Biolistic Transformation of Cryptococcus neoformans

Biolistic transformation of Cryptococcus neoformans is used as a molecular tool to genetically alter or delete targeted genes. The DNA is introduced into the yeast on DNA-coated gold beads by a helium shock wave produced using a biolistic particle system. The procedure often involves insertion of a dominant selectable marker into the desired site by homologous recombination. To increase the likelihood of homologous recombination, large fragments of overlapping DNA are used. The two most used dominant selectable markers are nourseothricin and Geneticin. With the need to generate multiple gene deletions in the same strain, there are recyclable marker systems, such as the bacteriophage P1 Cre-loxP system or CRISPR that provide additional useful molecular tools. While newer strategies exist to generate deletions and introduce markers and other gene modifications, biolistic transformation has remained a viable tool to facilitate the construction of genetically modified yeast strains. This chapter provides a working protocol on how to delete and restore a gene in C. neoformans.

Targeted Gene Editing of Nuclear-Encoded Plastid Proteins in Phaeodactylum tricornutum via CRISPR/Cas9

Genome modifications in microalgae have emerged as a crucial and indispensable tool for research in fundamental and applied biology. In particular, CRISPR/Cas9 has gained significant recognition as a highly effective method for genome engineering in these photosynthetic organisms, enabling the targeted induction of mutations in specific regions of the genome. Here, we present a comprehensive protocol for generating knock-out mutants in the model diatom Phaeodactylum tricornutum using CRISPR/Cas9 by both biolistic transformation and bacterial conjugation. Our protocol outlines the step-by-step procedures and experimental conditions required to achieve successful genome editing, including the design and construction of guide RNAs, the delivery of CRISPR/Cas9 components into the algae cells, and the selection of the generated knockout mutants. Through the implementation of this protocol, researchers can harness the potential of CRISPR/Cas9 in P. tricornutum to advance the understanding of diatom biology and explore their potential applications in various fields.

A DNA-binding protein capture technology that purifies proteins by directly isolating the target DNA

DNA-protein interactions are critical to almost all cellular functions, and identification of the proteins that bind to an DNA site of interest (gene-centered approach) is an important investigation area. However, gene-centered methods are mainly based on DNA hybridization to isolate target proteins, which is complex and inefficient. Here, we built a gene-centered approach involving direct isolation of target DNA, termed protein capture based on biolistic transformation (PCaB). The target DNA was labeled with biotin and cyanine 3 (Cy3) at its 5' and 3' DNA ends, respectively, and introduced into the host plants through biolistic transformation. The DNA and its binding proteins were crosslinked using formaldehyde. The labeled DNAs were obtained using gel excision and biotin-Streptavidin affinity according to the indication of Cy3 fluorescence, which make harvest of target DNA with a low background. The DNA-binding proteins were identified using mass spectrometry analysis. The PCaB method allowed us to identify and confirm 16 putative upstream regulators of the BpERF3 gene from Betula platyphylla. Theoretically, PCaB could be adapted to all plant species that can be transformed using biolistic bombardment, and captures DNA-binding proteins quickly with a low background. Therefore, PCaB will provide a powerful tool to discover DNA-protein interactions.

Inoculation of Maize with Sugarcane Mosaic Virus Constructs and Application for RNA Interference in Fall Armyworms

Virus-mediated transient gene overexpression and gene expression silencing can be used to screen gene functions in plants. Sugarcane mosaic virus (SCMV) is a positive strand RNA virus in the Potyviridae family that has been modified to be used as vector to infect monocots, including maize (Zea mays), for transient gene overexpression and gene expression silencing. Relative to stable transformation, SCMV-mediated transient expression in maize has the advantages of being faster and less expensive. Here, we describe a protocol for cloning constructs into the plasmid vector pSCMV-CS3. After maize seedlings are transformed with pSCMV-CS3 constructs by particle bombardment, the virus replicates and spreads systemically in the plants. Subsequent infections of maize seedlings can be accomplished by rub inoculation with sap from SCMV-infested plants. As an example of a practical application of the method, we also describe virus-induced gene silencing (VIGS) of fall armyworm (Spodoptera frugiperda) gene expression. Transgenic viruses are created by cloning a segment of the fall armyworm target gene into pSCMV-CS3 prior to maize transformation. Caterpillars are fed on the virus-infected maize plants, which make dsRNA to silence the expression of the fall armyworm target gene after ingestion. This use of SCMV for plant-mediated VIGS in insects allows rapid screening of gene functions when caterpillars are feeding on their host plants. Graphical overview.

