Virus‐induced gene silencing in Catharanthus roseus by biolistic inoculation of tobacco rattle virus vectors

Catharanthus roseus constitutes the unique source of several valuable monoterpenoid indole alkaloids, including the antineoplastics vinblastine and vincristine. These alkaloids result from a complex biosynthetic pathway encompassing between 30 and 50 enzymatic steps whose characterisation is still underway. The most recent identifications of genes from this pathway relied on a tobacco rattle virus‐based virus‐induced gene silencing (VIGS) approach, involving an Agrobacterium‐mediated inoculation of plasmids encoding the two genomic components of the virus. As an alternative, we developed a biolistic‐mediated approach of inoculation of virus‐encoding plasmids that can be easily performed by a simple bombardment of young C. roseus plants. After optimisation of the transformation conditions, we showed that this approach efficiently silenced the phytoene desaturase gene, leading to strong and reproducible photobleaching of leaves. This biolistic transformation was also used to silence a previously characterised gene from the alkaloid biosynthetic pathway, encoding iridoid oxidase. Plant bombardment caused down‐regulation of the targeted gene (70%), accompanied by a correlated decreased in MIA biosynthesis (45–90%), similar to results obtained via agro‐transformation. Thus, the biolistic‐based VIGS approach developed for C. roseus appears suitable for gene function elucidation and can readily be used instead of the Agrobacterium‐based approach, e.g. when difficulties arise with agro‐inoculations or when Agrobacterium‐free procedures are required to avoid plant defence responses.     

Development of resources for the analysis of gene function in Pucciniomycotina red yeasts

The Pucciniomycotina is an important subphylum of basidiomycete fungi but with limited tools to analyze gene functions. Transformation protocols were established for a Sporobolomyces species (strain IAM 13481), the first Pucciniomycotina species with a completed draft genome sequence, to enable assessment of gene function through phenotypic characterization of mutant strains. Transformation markers were the URA3 and URA5 genes that enable selection and counter-selection based on uracil auxotrophy and resistance to 5-fluoroorotic acid. The wild type copies of these genes were cloned into plasmids that were used for transformation of Sporobolomyces sp. by both biolistic and Agrobacterium-mediated approaches. These resources have been deposited to be available from the Fungal Genetics Stock Center. To show that these techniques could be used to elucidate gene functions, the LEU1 gene was targeted for specific homologous replacement, and also demonstrating that this gene is required for the biosynthesis of leucine in basidiomycete fungi. T-DNA insertional mutants were isolated and further characterized, revealing insertions in genes that encode the homologs of Chs7, Erg3, Kre6, Kex1, Pik1, Sad1, Ssu1 and Tlg1. Phenotypic analysis of these mutants reveals both conserved and divergent functions compared with other fungi. Some of these strains exhibit reduced resistance to detergents, the antifungal agent fluconazole or sodium sulfite, or lower recovery from heat stress. While there are current experimental limitations for Sporobolomyces sp. such as the lack of Mendelian genetics for conventional mating, these findings demonstrate the facile nature of at least one Pucciniomycotina species for genetic manipulation and the potential to develop these organisms into new models for understanding gene function and evolution in the fungi.     

Stable nuclear transformation of the diatom Chaetoceros sp.

A nuclear transformation system for the centric diatom Chaetoceros sp. has been established using two plasmids pTpfcp/nat and pTpNR/green fluorescent protein (GFP) that had been used for Thalassiosira pseudonana transformation. These contain the nourseothricin resistance gene (nat) with the fucoxanthin chlorophyll a/c binding protein (fcp) promoter/terminator from T. pseudonana and the enhanced green fluorescent protein gene (egfp), with the nitrate reductase (NR) promoter/terminator from T. pseudonana, respectively. Transformants were recovered in the presence of the antibiotic nourseothricin. One to four copies of both nat and egfp genes were integrated into genomic DNA of the transformants. Transformation efficiency was 1.5–6.0 transformants per 10⁸ cells. This work is the first report of stable genetic transformation of Chaetoceros, which is important as not only a constituent member of marine ecosystem but also feed for aquaculture.     

