High-throughput CRISPR Vector Construction and Characterization of DNA Modifications by Generation of Tomato Hairy Roots

Summary

Using DNA assembly, multiple CRISPR vectors can be constructed in parallel in a single cloning reaction, making the construction of large numbers of CRISPR vectors a simple task. Tomato hairy roots are an excellent model system to validate CRISPR vectors and generate mutant materials.

Abstract

Targeted DNA mutations generated by vectors with clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9 technology have proven useful for functional genomics studies. While most cloning strategies are simple to perform, they generally use multiple steps and can require several days to generate the ultimate constructs. The method presented here is based on DNA assembly and can produce fully functional CRISPR vectors in a single cloning reaction. Vector construction can also be pooled, further increasing the efficiency and utility of the process. A modification of the method is used to create CRISPR vectors with multiple gene targets. CRISPR vectors are then transformed into tomato hairy roots to generate transgenic materials with targeted DNA modifications. Hairy roots are a useful system for testing vector functionality as they are technically simple to generate and amenable to large-scale production. The methods presented here will have wide application as they can be used to generate a variety of CRISPR vectors and be used in a wide range of plant species.

Introduction

The ability to generate targeted DNA modifications with CRISPR/Cas9 has great potential for functional genomics studies. There are two components of the CRISPR/Cas9 system; the Cas9 nuclease, derived from Staphylococcus pyogenes and an approximately 100-nt guide RNA (gRNA) molecule that directs Cas9 to the targeted DNA site(s)¹. Target recognition is conferred by the first ~20-nt of the gRNA, which allows for high-throughput production of targeting vectors^2,3. Most organisms that can be engineered, already have been with CRISPR/Cas9 technology^4,5.

In plants, constitutive promoters, such as the CaMV 35S promoter, are commonly used to drive the expression of the Cas9 nuclease⁶. The gRNAs are expressed using the RNA polymerase III U6 or U3 promoters which restricts the first base of the gRNA to either a G, for U6, or A for U3, for efficient transcription. However RNA polymerase II promoters, which are free of these restrictions, have also been used^7,8.

Different gRNAs induce DNA mutations with different efficiencies, and so it can be important to first validate CRISPR vectors before investing in whole-plant transformations or setting up extensive phenotypic screens. Transient expression of CRISPR constructs in plants, by using agroinfiltration for example, generally results in a lower frequency of DNA modification as compared to stable plants⁶, making detection of mutations difficult and phenotypic assays impractical with such approaches. So-called hairy roots are a convenient, alternative system since a large number of independent, stably transformed materials can be generated within weeks, as opposed to months for stable plants. CRISPR vectors are very effective at inducing DNA mutations in hairy roots^9,10.

DNA assembly methods efficiently ligate DNA fragments containing overlapping ends¹¹. A major advantage of some DNA assembly methods is the ability to incorporate ssDNA (i.e., oligos) into the assembled products. Since gRNAs are only ~20-nt long and new targets can be made with synthesized oligos, these DNA assembly methods are well suited to CRISPR cloning. The protocols described here are based on the p201 series of CRISPR vectors that has been successfully used in soybean¹⁰, poplar¹² and now tomato. The cloning procedure presented offers several advantages over the current cloning method¹⁰. Namely, fully functional vectors can be generated in a single cloning reaction in a single day. Vector construction can also be pooled to generate multiple CRISPR vectors in parallel, further reducing hands-on time and material costs. We also present a protocol for the generation of tomato hairy roots as an efficient method to produce transgenic materials with targeted gene deletions. Hairy roots are used to validate the CRISPR vectors and provide material for subsequent experiments.