Development of an in vitro regeneration system from immature inflorescences and CRISPR/Cas9-mediated gene editing in sudangrass

BACKGROUND

Sudangrass (Sorghum sudanense) is a major biomass producer for livestock feed and biofuel in many countries. It has a wide range of adaptations for growing on marginal lands under biotic and abiotic stresses. The immature inflorescence is an explant with high embryogenic competence and is frequently used to regenerate different sorghum cultivars. Caffeic acid O-methyl transferase (COMT) is a key enzyme in the lignin biosynthesis pathway, which limits ruminant digestion of forage cell walls and is a crucial barrier in the conversion of plant biomass to bioethanol. Genome editing by CRISPR/Cas9-mediated mutagenesis without a transgenic footprint will accelerate the improvement and facilitate regulatory approval and commercialization of biotech crops.

METHODS AND RESULTS

We report the overcome of the recalcitrance in sudangrass transformation and regeneration in order to use genome editing technique. Hence, an efficient regeneration system has been established to induce somatic embryogenesis from the immature inflorescence of two sudangrass cultivars on four MS-based media supplemented with different components. Our results indicate an interaction between genotype and medium composition. The combination of Giza-1 cultivar and M4 medium produces the maximum frequency of embryogenic calli of 80% and subsequent regeneration efficiency of 22.6%. Precise mutagenesis of the COMT gene is executed using the CRISPR/Cas9 system with the potential to reduce lignin content and enhance forage and biomass quality in sudangrass.

CONCLUSION

A reliable regeneration and transformation system has been established for sudangrass using immature inflorescence, and the CRISPR/Cas9 system has demonstrated a promising technology for genome editing. The outcomes of this research will pave the road for further improvement of various sorghum genotypes to meet the global demand for food, feed, and biofuels, achieving sustainable development goals (SDGs).

A simple technology for plastid transformation with fragmented DNA

Plastid engineering has several unique advantages such as high expression of transgenes due to high polyploidy of plastid genomes and environmental biosafety because of maternal inheritance of transgenes, and has become a promising tool for molecular farming, metabolic engineering, and genetic improvement. However, there are no standard vectors available for plastid transformation. Moreover, the construction of plastid transformation vectors containing long operons or genes encoding proteins that are toxic to Escherichia coli was tedious or difficult. Here, we developed a simple plastid transformation technology without the need for in vitro vector construction by using multiple linear DNA fragments which share homologous sequences (HSs) at their ends. The strategy is based on homologous recombination between HSs of DNA fragments via endogenous recombination machinery in plastids, which subsequently are integrated into the plastid genome. We found that HSs of 200 bp or longer were sufficient for mediating the integration into the plastid genome with at least similar efficiency to that of plasmid DNA-based plastid transformation. Furthermore, we successfully used this method to introduce a phage lysin-encoding gene and a long operon into a tobacco plastid genome. The establishment of this technology simplifies the plastid transformation procedure and provides a novel solution for expressing proteins, which are either toxic to the cloning host or large operons in plastids, without need of vector cloning.

Gene Gun-Mediated Transient Gene Expression for Functional Studies in Plant Immunity

One major threat to plant cultivation are fungal pathogens, which can cause substantial yield losses in agriculture. As an example, cereal powdery mildew fungi such as the barley (Hordeum vulgare) pathogen, Blumeria graminis f. sp. hordei (Bgh), are among the ten most relevant fungal plant pathogens in molecular plant pathology and can lead to yield losses of up to 30%. Plant Mildew resistance Locus O (MLO) genes are required for successful colonization of plants by powdery mildew fungi. Accordingly, loss-of-function mlo mutants confer durable resistance against powdery mildew fungi in many plant species. In the case of barley, mlo-based resistance has been used for more than 40 years in agriculture without powdery mildew fungi effectively overcoming this kind of immunity. However, the molecular basis of mlo resistance and function(s) of the transmembrane Mlo protein(s) are still incompletely understood. The generation of transgenic barley plants to study the plant immune response and the involvement of Mlo therein is time-consuming and challenging. Therefore, transient gene expression via gene gun-mediated particle bombardment became a popular, easy, and efficient tool to investigate different aspects of plant defense responses in barley. Since Bgh fails to penetrate leaf epidermal cells of mlo mutants, single-cell complementation upon biolistic transformation resulting in (over-)expression of Mlo can be used to characterize the Mlo protein functionally in vivo. In this chapter, we describe in detail the gene gun-mediated transient expression of Mlo in barley leaf epidermal cells followed by powdery mildew inoculation and the subsequent microscopic evaluation. However, gene gun-mediated transient gene expression may be also used to address other research questions or to transform the epidermal tissues of other plant organs and/or species.