Genetic Transformation of Wheat: State of the Art

The review provides the latest achievements in the field of wheat transformation and analysis of the factors affecting transformation efficiency. A comparative analysis of the most commonly used methods of wheat transformation, i.e., direct gene transfer by biolistic transformation and by Agrobacterium tumefaciens in vitro and in planta, is carried out. The stages and components of methods that affect transformation efficiency are examined in detail. Since the first successful biolistic transformation of wheat in 1992 and Agrobacterium- mediated transformation in 1997, 25 to 20 years have passed. Since then, all physical and biological parameters for the heterologous DNA delivery to the wheat genome and regeneration of plant transformants in vitro have been investigated and described in detail. Information on the influence of key parameters and factors on increasing transformation efficiency of highly productive wheat varieties is presented.     

Genetic transformation of <Emphasis Type="Italic">Agave salmiana</Emphasis> by <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis> and particle bombardment

Agave salmiana was transformed using two different protocols: co-cultivation with Agrobacterium tumefaciens and particle bombardment. The uidA (β-glucuronidase) gene was used as a reporter gene for both methods whereas the nptII and bar genes were used as selectable markers for A. tumefaciens and biolistic transformation respectively. Previous reports for in vitro regeneration of A. salmiana have not been published; therefore the conditions for both shoot regeneration and rooting were optimized using leaves and embryogenic calli of Agave salmiana. The transgenes were detected by Polymerase Chain Reaction (PCR) in 11 month old plants. The transgenic nature of the plants was also confirmed using GUS histochemical assays. Transformation via co-cultivation of explants with Agrobacterium harbouring the pBI121 binary vector was the most effective method of transformation, producing 32 transgenic plants and giving a transformation efficiency of 2.7%. On the other hand, the biolistic method produced transgenic calli that tested positive with the GUS assay after 14 months on selective medium while still undergoing regeneration.     

Efficient biolistic transformation of the moss Physcomitrella patens

High rates of homologous recombination (HR) in comparison to other plants make the moss Physcomitrella patens an attractive model organism for genetic studies as well as biotechnological applications. We describe a simple protocol for the efficient biolistic transformation of protonemal tissue with minimum tissue handling steps. The transformation efficiency depends on the biolistic conditions. The bombardment of tissue with 1 μm gold particles yielded between 20 and 40 stable transformants per 1 μg of DNA. Transformation with circular plasmids generates higher frequencies of random transgene integration, whereas linear plasmids are more efficient in generating gene-targeted insertions.     

A Functional Bacterium-to-Plant DNA Transfer Machinery of Rhizobium etli

Different strains and species of the soil phytopathogen Agrobacterium possess the ability to transfer and integrate a segment of DNA (T-DNA) into the genome of their eukaryotic hosts, which is mainly mediated by a set of virulence (vir) genes located on the bacterial Ti-plasmid that also contains the T-DNA. To date, Agrobacterium is considered to be unique in its capacity to mediate genetic transformation of eukaryotes. However, close homologs of the vir genes are encoded by the p42a plasmid of Rhizobium etli; this microorganism is related to Agrobacterium, but known only as a symbiotic bacterium that forms nitrogen-fixing nodules in several species of beans. Here, we show that R. etli can mediate functional DNA transfer and stable genetic transformation of plant cells, when provided with a plasmid containing a T-DNA segment. Thus, R. etli represents another bacterial species, besides Agrobacterium, that encodes a protein machinery for DNA transfer to eukaryotic cells and their subsequent genetic modification.     

