eoe sub articles

EoE Sub Articles

&#160;1. Arabidopsis Transformation
<ol>
	<li>Prepare the&#160;Arabidopsis&#160;plants for transformation.
	<ol>
		<li>Grow&#160;Arabidopsis&#160;plants in a greenhouse or climate-controlled growth chamber until they are flowering (12 pots with 9 plants each per dipping).</li>
		<li>Clip the first bolts to allow more secondary bolts to emerge. Plants are ready for dipping 4&#8211;6 days after clipping, when the plants have many immature flower heads and not many fertilized siliques.</li>
	</ol>
	</li>
	<li>Floral dipping
	<ol>
		<li>Dip inflorescences for 5&#8211;10s in&#160;Agrobacterium&#160;suspension carrying T-DNA cloned with binary bacterial artificial chromosome or BIBAC. Use gentle agitation.</li>
		<li>Wrap the above-ground parts of the plants in cling film to keep the humidity high, and cover the plant pots with a box to keep the plants in the dark. Incubate the plants for 2 days in a greenhouse/growth chamber.</li>
		<li>Remove the box and the cling film and grow the plants to maturity in a greenhouse/growth chamber. 
		NOTE: To increase the efficiency of transformation, the same plants can be re-dipped 7 days after the first dipping.</li>
		<li>Harvest the seeds. Pool and analyze the seeds (T1) of plants, transformed with the same construct, as a single set.</li>
	</ol>
	</li>
	<li>Screen for transgenic plants.
	<ol>
		<li>To screen for transgenic plants transformed with a pBIBAC-RFP-GW derivative, analyze the seeds using fluorescence microscopy. In order to detect DsRed expression in seed coats, image the seeds at an excitation of 560 nm and emission of 600&#8211;650 nm. Separate the fluorescent seeds from non-fluorescent counterparts using forceps.</li>
		<li>To screen for transgenic plants transformed with a pBIBAC-BAR-GW derivative, sow the seeds in trays filled with soil (~2,500 seeds/0.1 m2). To ensure an even spreading of seeds over trays, suspend seeds in 0.1% agar in 0.5x Murashige Skoog medium (MS), and spread the seeds using a 1 mL pipette. 
		NOTE: To stimulate the seeds to germinate in a synchronous manner, incubate the seeds for at least 2 days at 4 &#176;C. This can be done before or after sowing the seeds.
		<ol>
			<li>Spray the seedlings with 0.5% Glufosinate-ammonium solution 2 weeks and 3 weeks after sowing in trays. Use 500 mL of Glufosinate-ammonium solution per 1 m2.</li>
			<li>Transfer surviving seedlings to individual pots. A typical image of a tray with seedlings before and after (second) Glufosinate-ammonium treatment are shown in&#160;Figure 1.</li>
			<li>Analyze the Glufosinate-ammonium-resistant plants by PCR for the presence of the construct of interest.
			<ol>
				<li>Isolate the genomic plant DNA for PCR.</li>
			</ol>
			</li>
		</ol>
		</li>
	</ol>
	</li>
</ol>

<table border="1" fo:keep-together.within-page="1" fo:keep-with-next.within-page="always">
	<tbody>
		<tr>
			<td>Kanamycin sulphate monohydrate</td>
			<td>Duchefa</td>
			<td>K0126</td>
			<td></td>
		</tr>
		<tr>
			<td>Gateway LR clonase enzyme mix&#160;</td>
			<td>Thermo Scientific - Invitrogen</td>
			<td>11791-019</td>
			<td></td>
		</tr>
		<tr>
			<td>Murashige Skoog medium</td>
			<td>Duchefa</td>
			<td>M0221</td>
			<td></td>
		</tr>
		<tr>
			<td>Agar</td>
			<td>BD</td>
			<td>214010</td>
			<td></td>
		</tr>
		<tr>
			<td>Glufosinate-ammonium (Basta)</td>
			<td>Bayer</td>
			<td>79391781</td>
			<td></td>
		</tr>
		<tr>
			<td>Phosphor imager</td>
			<td>GE Healthcare Life Sciences</td>
			<td>Typhoon FLA 7000</td>
			<td></td>
		</tr>
		<tr>
			<td>cling film (Saran wrap)</td>
			<td>Omnilabo</td>
			<td>1090681</td>
			<td></td>
		</tr>
		<tr>
			<td>Agarose</td>
			<td>Thermo Scientific - Invitrogen</td>
			<td>16500</td>
			<td></td>
		</tr>
	</tbody>
</table>

binary bacterial artificial chromosome vector based gene transformation in arabidopsis plants: a technique to generate transgenic plants with single-copy insertion

Source: Tark-Dame, M., et al. <a href="https://www.jove.com/v/57295">Generating Transgenic Plants with Single-copy Insertions Using BIBAC-GW Binary Vector.</a> J. Vis. Exp. (2018).
In this video, we demonstrate generation of transgenic Arabidopsis plants expressing stable transgene through Agrobacterium-mediated binary bacterial artificial chromosome-based gene transformation.

