Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Heritable Targeted Inactivation of Myostatin Gene in Yellow Catfish (Pelteobagrus fulvidraco) Using Engineered Zinc Finger Nucleases

  • Zhangji Dong ,

    Contributed equally to this work with: Zhangji Dong, Jiachun Ge

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Jiachun Ge ,

    Contributed equally to this work with: Zhangji Dong, Jiachun Ge

    Affiliations Freshwater Fisheries Research Institute of Jiangsu Province, Nanjing, China, College of Life Sciences, Nanjing Normal University, Nanjing, China

  • Kui Li,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Zhiqiang Xu,

    Affiliations Freshwater Fisheries Research Institute of Jiangsu Province, Nanjing, China, College of Life Sciences, Nanjing Normal University, Nanjing, China

  • Dong Liang,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Jingyun Li,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Junbo Li,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Wenshuang Jia,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Yuehua Li,

    Affiliation Freshwater Fisheries Research Institute of Jiangsu Province, Nanjing, China

  • Xiaohua Dong,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Shasha Cao,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Xiaoxiao Wang,

    Affiliation Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China

  • Jianlin Pan,

    Affiliation Freshwater Fisheries Research Institute of Jiangsu Province, Nanjing, China

  • Qingshun Zhao

    qingshun@nju.edu.cn

    Affiliations Model Animal Research Center, MOE Key Laboratory of Model Animal for Disease Study, Nanjing University, Nanjing, China, Zhejiang Provincial Key Lab for Technology and Application of Model Organisms, School of Life Sciences, Wenzhou Medical College, Wenzhou, China

Abstract

Yellow catfish (Pelteobagrus fulvidraco) is one of the most important freshwater aquaculture species in China. However, its small size and lower meat yield limit its edible value. Myostatin (MSTN) is a negative regulator of mammalian muscle growth. But, the function of Mstn in fish remains elusive. To explore roles of mstn gene in fish growth and create a strain of yellow catfish with high amount of muscle mass, we performed targeted disruption of mstn in yellow catfish using engineered zinc-finger nucleases (ZFNs). Employing zebrafish embryos as a screening system to identify ZFN activity, we obtained one pair of ZFNs that can edit mstn in yellow catfish genome. Using the ZFNs, we successfully obtained two founders (Founder July29-7 and Founder July29-8) carrying mutated mstn gene in their germ cells. The mutated mstn allele inherited from Founder July29-7 was a null allele (mstnnju6) containing a 4 bp insertion, predicted to encode function null Mstn. The mutated mstn inherited from Founder July29-8 was a complex type of mutation (mstnnju7), predicted to encode a protein lacking two amino acids in the N-terminal secretory signal of Mstn. Totally, we obtained 6 mstnnju6/+ and 14 mstnnju7/+ yellow catfish. To our best knowledge, this is the first endogenous gene knockout in aquaculture fish. Our result will help in understanding the roles of mstn gene in fish.

Introduction

Yellow catfish (Pelteobagrus fulvidraco Richardson) is a teleost fish belonging to Siluriformes, commonly found in Yangtze River, China. The increasing demand from national and international markets for this delicious freshwater fish promotes it becoming one of the most important freshwater farmed species in China. However, the small size and low amount of muscle mass limit its edible value. Myostatin (MSTN), a member of the transforming growth factor β superfamily, is a negative regulator of mammalian muscle growth [1]. Mstn knockout mice display 2- to 3-fold increase in both myofiber size (hypertrophy) and myofiber number (hyperplasia) than their heterozygous and wild-type littermates [2]. Mammals including cattle, sheep, dog, mouse and human beings with spontaneous mutations in their Mstn gene all exhibit double-muscle phenotype [1]. For example, the Belgian Blue cattle with an 11-bp deletion occurring in the third exon of Mstn that eliminates the entire bioactive domain of the protein exhibits 20–25% more muscle mass than standard breeds due to skeletal muscle hyperplasia [3]. However, no such mutations have been found in other vertebrates including fish [1]. To investigate roles of mstn gene in yellow catfish growth and create a strain of yellow catfish with increased muscle growth, it is necessary to knock out mstn [4] in yellow catfish.

