Development of an airgun device for particle bombardment

Construction and operation of an airgun device for transient gene-expression studies in monocots is described. Compressed air in a cylinder of an airgun was used as the source of propulsion for DNA-coated gold or tungsten particles. Under a partial vacuum of 700 mm Hg, velocity of the macrocarrier was measured at 520 m sec^?1 and 432 m sec^?1 at atmospheric pressure. Optimum distance from the stopping plate to different target cells during bombardment ranged from 4 to 7 cm. Mean transformation efficiency of the GUS-gene marker was estimated at 350 transformants per 65 mg fresh weight of the maize cultured cells. Up to 200 GUS transformed cells were detected per 100 mg of embryogenic rice callus. Use of gold flakes or tungsten powder as microcarriers resulted in similar transformation rates. No transformation was observed in any cells when DNA constructs contained prokaryotic translation initiation sequences for the GUS gene. Based on transient GUS assays, further modification of the airgun device will likely be necessary to obtain high stable transformation rates.     

Effects of tissue type and promoter strength on transient GUS expression in sugarcane following particle bombardment

Effects of tissue type and promoter strength on transient GUS expression in the sugarcane (Saccharum spp. hybrids) cultivar NCo 310 were evaluated following microprojectile bombardment of leaf explants. GUS expression was histochemically or fluorometrically measured 48 h after delivery of the uidA gene. High levels of GUS expression were obtained in leaf segments isolated from young, expanding sugarcane leaves cultured for 1, 3, or 6 d prior to bombardment. The promoter derived from the maize ubiquitin 1 gene (Ubi-1) produced significantly more GUS foci and higher GUS activity levels compared to the recombinant Emu, rice actin 1 (Act1), and CaMV 35S promoters. Our transient expression system should facilitate efforts to identify promoters and elements which will regulate desired gene expression patterns in sugarcane and aid in development of an efficient stable transformation system.Abbreviations Act1 rice actin 1 gene - CaMV cauliflower mosaic virus - GUS ß-glucuronidase - Ubi-1 maize ubiquitin 1 gene - uidA GUS gene - X-Glu 5-bromo-4-chloro-3-indoylglucuronide     

利用花色素苷合成调节基因C1-R作为基因枪转化效果指示的研究

报道了玉米花色素苷合成调节基因Ｃ１－Ｒ在小麦幼胚、玉米愈伤组织、水稻愈伤组织、烟草叶片中的瞬时表达情况。由于调节基因Ｃ１－Ｒ激活了植物体细胞内花色素苷的合成,因此不需任何生色底物,即可活体观察到花色素苷的表达。结果表明,对于目前仍主要通过基因枪法转化的几类主要粮食作物──小麦、玉米、水稻、枪击４８ｈ后,放大２倍便清晰可见红色斑点,且其表达强度远高于ＧＵＳ的表达,证明Ｃ１－Ｒ可作为一个很好的衡量打枪效果的指示,同时还证明其在双子叶植物──烟草叶片的基因枪转化瞬时表达体系中也起同样的作用。     

A maize α-zein promoter drives an endosperm-specific expression of transgene in rice

An alpha-zein promoter isolated from maize containing P-box, E motif sequence TGTAAAGT, opaque-2 box and TATA box was studied for its tissue-specific expression in rice. A 1,098 bp promoter region of alpha-zein gene, fused to the upstream of gusA reporter gene was used for transforming rice immature embryos (ASD 16 or IR 64) via the particle bombardment-mediated method. PCR analysis of putative transformants demonstrated the presence of transgenes (the zein promoter, gusA and hpt). Nineteen out of 37 and two out of five events generated from ASD 16 and IR 64 were found to be GUS-positive. A histological staining analysis performed on sections of mature T₁ seeds revealed that the GUS expression was limited to the endosperm and not to the pericarp or the endothelial region. GUS expression was observed only in the following seed development stages : milky (14–15 DAF), soft dough (17–18 DAF), hard dough (20–23 DAF), and mature stages (28–30 DAF) of zein-gusA transformed (T₀) plants. On the contrary a constitutive expression of GUS was evident in CaMV35S-gusA plants. PCR and Southern blotting analyses on T₁ plants demonstrated a stable integration and inheritance of transgene in the subsequent T₁ generation. GUS assay on T₂ seeds revealed that the expression of gusA gene driven by alpha-zein promoter was stable and tissue-specific over two generations. Results suggest that this alpha-zein promoter could serve as an alternative promoter to drive endosperm-specific expression of transgenes in rice and other cereal transformation experiments.     