Protocol

1. Guide RNA Design and Vector Construction

1. Identify target sequences for the genes of interest. There are a variety of online CRISPR target-finding programs suitable for this step^13,14.
   NOTE: Here we use the GN₂₀GG target motif, but other designs may be suitable depending on the application or vector system used.
2. Design 60-mer gRNA oligos to include the GN₁₉ portion of the target motifs flanked by 5' and 3' 20-nt sequences that are required for DNA assembly. The final 60-mer motif is: 5'-TCAAGCGAACCAGTAGGCTT-GN₁₉-GTTTTAGAGCTAGAAATAGC-3'.
   NOTE: Standard, desalted primers work fine.
3. Prepare the four DNAs for assembly (Figure 1). See supplementary file for DNA sequences.
   1. Digest 1 - 5 µg of p201N:Cas9¹⁰ plasmid with the restriction enzyme SpeI in 1x Buffer 4 at 37 °C for 2 hr. Column-purify the digest according to manufacturer's instructions. Resuspend in ~15 µl of 10 mM Tris-HCl, and quantify by UV spectrophotometry.
   2. Perform a second digest with the restriction enzyme SwaI in 1x Buffer 3.1 at 25 °C for 2 hr. Check 100 - 200 ng on a 0.8% agarose gel to confirm complete digestion.
      NOTE: A correctly digested plasmid will have a single band at 14,313 bp. Note: Heat inactivation of the enzyme and dephosphorylation are not required. Digested plasmid may be stored at -20 °C.
   3. PCR amplify the Medicago truncatula (Mt) U6 promoter and scaffold DNAs from the pUC gRNA Shuttle¹⁰ plasmid using the primers SwaI_MtU6F / MtU6R and ScaffoldF / SpeI_ScaffoldR, respectively. Use a high-fidelity polymerase with the PCR conditions: 95 °C for 3 min; 31 cycles (98 °C for 20 sec, 60 °C for 15 sec, 72 °C for 30 sec); and 72 °C for 5 min.
      1. Visualize ~3 µl aliquots of PCR products on a 1% agarose gel to confirm amplification. The MtU6 amplicon is 377 bp and the scaffold amplicon is 106 bp. Column-purify the remaining PCR products according to manufacturer's instructions, quantify by UV spectrophotometry and store at -20 °C.
   4. Resuspend the entire tube of gRNA oligos to 100 µM in laboratory-grade water. Add 1 µl of 100 µM oligo to 500 µl of 1x Buffer 2.1. Mix well. If pooling multiple oligos, add 1 µl of each 100 µM oligo to the 1x Buffer 2.1 tube. Diluted oligos can be stored at -20 °C.
4. Program a thermal cycler to hold at 50 °C, using a heated lid. Combine 100 ng (0.011 pmol) of linearized vector, 50 ng (0.2 pmol) of MtU6 promoter, 12 ng (0.2 pmol) of scaffold, 1 µl (0.2 pmol) of diluted gRNA oligo(s), and water to a volume of 5 µl. Add 5 µl of 2x high-fidelity DNA assembly master mix, mix well and spin down. Incubate reaction for 60 min in the 50 °C thermal cycler. Then place the reaction on ice.
   Note: Reaction volumes can be increased to accommodate low DNA yields.
5. Transform 2 µl of the reaction into competent E. coli cells using standard techniques and plate on LB supplemented with 50 mg L^-1 kanamycin (Kan₅₀). Grow plated-cells at 37 °C overnight. Save the remaining DNA assembly reaction at -20 °C.
6. Colony screen by PCR using the primers StUbi3P218R and ISceIR. Dilute an aliquot of the remaining DNA assembly reaction with water 1:5. Use 1 µl as a positive control for the colony screen and 1 ng of circular p201N:Cas9 plasmid as a no-insert control.
   1. PCR amplify with the conditions; 95 °C for 3 min; 31 cycles (95 °C for 30 sec, 58 °C for 30 sec, 72 °C for 30 sec); and at 72 °C for 5 min. Visualize PCR products on a 1% agarose gel. Ensure that correct insertions have a band at 725 bp and vectors without inserts (e.g., uncut vector) will have a 310-bp band.
7. Grow positive colonies in LB Kan₅₀ liquid cultures overnight at 37 °C and purify plasmids according to manufacturer's instructions. Sanger sequence plasmids with the StUbi3P218R primer and align chromatograms to the MtU6 promoter, target, and scaffold sequences to ensure no errors were introduced during cloning.
8. Perform a diagnostic digest by digesting ~1 µg of plasmid with EcoRV and StyI. Visualize on a 0.8% agarose gel. Fragments (in bp) are: 4192, 2001, 1743, 1544, 1381, 995, 831, 702, 460, 423, 318, and 174.
9. Use DNA assembly to construct vectors with multiple gRNAs.
   1. To construct a vector with two gRNA cassettes, PCR amplify the first-position gRNA with the primers SwaI_MtU6F / UNS1_ScaffoldR and the second-position gRNA with the primers UNS1_MtU6F / SpeI_ScaffoldR from 1 ng of each of the respective plasmids constructed in steps 1.1 - 1.8. Use the PCR conditions in step 1.3.3. Visualize ~3 µl aliquots of PCR products on a 1% agarose gel to confirm amplification. Amplicons are ~500 bp.
   2. Combine and mix approximately equal amounts of un-purified PCR products in a 200 µl tube (typically 3 - 4 µl of each). For assembly, add 1 µl combined PCR products, 50 ng of SwaI and SpeI linearized p201N:Cas9, laboratory-grade water to 2.5 µl and 2.5 µl of 2x high-fidelity DNA assembly master mix. Incubate in a 50 °C thermal cycler for 15 min.
      Note: The DNA assembly manuals recommends a 15 min incubation for 2 - 3 fragments.
   3. Transform 1 - 2 µl into competent E. coli cells and plate on LB Kan₅₀. Grow plated cells at 37 °C overnight. Save the remaining reaction at -20 °C.
   4. Colony screen by PCR with primers StUbi3P218R and ISceIR with the same conditions as step 1.6. Correct clones will have a 1,200 bp amplicon. Grow positive colonies in LB Kan₅₀ liquid cultures overnight and purify plasmids.
   5. Sanger sequence plasmids with the primers StUbi3P218R (covers first-position gRNA) and p201R (covers second-position gRNA). Align chromatograms to the MtU6 promoter, target, and scaffold sequences. Diagnostic digest with EcoRV and StyI will result in the following fragments (in bp): 4192, 2476, 1743, 1544, 1381, 995, 831, 702, 460, 423, 318, 174. Bolded fragment contains the second gRNA.
10. After meeting all the quality-control expectations, transform plasmids into Agrobacterium rhizogenes strain ARqua1¹⁵. Add 1 µl of the plasmid prep to 50 µl of electrocompetent cells and electroporate in a 1 mm cuvette with the settings: 2.4 kV, 25 µF, and 200 Ω. Recover cells in ~500 µl of SOC and shake at 28 °C for 2 hr. Plate on LB Kan₅₀ and grow at 28 °C for 2 days. Perform colony screen using the same primers and PCR conditions as 1.3.3. Make glycerol stocks from positive clones.