<img alt="Figure 1" src="/files/ftp_upload/20980/20980_Figure1.jpg" /> 
Figure 1: Tray filled with Arabidopsis seedlings before and after Glufosinate-ammonium treatment. Seedlings not expressing the bar gene that is present in the pBIBAC-BAR-GW T-DNA die after being sprayed with Glufosinate-ammonium solution. The photos show the same tray of seedlings (A) before spraying with Glufosinate-ammonium, 14 days after sowing, and (B) 10 days later, after being spra...

Binary Bacterial Artificial Chromosome Vector Based Gene Transformation in Arabidopsis Plants: A Technique to Generate Transgenic Plants With Single-Copy Insertion

Source: Tark-Dame, M., et al. Generating Transgenic Plants with Single-copy Insertions Using BIBAC-GW Binary Vector. J. Vis. Exp. (2018).
In this video, ...

Begin with Arabidopsis plants bearing immature flower heads. Dip the flower heads in Agrobacterium cell suspension carrying T-DNA cloned with binary bacterial artificial chromosome or BIBAC, a vector replicating in both E. coli and Agrobacterium systems. This T-DNA binary vector can deliver large transgenes such as herbicide resistance gene and fluorescent selectable markers along a seed-specific promoter.
While the flower heads are still immersed, gently agitate the plants to enhance their contact with Agrobacterium. With its inherent ability to infect plants, Agrobacterium transfers the transgene into the floral cell. As the transgene enters the cell, it moves to the nucleus and fuses with the plant genome.
Now, wrap the plant in cling film and incubate in the dark to retain humidity for improved transformation. Remove the film and grow plants under physiological conditions until they produce seeds.
Next, harvest the seeds and observe under fluorescence microscope to select transformants. Now, grow the transformed seeds in suitable conditions until germination. Spray the plants with herbicide, and incubate.
Plants with multiple transgene insertion experience gene silencing and wither, whereas plants with a single-copy insertion express an active herbicide-metabolizing enzyme and survive the treatment. Extract genomic DNA from the surviving transformants and perform PCR to calculate efficiency of single-copy insertion.

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1.3K Views. Source: Tark-Dame, M., et al. Generating Transgenic Plants with Single-copy Insertions Using BIBAC-GW Binary Vector. J. Vis. Exp. (2018). In this video, we demonstrate generation of transgenic Arabidopsis plants expressing stable transgene through Agrobacterium-mediated binary bacterial artificial chromosome-based gene transformation. 

Video: Binary Bacterial Artificial Chromosome Vector Based Gene Transformation in Arabidopsis Plants: A Technique to Generate Transgenic Plants With Single-Copy Insertion - Concept

Plant Growth and Agrobacterium-mediated Floral-dip Transformation of the Extremophyte Schrenkiella parvula

Schrenkiella parvula is an extremophyte adapted to various abiotic stresses, including multiple ion toxicity stresses. Despite high-quality genomic resources available to study how plants adapt to environmental stresses, its value as a functional genomics model and tool has been limited by the lack of a feasible transformation system. In this protocol, we report how to generate stable transgenic S. parvula lines using an Agrobacterium-mediated floral-dip method. We modified the transformation protocol used for A. thaliana to account for unique traits of S. parvula, such as an indeterminate flowering habit and a high epicuticular wax content on leaves. Briefly, S. parvula seeds were stratified at 4 &#176;C for five days before planting. Plants were grown at a photoperiod of a 14 h light and 10 h dark and a 130 &#181;mol m-2s-1 light intensity, at 22 &#176;C to 24 &#176;C. Eight to nine week-old plants with multiple inflorescences were selected for transformation. These inflorescences were dipped in an infiltration solution of Agrobacterium tumefaciens GV3101 carrying the pMP90RK plasmid. We performed two rounds of flower dipping with an interval of three to four weeks to increase the transformation efficiency. The T1 seeds were collected and dried for four weeks in a container with desiccants before germination to screen for candidate transformed lines. Resistance to BASTA was used to screen T1 plants. We sprayed the BASTA solution three times with an interval of three days starting at two week-old plants to reduce false positives. A BASTA drop test was performed on surviving individual plants to identify true positive transformants. The transformation efficiency was 0.033%, yielding 3&#8211;4 transgenic plants per 10,000 T1 seeds propagated.