DNA addition or deletion is associated with a major karyotype polymorphism in the fungal phytopathogen Colletotrichum gloeosporioides

The bacterial GUS (β-glucuronidase) gene has been used as a reporter gene in plants and bacteria and was recently expressed in filamentous fungi. Here, we report the application of GUS for the establishment of transient and stable gene expression systems in the phytopathogenic fungus Cochliobolus heterostrophus. The utility of the transient expression system is demonstrated in applications involving promoter analysis and in tests of various parameters of a transformation system, for comparing the rates of stable and transient transformation events using GUS as sole screening marker and for comparing different transformation systems using either GUS or a dominant selection marker. For these purposes two plasmids were constructed harbouring the GUS gene and the hph gene of Escherichia coli which confers resistance to the antibiotic hygromycin B (HygB), ligated either to the P1 or GPD1 (glyceraldehyde 3 phosphate dehydrogenase) promoter of C. heterostrophus. In transient expression studies the first appearance of GUS activity was observed within 2 h after transformation and maximal values were obtained after 7 or 10 h, depending on the promoter fused to the GUS gene. At peak activity, the GPD1 promoter was revealed to be five fold stronger than the P1 promoter. The same difference in promoter strenght was observed when the vectors were stably integrated in the fungal genome. Using the GUS gene as a colour selection marker in plate assays, it was possible to detect transformants and monitor the process of transient gene expression visually. Blue transformants obtained by screening for the GUS phenotype were mitotically unstable. Transformants obtained by selecting for HygB resistance were mitotically stable and expressed the β-glucuronidase gene constitutively. GUS activity in fungal colonies was detected fluorometrically in a nondestructive plate assay. The pathogenicity of these strains was unaltered compared with wild type. The GUS phenotype allowed selective blue staining of the colonizing mycelia on maize leaves.     

Screening promoters for Anthurium transformation using transient expression

Key message

There are multiple publications on Anthurium transformation, yet a commercial product has not been achieved. This may be due to use of non-optimum promoters here we address this problem.

Abstract

Different promoters and tissue types were evaluated for transient β-glucuronidase (GUS) expression in Anthurium andraeanum Hort. ‘Marian Seefurth’ following microprojectile bombardment. Plasmids containing the Ubiquitin 2, Actin 1, Cytochrome C1 from rice, Ubiquitin 1 from maize and 35S promoter from Cauliflower Mosaic Virus fused to a GUS reporter gene were bombarded into in vitro grown anthurium lamina, somatic embryos and roots. The number of GUS foci and the intensity of GUS expression were evaluated for each construct. Ubiquitin promoters from rice and maize resulted in the highest number of expressing cells in all tissues examined. Due to the slow growth of anthurium plants, development of transgenic anthurium plants takes years. This research has rapidly identified multiple promoters that express in various anthurium tissues facilitating the development of transformation vectors for the expression of desirable traits in anthurium plants.     

Activity of a maize ubiquitin promoter in transgenic rice

We have used the maize ubiquitin 1 promoter, first exon and first intron (UBI) for rice (Oryza sativa L. cv. Taipei 309) transformation experiments and studied its expression in transgenic calli and plants. UBI directed significantly higher levels of transient gene expression than other promoter/intron combinations used for rice transformation. We exploited these high levels of expression to identify stable transformants obtained from callus-derived protoplasts co-transfected with two chimeric genes. The genes consisted of UBI fused to the coding regions of the uidA and bar marker genes (UBI:GUS and UBI:BAR). UBI:GUS expression increased in response to thermal stress in both transfected protoplasts and transgenic rice calli. Histochemical localization of GUS activity revealed that UBI was most active in rapidly dividing cells. This promoter is expressed in many, but not all, rice tissues and undergoes important changes in activity during the development of transgenic rice plants.     

Dehydration-Stress-Regulated Transgene Expression in Stably Transformed Rice Plants

To confer abscisic acid (ABA) and/or stress-inducible gene expression, an ABA-response complex (ABRC1) from the barley (Hordeum vulgare L.) HVA22 gene was fused to four different lengths of the 5′ region from the rice (Oryza sativa L.) Act1 gene. Transient assay of β-glucuronidase (GUS) activity in barley aleurone cells shows that, coupled with ABRC1, the shortest minimal promoter (Act1–100P) gives both the greatest induction and the highest level of absolute activity following ABA treatment. Two plasmids with one or four copies of ABRC1 combined with the same Act1–100P and HVA22(I) of barley HVA22 were constructed and used for stable expression of uidA in transgenic rice plants. Three Southern blot-positive lines with the correct hybridization pattern for each construct were obtained. Northern analysis indicated that uidA expression is induced by ABA, water-deficit, and NaCl treatments. GUS activity assays in the transgenic plants confirmed that the induction of GUS activity varies from 3- to 8-fold with different treatments or in different rice tissues, and that transgenic rice plants harboring four copies of ABRC1 show 50% to 200% higher absolute GUS activity both before and after treatments than those with one copy of ABRC1.     