2. Hairy Root Transformation

1. Sterilize tomato seeds in 20% household bleach for 15 min, with constant mixing. In a laminar flow hood, remove the bleach and wash in sterile laboratory-grade water 3 times.
2. Plate 30 seeds in a GA-7 box containing ½ MS media (2.22 g L^-1 MS salts + Gamborg Vitamins, 10 g L^-1 sucrose, 3 g L^-1 gellan gum, pH 5.8). Germinate for ~2 days in the dark, then move GA-7 boxes to light. Grow seedlings for ~4 more days in the light.
3. The day before transformation, streak out A. rhizogenes cultures on solid LB Kan₅₀ and grow at 28 °C overnight.
4. Day of transformation, in the laminar flow hood assemble sterile materials: 12 ml culture tubes, 50 ml conical tube, ½ MS liquid (no gellan gum), 200 µM acetosyringone, filter paper, Petri dishes, forceps and scalpel, pipettes and pipette tips. Add 25 µl of acetosyringone to 50 ml of ½ MS and pour ~ 6 ml into each culture tube.
5. Use a bent 200 µl tip to scrape A. rhizogenes cells from the plate and resuspend in the 6 ml of ½ MS liquid. Vortex the tube to completely resuspend the cells. After resuspending cells from each vector, measure the optical density (O.D.) of 1 ml of cells at a fixed wavelength of 600 nM. Ensure O.D. is between 0.2 and 0.4; dilute or add more cells as necessary. Repeat for each construct.
6. Add ~ 2 ml of ½ MS liquid to a Petri dish with a sterile filter paper. Excise cotyledons from the seedlings and place on the moistened filter paper. Once all cotyledons have been collected, cut the distal ~1 cm off of the cotyledons, resulting in cotyledon pieces with two cut ends. Add explants to A. rhizogenes solutions, mix, and incubate for 20 min with occasional inverting.
   Note: Approximately 12 explants per construct are routinely used, though as many as 80 explants have been inoculated in 6 ml of A. rhizogenes solution.
7. During the A. rhizogenes incubation, add filter paper to Petri dishes, one per construct transformed. Also set ½ MS solid media, no antibiotics, in the laminar flow hood to dry.
8. Scoop cotyledons out of A. rhizogenes solution with sterile forceps and place on dry filter paper. Cover with Petri lid to ensure tissues do not dry out while proceeding to the next transformation. Blot cotyledons on the filter paper and transfer, abaxial side up, to ½ MS media. Wrap plates with surgical tape and co-cultivate in the dark at room temperature for 2 days.
9. After co-cultivation, transfer cotyledons, abaxial side up, to ½ MS media supplemented with 300 mg L^-1 ticarcillin/clavulanic acid (Tim₃₀₀, to prevent the growth of residual A. rhizogenes) and Kan₅₀ (for plant selection) and wrap with surgical tape. Maintain cultures under fluorescent lights at room temperature with a 16-hour photoperiod.
10. After ~1.5 - 2 weeks roots at least 2 cm in length are excised from the cotyledons using sterile forceps and a scalpel and transferred to ½ MS Kan₅₀ Tim₃₀₀ media. Transfer 10 to 15 roots to a single plate. Mark the position of the root tips with a marker, wrap with surgical tape, and maintain in culture room.
11. After one week, transformed roots are seen growing on the selective media. Harvest a subsample of transformed roots for DNA extraction using the preferred DNA-extraction method. Note: Plates with cotyledons can be kept for 2 - 3 weekly harvests, after which point the roots grow into a tangled mess and are difficult to isolate. Non harvested root tissues can be maintained indefinitely. A variety of assays can be performed on the isolated DNA samples to determine DNA mutation frequency and type. Results from a few such assays are described below.

