Green fluorescent protein as a visual selection marker for papaya (<Emphasis Type="Italic">Carica papaya</Emphasis> L.) transformation

Chemical-based selection for plant transformation is associated with a number of real and perceived problems that might be avoided through visual selection. We have used green fluorescent protein (GFP), as a visual selectable marker to produce transformed papaya (Carica papaya) plants following microprojectile bombardment of embryogenic callus. GFP selection reduced the selection time from 3 months on a geneticin (G418) antibiotic-containing medium to 3–4 weeks. Moreover, GFP selection increased the number of transformed papaya plants by five-to eightfold compared to selection in the presence of antibiotics. Overall, the use of GFP for selecting transgenic papaya lines improved our throughput for transformation by 15- to 24-fold while avoiding the drawbacks associated with the use of antibiotic resistance-based selection markers.Abbreviations BA: Benzyladenine - 2, 4-D: 2,4-Dichlorophenoxyacetic acid - GFP: Green fluorescent protein - IBA: Indole-3-butyric acid - NAA: -Naphthaleneacetic acid - MS: Murashige and Skoog plant culture mediumCommunicated by R.J. Rose     

Agrobacterium-mediated transformation of the endophytic fungus Acremonium implicatum associated with Brachiaria grasses

Acremonium implicatum is a seed-transmitted endophytic fungus that forms symbiotic associations with the economically significant tropical forage grasses, Brachiaria species. To take advantage of the endophyte's plant protective properties, we developed an efficient Agrobacterium-mediated transformation system for Acremonium implicatum, using green fluorescent protein (GFP) expression and vector pSK1019 (trpC promoter) or pCAMBIA1300 (CaMV35S promoter). We found that transformation efficiency doubled for both mycelial and conidial transformation as the co-cultivation period for Agrobacterium tumefaciens and Acremonium implicatum was increased from 48 to 72 h. Significantly, optimal results were obtained for either mycelial or conidial transformation with Agrobacterium tumefaciens strain AGL-1 and vector pSK1019 under the control of the trpC promoter. However, mycelial transformation consistently generated a significantly higher number of transformants than did conidial transformation. The mitotic stability of the transferred DNA was confirmed by growing ten transformants in liquid and agar media for six generations. In all cases, resistance to the selection pressure (hygromycin B) was maintained. Fluorescence emission was retained by the transformants and also expressed in Brachiaria tissues from plants inoculated with GFP-transformed A. implicatum. This technology will help in the transfer and expression of agronomically important genes in host plants.     

Green fluorescent protein as a visual marker for wheat transformation

 Wheat (Triticum aestivum L.) transformation via particle bombardment is now established in many laboratories, but transformation efficiencies are still largely low and the highest efficiencies can only be obtained with certain genotypes. For rapid optimization and improvement of wheat transformation protocols, a non-destructive marker which permits early detection of transformed cells is needed. We have assessed the ability of a modified version of the Aequorea victoria green fluorescent protein (GFP) to act as a marker for detecting transformed cells and tissues of wheat. Multicellular clusters emitting green fluorescence were observed 14 days after particle bombardment with a sGFPS65T gene construct, and gfp-expressing shoots (often with expressing roots) could be observed as early as 21 days after bombardment. These shoots can be removed from the callus and grown further until they are ready to transfer to soil. Transgenic wheat plants could be selected on the basis of gfp expression alone although the inclusion of antibiotic resistance as a selectable marker could improve the efficiency. Using sgfpS65T as a marker gene in an experiment comparing bombardment parameters allowed the rapid identification of variables that could be targeted for optimization. Received: 29 March 2000 / Accepted: 29 March 2000     

The green fluorescent protein (GFP) as a vital screenable marker in rice transformation

 An engineered green fluorescent protein (GFP) from the jellyfish Aequora victoria was used to develop a facile and rapid rice transformation system using particle bombardment of immature embryos. The mgfp4 gene under the control of the 35s Cauliflower Mosaic Virus promoter produced bright-green fluorescence easily detectable and screenable in rice tissue 12–22 days after bombardment. Visual screening of transformed rice tissue, associated with a low level of antibiotic selection, drastically reduced the quantity of tissue to be handled and the time required for the recovery of transformed plants. GFP expression was observed in primary transformed rice plants (T₀) and their progeny (T₁). We describe various techniques to observe GFP in vitro and in vivo. The advantages of this new screenable marker in rice genetic engineering programmes are discussed. Received: 6 October 1997 / Accepted: 9 October 1997     

Transient expression and stable transformation of soybean using the jellyfish green fluorescent protein