Traditionally, creating a gene knockout animal is solely dependent on the availability of embryonic stem cell lines that have been only established in mouse and rat [5], [6]. Recently, zinc-finger nuclease (ZFN) technology has provided powerful tools for editing genomes of any animals [7]. Employing ZFN technology, researchers have accomplished gene knockout in domesticated animals such as silkworm (Bombyx mori) [8], pig (Sus domestica) [9], [10] and rabbit [11] in addition to model animals including fruit fly (Drosophila melanogaster) [12], zebrafish (Danio rerio) [13], [14], frog (Xenopus tropicalis) [15], mouse [16], [17] and rat [18]. However, no knockout farmed fish has been reported though zebrafish is the first vertebrate animal that its genome was edited with ZFN [13], [14]. In this study, we report targeted disruption of mstn gene in yellow catfish using ZFNs.

Results and Discussion

To knock out mstn gene (DQ767967) in yellow catfish, we designed ZFNs that can cut yellow catfish mstn using the modular assembly method [19], [20], [21]. Totally, two potential target sites and their corresponding ZFN pairs (ZFN1 and ZFN2) were selected (Figure 1A, Table 1). To test the activity of the two pairs of ZFNs, we first co-microinjected the plasmid carrying a genomic DNA fragment of yellow catfish mstn gene containing target site of a ZFN pair with mRNA of the ZFN pair into zebrafish embryos at 1–2-cell stage. Sequencing analyses on the molecules of the yellow catfish mstn gene that were PCR amplified from the microinjected embryos at 24 hpf (hours post fertilization) revealed that 37 of 144 molecules were mutated in ZFN1 co-microinjected embryos. The mutations of the mstn molecules were categorized into three groups including deletions (15 of 37; 40.5%), insertions (20 of 37; 54.1%) and complex type containing both deletions and insertions (2 of 37; 5.4%) (Figure 1B). However, none of 100 molecules were mutated in ZFN2 co-microinjected embryos.

thumbnail
Figure 1. Zebrafish embryos can be used as an in vivo system to examine ZFN activity of editing yellow catfish mstn gene.

(A) Schematic diagram shows ZFN1 binding to the yellow catfish mstn gene. Yellow catfish mstn exons are shown as boxes and its introns are shown as solid lines. Start codon (ATG) and stop codon (TGA) are marked in exon 1 and exon 3, respectively. Number above the exon box denotes the position of nucleotides in the gene [4]. The ZFN1 binding site is in exon 1. The triplets of nucleotides recognized by ZFN1 fingers are marked in different colors. (B) Zebrafish embryos were used as an in vivo system to examine ZFN activity of editing yellow catfish mstn gene. The plasmid containing exon 1 of yellow catfish mstn gene (pGEM-ycMSTN) was co-microinjected with ZFN1 mRNA into zebrafish embryos at 1–2-cell stage. The mstn molecules were amplified from the zebrafish embryos at 24 hpf and then subcloned for sequencing. Analyses on sequences of the molecules revealed that the molecules of disrupted mstn were categorized into three groups including deletions, insertions and complex. (C) ZFN1 cut mstn in yellow catfish genome. ZFN1 mRNA was microinjected into yellow catfish embryos at 1–2-cell stage. The mstn molecules were amplified from the yellow catfish embryos at 72 hpf and then subcloned for sequencing. Analyses on sequences of the molecules revealed that the molecules of disrupted mstn in yellow catfish genome were categorized into three groups including deletions, insertion and complex. WT: partial sequence of wild type mstn containing ZFN1 targeting site (B, C). Number in the leftmost of the panels (B, C) shows the number of nucleotides was deleted (−) or inserted (+) in the mutated mstn gene. Number in the bracket shows the frequency of the mutated molecules (B, C). Inserted nucleotides are bolded (B, C).

https://doi.org/10.1371/journal.pone.0028897.g001

thumbnail
Table 1. Zinc fingers used in ZFN1 (active) and ZFN2 (inactive)*.

https://doi.org/10.1371/journal.pone.0028897.t001

To test whether ZFN1 could cut the mstn gene in yellow catfish genome, we microinjected mRNA of the ZFN pair into animal poles of yellow catfish embryos at 1–2-cell stage. Sequencing analyses on the molecules of the yellow catfish mstn gene that were PCR amplified from the microinjected yellow catfish embryos at 72 hpf revealed that 7 of 288 molecules were mutated. The mutations in yellow catfish mstn were categorized into three groups including deletions (5 of 7; 71.4%), insertion (1 of 7; 14.3%) and complex type containing both deletion and insertion (1 of 7; 14.3%) (Figure 1C). The results demonstrated that ZFN1 has the ability to cut genomic mstn in yellow catfish genome.

