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Generation of seed lipoxygenase-free soybean using CRISPR-Cas9

December 2019
The Crop Journal 8(3)

December 2019
8(3)

DOI:10.1016/j.cj.2019.08.008

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CC BY-NC-ND

Authors:

Yongqing Yang

Fujian Agriculture and Forestry University

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Beany flavor induced by three lipoxygenases (LOXs, including LOX1, LOX2, and LOX3) restricts human consumption of soybean. It is desirable to generate lipoxygenase-free new mutant lines to improve the eating quality of soybean oil and protein products. In this study, a pooled clustered regularly interspaced short palindromic repeats (CRISPR)-CRISPR-associated protein 9 (Cas9) strategy targeting three GmLox genes (GmLox1, GmLox2, and GmLox3) was applied and 60 T0 positive transgenic plants were generated, carrying combinations of sgRNAs and mutations. Among them, GmLox-28 and GmLox-60 were gmlox1gmlox2gmlox3 triple mutants and GmLox-40 was a gmlox1gmlox2 double mutant. Sequencing of T1 mutant plants derived from GmLox-28, GmLox-60, and GmLox-40 showed that mutation in the GmLox gene was inherited by the next generation. Colorimetric assay revealed that plants carrying different combinations of mutations lost the corresponding lipoxygenase activities. Transgene-free mutants were obtained by screening the T2 generation of lipoxygenase-free mutant lines (GmLox-28 and GmLox-60). These transgene- and lipoxygenase-free mutants could be used for soybean beany flavor reduction without restriction by regulatory frameworks governing transgenic organisms.

Schematic figure of gene structures and target sites in three GmLox genes. (A, B) Gene structures of GmLox1 (A) and GmLox2 (B) with the same target site "sgRNA-GmLox1/2". (C) Gene structure of GmLox3 with the target site "sgRNA-GmLox3".

…

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Generation of seed lipoxygenase-free soybean

using CRISPR-Cas9☆

Jie Wang

a,b

, Huaqin Kuang

, Zhihui Zhang

a,b

, Yongqing Yang

, Long Yan

Mengchen Zhang

, Shikui Song

, Yuefeng Guan

⁎

College of Resources and Environment, Fujian Provincial Key Laboratory of Haixia Applied Plant Systems Biology, Fujian Agriculture and

Forestry University, Fuzhou 350002, Fujian, China

FAFU-UCR Joint Center for Horticultural Plant Biology and Metabolomics, Haixia Institute of Science and Technology, Fujian Agriculture and

Forestry University, Fuzhou 350002, Fujian, China

Root Biology Center, College of Resources and Environment, Fujian Agriculture and Forestry University, Fuzhou 350002, Fujian, China

The Key Laboratory of Crop Genetics and Breeding of Hebei, Institute of Cereal and Oil Crops, Hebei Academy of Agricultural and Forestry

Sciences, Shijiazhuang 050035, Hebei, China

ARTICLE INFO ABSTRACT

Article history:

Received 30 April 2019

Received in revised form 12 June

2019

Accepted 11 September 2019

Available online xxxx

Beany flavor induced by three lipoxygenases (LOXs, including LOX1, LOX2, and LOX3)

restricts human consumption of soybean. It is desirable to generate lipoxygenase-free new

mutant lines to improve the eating quality of soybean oil and protein products. In this

study, a pooled clustered regularly interspaced short palindromic repeats (CRISPR)-CRISPR-

associated protein 9 (Cas9) strategy targeting three GmLox genes (GmLox1,GmLox2, and

GmLox3) was applied and 60 T

positive transgenic plants were generated, carrying

combinations of sgRNAs and mutations. Among them, GmLox-28 and GmLox-60 were

gmlox1gmlox2gmlox3 triple mutants and GmLox-40 was a gmlox1gmlox2 double mutant.

Sequencing of T

mutant plants derived from GmLox-28, GmLox-60, and GmLox-40 showed

that mutation in the GmLox gene was inherited by the next generation. Colorimetric assay

revealed that plants carrying different combinations of mutations lost the corresponding

lipoxygenase activities. Transgene-free mutants were obtained by screening the T

generation of lipoxygenase-free mutant lines (GmLox-28 and GmLox-60). These transgene-

and lipoxygenase-free mutants could be used for soybean beany flavor reduction without

restriction by regulatory frameworks governing transgenic organisms.

hosting by Elsevier B.V. on behalf of KeAi Communications Co., Ltd. This is an open access

article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.

0/).

THE CROP JOURNAL XX (XXXX) XXX

☆Peer review under responsibility of Crop Science Society of China and Institute of Crop Science, CAAS.

⁎Corresponding author.

E-mail address: guan@fafu.edu.cn. (Y. Guan).

Peer review under responsibility of Crop Science Society of China and Institute of Crop Science, CAAS.

https://doi.org/10.1016/j.cj.2019.08.008

Available online at www.sciencedirect.com

ScienceDirect

CJ-00429; No of Pages 8

Please cite this article as: J. Wang, H. Kuang, Z. Zhang, et al., Generation of seed lipoxygenase-free soybean using CRISPR-Cas9, The

Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

1. Introduction

Soybean (Glycine max [L.] Merr.), is a globally important crop

providing human dietary protein, vegetable oil, and animal

feed. However, lipoxygenases (LOXs), which are present in

mature soybean seeds, can catalyze the oxidation of

unsaturated fatty acids such as linoleic and linolenic acids to

produce conjugated unsaturated fatty acid hydroperoxides,

which are converted to volatile compounds associated with

unpleasant beany flavor [1–4]. The beany flavor of soybean

seed products restricts human consumption of soybean [5]. In

the food industry, treatments such as heat, microwave

processing, and organic solvent extraction have been used to

eliminate the beany flavor from soybean products (oil,

soymilk, tofu, etc.), increasing the cost of soybean production

and processing [6]. Breeding lipoxygenase-free soybean

varieties is a promising strategy for eliminating beany flavor

in soybean products without a cost penalty.