Plastid Transformation in Tomato: A Vegetable Crop and Model Species

Tomato (Solanum lycopersicum L.), a member of the nightshade family (Solanaceae), is one of the most important vegetable crops and has long been an important model species in plant biology. Plastid biology in tomato is especially interesting due to the chloroplast-to-chromoplast conversion occurring during fruit ripening. Moreover, as tomato represents a major food crop with a fleshy fruit that can be eaten raw, the development of a plastid transformation protocol for tomato was of particular interest to plant biotechnologists. Recent methodological improvements have made tomato plastid transformation more efficient, and facilitated applications in metabolic engineering and molecular farming. This chapter describes the basic methods involved in the generation and analysis of tomato plants with transgenic chloroplast genomes and summarizes recent applications of tomato plastid transformation in plant biotechnology.

Resistance Marker- and Gene Gun-Mediated Transformation of Trichoderma reesei

Transformation enables the transfer of DNA into fungal cells for subsequent integration into the genome. Due to its versatility in industrial application, transformation is of utmost importance in Trichoderma reesei and hence continuously optimized. As one of the most crucial obstacles in fungal transformation efforts, removal of the cell wall is required to efficiently target genome modification cassettes to the genome. Here we describe resistance marker-mediated gene gun (biolistic) transformation of fungal spores of T. reesei as an alternative to protoplast transformation.

Plastid Transformation in Poplar: A Model for Perennial Trees

Poplar (Populus) is an important forest tree and considered model for perennial trees. Here we describe a method for poplar plastid transformation, which involves preparation of explants, vector construction, biolistic bombardment, regeneration and selection of transplastomic poplar plants. The young leaves of 4-week-old poplar plants are used for biolistic bombardment and aadA gene as selectable marker. Homoplasmic transplastomic lines are obtained after regeneration and several rounds of selection with spectinomycin over 10 months. Homoplasmy is further confirmed by Southern blot. The establishment of a plastid transformation system for Populus is likely to make a significant contribution to tree genetic improvement.

Expression of Escherichia coli Heat-Labile Enterotoxin B Subunit in Centella (Centella asiatica (L.) Urban) via Biolistic Transformation

BACKGROUND

Heat-Labile enterotoxin B subunit (LTB) produced by Escherichia coli, a non-toxic protein subunit with potential biological properties, is a powerful mucosal and parenteral adjuvant which can induce a strong immune response against co-administered antigens.

OBJECTIVE

In the present study, LTB protein, encoded by the optimized ltb (also known synthetic ltb, s-ltb) gene in centella plant (Centella asiatica) for use as an antigen, has been discussed.

METHODS

The s-ltb gene was cloned into a plant expression vector, pMYO51, adjacent to the CaMV 35S promoter and was then introduced into centella plant by biolistic transformation. PCR amplification was conducted to determine the presence of s-ltb gene in the transgenic centella plant. The expression of s-ltb gene was analyzed by immunoblotting and quantified by ELISA. In vitro activity of LTB protein was determined by GM1-ELISA.

RESULTS

PCR amplification has found seven transgenic centella individuals. However, only five of them produced LTB protein. ELISA analysis showed that the highest amount of LTB protein detected in transgenic centella leaves was about 0.8% of the total soluble protein. GM1-ELISA assay indicated that plant LTB protein bound specifically to GM1-ganglioside, suggesting that the LTB subunits formed active pentamers.

CONCLUSION

The s-ltb gene that was successfully transformed into centella plants by the biolistic method has produced a relatively high amount of plant LTB protein in the pentameric quaternary structure that has GM1-ganglioside binding affinity, a receptor on the intestinal epithelial membrane.

