Skip to main content
Advertisement
Browse Subject Areas
?

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

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Creation of novel alleles of fragrance gene OsBADH2 in rice through CRISPR/Cas9 mediated gene editing

  • Shanthinie Ashokkumar,

    Roles Formal analysis, Methodology

    Affiliation Department of Plant Biotechnology, Centre for Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India

  • Deepa Jaganathan,

    Roles Software, Writing – original draft

    Affiliation Department of Plant Biotechnology, Centre for Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India

  • Valarmathi Ramanathan,

    Roles Data curation, Methodology

    Affiliation Department of Plant Biotechnology, Centre for Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India

  • Hifzur Rahman,

    Roles Methodology, Validation

    Current address: International Center for Biosaline Agriculture, Dubai, UAE

    Affiliation Department of Plant Biotechnology, Centre for Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India

  • Rakshana Palaniswamy,

    Roles Software, Validation

    Affiliation Department of Plant Biotechnology, Centre for Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India

  • Rohit Kambale,

    Roles Data curation, Writing – original draft

    Affiliation Department of Plant Biotechnology, Centre for Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India

  • Raveendran Muthurajan

    Roles Conceptualization, Methodology, Supervision, Writing – review & editing

    raveendrantnau@gmail.com

    Affiliation Department of Plant Biotechnology, Centre for Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India

Abstract

Fragrance in rice grains is a key quality trait determining its acceptability and marketability. Intensive research on rice aroma identified mutations in betaine aldehyde dehydrogenase (OsBADH2) leading to production of aroma in rice. Gene editing technologies like CRISPR/Cas9 system has opened new avenues for accelerated improvement of rice grain quality through targeted mutagenesis. In this study, we have employed CRISPR/Cas9 tool to create novel alleles of OsBADH2 leading to introduction of aroma into an elite non-aromatic rice variety ASD16. PCR analysis of putative transformants using primers targeting the flanking regions of sgRNA in the 7th exon of OsBADH2 identified 37.5% potential multi-allelic mutations in T0 generation. Sensory evaluation test in the leaves of T0 lines identified thirteen lines belonging to five independent events producing aroma. Sequence analysis of these aromatic T0 lines identified 22 different types of mutations located within -17 bp to +15bp of sgRNA region. The -1/-2 bp deletion in the line # 8–19 and -8/-5 bp deletion in the line # 2–16 produced strong aroma and the phenotype was stably inherited in the T1 generation. Comparative volatile profiling detected novel aromatic compounds viz., pyrrolidine, pyridine, pyrazine, pyradazine and pyrozole in the grains of T1 progenies of line # 8–19. This study has demonstrated the use of CRISPR/Cas9 in creating novel alleles of OsBADH2 to introduce aroma into any non-aromatic rice varieties.

Introduction

Rice is a staple food for more than half of the world’s population [1]. Apart from yield, grain quality traits such as milling %, appearance, grain size, cooking quality and aroma determine the acceptance of a variety by the consumers which in turn determines the adoption of the variety by the farmers and marketability. Aroma is considered as one of the most preferred quality parameters next to cooking quality, taste and elongation after cooking [2]. Fragrant rice varieties are becoming popular not only among the consumers of Asia but also in Europe and USA [3]. More than 200 volatile compounds have been reported to be associated with aroma in rice grains, among which 2-acetyl-1-pyrroline (2AP) was reported to be the principal compound producing aroma [4]. In addition to 2AP, several volatiles belonging to classes of hydrocarbons, aldehydes, ketones, esters, alcohols, phenols etc., have also been reported to contribute for rice aroma [5].

It was thought that rice aroma is determined by a single dominant gene [6]. Later, it was reported that aroma in rice grains is controlled by a single recessive gene [7]. Several other studies have reported that aroma in rice grains is a polygenic trait [817]. Amarawathi et al. [17] mapped three different loci (one each on chromosomes 3, 4 and 8) by utilizing a mapping population derived between Pusa 1121 and Pusa 1342. Among the three loci, ARO8.1 was found to be consistent across several genetic backgrounds [9, 10]. Further efforts on fine mapping of ARO8.1 have led to the identification of BADH2 (betaine aldehyde dehydrogenase) responsible for the production of aroma in rice grains [17, 18]. It is reported that dominant BADH2 converts γ-aminobutyraldehyde (GABald) to gamma aminobutyric acid (GABA). In the absence of a functional BADH2 i.e., non-functional BADH2 with an 8 bp deletion in exon 7 of BADH2 gene, GABald is converted into an aromatic compound 2-Acetyl 1-Pyrroline [13]. Intensive research on the haplotype diversity of BADH2 led to the development of user- friendly Indel marker discriminating aromatic and non-aromatic rice genotypes [17] which enabled accelerated development of aromatic rice genotypes through MAS programs.

Development of aromatic rice genotypes possessing high yield and desirable grain quality traits through conventional breeding or marker assisted breeding is time consuming and labor intensive. Few attempts have been made through RNAi technology to reduce the expression levels of OsBADH2 and thereby increasing the level of 2AP in rice grains [1922]. However, due to the incomplete suppression of the expression of OsBADH2 and also due to the regulatory issues, transgenic approach is no longer a preferred technique for aroma improvement in rice. Recent advancements in the genome editing technology using sequence-specific nucleases (SSNs) have paved way for accelerated improvement of complex traits through targeted gene editing. Among the SSNs, Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)-associated endonuclease Cas9 (CRISPR/Cas9) is becoming popular due to its efficiency in creating precise mutations. CRISPR/Cas9 is increasingly applied in various crop improvement programs including rice [23, 24], maize [25] and wheat [26], tomato [27], soybean [28], citrus [29], cotton [30], and cassava [31] etc.