Mature soybean seeds contain mainly three lipoxygenase

isozymes, LOX1, LOX2, and LOX3, encoded by

Glyma.13g347600 (GmLox1), Glyma.13g347500 (GmLox2), and

Glyma.15g026300 (GmLox3), respectively [7,8]. These isozymes

are involved in the formation of beany flavor, LOX2 being the

main isozyme responsible [6,9–11]. Natural or artificial

mutants for single, double, and triple lipoxygenase isozymes

have been identified [12–15] and a series of soybean varieties

lacking lipoxygenase have been developed using these

mutant lines [16–21]. Conventionally, backcrossing or selfing

and rounds of selection over several generations, a time-

consuming and laborious process, are required to introgress

mutations into elite soybean cultivars during the breeding of

lipoxygenase-free soybean varieties.

The newly developed clustered regularly interspaced short

palindromic repeats (CRISPR)-CRISPR-associated protein 9

(Cas9) technology presents new opportunities to rapidly and

cost-effectively create new varieties [22–25]. The CRISPR-Cas9

system has become the most widely used technology for

genome editing and has been applied in many crops including

rice, maize, wheat, barley, cotton, tobacco, and sorghum

[22–28]. In soybean, the successful application of the CRISPR-

Cas9 system for mutating the genes GmFT2a,FAD2-2, and

GmSPL9 has been reported [29–31], to modify flowering time,

seed oil profile, and plant architecture, respectively. This

achievement suggests that genetic improvement of soybean

agronomical traits using the CRISPR-Cas9 system is feasible.

Here, we report the development of targeted mutagenesis

of three GmLox genes (GmLox1,GmLox2, and GmLox3)in

soybean, using a pooled CRISPR-Cas9 system [32].

Lipoxygenase-free soybean lines were characterized in the

progenies, showing the feasibility of generation of new

germplasms by this method.

2. Materials and methods

2.1. Plant material and growth

One of the main soybean cultivars of south China,

Huachun 6 (WT), was used for transformation. Wild-type

(WT, as a control; GmLox1,2,3-harboring), lipoxygenase-

free cultivar Wuxing 4 (WX4, as a control; GmLox1,2,3-

free), and mutant plants were cultivated in a greenhouse

(60%–80% relative humidity) under cycles of 14/10 h with

27/25 °C (day/night).

2.2. Single-guide RNA (sgRNA) design, CRISPR-Cas9

expression vector construction, and soybean transformation

0.09pt?>For sgRNA design, guide RNA spacer sequences

were computationally identified based on Wm82.a2

genomic sequences. SgRNA fragments were produced by

annealing complementary oligonucleotides and ligating to

BsaI-digested pGES201 plasmids with a T4 DNA ligation kit

(Takara, Dalian, China) according to the manufacturer's

instructions. After E. coli transformation, positive clones

were identified by colony PCR and Sanger sequencing of

the extracted plasmids. For mutagenesis of these three

GmLox genes simultaneously, a pooled CRISPR-Cas9

knockout strategy described previously [32,33]wasused.

The general procedure was as follows: first, two single

sgRNA CRISPR-Cas9 vectors were constructed separately

using sgRNA-GmLox1/2and sgRNA-GmLox3,andthen

Agrobacterium strains GV3101 containing each vector and

having similar optical density were mixed together. Finally,

the mixed Agrobacterium solution was transformed into the

soybeancultivarWTviaA. tumefaciens-mediated

transformation. Soybean transformation was performed as

described previously [34].

2.3. Mutation screening by sequencing analysis

Gene editing of target regions was assessed by PCR and

sequencing. PCR primers were designed to amplify

specifically the target regions (Table S1). The PCR products

were purified for Sanger sequencing to detect potential

mutations. Different types of gene editing were identified via

sequence peaks and alignment to the reference sequences as

previously described [32].

2.4. Quantitative reverse transcriptase polymerase chain

reaction (Q-RT-PCR)

To measure the expression of GmLox genes in WT plants

and GmLox mutants, Q-RT-PCR of three GmLox genes was

performedusingtotalRNAextractedfromcotyledonsamples

(5 days after sowing) of WT and four T

plants each from lines

GmLox-28, GmLox-40, and GmLox-60. Total soybean cotyledon

RNA was extracted using the E.Z.N.A. RNA Extraction Kit

(Omega Bio-Tek, Norcross, Georgia, USA) according to the

manufacturer's protocol. The PrimeScript RT Reagent Kit

with gDNA Eraser (TaKaRa Biotech, Kyoto, Japan) was used

for RT, and first-strand cDNA was amplified according to the

instructions for the SYBR Premix Ex Taq II ROX Plus Kit

(TaKaRa Biotech, Kyoto, Japan). A G. max TEFS1

(Glyma.17G186600, encoding the elongation factor EF-1a)

gene-specific primer was used as control to normalize the

expression data. Three biological replicates were used for

each sample. The primer sequences are presented in Table

S1.

2THE CROP JOURNAL XX (XXXX) XXX

Please cite this articleas: J. Wang, H. Kuang, Z. Zhang, et al., Generationof seed lipoxygenase-free soybean using CRISPR-Cas9, The

Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

2.5. Detection of seed lipoxygenases with a colorimetric assay

method

A colorimetric assay method for determination of

lipoxygenase activity was applied as previously described

[35,36], with minor modifications. Briefly, dry seed samples

were separately ground into powder. For each sample,

lipoxygenase solutions 1, 2, and 3 (LS1, LS2, and LS3; used for

the detection of LOX1, LOX2, and LOX3, respectively) were

extracted in 1.5 mL 0.2 mol L

−1

pH 9.0 sodium borate buffer,

1.5 mL 0.2 mol L

−1

pH 6.0 sodium phosphate buffer, and 1.5 mL

0.2 mol L

−1

pH 6.6 sodium phosphate buffer from respectively

15, 30, and 15 mg of soybean seed powder, and the clear

supernatant was collected after centrifugation (12,000 rpm,

5 min, 4 °C). For detection of LOX1, 0.5 mL LS1 was added to

1.0 mL substrate solution (0.125 mol L

−1

pH 9.0 sodium borate

buffer, 12.5 μmol L

−1

methylene blue, 1.375 mmol L

−1

sodium

linoleate substrate). For detection of LOX2, 0.5 mL LS2 was

added to 1.0 mL substrate solution (0.125 mol L

−1

pH 6.0

sodium phosphate buffer, 12.5 μmol L

−1

methylene blue,

1.375 mmol L

−1

sodium linoleate substrate, 25 mmol L

−1

DTT,

12.5% acetone). For detection of LOX3, 0.5 mL LS3 was added to

1.0 mL substrate solution (0.125 mol L

−1

pH 6.6 sodium

phosphate buffer, 1.375 mmol L

−1

sodium linoleate substrate,

12.5% β-carotene at 50% saturation). After mixing, each

reaction was incubated in a transparent tube for 15 min and

the solution color was recorded (clear or blue for LOX1 and

LOX2, clear or yellow for LOX3). Their absorbances at 660 nm

(for measurement of LOX1 and LOX2) and 452 nm (for

measurement of LOX3) were measured with a

spectrophotometer (UV-1600; Shimadzu, Kyoto, Japan).

2.6. Phenotypic measurement of soybean seeds

Seeds from each T

plant or WT were randomly divided into

three equal parts (treated as three biological replicates) for

seed composition analysis. Seed protein and oil content were

measured using a MATRIX-I Fourier-transform near-infrared

reflectance spectroscope (FT-NIRS) (Bruker Optics, Bremen,

Germany).

3. Results

3.1. Pooled CRISPR-Cas9 knockout of three GmLox genes in

soybean

According to sequence similarity with reference to the full

soybean genome assembly (http://www.phytozome.net/

soybean), sgRNA-GmLox1/2, targeting GmLox1 and GmLox2

Fig. 1 –Schematic figure of gene structures and target sites in three GmLox genes. (A, B) Gene structures of GmLox1 (A) and

GmLox2 (B) with the same target site “sgRNA-GmLox1/2”. (C) Gene structure of GmLox3 with the target site “sgRNA-GmLox3”.

Nucleotides marked by black or red lines represent the target sites or the protospacer adjacent motif (PAM) sequences,

respectively.

3THE CROP JOURNAL XX (XXXX) XXX

Please cite this article as: J. Wang, H. Kuang, Z. Zhang, et al., Generation of seed lipoxygenase-free soybean using CRISPR-Cas9, The

Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

in the second exon of these two genes, and sgRNA-

GmLox3, targeting GmLox3 in its third exon, were designed

(Fig. 1).

Stable transformation of soybean cotyledons yielded 76 T

plants. DNA was extracted from leaf tissue of these plants to

detect transgene presence, sgRNA distribution, and the type

Fig. 2 –Sequences of wild type and mutation types at target sites of GmLox1,GmLox2, and GmLox3, induced by CRISPR-Cas9

technology, in the T

soybean plants. The triple lipoxygenase mutants GmLox-28 and GmLox-60 are marked by red circles.

4THE CROP JOURNAL XX (XXXX) XXX

Please cite this articleas: J. Wang, H. Kuang, Z. Zhang, et al., Generationof seed lipoxygenase-free soybean using CRISPR-Cas9, The

Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

Fig. 3 –Lipoxygenase activity and sequences of wild type and mutant types at target sites of GmLox1,GmLox2, and GmLox3,in

soybean plants. Color reaction (A, D, and G) and absorbance value (B, E, and H) were used for detection of the enzyme activity

of LOX1, LOX2, and LOX3, respectively. Detailed sequences at the target site of GmLox1 (C), GmLox2 (F), and GmLox1 (I) were used

for the identification of targeted mutations in T

plants.

5THE CROP JOURNAL XX (XXXX) XXX

Please cite this article as: J. Wang, H. Kuang, Z. Zhang, et al., Generation of seed lipoxygenase-free soybean using CRISPR-Cas9, The

Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

and frequency of mutations generated. Based on sgRNA

specific PCR (SSP) amplification, 60 T

positive transgenic

plants were identified, of which 27 contained sgRNA-GmLox1/

2vector only, 22 contained sgRNA-GmLox3 vector only, and 11

contained both vectors (Table S2). Sanger sequencing showed

that 22 T

positive transgenic plants carried mutations in at

least one target site. Eleven, 14, and 10 positive transgenic T

plants carried heterozygous mutations of GmLox1,GmLox2,

and GmLox3, respectively (Fig. 2, Table S2). Single or double

lipoxygenase mutants were identified: GmLox-1 is a single

lipoxygenase mutant (with heterozygous mutations at the

target site of GmLox3) and GmLox-40 is a double lipoxygenase

mutant (with heterozygous mutations at the target site of

GmLox1 and GmLox2). GmLox-28 and GmLox-60 both harbored

heterozygous mutations at the target sites of GmLox1,GmLox2,

and GmLox3 (Fig. 2, Table S2). Thus, GmLox-28 and GmLox-60

were triple lipoxygenase mutants.

3.2. Targeted mutations and lipoxygenase activity in T

generation

To characterize the sgRNA distribution and mutations in

the target site in T

plants, the genotypes of some T

plants

were examined. Three T

plants were selected for further

analysis, including two triple lipoxygenase mutants, GmLox-

28 and GmLox-60, and a double lipoxygenase mutant, GmLox-

40 (Fig. 2, Table S2). Ten seeds collected from each self-

pollinated T

plant were grown in a growth chamber and a

total of 26 T

plants (9, 9, and 8 of lines GmLox-28, GmLox-60,

and GmLox-40, respectively) were used to examine the

genotypes at the target sites of these three GmLox genes. The

T-DNA of the sgRNA/Cas9 vectors in T

plants could be

transmitted to their progeny: most T

plants of lines GmLox-

40 (except GmLox-40-2) contained sgRNA-GmLox1/2vector

only, all T

plants of lines GmLox-28 except GmLox-28-3, -4,

-8, and -9, and all T

plants of GmLox-60 contained both

vectors (Table S3). Further, all T

plants of lines GmLox-28 and

GmLox-60 showed heterozygous or homozygous targeted

mutations within all three GmLox genes, and all T

plants of

line GmLox-40 showed heterozygous or homozygous targeted

mutations within GmLox1 and GmLox2 (Fig. S1, Table S3). A

total of 12 T

plants (2 GmLox-28, 3 GmLox-60, and 7 GmLox-40),

plants (2 GmLox-28, 3 GmLox-60, and 4 GmLox-40), and 11

plants (9 GmLox-28 and 2 GmLox-60) showed homozygous

targeted mutations within GmLox1,GmLox2 and GmLox3,

respectively (Table S3). Simultaneously, all three types of

mutations were found at target site GmLox1 (3-, 4-, and 8-bp

deletions), GmLox2 (4-, 6-, and 8-bp deletions), and GmLox3 (4-

and 8-bp deletions and 1-bp insertion) (Fig. S1, Table S3).

