Rapid Deletion Production in Fungi via Agrobacterium Mediated Transformation of OSCAR Deletion Constructs

Podsumowanie

Gene deletion mutants generated through homologous recombination are the gold standard for gene function studies. The OSCAR (One Step Construction of Agrobacterium-Recombination-ready-plasmids) method for rapid generation of deletion constructs is described. Agrobacterium mediated fungal transformation follows. Finally, a PCR based confirmation method of gene deletions in fungal transformants is presented.

Streszczenie

Precise deletion of gene(s) of interest, while leaving the rest of the genome unchanged, provides the ideal product to determine that particular gene's function in the living organism. In this protocol the OSCAR method of precise and rapid deletion plasmid construction is described. OSCAR relies on the cloning system in which a single recombinase reaction is carried out containing the purified PCR-amplified 5' and 3' flanks of the gene of interest and two plasmids, pA-Hyg OSCAR (the marker vector) and pOSCAR (the assembly vector). Confirmation of the correctly assembled deletion vector is carried out by restriction digestion mapping followed by sequencing. Agrobacterium tumefaciens is then used to mediate introduction of the deletion construct into fungal spores (referred to as ATMT). Finally, a PCR assay is described to determine if the deletion construct integrated by homologous or non-homologous recombination, indicating gene deletion or ectopic integration, respectively. This approach has been successfully used for deletion of numerous genes in Verticillium dahliae and in Fusarium verticillioides among other species.

Wprowadzenie

Genetic dissection is a powerful methodology for determining the functional importance of individual or combinations of genes. A standard approach to understand the role of specific genes is production of single gene mutants unaltered in any other gene. The most powerful and least potentially confounding approach is complete and precise deletion of a gene of interest's open reading frame (GOI ORF) without damage to any other gene function.

Because standard ligation approaches for deletion plasmid generation require multiple steps, the rational for OSCAR¹ was to produce a more rapid in vitro approach. Figure 1 depicts the assembly process in the OSCAR approach. The method described here has the advantage of combining rapid construction of individual gene deletion vectors in a single multipart reaction in combination with subsequent Agrobacterium tumefaciens mediated transformation (ATMT). OSCAR is very rapid and compares well with other strategies such as use of Gibson assembly in yeast². The OSCAR method has been used successfully with several Ascomycota species of fungi. These species include: Fusarium verticillioides (unpublished), Verticillium dahliae³, Setosphaeria turcica⁴, Metarhizium robertsii⁵, Fusarium oxysporum f. sp. vasinfectum⁶, Pestalotiopsis microspora⁷, Colletotrichum higginsianum⁸, and Dothistroma septosporum⁹ and Sarocladium zeae (unpublished).

This protocol provides step-by-step instruction for the method including primer design, flank PCR amplification, the OSCAR BP reaction, deletion construct structure confirmation, transformation of Agrobacterium with the construct followed by ATMT based transfer of the deletion construct into the fungal cells, and finally differentiating fungal deletion mutants from those with ectopically integrated deletion constructs.

Protokół

1. Primer Design for PCR Amplification of Gene Flanks

1. Download to a word processing file the genomic region of the gene of interest (GOI) including the open reading frame (ORF) and at least 2 kb flanking the gene on each side from FungiDB or other genomic data resource.
2. Highlight the ORF intended for deletion and label start and stop codons.
3. Identify and highlight adjacent ORFs within the downloaded sequence.
4. Use the 2 kb 5' end of the GOI ORF and the primer design tool (see Materials List) to design PCR primer pair O1 and O2 to generate a minimum size product of 1 kb. Take care to not impact adjacent ORFs.
   1. Paste the 2 kb 5' flank into the "Sequence Entry" window. Click on "Show Custom Parameters" box. Enter the following custom design parameters: primer TM 58 (min), 60 (opt) and 62 (max); Primer GC 40 (min), 50 (opt) and 60 (max); Primer Size 22 (min), 24 (opt) and 26 (max); Amplicon Size 1250 (min), 1500 (opt) and 2000 (max).
   2. Choose the result that places the reverse primer (O2) closest to the ORF. Capture a screen shot of the assays and copy and paste the primer sequences into the word processing document.
   3. Repeat the process for 3' flank to generate primers O3 and O4, this time choose the result placing the forward primer (O3) closest to the target ORF.
5. Add appropriate attach sites to 5' ends of primers 1 through 4 (see Table 1).
6. Also design and order ORF specific primers to be used for deletion confirmation in section 4 below. Parameters should be the same as in step 1.4.1 except use Amplicon Size 500 (min), 750 (opt) and 1000 (max) adjusting for length of ORF if necessary. Finally, for confirmation of homologous recombinants, generate 5' out and 3' out primers found just outside the flanks within the chromosome. These "out" primers will be used with hygR (210) and hygF (850), respectively (Fig 2).
7. Order primers.

