- Email: [email protected]
Cas9
Accepted Manuscript Establishing targeted carp TLR22 gene disruption via homologous recombination using CRISPR/Cas9 Vemulawada Chakrapani, Swagat Kumar Patra, Rudra Prasanna Panda, Kiran Dashrath Rasal, Pallipuram Jayasankar, Hirak Kumar Barman PII:
S0145-305X(16)30126-4
DOI:
10.1016/j.dci.2016.04.009
Reference:
DCI 2613
To appear in:
Developmental and Comparative Immunology
Received Date: 29 February 2016 Revised Date:
8 April 2016
Accepted Date: 8 April 2016
Please cite this article as: Chakrapani, V., Patra, S.K., Panda, R.P., Rasal, K.D., Jayasankar, P., Barman, H.K., Establishing targeted carp TLR22 gene disruption via homologous recombination using CRISPR/Cas9, Developmental and Comparative Immunology (2016), doi: 10.1016/j.dci.2016.04.009. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT 1 2 3
Short Communication
4 5 6 7
Establishing targeted carp TLR22 gene disruption via homologous recombination using CRISPR/Cas9
8
Dashrath Rasal, Pallipuram Jayasankar, Hirak Kumar Barman*
RI PT
Vemulawada Chakrapani, Swagat Kumar Patra, Rudra Prasanna Panda, Kiran
9 10
Fish Genetics and Biotechnology Division, ICAR - Central Institute of Freshwater
12
Aquaculture, Bhubaneswar 751 002, Odisha, India
14 15
*Corresponding Author: Hirak Kumar Barman, PhD
M AN U
13
SC
11
TE D
E-mail: [email protected]; [email protected] Tel: +916742465407; +916742465414
AC C
16
EP
Fax:+916742465407.
1
ACCEPTED MANUSCRIPT Abstract
18
Recent advances in gene editing techniques have not been exploited in farmed fishes. We
19
established a gene targeting technique, using the CRISPR/Cas9 system in Labeo rohita, a
20
farmed carp (known as rohu). We demonstrated that donor DNA was integrated via
21
homologous recombination (HR) at the site of targeted double-stranded nicks created by
22
CRISPR/Cas9 nuclease. This resulted in the successful disruption of rohu Toll-like receptor
23
22 (TLR22) gene, involved in innate immunity and exclusively present in teleost fishes and
24
amphibians. The null mutant, thus, generated lacked TLR22 mRNA expression. Altogether,
25
this is the first evidence that the CRISPR/Cas9 system is a highly efficient tool for targeted
26
gene disruption via HR in teleosts for generating model large-bodied farmed fishes.
SC
RI PT
17
Keywords:
29
CarpTLR22
30
Gene editing
31
CRISPR/Cas9
32
Microinjection
33
Homologous recombination
EP AC C
34
TE D
28
M AN U
27
2
ACCEPTED MANUSCRIPT 35
1. Introduction Toll-like receptors (TLRs) are major players for innate immunity (Baoprasertkul et
37
al., 2007; Oshiumi et al., 2008; Panda et al., 2014). The TLRs are type 1 integral membrane
38
glycoproteins, having leucine-rich repeat (LRR) domains in their extracellular regions for
39
binding pathogen associated molecular patterns (PAMPs) and a Toll-interleukin-1 receptor
40
domain (TIR), which transmits downstream signals into the cytosol by recruiting and
41
activating a cascade of adaptor molecules (Akira, 2009; Panda et al., 2014). Together, the
42
extracellular LRR domains constitute a horse-shoe shape and, mainly, act as pathogen
43
recognition receptors (PRRs). In teleost fishes, most TLRs were identified as orthologs of
44
mammalian TLRs (Byadgi et al., 2014; Reyes-Becerril et al., 2015). However, TLR5,
45
TLR14, TLR19, TLR20, TLR21 and TLR22 are exclusively present in fish species (Aoki et
46
al., 2008; Rebl et al., 2007; Reyes-Becerril et al., 2015) and, hence, are likely to play
47
distinctive roles. Among these, TLR22 has been studied extensively in teleosts and
48
amphibians (Ishii et al., 2007; Panda et al., 2014; Rebl et al., 2007; Reyes-Becerril et al.,
49
2015; Roach et al., 2005; Samanta et al., 2014). It is present on the cell surface membrane
50
and can recognize viral nucleic acids on the cell surface to transmit signals to induce
51
cytokines (Aoki et al., 2008; Panda et al., 2014; Rebl et al., 2007). Recently, we cloned and
52
characterized the TLR22 gene (Database ID: KC953874) in Labeo rohita (popularly known
53
as rohu), a commercially important farmed carp species (Barman et al., 2003; Barman et al.,
54
2011; Panda et al., 2011).
55
profiling, provided the clue that it confers resistance against wide range of viral, bacterial
56
and lice infections (Panda et al., 2014; Reyes-Becerril et al., 2015; Samanta et al., 2014).
TE D
M AN U
SC
RI PT
36
EP
Documented evidences, based on mRNA/protein expression
Elucidation of exact immune-related mechanistic pathways has been made possible by
58
establishing model animals to target disruption/integration of the selected gene. For example,
59
the exact functions of TLRs, including other down regulated genes in mammals, were
60
determined mainly by knock-out mice analysis (Alexopoulou et al., 2002; Zhang et al., 2007).
61
Such knock-out models are lacking in teleost species (Schartl, 2014). Since the TLR22 gene
62
is teleost-specific and targeting this gene in carp would be useful to enrich knowledge about
63
defense mechanisms. This should have a larger impact on the progress of exploring molecular
64
functions and its involvements in disease and host defense.
AC C
57
65
Gene targeting by homologous recombination (HR) was made possible with
66
mammalian embryonic stem (ES) cells and selective somatic chicken DT40 cell line (Barman
67
et al., 2006; Barman et al., 2008; Sanematsu et al., 2006). In fish, such targeting efficient ES 3
ACCEPTED MANUSCRIPT cell or somatic cells are not available, impeding research progress in physiological or
69
immunological pathways. The discovery of zinc-finger nucleases (ZFNs) based technology
70
brought revolutionary change to gene editing/targeting in the predetermined position in the
71
genome of wide ranging species, including cell lines (Klug, 2010). More recently, sequence-
72
specific nuclease tools, such as ‘Transcription Activator-Like Effector Nucleases (TALENs)’
73
and ‘Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)-associated
74
nucleases (Cas9)’ have impressively extended the genome editing possibilities in model
75
organisms, including zebrafish and several cell lines (Auer et al., 2014; Bachu et al., 2015;
76
Gaj et al., 2013; Hockemeyer et al., 2011; Sanjana et al., 2012; Tatsumi et al., 2014; Wang et
77
al., 2015; Wang et al., 2013; Yang et al., 2014a). Both systems have recently been used to
78
create knock-out allele efficienctly. Also,both the tools have been successfully employed in
79
knock-in of DNA cassettes at defined loci via HR repair mechanism (Auer et al., 2014;
80
Choulika et al., 1995; Sadelain et al., 2012).
M AN U
SC
RI PT
68
These nucleases are efficient in generating double-strand breaks within the precise
82
locus in the genome that can be repaired by error-prone nonhomologous end joining leading
83
to a functional knock-out of the targeted gene and can be used to integrate a foreign DNA
84
sequence at a specific locus through homologous recombination. The Cas9 system has been
85
shown to be most efficient in the generation genetically modified mice, rats, rabbits,
86
zebrafish, medaka, atlantic salmon frog and tilapia (Auer et al., 2014; Edvardsen et al., 2014;
87
Li et al., 2013; Li et al., 2014; Qiu et al., 2014; Wang et al., 2015; Wang H et al., 2013; Yang
88
et al., 2014a).
TE D
81
Fish generally have some inherent advantages for genetic engineering research,
90
including enormous brood and in vitro fertilization, and ease of operation and observation.
91
Even in such a scenario, recent advancements of genome editing technologies have not been
92
fully implemented, which has limited research on in vivo gene function. HR mediated gene
93
disruption is only limited to the model zebrafish (Zu et al., 2013). In this study, we
94
successfully disrupted the LrTLR22 gene by enforcing HR mediated repair of double
95
stranded nicks created by the Cas9 nuclease.
AC C
EP
89
96 97 98 99 100 101 4
ACCEPTED MANUSCRIPT 102
2. Materials and methods
103 104
2.1. Fish and breeding Labeo rohita (rohu) were collected from the farm of the ICAR-Central Institute of
106
Freshwater Aquaculture, Bhubaneswar, Odisha, India. In vitro fertilization was performed in
107
the hatchery, following the induced breeding protocol, using the ovaprim hormone as
108
described by Mahapatra et al., (2006).
109 110
2.2. Total RNA/genomic DNA extraction and cDNA preparation
RI PT
105
Total RNA was extracted using the TRIzol reagent (Invitrogen, USA) following an
112
established protocol (Mohanta et al., 2014b; Panda et al., 2014; Patra et al., 2015). The
113
extracted RNAs were purified and quantified as per standard protocol. The reverse
114
transcriptase cDNA synthesis kit (Clontech, USA) was used to reverse transcribed RNA into
115
cDNA (Mohanta et al., 2014b; Panda et al., 2011; Patra et al., 2015). Genomic DNA was
116
isolated by standard phenol–chloroform extraction and ethanol precipitation methods
117
(Mohanta et al., 2014a; Panda et al., 2014; Patra et al., 2015).
M AN U
SC
111
118
2.3. Construction of Cas9 Smart Nuclease targeting vector with gene specific guide RNA
TE D
119
The extracellular pathogen recognition site i.e. LRR of LrTLR22 (Panda et al., 2014)
121
was chosen as an unique target site, and accordingly the guide RNA (gRNA) oligonucleotides
122
were cloned into CRISPR-Cas9 vector named as EF1-hspCas9-H1-gRNA linearized
123
SmartNuclease vector (Cat. No. CAS900A-1, SBI, USA) as per manufacturer’s guidelines.