Among them, GmLox-28-8 and GmLox-28-9 carried two

homozygous mutations of all three GmLox genes (Table S3).

The expression of the edited GmLox genes in GmLox-28,

GmLox-40, and GmLox-60 lines was measured. The expression

of most edited genes was reduced (GmLox1 in 9 of 12 mutants,

GmLox2 in 10 of 12 mutants, and GmLox3 in all 8 mutants; P<

0.05) (Fig. S2).

To determine the presence or absence of lipoxygenase

activity in soybean T

plants, T

seeds collected from GmLox-

28, GmLox-40, and GmLox-60 were used for colorimetric assay.

WT (wild-type; GmLox1,2,3-harboring) and WX4 (GmLox1,2,3-

free) seeds were used as respectively positive and negative

controls. In consistency with the knockout of the three GmLox

genes, all T

plants of line GmLox-28 and line GmLox-60

maintained the color of the substrate solution, indicating

that they were free of LOX1 (the solution remained blue), LOX2

(the solution remained blue), and LOX3 (the solution

remained yellow) activities (Fig. 3A, D, G). T

plants of line

GmLox-40 were negative for LOX1 and LOX2 but positive for

LOX3 (Fig. 3A, D, G). The absorbances of these samples

supported these results (Fig. 3B, E, H). When T

seeds collected

from lines GmLox-28, GmLox-40, and GmLox-60 were subjected

to seed composition analysis, no differences (P> 0.05, n=8)in

seed oil or protein content were observed between WT and

Gmlox mutants (Fig. S3).

3.3. Generation of transgene- and lipoxygenase-free soybean

plants

To obtain transgene- and lipoxygenase-free soybean plants,

four lipoxygenase-free T

plants (GmLox-28-4 and -8; GmLox-60-1

and -5) were selected for further analysis. About 30 seeds

collected from each self-pollinated T

plantweregrownina

growth chamber and 84 T

plants (23, 18, 27, and 16 of lines

GmLox-28-4, GmLox-28-8, GmLox-60-1, and GmLox-60-5,

respectively) were used to screen for transgene- and

lipoxygenase-free soybean plants. CRISPR-Cas9 and sgRNA-

specific primers were used to detect transgene presence (Table

S1). Two plants from line GmLox-60-1, one from line GmLox-28-4,

one from line GmLox-28-8, and one from line GmLox-60-5 were

found to be free of transgenes (Fig. S4, Table S4). In addition, seeds

collected from eight randomly selected T

plants (two each from

lines GmLox-28-4, GmLox-28-8, GmLox-60-1, and GmLox-60-5) were

free of LOX1, LOX2, and LOX3 activities (Fig. S5). This result

showed that the lipoxygenase-free trait could be inherited by the

generations.

4. Discussion

In this study, we generated LOX-free soybean germplasms

using a pooled CRISPR-Cas9 system. Triple mutants of lox loci

may be obtained within two generations. Moreover, the lox

loci can be knocked out in an elite cultivar background (such

as Huachun 6 in this study), based on existing agricultural

traits. In addition, transgenes in CRISPR-Cas9-edited plants

could be eliminated by selfing or backcrossing. Thus, CRISPR-

Cas9 technology provides a practical method to rapidly and

cost-effectively create new LOX-free varieties.

Compared with the multiplex CRISPR-Cas9 system that

carries multiple sgRNAs on a single vector [31], pooled CRISPR-

Cas9 requires integration of multiple T-DNAs in a single line

to generate multiplex mutants [32,33]. Such a strategy

facilitates the characterization of combinations of desired

mutations after a single transformation [32,33]. However, it

might pose concerns about increased difficulty of identifying

transgene-free lines. In this study, we identified five

transgene-free plants in T

progenies. This result showed

that it is also feasible to obtain transgene-free lines in a

pooled CRISPR-Cas9 population.

6THE CROP JOURNAL XX (XXXX) XXX

Please cite this articleas: J. Wang, H. Kuang, Z. Zhang, et al., Generationof seed lipoxygenase-free soybean using CRISPR-Cas9, The

Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

Lipoxygenases (LOXs) are members of non-heme iron-

containing proteins that are widely distributed in plants [3].

LOXs may play roles in plant physiological processes, such as

plant growth and development, responses to biotic and

abiotic stresses, and mobilization of storage lipids during

germination [37–41]. The lipoxygenase-free mutants await

functional studies to characterize their agronomic characters,

seed germination, and resistance to biotic and abiotic

stresses.

Supplementary data for this article can be found online at

https://doi.org/10.1016/j.cj.2019.08.008.

Declaration of competing interest

Authors declare that there are no conflicts of interest.

Acknowledgments

This work was supported by funds from the National Key

Research and Development Program of China

(2016YFD0100700) to Y.G.