 Embryogenic soybean [Glycine max (L.) Merrill.] suspension cultures were bombarded with five different gene constructions encoding the jellyfish (Aequorea victoria) green fluorescent protein (GFP). These constructions had altered codon usage compared to the native GFP gene and mutations that increased the solubility of the protein and/or altered the native chromophore. All of the constructions produced green fluorescence in soybean cultures upon blue light excitation, although a soluble modified red-shifted GFP (smRS-GFP) was the easiest to detect based on the brightness and number of foci produced. Expression of smRS-GFP was visible as early as 1.5 h after bombardment, with peak expression at approximately 6.5 h. Large numbers of smRS-GFP-expressing areas were visible for 48 h postbombardment and declined rapidly thereafter. Stably transformed cultures and plants exhibited variation in the intensity and location of GFP expression. PCR and Southern hybridization analyses confirmed the presence of introduced GFP genes in stably transformed cultures. Received: 23 September 1998 / Revision received: 4 January 1999 / Accepted: 15 January 1999     

Green fluorescent protein as a visual marker in a p-nitrophenol degrading Moraxella sp.

The green fluorescent protein gene (gfp) was introduced into a p-nitrophenol-metabolizing strain of Moraxella sp. by chromosomal integration. The gfp-marked transformants, designated Moraxella sp. strains G21 and G25, exhibited green fluorescence under UV light. Molecular characterization by PCR and Southern hybridization showed the presence of gfp in both transformants. Both transformants and the parent strain degraded 720 μM of p-nitrophenol with nitrite release within 4 h after inoculation in minimal medium supplemented with yeast extract. Transformants degraded up to 1440 μM p-nitrophenol and mineralized about 60% of 720 μM p-nitrophenol, both in broth and in soil, to the same extent as the parent strain. Insertion of gfp did not adversely affect the expression of p-nitrophenol-degrading genes in the transformants. Survival studies indicated that individual green fluorescent colonies of transformants can be detected up to 2 weeks after inoculation in soil. These marked strains could be of value in studies on microbial survival in the environment.     

Isolation of soybean plants with stable transgene expression by visual selection based on green fluorescent protein

Particle bombardment is a common platform for soybean transformation but tends to cause transgene silencing due to the integration of rearranged or multiple copies of transgenes. We now describe the isolation of a total of 44 independent transgenic soybean plants after transformation by particle bombardment with one of two gene constructs, pHV and pHVS. Both constructs contain the hygromycin phosphotransferase gene (hpt) as a selectable marker and a modified glycinin gene (V3-1) for evaluation of homology-dependent silencing of endogenous glycinin genes; pHVS also contains sGFP(S65T), which encodes a modified form of green fluorescent protein (GFP), as a reporter gene in the flanking region of V3-1. Fluorescence microscopy revealed that the leaves of 8 of the 25 independent transgenic plants obtained with pHVS expressed GFP; most of these GFP-positive plants also contained V3-1 mRNA and an increased glycinin content in their seeds, and they exhibited simple banding patterns on Southern blots that were indicative of a low copy number of each of the three transgenes. In contrast, most of the transgenic plants obtained with pHVS that did not express GFP, as well as most of those obtained with pHV, lacked endogenous glycinin in their seeds and exhibited more complex patterns of transgene integration. The use of a reporter gene such as sGFP(S65T) in addition to an antibiotic resistance gene may thus help to reduce the problem of gene silencing associated with direct DNA transformation systems and facilitate the recovery of transgenic plants that stably express the gene of interest.     

Regeneration from intact and sectioned immature embryos of barley (Hordeum vulgare L.): the scutellum exhibits an apico-basal gradient of embryogenic capacity

Immature zygotic embryos from spring barley cv. Dissa were used to induce somatic embryogenenesis. Up to 158 germinated somatic embryos could be recovered per plated zygotic embryo. Critical factors for obtaining a high yield of regenerants were the size of the explant, the level of 2,4-D used for callus induction and the careful division of callus at each subculture. Use of microsections of immature embryos as explants revealed a pronounced gradient of callus formation and embryogenic response across the scutellum. Sections from the scutellar tissue at the coleoptilar end of the embryo gave the most callus and were highly embryogenic. The regeneration response of sectioned explants was comparable to that recovered from intact embryos of similar size.     