124
Briefly, the PAM sequence (5’-CGG-3’) immediately followed the 20 bp target sequence (5’-
125
GTCTGAAGACAACTCGATCC-3’), spanning 1836 to 1858 bases of LRR domain of
126
LrTLR22 (Database ID: KC953874). The possible off-target sites were scanned with the help
127
of online tools, such as CHOPCHOP (https://chopchop.rc.fas.harvard.edu/), ZiFiT Targeter
128
(http://zifi t.partners.org/ZiFiT/) and CRISPRdirect (http://crispr.dbcls.jp/). The structure of
129
double stranded gRNA oligonucleotides contained desirable overhangs at 5’-termini (as
130
shown in Fig. 1). The oligonucleotides were annealed by incubating at 95oC for 5 min to
131
form a duplex. Subsequently, the duplex was ligated with the linearized CRISPR-Cas9 vector
132
containing H1 polymerase III promoter as depicted in Fig. S1. The ligated products were
133
transformed into the One Shot TOP10 chemically competent E. coli (Invitrogen, USA). The
134
positive clones were screened and plasmid DNA (hereafter, known as LrTLR22Cas9) was
135
extracted using QIAprep Spin Miniprep Kit (Qiagen, Germany).
AC C
EP
120
5
ACCEPTED MANUSCRIPT 136 137
2.4. Construction of donor HR vector with homology arms of targeted site Two homology arms of LrTLR22 surrounding the gRNA target site were cloned into
139
donor HR targeting vector (Cat. No. HR100PA-1, SBI, USA), containing a red fluorescence
140
protein (RFP) reporter gene expression cassette. Briefly, respective modified primer sets were
141
designed/synthesized with required restriction enzyme sites (Table S1) compatible with the
142
HR vector. Homology arms were PCR-amplified (using Advantage polymerase, Clontech,
143
USA) from LrTLR22 cDNA, restriction digested and purified by gel extraction, using
144
NucleoSpin Extract II, MN, Germany. The purified PCR products were ligated using Ligate-
145
IT Rapid Ligation kit, USB, USA, into restriction digested HR vector within respective
146
multiple cloning sites I and II, one-by-one following established protocols described by
147
(Barman et al., 2010; Mohanta et al., 2014a; Mohapatra and Barman, 2014; Mohapatra et al.,
148
2014). The ligated DNA products were transformed into One Shot TOP10 chemically
149
competent E. coli (Invitrogen, USA). The plasmids of screened clones were extracted by
150
using Qiagen plasmid kit (Qiagen, USA).
M AN U
SC
RI PT
138
To examine the targeted mutagenesis as well as integration, genomic DNA, from
152
experimental and control fishes, were PCR-amplified to obtain either surrounding the target
153
site or the full length TLR22 gene, using primers as depicted in Table S1. The resulting PCR
154
products were bi-directionally sequenced as described by (Mohapatra et al., 2010; Panda et
155
al., 2014; Patra et al., 2015). The targeted integration should yield new restriction enzyme
156
sites, not as that of wild-type sequences. Hence, the DNA sequence information, including
157
orientations of donor HR vector (hereafter, known as LrTLR22HR) were confirmed/judged
158
by the restriction mapping followed by repeated both-directional sequencing.
EP
TE D
151
160 161
AC C
159
2.5 Microinjection of rohu embryos LrTLR22Cas9 (33.3 pg) and linearized (ScaI digested) LrTLR22HR (66.3 pg) DNA
162
constructs t were co-injected into rohu embryos at 1- to 4-cell stage as described (Gong et al.,
163
2003; Ju et al., 1999) at a total concentration of 100 pg/µl/embryo using CellTram micro-
164
injector (Eppendorf, Germany). Injected embryos along with controls were reared in 70%
165
natural pond water containing 1% penicillin/streptomycin. After 6 days of post-fertilization,
166
embryos were inspected under a fluorescence microscope (Leica, Germany) for RFP
167
expression.
168 169 6
ACCEPTED MANUSCRIPT 170
3. Results and Discussion Because immune responsive TLR22 is specific to teleosts/amphibians and its intron-
172
less gene structure in L. rohita (rohu carp) was available (Panda et al., 2014; Samanta et al.,
173
2014); we intended to explore developing/generating model rohu fish lacking TLR22. We
174
selected CRISPER/Cas9 system to disrupt the TLR22 locus, because of its ease of design
175
with efficiency relative to ZFNs and TALE nucleases (Liang et al., 2015; Nakade et al., 2014;
176
Ota et al., 2014; Tatsumi et al., 2014; Xiao et al., 2013; Zu et al., 2013). The unique LRR
177
ecto-domains (act as PRRs) of TLR22 were targeted to enhance the specificity among the
178
TLR family. Our previous findings revealed the LrTLR22 gene comprised nineteen LRR
179
domains along with an intracellular conserved TIR domain (Panda et al., 2014). The gRNA
180
sequence (upper panel of Fig. 1), containing PAM site (5’-CGG-3’), preceded by unique 20
181
nucleotide bases (target site: 1836-1856 bases) as per (N)20NGG rule, was designed from the
182
eighteenth LRR domain to construct a Cas9 target vector termed LrTLR22Cas9 (lower panel
183
of Fig. 1). Above gRNA sequence was unique to LrTLR22, because no homology was
184
detected with zebrafish (Danio rerio), human (Homo sapiens), mouse (Mus musculus) and
185
chicken (Gallus gallus). This ruled out the possible off-target sites for CRISPR/Cas9
186
nuclease mediated mutagenesis. To examine whether LrTLR22Cas9 can efficiently enforce
187
precise gene targeting via HR, we designed experiments to co-inject the exogenous HR donor
188
vector (LrTLR22HR), containing EF1α-RFP-T2A-Puro expression/selection cassette within
189
ligated two homology arms (924 and 890 bp), respectively (Fig. 2A), immediately preceding
190
the 924 bp spanning 912/1835 bases of LrTLR22 and following 890 bp positioned at 1860 -
191
2750 bases of LrTLR22, gRNA target sequence of TRL22.
EP
TE D
M AN U
SC
RI PT
171
LrTLR22Cas9 nuclease construct was co-injected with LrTLR22HR, linearized with
193
ScaI, into 2-4 cell stages of rohu fertilized eggs (50 embryos). Out of which, seven embryos
194
survived and grew to the fry stage (6 days). Among them, one individual (T2) was found to
195
be positive, as detected by the expression of RFP in organs such as brain, spleen, liver,
196
intestine and kidney (Fig. 2B). In line with this, LrTLR22 mRNA expression could not be
197
detected only in RFP expressing embryo (T2), whereas others including non-injected control
198
embryos expressed transcripts (Fig. 2C). Thus, it is most likely that there was an integration
199
of exogenous donor DNA cassette of LrTLR22HR within LrTLR22 locus of T2 embryo.
AC C
192
200
Next, the HR event was examined by PCR amplification for genomic DNA using
201
primer sets for full-length cDNA (Table S1). The PCR amplification produced a PCR band
202
(5900 bp) of expected size in RFP positive individuals (T2) for a successful HR event,
203
whereas the rest of RFP negative embryos, including controls did not amplify this size rather 7
ACCEPTED MANUSCRIPT than wild-type (WT) 2700 bp band (Fig. 3A). Subsequent restriction mappings (BglII
205
digested) of these PCR products also generated fragments of expected sizes of 300 bp, 1000
206
bp and 4600 bp in RFP positive, in the case of HR event; whereas 300 bp and 2400 bp (WT)
207
in the negative as well as control individuals (Fig. 3B). To further confirm integration by
208
HR, junction sequences between target locus and knocked-in donors were analysed by bi-
209
directional sequencing (Fig. 3C). Sequencing results of PCR amplified genomic DNA
210
suggested the exogenous donor HR plasmid sequence was integrated efficiently within the
211
expected cleavage site of Cas9. Together, above findings clearly demonstrated that Cas9-
212
induced DSBs prompted the targeted integration of exogenous HR cassette in T2 embryos
213
(Fig. 3B). In the absence of a TLR22 mRNA expression, the mutant individuals thus
214
generated, should be considered as model fishes (∆LrTLR22 with knock-out allele) for
215
undertaking basic research, particularly uncovering it’s in vivo functions.
SC
RI PT
204
One concern with new genome editing tools is the potential for off-target sites as
217
recently emphasised for CRISPR/Cas9 system (Fu et al., 2013). The possible off-target
218
activities, as also reported in zebrafish, mice, rabbits and human cells (Ota et al., 2014; Yang
219
et al., 2014b; Yasue et al., 2014; Zou et al., 2009), could not be ruled out. Evidence also was
220
found of double nickase, which potentially could reduce the likelihood of off-target
221
modifications (Cho et al., 2014; Ran et al., 2013). Based on our sequencing data, off-target
222
alteration was not detected in the LrTLR22 gene. Off-target mutations could not be detected
223
in other carp TLRs, such as TLR21 and TLR23 (data not presented), specific to teleosts. This
224
is in line with the fact that off-targets sites could not be predicted with genomes of zebrafish,
225
human, mouse and chicken. However, it is essential to determine other off-target sites, if any,
226
while generating model rohu fishes lacking TLR22 gene expression. Nevertheless, this is the
227
first report of developing the successful gene (TLR22) disruption technique mediated by HR
228
in large-bodied teleost (rohu carp, L. rohita) by using CRISPR/Cas9 system. Development of
229
such type of model carps would enrich basic understanding of participatory distinctive roles
230
being played by TLR22 in relation to its effects on pathogenic dsRNA viruses and bacteria,
231
including lice infections. Our study shows the utility of the CRISPR/Cas9 system as a genetic
232
tool in creating model fish species, potentially in the area of genome editing as well as
233
transgenic research.