Rice Triosephosphate Isomerase Gene 5[prime] Sequence Directs [beta]-Glucuronidase Activity in Transgenic Tobacco but Requires an Intron for Expression in Rice

In rice (Oryza sativa L.), cytosolic triosephosphate isomerase (TPI) is encoded by a single gene. TPI catalyzes a vital step in glycolysis, and RNA blots showed that the tpi gene is expressed in all vegetative tissues (root, culm, and leaves) and in rice suspension cells. No effect of light on expression was detected, but submergence of rice seedlings resulted in elevated levels of TPI mRNA in roots and culms. The 2767-bp 5[prime] upstream sequence of the tpi gene was fused translationally with the [beta]-glucuronidase (gusA) gene, and the resulting construct, TPI-GUS, was found to express constitutive, high levels of GUS activity in transgenic tobacco (Nicotiana tabacum) plants. However, the same construct yielded no GUS activity in stably transformed rice plants, and RNA blots showed that no GUS mRNA could be detected even though stable integration of functional copies of the construct was confirmed by Southern blot and genomic polymerase chain reaction analyses. Transient assays using particle bombardment yielded high levels of GUS expression from the TPI-GUS construct in tobacco leaves, but essentially no expression in rice, barley, or maize leaves. When the first intron of the tpi gene was included in the construct (TPI-int1-GUS), transient GUS activity was routinely obtained in rice leaves, revealing that the first intron of the rice tpi gene is crucial for its expression in rice. TPI-int1-GUS also directed transient GUS expression in maize and barley leaves, but little or no activity was obtained from this construct in tobacco, tomato, or soybean leaves. These results with the rice tpi promoter are in accordance with mounting evidence that differences in gene expression exist between monocots and dicots.     

Characterization of the regulatory elements of the maize P-rr gene by transient expression assays

The maize P-rr gene conditions floral-specific flavonoid pigmentation, especially in the kernel pericarp and cob. We analyzed the P-rr promoter by transient expression assays, in which segments of the P-rr promoter were fused to the GUS reporter gene and introduced into maize cells by particle bombardment. A basal P-rr promoter fragment (–235 to +326) gave low, but significant, levels of GUS reporter gene expression. Interestingly, two widely spaced segments containing enhancer-like activity were found. When tested individually, both the proximal (–1252 to –236) and distal (–6110 to –4842) segments boosted expression of the basal P-rr promoter::GUS construct about five-fold. A 1.6 kb segment of the P-rr promoter (–1252 to +326) containing the proximal enhancer and the 5-untranslated leader driving the GUS reporter gene showed preferential expression in BMS and embryogenic suspension cell cultures vs. endosperm-derived suspension cell cultures. These results demonstrate the application of transient assay techniques for the identification of regulatory elements responsible for floral-specific regulation of the complex P-rr gene promoter in maize.     

Physical,chemical and physiological parameters for electroporation-mediated gene delivery into rice protoplasts

Transformation of cereal protoplasts has been reported using several methods; however, the efficiencies of transformations are still very low. We have evaluated a number of parameters that influence electroporation-mediated DNA uptake and have also compared the efficiency of transient GUS activity and stable transformation obtained using an optimized electroporation method with that of the PEG method. The electroporation conditions tested were ionic composition of buffer, ionic strength, resistivity of buffer, type of anions, voltage, and capacitance.Protoplasts isolated from suspension cultures derived from immature embryos of rice (cvs Radon and IR-54) were used for this study. Stable transformation or transient GUS expression experiments were carried out using a plasmid construct containing the CaMV 35S promoter driving thebar gene and a rice actin promoter driving thegus A (uid A) gene (pAG35bar). Electroporation under optimized conditions resulted in about 13-fold higher GUS activities compared to the PEG method. Protoplast survival following optimized electroporation conditions was 55–60%, compared to 35–40% with the PEG treatment. Protoplasts isolated from a suspension culture at different ages gave substantially different levels of transient GUS expression following electroporation-mediated DNA uptake. In contrast, the age of the suspension culture did not influence PEG-mediated DNA uptake and transient GUS activities, which remained low throughout the culture period examined (21 months). Putatively transformed calluses were selected after three to four weeks on medium containing phosphinothricin as the selection agent. The transformation frequencies ranged from 6.2×10^–5 to 5.4×10^–4 with the electroporation method compared to 1.3×10^–5 to 5.3×10^–5 with the PEG method. Southern blot analysis of PPT-resistant calluses obtained by the electroporation-mediated transformation showed simple intergration patterns of integrated DNA in most of the transformants.