To create mstn knockout yellow catfish, we microinjected more than 20,000 yellow catfish embryos at 1-cell stage with ZFN1 mRNA. When the microinjected embryos reached 2 months old, we selected founders that potentially carried mutated mstn alleles in their germ cells by genotyping each juvenile yellow catfish. The general strategy for us to select mstn knockout founders was to genotype all juveniles by sequencing the mstn molecules cloned from their fin genome as described above. Once it was identified to carry disrupted mstn gene in its somatic cells, a juvenile yellow catfish was selected as a founder. However, after analyzing the sequences of all mutated molecules created by ZFN1, we found that the molecule with the 4 bp insertion occurring most frequently (16 of 37; 43.2%) among the mutated molecules amplified from the zebrafish embryos that were used as a testing system was also present in the yellow catfish embryos microinjected with ZFN1 mRNA though at a lower frequency (1 of 7; 14.3%) (Figure 1B, 1C). Because the 4 bp insertion resulted in a null mutation of mstn gene, the yellow catfish carrying this type of mutation in their somatic cells had more chance to possess germ cells carrying the mstn null allele. Moreover, the screening of looking for the 4 bp insertion did not exclude other disruptions such as the other 6 six types of mutations we found (Figure 1C) because the frequency of the 4 bp insertion was only 14.3% of the mutated mstn molecules we detected from the yellow catfish embryos. In other words, a founder yellow catfish carrying the 4 bp insertion in its somatic cells must have many other types of disrupted mstn in its body. Furthermore, we found the 4 bp insertion could be specifically and easily picked out by two rounds of PCR (Figure 2A). Therefore, the strategy of looking for the 4 bp insertion was easier, less laborious, and more economical for us to identify a founder carrying disrupted mstn gene in their genome of somatic cells than the general strategy described above. Performing PCR that could identify the mutated mstn gene with the 4 bp insertion, we obtained 130 juveniles as founders from 577 juveniles examined.

thumbnail
Figure 2. Generation of mstn knockout yellow catfish using engineered zinc finger nucleases.

(A) 7 yellow catfish founders were identified to potentially carry mutated mstn in their germ cells by PCR. Agarose gel electrophoresis revealed that embryos from 7 yellow catfish founders gave out a predicted 186 bp product. The results suggested these fish carried a mutated mstn with the 4 bp insertion in their germ cells. “Wild type” and “Positive” denote the templates used for the 1st round PCR were the genomic DNA isolated from a wild type yellow catfish (negative control) or the mutated mstn molecules with the 4 bp insertion (positive control), respectively. “July21-1, July21-6, July22-3, July22-5, July22-6, July29-7 and July29-8” denote the templates used for the 1st PCR were the genomic DNA isolated from the different founders, respectively. (B) Sequencing chromatography shows the PCR products from two juvenile yellow catfish containing different mutated mstn alleles in their genomes. Arrow heads indicate that the mutated mstn alleles have different sequences from wild type allele stating from the base pointed. (C) Schematic diagram shows two mutated proteins would be produced from the two different strains of yellow catfish carrying different mutated mstn alleles. Mstn: Yellow catfish wild type Mstn comprises a signal sequence (N-terminal secretory signal), a propeptide domain (propeptide) and a bioactive domain (C-terminal domain). RX is a proteolytic site to remove the signal sequence and RXXR is a proteolytic processing site (RSSR) to produce bioactive form of Mstn. The number shows the position of amino acid residue [4]. Mstnnju6: A truncated protein encoded by mstnnju6 contains only the 42 amino acid residues of the N-terminal secretory signal of yellow catfish Mstn plus 5 new amino acid residues. Mstnnju7: A mutated protein encoded by mstnnju7 lacks two amino acid residues between aa37 and aa40 in the N-terminal secretory signal of yellow catfish Mstn.