Results

CRISPR vector construction with DNA assembly typically generates tens to hundreds of independent clones. Colony screening by PCR easily identifies correct clones and can distinguish between plasmids with and without inserts (Figure 2A) which is useful for troubleshooting. Typically, all of the clones contain an insert and a user may opt to skip the colony screening steps altogether. Diagnostic digests (Figure 2B) and Sanger sequencing are used for quality...

Discussion

Since DNA assembly is used to recombine any overlapping DNA sequences, this cloning method can be applied to any CRISPR vector construction. Most CRISPR cloning schemes use either gene synthesis of the gRNA, type IIS restriction enzymes^17,18, or overlap-extension PCR¹⁹. Each of these techniques has inherent advantages and disadvantages, but they typically require multiple hands-on cloning steps. The primary advantage of the cloning method presented here is that the entire process occurs in a single,...

Materials

Name	Company	Catalog Number	Comments
NEBuilder® (HiFi DNA assembly mix)	New England Biolabs	E5520
p201N:Cas9	Addgene	59175	The p201H:Cas9 plasmid (59176) is also compatible with the reported overlaps and enzymes.
pUC gRNA Shuttle	Addgene	47024
SwaI	New England Biolabs	R0604S
SpeI	New England Biolabs	R0133S
Zymo clean and concentrator-5 column purification	Zymo Research	D4003
NEB Buffer 2.1	New England Biolabs	B7202S
NEB CutSmart (Buffer 4)	New England Biolabs	B7204S
NEB Buffer 3.1	New England Biolabs	B7203S
EconoSpin Mini Spin Column (plasmid prep)	Epoch Life Sciences	1910-050/250
EcoRV-HF®	New England Biolabs	R3195S
StyI-HF®	New England Biolabs	R3500S
MS Salts + Gamborg Vitamins	Phytotechnology Laboratories	M404
Phytagel™ (gellan gum)	Sigma Aldrich	P8169
GA-7 Boxes	Sigma Aldrich	V8505
Micropore™ surgical tape	3M	1535-0
Timentin® (Ticarcillin/Clavulanic acid)	Various	0029-6571-26
Primers 5' → 3'
SwaI_MtU6F	GATATTAATCTCTTCGATGA AATTTATGCCTATCTTATAT GATCAATGAGG
MtU6R	AAGCCTACTGGTTCGCTTG AAG
ScaffoldF	GTTTTAGAGCTAGAAATAGC AAGTT
SpeI_Scaffold R	GTCATGAATTGTAATACGACTC AAAAAAAAGCACCGACTCGGTG
StUbi3P218R	ACATGCACCTAATTTCACTA GATGT
ISceIR	GTGATCGATTACCCTGTTAT CCCTAG	Cannot be used for Sanger sequencing since there is a second binding site on the plasmid
UNS1_Scaffold R	GAGAATGGATGCGAGTAATGAA AAAAAGCACCGACTCGGTG
UNS1_MtU6 F	CATTACTCGCATCCATTCTCAT GCCTATCTTATATGATCAATGAGG
p201R	CGCGCCGAATTCTAGTGATCG
Bolded sequences denote 20-nt overlaps with linearized p201N:Cas9.