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7THE CROP JOURNAL XX (XXXX) XXX

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Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

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8THE CROP JOURNAL XX (XXXX) XXX

Please cite this articleas: J. Wang, H. Kuang, Z. Zhang, et al., Generationof seed lipoxygenase-free soybean using CRISPR-Cas9, The

Crop Journal, https://doi.org/10.1016/j.cj.2019.08.008

CRISPR-Cas9 genome editing in crop breeding for climate change resilience: Implications for smallholder farmers in Africa

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Mar 2024

Progress of Construction of Gene-Modified Soybean Based on the CRISPR/Cas9 System

Article

Full-text available

Apr 2024

Yuyang Tao

From the first discovery by Japanese scholar Ishino in 1987 to being named and classified in 2002, CRISPR technology was proven by the Nobel Prize for Chemistry in 2020. In 2010, the type II CRISPR/Cas system (CRISPR/Cas9) was developed as an RNA-targeted genome editing system, which, as a novel and emerging genome editing technology in recent years, has a promising application prospect because of its high efficiency, simplicity and low cost. There is a serious mismatch between the plant area and yield of soybeans in China with market demand. Soybean is an important source of oil and biofuel. It is closely related to national food security. The large demand has led to a high dependence on imports of soybeans in China. Therefore, there is an urgent need to breed Chinese soybean varietal strains with outstanding forms in soybean selection and breed in order to breeding good strains and realize the goal of basically satisfying independent production. This review summarizes the research of the CRISPR/Cas9 system in constructing biological models of specific genes or genomic deletions in soybeans, introduces the latest development of this technology, and discusses for the advantages of CRISPR/Cas9 system in breeding target soybeans with good resistance and high economic production value.

Unraveling the regulatory network of flower coloration in soybean: Insights into roles of GmMYBA3 and GmMYBR1

Article

Full-text available

Mar 2024

CRISPR/Cas Genome Editing in Legume Crops: Challenges and Opportunities: A Review

Article

Jun 2024

Legumes are an important source of protein and provide a health-rich diet for human beings. It contains essential amino acids. It mainly plays a significant role in soil enrichment. Due to their role in agriculture and human nutrition, scientists have made efforts to develop new traits. The genetic enhancement of legumes was achieved using traditional breeding over the years however, the progress is very slow. Recent developments in genome editing technologies, specifically CRISPR-Cas technology, have improved key agricultural traits in legumes and offer a wealth of opportunities for studying traits like improved seed nutrient content, enhancing productivity and resilience to biotic and abiotic stresses recently introduced in legumes. So far, the genome editing technology has been effectively used in various legume crops, mainly soybean, peanut, cowpea and chickpea. Still, the transformation and regeneration of other legumes have remained a significant hurdle to the implementation of gene editing. This review mainly highlights the use of different gene editing technologies in legumes, progress and updates of CRISPR/Cas9 tools in legumes and challenges of legume crops face during production.

GENOME ENGINEERING WITH CRISPR/CAS9 FOR CROP IMPROVEMENT

Chapter

Full-text available

Jun 2024

Adoption of CRISPR-Cas for crop production: present status and future prospects

Article

Full-text available

Jun 2024

Background Global food systems in recent years have been impacted by some harsh environmental challenges and excessive anthropogenic activities. The increasing levels of both biotic and abiotic stressors have led to a decline in food production, safety, and quality. This has also contributed to a low crop production rate and difficulty in meeting the requirements of the ever-growing population. Several biotic stresses have developed above natural resistance in crops coupled with alarming contamination rates. In particular, the multiple antibiotic resistance in bacteria and some other plant pathogens has been a hot topic over recent years since the food system is often exposed to contamination at each of the farm-to-fork stages. Therefore, a system that prioritizes the safety, quality, and availability of foods is needed to meet the health and dietary preferences of everyone at every time. Methods This review collected scattered information on food systems and proposes methods for plant disease management. Multiple databases were searched for relevant specialized literature in the field. Particular attention was placed on the genetic methods with special interest in the potentials of the Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) and Cas (CRISPR associated) proteins technology in food systems and security. Results The review reveals the approaches that have been developed to salvage the problem of food insecurity in an attempt to achieve sustainable agriculture. On crop plants, some systems tend towards either enhancing the systemic resistance or engineering resistant varieties against known pathogens. The CRISPR-Cas technology has become a popular tool for engineering desired genes in living organisms. This review discusses its impact and why it should be considered in the sustainable management, availability, and quality of food systems. Some important roles of CRISPR-Cas have been established concerning conventional and earlier genome editing methods for simultaneous modification of different agronomic traits in crops. Conclusion Despite the controversies over the safety of the CRISPR-Cas system, its importance has been evident in the engineering of disease- and drought-resistant crop varieties, the improvement of crop yield, and enhancement of food quality.

Advancements in Genetic Enhancement: CRISPR/Cas-Mediated Genome Editing in Leguminous Crops

Article

May 2024

Legumes play a crucial role in human nutrition and sustainable agriculture due to their high protein content and health-promoting phytochemicals. To accelerate genetic gain in yield, stress resilience, and nutritional quality, extensive efforts are underway. Recent advancements in genomic resources have paved the way for the application of cutting-edge breeding technologies like genomic selection and genome editing in legume crops. This review focuses on the latest advancements in CRISPR/Cas9-based gene editing technology, specifically tailored for improving traits in legume crops. While successful gene-editing methods have been established for crops like soybean, cowpea, and chickpea, challenges remain, particularly in overcoming the recalcitrance of certain legumes to gene transfer and regeneration in vitro. Strategies to enhance transformation and regeneration rates through modifications in culture methods and DNA delivery are discussed. Despite the potential benefits of gene editing in legume breeding, regulatory barriers pose significant challenges. A comparison of regulatory environments in different regions sheds light on the importance of favourable regulations and public acceptance for realizing CRISPR's potential in enhancing global food security. Additionally, leguminous crops are vital for their nutritional properties, nitrogen-fixing abilities, and contribution to sustainable agriculture. Traditional breeding methods focused on increasing yield, while recent advancements in genome editing techniques, notably CRISPR-Cas technology, have revolutionized the improvement of agronomic traits in legumes. This chapter provides insights into the application of genome editing tools for enhancing traits such as stress tolerance, yield, and seed content in grain legumes. Furthermore, it discusses the challenges and prospects associated with enhancing grain legumes using molecular breeding techniques. Genome editing has been successfully employed in diverse legumes, including model species like Medicago and widely cultivated crops such as soybean and chickpea, offering exciting opportunities for enhancing agronomic characteristics.

