Systems

Stable genetic transformation depends on DNA recombination, a process defined as a physical exchange of genetic information between interacting DNA molecules. DNA recombination reactions are conveniently divided into three categories: homologous recombination, site-specific recombination, and all others pejoratively described as illegitimate recombination. Current plant transformation techniques primarily rely on the least understood mechanisms, that is, illegitimate recombination. As a result, genetic transformations are unpredictable with respect to the efficiency of transformation and reliability of transgene expression. The use of homologous recombination in DNA integration processes (described as gene targeting) is still a very inefficient process despite substantial ongoing research efforts to develop such techniques both for animal and plant applications [1, 2], Site-specific recombination may bridge the gap between random, unpredictable illegitimate integration and future fully controllable genomic DNA manipulations based on homologous recombination or other mechanisms. There is already available evidence that site-specific recombination can increase the efficiency of genetic transformation, improve its reliability, and reduce the extent of modifications imposed on genomic DNA during the transformation process.