In rice, several genes such as phytoene desaturase (OsPDS), mitogen-activated protein kinase (OsMPK2), bacterial blight susceptible genes/sugar transporters (SWEETs), Myb family transcription factor (OsMYB1), stress-responsive rice mitogen-activated protein kinase (OsMPK5), chlorophyll A oxygenase-1 (CAO1) and LA1/rice tiller angle controlling gene (LAZY01) have been successfully edited using CRISPR/Cas9 system [23, 32, 33]. Shan et al. [34] successfully edited OsBADH2 using transcription activator like effector nucleases (TALENs) and the edited plants were found to possess increased accumulation of 2AP. Due to its technical tediousness, TALEN technology is not preferred for gene editing in plants. Shao et al. [35] successfully edited OsBADH2 in non-aromatic rice Zhonghua 11 using CRISPR/Cas9 which led to increased accumulation of 2AP. The present study was formulated with an aim of creating novel alleles of OsBADH2 through CRISPR/Cas9 mutagenesis and identify novel alleles of OsBADH2 leading to production of aroma in a non-aromatic rice variety ASD16.

Materials and methods

Plant materials

A popular non-aromatic rice variety, ASD 16 was used in this study. Genetically pure seeds of ASD16 were obtained from Paddy Breeding Station, Tamil Nadu Agricultural University, Coimbatore, India and used in this study.

Construction of CRISPR/Cas9 plant expression vectors

Nucleotide sequence encoding for functional BADH2 (LOC_Os08g32870) was retrieved from MSU rice genome annotation project database (http://rice.plantbiology.msu.edu/). Synthetic guide RNA (OsBADH2-sgRNA:5’-TATGGCTTCAGCTGCTCCTA-3’) targeting the upstream of previously reported 8-bp deletion on the 7th exon of BADH2 [13] was designed using the E-CRISP tool (http://www.e-crisp.org). Oligomer of designed sgRNA was synthesized and cloned into pRGEB31 binary vector carrying Cas9 gene (Addgene plasmid # 51295; http://n2t.net/addgene:51295; RRID: Addgene_51295) [36]. BsaI was used to create the sticky ends in pRGEB31 vector and the sgRNA with BsaI hanging site was ligated. The ligated product was mobilized into XL1-blue strain and positive colonies were used for isolation of plasmid DNA.

Rice transformation

The binary vector pRGEB31 harboring Cas9/OsBADH2 sgRNA was mobilized into Agrobacterium tumefaciens LBA4404 by freeze-thaw method [37]. Immature embryos of rice variety ASD16 were collected from maturing panicles (15 days after anthesis) and used for Agrobacterium mediated transformation. After co-cultivation, putative transformed calli were kept in resting medium for a period of 5 days followed by the second round of resting for 10 days. Putative transformants were selected by subjecting the calli to two rounds of selection in a medium containing 50 mg/L hygromycin. Putative transgenic calli were regenerated in the presence of 1 mg/mL of NAA and 3 mg/mL 6-BA and rooted on half MS media containing 50 mg/L hygromycin [38]. Putative transgenic plants were transferred to transgenic green house at Tamil Nadu Agricultural University, Coimbatore, India (11.0152° N, 76.9326° E) for hardening and establishment.

Molecular characterization of T0 progenies

Genomic DNA was isolated from the leaves of all the T0 progenies using CTAB method [39] and used for PCR analysis. All the lines were evaluated for the presence/absence of Cas9/sgRNA T-DNA through PCR using primers specific to hygromycin phosphotransferase (Hpt) gene and the Cas9 gene(s). List of primers used in this study and the PCR profile followed for each primer combinations are listed in Table 1. PCR products were subjected to agarose gel electrophoresis for identifying putative edited plants based on amplicon size variations and subsequently by sequencing the PCR products. Sequencing data was analyzed using DSDecode [40], ICE v2 CRISPR analysis tool (https://ice.synthego.com/) and Clustal Omega [41]. Obtained results were confirmed by uploading the chromatogram files into TIDE analysis tool [42]. During TIDE analysis, default parameters were used and Indel range was set as 10. Proportion of edited DNA was calculated based on the sum of all significant Indels (P<0.001) detected by TIDE. Segregation of the Cas9/sgRNA T-DNA was investigated in T1 generation.

thumbnail
Table 1. List of primer combinations used for PCR analysis of recombinant bacterial colonies and putative genome edited rice plants.

https://doi.org/10.1371/journal.pone.0237018.t001

Screening of T0 and T1 progenies for aroma through sensory evaluation test

Putative gene (OsBADH2) edited plants of ASD16 were screened for the production of aroma through a sensory evaluation test using KOH-based method as described earlier [43]. About 10 cm long rice leaves from both non-transgenic and transgenic ASD16 were cut into small pieces and placed in petri dishes. Then 10 mL of 1.7% KOH solution was added onto the leaves. The petri dishes were covered and left for 20 to 30 minutes at room temperature and evaluated for the presence of aroma through sensory evaluation. Each sample was scored on a 1–4 scale, where 1 stands for absence of aroma, 2 for slight aroma, 3 for moderate aroma, and 4 for strong aroma. A panel of four persons smelled the samples and their evaluation were recorded.

Profiling of volatile aromatic compounds in the seeds using GC-MS

Transgenic plants exhibiting strong aroma were selected and forwarded to T1 generation. Presence of aroma was again confirmed through sensory evaluation test as described earlier. Seeds of two lines (# 8-19-2 and 8-19-6) producing strong aroma during sensory evaluation test were subjected to profiling of volatile compounds using GC-MS analysis along with seeds of non-transgenic ASD16. Grains were finely ground and added with 10 ml of 1.7% KOH solution. Elaborate protocol was described in our previous study [44]. In brief, the conical flask was tightly closed using a rubber cap containing a provision for a collector tube and sealed using the para film wrap to avoid leakage of volatiles. DB-5 ms capillary standard non-polar column with 30Mts dimension and Helium (He) as carrier gas were used. Sample collection tubes were removed from the flask and directly fed into the GC-MS. The analysis system is equipped with data acquisition and evaluation was carried out using Perkin Elemer Turbo Mass software Ver 6.1.0. Data analysis was carried out using XcaliburTM (Thermo-Fisher Scientific) software. Obtained mass spectra was compared against NIST2014 (Version 2.2) library.