AC C
EP
TE D
M AN U
216
234 235 236 8
ACCEPTED MANUSCRIPT 237
Acknowledgements
238
This work was supported by a grant from the National Agricultural Science Fund (NASF),
239
Indian Council of Agricultural Research, Union Ministry of Agriculture, Government of
240
India. Thanks to the Director of this Institute for providing required facilities to carry out this
241
research.
RI PT
242
AC C
EP
TE D
M AN U
SC
243
9
ACCEPTED MANUSCRIPT
References
245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266 267 268 269 270 271 272 273 274 275 276 277 278 279 280 281 282 283 284 285 286 287 288 289 290 291
Akira, S., 2009. Pathogen recognition by innate immunity and its signaling. Proceedings of the Japan Academy. Series B, Physical and biological sciences 85, 143-156. Alexopoulou, L., Thomas , V., Schnare, M., Lobet, Y., Anguita, J., Schoen, R., Medzhitov, R., Fikrig, E., Flavell, R., 2002. Hyporesponsiveness to vaccination with Borrelia burgdorferi OspA in humans and in TLR1- and TLR2-deficient mice. Nat Med 8, 878-884. Aoki, T., Takano, T., Santos, M., Kondo, H., Hirono, I., 2008. Molecular Innate Immunity in Teleost Fish: Review and Future Perspectives, 5th World Fisheries Congress, pp. 263-276. Auer, T., Duroure, K., De Cian, A., Concordet, A., Del Bene, F., 2014. Highly efficient CRISPR/Cas9mediated knock-in in zebrafish by homology-independent DNA repair. Genome research 24, 142-153. Bachu, R., Bergareche, I., Chasin, L., 2015. CRISPR-Cas targeted plasmid integration into mammalian cells via non-homologous end joining. Biotechnology and bioengineering 112, 2154-2162. Baoprasertkul, P., Xu, P., Peatman, E., Kucuktas, H., Liu, Z., 2007. Divergent Toll-like receptors in catfish (Ictalurus punctatus): TLR5S, TLR20, TLR21. Fish & shellfish immunology 23, 12181230. Barman, H.K., Barat, A., Yadav, B.M., Banerjee, S., Meher, P.K., Reddy, P., Jana, R.K., 2003. Genetic variation between four species of Indian major carps as reveled by random amplified polymorphic DNA assay. Aquaculture 217, 115-123. Barman, H.K., Das, V., Mohanta, R., Mohapatra, C., Panda, R.P., Jayasankar, P., 2010. Expression analysis of β-actin promoter of rohu (Labeo rohita) by direct injection into muscle. Curr Sci India 99, 1030-1032. Barman, H.K., Patra, S.K., Das, V., Mohapatra, S.D., Jayasankar, P., Mohapatra, M., Mohanta, R., Panda, R.P., Rath, S.N., 2011. Identification and characterization of differentially expressed transcripts in the gills of freshwater prawn (Macrobrachium rosenbergii) under salt stress. The Scientific World Journal. Barman, H.K., Takami, Y., Ono, T., Nishijima, H., Sanematsu, F., Shibahara, K., Nakayama, T., 2006. Histone acetyltransferase 1 is dispensibale for replication-coupled chromatin assembly but contributes to recover DNA damages created following replication blockage in vertebrate cells. Biochem. Biophy. Res. Commn. 345, 1547-1557. Barman, H.K., Takami, Y., Ono, T., Nishijima, H., Shibahara, K., Sanematsu, F., Nakayama, T., 2008. Histone acetyltransferase-1 regulates integrity of cytosolic histone H3-H4 containing complex. Biochem. Biophy. Res. Commn. 373, 624-630. Byadgi, O., Puteri, D., Lee, Y., Lee, J., Cheng, T., 2014. Identification and expression analysis of cobia (Rachycentron canadum) Toll-like receptor 9 gene. Fish & shellfish immunology 36, 417-427. Cho, S., Kim, S., Kim, Y., Kweon, J., Kim, H., Bae, S., Kim, J., 2014. Analysis of off-target effects of CRISPR/Cas-derived RNA-guided endonucleases and nickases. Genome research 24, 132-141. Choulika, A., Perrin, A., Dujon, B., Nicolas, J., 1995. Induction of homologous recombination in mammalian chromosomes by using the I-SceI system of Saccharomyces cerevisiae. Molecular and cellular biology 15, 1968-1973. Edvardsen, R.B., Leininger, S., Kleppe, L., Skaftnesmo, K.O., Wargelius, A., 2014. Targeted mutagenesis in Atlantic salmon (Salmo salar L.) using the CRISPR/Cas9 system induces complete knockout individuals in the F0 generation. PloS one 9, e108622. Fu, Y., Foden, J., Khayter, C., Maeder, M., Reyon, D., Joung, J., Sander, J., 2013. High-frequency offtarget mutagenesis induced by CRISPR-Cas nucleases in human cells. Nature biotechnology 31, 822-826. Gaj, T., Gersbach, C., Barbas, C., 2013. ZFN, TALEN, and CRISPR/Cas-based methods for genome engineering. Trends in biotechnology 31, 397-405.
AC C
EP
TE D
M AN U
SC
RI PT
244
10
ACCEPTED MANUSCRIPT
EP
TE D
M AN U
SC
RI PT
Gong, Z., Wan, H., Tay, T., Wang, H., Chen, M., Yan, T., 2003. Development of transgenic fish for ornamental and bioreactor by strong expression of fluorescent proteins in the skeletal muscle. Biochemical and biophysical research communications 308, 58-63. Hockemeyer, D., Wang, H., Kiani, S., Lai, C., Gao, Q., Cassady, J., Cost, G., Zhang, L., Santiago, Y., Miller, J., Zeitler, B., Cherone, J., Meng, X., Hinkley, S., Rebar, E., Gregory, P., Urnov, F., Jaenisch, R., 2011. Genetic engineering of human pluripotent cells using TALE nucleases. Nature biotechnology 29, 731-734. Ishii, A., Kawasaki, M., Matsumoto, M., Tochinai, S., Seya, T., 2007. Phylogenetic and expression analysis of amphibian Xenopus Toll-like receptors. Immunogenetics 59, 281-293. Ju, B., Xu, Y., He, J., Liao, J., Yan, T., Hew, C., Lam, T., Gong, Z., 1999. Faithful expression of green fluorescent protein (GFP) in transgenic zebrafish embryos under control of zebrafish gene promoters. Developmental genetics 25, 158-167. Klug, A., 2010. The discovery of zinc fingers and their development for practical applications in gene regulation and genome manipulation. Quarterly reviews of biophysics 43, 1-21. Li, D., Qiu, Z., Shao, Y., Chen, Y., Guan, Y., Liu, M., Li, Y., Gao, N., Wang, L., Lu, X., Zhao, Y., Liu, M., 2013. Heritable gene targeting in the mouse and rat using a CRISPR-Cas system. Nature biotechnology 31, 681-683. Li, M., Yang, H., Zhao, J., Fang, L., Shi, H., Li, M., Sun, Y., Zhang, X., Jiang, D., Zhou, L., Wang, D., 2014. Efficient and Heritable Gene Targeting in Tilapia by CRISPR/Cas9. Genetics 197, 591-599. Liang, P., Xu, Y., Zhang, X., Ding, C., Huang, R., Zhang, Z., Lv, J., Xie, X., Chen, Y., Li, Y., Sun, Y., Bai, Y., Songyang, Z., Ma, W., Zhou, C., Huang, J., 2015. CRISPR/Cas9-mediated gene editing in human tripronuclear zygotes. Protein & cell 6, 363-372. Mahapatra, K.D., Jena, R.K., Saha, J.N., Gjerde, B., Sarangi, N., 2006. Development of Aquatic Animal Genetic Improvement and Dissemination Programs: Current Status and Action Plans, Lessons from the Breeding Program of Rohu. WorldFish Center. Mohanta, R., Jayasankar, P., Das Mahapatra, K., Saha, J.N., Barman, H.K., 2014a. Molecular cloning, characterization and functional assessment of the myosin light polypeptide chain 2 (mylz2) promoter of farmed carp, Labeo rohita. Transgenic research 23, 601-607. Mohanta, R., Jayasankar, P., Mahapatra, K.D., Saha, J.N., Barman, H.K., 2014b. Molecular cloning, characterization and functional assessment of the myosin light polypeptide chain 2 (mylz2) promoter of farmed carp, Labeo rohita. Transgenic research 23, 601-607. Mohapatra, C., Barman, H.K., 2014. Identification of promoter within the first intron of Plzf gene expressed in carp spermatogonial stem cells. Molecular biology reports 41, 6433-6440. Mohapatra, C., Barman, H.K., Panda, R.P., Kumar, S., Das, V., Mohanta, R., Mohapatra, S.D., Jayasankar, P., 2010. Cloning of cDNA and prediction of peptide structure of Plzf expressed in the spermatogonial cells of Labeo rohita. Marine genomics 3, 157-163. Mohapatra, C., Patra, S.K., Panda, R.P., Mohanta, R., Saha, A., Saha, J.N., Mahapatra, K.D., Jayasankar, P., Barman, H.K., 2014. Gene structure and identification of minimal promoter of Pou2 expressed in spermatogonial cells of rohu carp, Labeo rohita. Molecular biology reports 41, 4123-4132. Nakade, S., Tsubota, T., Sakane, Y., Kume, S., Sakamoto, N., Obara, M., Daimon, T., Sezutsu, H., Yamamoto, T., Sakuma, T., Suzuki, K., 2014. Microhomology-mediated end-joiningdependent integration of donor DNA in cells and animals using TALENs and CRISPR/Cas9. Nature communications 5, 5560. Oshiumi, H., Matsuo, A., Matsumoto, M., Seya, T., 2008. Pan-vertebrate toll-like receptors during evolution. Current Genomics 9, 488-493. Ota, S., Hisano, Y., Ikawa, Y., Kawahara, A., 2014. Multiple genome modifications by the CRISPR/Cas9 system in zebrafish. Genes to cells : devoted to molecular & cellular mechanisms 19, 555564. Panda, R.P., Barman, H.K., Mohapatra, C., 2011. Isolation of enriched carp spermatogonial stem cells from Labeo rohita testis for in vitro propagation. Theriogenology 76., 241-251.