Multiomic analysis of genes related to oil traits in legumes provide insights into lipid metabolism and oil richness in soybean

Preprint

Full-text available

May 2024

Soybean (Glycine max) and common bean (Phaseolus vulgaris) diverged approximately 19 million years ago. While these species share a whole-genome duplication (WGD), the Glycine lineage experienced a second, independent WGD. Despite the significance of these WGDs, their impact on gene families related to oil-traits remains poorly understood. Here, we report an in-depth investigation of oil-related gene families in soybean, common bean, and twenty-eight other legume species. We adopted a systematic approach that included transcriptome and co-expression analysis, identification of orthologous groups, gene duplication modes and evolutionary rates, and family expansions and contractions. We curated a list of oil candidate genes and found that 91.5% of the families containing these genes expanded in soybean in comparison to common bean. Notably, we observed an expansion of triacylglycerol (TAG) biosynthesis (~3:1) and an erosion of TAG degradation (~1.4:1) families in soybean in comparison to common bean. In addition, TAG degradation genes were two-fold more expressed in common bean than in soybean, suggesting that oil degradation is also important for the sharply contrasting seed oil contents in these species. We found 17 transcription factor hub genes that are likely regulators of lipid metabolism. Finally, we inferred expanded and contracted families and correlated these patterns with oil content found in different legume species. In summary, our results do not only shed light on the evolution of oil metabolism genes in soybean, but also present multifactorial evidence supporting the prioritization of candidates for crop improvement.

Current approaches and future potential for delivering CRISPR/Cas components in oilseeds and millets

Article

May 2024

Satabdi Ghosh

Innovations and novel technologies are essential to address the needs of the future food system. Enhancing the genetics of important oil crops and millets, as well as domesticating new high-yielding varieties, is crucial to address the growing need for food security. Genome editing in plants is accomplished by changing the genome of cultured cells, which is followed by the regeneration of entire plants. Emerging as a ground-breaking breeding tool, CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) may provide a framework for accommodating increasing demand and potentially reducing regulatory burden. Although the CRISPR/Cas system is highly efficient for genome editing, several barriers and challenges impede its further improvement and adoption. Successful implementation of editing technologies requires an effective plant regeneration system. This review gives a comprehensive insight into many standard tissue culture-based regeneration and non-tissue culture-based genetic transformation techniques, making gene editing suitable for application in much less explored recalcitrant crops like oilseed and millets. This review also outlines the existing obstacles and introduces the techniques and emerging platforms that are being devised to address these limitations.

Legume Seed: A Useful Platform for the Production of Medical Proteins/Peptides

Chapter

Jan 2024

Legumes are one of the most valuable food crops and nutritious staples of many cultures around the world. They are an economical source of high-quality protein, complex carbohydrates, vitamins, and fiber, as well as health-promoting bioactive compounds and proteins/peptides. Here, we present an overview of legume seed storage proteins, their macromolecular structures, mechanisms of transport, accumulation, and compositions, as well as examples of using traditional breeding to improve legumes and modern genetic engineering to produce recombinant proteins/peptides, making the legume seed an excellent platform for molecular farming.

Generation of a Multiplex Mutagenesis Population via Pooled CRISPR‐Cas9 in Soybean

Article

Full-text available

Sep 2019
PLANT BIOTECHNOL J

The output of genetic mutant screenings in soybean [Glycine max (L.) Merr.] has been limited by its paleopolypoid genome. CRISPR‐Cas9 can generate multiplex mutants in crops with complex genomes. Nevertheless, the transformation efficiency of soybean remains low and, hence, remains the major obstacle in the application of CRISPR‐Cas9 as a mutant screening tool. Here, we report a pooled CRISPR‐Cas9 platform to generate soybean multiplex mutagenesis populations. We optimized the key steps in the screening protocol, including vector construction, sgRNA assessment, pooled transformation, sgRNA identification, and gene editing verification. We constructed 70 CRISPR‐Cas9 vectors to target 102 candidate genes and their paralogs which were subjected to pooled transformation in 16 batches. A population consisting of 407 T0 lines was obtained containing all sgRNAs at an average mutagenesis frequency of 59.2%, including 35.6% lines carrying multiplex mutations. The mutation frequency in the T1 progeny could be increased further despite obtaining a transgenic chimera. In this population, we characterized gmric1/gmric2 double mutants with increased nodule numbers, and gmrdn1‐1/1‐2/1‐3 triple mutant lines with decreased nodulation. Our study provides an advanced strategy for the generation of a targeted multiplex mutant population to overcome the gene redundancy problem in soybean as well as in other major crops. This article is protected by copyright. All rights reserved.

CRISPRCas9-mediated targeted mutagenesis of GmSPL9 genes alters plant architecture in soybean

Article

Full-text available

Apr 2019
BMC PLANT BIOL

Background The plant architecture has significant effects on grain yield of various crops, including soybean (Glycine max), but the knowledge on optimization of plant architecture in order to increase yield potential is still limited. Recently, CRISPR/Cas9 system has revolutionized genome editing, and has been widely utilized to edit the genomes of a diverse range of crop plants. Results In the present study, we employed the CRISPR/Cas9 system to mutate four genes encoding SQUAMOSA PROMOTER BINDING PROTEIN-LIKE (SPL) transcription factors of the SPL9 family in soybean. These four GmSPL9 genes are negatively regulated by GmmiR156b, a target for the improvement of soybean plant architecture and yields. The soybean Williams 82 was transformed with the binary CRISPR/Cas9 plasmid, assembled with four sgRNA expression cassettes driven by the Arabidopsis thaliana U3 or U6 promoter, targeting different sites of these four SPL9 genes via Agrobacterium tumefaciens-mediated transformation. A 1-bp deletion was detected in one target site of the GmSPL9a and one target site of the GmSPL9b, respectively, by DNA sequencing analysis of two T0-generation plants. T2-generation spl9a and spl9b homozygous single mutants exhibited no obvious phenotype changes; but the T2 double homozygous mutant spl9a/spl9b possessed shorter plastochron length. In T4 generation, higher-order mutant plants carrying various combinations of mutations showed increased node number on the main stem and branch number, consequently increased total node number per plants at different levels. In addition, the expression levels of the examined GmSPL9 genes were higher in the spl9b-1 single mutant than wild-type plants, which might suggest a feedback regulation on the expression of the investigated GmSPL9 genes in soybean. Conclusions Our results showed that CRISPR/Cas9-mediated targeted mutagenesis of four GmSPL9 genes in different combinations altered plant architecture in soybean. The findings demonstrated that GmSPL9a, GmSPL9b, GmSPL9c and GmSPL9 function as redundant transcription factors in regulating plant architecture in soybean. Electronic supplementary material The online version of this article (10.1186/s12870-019-1746-6) contains supplementary material, which is available to authorized users.