Stable transformation of sunflower (Helianthus annuus L.) using a non-meristematic regeneration protocol and green fluorescent protein as a vital marker

Stable transformation of sunflower was achieved using a non-meristematic hypocotyl explant regeneration protocol of public inbred HA300B. Uniformly transformed shoots were obtained after co-cultivation with Agrobacterium tumefaciens carrying a gfp (green fluorescent protein) gene containing an intron that blocks expression of gfp in Agrobacterium. Easily detectable, bright green fluorescence of transformed tissues was used to establish an optimal regeneration and transformation procedure. By Southern blot analysis, integration of the gfp and nptII genes was confirmed. Stable transformation efficiency was 0.1%. From 68 T₁ plants analyzed, 17 showed transmission of transgene DNA and 15 of them contained the intact gfp gene. Expression of gfp was detected in 10 T₁ plants carrying the intact gfp gene using a fluorimetric assay or western blot analysis. Expression of the nptII gene was confirmed in 13 T₁ plants. The transformation system enables the rapid transfer of agronomically important genes.     

Jellyfish green fluorescent protein as a useful reporter for transient expression and stable transformation in<Emphasis Type="Italic"> Medicago sativa</Emphasis> L.

The aim of the experiments reported herein was to transiently test different gene constructs using green fluorescent protein (GFP) as a reporter gene for a future localization of the maize -zein in the chloroplast of alfalfa (Medicago sativa L.). The transient expression of two GFP genes was compared in alfalfa leaves to determine which of these two mutants is the easier to detect. Based on the intensity of fluorescence emitted, the GFP S65C gene was used to assemble a chloroplast-targeted GFP to verify the efficiency of the transit peptide for chloroplast targeting. A chloroplast-targeted fusion protein between -zein and GFP was then assembled, and this protein was observed to accumulate in small aggregates into the chloroplasts of transiently transformed cells. To the best of our knowledge, this is the first report of the GFP S65C gene being used to obtain transformed alfalfa plants expressing GFP.Communicated by D. Dudits     

Green fluorescent protein as a visual marker in somatic hybridization

Using a transgenic citrus plant expressing Green Fluorescent Protein (GFP) as a parent in somatic fusion experiments, we investigated the suitability of GFP as an in vivo marker to follow the processes of protoplast fusion, regeneration and selection of hybrid plants. A high level of GFP expression was detected in transgenic citrus protoplasts, hybrid callus, embryos and plants. It is demonstrated that GFP can be used for the continuous monitoring of the fusion process, localization of hybrid colonies and callus, and selection of somatic hybrid embryos and plants.     

An improved method for Beauveria bassiana transformation using phosphinothricin acetlytransferase and green fluorescent protein fusion gene as a selectable and visible marker

An improved transformation method for the biocontrol agent, Beauveria bassiana, was developed. For convenience of transformation selection and detection, the coding regions of the genes for phosphinothricin acetyltransferase and green fluorescent protein were fused and an expression vector, pBFT, carrying this fusion was constructed. Under optimum conditions, over 60 transformants microg(-1) plasmid DNA were obtained. B. bassiana conidia frozen 1 month at -80 degrees C were fully competent for transformation. The method was significantly less laborious and more rapid than current methods for B. bassiana. The bar::egfp provides a selectable and visible marker which may expedite future genetic engineering of this fungus.     

Green fluorescent protein as a vital marker for non-destructive detection of transformation events in transgenic plants

Transformation of plants is a popular tool for modifying various desirable traits. Marker genes, like those encoding for bacterial β-glucuronidase (GUS), firefly luciferase (LUC) or jellyfish green fluorescent protein (GFP) have been shown to be very useful for establishing of efficient transformation protocols. Due to favourable properties such as no need of exogenous substrates and easy visualization, GFP has been found to be superior in to other markers in many cases. However, the use of GFP fluorescence is associated with some obstacles, mostly related to the diminishing of green fluorescence in older tissues, variation in fluorescence levels among different tissues and organs, and occasional interference with other fluorescing compounds in plants. This paper briefly summarizes basic GFP properties and applications, and describes in more detail the contribution of GFP to the establishment, evaluation and improvement of transformation procedures for plants. Moreover, features and possible obstacles associated with monitoring GFP fluorescence are discussed.     

Androgen receptor transactivation assay using green fluorescent protein as a reporter

For screening of a large number of samples for androgenic activity, a robust system with minimal handling is required. The coding sequence for human androgen receptor (AR) was inserted into expression plasmid YEpBUbi-FLAG1, resulting in the plasmid YEpBUbiFLAG-AR, and the estrogen response element (ERE) on the reporter vector YRpE2 was replaced by an androgen response element (ARE), resulting in the plasmid YRpE2-ARE. Thus, a fully functional transactivation assay system with beta-galactosidase as a reporter gene could be created. Furthermore, green fluorescent protein (GFP) was introduced as an alternative reporter gene that resulted in a simplification of the whole assay procedure. For evaluation of both reporter systems, seven steroidal compounds with known AR agonistic properties (5 alpha-dihydrotestosterone, testosterone, androstenedione, 17 alpha-methyltestosterone, progesterone, epitestosterone, and d-norgestrel) were tested, and their potencies obtained in the different assays were compared. Furthermore, potencies from the transactivation assays were compared with IC(50) values obtained in radioligand binding assays. The newly developed androgen receptor transactivation assay is a useful tool for characterizing compounds with androgenic activity.     