Results

Designing sgRNA targeting OsBADH2

For creating novel alleles of OsBADH2 producing aroma in rice through CRISPR/Cas9 mutagenesis, sgRNA was designed near the 8 bp deletion on the exon 7 of OsBADH2 using E-CRISP online tool (http://www.e-crisp.org). sgRNAs were synthesized with the adapter sequences specific to the forward primer (5’-GGCA-3’) and reverse primer (5’-AAAC-3’) as shown in Fig 1A. A schematic representation of the Agrobacterium T-DNA binary vector is shown in Fig 1B.

thumbnail
Fig 1. Details of the target gene and vector used.

a) Structure of OsBADH2 and target region on 7th exon chosen for designing sgRNA; b) Schematic representation of CRISPR/Cas9 vector pRGEB31 with sgRNA targeting OsBADH2 used for stable Agrobacterium-mediated transformation of rice.

https://doi.org/10.1371/journal.pone.0237018.g001

Generation of gene edited plants of ASD 16

Immature embryos (15 DAF) were collected from a non-aromatic rice variety ASD16 and used for Agrobacterium-mediated transformation. About 400 immature embryos were used for co-cultivation using Agrobacterium harboring pRGEB31 binary vector engineered with OsBADH2 sgRNA (S1 Fig). A total of 230 embryos were found to be healthy after two rounds of resting and subjected to selection. Around 120 calli were found to survive after two rounds of selection using hygromycin. The proliferating resistant calli were forwarded to pre-regeneration and then to regeneration medium (Fig 2A–2I). A total of 211 T0 progenies belonging to 15 independent transgenic events were regenerated and transferred to rooting media. All the 211 T0 progenies were screened for the presence of binary vector harboring Cas9-OsBADH2 sgRNA and hygromycin expression cassette through PCR analysis using primers specific to the vector (reverse primer in the CaMV35 S and the forward primer in the hpt gene). All the 211 progenies were found to be positive for both vector and gene specific primers. In order to screen for the presence of mutations in the target loci, DNA isolated from all the 211 T0 progenies were amplified using a set of primers flanking the sgRNA region on OsBADH2. Out of 211, ten progenies were found to possess insertions/deletions upon analysis through agarose gel electrophoresis. The amplicon size was ranging between 250–450 bp in the ten progenies whereas the non-transgenic showed an amplification of 390 bp (Figs 2J and S2).

thumbnail
Fig 2. Agrobacterium-mediated transformation of immature embryos of rice cultivar ASD16 with pRGEB31 vector harbouring BADH2-sgRNA.

a) Co-cultivated immature embryos; b) Immature embryo derived calli (7 days after co-cultivation); c) Resting stage; d) Selection using hygromycin; e) Regeneration of putative transformants; f) Shooting and root initiation; g) Second rooting; h) Hardening of putative transgenic plants in portrays; i) Establishment of putative transgenic plants under transgenic greenhouse conditions; j) Agarose gel electrophoresis showing presence of varying sizes of amplicons in the target region; the bars denotes the multi-allelic mutations.

https://doi.org/10.1371/journal.pone.0237018.g002

Sensory evaluation test identified T0 progenies producing aroma

Sensory evaluation test was carried out in the leaf samples of all the 211 T0 progenies using 1.7% KOH. Among the 211 T0 progenies tested, thirteen lines belonging to six different events namely, Event# 1, 2, 7, 8, 9 and 12 were found to be aromatic (S3 Fig). Remaining 198 lines belonging to other nine events (Event # 3, 4, 5, 6, 10, 11, 13, 14 and 15) did not produce aroma in the T0 generation.

Molecular characterization of mutations in OsBADH2 leading to aroma

All the thirteen progenies producing aroma in T0 generation were subjected to PCR amplification using gene specific primers flanking the sgRNA and the amplicons were sequenced. Mutations were detected by comparing the sequences of edited lines against the non-transgenic ASD16 (NTASD16). Sequence analysis detected different types of mutations in the 13 aromatic lines as against the non-transgenic ASD16 (Fig 3). Among the thirteen progenies, eleven progenies showed bi-allelic mutations, one progeny showed multi-allelic and one progeny showed mono-allelic mutation (Table 2).

thumbnail
Fig 3. Sequence analysis of target region in the T0 mutant lines using ICE v2 CRISPR online tool.

Vertical black dots represent the predicted cleavage site of Cas9 and the horizontal black hyphen denotes deletions.

https://doi.org/10.1371/journal.pone.0237018.g003

thumbnail
Table 2. Different types of mutations observed in T0 progenies; Indels were predicted by using Synthego tool.

https://doi.org/10.1371/journal.pone.0237018.t002

Sequencing results were further analyzed using ICE v2 CRISPR analysis tool to calculate the Indel percentage and knock-out score (Table 3). One of the edited lines, # 12–2 was found to possess a bi-allelic homozygous deletion mutation (-17/-17bp). Whereas, lines 1–11 (+1/-1), 1–17 (+1/-1), 1–19 (+1/-1), 2–15 (-5/-8), 2–16 (-8/-5), 2–17 (+1/-1), 2–19 (-8/-8), 7–1 (-4/-1), 7–2 (-4/-1), 8–19 (-2/-1), 8–27 (-2/-7), 9–29 (multi-allelic) and 11–7 (-1/+1) were found to harbor bi-allelic heterozygous mutations. Overall, all the 13 T0 progenies producing aroma were found to possess 22 different types of mutations in the vicinity of sgRNA (-17 bp to + 15 bp) region (Fig 4A and 4B). Out of the 22 mutations, -1/+1 bp mutation located 3 bp upstream from PAM region was found to be more frequent in five events (Event # 1, 2, 7, 8 and 9). This was followed by 8 bp deletion in the PAM region and 5 bp deletions at 1bp upstream from PAM region in two events (# 2 and 9). Tracking of Indels by Decomposition (TIDE) analysis confirmed the presence of targeted mutations in OsBADH2 (S4 Fig). Predominant allele frequency was observed for all the events except line # 9 where multi-allelic mutation was observed. This might be due to chimeric events in the T0 generation which require further analysis on T1 and succeeding generations. R2 value varied from 0.91–0.97 for heterozygous bi-allelic mutants and the total efficiency ranged between 56.6 to 96.8%.

thumbnail
Fig 4.