CRISPR/Cas9-mediated knockout of Ms1 enables the rapid generation of male-sterile hexaploid wheat lines for use in hybrid seed production

Article

Full-text available

Apr 2019
PLANT BIOTECHNOL J

The development and adoption of hybrid seed technology has led to dramatic increases in agricultural productivity. However, it has been a challenge to develop a commercially viable platform for the production of hybrid wheat (Triticum aestivum) seed due to wheat's strong inbreeding habit. Recently, a novel platform for commercial hybrid seed production was described. This hybridisation platform utilises nuclear male sterility to force outcrossing, and has been applied to maize and rice. With the recent molecular identification of the wheat male fertility gene Ms1, it is now possible to extend the use of this novel hybridisation platform to wheat. In this report, we used the CRISPR/Cas9 system to generate heritable, targeted mutations in Ms1. The introduction of biallelic frameshift mutations into Ms1 resulted in complete male sterility in wheat cultivars Fielder and Gladius, and several of the selected male‐sterile lines were potentially non‐transgenic. Our study demonstrates the utility of the CRISPR/Cas9 system for the rapid generation of male sterility in commercial wheat cultivars. This represents an important step towards capturing heterosis to improve wheat yields, through the production and use of hybrid seed on an industrial scale. This article is protected by copyright. All rights reserved.

Pooled CRISPR/Cas9 reveals redundant roles of plastidial phosphoglycerate kinases in carbon fixation and metabolism

Article

Full-text available

Mar 2019

Phosphoglycerate kinase (PGK) is a highly conserved reversible enzyme that participates in both glycolysis and photosynthesis. In Arabidopsis thaliana, one cytosolic PGK (PGKc) and two plastidial PGKs (PGKp) are known. It remains debatable whether the two PGKp isozymes are functionally redundant or specialized in plastidial carbon metabolism and fixation. Here, using a pooled clustered regularly‐interspaced short palindromic repeats (CRISPR)/CRISPR‐associated protein 9 (Cas9) strategy, we found that plants with single mutations in pgkp1 or pgkp2 were not significantly affected, whereas a pgkp1pgkp2 double mutation was lethal due to retarded carbon fixation, suggesting that PGKp isozymes play redundant functional roles. Metabolomic analysis demonstrated that the sugar‐deficient pgkp1pgkp2 double mutation was partially complemented by exogenous sugar, although respiration intermediates were not rescued. Chloroplast development was defective in pgkp1pgkp2, due to a deficiency in glycolysis‐dependent galactoglycerolipid biosynthesis. Ectopic expression of a plastid targeting PGKc did not reverse the pgkp1pgkp2 double‐mutant phenotypes. Therefore, PGKp1 and PGKp2 play redundant roles in carbon fixation and metabolism, whereas the molecular function of PGKc is more divergent. Our study demonstrates the functional conservation and divergence of glycolytic enzymes.

CRISPR-Cas9 mediated targeted disruption of FAD2–2 microsomal omega-6 desaturase in soybean (Glycine max.L)

Article

Full-text available

Jan 2019
BMC BIOTECHNOL

Background Recent innovation in the field of genome engineering encompasses numerous levels of plant genome engineering which attract the substantial excitement of plant biologist worldwide. RNA-guided CRISPR Cas9 system has appeared a promising tool in site-directed mutagenesis due to its innovative utilization in different branches of biology. CRISPR-Cas9 nuclease system have supersedes all previously existed strategies and their associated pitfalls encountered with site-specific mutagenesis. Results Here we demonstrated an efficient sequence specific integration/mutation of FAD2–2 gene in soybean using CRISPR-Cas9 nuclease system. A single guided RNA sequence was designed with the help of a number of bioinformatics tools aimed to target distinct sites of FAD2–2 loci in soybean. The binary vector (pCas9-AtU6-sgRNA) has been successfully transformed into soybean cotyledon using Agrobacterium tumafacien. Taken together our findings complies soybean transgenic mutants subjected to targeted mutation were surprisingly detected in our target gene. Furthermore, the detection of Cas9 gene, BAR gene, and NOS terminator were carried out respectively. Southern blot analysis confirmed the stable transformation of Cas9 gene into soybean. Real time expression with qRT-PCR and Sanger sequencing analysis confirmed the efficient CRISPR-Cas9/sgRNA induced mutation within the target sequence of FAD2–2 loci. The integration of FAD2–2 target region in the form of substitution, deletions and insertions were achieved with notably high frequency and rare off-target mutagenesis. Conclusion High frequent mutation efficiency was recorded as 21% out of all transgenic soybean plants subjected to targeted mutagenesis. Furthermore, Near-infrared spectroscopy (NIR) indicates the entire fatty acid profiling obtained from the mutants seeds of soybean. A considerable modulation in oleic acid content up to (65.58%) whereas the least level of linoleic acid is (16.08%) were recorded. Based on these finding CRISPR-Cas9 system can possibly sum up recent development and future challenges in producing agronomically important crops. Electronic supplementary material The online version of this article (10.1186/s12896-019-0501-2) contains supplementary material, which is available to authorized users.