Biolistic DNA Delivery and Its Applications in Sorghum bicolor

Biolistic DNA delivery has been considered a universal tool for genetic manipulation to transfer exotic genes to cells or tissues due to its simplicity, versatility, and high efficiency. It has been a preferred method for investigating plant gene function in most monocot crops. The first transgenic sorghum plants were successfully regenerated through biolistic DNA delivery in 1993, with a relatively low transformation efficiency of 0.3%. Since then, tremendous progress has been made in recent years where the highest transformation efficiency was reported at 46.6%. Overall, the successful biolistic DNA delivery system is credited to three fundamental cornerstones: robust tissue culture system, effective gene expression in sorghum, and optimal parameters of DNA delivery. In this chapter, the history, application, and current development of biolistic DNA delivery in sorghum are reviewed, and the prospect of sorghum genetic engineering is discussed.

Biolistic Transformation of Cotton Zygotic Embryo Meristem

Biolistic transformation of cotton (Gossypium hirsutum L.) meristems, isolated from mature seed, is detailed in this report. A commercially available, helium-driven biolistic device (Bio-Rad PDS1000/He ) was used to bombard gold particles coated with a marker gene (uidA or "GUS") into the shoot meristem. The penetration of gold particles was dependent on bombardment parameters, and it was mostly one- to two-cell layers deep. Stable transformation of epidermal L1 layer was consistently observed in approximately 5% of the seedlings. Germ line transformation was observed in up to 0.71% of bombarded meristems by several laboratories. Using this method identification of germ line transformation is laborious and time-consuming. However, the protocol described here represents a simple and efficient method for generating germ line transformation events. In addition, this procedure offers a quick method to evaluate gene constructs in cotton tissues (embryos, cotyledons, leaf) especially fibers which originate as single cells from the maternal epidermis layer.

Biolistic Transformation of Cotton Embryogenic Cell Suspension Cultures

Genetic transformation of cotton (Gossypium hirsutum L.) is highly dependent on the ability to regenerate fertile plants from transgenic cells through somatic embryogenesis. Induction of embryogenic cell cultures is genotype-dependent. However, once embryogenic cell cultures are available, they can be effectively used for transformation by Agrobacterium or biolistic bombardment methods. Here I describe a detailed procedure to transform cotton embryogenic cell suspension cultures by biolistic bombardment. A commercially available, helium-driven biolistic device (Bio-Rad PDS1000/He) was used to bombard gold particles coated with plasmid DNA (for visual identification of transformed cells and/or selection) into embryogenic cells. Stable transformation at a high frequency (up to 4% of the transiently expressing cells) is possible. Regeneration of fertile transgenic plants from embryogenic cells takes only about 2 months. Another advantage of the embryogenic cell suspension cultures is that they are amenable for cryopreservation and long-term storage. It is highly preferable to transform commercial varieties of choice than obsolete varieties to avoid genetic drug due to backcrossing.

Repurposing Macromolecule Delivery Tools for Plant Genetic Modification in the Era of Precision Genome Engineering

Efficient delivery of macromolecules into plant cells and tissues is important for both basic research and biotechnology product applications. In transgenic research, the goal is to deliver DNA molecules into regenerable cells and stably integrate them into the genome. Over the past 40 years, many macromolecule delivery methods have been studied. To generate transgenic plants, particle bombardment and Agrobacterium-mediated transformation are the methods of choice for DNA delivery. The rapid advance of genome editing technologies has generated new requirements on large biomolecule delivery and at the same time reinvigorated the development of new transformation technologies. Many of the gene delivery options that have been studied before are now being repurposed for delivering genome editing machinery for various applications. This article reviews the major progress in the development of tools for large biomolecule delivery into plant cells in the new era of precision genome engineering.

A biolistic method for high-throughput production of transgenic wheat plants with single gene insertions

BACKGROUND

The relatively low efficiency of biolistic transformation and subsequent integration of multiple copies of the introduced gene/s significantly complicate the genetic modification of wheat (Triticum aestivum) and other plant species. One of the key factors contributing to the reproducibility of this method is the uniformity of the DNA/gold suspension, which is dependent on the coating procedure employed. It was also shown recently that the relative frequency of single copy transgene inserts could be increased through the use of nanogram quantities of the DNA during coating.