AC C
292 293 294 295 296 297 298 299 300 301 302 303 304 305 306 307 308 309 310 311 312 313 314 315 316 317 318 319 320 321 322 323 324 325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342
11
ACCEPTED MANUSCRIPT
EP
TE D
M AN U
SC
RI PT
Panda, R.P., Chakrapani, V., Patra, S.K., Saha, J.N., Jayasankar, P., Barman, H.K., 2014. First evidence of comparative responses of Toll-like receptor 22 (TLR22) to relatively resistant and susceptible Indian farmed carps to Argulus siamensis infection. Dev Comp Immunol. Patra, S.K., Chakrapani, V., Panda, R.P., Mohapatra, C., Jayasankar, P., Barman, H.K., 2015. First evidence of molecular characterization of rohu carp Sox2 gene being expressed in proliferating spermatogonial cells. Theriogenology 84, 268-276 e261. Qiu, C., Cheng, B., Zhang, Y., Huang, R., Liao, L., Li, Y., Luo, D., Hu, W., Wang, Y., 2014. Efficient knockout of transplanted green fluorescent protein gene in medaka using TALENs. Marine biotechnology 16, 674-683. Ran, F., Hsu, P., Lin, C., Gootenberg, J., Konermann, S., Trevino, A., Scott, D., Inoue, A., Matoba, S., Zhang, Y., Zhang, Y., 2013. Double nicking by RNA-guided CRISPR Cas9 for enhanced genome editing specificity. Cell 154, 1380-1389. Rebl, A., Siegl, E., Kollner, B., Fischer, U., Seyfert, H., 2007. Characterization of twin toll-like receptors from rainbow trout (Oncorhynchus mykiss): evolutionary relationship and induced expression by Aeromonas salmonicida salmonicida. Dev Comp Immunol 31, 499-510. Reyes-Becerril, M., Ascencio-Valle, F., Alamillo, E., Hirono, I., Kondo, H., Jirapongpairoj, W., Angulo, C., 2015. Molecular cloning and comparative responses of Toll-like receptor 22 following ligands stimulation and parasitic infection in yellowtail (Seriola lalandi). Fish & shellfish immunology 46, 323-333. Roach, J., Glusman, G., Rowen, L., Kaur, A., Purcell, M., Smith, K., Hood, L., Aderem, A., 2005. The evolution of vertebrate Toll-like receptors. Proceedings of the National Academy of Sciences of the United States of America 102, 9577-9582. Sadelain, M., Papapetrou, E., Bushman, F., 2012. Safe harbours for the integration of new DNA in the human genome. Nature reviews. Cancer 12, 51-58. Samanta, M., Swain, B., Basu, M., Mahapatra, G., Sahoo, B., Paichha, M., Lenka, S., Jayasankar, P., 2014. Toll-like receptor 22 in Labeo rohita: molecular cloning, characterization, 3D modeling, and expression analysis following ligands stimulation and bacterial infection. Applied biochemistry and biotechnology 174, 309-327. Sanematsu, F., Takami, Y., Barman, H., Fukagawa, T., Ono, T., Shibahara, K., Nakayama, T., 2006. Asf1 is required for viability and chromatin assembly during DNA replication in vertebrate Cells. Journal of Biological Chemistry 218, 13817-13827. Sanjana, N., Cong, L., Zhou, Y., Cunniff, M., Feng, G., Zhang, F., 2012. A transcription activator like effector toolbox for genome engineering. Nature protocols. Nature protocols 7, 171-192. Schartl, M., 2014. Beyond the zebrafish: diverse fish species for modeling human disease. Disease models & mechanisms 7, 181-192. Tatsumi, Y., Takeda, M., Matsuda, M., Suzuki, T., Yokoi, H., 2014. TALEN-mediated mutagenesis in zebrafish reveals a role for r-spondin 2 in fin ray and vertebral development. FEBS letters 588, 4543-4550. Wang, F., Shi, Z., Cui, Y., Guo, X., Shi, Y., Chen, Y., 2015. Targeted gene disruption in Xenopus laevis using CRISPR/Cas9. Cell & bioscience 5, 15. Wang H, Yang H, Shivalila CS, Dawlaty MM, Cheng AW, Zhang F, Jaenisch R, 2013. One-step generation of mice carrying mutations in multiple genes by CRISPR/Cas-mediated genome engineering. Cell 153, 910-918. Wang, H., Yang, H., Shivalila, C., Dawlaty, M., Cheng, A., Zhang, F., Jaenisch, F., 2013. One-step generation of mice carrying mutations in multiple genes by CRISPR/Cas-mediated genome engineering. Cell 153, 910-918. Xiao, A., Wang, Z., Hu, Y., Wu, Y., Luo, Z., Yang, Z., Zu, Y., Li, W., Huang, P., Tong, X., Zhu, Z., Lin, S., Zhang, B., 2013. Chromosomal deletions and inversions mediated by TALENs and CRISPR/Cas in zebrafish. Nucleic acids research 41, e141. Yang, D., Xu, J., Zhu, T., Fan, J., Lai, L., Zhang, J., Chen, Y., 2014a. Effective gene targeting in rabbits using RNA-guided Cas9 nucleases. Journal of molecular cell biology 6, 97-99.
AC C
343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387 388 389 390 391 392 393
12
ACCEPTED MANUSCRIPT
RI PT
Yang, D., Xu, J., Zhu, T., Fan, J., Lai, L., Zhang, L., Chen, L., 2014b. Effective gene targeting in rabbits using RNA-guided Cas9 nucleases. Journal of molecular cell biology 6, 97-99. Yasue, A., Mitsui, S., Watanabe, T., Sakuma, T., Oyadomari, S., Yamamoto, T., Noji, S., Mito, T., Tanaka, E., 2014. Highly efficient targeted mutagenesis in one-cell mouse embryos mediated by the TALEN and CRISPR/Cas systems. Scientific reports 4, 5705. Zhang, S., Jouanguy, E., Ugolini, S., Smahi, A., Elain, G., Romero, P., Segal, D., Sancho-Shimizu, V., Lorenzo, L., Puel, A., Picard, C., Chapgier, A., Plancoulaine, S., Titeux, M., Cognet, C., Von Bernuth, H., Ku, C., Casrouge, A., Zhang, X., Barreiro, L., Leonard, J., Hamilton, C., Lebon, P., Heron, B., Vallee, L., Quintana-Murci, L., Hovnanian, A., Rozenberg, F., Vivier, E., Geissmann, F., Tardieu, M., Abel, L., Casanova, J., 2007. TLR3 deficiency in patients with herpes simplex encephalitis. Science 317, 1522–1527. Zou, J., Maeder, M., Mali, P., Pruett-Miller, S., Thibodeau-Beganny, S., Chou, B., Chen, G., Ye, Z., Park, I., Daley, G., Porteus, M., Joung, J., Cheng, L., 2009. Gene targeting of a disease-related gene in human induced pluripotent stem and embryonic stem cells. Cell stem cell 5, 97-110. Zu, Y., Tong, X., Wang, Z., Liu, D., Pan, R., Li, Z., Hu, Y., Luo, Z., Huang, P., Wu, Q., Zhu, Z., Zhang, B., Lin, S., 2013. TALEN-mediated precise genome modification by homologous recombination in zebrafish. Nature methods 10, 329-331.
SC
394 395 396 397 398 399 400 401 402 403 404 405 406 407 408 409 410
M AN U
411 412
AC C
EP
TE D
413
13
ACCEPTED MANUSCRIPT
Figure legends
415
Fig. 1. Step-wise depiction of Construction of CRISPR/Cas9 Nuclease target vector. Each
416
complementary guide RNA strands were designed, synthesized and annealed. The double-
417
stranded guide RNA was cloned into Cas9 nuclease vector to prepare LrTLR22Cas9
418
construct.
RI PT
414
419
Fig. 2. Gene targeting of TLR22 locus, RFP expression and assessment of TLR22 gene
421
expression. (A) Schematic representation of targeting HR donor construct (top), intact
422
(middle) and targeted (bottom) TLR22 alleles. Only relevant restriction sites (BglII site) and
423
possible relevant fragments with their lengths in kb are shown. (B) The RFP was expressed in
424
one (T2) of the targeted embryos, but not in other embryos. (C) A representative figure of
425
mRNA expression profiling that documented lack of TLR22 expression in T2 embryo.
426
T1/T2/T3, injected; control, non-injected.
M AN U
SC
420
427
Fig. 3. HR mediated gene integration at a pre-determined LrTLR22 locus. (A) A
429
representative gel of PCR amplifications (for LrTLR22 gene) from genomic DNA generating
430
bands of the expected sizes in targeted vs non-targeted individuals. (B) Restriction (BglII)
431
mapping of respective above PCR-amplified fragments showing expected digested banding
432
patterns of targeted (T2) and non-targeted individuals. (C) Genotyping by nucleotide
433
sequencing (of above PCR-amplified fragment of the targeted T2 embryo) validated the
434
successful integration of HR donor vector at targeted sites of LrTLR22 gene. Sequences in
435
italic and non-italic represent HR vector and LrTLR22, respectively. T1/T2/T3/T4/T5,
436
injected; control, non-injected.
438 439
EP
AC C
437
TE D
428
Fig. S1. LrTLR22Cas9 vector construct bearing TLR22 targeted guide RNA.
14
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
ACCEPTED MANUSCRIPT
Highlights 1. Establishment of a TLR22 gene editing technique using CRISPR/Cas9 system in Labeo
RI PT
rohita carp.