Generation of Transgene-Free Maize Male Sterile Lines Using the CRISPR/Cas9 System

Article

Full-text available

Sep 2018

Male sterility (MS) provides a useful breeding tool to harness hybrid vigor for hybrid seed production. It is necessary to generate new male sterile mutant lines for the development of hybrid seed production technology. The CRISPR/Cas9 technology is well suited for targeting genomes to generate male sterile mutants. In this study, we artificially synthesized Streptococcus pyogenes Cas9 gene with biased codons of maize. A CRISPR/Cas9 vector targeting the MS8 gene of maize was constructed and transformed into maize using an Agrobacterium-mediated method, and eight T0 independent transgenic lines were generated. Sequencing results showed that MS8 genes in these T0 transgenic lines were not mutated. However, we detected mutations in the MS8 gene in F1 and F2 progenies of the transgenic line H17. A potential off-target site sequence which had a single nucleotide that was different from the target was also mutated in the F2 progeny of the transgenic line H17. Mutation in the MS8 gene and the male sterile phenotype could be stably inherited by the next generation in a Mendelian fashion. Transgene-free ms8 male sterile plants were obtained by screening the F2 generation of male sterile plants, and the MS phenotype could be introduced into other elite inbred lines for hybrid production.

Genome Editing in Cotton with the CRISPR/Cas9 System

Article

Full-text available

Aug 2017

Genome editing is an important tool for gene functional studies as well as crop improvement. The recent development of the CRISPR/Cas9 system using single guide RNA molecules (sgRNAs) to direct precise double strand breaks in the genome has the potential to revolutionize agriculture. Unfortunately, not all sgRNAs are equally efficient and it is difficult to predict their efficiency by bioinformatics. In crops such as cotton (Gossypium hirsutum L.), with labor-intensive and lengthy transformation procedures, it is essential to minimize the risk of using an ineffective sgRNA that could result in the production of transgenic plants without the desired CRISPR-induced mutations. In this study, we have developed a fast and efficient method to validate the functionality of sgRNAs in cotton using a transient expression system. We have used this method to validate target sites for three different genes GhPDS, GhCLA1, and GhEF1 and analyzed the nature of the CRISPR/Cas9-induced mutations. In our experiments, the most frequent type of mutations observed in cotton cotyledons were deletions (∼64%). We prove that the CRISPR/Cas9 system can effectively produce mutations in homeologous cotton genes, an important requisite in this allotetraploid crop. We also show that multiple gene targeting can be achieved in cotton with the simultaneous expression of several sgRNAs and have generated mutations in GhPDS and GhEF1 at two target sites. Additionally, we have used the CRISPR/Cas9 system to produce targeted gene fragment deletions in the GhPDS locus. Finally, we obtained transgenic cotton plants containing CRISPR/Cas9-induced gene editing mutations in the GhCLA1 gene. The mutation efficiency was very high, with 80.6% of the transgenic lines containing mutations in the GhCLA1 target site resulting in an intense albino phenotype due to interference with chloroplast biogenesis.

CRISPR/Cas9-mediated targeted mutagenesis of GmFT2a delays flowering time in soybean

Article

Full-text available

May 2017
PLANT BIOTECHNOL J

Flowering is an indication of the transition from vegetative growth to reproductive growth and has considerable effects on the life cycle of soybean (Glycine max). In this study, we employed the CRISPR/Cas9 system to specifically induce targeted mutagenesis of GmFT2a, an integrator in the photoperiod flowering pathway in soybean. The soybean cultivar Jack was transformed with three sgRNA/Cas9 vectors targeting different sites of endogenous GmFT2a via Agrobacterium tumefaciens-mediated transformation. Site-directed mutations were observed at all targeted sites by DNA sequencing analysis. T1 generation soybean plants homozygous for null alleles of GmFT2a frameshift mutated by a 1-bp insertion or short deletion exhibited late flowering under natural conditions (summer) in Beijing, China (N39°58', E116°20'). We also found that the targeted mutagenesis was stably heritable in the following T2 generation, and the homozygous GmFT2a mutants exhibited late flowering under both long-day and short-day conditions. We identified some "transgene-clean" soybean plants that were homozygous for null alleles of endogenous GmFT2a and without any transgenic element from the T1 and T2 generations. These "transgene-clean" mutants of GmFT2a may provide materials for more in-depth research of GmFT2a functions and the molecular mechanism of photoperiod responses in soybean. They will also contribute to soybean breeding and regional introduction. This article is protected by copyright. All rights reserved.

Heritable Genomic Fragment Deletions and Small Indels in the Putative ENGase Gene Induced by CRISPR/Cas9 in Barley

Article

Full-text available

Apr 2017

Targeted genome editing with the CRISPR/Cas9 system has been used extensively for the selective mutation of plant genes. Here we used CRISPR/Cas9 to disrupt the putative barley (Hordeum vulgare cv. “Golden Promise”) endo-N-acetyl-β-D-glucosaminidase (ENGase) gene. Five single guide RNAs (sgRNAs) were designed for different target sites in the upstream part of the ENGase coding region. Targeted fragment deletions were induced by co-bombarding selected combinations of sgRNA with wild-type cas9 using separate plasmids, or by co-infection with separate Agrobacterium tumefaciens cultures. Genotype screening was carried out in the primary transformants (T0) and their T1 progeny to confirm the presence of site-specific small insertions and deletions (indels) and genomic fragment deletions between pairs of targets. Cas9-induced mutations were observed in 78% of the plants, a higher efficiency than previously reported in barley. Notably, there were differences in performance among the five sgRNAs. The induced indels and fragment deletions were transmitted to the T1 generation, and transgene free (sgRNA:cas9 negative) genome-edited homozygous ENGase knock outs were identified among the T1 progeny. We have therefore demonstrated that mutant barley lines with a disrupted endogenous ENGase and defined fragment deletions can be produced efficiently using the CRISPR/Cas9 system even when this requires co-transformation with multiple plasmids by bombardment or Agrobacterium-mediated transformation. We confirm the specificity and heritability of the mutations and the ability to efficiently generate homozygous mutant T1 plants.

Biochemical Characterization of Lipoxygenase Lacking Mutants, L-l-less, L-2-less, and L-3-less Soybeans

Article

Sep 1984

Keisuke Kitamura

Generation of seed lipoxygenase-free soybean using CRISPR-Cas9

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