Green fluorescent protein (GFP) as a new vital marker in the phytopathogenic fungusUstilago maydis

Pathogenic development ofUstilago maydis, the causative agent of corn smut disease, is a multistep process. Compatible yeast-like cells fuse and this generates the infectious dikaryon which grows filamentously. Having entered the plant the dikaryon induces tumors in its host in which massive proliferation of fungal material, karyogamy and spore formation occur. In order to follow fungal development from the initial steps to the final stage we have expressed the green fluorescent protein (GFP) fromAequorea victoria as a vital marker inU. maydis and demonstrate that GFP-tagged strains can be used to study host-pathogen interactions in vivo.     

Green fluorescent protein as a screenable marker to increase the efficiency of generating transgenic woody fruit plants

 The green fluorescent protein (GFP) from Aequorea victoria has been introduced into three different citrus genotypes [Citrus aurantium L., C. aurantifolia (Christm.) Swing. and C. sinensis L. Osbeck×Poncirus trifoliata (L.) Raf.] which are considered recalcitrant to transformation, mainly due to low transformation frequencies and to the regeneration of escape shoots at high frequencies from the Agrobacterium-inoculated explants. High-level GFP expression was detected in transgenic cells, tissues and plants. Using GFP as a vital marker has allowed us to localize the sites of transgene expression in specific cells, always occurring in callus tissue formed from the cambium of the cut ends of explants. Whereas green fluorescent shoots regenerated in all cases from this callus, most escapes regenerated directly from explants with almost no callus formation. Thus, development of callus from cambium is a prerequisite for citrus transformation. Furthermore, in vivo monitoring of GFP expression permitted a rapid and easy discrimination of transgenic and escape shoots. The selection of transgenic shoots could be easily favored by eliminating the escapes and/or by performing shoot-tip grafting of the transgenic buds soon after their origin. GFP-expressing shoots have also been observed in citrus explants co-cultivated with Agrobacterium but cultured in a medium without the selective agent kanamycin. This opens the possibility to rescue the transgenic sectors and to regenerate transgenic plants without using selectable marker genes conferring antibiotic or herbicide resistance, which is currently a topic of much discussion for the commercialization of transgenic plants. Received: 28 October 1998 / Accepted: 28 November 1998     

一种由粉红粘帚霉引起的青稞根腐病

[背景]根腐病在青稞生产中的危害日趋严重,阻碍了青稞根腐病的有效防控及青海省青稞产业的发展。然而人们对青稞根腐病的研究甚少且病原菌不详。[目的]明确青稞根腐病发生的危害、病原及致病性,为青稞根腐病的防控提供理论依据。[方法]采用常规的组织分离法分离青稞根腐病病原,通过形态鉴定与分子鉴定结合的方法对病原进行鉴定,并采用烧杯水琼脂法测定其致病性。[结果]共分离得到4株青稞根腐病病原菌,鉴定为Clonostachys rosea,有较强的致病性且致病性差异显著,经柯赫氏法则验证为青稞根腐病病原菌,并且是一种新的青稞根腐病病原,该类根腐病也是一种新的根腐类病害,在国内外属首次发现。[结论]Clonostachys rosea可引起青稞根腐病且致病性强。     

Construction of a Sinorhizobium meliloti strain carrying a stable and non-transmissible chromosomal single copy of the green fluorescent protein GFP-P64L/S65T

A single copy of the green fluorescent protein (GFP)-encoding gene gfp-P64L/S65T under the control of the constitutive nptII promoter was introduced in a neutral region of the Sinorhizobium meliloti chromosome, between the genes recA and alaS. Within the same chromosomal region downstream of gfp-P64L/S65T a tetracycline (Tc) resistant cassette was also inserted. Both markers were very stable during at least 40 bacterial generations without any selective pressure. Similarly, the gfp-Tc cassette was stable and functional in all rhizobia that were recovered from alfalfa nodules. The GFP-associated fluorescence derived from the (single copy) chromosomal gfp-P64L/S65T allowed detection of rhizobia during the colonisation of the root, infection thread formation, and nodule development. The gfp-Tc rhizobia showed indistinguishable phenotypes for nodulation, competitiveness, and nitrogen-fixation from the parental strain. The labelling system described here can be used for the stable fluorescent tagging of S. meliloti strains allowing their detection in biologically complex soil environments.