https://doi.org/10.1371/journal.pone.0028897.g002

When the founder yellow catfish reached 1 year old, 58 of the founders were used for artificial insemination by mixing reproductive cells of each founder yellow catfish with those of a wild type partner. PCR analyses on the embryos (F1) at 72 hpf produced from 31 founders revealed that 7 founders might produce embryos carrying mutated mstn allele (Figure 2A, Table 2). When the remaining offspring from the 7 founders reached 5 weeks old, we started to genotype each juvenile by directly sequencing PCR product amplified from its fin genome with primers specific for amplifying the mstn fragment containing ZFN1 targeting site. The results showed that some of the offspring produced from Founder July29-7 and Founder July29-8 carried mutated mstn gene (Figure 2B). Analyzing the DNA sequences of the molecules subcloned from the PCR product, we found the mutated mstn allele (mstnnju6) inherited from Founder July29-7 contains the 4 bp insertion, a microduplication of GTGA in the spacer (nt+244—+247) of ZFN1 targeting site (Figure 1C), predicted to encode a truncated protein only containing 42 amino acid residues of the N-terminal secretory signal of yellow catfish Mstn (Figure 2C) [4]. The result suggested that the mutated allele with the 4 bp insertion (mstnnju6) is a null allele. However, the mutated mstn (mstnnju7) inherited from Founder July29-8 was a complex type of mutation in which a 9 bp fragment (CAACCCACT, nt+228—+236) was replaced with a 3 bp fragment (ACA), predicted to encode a protein lacking two amino acid residues (aa38 and aa39) in the N-terminal secretory signal of yellow catfish Mstn (Figure 2C) [4]. The result was somehow surprising because the genotypes of the yellow catfish carrying disrupted mstn allele we screened from 156 offspring of Founder July29-8 were all mstnnju7/+ but not mstnnju6/+ though the PCR results from the genome of their sibling embryos at 72 hpf suggested that some of their siblings should carry mstnnju6 allele (Table 2). But, the result that none of the 156 offspring carried mstnnju6 allele is understandable if we consider that the germline transmission rate of mstnnju6 allele could be as low as 0.5% (1/200) (Table 2). Additionally, germ cells and somatic cells of a founder do not necessarily share the same mutagenic genotype because the repair of a double strand break created by ZFN cutting in genomic DNA is an error-prone repair by non-homologous end joining and the repair occurring in the genomes of different cells would come out totally different results [7]. This was also evidenced in our observation that the sequences of most disrupted mstn molecules were unique not only in zebrafish embryos but also in yellow catfish embryos except that two molecules with the same +3 insertion were found in zebrafish embryos and the molecule with the 4 bp insertion were found not only in zebrafish embryos with much higher frequency (43.2%) but also in yellow catfish embryos with lower frequency (14.3%) (Figure 1B, 1C). Therefore, the offspring of Founder July29-8 carrying mstnnju7 is explainable. Totally, we obtained 6 F1 yellow catfish carrying mstnnju6/+ from Founder July29-7 and 14 F1 yellow catfish carrying mstnnju7/+ from Founder July29-8 (Table 2).

thumbnail
Table 2. Summary of the identification of the yellow catfish carrying disrupted mstn.