Frequency of deletion (a) and insertion (b) mutations observed among the thirteen T0 lines.

https://doi.org/10.1371/journal.pone.0237018.g004

thumbnail
Table 3. Indel and Knock-out scores in the T0 progenies predicted by using ICE v2 CRISPR analysis tool.

https://doi.org/10.1371/journal.pone.0237018.t003

Inheritance of CRISPR/Cas9 induced mutations in the T1 generation

To determine whether the CRISPR/Cas9 induced mutations in the OsBADH2 and its influence on aroma were heritable, two events namely # 2–16 and # 8–19 which produced strong aroma in T0 were forwarded to T1 generation. Leaf sensory evaluation test in the progenies of two aromatic lines viz., # 8–19 (three plants namely 8-19-1, 8-19-2 and 8-19-6) and # 2–16 (three plants namely 2-16-1, 2-16-2 and 2-16-3) revealed the inheritance of aroma in all the 6 T1 progenies. Similarly, these lines were subjected to Sanger sequencing and the mutant alleles were tracked for their inheritance. Among the three progenies of # 8–19 (harboring -2/-1 bp mutation in T0), one line (# 8-19-1) was found to be homozygous for -2 bp mutation and the other two lines (8-19-2 and 8-19-6) were found to be still heterozygous for the bi-allelic (-2/-1 bp) mutation (Fig 5). In case of line # 2–16, all the three T1 progenies (2-16-1, 2-16-2 and 2-16-3) were found to be still heterozygous for the bi-allelic mutation (-5/-8 bp). Indel percentage was found to be > 90% for homozygous mutations and 42.3 to 49.4% for the heterozygous mutations. The R2 value ranged from 0.9 to 0.94 (S5 Fig).

thumbnail
Fig 5. Sequence analysis of target region using ICE v2 CRISPR tool in the T1 generation identified 8-19-1 possessing homozygous mutation.

Vertical black dotted line represents the predicted cleavage site of Cas9 and the horizontal black hyphen denotes deletions.

https://doi.org/10.1371/journal.pone.0237018.g005

Comparative profiling of volatile compounds in the T1 edited lines and non-transgenic ASD16

GC-MS analysis of volatiles released from seeds of two edited progenies # 8-19-2 and 8-19-6 identified accumulation of several novel aromatic compounds in the edited progenies (S1 Table). Important aromatic compounds namely, pyrrolidine, pyridine, pyrazine, pyradazine and pyrozole were present in the grains of edited progenies (S1 Table). Analysis of retention time and area percentage of peaks pertaining to the novel aromatic compounds clearly indicated that these compounds were not present in the non-transgenic ASD16 where as they were present at detectable limits in the edited lines producing aroma (Fig 6). Among the novel aromatic compounds detected, pyrrolidine is the precursor molecule in the synthesis of 2AP and pyridine shares structural homology with 2AP. Apart from the above compounds, aromatic compounds such as nonanal, octanal, hexanal, propanal, dodecane, undecane, tetradecane, butanone, pyrrole, dioxolane, propanone, octenal, acetophenone, propenal, styrene and decanal were also found only in the grains of edited lines.

thumbnail
Fig 6. Chromatogram of aromatic compounds detected in the extracts of non-transgenic ASD16 and two edited lines viz., # 8-19-2 and 8-19-6.

https://doi.org/10.1371/journal.pone.0237018.g006

Discussion

CRISPR/Cas9 induced novel alleles of OsBADH2

Physical and cooking qualities of rice grains determine the marketability and acceptability of rice varieties. Aroma is one of the key traits determining the price of rice in both local and international market. Apart from Basmati genotypes possessing long slender grains, only few other medium/short slender grain rice varieties possessing aroma are in the market. Those short/medium slender aromatic genotypes are not high yielding and possess several other disadvantages. Development of aromatic rice varieties possessing superior grain qualities through conventional or molecular breeding approaches takes considerable number of years and in some cases retaining the superior grain qualities of elite genotypes still remains a challenge. In this context, creating mutations leading to aroma in high yielding elite genotypes through CRISPR/Cas9 seems to be an attractive strategy to overcome the number of years required for developing desired genotypes and also to overcome the problems due to linkage drag [45, 46].

Several attempts have been made to unravel biochemical, genetic and molecular basis of aroma in rice which led to the identification of a major volatile compound 2-acetyl 1-pyrroline responsible for aroma in rice [13, 4750]. Lorieux et al. [9] identified one major QTL on chromosome 8 and two minor QTLs (one on chromosome 4 and another on chromosome 12) linked to accumulation of 2AP. Similarly, Amarawathi et al. [17] identified 3 loci, one each on chromosome 3 (ARO3.1 with 6.1% PVE), chromosome 4 (ARO4.1 with10.3% PVE) and chromosome 8 (ARO8.1 with 18.9% PVE). Subsequent studies led to the identification of a single recessive gene encoding betaine aldehyde dehydrogenase 2 (BADH2) on chromosome 8 to be responsible for aroma in scented rice [13]. Majority of the aromatic rice genotypes possess an 8 bp deletion in exon 7 of badh2 gene [51]. Based on this, a breeder friendly Indel marker discriminating aromatic and non-aromatic rice genotypes was developed [17] which enabled accelerated development of aromatic rice genotypes through MAS programs. Shao et al. [52] made a thorough survey of allelic variants of OsBADH2 in a set of 144 aromatic rice varieties and found 6 different haplotypes of OsBADH2 viz., i). BADH2.2 (7 bp deletion on exon 2); ii) BADH2.2 (75 bp deletion on exon2); iii) BADH2.4–5 (806 bp deletion on exon4 and exon5); iv) BADH2.7 (8 bp deletion on exon 7); v) BADH2.10 (G to A on exon 10) and vi) BADH2.13 (C to T on exon 13). Interestingly all the 6 different haplotypes were producing aroma. This indicated that different types of mutations in OsBADH2 can lead to accumulation of aroma in rice. Creating desired mutant phenotype through conventional breeding is a challenging task which will involve generation and screening of several thousands of mutant progenies. Genome editing is a controlled site-specific process that allows editing of DNA sequences using molecular tools viz., Zinc finger nucleases (ZFNs), Transcription Activator Like effector nucleases (TALENs) and Clustered Regulatory Interspaced Short Palindromic Repeats (CRISPR) associated (CRISPR/Cas), CRISPR/Cas is preferred over other site specific nucleases due to its simplicity, flexibility and accuracy [53].