2. Production of OSCAR Constructs

1. Using a hi-fidelity Taq, carry out two reactions, one each for the 5' and 3' flanks, using primers (100 µM) O1 and O2 in one reaction and primers O3 and O4 in the second. Reaction mixture contains the following: 29.5 µL sterile distilled water (SDW), 5 µL 10x LA PCR buffer, 8 µL 2.5 mM dNTP mix, 5 µL 25 mM MgCl₂, 1 µL template (50 ng/µL), 0.5 µL hi-fidelity Taq, 0.5 µL Primer O1 and 0.5 µL Primer O2 for 5' flank (or 0.5 µL Primer O3 and 0.5 µL Primer O4 for 3' flank) Use reaction conditions are as follows: 94 °C for 1 min, then 30 cycles of 94 °C for 30 s, 60 °C for 30 s, 72 °C for 2 min, then final steps of 72 °C for 5 min and then hold indefinitely at 10 °C.
2. Run 0.8% agarose 1x TAE (40 mM Tris acetate pH 8.3, 1 mM EDTA) gel electrophoresis for approximately 125 Vh in a standard minigel apparatus to determine product size and relative concentration. Post stain the gel with non-ethidium stain according to the manufacturer instructions. Visualize on a UV illuminator.
3. If 5' and 3' flank products are in roughly even concentration, combine them and use an affinity column kit (or PEG precipitation 90 µL combined PCR products, 240 µL TE buffer pH 7.5, 160 µL of 30% polyethylene glycol PEG8000 30 mM MgCl₂) to co-purify the PCR products according to the manufacturer's protocol. If they are not of equal concentration combine all of low concentration product with an estimated equal amount of product from the higher yield reaction.
4. Use a spectrophotometer to measure purified DNA concentration.
5. Carry out BP reaction by mixing the following: 1 µL of 60 ng/µL pOSCAR, 2 µL of 60 ng/µL pA-Hyg-OSCAR, 1 µL of 60 ng/µL combined flanks, 1 µL of clonase. Incubate for 16 h at 25 °C. Terminate the reaction by adding 0.5 µL proteinase K and incubate for 10 min at 37 °C.
6. Transform high competence E. coli cells. Both commercially available competent cells and home-made DH5α CaCl₂ competent cells were used successfully as recipients as described by the manufacturer's instructions. Plate on low sodium (0.5 g/L NaCl) LB containing 100 µg/mL spectinomycin (Spec).
7. Identify the correct construct by performing DNA minipreps¹⁰ of colonies generated above. Perform double digestion with HindIII and KpnI as follows: pipette 5 µL DNA, 2 U of each enzyme, 2 µL appropriate 10x buffer with SDW to a 20 µL total volume. This releases the insert (approximately 4.5 kb with 1.5 kb gene flanks) from the vector (ca. 7 kb) and cuts any sites in flanks which can give predictable band sizes.
8. Sequence¹¹ select clones showing an appropriate banding pattern.

3. Agrobacterium tumefaciens Mediated Transformation (ATMT) of Fungi

1. Transform Agrobacterium tumefaciens strain AGL1 with OSCAR deletion construct¹².
2. Transform fungus with AGL1 containing the GOI OSCAR deletion plasmid. To do this carry out the following steps:
   1. Prepare a fungal spore suspension with sterile water at 2 x 10⁶ spores/mL. Quantify spores on a hemocytometer or automated cell counter. Place 500 µL of this in a 1.5 mL microcentrifuge tube. This set up is for 4 transformation plates.
   2. Use a blue sterile disposable loop to add an easily visible gob (should cover about 20% of the loop diameter) of the deletion plasmid containing AGL1 from 2-3 day old LB-Spec 100 medium (see Materials List for composition) containing plates and mix into the spore suspension. Vortex till bacterial cells are well dispersed (ca. 5 min medium speed).
   3. Pipette 100 µL of the conidia-Agro suspension onto the center of a cellulose membrane filter placed on each of four 6 cm Petri dishes containing co-cultivation medium¹².
   4. Spread the suspension with sterile glass beads (about 4) to cover the whole surface of the membrane filter. Alternatively spread the suspension using a traditional spreader tool. Allow the membrane filter to dry in a hood for approximately 10 min, wrap with paraffin film. Repeat steps 3.2.2 and 3.2.3 to set up multiple transformations.
   5. Incubate the plate for 2 days at room temperature, inverted.
   6. Transfer the membrane filter onto 6 cm Aspergillus selection medium¹² plates containing hygromycin B (Hyg) 150 µg/mL, 200 mM cefotaxime and 100 µg/mL moxalactam. Incubate at room temperature for 5-7 days before isolating Hyg resistant colonies.
   7. With sterile toothpicks, transfer putative transformants onto 6 cm Potato Dextrose Agar (PDA) plates containing 150 µg/mL Hyg, 100 µg/mL kanamycin.