Lox-dependent gene expression in transgenic plants obtained via Agrobacterium-mediated transformation

Lox sites of the Cre/lox recombination system from bacteriophage P1 were analyzed for their ability to affect on transgene expression when inserted upstream from a gene coding sequence adjacent to the right border (RB) of T-DNA. Wild and mutated types of lox sites were tested for their effect upon bar gene expression in plants obtained via Agrobacterium-mediated and biolistic transformation methods. Lox-mediated expression of bar gene, recognized by resistance of transgenic plants to PPT, occurred only in plants obtained via Agrobacterium-mediated transformation. RT-PCR analysis confirms that PPT-resistant phenotype of transgenic plants obtained via Agrobacterium-mediated transformation was caused by activation of bar gene. The plasmid with promoterless gus gene together with the lox site adjacent to the RB was constructed and transferred to Nicotiana tabacum as well. Transgenic plants exhibited GUS activity and expression of gus gene was detected in plant leaves. Expression of bar gene from the vectors containing lox site near RB allowed recovery of numerous PPT-resistant transformants of such important crops as Beta vulgaris, Brassica napus, Lactuca sativa and Solanum tuberosum. Our results demonstrate that the lox site sequence adjacent to the RB can be used to control bar gene expression in transgenic plants.     

Cryptococcus neoformans virulence gene discovery through insertional mutagenesis

Insertional mutagenesis was applied to Cryptococcus neoformans to identify genes associated with virulence attributes. Using biolistic transformation, we generated 4,300 nourseothricin (NAT)-resistant strains, of which 590 exhibited stable resistance. We focused on mutants with defects in established virulence factors and identified two with reduced growth at 37 degrees C, four with reduced production of the antioxidant pigment melanin, and two with an increased sensitivity to nitric oxide (NO). The NAT insertion and mutant phenotypes were genetically linked in five of eight mutants, and the DNA flanking the insertions was characterized. For the strains with altered growth at 37 degrees C and altered melanin production, mutations were in previously uncharacterized genes, while the two NO-sensitive strains bore insertions in the flavohemoglobin gene FHB1, whose product counters NO stress. Because of the frequent instability of nourseothricin resistance associated with biolistic transformation, Agrobacterium-mediated transformation was tested. This transkingdom DNA delivery approach produced 100% stable nourseothricin-resistant transformants, and three melanin-defective strains were identified from 576 transformants, of which 2 were linked to NAT in segregation analysis. One of these mutants contained a T-DNA insertion in the promoter of the LAC1 (laccase) gene, which encodes a key enzyme required for melanin production, while the second contained an insertion in the promoter of the CLC1 gene, encoding a voltage-gated chloride channel. Clc1 and its homologs are required for ion homeostasis, and in their absence Cu+ transport into the secretory pathway is compromised, depriving laccase and other Cu(+)-dependent proteins of their essential cofactor. The NAT resistance cassette was optimized for cryptococcal codon usage and GC content and was then used to disrupt a mitogen-activated protein kinase gene, a predicted gene, and two putative chloride channel genes to analyze their contributions to fungal physiology. Our findings demonstrate that both insertional mutagenesis methods can be applied to gene identification, but Agrobacterium-mediated transformation is more efficient and generates exclusively stable insertion mutations.     

A Rapid,Highly Efficient and Economical Method of Agrobacterium-Mediated In planta Transient Transformation in Living Onion Epidermis

Transient transformation is simpler, more efficient and economical in analyzing protein subcellular localization than stable transformation. Fluorescent fusion proteins were often used in transient transformation to follow the in vivo behavior of proteins. Onion epidermis, which has large, living and transparent cells in a monolayer, is suitable to visualize fluorescent fusion proteins. The often used transient transformation methods included particle bombardment, protoplast transfection and Agrobacterium-mediated transformation. Particle bombardment in onion epidermis was successfully established, however, it was expensive, biolistic equipment dependent and with low transformation efficiency. We developed a highly efficient in planta transient transformation method in onion epidermis by using a special agroinfiltration method, which could be fulfilled within 5 days from the pretreatment of onion bulb to the best time-point for analyzing gene expression. The transformation conditions were optimized to achieve 43.87% transformation efficiency in living onion epidermis. The developed method has advantages in cost, time-consuming, equipment dependency and transformation efficiency in contrast with those methods of particle bombardment in onion epidermal cells, protoplast transfection and Agrobacterium-mediated transient transformation in leaf epidermal cells of other plants. It will facilitate the analysis of protein subcellular localization on a large scale.     