During recent years, several research papers have reported the diverse applications of genome editing using the CRISPPR/Cas9 [54]. Genome editing for multiple susceptible genes have been targeted to confer broad spectrum resistance against blight disease in rice [5557]. Subsequently, CRISPR/Cas9 was applied for improving important quantitative and qualitative traits in rice including editing of OsSAPK2 regulating drought responses [58], OsGIF1 regulating size of stem, leaves and grain [59], OsMGD2 regulating grain quality [60], OsARM1 controlling tolerance against for arsenic toxicity [61], OsPPa6 contributing for tolerance against alkalinity [62] and OsBADH2 leading to aroma in rice [35]. Based on the above evidences, this study was undertaken with an aim of demonstrating the efficacy of CRISPR/Cas9 in accelerated development of aromatic rice genotypes and secondly to create different mutations in OsBADH2 leading to accumulation of aroma in rice.

In this study, CRISPR/Cas9 tool was used to create mutations in OsBADH2 of a non-aromatic rice variety ASD16. Rice genome harbors two homologs of BADH namely, BADH1 (LOC_Os04g39020) and BADH2 (LOC_Os08g32870) which share 75.94% sequence similarity [64]. BADH1 was reported to be involved in modulating abiotic stress responses and BADH2 was found to be involved in the production of aroma [63, 64]. sgRNA targeting BADH2 was designed carefully after comparing the sequences of both the homologs and the designed sgRNA targeting BADH2 shared less than 50% similarity with BADH1 (S6 Fig). PCR analysis of 211 T0 progenies confirmed the presence of vector backbone pRGEB31 in all the putative edited lines. Presence of amplicons in 10 putative edited lines having molecular weight deviating from the expected size (390 bp) indicated the presence of mutations in those lines (Figs S2 and 2J). Sensory evaluation test conducted among the 211 putative gene edited T0 progenies identified 13 progenies producing various degrees of aroma (S3 Fig). Cloning and sequencing of target regions of all the 13 aromatic progenies identified 22 different kinds of mutations (Fig 4). Among the various kinds of mutations, -1/-2 bp deletions present in the line # 8–19 and -8 /-5 bp deletion present in the line # 2–16 were found to produce strong aroma and thus indicating significant level of 2AP accumulation. Screening of T1 progenies revealed the stable inheritance of aroma in the progenies of above two lines. Among the 13 T0 progenies producing aroma, the reported mutation (8 bp deletion in the exon 7) was not present in any of the lines. Thus, all the 13 could be novel alleles of fragrance gene (OsBADH2) in rice and can be utilized in breeding programs. Studies have reported the presence of alleles other than the traditionally reported 8bp deletion of OsBADH2. Further, valedictory experiments are needed for confirming the association of 13 novel mutations with aroma in rice.

Mutations in OsBADH2 led to the alteration in the aroma profile

Several studies have documented the profile of volatile compounds in aromatic rice varieties. However, 2AP is reported to be the main volatile compound responsible for the production of aroma in rice [5]. In the present study, several allelic variants of OsBADH2 associated with aroma have been identified. One of the mutations (-1/-2 bp deletion) present in # 8–19 produced strong aroma in both T0 and T1 generation. GC-MS analysis in the seeds of aromatic progenies of ASD16 (# 8-19-2 and # 8-19-6) showed the presence of altered profile of aromatic compounds when compared to non-transgenic ASD16. The comparative profiling of volatile compounds in the seeds of T1 progenies showed the presence of several unique aromatic compounds viz., pyrrolidine, pyridine, pyrazine, pyradazine, pyrozole, pyrrolidine methanol and 2,5-pyrrolidinedione [5]. Pyrrolidine is a direct precursor of 2AP [65].

Pleasant aroma in the grains of basmati and other short grain aromatic rice genotypes is due to the blend of more than 500 volatile aromatic compounds [66]. In this study also, several aromatic compounds belonging to the class of aldehydes, ketones, organic acids, esters, alcohols, aromatic hydrocarbons, terpenes, alkenes, pyridines and N-heterocyclic compounds were detected only in the seeds of gene edited and aromatic T1 progenies. These chemical compounds were used to distinguish between scented and non-scented rice cultivars [5]. Other heterocyclic aromatic compounds such as pyridine, pyrazole, pyrazoline, pyrimidinone, pyrrolidinedione and furan found in the seeds of aromatic progenies share a common 5’ carbon ring similar to 2AP.

Similarly, other additional volatile compounds found in our current study were reported in aromatic rice varieties. For instance, propanal possesses sharp musty odor like rubbing alcohol [67] and octanal is a fragrant liquid with a fruit-like odor, it occurs naturally in citrus oils. It is used commercially as a component in perfumes and in flavor production for the food industry [68]. Whereas, nonanal possess rose-orange odor (https://pubchem.ncbi.nlm.nih.gov/compound/Nonanal), decanal is an odor agent smells similar to that of orange peel and acetophenone was present in 8-19-6 which possess sweet pungent taste and odor resembling the odor of oranges (https://pubchem.ncbi.nlm.nih.gov/compound/Decanal).

In summary, CRISPR/Cas9 system has been successfully applied to create new allelic variations OsBADH2 gene. The allelic variations we observed in the exon 7 of BADH2 in the current study may be contributing to aroma in the non-aromatic rice variety ASD16 and further functional analysis along with phenotyping may confirm the hypothesis. Studies have reported that the fragrance of cooked rice consists of more than 200 volatile compounds such as hydrocarbons, alcohols, aldehydes, ketones, acids, esters, phenols, pyridines, pyrazines, and other compounds [69]. Therefore, along with the traditional volatile compounds other aromatic compound we observed might be the effect of new alleles created in this study. However further analysis on all the T1 lines and succeeding generations may reveal the role of the newly created novel alleles for aroma in rice. The heterozygous mutants obtained from the current study will be useful to obtain homozygous mutants in the next generation and characterization of the new alleles for aroma trait will pave way to improve aroma in agronomically important non-aromatic rice varieties.