4. Deletion Mutant Identification by PCR

1. Extract DNA for PCR from transformants by thermolysis¹³.
   1. Once transformants form colonies on the PDA from step 3.2.7, use a sterile toothpick to transfer a small amount (2 mm x 2 mm) of mycelium or yeast cells from the colony into 100 µL of lysis solution (50 mM sodium phosphate, pH 7.4, 1 mM EDTA, 5% glycerol) in a microcentrifuge tube.
   2. Incubate the mixture at 85-90 °C for 20-30 min. Store the crude extract containing genomic DNA at -20 °C until use in step 4.2.
2. Carry out 4 PCR reactions per transformant, one each to detect homologous recombination of the 5' and 3' flanks, respectively, one for the selectable marker (hygromycin phosphotransferase in this case) and one for the GOI ORF.
   NOTE: We generally use inexpensive low-fidelity Taq for these reactions. Reaction conditions are as described in step 2.1 above and contain SDW 20 µL, 10x Taq buffer 2.5 µL, dNTPS (10 mM) 0.5 µL, homemade Taq¹⁴, 0.5 µL, Primer A (100 µM) 0.5 µL, Primer B (100 µM) 0.5 µL, Template 0.5 µL. Lower concentration primer stocks (10 µM) can be used equally well.
3. Run an agarose gel (e.g. 0.8%) of the PCR products. Deletion mutants will produce the Hyg band but not an ORF product. Ectopic integrants will show both bands. Wild type will produce only the ORF band.
4. Permanently store deletion mutants (and an ectopic transformant or two for controls) for future use.
   NOTE: 15% glycerol is used to store our strains long-term at -80 °C.

Wyniki

The OSCAR method, in a single reaction, generates a plasmid containing the flanks of the target gene to be deleted surrounding the selectable marker cassette. The production of deletion constructs using OSCAR is very efficient. The system can, however, produce partial constructs containing some but not all three fragments (the two gene flanks and the selectable marker). Generally, the majority of E. coli transformants contain the correct OSCAR construct. For example, Figu...

Dyskusje

One Step Construction of Agrobacterium-Recombination-ready-plasmids (OSCAR) has been successfully employed with an ever-increasing number of Ascomycota fungi. The method should also easily be applicable to the Basidiomycota and species from other fungal phyla (with appropriate promoters driving selectable marker genes), assuming Agrobacterium mediated transformation and homologous recombination are possible. Additional marker vectors have been generated to diversify choices of anti-fungal compound as we...

Materiały

Name	Company	Catalog Number	Comments
FungiDB			Database/ http://fungidb.org/fungidb/
IDT PrimerQuest	IDT		Primer design online software/ http://www.idtdna.com/Primerquest/Home/Index
Microsoft Word			Sequence file manipulation
Low Na LB Spec 100 medium			E. coli transformant selection, composition: 1% tryptone, 0.05% NaCl, 0.5% yeast extract, 1.5% agar if for solid medium
Co-cultivation medium			ATMT transformation induction (Reference 12)
Aspergillus minimal medium with Hygromycin			Fungal transformant selection
PDA medium	Acumedia	7149A	Single spore slant tubes
PDA-Hyg-Kan medium			Fungal ransformant isolation, PDA containing 150 μg/mL hygromycin B and 100 μg/mL Kanamycin
Glass beads	Genlantis	C400100	Plate spreading
Nitrocellulose filters (47 mm)	Fisher	09-719-555	Co-culturing for ATMT
Various centifuge tubes			multiple preps
Petri plates (various)			Culturing of bacteria and Fungi
pA-Hyg OSCAR	Addgene	29640	Selectable marker vector
pOSCAR	Addgene	29639	Assembly vector
DH5α One Shot Competent E. coli cells	Life Technologies	12297-016	BP reaction transformation
ccdB survival E. coli cells	Life Technologies	A10460	Maintenance of pOSCAR
Wooden transfer sticks			Colony streaking
Toothpicks			Colony picking
Microcentrifuge			Pelleting Bacteria, etc.
Preparative centrifuge			Fungal spore collection
Dissecting microscope			Single spore isolation
Automated Cell Counter			Spore suspension calculation
Compound microscope			Hemocytometer cell counting
QIAquick PCR Purification Kit	Qiagen	28104	PCR gene flank produict purification
TaKaRa LA Taq	Takara Bio USA	RR002A	Hi Fidelity taq polymerase for OSCAR flank generation
Hygromycin B	InvivoGen	ant-hg-5
Spectinomycin	Sigma	22189-32-8
Cefotaxime	TCI America	C2224
Kanamycin		11815032
Moxalactam	Sigma-Aldrich	43963
GelRed	Phenix Research Products	RGB-4103	Post staining agarose gels
Qiagen QIAquick PCR Purification Kit (Cat. No. 28104)
(OneShot_ Mach1TM T1R or One Shot_ OmniMAX™ 2 T1R from Invitrogen)	Thermo Fisher Scientific	C862003
Gateway BP Clonase II Enzyme mix	Thermo Fisher Scientific	11789020	Used to assemble deletion construct in pOSAR