Plant Growth and Agrobacterium-mediated Floral-dip Transformation of the Extremophyte Schrenkiella parvula

Agrobacterium-mediated transformation using a floral-dip method can be successfully employed to create stable transgenic lines of the extremophyte model Schrenkiella parvula. We present a protocol modified from that for Arabidopsis thaliana, considering different growth habits and physiological characteristics of the extremophyte.

Schrenkiella parvula is an extremophyte adapted to various abiotic stresses, including multiple ion toxicity stresses. Despite high-quality genomic ...

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Genetics

Inducible, Cell Type-Specific Expression in Arabidopsis thaliana Through LhGR-Mediated Trans-Activation

Inducible, tissue-specific expression is an important and powerful tool to study the spatio-temporal dynamics of genetic perturbation. Combining the flexible and efficient GreenGate cloning system with the proven and benchmarked LhGR system (here termed GR-LhG4) for the inducible expression, we have generated a set of transgenic Arabidopsis lines that can drive the expression of an effector cassette in a range of specific cell types in the three main plant meristems. To this end, we chose the previously developed GR-LhG4 system based on a chimeric transcription factor and a cognate pOp-type promoter ensuring tight control over a wide range of expression levels. In addition, to visualize the expression domain where the synthetic transcription factor is active, an ER-localized mTurquoise2 fluorescent reporter under control of the pOp4 or pOp6 promoter is encoded in driver lines. Here, we describe the steps necessary to generate a driver or effector line and demonstrate how cell type specific expression can be induced and followed in the shoot apical meristem, the root apical meristem and the cambium of Arabidopsis. By using several or all driver lines, the context specific effect of expressing one or multiple factors (effectors) under control of the synthetic pOp promoter can be assessed rapidly, for example in F1 plants of a cross between one effector and multiple driver lines. This approach is exemplified by the ectopic expression of VND7, a NAC transcription factor capable of inducing ectopic secondary cell wall deposition in a cell autonomous manner.

Inducible, Cell Type-Specific Expression in Arabidopsis thaliana Through LhGR-Mediated Trans-Activation

Here, we describe the generation and application of a set of transgenic Arabidopsis thaliana lines enabling inducible, tissue-specific expression in the three main meristems, the shoot apical meristem, the root apical meristem, and the cambium.

Inducible, tissue-specific expression is an important and powerful tool to study the spatio-temporal dynamics of genetic perturbation. Combining the ...

Split Green Fluorescent Protein System to Visualize Effectors Delivered from Bacteria During Infection

Bacteria, one of the most important causative agents of various plant diseases, secrete a set of effector proteins into the host plant cell to subvert the plant immune system. During infection cytoplasmic effectors are delivered to the host cytosol via a type III secretion system (T3SS). After delivery into the plant cell, the effector(s) targets the specific compartment(s) to modulate host cell processes for survival and replication of the pathogen. Although there has been some research on the subcellular localization of effector proteins in the host cells to understand their function in pathogenicity by using fluorescent proteins, investigation of the dynamics of effectors directly injected from bacteria has been challenging due to the incompatibility between the T3SS and fluorescent proteins.
Here, we describe our recent method of an optimized split superfolder green fluorescent protein system (sfGFPOPT) to visualize the localization of effectors delivered via the bacterial T3SS in the host cell. The sfGFP11 (11th &#946;-strand of sfGFP)-tagged effector secreted through the T3SS can be assembled with a specific organelle targeted sfGFP1-10OPT (1-10th &#946;-strand of sfGFP) leading to fluorescence emission at the site. This protocol provides a procedure to visualize the reconstituted sfGFP fluorescence signal with an effector protein from Pseudomonas syringae in a particular organelle in the Arabidopsis and Nicotiana benthamiana plants.

Fluorescent protein-based approaches to monitor effectors secreted by bacteria into host cells are challenging. This is due to the incompatibility between fluorescent proteins and the type-III secretion system. Here, an optimized split superfolder GFP system is used for visualization of effectors secreted by bacteria into the host plant cell.

Bacteria, one of the most important causative agents of various plant diseases, secrete a set of effector proteins into the host plant cell to subvert the ...

Binary Bacterial Artificial Chromosome Vector Based Gene Transformation in Arabidopsis Plants: A Technique to Generate Transgenic Plants With Single-Copy Insertion

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