A study on optimization of pat gene expression cassette for maize transformation.

Phosphinothricin acetyltransferase gene (pat) is an important selectable marker and also a key herbicide trait gene in several commercial products. In maize, the transformation frequency (TF) using pat as a selectable marker is the lowest among the commonly used marker options including epsps, pmi or ppo. Low pat transformation efficiency can become a major bottleneck in our ability to efficiently produce large numbers of events, especially for large molecular stack vectors with multiple trait gene cassettes. The root cause of the lower efficiency of pat in maize is not well understood and it is possible that the causes are multifaceted, including maize genotype, pat marker cassette, trait gene combinations and selection system. In this work we have identified a new variant of pat gene through codon optimization that consistently produced a higher transformation frequency (> 2x) than an old version of the pat gene that has codons optimized for expression in dicot plants. The level of PAT protein in all 16 constructs was also found multifold higher (up to 40 fold) over that of the controls. All of the T0 low copy transgenic plants generated from the 16 different constructs showed excellent tolerance to ammonium glufosinate herbicide spray tests at 4x and 8x recommended field application rates (1x = 595 g active ingredient (ai)/hectare of ammonium glufosinate) in the greenhouse.

Strategies to improve low copy transgenic events in Agrobacterium-mediated transformation of maize.

Transgenic plants containing low copy transgene insertion free of vector backbone are highly desired for many biotechnological applications. We have investigated two different strategies for increasing the percentage of low copy events in Agrobacterium-mediated transformation experiments in maize. One of the strategies is to use a binary vector with two separate T-DNAs, one T-DNA containing an intact E.coli manA gene encoding phosphomannose isomerase (PMI) as selectable marker gene cassette and another T-DNA containing an RNAi cassette of PMI sequences. By using this strategy, low copy transgenic events containing the transgenes were increased from 43 to 60 % in maize. An alternate strategy is using selectable marker gene cassettes containing regulatory or coding sequences derived from essential plant genes such as 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) or MADS box transcription factor. In this paper we demonstrate that higher percentage of low copy transgenic events can be obtained in Agrobacterium-mediated maize transformation experiments using both strategies. We propose that the above two strategies can be used independently or in combination to increase transgenic events that contain low copy transgene insertion in Agrobacterium-mediated transformation experiments.

Protamine-mediated DNA coating remarkably improves bombardment transformation efficiency in plant cells.

We have developed a method by which remarkably higher efficiencies of transient and stable transformation were achieved in bombardment transformation of plants. Over fivefold increase in transient gus gene expression was achieved when rice or maize suspension cells were bombarded with gold particles coated with plasmid DNA in the presence of protamine instead of the conventional spermidine. A 3.3-fold improvement in stable transformation efficiency was also observed using rice suspension cells with the new coating approach. The coated protamine-plasmid DNA complex resisted degradation by a DNase or by rice cell extract much longer than the spermidine-plasmid DNA complex. The results from this study suggest that protamine protects plasmid DNA longer than spermidine when being delivered inside the cells, probably by forming a nano-scale complex, and thus helps improve the efficiency of particle bombardment-mediated plant transformation.

Activity of the 5' regulatory regions of the rice polyubiquitin rubi3 gene in transgenic rice plants as analyzed by both GUS and GFP reporter genes.

Ubiquitin is an abundant protein involved in protein degradation and cell cycle control in plants and rubi3 is a polyubiquitin gene isolated from rice (Oryza sativa L.). Using both GFP and GUS as reporter genes, we analyzed the expression pattern of the rubi3 promoter as well as the effects of the rubi3 5'-UTR (5' untranslated region) intron and the 5' terminal 27 bp of the rubi3 coding sequence on the activity of the promoter in transgenic rice plants. The rubi3 promoter with the 5'-UTR intron was active in all the tissue and cell types examined and supported more constitutive expression of reporter genes than the maize Ubi-1 promoter. The rubi3 5'-UTR intron mediated enhancement on the activity of its promoter in a tissue-specific manner but did not alter its overall expression pattern. The enhancement was particularly intense in roots, pollen grains, inner tissue of ovaries, and embryos and aleurone layers in maturing seeds. The translational fusion of the first 27 bp of the rubi3 coding sequence to GUS gene further enhanced GUS expression directed by the rubi3 promoter in all the tissues examined. The rubi3 promoter should be an important addition to the arsenal of strong and constitutive promoters for monocot transformation and biotechnology.

Gene expression enhancement mediated by the 5' UTR intron of the rice rubi3 gene varied remarkably among tissues in transgenic rice plants.

Introns are important sequence elements that modulate the expression of genes. Using the GUS reporter gene driven by the promoter of the rice (Oryza sativa L.) polyubiquitin rubi3 gene, we investigated the effects of the 5' UTR intron of the rubi3 gene and the 5' terminal 27 bp of the rubi3 coding sequence on gene expression in stably transformed rice plants. While the intron enhanced GUS gene expression, the 27-bp fused to the GUS coding sequence further augmented GUS expression level, with both varying among different tissues. The intron elevated GUS gene expression mainly at mRNA accumulation level, but also stimulated enhancement at translational level. The enhancement on mRNA accumulation, as determined by realtime quantitative RT-PCR, varied remarkably with tissue type. The augmentation by the intron at translational level also differed by tissue type, but to a lesser extent. On the other hand, the 27-bp fusion further boosted GUS protein yield without affecting mRNA accumulation level, indicating stimulation at translation level, which was also affected by tissue type. The research revealed substantial variation in the magnitudes of intron-mediated enhancement of gene expression (IME) among tissues in rice plants and the importance of using transgenic plants for IME studies.