Conclusion

This study has demonstrated the efficiency of CRISPR/Cas9 in creating novel alleles of BADH2 leading to aroma in rice. Conventional/MAS breeding strategies require at least half a decade of time to develop aromatic rice varieties. Utilization of CRISPR/Cas9 tool has shortened the time required in developing aromatic ASD16 lines. Developed lines will serve as novel genetic stocks/donors in breeding programs for developing non-basmati aromatic rice varieties. Further experiments will focus on characterization of aroma profiles of gene edited lines of ASD16 thereby to identify novel aromatic compounds in rice and to understand the molecular basis of aroma production in rice.

Supporting information

S1 Fig. Details of pRGEB31 harbouring BADH2-sgRNA under OsU3 promoter.

a) pRGEB31 possessing OsBadh2 guide RNA b) Sequence analysis showing the presence of OsBADH2-sgRNA in pRGEB31.

https://doi.org/10.1371/journal.pone.0237018.s001

(TIF)

S2 Fig. Agarose gel electrophoresis showing amplification pattern of OsBADH2 fragments in the T0 progenies.

https://doi.org/10.1371/journal.pone.0237018.s002

(TIF)

S3 Fig. Sensory evaluation test for assessing the production of aroma in the selected T0 lines.

https://doi.org/10.1371/journal.pone.0237018.s003

(TIF)

S4 Fig. Screening of T0 progenies for targeted mutations.

Prediction of putative bi-allelic mutants using TIDE analysis.

https://doi.org/10.1371/journal.pone.0237018.s004

(TIF)

S5 Fig. Inheritance percentage of Indels in the T1 progenies using TIDE software.

https://doi.org/10.1371/journal.pone.0237018.s005

(TIF)

S6 Fig. Multiple sequence alignment of BADH1 (LOC_Os04g39020.1), functional BADH2 (LOC_Os08g32870.1 (F) and non-functional BADH2 (LOC_Os08g32870.1 (NF)).

https://doi.org/10.1371/journal.pone.0237018.s006

(TIF)

S1 Table. List of volatile compounds identified in seeds of non-transgenic ASD16 and gene edited lines.

https://doi.org/10.1371/journal.pone.0237018.s007

(XLSX)