Development of genetic transformation methodologies for an industrially-promising microalga: Scenedesmus almeriensis

The development of the microalgal industry requires advances in every aspect of microalgal biotechnology. In this regard, the availability of genetic engineering tools for industrially-promising species is key. As Scenedesmus almeriensis has promise for industrial use, we describe here an Agrobacterium-based methodology that allows stable genetic transformation of it for the first time, thus opening the way to its genetic manipulation. Transformation was accomplished using two different antibiotic resistance genes [hygromicine phophotransferase (hpt) and Shble] and it is credited by PCR amplification of both hpt/Shble and GUS genes and by the β-glucuronidase activity of transformed cells. Nevertheless, the single 35S promoter seems unable to direct gene expression to a convenient level in S. almeriensis as suggested by the low GUS enzymatic activity. Temperature was critical for the transformation efficiency.     

New Genes for Old Trees

In addition to the extensive improvement programmes within fruitorchards and forest stands, considerable momentum is being generatedin the application of genetic manipulation strategies to a varietyof woody species. Several transformation approaches have beenadopted for the production of transgenic trees. These includeAgrobacterium-mediated gene delivery, chemical and/or electricalstimulated uptake of DNA into protoplasts, and the use of thenewer technology of high velocity bombardment of plant tissueswith DNA-coated particles. Transformation offers advantagesover other genetic manipulation techniques, such as somatichybridization, in that it allows the directed improvement oftrees with minimum disruption of the genetic integrity of anelite genome. The information presented here is a comprehensivereview of transformation in woody plants. Many of the advanceshave been made in this area during the last five years. Key words: Woody species, transformation, Agrobacterium, direct gene transfer     

Shorter T-DNA or additional virulence genes improve Agrobactrium-mediated transformation

The effect of additional virulence (vir) genes and size of plasmid T-DNA in Agrobacterium tumefa- ciens was investigated for their impact on transformation efficiency. Transformation efficiency in tobacco, cotton, and rice was increased when the T-DNA was 4.3 kb compared to 8.4 kb in size. However, when additional virG, virGN54D,virE, or virE/virG plasmids were included with the 8.4-kb T-DNA, transformation frequencies in all cases were increased over that of the shorter T-DNA without additional vir plasmids. The use of virE, virG or virGN54D copies enhanced transformation efficiency; however, the most significant increase of transformation efficiency in all three plant species was observed when the virE/virG plasmid was used for infection. The virE/virG plasmid dramatically enhanced the efficiency of Agrobacterium-mediated gene transfer; moreover, this plasmid appears to have broad efficiency since it was consistently effective on two different dicotyledon species as well as a monocotyledon species. Received: 8 February 2000 / Accepted: 21 March 2000     

Biolistic transformation of wheat: increased production of plants with simple insertions and heritable transgene expression