https://doi.org/10.1371/journal.pone.0028897.t002

In summary, we have created a strain of yellow catfish (Pelteobagrus fulvidraco) (mstnnju6/+) carrying an mstn null allele using ZFNs. To our best knowledge, this is the first endogenous gene knockout in farmed fish. It is known that ZFNs could cause off-target cleavage in organism genome. However, the off-target cutting could be separated from the desired mutation by backcrossing to the parent strain [18]. Therefore, we can obtain mstn null yellow catfish (mstnnju6/nju6) on a wild type background by genetic crossing. Provided we have yellow catfish homologous for mstn null allele (mstnnju6/nju6), we can investigate the roles of mstn gene in muscle growth of yellow catfish. Because Mstn is highly conserved during vertebrate evolution [1] and inhibiting the function of mstn either by knocking down mstn in zebrafish or overexpressing follistatin in trout results in increased growth in zebrafish or trout respectively [22], [23], it is very likely that piscine Mstn functions as a negative regulator of muscle growth like mammalian ones. However, unlike mammals, fish possess two copies of mstn gene or even four copies within salmonids likely due to tetraploidization [1]. To fully understand the roles of mstn gene in yellow catfish, we have to knock out the second mstn gene in yellow catfish. We are now looking for the other mstn gene in yellow catfish by deep sequencing the transcriptome of yellow catfish muscle. Once we find out a duplicated copy of mstn (mstnb) in yellow catfish, we will align its sequence with that of current mstn copy. If both genes share the same or highly similar sequence of ZFN1 target site, we will examine whether ZFN1 can also cut mstnb using the in vivo testing system we established. If ZFN1 can cut mstnb, we will examine the mstn knockout yellow catfish to see whether their mstnb is also disrupted. However, if mstnb is not disrupted in the mstn knockout yellow catfish, we will screen the other 62 founders we generated to look for the yellow catfish inheritably carrying mstnb null allele. If ZFN1 cannot cut mstnb gene, we will knock out the second mstn gene by designing new ZFNs or using the technology of the recently developed TALENs (transcription activator-like effectors nucleases) [24], [25].

Materials and Methods

Ethics statement

This study was approved by the Institutional Animal Care and Use Committee of Model Animal Research Center of Nanjing University under approved protocol (MARC-AP QZ01…Basic Zebrafish Protocol).

Design of zinc finger nuclease targeting myostatin gene in yellow catfish

The ZFNs targeting yellow catfish mstn gene were designed using the modular assembly method [19], [20], [21]. Briefly, nucleotide sequence of the 1st exon containing initiation codon of yellow catfish mstn gene [4] served as an input to search the targeting sites and their corresponding 3-zinc-finger left array and 3-zinc-finger right array using ZiFiT software (ZiFiT:http://zifit.partners.org/) [19], [20], [21]. Selected potential target sites in the yellow catfish mstn gene output from the software were aACCCACTGCCGTGACGGAGGAGCGt (nt+113—+138) (with GNN score 0.59 by 0.59 and affinity score 3.77 by 4.77) and gATTTCTCTGGGCTTCGTGGTGGCTt (+21—+46) (with GNN score 0.59 by 0.00 and affinity score 6.79 by N/A). The fingers in the output from the same modular sources (SGMO or Barbas) were selected to make the 3-zinc-finger arrays of two pairs of ZFNs correspondingly (Table 1). The sequences of 3-zinc-finger arrays were then inserted into the sequences of ZFN backbone [26], [27] to design two pairs of ZFNs (ZFN1 and ZFN2). The designed ZFNs were synthesized and then cloned into plasmids containing nuclear localization signal sequence under T7 promoter direction by a commercial company.

Examination of ZFN activity in zebrafish embryos

The ZFN activity was examined first in zebrafish embryos. To perform the test, we cloned genomic DNA fragment of yellow catfish mstn gene containing 1st exon into pGEM-T easy vector (Promega, USA) with primers CAAGGTGTTCCTGTTCCTGCTG (forward) and TCCTTGCTTGCTGCTATTCTGG (reverse) [4] using the genomic DNA isolated from yellow catfish fin as template. The resulting plasmid (pGEM-ycMSTN) was treated with proteinase K to make it RNase free. We next in vitro synthesized the corresponding mRNA (capped and tailed) of the ZFNs using as templates the ZFN plasmids with mMessage mMachine T7 Ultra Kit (Ambion, USA). The mRNA was then purified using Oligotex mRNA Mini Kit (Qiagen, Germany). The left arm and right arm mRNA of each ZFN pair was then mixed with plasmid pGEM-ycMSTN. The final concentration in the mixture was 200 ng/µl mRNA of each arm and 50 ng/µl of pGEM-ycMSTN. 1 nl of the mixture was microinjected into zebrafish embryos at 1–2-cell stage. The injected embryos were grown at 28.5°C and collected at 24 hpf to extract DNA. The extracted DNA was dissolved in 100 µl water and 1 µl of the DNA solution was then used as template to amplify the mstn fragment containing the potential ZFN targeting site by PCR using primers of GATCCCAAGGTGTTCCTGTT (forward) and CTTGAAGACGGAGCTGCTTG (reverse) in a 20 µl reaction system. The PCR conditions were 94°C for 2 min, 30 cycles of (30 s at 94°C, 30 s at 60°C, and 1 min at 72°C), and a final extension of 6 min at 72°C. The PCR product was then cloned into pGEM-T easy vector (Promega, USA) and transformed into DH5α competent cells. The transformants were randomly selected and identified by PCR as described above. 144 and 100 of the PCR positive transformants were further sequenced for examining activity of ZFN1 and ZFN2, respectively. The sequences were then aligned with the wild type sequence of yellow catfish mstn to determine whether they were mutated.