References

  1. 1. Long-ping Y. Development of hybrid rice to ensure food security. Rice science. 2014;21(1):1–2.
  2. 2. Verma DK, Srivastav PP. Extraction Technology for Rice Volatile Aroma Compounds. Food Engineering: Apple Academic Press; 2016. p. 281–328.
  3. 3. Cruz ND, Khush G. Rice grain quality evaluation procedures. Aromatic rices. 2000;3:15–28.
  4. 4. Buttery RG, Ling LC, Juliano BO, Turnbaugh JG. Cooked rice aroma and 2-acetyl-1-pyrroline. Journal of agricultural and food chemistry. 1983;31(4):823–6.
  5. 5. Hinge VR, Patil HB, Nadaf AB. Aroma volatile analyses and 2AP characterization at various developmental stages in Basmati and Non-Basmati scented rice (Oryza sativa L.) cultivars. Rice. 2016;9(1):38. pmid:27495313
  6. 6. Kadam B, Patankar V. Inheritance of aroma in rice. Chronica Bot. 1938;4(32):4.
  7. 7. Jodon N. inheritance of flower fragrance and other characters in rice. Journal of the American Society of Agronomy. 1944.
  8. 8. Pinson S. Inheritance of aroma in six rice cultivars. Crop Science. 1994;34(5):1151–7.
  9. 9. Lorieux M, Petrov M, Huang N, Guiderdoni E, Ghesquière A. Aroma in rice: genetic analysis of a quantitative trait. Theoretical and Applied Genetics. 1996;93(7):1145–51. pmid:24162494
  10. 10. Ahn S, Bollich C, Tanksley S. RFLP tagging of a gene for aroma in rice. Theoretical and Applied Genetics. 1992;84(7–8):825–8. pmid:24201481
  11. 11. Dong Y, Tsuzuki E, Terao H. Trisomic genetic analysis of aroma in three Japanese native rice varieties (Oryza sativa L.). Euphytica. 2001;117(3):191–6.
  12. 12. Aluko G, Martinez C, Tohme J, Castano C, Bergman C, Oard J. QTL mapping of grain quality traits from the interspecific cross Oryza sativa× O. glaberrima. Theoretical and Applied Genetics. 2004;109(3):630–9. pmid:15105992
  13. 13. Bradbury LM, Fitzgerald TL, Henry RJ, Jin Q, Waters DL. The gene for fragrance in rice. Plant biotechnology journal. 2005;3(3):363–70. pmid:17129318
  14. 14. Wanchana S, Kamolsukyunyong W, Ruengphayak S, Toojinda T, Tragoonrung S, Vanavichit A. A rapid construction of a physical contig across a 4.5 cM region for rice grain aroma facilitates marker enrichment for positional cloning. Sci Asia. 2005;31(3):299–306.
  15. 15. Wan X, Wan J, Jiang L, Wang J, Zhai H, Weng J, et al. QTL analysis for rice grain length and fine mapping of an identified QTL with stable and major effects. Theoretical and Applied Genetics. 2006;112(7):1258–70. pmid:16477428
  16. 16. Chen S, Wu J, Yang Y, Shi W, Xu M. The fgr gene responsible for rice fragrance was restricted within 69 kb. Plant Science. 2006;171(4):505–14. pmid:25193648
  17. 17. Amarawathi Y, Singh R, Singh AK, Singh VP, Mohapatra T, Sharma TR, et al. Mapping of quantitative trait loci for basmati quality traits in rice (Oryza sativa L.). Molecular Breeding. 2008;21(1):49–65.
  18. 18. Singh A, Singh PK, Singh R, Pandit A, Mahato AK, Gupta DK, et al. SNP haplotypes of the BADH1 gene and their association with aroma in rice (Oryza sativa L.). Molecular breeding. 2010;26(2):325–38.
  19. 19. Vanavichit A, Tragoonrung S, Toojinda T, Wanchana S, Kamolsukyunyong W. Transgenic rice plants with reduced expression of Os2AP and elevated levels of 2-acetyl-1-pyrroline. Google Patents; 2008.
  20. 20. Niu X, Tang W, Huang W, Ren G, Wang Q, Luo D, et al. RNAi-directed downregulation of OsBADH2 results in aroma (2-acetyl-1-pyrroline) production in rice (Oryza sativa L.). BMC plant biology. 2008;8(1):100.
  21. 21. Chen S, Yang Y, Shi W, Ji Q, He F, Zhang Z, et al. Badh2, encoding betaine aldehyde dehydrogenase, inhibits the biosynthesis of 2-acetyl-1-pyrroline, a major component in rice fragrance. The Plant Cell. 2008;20(7):1850–61. pmid:18599581
  22. 22. Chen M, Wei X, Shao G, Tang S, Luo J, Hu P. Fragrance of the rice grain achieved via artificial microRNA‐induced down‐regulation of OsBADH2. Plant breeding. 2012;131(5):584–90.
  23. 23. Miao J, Guo D, Zhang J, Huang Q, Qin G, Zhang X, et al. Targeted mutagenesis in rice using CRISPR-Cas system. Cell research. 2013;23(10):1233–6. pmid:23999856
  24. 24. Li M, Li X, Zhou Z, Wu P, Fang M, Pan X, et al. Reassessment of the four yield-related genes Gn1a, DEP1, GS3, and IPA1 in rice using a CRISPR/Cas9 system. Frontiers in plant science. 2016;7:377. pmid:27066031
  25. 25. Li J, Zhang H, Si X, Tian Y, Chen K, Liu J, et al. Generation of thermosensitive male-sterile maize by targeted knockout of the ZmTMS5 gene. Journal of genetics and genomics = Yi chuan xue bao. 2017;44(9):465. pmid:28412227
  26. 26. Zhang Y, Liang Z, Zong Y, Wang Y, Liu J, Chen K, et al. Efficient and transgene-free genome editing in wheat through transient expression of CRISPR/Cas9 DNA or RNA. Nature communications. 2016;7(1):1–8.
  27. 27. Li X, Wang Y, Chen S, Tian H, Fu D, Zhu B, et al. Lycopene is enriched in tomato fruit by CRISPR/Cas9-mediated multiplex genome editing. Frontiers in plant science. 2018;9:559. pmid:29755497
  28. 28. Li Z, Liu Z-B, Xing A, Moon BP, Koellhoffer JP, Huang L, et al. Cas9-guide RNA directed genome editing in soybean. Plant physiology. 2015;169(2):960–70. pmid:26294043
  29. 29. Peng A, Chen S, Lei T, Xu L, He Y, Wu L, et al. Engineering canker‐resistant plants through CRISPR/Cas9‐targeted editing of the susceptibility gene Cs LOB 1 promoter in citrus. Plant biotechnology journal. 2017;15(12):1509–19. pmid:28371200
  30. 30. Zhang Z, Ge X, Luo X, Wang P, Fan Q, Hu G, et al. Simultaneous editing of two copies of Gh14-3-3d confers enhanced transgene-clean plant defense against Verticillium dahliae in allotetraploid upland cotton. Frontiers in plant science. 2018;9:842. pmid:30013582
  31. 31. Hummel AW, Chauhan RD, Cermak T, Mutka AM, Vijayaraghavan A, Boyher A, et al. Allele exchange at the EPSPS locus confers glyphosate tolerance in cassava. Plant biotechnology journal. 2018;16(7):1275–82. pmid:29223136
  32. 32. Feng Z, Zhang B, Ding W, Liu X, Yang D-L, Wei P, et al. Efficient genome editing in plants using a CRISPR/Cas system. Cell research. 2013;23(10):1229–32. pmid:23958582
  33. 33. Shan Q, Wang Y, Li J, Zhang Y, Chen K, Liang Z, et al. Targeted genome modification of crop plants using a CRISPR-Cas system. Nature biotechnology. 2013;31(8):686–8. pmid:23929338
  34. 34. Shan Q, Zhang Y, Chen K, Zhang K, Gao C. Creation of fragrant rice by targeted knockout of the Os BADH 2 gene using TALEN technology. Plant biotechnology journal. 2015;13(6):791–800. pmid:25599829