RESULTS

A simplified DNA/gold coating method was developed to produce fertile transgenic plants, via microprojectile bombardment of callus cultures induced from immature embryos. In this method, polyethyleneglycol (PEG) and magnesium salt solutions were utilized in place of the spermidine and calcium chloride of the standard coating method, to precipitate the DNA onto gold microparticles. The prepared microparticles were used to generate transgenics from callus cultures of commercial bread wheat cv. Gladius resulting in an average transformation frequency of 9.9%. To increase the occurrence of low transgene copy number events, nanogram amounts of the minimal expression cassettes containing the gene of interest and the hpt gene were used for co-transformation. A total of 1538 transgenic wheat events were generated from 15,496 embryos across 19 independent experiments. The variation of single copy insert frequencies ranged from 16.1 to 73.5% in the transgenic wheat plants, which compares favourably to published results.

CONCLUSIONS

The DNA/gold coating procedure presented here allows efficient, large scale transformation of wheat. The use of nanogram amounts of vector DNA improves the frequency of single copy transgene inserts in transgenic wheat plants.

Biolistic Transformation of Wheat

The wheat genome encodes some 100,000 genes. To understand how the expression of these genes is regulated it will be necessary to carry out many genetic transformation experiments. Robust protocols that allow scientists to transform a wide range of wheat genotypes are therefore required. In this chapter, we describe a protocol for biolistic transformation of wheat that uses immature embryos and small quantities of DNA cassettes. An original method for DNA cassette purification is also described. This protocol can be used to transform a wide range of wheat genotypes and other related species.

Generation of Mutants of Nuclear-Encoded Plastid Proteins Using CRISPR/Cas9 in the Diatom Phaeodactylum tricornutum

Genome modifications in microalgae are becoming a widespread and mandatory tool for research in both fundamental and applied biology. Among genome editing methods in these photosynthetic organisms, CRISPR/Cas9 offers a specific, powerful and efficient tool for genome engineering by inducing mutations in targeted regions of the genome. Here we described a protocol that allows the generation of knockout mutants by CRISPR/Cas9 in the diatom Phaeodactylum tricornutum using biolistic transformation.

Efficient genetic transformation of Momordica charantia L. by microprojectile bombardment

Here, we report the optimized conditions for biolistic particle delivery-mediated genetic transformation of bitter melon using petiole segments. In this study, DNA-coated gold particles of 0.6 µm were used for optimizing the parameters of transformation and eventually regeneration of bitter melon putative transgenics. Initially, biolistic parameters namely helium pressure and macrocarrier to target tissue distance, were optimized using binary vector pBI121 carrying both β-glucuronidase gene (GUS) and neomycin phosphotransferase II gene (npt II) as a reporter and as a selectable marker gene, respectively. The effect of optimized physical parameters on the frequency of transient (79.2 ± 1.52%) and stable (41.9%) expressions has been investigated. The optimized biolistic parameters for petiole segments of Momordica charantia L. were determined as follows: 650 psi helium pressure and 6 cm target distance. Using the optimized parameters, transformation of bitter melon was carried out for generation of putative transformants from bombarded tissues on SRM-K medium, with a mean number of 50.3 explants surviving at the end of the final selection (50 mg l-1 kanamycin) round. Finally, the transformants produced were subjected to GUS histochemical assay, and integration of the transgenes (GUS and npt II) into the nuclear genome was confirmed by PCR analysis. DNA blot analysis confirmed the transgene integration in the transformed plantlet genomes. The present study may be used for developing transplastomic technology in this valuable medicinal plant for enhanced metabolic engineering pathways and production of biopharmaceuticals.

