Transient expression of the β-glucuronidase gene in tissues ofArabidopsis thaliana by bombardment-mediated transformation

Particle bombardment has proved to be useful for the transformation of plants. We have previously reported successful transient expression of the beta-glucuronidase (GUS) gene in cultured plant cells and tissues and the stable transformation of various plants using a pneumatic particle gun. In this chapter, we describe transient expression of the GUS gene in Arabidopsis thaliana leaves and roots using the pneumatic particle gun.     

In vivo gene gun-mediated DNA delivery into rodent brain tissue

Various types of gene transfer into live tissues have been tried. However, in vivo gene transfer into brain tissue or neuronal cells without virus vector has required a great effort. Particle-mediated gene transfer into live brain tissue was thought to be impossible because of its fragility and the mechanical problem of a previous type of gene gun. In addition, particle-mediated DNA transfer into monolayer-cultured cells without mechanical damage has been difficult. We successfully transferred DNA into rodent live brain tissue and also into monolayer-cultured cells without mechanical damage by using a new type of gene gun and also confirmed gene expression in the brain. This new method represents another variation of gene transfer into the brain.     

Gene targeting in plants using theAgrobacterium vector system

In the past decade several methods have been developed for the introduction of foreign DNA into plant cells to obtain transgenic plants. In some of these methods, purified DNA is directly introduced into protoplasts that for some species can be regenerated into mature plants. The more commonly used protocols, however, employ the natural capacity ofAgrobacterium tumefaciens to transfer a defined peice of DNa, called T-DNA, to the nucleus of plant cells that are more easy to regenerate than protoplasts. In plant cells, like in animal cells, foreign DNA (including T-DNA) is readily inserted into the genome via illegitimates recombination. In contrast, targeted integration via homologous recombination, referred to as ‘gene targeting’, can only be obtained at relatively low frequencies. Nevertheless, gene targeting has become a standard strategy for reverse genetics studies in animals. In plants, the occurrence of gene targeting was only reported recently. This review focuses on the use of theAgrobacterium vector system to achieve gene targeting in plants. Recent experimental data concerning gene targeting in plants are presented and the overall suitability ofAgrobacterium T-DNA transfer for this purpose is assessed in light of contemporary views on the mechanism of T-DNA transfer.     

Tissue culture and the use of transgenic plants to study plant development

Summary Recent advances in plant molecular biology have depended largely on the development of efficient methods of introducing foreign DNA into plant cells. Gene transfer into plant cells can be achieved by either direct uptake of DNA or the natural process of gene transfer carried out by the soil bacteriumAgrobacterium. Although both of these processes allow the generation of stably transformed plants, the former offers the advantage of allowing the study of transient expression of gene constructs in protoplasts cultured in vitro. In addition to the potential application of transgenic plants in agriculture and biotechnology they can be used to study the expression of foreign DNA, to carry out the functional analysis of plant DNA sequences, to investigate the mechanism of viral DNA replication and cell-to-cell spread, as well as to study transposition. Moreover, the versatility of the gene transfer vectors is such that they may be used to isolate genes unamenable to isolation using conventional protocols. Presented in the Formal Symposium Frontiers in Cell Biotechnology at the 41st Annual Meeting of the Tissue Culture Association, Houston, Texas, June 10–13, 1990.     

A plant scaffold attached region detected close to a T-DNA integration site is active in mammalian cells.

Integration of foreign genes into plant genomes by the Agrobacterium T-DNA transfer system has been considered to occur at random. It has been speculated that the chromosomal structure of the integration site might affect the expression pattern of the introduced genes. To gain insight into the molecular structure of T-DNA integration sites and its possible impact on gene expression, we have examined plant DNA sequences in the vicinity of T-DNA borders. Analysis of a transgenic petunia plant containing a chloramphenicol acetyltransferase (CAT) gene regulated by the hemoglobin promoter (PAR) from Parasponia andersonii revealed a scaffold attachment region (SAR) close to one T-DNA end. In addition to having strong binding affinities for both animal and plant nuclear scaffolds this petunia SAR element is as active in mammalian cells as the authentic elements from mammalian sources.     