The feasibility of map-based cloning in wheat has been demonstrated recently, opening new perspectives for a better understanding of wheat plant biology and for accelerating wheat improvement in the coming decades. To validate the function of candidate genes, an efficient transformation system is needed. Here, we have performed two methods for wheat transformation using particle bombardment that ensures the production of transgenic plants with simple integration patterns for research purposes and stable transgene expression for accurate and rapid validation of gene function. To establish this method, we used the bar and pmi selectable genes either as part of whole plasmids, gene cassettes (obtained by PCR or purified on agarose gels), or as dephosphorylated cassettes. The analysis of about 300 transgenic plants showed that the use of gene cassettes or dephosphorylated gene cassettes leads to a majority (50–60 %) of simple integration events. This is significantly higher than the number of simple events obtained with whole plasmids (9–25 %). Moreover, the decrease of the quantity of DNA from 500 to 5 ng/µl for PCR-amplified cassettes used for transformation increased the number of single integration events. The transformation efficiency remained stable at 2.5 %, and a higher number of plants expressing the transgenes were obtained with the dephosphorylated cassette. No correlation was observed between the complexity of the events and stability of expression of the transgene, suggesting that plasmid sequences could be involved on transgene silencing. The inheritability of the transgene was demonstrated in T1 and T2 generations. These results show that biolistic transformation of dephosphorylated gene cassettes provides an easy and efficient route to produce backbone vector-free transgenic wheat carrying and expressing intact and single transgenes.     

Rare Homologous Gene Targeting in Histoplasma capsulatum: Disruption of the URA5Hc Gene by Allelic Replacement

URA5 genes encode orotidine-5′-monophosphate pyrophosphorylase (OMPpase), an enzyme involved in pyrimidine biosynthesis. We cloned the Histoplasma capsulatum URA5 gene (URA5_Hc) by using a probe generated by PCR with inosine-rich primers based on relatively conserved sequences in OMPpases from other organisms. Transformation with this gene restored uracil prototrophy and OMPpase activity to UV-mutagenized ura5 strains of H. capsulatum. We attempted to target the genomic URA5 locus in this haploid organism to demonstrate homologous allelic replacement with transforming DNA, which has not been previously done in H. capsulatum and has been challenging in some other pathogenic fungi. Several strategies commonly used in Saccharomyces cerevisiae and other eukaryotes were unsuccessful, due to the frequent occurrence of ectopic integration, linear plasmid formation, and spontaneous resistance to 5-fluoroorotic acid, which is a selective agent for URA5 gene inactivation. Recent development of an efficient electrotransformation system and of a second selectable marker (hph, conferring hygromycin B resistance) for this fungus enabled us to achieve allelic replacement by using transformation with an insertionally inactivated Δura5_Hc::hph plasmid, followed by dual selection with hygromycin B and 5-fluoroorotic acid, or by screening hygromycin B-resistant transformants for uracil auxotrophy. The relative frequency of homologous gene targeting was approximately one allelic replacement event per thousand transformants. This work demonstrates the feasibility but also the potential challenge of gene disruption in this organism. To our knowledge, it represents the first example of experimentally directed allelic replacement in H. capsulatum, or in any dimorphic systemic fungal pathogen of humans.     

Transformation of Zea mays L. Using Agrobacterium tumefaciens and the Shoot Apex

Agrobacterium tumefaciens is established as a vector for gene transfer in many dicotyledonous plants but is not accepted as a vector in monocotyledonous plants, especially in the important Gramineae. The use of Agrobacterium to transfer genes into monocot species could simplify the transformation and improvement of important crop plants. In this report we describe the use of Agrobacterium to transfer a gene into corn, the regeneration of plants, and detection of the transferred genes in the F₁ progeny. Shoot apices of Zea mays L. variety Funk's G90 were cocultivated with A. tumefaciens EHA 1, which harbored the plasmid pGUS3 containing genes for kanamycin resistance (NPT II) and β-glucuronidase (GUS). Plants developed from these explants within 4 to 6 weeks. Fluorometric GUS assays of leaves and immature seeds from the plants exhibited low GUS activity. Both NOS and GUS gene fragments were amplified by polymerase chain reaction in the DNA isolated from the F₁ generations of one of the original transformed plants. Southern analysis showed both GUS and NPT probes hybridized to DNA in several of the F₁ progeny, demonstrating the incorporation of GUS and NPT II genes into high molecular weight DNA. These data establish successful gene transfer and sexual inheritance of the genes.