Molecular and FISH analyses of a 53-kbp intact DNA fragment inserted by biolistics in wheat (Triticum aestivum L.) genome

A large, 53-kbp, intact DNA fragment was inserted into the wheat ( Triticum aestivum L.) genome. FISH analyses of individual transgenic events revealed multiple insertions of intact fragments. Transferring large intact DNA fragments containing clusters of resistance genes or complete metabolic pathways into the wheat genome remains a challenge. In a previous work, we showed that the use of dephosphorylated cassettes for wheat transformation enabled the production of simple integration patterns. Here, we used the same technology to produce a cassette containing a 44-kb Arabidopsis thaliana BAC, flanked by one selection gene and one reporter gene. This 53-kb linear cassette was integrated in the bread wheat (Triticum aestivum L.) genome by biolistic transformation. Our results showed that transgenic plants harboring the entire cassette were generated. The inheritability of the cassette was demonstrated in the T1 and T2 generation. Surprisingly, FISH analysis performed on T1 progeny of independent events identified double genomic insertions of intact fragments in non-homoeologous positions. Inheritability of these double insertions was demonstrated by FISH analysis of the T1 generation. Relative conclusions that can be drawn from molecular or FISH analysis are discussed along with future prospects of the engineering of large fragments for wheat transformation or genome editing.

CRISPR/Cas9 Gene Editing in the Marine Diatom Phaeodactylum tricornutum

The establishment of the CRISPR/Cas9 technology in diatoms ( Hopes et al., 2016 ; Nymark et al., 2016 ) enables a simple, inexpensive and effective way of introducing targeted alterations in the genomic DNA of this highly important group of eukaryotic phytoplankton. Diatoms are of interest as model microorganisms in a variety of areas ranging from oceanography to materials science, in nano- and environmental biotechnology, and are presently being investigated as a source of renewable carbon-neutral fuel and chemicals. Here we present a detailed protocol of how to perform CRISPR/Cas9 gene editing of the marine diatom Phaeodactylum tricornutum, including: 1) insertion of guide RNA target site in the diatom optimized CRISPR/Cas9 vector (pKS diaCas9-sgRNA), 2) biolistic transformation for introduction of the pKS diaCas9-sgRNA plasmid to P. tricornutum cells and 3) a high resolution melting based PCR assay to screen for CRISPR/Cas9 induced mutations.

Microprojectile Bombardment Transformation of Date Palm Using the Insecticidal Cholesterol Oxidase (ChoA) Gene

The overall objective of this work is to optimize the transformation system for date palm as a first step toward production of date palm clones resistant to noxious pests. A construct harboring the cholesterol oxidase (ChoA) gene, which renders plant resistance against insect attack, is introduced into embryogenic date palm callus using the PDS-1000/He particle bombardment system. The process involves the establishment of embryogenic callus cultures as well as immature embryo-derived microcalli that are used as target tissues for shooting and optimization of transformation conditions. This chapter in addition explains molecular and histochemical assays conducted to confirm gene integration and expression.

Biolistic transformation of Scoparia dulcis L

Here, we report for the first time, the optimized conditions for microprojectile bombardment-mediated genetic transformation in Vassourinha (Scoparia dulcis L.), a Plantaginaceae medicinal plant species. Transformation was achieved by bombardment of axenic leaf segments with Binary vector pBI121 harbouring β-glucuronidase gene (GUS) as a reporter and neomycin phosphotransferase II gene (npt II) as a selectable marker. The influence of physical parameters viz., acceleration pressure, flight distance, gap width & macroprojectile travel distance of particle gun on frequency of transient GUS and stable (survival of putative transformants) expressions have been investigated. Biolistic delivery of the pBI121 yielded the best (80.0 %) transient expression of GUS gene bombarded at a flight distance of 6 cm and rupture disc pressure/acceleration pressure of 650 psi. Highest stable expression of 52.0 % was noticed in putative transformants on RMBI-K medium. Integration of GUS and npt II genes in the nuclear genome was confirmed through primer specific PCR. DNA blot analysis showed more than one transgene copy in the transformed plantlet genomes. The present study may be used for metabolic engineering and production of biopharmaceuticals by transplastomic technology in this valuable medicinal plant.

Chloroplast-Based Expression of Recombinant Proteins by Gateway® Cloning Technology

Plastid transformation for the expression of recombinant proteins and entire enzymatic pathways has become a promising tool for plant biotechnology in the past decade. Several improvements of the technology have turned plant plastids into robust and dependable expression platforms for multiple high value compounds. In this chapter, we describe our current methodology based on Gateway(®) recombinant cloning, which we have adapted for plastid transformation. We describe the steps required for cloning, biolistic transformation, identification, and regeneration of transplastomic plant lines and Western blot analysis.