A transgene and its expression profile are stably transmitted to offspring in transgenic medaka generated by the particle gun method

A particle gun is used in a potential method for introducing foreign genes into fish. In this paper, we report on the stable transmission of a transgene and its expression profile of the F4 generation in the transgenic medaka (Oryzias latipes). We established four transgenic strains, which contained a green fluorescent protein (GFP) gene controlled by a medaka beta-actin promoter, using a particle gun. One more transgenic strain was also generated by microinjection for comparison. In all five strains, the founder was discovered to be mosaic for the transgene. However, from the F1 to F4 generations, transgenes and their expression profiles were stably inherited in the Mendelian manner. The expression profile was common among the five strains regardless of the method for gene transfer: GFP fluorescence became detectable at an early neurula stage. In this stage, the fluorescence was observed ubiquitously in most tissues. As somite developed, GFP fluorescence became intense only in the skeletal muscle and lens but it decreased in other tissues. In adult fish, an intense fluorescence was restricted in the skeletal muscle and lens, while a considerably weak fluorescence was observed in the brain, gill, heart, kidney, spleen, and ovary. From these results, it was concluded that the transgene and its expression profile were stably transmitted to offspring, and thus the particle gun is an effective method for transgenesis in spite of its easiness.     

Multiple Tissue Transformation in Adult Zebrafish by Gene Gun Bombardment and Muscular Injection of Naked DNA

The efficiency of two direct gene transfer methods, gene gun (or particle bombardment) and intramuscular injection, in transforming adult zebrafish tissues in vivo was examined by a noninvasive approach using green fluorescent protein (GFP) reporter gene driven by the ubiquitously expressed human cytomegalovirus promoter. Particle bombardment of adult zebrafish caused internalization and expression of the plasmid only in the superficial layer such as epithelial cells, pigment cells, endothelial cells, and neurons, whereas direct injection primarily transformed muscle fibers of several bundles near or around the injection site. Expression was also evident in several nonmuscle tissues, such as skin epithelia, pigment cells, blood vessel cells, and neuron-like cells. GFP expression persisted for more than 50 days with both methods. These observations indicate the potential of these methods for functional analysis of tissue-specific promoters, delivery of DNA vaccine, and muscular expression of other useful genes. Received June 12, 2000; accepted September 12, 2000     

Viral transgenesis of embryonic cell cultures from the freshwater microcrustacean Daphnia

The aim of this study was to determine whether a recombinant vesicular stomatitis virus (VSV) vector encoding a transgene could be used to infect and express a foreign gene in embryonic primary cell cultures derived from the freshwater microcrustacean Daphnia, the most widely used ecotoxicological model organism. To facilitate the evaluation of gene transfer, a reproducible method for establishing primary cultures from Daphnia embryonic tissues was developed. Within 24 hr after infection, transgene expression could be detected in cell culture. VSV was found to replicate in the cells with no apparent cytopathic effect. Here we report the first evidence of gene transfer and foreign gene expression in cultures of Daphnia embryonic cells using a recombinant viral vector.     

Comparative evaluation of CD8+CTL responses following gene gun immunization targeting the skin with intracutaneous injection of antigen-transduced dendritic cells

The skin is an attractive target for antigen-specific vaccination. Particle bombardment of the epidermis with plasmid DNA using the gene gun results in antigen expression in keratinocytes of the epidermis leading to antigen presentation in the draining lymph nodes by migratory dendritic cells (DC). In order to better understand the role of the skin in stimulating antigen-specific CD8+cytotoxic T cells (CTL), we compared gene gun immunization with intracutaneous injections of antigen-transduced DC. A single intracutaneous injection of antigen-transduced DC was able to induce in vivo expansion of CD8+CTL specific for the model antigen chicken ovalbumin while four simultaneous shots with the gene gun were not effective. Antigen-transduced DC were much more efficient than particle bombardment of the epidermis in stimulating adoptively transferred TCR-transgenic CD8+CTL in the draining lymph nodes. Employing the novel technique of in vivo bioluminescence imaging, we demonstrated efficient gene transfer to the skin following gene gun bombardment and confirmed that a similar amount of antigen reached the lymph node when compared with injection of antigen-transduced DC. Our results suggest that direct transfection of the skin does not optimally reach and activate appropriate antigen-presenting DC. We believe that this reflects the immunological function of the epidermis which must balance immunity and tolerance to foreign antigens. Further investigations will have to address the role of Langerhans cells for the activation of cellular immunity in the skin.     