Artificial insemination of yellow catfish

To obtain fertilized eggs of yellow catfish, we performed artificial insemination on yellow catfish. Two years old yellow catfish living in wild environment or one year old ones living in lab aquarium like zebrafish were used for artificial insemination. To carry out artificial insemination, we executed a first round of injection with 0.3 ml of 0.68% NaCl solution (sterilized) containing 3 µg of LHRH-A2 (Ningbo Sansheng Pharmaceutical Co., Ltd., Ningbo, China) into each female yellow catfish at 9:00 am, then a second round of injection with 0.3 ml of the solution containing 6 µg of LHRH-A2 and 300 IU hCG (Ningbo Sansheng Pharmaceutical Co., Ltd., Ningbo, China) into the same female yellow catfish at 11:00 pm and only one round of injection with 0.2 ml of the solution containing 4 µg of LHRH-A2 and 200 IU hCG into male yellow catfish at 11:00 pm the day before artificial insemination was performed. The injection was performed abdominally under pectoral fin. In the next morning, each injected female fish was examined for the maturity of its eggs. If eggs came out from apertura cloacalis of a female yellow catfish immediately after its abdomen was gently pressed, the eggs were recognized to be good for in vitro fertilization. We then collected the mature eggs by pressing the female yellow catfish hard in the abdomen and placed them into 100 mm culture dishes. Immediately after egg collection, the two entire testes of a male yellow catfish were taken out surgically and minced with scissors thoroughly. 3 ml of 0.69% NaCl was then added to suspend the minced testes. The solution containing sperms was immediately transferred to the dishes containing eggs and mixed thoroughly with the eggs. Shortly after the mixture, the fertilized eggs were dispersed into 100 mm culture dishes filled with aerated water. The eggs were changed with aerated water 1 minute later and were then ready for further experiment.

Examination of ZFN activity in yellow catfish embryos

To test whether the ZFN pair that was able to cut yellow catfish mstn gene in zebrafish embryo system could cut mstn gene in yellow catfish genome, we microinjected 1 nl of the mixture containing 200 ng/µl mRNA of ZFN1 each arm into animal poles of yellow catfish embryos at 1–2-cell stage. The injected embryos were then grown at 28.5°C in the same conditions as zebrafish embryos. When reaching 72 hpf, 40 of the injected embryos were randomly selected to examine mutated mstn in their genomes by using the same procedures as described in the section of “Examination of ZFN activity in zebrafish embryos”. Totally, 288 of the PCR positive transformants were further sequenced for examining ZFN1 activity in yellow catfish embryos.

Generation of heritable targeted inactivation of myostatin gene in yellow catfish

To generate mstn knockout yellow catfish, we first microinjected 1 nl of the mixture containing 200 ng/µl mRNA of ZFN1 each arm into animal poles of yellow catfish embryos at 1-cell stage. We then raised the injected embryos at 28.5°C in the same conditions as growing zebrafish embryos. When the yellow catfish reached 2 months old, a piece of tail fin was clipped from each juvenile and then submerged into 8.8 µl of the Trace DNA Extraction Solution to extract its genomic DNA using Trace DNA Extraction Kit (Nanjing Runbang Bio-tech Company, Nanjing, China). 1 µl of the extracted DNA was then used as PCR template directly to amplify the mstn fragment containing ZFN1 targeting site using the methods as described in the above section of “Examination of ZFN activity in zebrafish embryos” with a modification of reducing the cycle number to 20. A second round PCR was further performed using 1 µl of the 1st round PCR product as template. The sequences of primer pair for the 2nd round PCR were CCAACAGTCCAACAGCTCCTCT (forward) and CGCTTCACGCTCCTCCGTCACTCAC (reverse). The PCR conditions were 94°C for 2 min, 30 cycles of (30 s at 94°C, 30 s at 70°C, and 30 s at 72°C), and a final extension of 5 min at 72°C. The PCR products were then subjected to 1.5% agarose gel electrophoresis separation. The yellow catfish which produced a 186 bp PCR product were selected as founders to grow at 28.5°C in lab aquarium like zebrafish.