2. Successful integration of donor DNA via HR at a targeted Cas9 nuclease site of TLR22 gene.
SC
3. Gene edited mutant carp lacked TLR22 mRNA expression evidencing targeted TLR22
AC C
EP
TE D
M AN U
gene disruption.
S0145-305X(16)30126-4
DOI:
10.1016/j.dci.2016.04.009
Reference:
DCI 2613
To appear in:
Developmental and Comparative Immunology
Received Date: 29 February 2016 Revised Date:
8 April 2016
Accepted Date: 8 April 2016
Please cite this article as: Chakrapani, V., Patra, S.K., Panda, R.P., Rasal, K.D., Jayasankar, P., Barman, H.K., Establishing targeted carp TLR22 gene disruption via homologous recombination using CRISPR/Cas9, Developmental and Comparative Immunology (2016), doi: 10.1016/j.dci.2016.04.009. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT 1 2 3
Short Communication
4 5 6 7
Establishing targeted carp TLR22 gene disruption via homologous recombination using CRISPR/Cas9
8
Dashrath Rasal, Pallipuram Jayasankar, Hirak Kumar Barman*
RI PT
Vemulawada Chakrapani, Swagat Kumar Patra, Rudra Prasanna Panda, Kiran
9 10
Fish Genetics and Biotechnology Division, ICAR - Central Institute of Freshwater
12
Aquaculture, Bhubaneswar 751 002, Odisha, India
14 15
*Corresponding Author: Hirak Kumar Barman, PhD
M AN U
13
SC
11
TE D
E-mail: [email protected]; [email protected] Tel: +916742465407; +916742465414
AC C
16
EP
Fax:+916742465407.
1
ACCEPTED MANUSCRIPT Abstract
18
Recent advances in gene editing techniques have not been exploited in farmed fishes. We
19
established a gene targeting technique, using the CRISPR/Cas9 system in Labeo rohita, a
20
farmed carp (known as rohu). We demonstrated that donor DNA was integrated via
21
homologous recombination (HR) at the site of targeted double-stranded nicks created by
22
CRISPR/Cas9 nuclease. This resulted in the successful disruption of rohu Toll-like receptor
23
22 (TLR22) gene, involved in innate immunity and exclusively present in teleost fishes and
24
amphibians. The null mutant, thus, generated lacked TLR22 mRNA expression. Altogether,
25
this is the first evidence that the CRISPR/Cas9 system is a highly efficient tool for targeted
26
gene disruption via HR in teleosts for generating model large-bodied farmed fishes.
SC
RI PT
17
Keywords:
29
CarpTLR22
30
Gene editing
31
CRISPR/Cas9
32
Microinjection
33
Homologous recombination
EP AC C
34
TE D
28
M AN U
27
2
ACCEPTED MANUSCRIPT 35
1. Introduction Toll-like receptors (TLRs) are major players for innate immunity (Baoprasertkul et
37
al., 2007; Oshiumi et al., 2008; Panda et al., 2014). The TLRs are type 1 integral membrane
38
glycoproteins, having leucine-rich repeat (LRR) domains in their extracellular regions for
39
binding pathogen associated molecular patterns (PAMPs) and a Toll-interleukin-1 receptor
40
domain (TIR), which transmits downstream signals into the cytosol by recruiting and
41
activating a cascade of adaptor molecules (Akira, 2009; Panda et al., 2014). Together, the
42
extracellular LRR domains constitute a horse-shoe shape and, mainly, act as pathogen
43
recognition receptors (PRRs). In teleost fishes, most TLRs were identified as orthologs of
44
mammalian TLRs (Byadgi et al., 2014; Reyes-Becerril et al., 2015). However, TLR5,
45
TLR14, TLR19, TLR20, TLR21 and TLR22 are exclusively present in fish species (Aoki et
46
al., 2008; Rebl et al., 2007; Reyes-Becerril et al., 2015) and, hence, are likely to play
47
distinctive roles. Among these, TLR22 has been studied extensively in teleosts and
48
amphibians (Ishii et al., 2007; Panda et al., 2014; Rebl et al., 2007; Reyes-Becerril et al.,
49
2015; Roach et al., 2005; Samanta et al., 2014). It is present on the cell surface membrane
50
and can recognize viral nucleic acids on the cell surface to transmit signals to induce
51
cytokines (Aoki et al., 2008; Panda et al., 2014; Rebl et al., 2007). Recently, we cloned and
52
characterized the TLR22 gene (Database ID: KC953874) in Labeo rohita (popularly known
53
as rohu), a commercially important farmed carp species (Barman et al., 2003; Barman et al.,
54
2011; Panda et al., 2011).
55
profiling, provided the clue that it confers resistance against wide range of viral, bacterial
56
and lice infections (Panda et al., 2014; Reyes-Becerril et al., 2015; Samanta et al., 2014).
TE D
M AN U
SC
RI PT
36
EP
Documented evidences, based on mRNA/protein expression
Elucidation of exact immune-related mechanistic pathways has been made possible by
58
establishing model animals to target disruption/integration of the selected gene. For example,
59
the exact functions of TLRs, including other down regulated genes in mammals, were
60
determined mainly by knock-out mice analysis (Alexopoulou et al., 2002; Zhang et al., 2007).
61
Such knock-out models are lacking in teleost species (Schartl, 2014). Since the TLR22 gene
62
is teleost-specific and targeting this gene in carp would be useful to enrich knowledge about
63
defense mechanisms. This should have a larger impact on the progress of exploring molecular
64
functions and its involvements in disease and host defense.
AC C
57
65
Gene targeting by homologous recombination (HR) was made possible with
66
mammalian embryonic stem (ES) cells and selective somatic chicken DT40 cell line (Barman
67
et al., 2006; Barman et al., 2008; Sanematsu et al., 2006). In fish, such targeting efficient ES 3
ACCEPTED MANUSCRIPT cell or somatic cells are not available, impeding research progress in physiological or
69
immunological pathways. The discovery of zinc-finger nucleases (ZFNs) based technology
70
brought revolutionary change to gene editing/targeting in the predetermined position in the
71
genome of wide ranging species, including cell lines (Klug, 2010). More recently, sequence-
72
specific nuclease tools, such as ‘Transcription Activator-Like Effector Nucleases (TALENs)’
73
and ‘Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)-associated
74
nucleases (Cas9)’ have impressively extended the genome editing possibilities in model
75
organisms, including zebrafish and several cell lines (Auer et al., 2014; Bachu et al., 2015;
76
Gaj et al., 2013; Hockemeyer et al., 2011; Sanjana et al., 2012; Tatsumi et al., 2014; Wang et
77
al., 2015; Wang et al., 2013; Yang et al., 2014a). Both systems have recently been used to
78
create knock-out allele efficienctly. Also,both the tools have been successfully employed in
79
knock-in of DNA cassettes at defined loci via HR repair mechanism (Auer et al., 2014;
80
Choulika et al., 1995; Sadelain et al., 2012).
M AN U
SC
RI PT
68
These nucleases are efficient in generating double-strand breaks within the precise
82
locus in the genome that can be repaired by error-prone nonhomologous end joining leading
83
to a functional knock-out of the targeted gene and can be used to integrate a foreign DNA
84
sequence at a specific locus through homologous recombination. The Cas9 system has been
85
shown to be most efficient in the generation genetically modified mice, rats, rabbits,
86
zebrafish, medaka, atlantic salmon frog and tilapia (Auer et al., 2014; Edvardsen et al., 2014;
87
Li et al., 2013; Li et al., 2014; Qiu et al., 2014; Wang et al., 2015; Wang H et al., 2013; Yang
88
et al., 2014a).
TE D
81
Fish generally have some inherent advantages for genetic engineering research,
90
including enormous brood and in vitro fertilization, and ease of operation and observation.
91
Even in such a scenario, recent advancements of genome editing technologies have not been
92
fully implemented, which has limited research on in vivo gene function. HR mediated gene
93
disruption is only limited to the model zebrafish (Zu et al., 2013). In this study, we
94
successfully disrupted the LrTLR22 gene by enforcing HR mediated repair of double
95
stranded nicks created by the Cas9 nuclease.
AC C
EP
89
96 97 98 99 100 101 4
ACCEPTED MANUSCRIPT 102
2. Materials and methods
103 104
2.1. Fish and breeding Labeo rohita (rohu) were collected from the farm of the ICAR-Central Institute of
106
Freshwater Aquaculture, Bhubaneswar, Odisha, India. In vitro fertilization was performed in
107
the hatchery, following the induced breeding protocol, using the ovaprim hormone as
108
described by Mahapatra et al., (2006).
109 110
2.2. Total RNA/genomic DNA extraction and cDNA preparation
RI PT
105
Total RNA was extracted using the TRIzol reagent (Invitrogen, USA) following an
112
established protocol (Mohanta et al., 2014b; Panda et al., 2014; Patra et al., 2015). The
113
extracted RNAs were purified and quantified as per standard protocol. The reverse
114
transcriptase cDNA synthesis kit (Clontech, USA) was used to reverse transcribed RNA into
115
cDNA (Mohanta et al., 2014b; Panda et al., 2011; Patra et al., 2015). Genomic DNA was
116
isolated by standard phenol–chloroform extraction and ethanol precipitation methods
117
(Mohanta et al., 2014a; Panda et al., 2014; Patra et al., 2015).
M AN U
SC
111
118
2.3. Construction of Cas9 Smart Nuclease targeting vector with gene specific guide RNA
TE D
119
The extracellular pathogen recognition site i.e. LRR of LrTLR22 (Panda et al., 2014)
121
was chosen as an unique target site, and accordingly the guide RNA (gRNA) oligonucleotides
122
were cloned into CRISPR-Cas9 vector named as EF1-hspCas9-H1-gRNA linearized
123
SmartNuclease vector (Cat. No. CAS900A-1, SBI, USA) as per manufacturer’s guidelines.