Localized transient expression of GUS in leaf discs following cocultivation with Agrobacterium

A chimaeric gene has been constructed that expresses -D-glucuronidase (GUS) in transformed plant tissues, but not in bacterial cells. This gene has proved extremely useful for monitoring transformation during the period immediately following gene transfer from Agrobacterium tumefaciens. GUS expression was detectable 2 days after inoculation, peaked at 3–4 days and then declined; if selection was imposed expression increased again after 10–14 days. The extent of transient expression after 4 days correlated well with stable integration as measured by kanamycin resistance, hormone independence, and gall formation. Histochemical staining of inoculated leaf discs confirmed the transient peak of GUS expression 3–4 days after inoculation. The most surprising result was that the blue staining was concentrated in localized zones on the circumference of the disc; within these zones, essentially all the cells appeared to be expressing GUS. We suggest that the frequency of gene transfer from Agrobacterium is extremely high within localized regions of leaf explants, but that the frequency of stable integration is several orders of magnitude lower.     

Optimized, highly efficient transfer of foreign genes into newborn mouse hearts in vivo

Expression of foreign genes in vivo is a standard method to disclose functions of specific genes and to alter physiological conditions in distinct cell types and tissues. Virus-mediated gene transfer has proved to be a valuable tool for directed gene expression in vivo complementary to transgenic approaches. However, several problems associated with routes of application, endurance of gene expression, and efficiency of infections still have to be solved. We have optimized a gene transfer protocol into hearts of newborn mice to achieve widespread long-lasting expression using adenoviral vectors. Intrathoracic injection of high-titer adenoviral preparations (10(8)pfu) led to expression of foreign genes in >71+/-8% of all heart cells for >50 days after infection without any morphological signs of cardiac malfunction, inflammation, or immune response. This approach might be adapted to long-term cellular studies in vivo since 5 months after infection up to 20% of all cardiac cells still expressed virally encoded genes. Successful and efficient expression of other gene of interest can be easily controlled by co-injection of low titers of a reporter vector encoding EGFP (10(6)pfu).     

Permanent genome modifications in plant cells by transient viral vectors

Endonuclease-mediated induction of genomic double-strand breaks has enabled genome editing in living cells. However, deploying this technology for the induction of gene disruption in plant cells often relies on direct gene transfer of endonuclease (i.e. zinc finger nuclease or homing endonuclease) expression constructs into the targeted cell, followed by regeneration of a mutated plant. Such mutants, even when they have no detectable traces of foreign DNA, might still be classified as transgenic because of the transgenic nature of the endonuclease delivery method. Indirect delivery of endonucleases into target cells by viral vectors provides a unique non-transgenic approach to the production of mutated plants. Furthermore, viral vectors can spread into the growing and developing tissues of infected plants, which could provide a unique opportunity to bypass the regeneration step that is often required in direct gene-transfer methods.     

Gene insertion into Hevea brasiliensis

A transformation system has been developed for Hevea brasiliensis using the particle gun method. Anther derived calluses were transformed with vectors harbouring the ß-glucuronidase (gus) gene, the neomycin phosphotransferase (nptII) gene, and the chloramphenicol acetyl transferase (cat) gene. Gene transfer was determined by histochemical staining and fluorometric assay for ß-glucuronidase activity, enzyme linked immunosorbent assay for detecting neomycin phosphotransferase II gene and direct enzyme assay for detection of expression of the cat gene. These independent assays all showed a several-fold increase, compared to control values, in gene product level and enzyme activity in extracts from transformed callus and embryoids of Hevea. These results were confirmed using polymerase chain reaction with primers designed to amplify an internal gus fragment. Together, the results show the feasibility of the particle gun method for the introduction of foreign genes into Hevea.Abbreviations BSA bovine serine albumin - CAT chloramphenicol acetyl transferase - ELISA enzyme-linked immunosorbent assay - GUS ß-glucuronidase - kb kilobase - MU 4-methyl-umbelliferyl-ß-D-glucuronide - NPT-II neomycin phosphotransferase II - PCR polymerase chain reaction - Tris Trizma base - X-gluc 5-bromo-4-chloro-3-indolyl glucuronide     

Microprojectile bombardment mediated genetic transformation of embryo axes and plant regeneration in cumin (<Emphasis Type="Italic">Cuminum cyminum</Emphasis> L.)