After having been raised for 10 months, the founder yellow catfish were transferred into a fishnet set in a wild pond starting from middle May of 2011 when the temperature was above 22°C in Nanjing, China. Two months after they had been raised in the pond, the founder yellow catfish were used for artificiality insemination by mixing reproductive cells of a founder yellow catfish with those of a wild type partner collected from local market. To test whether offspring (F1) of the founders contained mutated mstn gene, 80 to 200 embryos at 72 hpf produced from each founder were randomly selected for genotyping. Briefly, each 10 embryos were grouped to submerge into 88 µl of the Trace DNA Extraction Solution for extracting their genomic DNA using Trace DNA Extraction Kit (Nanjing Runbang Bio-tech Company, Nanjing, China). The extracted DNA was then used as PCR template to perform two rounds of PCR as described above. Once the embryos gave a PCR product sized 186 bp in the gel electrophoresis, the remaining F1 yellow catfish from the founder were raised in lab aquarium in the way similar to growing zebrafish for further screening.

When the offspring reached 5 weeks old, the tail fin of each F1 was clipped to amplify the mstn fragment containing ZFN1 targeting site as described above. The PCR product from each F1 was then subjected to sequence directly. The PCR product with mutated mstn molecules revealed by the sequencing chromatography was further subcloned to identify exact genotype for the individual F1. The F1 yellow catfish with mutated mstn gene were grown in lab aquarium in the way similar to growing zebrafish.

Acknowledgments

The authors thank Dr. Xingxu Huang and Mr. Yinan Du for thoughtful suggestions and technical help on the project.

Author Contributions

Conceived and designed the experiments: QZ ZD. Performed the experiments: ZD JG KL ZX DL JYL JBL WJ YHL XD SC XW JP. Analyzed the data: QZ ZD. Wrote the paper: QZ DJ.