124
Briefly, the PAM sequence (5’-CGG-3’) immediately followed the 20 bp target sequence (5’-
125
GTCTGAAGACAACTCGATCC-3’), spanning 1836 to 1858 bases of LRR domain of
126
LrTLR22 (Database ID: KC953874). The possible off-target sites were scanned with the help
127
of online tools, such as CHOPCHOP (https://chopchop.rc.fas.harvard.edu/), ZiFiT Targeter
128
(http://zifi t.partners.org/ZiFiT/) and CRISPRdirect (http://crispr.dbcls.jp/). The structure of
129
double stranded gRNA oligonucleotides contained desirable overhangs at 5’-termini (as
130
shown in Fig. 1). The oligonucleotides were annealed by incubating at 95oC for 5 min to
131
form a duplex. Subsequently, the duplex was ligated with the linearized CRISPR-Cas9 vector
132
containing H1 polymerase III promoter as depicted in Fig. S1. The ligated products were
133
transformed into the One Shot TOP10 chemically competent E. coli (Invitrogen, USA). The
134
positive clones were screened and plasmid DNA (hereafter, known as LrTLR22Cas9) was
135
extracted using QIAprep Spin Miniprep Kit (Qiagen, Germany).
AC C
EP
120
5
ACCEPTED MANUSCRIPT 136 137
2.4. Construction of donor HR vector with homology arms of targeted site Two homology arms of LrTLR22 surrounding the gRNA target site were cloned into
139
donor HR targeting vector (Cat. No. HR100PA-1, SBI, USA), containing a red fluorescence
140
protein (RFP) reporter gene expression cassette. Briefly, respective modified primer sets were
141
designed/synthesized with required restriction enzyme sites (Table S1) compatible with the
142
HR vector. Homology arms were PCR-amplified (using Advantage polymerase, Clontech,
143
USA) from LrTLR22 cDNA, restriction digested and purified by gel extraction, using
144
NucleoSpin Extract II, MN, Germany. The purified PCR products were ligated using Ligate-
145
IT Rapid Ligation kit, USB, USA, into restriction digested HR vector within respective
146
multiple cloning sites I and II, one-by-one following established protocols described by
147
(Barman et al., 2010; Mohanta et al., 2014a; Mohapatra and Barman, 2014; Mohapatra et al.,
148
2014). The ligated DNA products were transformed into One Shot TOP10 chemically
149
competent E. coli (Invitrogen, USA). The plasmids of screened clones were extracted by
150
using Qiagen plasmid kit (Qiagen, USA).
M AN U
SC
RI PT
138
To examine the targeted mutagenesis as well as integration, genomic DNA, from
152
experimental and control fishes, were PCR-amplified to obtain either surrounding the target
153
site or the full length TLR22 gene, using primers as depicted in Table S1. The resulting PCR
154
products were bi-directionally sequenced as described by (Mohapatra et al., 2010; Panda et
155
al., 2014; Patra et al., 2015). The targeted integration should yield new restriction enzyme
156
sites, not as that of wild-type sequences. Hence, the DNA sequence information, including
157
orientations of donor HR vector (hereafter, known as LrTLR22HR) were confirmed/judged
158
by the restriction mapping followed by repeated both-directional sequencing.
EP
TE D
151
160 161
AC C
159
2.5 Microinjection of rohu embryos LrTLR22Cas9 (33.3 pg) and linearized (ScaI digested) LrTLR22HR (66.3 pg) DNA
162
constructs t were co-injected into rohu embryos at 1- to 4-cell stage as described (Gong et al.,
163
2003; Ju et al., 1999) at a total concentration of 100 pg/µl/embryo using CellTram micro-
164
injector (Eppendorf, Germany). Injected embryos along with controls were reared in 70%
165
natural pond water containing 1% penicillin/streptomycin. After 6 days of post-fertilization,
166
embryos were inspected under a fluorescence microscope (Leica, Germany) for RFP
167
expression.
168 169 6
ACCEPTED MANUSCRIPT 170
3. Results and Discussion Because immune responsive TLR22 is specific to teleosts/amphibians and its intron-
172
less gene structure in L. rohita (rohu carp) was available (Panda et al., 2014; Samanta et al.,
173
2014); we intended to explore developing/generating model rohu fish lacking TLR22. We
174
selected CRISPER/Cas9 system to disrupt the TLR22 locus, because of its ease of design
175
with efficiency relative to ZFNs and TALE nucleases (Liang et al., 2015; Nakade et al., 2014;
176
Ota et al., 2014; Tatsumi et al., 2014; Xiao et al., 2013; Zu et al., 2013). The unique LRR
177
ecto-domains (act as PRRs) of TLR22 were targeted to enhance the specificity among the
178
TLR family. Our previous findings revealed the LrTLR22 gene comprised nineteen LRR
179
domains along with an intracellular conserved TIR domain (Panda et al., 2014). The gRNA
180
sequence (upper panel of Fig. 1), containing PAM site (5’-CGG-3’), preceded by unique 20
181
nucleotide bases (target site: 1836-1856 bases) as per (N)20NGG rule, was designed from the
182
eighteenth LRR domain to construct a Cas9 target vector termed LrTLR22Cas9 (lower panel
183
of Fig. 1). Above gRNA sequence was unique to LrTLR22, because no homology was
184
detected with zebrafish (Danio rerio), human (Homo sapiens), mouse (Mus musculus) and
185
chicken (Gallus gallus). This ruled out the possible off-target sites for CRISPR/Cas9
186
nuclease mediated mutagenesis. To examine whether LrTLR22Cas9 can efficiently enforce
187
precise gene targeting via HR, we designed experiments to co-inject the exogenous HR donor
188
vector (LrTLR22HR), containing EF1α-RFP-T2A-Puro expression/selection cassette within
189
ligated two homology arms (924 and 890 bp), respectively (Fig. 2A), immediately preceding
190
the 924 bp spanning 912/1835 bases of LrTLR22 and following 890 bp positioned at 1860 -
191
2750 bases of LrTLR22, gRNA target sequence of TRL22.
EP
TE D
M AN U
SC
RI PT
171
LrTLR22Cas9 nuclease construct was co-injected with LrTLR22HR, linearized with
193
ScaI, into 2-4 cell stages of rohu fertilized eggs (50 embryos). Out of which, seven embryos
194
survived and grew to the fry stage (6 days). Among them, one individual (T2) was found to
195
be positive, as detected by the expression of RFP in organs such as brain, spleen, liver,
196
intestine and kidney (Fig. 2B). In line with this, LrTLR22 mRNA expression could not be
197
detected only in RFP expressing embryo (T2), whereas others including non-injected control
198
embryos expressed transcripts (Fig. 2C). Thus, it is most likely that there was an integration
199
of exogenous donor DNA cassette of LrTLR22HR within LrTLR22 locus of T2 embryo.
AC C
192
200
Next, the HR event was examined by PCR amplification for genomic DNA using
201
primer sets for full-length cDNA (Table S1). The PCR amplification produced a PCR band
202
(5900 bp) of expected size in RFP positive individuals (T2) for a successful HR event,
203
whereas the rest of RFP negative embryos, including controls did not amplify this size rather 7
ACCEPTED MANUSCRIPT than wild-type (WT) 2700 bp band (Fig. 3A). Subsequent restriction mappings (BglII
205
digested) of these PCR products also generated fragments of expected sizes of 300 bp, 1000
206
bp and 4600 bp in RFP positive, in the case of HR event; whereas 300 bp and 2400 bp (WT)
207
in the negative as well as control individuals (Fig. 3B). To further confirm integration by
208
HR, junction sequences between target locus and knocked-in donors were analysed by bi-
209
directional sequencing (Fig. 3C). Sequencing results of PCR amplified genomic DNA
210
suggested the exogenous donor HR plasmid sequence was integrated efficiently within the
211
expected cleavage site of Cas9. Together, above findings clearly demonstrated that Cas9-
212
induced DSBs prompted the targeted integration of exogenous HR cassette in T2 embryos
213
(Fig. 3B). In the absence of a TLR22 mRNA expression, the mutant individuals thus
214
generated, should be considered as model fishes (∆LrTLR22 with knock-out allele) for
215
undertaking basic research, particularly uncovering it’s in vivo functions.
SC
RI PT
204
One concern with new genome editing tools is the potential for off-target sites as
217
recently emphasised for CRISPR/Cas9 system (Fu et al., 2013). The possible off-target
218
activities, as also reported in zebrafish, mice, rabbits and human cells (Ota et al., 2014; Yang
219
et al., 2014b; Yasue et al., 2014; Zou et al., 2009), could not be ruled out. Evidence also was
220
found of double nickase, which potentially could reduce the likelihood of off-target
221
modifications (Cho et al., 2014; Ran et al., 2013). Based on our sequencing data, off-target
222
alteration was not detected in the LrTLR22 gene. Off-target mutations could not be detected
223
in other carp TLRs, such as TLR21 and TLR23 (data not presented), specific to teleosts. This
224
is in line with the fact that off-targets sites could not be predicted with genomes of zebrafish,
225
human, mouse and chicken. However, it is essential to determine other off-target sites, if any,
226
while generating model rohu fishes lacking TLR22 gene expression. Nevertheless, this is the
227
first report of developing the successful gene (TLR22) disruption technique mediated by HR
228
in large-bodied teleost (rohu carp, L. rohita) by using CRISPR/Cas9 system. Development of
229
such type of model carps would enrich basic understanding of participatory distinctive roles
230
being played by TLR22 in relation to its effects on pathogenic dsRNA viruses and bacteria,
231
including lice infections. Our study shows the utility of the CRISPR/Cas9 system as a genetic
232
tool in creating model fish species, potentially in the area of genome editing as well as
233
transgenic research.
AC C
EP
TE D
M AN U
216
234 235 236 8
ACCEPTED MANUSCRIPT 237
Acknowledgements
238
This work was supported by a grant from the National Agricultural Science Fund (NASF),
239
Indian Council of Agricultural Research, Union Ministry of Agriculture, Government of
240
India. Thanks to the Director of this Institute for providing required facilities to carry out this
241
research.