Pre-cultured cumin embryos were bombarded under 27 inches Hg vacuum, 25 mm distance from rupture disc to macrocarrier, 10 mm macrocarrier flight distance using 1100 psi rupture disc and 9 cm microprojectile travel distance. An average of 110 embryos was used per shot and 91% embryos showed transient GUS expression after 24 h. Shoot tips and roots of T₀ plantlets exhibited GUS expression done after 3 months of bombardment. Transformation was confirmed with PCR amplification of 0.96 and 1.3 kb band of hptII and gus genes respectively from T₀ transgenics and southern blot analysis using PCR amplified DIG labeled hptII gene as probe. It is the first successful attempt of transformation of cumin plant through direct gene transfer using particle gene gun and adequately exhibiting the possibility of stable transformation in cumin.     

Foreign protein production using plant cell and organ cultures: Advantages and limitations

Plants and plant tissue cultures are used as host systems for expression of foreign proteins including antibodies, vaccines and other therapeutic agents. Recombinant or stably transformed plants and plant cell cultures have been applied for foreign protein production for about 20 years. Because the product concentration achieved exerts a major influence on process economics, considerable efforts have been made by commercial and academic research groups to improve foreign protein expression levels. However, post-synthesis product losses due to protease activity within plant tissues and/or extracellular protein adsorption in plant cell cultures can negate the benefits of molecular or genetic enhancement of protein expression. Transient expression of foreign proteins using plant viral vectors is also a practical approach for producing foreign proteins in plants. Adaptation of this technology is required to allow infection and propagation of engineered viruses in plant tissue cultures for transient protein expression in vitro.     

Electroporated intact BY-2 tobacco culture cells as a model of transient expression study

Transfer of foreign genes into plant cells can be accomplished by several methods: agrobacterium-mediated, microinjection, biolistic particle bombardment and electroporation. The last one is frequently used for transfection of plant protoplasts for transient gene expression. Electroporation is a simple procedure and allows transfecting a large number of cells at one time. Square wave-modulated porators are the most efficient for introducing expression cassettes into plant protoplasts. Based on a protocol developed by Wu & Feng (Plant Cell Reports, 1999, 18, 381-386), we optimized conditions for transfection of intact Nicotiana tabacum BY-2 cells using square wave-modulated electroporator. To simplify screening for transfected gene expression we used constructs with a GFP marker gene.     

In Vivo Transfection of Animals by Intravenous Injection of Cationic Liposome: DNA Complexes

Abstract

Cationic liposome:DNA complex (CLDC)-mediated gene transfer by intravenous injection results in expression of genes of interest in a variety of animal tissues. Large multilamellar vesicles transfect more efficiently than small unilamellar vesicles when complexed to plasmid DNA, and higher ratios of liposome to DNA result in higher transfection levels. Inclusion of the neutral lipid cholesterol enhances gene expression in animals, and our most efficient liposome formulation to date (DOTIM:cholesterol MLV) produced significant levels of gene expression in a sheep for a period of up to 5 months following a single intravenous injection. In addition, the normal vascular cells surrounding melanoma-induced tumors in mice can be transfected by intravenous injection of CLDC, suggesting sanguine prospects for the possibility of anti-cancer gene therapy by CLDC-mediated intravenous gene transfer.     

Stable Expression of a Foreign Gene, Delivered by Gene Gun, in the Muscle of Rainbow Trout Oncorhynchus mykiss

We report the efficient delivery of a foreign gene into muscle of rainbow trout Oncorhynchus mykiss with a gene gun. The foreign gene was a reporter gene, chloramphenicol acetyltransferase (CAT). Two CAT-containing plasmids were used: pCMV-CAT, which contains cytomegalovirus immediate early promoter, and pSV2-CAT, which contains the simian virus 40 early promoter. All plasmids were introduced by particle bombardment using a gene gun. During the 90-day sampling period following bombardment, CAT was strongly and stably expressed in the muscle of all the fish bombarded with pCMV-CAT and pSV2-CAT. No CAT expression was detected in the blood samples until 90 days after introduction, when it was found in only one fish from the pCMV-CAT group and one from the pSV2-CAT group. The stable and long-term expression of plasmid DNA in muscle makes muscle an attractive target tissue for the introduction of viral DNA for the purpose of DNA vaccination. Received June 5, 1999; accepted November 2, 1999.