Transcriptional and post-transcriptional enhancement of gene expression by the 5' UTR intron of rice rubi3 gene in transgenic rice cells.

Introns play a very important role in regulating gene expression in eukaryotes. In plants, many introns enhance gene expression, and the effect of intron-mediated enhancement (IME) of gene expression is reportedly often more profound in monocots than in dicots. To further gain insight of IME in monocot plants, we quantitatively dissected the effect of the 5' UTR intron of the rice rubi3 gene at various gene expression levels in stably transformed suspension cell lines. The intron enhanced the GUS reporter gene activity in these lines by about 29-fold. Nuclear run-on experiments demonstrated a nearly twofold enhancement by the 5' UTR intron at the transcriptional level. RNA analysis by RealTime quantitative RT-PCR assays indicated the intron enhanced the steady state RNA level of the GUS reporter gene by nearly 20-fold, implying a strong role of the intron in RNA processing and/or export. The results also implicated a moderate role of the intron in enhancement at the translational level ( approximately 45%). Moreover, results from a transient assay experiment using a shortened exon 1 sequence revealed an important role of exon 1 of rubi3 in gene expression. It may also hint a divergence in IME mechanisms between plant and animal cells. These results demonstrated transcriptional enhancement by a plant intron, but suggested that post-transcriptional event(s) be the major source of IME.

Expression of the bacteriophage T4 lysozyme gene in tall fescue confers resistance to gray leaf spot and brown patch diseases.

Tall fescue (Festuca arundinacea Schreb.) is an important turf and forage grass species worldwide. Fungal diseases present a major limitation in the maintenance of tall fescue lawns, landscapes, and forage fields. Two severe fungal diseases of tall fescue are brown patch, caused by Rhizoctonia solani, and gray leaf spot, caused by Magnaporthe grisea. These diseases are often major problems of other turfgrass species as well. In efforts to obtain tall fescue plants resistant to these diseases, we introduced the bacteriophage T4 lysozyme gene into tall fescue through Agrobacterium-mediated genetic transformation. In replicated experiments under controlled environments conducive to disease development, 6 of 13 transgenic events showed high resistance to inoculation of a mixture of two M. grisea isolates from tall fescue. Three of these six resistant plants also displayed significant resistance to an R. solani isolate from tall fescue. Thus, we have demonstrated that the bacteriophage T4 lysozyme gene confers resistance to both gray leaf spot and brown patch diseases in transgenic tall fescue plants. The gene may have wide applications in engineered fungal disease resistance in various crops.

Expression enhancement of a rice polyubiquitin gene promoter.

An 808 bp promoter from a rice polyubiquitin gene, rubi3, has been isolated. The rubi3 gene contained an open reading frame of 1,140 bp encoding a pentameric polyubiquitin arranged as five tandem, head-to-tail repeats of 76 aa. The 1,140 bp 5' UTR intron of the gene enhanced its promoter activity in transient expression assays by 20-fold. Translational fusion of the GUS reporter gene to the coding sequence of the ubiquitin monomer enhanced GUS enzyme activity in transient expression assays by 4.3-fold over the construct containing the original rubi3 promoter (including the 5' UTR intron) construct. The enhancing effect residing in the ubiquitin monomer coding sequence has been narrowed down to the first 9 nt coding for the first three amino acid residues of the ubiquitin protein. Mutagenesis at the third nucleotide of this 9 nt sequence still maintains the enhancing effect, but leads to translation of the native GUS protein rather than a fusion protein. The resultant 5' regulatory sequence, consisting of the rubi3 promoter, 5' UTR exon and intron, and the mutated first 9 nt coding sequence, has an activity nearly 90-fold greater than the rubi3 promoter only (without the 5' UTR intron), and 2.2-fold greater than the maize Ubi1 gene promoter (including its 5' UTR intron). The newly created expression vector is expected to enhance transgene expression in monocot plants. Considering the high conservation of the polyubiquitin gene structure in higher plants, the observed enhancement in gene expression may apply to 5' regulatory sequences of other plant polyubiquitin genes.

Resistance to wheat streak mosaic virus in transgenic wheat engineered with the viral coat protein gene.

Wheat (Triticum aestivum) plants were stably transformed with the coat protein (CP) gene of wheat streak mosaic virus (WSMV) by the biolistic method. Eleven independently transformed plant lines were obtained and five were analyzed for gene expression and resistance to WSMV. One line showed high resistance to inoculations of two WSMV strains. This line had milder symptoms and lower virus titer than control plants after inoculation. After infection, new growth did not show symptoms. The observed resistance was similar to the 'recovery' type resistance described previously using WSMV NIb transgene and in other systems. This line looked morphologically normal but had an unusually high transgene copy number (approximately 90 copies per 2C homozygous genome). Northern hybridization analysis indicated a high level of degraded CP mRNA expression. However, no coat protein expression was detected.