RI PT
242
AC C
EP
TE D
M AN U
SC
243
9
ACCEPTED MANUSCRIPT
References
245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266 267 268 269 270 271 272 273 274 275 276 277 278 279 280 281 282 283 284 285 286 287 288 289 290 291
Akira, S., 2009. Pathogen recognition by innate immunity and its signaling. Proceedings of the Japan Academy. Series B, Physical and biological sciences 85, 143-156. Alexopoulou, L., Thomas , V., Schnare, M., Lobet, Y., Anguita, J., Schoen, R., Medzhitov, R., Fikrig, E., Flavell, R., 2002. Hyporesponsiveness to vaccination with Borrelia burgdorferi OspA in humans and in TLR1- and TLR2-deficient mice. Nat Med 8, 878-884. Aoki, T., Takano, T., Santos, M., Kondo, H., Hirono, I., 2008. Molecular Innate Immunity in Teleost Fish: Review and Future Perspectives, 5th World Fisheries Congress, pp. 263-276. Auer, T., Duroure, K., De Cian, A., Concordet, A., Del Bene, F., 2014. Highly efficient CRISPR/Cas9mediated knock-in in zebrafish by homology-independent DNA repair. Genome research 24, 142-153. Bachu, R., Bergareche, I., Chasin, L., 2015. CRISPR-Cas targeted plasmid integration into mammalian cells via non-homologous end joining. Biotechnology and bioengineering 112, 2154-2162. Baoprasertkul, P., Xu, P., Peatman, E., Kucuktas, H., Liu, Z., 2007. Divergent Toll-like receptors in catfish (Ictalurus punctatus): TLR5S, TLR20, TLR21. Fish & shellfish immunology 23, 12181230. Barman, H.K., Barat, A., Yadav, B.M., Banerjee, S., Meher, P.K., Reddy, P., Jana, R.K., 2003. Genetic variation between four species of Indian major carps as reveled by random amplified polymorphic DNA assay. Aquaculture 217, 115-123. Barman, H.K., Das, V., Mohanta, R., Mohapatra, C., Panda, R.P., Jayasankar, P., 2010. Expression analysis of β-actin promoter of rohu (Labeo rohita) by direct injection into muscle. Curr Sci India 99, 1030-1032. Barman, H.K., Patra, S.K., Das, V., Mohapatra, S.D., Jayasankar, P., Mohapatra, M., Mohanta, R., Panda, R.P., Rath, S.N., 2011. Identification and characterization of differentially expressed transcripts in the gills of freshwater prawn (Macrobrachium rosenbergii) under salt stress. The Scientific World Journal. Barman, H.K., Takami, Y., Ono, T., Nishijima, H., Sanematsu, F., Shibahara, K., Nakayama, T., 2006. Histone acetyltransferase 1 is dispensibale for replication-coupled chromatin assembly but contributes to recover DNA damages created following replication blockage in vertebrate cells. Biochem. Biophy. Res. Commn. 345, 1547-1557. Barman, H.K., Takami, Y., Ono, T., Nishijima, H., Shibahara, K., Sanematsu, F., Nakayama, T., 2008. Histone acetyltransferase-1 regulates integrity of cytosolic histone H3-H4 containing complex. Biochem. Biophy. Res. Commn. 373, 624-630. Byadgi, O., Puteri, D., Lee, Y., Lee, J., Cheng, T., 2014. Identification and expression analysis of cobia (Rachycentron canadum) Toll-like receptor 9 gene. Fish & shellfish immunology 36, 417-427. Cho, S., Kim, S., Kim, Y., Kweon, J., Kim, H., Bae, S., Kim, J., 2014. Analysis of off-target effects of CRISPR/Cas-derived RNA-guided endonucleases and nickases. Genome research 24, 132-141. Choulika, A., Perrin, A., Dujon, B., Nicolas, J., 1995. Induction of homologous recombination in mammalian chromosomes by using the I-SceI system of Saccharomyces cerevisiae. Molecular and cellular biology 15, 1968-1973. Edvardsen, R.B., Leininger, S., Kleppe, L., Skaftnesmo, K.O., Wargelius, A., 2014. Targeted mutagenesis in Atlantic salmon (Salmo salar L.) using the CRISPR/Cas9 system induces complete knockout individuals in the F0 generation. PloS one 9, e108622. Fu, Y., Foden, J., Khayter, C., Maeder, M., Reyon, D., Joung, J., Sander, J., 2013. High-frequency offtarget mutagenesis induced by CRISPR-Cas nucleases in human cells. Nature biotechnology 31, 822-826. Gaj, T., Gersbach, C., Barbas, C., 2013. ZFN, TALEN, and CRISPR/Cas-based methods for genome engineering. Trends in biotechnology 31, 397-405.
AC C
EP
TE D
M AN U
SC
RI PT
244
10
ACCEPTED MANUSCRIPT
EP
TE D
M AN U
SC
RI PT
Gong, Z., Wan, H., Tay, T., Wang, H., Chen, M., Yan, T., 2003. Development of transgenic fish for ornamental and bioreactor by strong expression of fluorescent proteins in the skeletal muscle. Biochemical and biophysical research communications 308, 58-63. Hockemeyer, D., Wang, H., Kiani, S., Lai, C., Gao, Q., Cassady, J., Cost, G., Zhang, L., Santiago, Y., Miller, J., Zeitler, B., Cherone, J., Meng, X., Hinkley, S., Rebar, E., Gregory, P., Urnov, F., Jaenisch, R., 2011. Genetic engineering of human pluripotent cells using TALE nucleases. Nature biotechnology 29, 731-734. Ishii, A., Kawasaki, M., Matsumoto, M., Tochinai, S., Seya, T., 2007. Phylogenetic and expression analysis of amphibian Xenopus Toll-like receptors. Immunogenetics 59, 281-293. Ju, B., Xu, Y., He, J., Liao, J., Yan, T., Hew, C., Lam, T., Gong, Z., 1999. Faithful expression of green fluorescent protein (GFP) in transgenic zebrafish embryos under control of zebrafish gene promoters. Developmental genetics 25, 158-167. Klug, A., 2010. The discovery of zinc fingers and their development for practical applications in gene regulation and genome manipulation. Quarterly reviews of biophysics 43, 1-21. Li, D., Qiu, Z., Shao, Y., Chen, Y., Guan, Y., Liu, M., Li, Y., Gao, N., Wang, L., Lu, X., Zhao, Y., Liu, M., 2013. Heritable gene targeting in the mouse and rat using a CRISPR-Cas system. Nature biotechnology 31, 681-683. Li, M., Yang, H., Zhao, J., Fang, L., Shi, H., Li, M., Sun, Y., Zhang, X., Jiang, D., Zhou, L., Wang, D., 2014. Efficient and Heritable Gene Targeting in Tilapia by CRISPR/Cas9. Genetics 197, 591-599. Liang, P., Xu, Y., Zhang, X., Ding, C., Huang, R., Zhang, Z., Lv, J., Xie, X., Chen, Y., Li, Y., Sun, Y., Bai, Y., Songyang, Z., Ma, W., Zhou, C., Huang, J., 2015. CRISPR/Cas9-mediated gene editing in human tripronuclear zygotes. Protein & cell 6, 363-372. Mahapatra, K.D., Jena, R.K., Saha, J.N., Gjerde, B., Sarangi, N., 2006. Development of Aquatic Animal Genetic Improvement and Dissemination Programs: Current Status and Action Plans, Lessons from the Breeding Program of Rohu. WorldFish Center. Mohanta, R., Jayasankar, P., Das Mahapatra, K., Saha, J.N., Barman, H.K., 2014a. Molecular cloning, characterization and functional assessment of the myosin light polypeptide chain 2 (mylz2) promoter of farmed carp, Labeo rohita. Transgenic research 23, 601-607. Mohanta, R., Jayasankar, P., Mahapatra, K.D., Saha, J.N., Barman, H.K., 2014b. Molecular cloning, characterization and functional assessment of the myosin light polypeptide chain 2 (mylz2) promoter of farmed carp, Labeo rohita. Transgenic research 23, 601-607. Mohapatra, C., Barman, H.K., 2014. Identification of promoter within the first intron of Plzf gene expressed in carp spermatogonial stem cells. Molecular biology reports 41, 6433-6440. Mohapatra, C., Barman, H.K., Panda, R.P., Kumar, S., Das, V., Mohanta, R., Mohapatra, S.D., Jayasankar, P., 2010. Cloning of cDNA and prediction of peptide structure of Plzf expressed in the spermatogonial cells of Labeo rohita. Marine genomics 3, 157-163. Mohapatra, C., Patra, S.K., Panda, R.P., Mohanta, R., Saha, A., Saha, J.N., Mahapatra, K.D., Jayasankar, P., Barman, H.K., 2014. Gene structure and identification of minimal promoter of Pou2 expressed in spermatogonial cells of rohu carp, Labeo rohita. Molecular biology reports 41, 4123-4132. Nakade, S., Tsubota, T., Sakane, Y., Kume, S., Sakamoto, N., Obara, M., Daimon, T., Sezutsu, H., Yamamoto, T., Sakuma, T., Suzuki, K., 2014. Microhomology-mediated end-joiningdependent integration of donor DNA in cells and animals using TALENs and CRISPR/Cas9. Nature communications 5, 5560. Oshiumi, H., Matsuo, A., Matsumoto, M., Seya, T., 2008. Pan-vertebrate toll-like receptors during evolution. Current Genomics 9, 488-493. Ota, S., Hisano, Y., Ikawa, Y., Kawahara, A., 2014. Multiple genome modifications by the CRISPR/Cas9 system in zebrafish. Genes to cells : devoted to molecular & cellular mechanisms 19, 555564. Panda, R.P., Barman, H.K., Mohapatra, C., 2011. Isolation of enriched carp spermatogonial stem cells from Labeo rohita testis for in vitro propagation. Theriogenology 76., 241-251.