References

  1. 1. Stinckens A, Georges M, Buys N (2011) Mutations in the myostatin gene leading to hypermuscularity in mammals: indications for a similar mechanism in fish? Anim Genet 42: 229–234.
  2. 2. McPherron AC, Lawler AM, Lee S-J (1997) Regulation of skeletal muscle mass in mice by a new TGF-β superfamily member. Nature 387: 83–90.
  3. 3. Grobet L, Martin LJR, Poncelet D, Pirottin D, Brouwers B, et al. (1997) A deletion in the bovine myostatin gene causes the double-muscled phenotype in cattle. Nat Genet 17: 71–74.
  4. 4. Pan J, Wang X, Song W, Chen J, Li C, et al. (2007) Molecular cloning and expression pattern of myostatin gene in yellow catfish (Pelteobagrus fulvidraco). DNA Seq 18: 279–287.
  5. 5. Capecchi MR (2005) Gene targeting in mice: functional analysis of the mammalian genome for the twenty-first century. Nat Rev Genet 6: 507–512.
  6. 6. Tong C, Li P, Wu NL, Yan Y, Ying QL (2010) Production of p53 gene knockout rats by homologous recombination in embryonic stem cells. Nature 467: 211–213.
  7. 7. Carroll D (2011) Genome engineering with zinc-finger nucleases. Genetics 188: 773–782.
  8. 8. Takasu Y, Kobayashi I, Beumer K, Uchino K, Sezutsu H, et al. (2010) Targeted mutagenesis in the silkworm Bombyx mori using zinc finger nuclease mRNA injection. Insect Biochem Mol Biol 40: 759–765.
  9. 9. Yang D, Yang H, Li W, Zhao B, Ouyang Z, et al. (2011) Generation of PPARγ mono-allelic knockout pigs via zinc-finger nucleases and nuclear transfer cloning. Cell Res 21: 979–982.
  10. 10. Hauschild J, Petersen B, Santiago Y, Queisser A-L, Carnwath JW, et al. (2011) Efficient generation of a biallelic knockout in pigs using zinc-finger nucleases. Proc Natl Acad Sci U S A 108: 12013–12017.
  11. 11. Flisikowska T, Thorey IS, Offner S, Ros F, Lifke V, et al. (2011) Efficient immunoglobulin gene disruption and targeted replacement in rabbit using zinc finger nucleases. PLoS ONE 6: e21045.
  12. 12. Bibikova M, Golic M, Golic KG, Carroll D (2002) Targeted chromosomal cleavage and mutagenesis in Drosophila using zinc-finger nucleases. Genetics 161: 1169–1175.
  13. 13. Doyon Y, McCammon JM, Miller JC, Faraji F, Ngo C, et al. (2008) Heritable targeted gene disruption in zebrafish using designed zinc-finger nucleases. Nat Biotechnol 26: 702–708.
  14. 14. Meng X, Noyes MB, Zhu LJ, Lawson ND, Wolfe SA (2008) Targeted gene inactivation in zebrafish using engineered zinc-finger nucleases. Nat Biotechnol 26: 695–701.
  15. 15. Young JJ, Cherone JM, Doyon Y, Ankoudinova I, Faraji FM, et al. (2011) Efficient targeted gene disruption in the soma and germ line of the frog Xenopus tropicalis using engineered zinc-finger nucleases. Proc Natl Acad Sci U S A 108: 7052–7057.
  16. 16. Carbery ID, Ji D, Harrington A, Brown V, Weinstein EJ, et al. (2010) Targeted genome modification in mice using zinc-finger nucleases. Genetics 186: 451–459.
  17. 17. Meyer M, de Angelis MH, Wurst W, Kuhn R (2010) Gene targeting by homologous recombination in mouse zygotes mediated by zinc-finger nucleases. Proc Natl Acad Sci U S A 107: 15022–15026.
  18. 18. Geurts AM, Cost GJ, Freyvert Y, Zeitler B, Miller JC, et al. (2009) Knockout rats via embryo microinjection of zinc-finger nucleases. Science 325: 433.
  19. 19. Wright DA, Thibodeau-Beganny S, Sander JD, Winfrey RJ, Hirsh AS, et al. (2006) Standardized reagents and protocols for engineering zinc finger nucleases by modular assembly. Nat Protoc 1: 1637–1652.
  20. 20. Sander JD, Zaback P, Joung JK, Voytas DF, Dobbs D (2007) Zinc Finger Targeter (ZiFiT): an engineered zinc finger/target site design tool. Nucleic Acids Res 35: W599–605.
  21. 21. Sander JD, Maeder ML, Reyon D, Voytas DF, Joung JK, et al. (2010) ZiFiT (Zinc Finger Targeter): an updated zinc finger engineering tool. Nucleic Acids Res 38: W462–468.
  22. 22. Lee C-Y, Hu S-Y, Gong H-Y, Chen MH-C, Lu J-K, et al. (2009) Suppression of myostatin with vector-based RNA interference causes a double-muscle effect in transgenic zebrafish. Biochem Biophys Res Commun 387: 766–771.
  23. 23. Medeiros EF, Phelps MP, Fuentes FD, Bradley TM (2009) Overexpression of follistatin in trout stimulates increased muscling. Am J Physiol Regul Integr Comp Physiol 297: R235–242.
  24. 24. Huang P, Xiao A, Zhou M, Zhu Z, Lin S, et al. (2011) Heritable gene targeting in zebrafish using customized TALENs. Nat Biotechnol 29: 699–700.
  25. 25. Tesson L, Usal C, Menoret S, Leung E, Niles BJ, et al. (2011) Knockout rats generated by embryo microinjection of TALENs. Nat Biotechnol 29: 695–696.
  26. 26. Mandell JG, Barbas CF III (2006) Zinc Finger Tools: custom DNA-binding domains for transcription factors and nucleases. Nucleic Acids Res 34: W516–523.
  27. 27. Miller JC, Holmes MC, Wang J, Guschin DY, Lee YL, et al. (2007) An improved zinc-finger nuclease architecture for highly specific genome editing. Nat Biotechnol 25: 778–785.