AC C
292 293 294 295 296 297 298 299 300 301 302 303 304 305 306 307 308 309 310 311 312 313 314 315 316 317 318 319 320 321 322 323 324 325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342
11
ACCEPTED MANUSCRIPT
EP
TE D
M AN U
SC
RI PT
Panda, R.P., Chakrapani, V., Patra, S.K., Saha, J.N., Jayasankar, P., Barman, H.K., 2014. First evidence of comparative responses of Toll-like receptor 22 (TLR22) to relatively resistant and susceptible Indian farmed carps to Argulus siamensis infection. Dev Comp Immunol. Patra, S.K., Chakrapani, V., Panda, R.P., Mohapatra, C., Jayasankar, P., Barman, H.K., 2015. First evidence of molecular characterization of rohu carp Sox2 gene being expressed in proliferating spermatogonial cells. Theriogenology 84, 268-276 e261. Qiu, C., Cheng, B., Zhang, Y., Huang, R., Liao, L., Li, Y., Luo, D., Hu, W., Wang, Y., 2014. Efficient knockout of transplanted green fluorescent protein gene in medaka using TALENs. Marine biotechnology 16, 674-683. Ran, F., Hsu, P., Lin, C., Gootenberg, J., Konermann, S., Trevino, A., Scott, D., Inoue, A., Matoba, S., Zhang, Y., Zhang, Y., 2013. Double nicking by RNA-guided CRISPR Cas9 for enhanced genome editing specificity. Cell 154, 1380-1389. Rebl, A., Siegl, E., Kollner, B., Fischer, U., Seyfert, H., 2007. Characterization of twin toll-like receptors from rainbow trout (Oncorhynchus mykiss): evolutionary relationship and induced expression by Aeromonas salmonicida salmonicida. Dev Comp Immunol 31, 499-510. Reyes-Becerril, M., Ascencio-Valle, F., Alamillo, E., Hirono, I., Kondo, H., Jirapongpairoj, W., Angulo, C., 2015. Molecular cloning and comparative responses of Toll-like receptor 22 following ligands stimulation and parasitic infection in yellowtail (Seriola lalandi). Fish & shellfish immunology 46, 323-333. Roach, J., Glusman, G., Rowen, L., Kaur, A., Purcell, M., Smith, K., Hood, L., Aderem, A., 2005. The evolution of vertebrate Toll-like receptors. Proceedings of the National Academy of Sciences of the United States of America 102, 9577-9582. Sadelain, M., Papapetrou, E., Bushman, F., 2012. Safe harbours for the integration of new DNA in the human genome. Nature reviews. Cancer 12, 51-58. Samanta, M., Swain, B., Basu, M., Mahapatra, G., Sahoo, B., Paichha, M., Lenka, S., Jayasankar, P., 2014. Toll-like receptor 22 in Labeo rohita: molecular cloning, characterization, 3D modeling, and expression analysis following ligands stimulation and bacterial infection. Applied biochemistry and biotechnology 174, 309-327. Sanematsu, F., Takami, Y., Barman, H., Fukagawa, T., Ono, T., Shibahara, K., Nakayama, T., 2006. Asf1 is required for viability and chromatin assembly during DNA replication in vertebrate Cells. Journal of Biological Chemistry 218, 13817-13827. Sanjana, N., Cong, L., Zhou, Y., Cunniff, M., Feng, G., Zhang, F., 2012. A transcription activator like effector toolbox for genome engineering. Nature protocols. Nature protocols 7, 171-192. Schartl, M., 2014. Beyond the zebrafish: diverse fish species for modeling human disease. Disease models & mechanisms 7, 181-192. Tatsumi, Y., Takeda, M., Matsuda, M., Suzuki, T., Yokoi, H., 2014. TALEN-mediated mutagenesis in zebrafish reveals a role for r-spondin 2 in fin ray and vertebral development. FEBS letters 588, 4543-4550. Wang, F., Shi, Z., Cui, Y., Guo, X., Shi, Y., Chen, Y., 2015. Targeted gene disruption in Xenopus laevis using CRISPR/Cas9. Cell & bioscience 5, 15. Wang H, Yang H, Shivalila CS, Dawlaty MM, Cheng AW, Zhang F, Jaenisch R, 2013. One-step generation of mice carrying mutations in multiple genes by CRISPR/Cas-mediated genome engineering. Cell 153, 910-918. Wang, H., Yang, H., Shivalila, C., Dawlaty, M., Cheng, A., Zhang, F., Jaenisch, F., 2013. One-step generation of mice carrying mutations in multiple genes by CRISPR/Cas-mediated genome engineering. Cell 153, 910-918. Xiao, A., Wang, Z., Hu, Y., Wu, Y., Luo, Z., Yang, Z., Zu, Y., Li, W., Huang, P., Tong, X., Zhu, Z., Lin, S., Zhang, B., 2013. Chromosomal deletions and inversions mediated by TALENs and CRISPR/Cas in zebrafish. Nucleic acids research 41, e141. Yang, D., Xu, J., Zhu, T., Fan, J., Lai, L., Zhang, J., Chen, Y., 2014a. Effective gene targeting in rabbits using RNA-guided Cas9 nucleases. Journal of molecular cell biology 6, 97-99.
AC C
343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387 388 389 390 391 392 393
12
ACCEPTED MANUSCRIPT
RI PT
Yang, D., Xu, J., Zhu, T., Fan, J., Lai, L., Zhang, L., Chen, L., 2014b. Effective gene targeting in rabbits using RNA-guided Cas9 nucleases. Journal of molecular cell biology 6, 97-99. Yasue, A., Mitsui, S., Watanabe, T., Sakuma, T., Oyadomari, S., Yamamoto, T., Noji, S., Mito, T., Tanaka, E., 2014. Highly efficient targeted mutagenesis in one-cell mouse embryos mediated by the TALEN and CRISPR/Cas systems. Scientific reports 4, 5705. Zhang, S., Jouanguy, E., Ugolini, S., Smahi, A., Elain, G., Romero, P., Segal, D., Sancho-Shimizu, V., Lorenzo, L., Puel, A., Picard, C., Chapgier, A., Plancoulaine, S., Titeux, M., Cognet, C., Von Bernuth, H., Ku, C., Casrouge, A., Zhang, X., Barreiro, L., Leonard, J., Hamilton, C., Lebon, P., Heron, B., Vallee, L., Quintana-Murci, L., Hovnanian, A., Rozenberg, F., Vivier, E., Geissmann, F., Tardieu, M., Abel, L., Casanova, J., 2007. TLR3 deficiency in patients with herpes simplex encephalitis. Science 317, 1522–1527. Zou, J., Maeder, M., Mali, P., Pruett-Miller, S., Thibodeau-Beganny, S., Chou, B., Chen, G., Ye, Z., Park, I., Daley, G., Porteus, M., Joung, J., Cheng, L., 2009. Gene targeting of a disease-related gene in human induced pluripotent stem and embryonic stem cells. Cell stem cell 5, 97-110. Zu, Y., Tong, X., Wang, Z., Liu, D., Pan, R., Li, Z., Hu, Y., Luo, Z., Huang, P., Wu, Q., Zhu, Z., Zhang, B., Lin, S., 2013. TALEN-mediated precise genome modification by homologous recombination in zebrafish. Nature methods 10, 329-331.
SC
394 395 396 397 398 399 400 401 402 403 404 405 406 407 408 409 410
M AN U
411 412
AC C
EP
TE D
413
13
ACCEPTED MANUSCRIPT
Figure legends
415
Fig. 1. Step-wise depiction of Construction of CRISPR/Cas9 Nuclease target vector. Each
416
complementary guide RNA strands were designed, synthesized and annealed. The double-
417
stranded guide RNA was cloned into Cas9 nuclease vector to prepare LrTLR22Cas9
418
construct.
RI PT
414
419
Fig. 2. Gene targeting of TLR22 locus, RFP expression and assessment of TLR22 gene
421
expression. (A) Schematic representation of targeting HR donor construct (top), intact
422
(middle) and targeted (bottom) TLR22 alleles. Only relevant restriction sites (BglII site) and
423
possible relevant fragments with their lengths in kb are shown. (B) The RFP was expressed in
424
one (T2) of the targeted embryos, but not in other embryos. (C) A representative figure of
425
mRNA expression profiling that documented lack of TLR22 expression in T2 embryo.
426
T1/T2/T3, injected; control, non-injected.
M AN U
SC
420
427
Fig. 3. HR mediated gene integration at a pre-determined LrTLR22 locus. (A) A
429
representative gel of PCR amplifications (for LrTLR22 gene) from genomic DNA generating
430
bands of the expected sizes in targeted vs non-targeted individuals. (B) Restriction (BglII)
431
mapping of respective above PCR-amplified fragments showing expected digested banding
432
patterns of targeted (T2) and non-targeted individuals. (C) Genotyping by nucleotide
433
sequencing (of above PCR-amplified fragment of the targeted T2 embryo) validated the
434
successful integration of HR donor vector at targeted sites of LrTLR22 gene. Sequences in
435
italic and non-italic represent HR vector and LrTLR22, respectively. T1/T2/T3/T4/T5,
436
injected; control, non-injected.
438 439
EP
AC C
437
TE D
428
Fig. S1. LrTLR22Cas9 vector construct bearing TLR22 targeted guide RNA.
14
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
ACCEPTED MANUSCRIPT
Highlights 1. Establishment of a TLR22 gene editing technique using CRISPR/Cas9 system in Labeo
RI PT
rohita carp.
2. Successful integration of donor DNA via HR at a targeted Cas9 nuclease site of TLR22 gene.
SC
3. Gene edited mutant carp lacked TLR22 mRNA expression evidencing targeted TLR22
AC C
EP
TE D
M AN U
gene disruption.