  35. 35. Shao G, Xie L, Jiao G, Wei X, Sheng Z, Tang S, et al. CRISPR/CAS9-mediated editing of the fragrant gene Badh2 in rice. Chin J Rice Sci. 2017;31(2):216–22.
  36. 36. Xie K, Yang Y. RNA-guided genome editing in plants using a CRISPR–Cas system. Molecular plant. 2013;6(6):1975–83. pmid:23956122
  37. 37. Weigel D, Glazebrook J. Transformation of agrobacterium using the freeze-thaw method. CSH protocols. 2006;2006(7):1031–6.
  38. 38. Hiei Y, Komari T. Agrobacterium-mediated transformation of rice using immature embryos or calli induced from mature seed. Nature protocols. 2008;3(5):824. pmid:18451790
  39. 39. Porebski S, Bailey LG, Baum BR. Modification of a CTAB DNA extraction protocol for plants containing high polysaccharide and polyphenol components. Plant molecular biology reporter. 1997;15(1):8–15.
  40. 40. Liu W, Xie X, Ma X, Li J, Chen J, Liu Y-G. DSDecode: a web-based tool for decoding of sequencing chromatograms for genotyping of targeted mutations. Molecular plant. 2015;8(9):1431–3. pmid:26032088
  41. 41. Sievers F, Wilm A, Dineen D, Gibson TJ, Karplus K, Li W, et al. Fast, scalable generation of high‐quality protein multiple sequence alignments using Clustal Omega. Molecular systems biology. 2011;7(1).
  42. 42. Brinkman EK, Chen T, Amendola M, van Steensel B. Easy quantitative assessment of genome editing by sequence trace decomposition. Nucleic acids research. 2014;42(22):e168–e. pmid:25300484
  43. 43. Nagaraju M, Mohanty K, Chaudhary D, Gangadharan C. A simple technique to detect scent in rice. Oryza. 1991;28:109–10.
  44. 44. Shanthinie A, Dilip KR, Raveendran M. Comparative profiling of volatile compounds in the grains of rice varieties differing in their aroma. Electronic Journal of Plant Breeding. 2019;10(2):614–9.
  45. 45. Roldan MVG, Périlleux C, Morin H, Huerga-Fernandez S, Latrasse D, Benhamed M, et al. Natural and induced loss of function mutations in SlMBP21 MADS-box gene led to jointless-2 phenotype in tomato. Scientific reports. 2017;7(1):1–10.
  46. 46. Soyk S, Müller NA, Park SJ, Schmalenbach I, Jiang K, Hayama R, et al. Variation in the flowering gene SELF PRUNING 5G promotes day-neutrality and early yield in tomato. Nature Genetics. 2017;49(1):162. pmid:27918538
  47. 47. Sood B, Siddiq E. A rapid technique for scent determination in rice [India]. Indian Journal of Genetics and Plant Breeding. 1978.
  48. 48. Berner DK, Hoff B. Inheritance of Scent in American Long Grain Rice 1. Crop science. 1986;26(5):876–8.
  49. 49. YOSHIHASHI T, NGUYEN TTH, KABAKI N. Area dependency of 2-acetyl-1-pyrroline content in an aromatic rice variety, Khao Dawk Mali 105. Japan Agricultural Research Quarterly: JARQ. 2004;38(2):105–9.
  50. 50. Kovach MJ, Calingacion MN, Fitzgerald MA, McCouch SR. The origin and evolution of fragrance in rice (Oryza sativa L.). Proceedings of the National Academy of Sciences. 2009;106(34):14444–9.
  51. 51. Fitzgerald MA, Sackville Hamilton NR, Calingacion MN, Verhoeven HA, Butardo VM. Is there a second fragrance gene in rice? Plant Biotechnology Journal. 2008;6(4):416–23. pmid:18331415
  52. 52. Shao G, Tang S, Chen M, Wei X, He J, Luo J, et al. Haplotype variation at Badh2, the gene determining fragrance in rice. Genomics. 2013;101(2):157–62. pmid:23220350
  53. 53. Doudna JA, Charpentier E. The new frontier of genome engineering with CRISPR-Cas9. Science. 2014;346(6213):1258096. pmid:25430774
  54. 54. Jaganathan D, Ramasamy K, Sellamuthu G, Jayabalan S, Venkataraman G. CRISPR for crop improvement: an update review. Frontiers in plant science. 2018;9:985. pmid:30065734
  55. 55. Hutin M, Sabot F, Ghesquière A, Koebnik R, Szurek B. A knowledge‐based molecular screen uncovers a broad‐spectrum Os SWEET 14 resistance allele to bacterial blight from wild rice. The Plant Journal. 2015;84(4):694–703. pmid:26426417
  56. 56. Blanvillain‐Baufumé S, Reschke M, Solé M, Auguy F, Doucoure H, Szurek B, et al. Targeted promoter editing for rice resistance to Xanthomonas oryzae pv. oryzae reveals differential activities for SWEET 14‐inducing TAL effectors. Plant biotechnology journal. 2017;15(3):306–17. pmid:27539813
  57. 57. Cai L, Cao Y, Xu Z, Ma W, Zakria M, Zou L, et al. A transcription activator-like effector Tal7 of Xanthomonas oryzae pv. oryzicola activates rice gene Os09g29100 to suppress rice immunity. Scientific reports. 2017;7(1):1–13.
  58. 58. Lou D, Wang H, Liang G, Yu D. OsSAPK2 confers abscisic acid sensitivity and tolerance to drought stress in rice. Frontiers in plant science. 2017;8:993. pmid:28659944
  59. 59. He Z, Zeng J, Ren Y, Chen D, Li W, Gao F, et al. OsGIF1 positively regulates the sizes of stems, leaves, and grains in rice. Frontiers in plant science. 2017;8:1730. pmid:29051769
  60. 60. Shu Q, BASNET R, Zhang J, Hussain N. Characterization and mutational analysis of a monogalactosyldiacylglycerol synthase gene OsMGD2 in rice. Frontiers in plant science. 2019;10:992. pmid:31428115
  61. 61. Wang M, Mao Y, Lu Y, Tao X, Zhu J-k. Multiplex gene editing in rice using the CRISPR-Cpf1 system. Molecular plant. 2017;10(7):1011–3. pmid:28315752
  62. 62. Wang B, Xie G-Q, Liu Z-L, He R, Han J, Huang S, et al. Mutagenesis reveals that the OsPPa6 gene is required for enhancing the alkaline tolerance in rice. Frontiers in plant science. 2019;10:759. pmid:31244876
  63. 63. Mitsuya S, Yokota Y, Fujiwara T, Mori N, Takabe T. OsBADH1 is possibly involved in acetaldehyde oxidation in rice plant peroxisomes. FEBS letters. 2009 Nov 19; 583(22):3625–9. pmid:19850038
  64. 64. Baicharoen A, Vijayan R, Pongprayoon P. Structural insights into betaine aldehyde dehydrogenase (BADH2) from Oryza sativa explored by modeling and simulations. Scientific reports. 2018 Aug 27;8(1):1–7.
  65. 65. De Kimpe NG, Stevens CV, Keppens MA. Synthesis of 2-acetyl-1-pyrroline, the principal rice flavor component. Journal of Agricultural and Food Chemistry. 1993;41(9):1458–61.
  66. 66. Verma DK, Srivastav PP. A Paradigm of Volatile Aroma Compounds in Rice and Their Product with Extraction and Identification Methods: A Comprehensive Review. Food Research International. 2019:108924. pmid:32156374
  67. 67. Unruh J, Pearson D. n‐Propyl Alcohol. Kirk‐Othmer Encyclopedia of Chemical Technology. 2000.
  68. 68. Kohlpaintner C, Schulte M, Falbe J, Lappe P, Weber J. Ullmann's encyclopedia of industrial chemistry. Wiley-VCH, Weinheim; 2008.
  69. 69. Vanavichit A, Yoshihashi T. Molecular aspects of fragrance and aroma in rice. Advances in botanical research. 56: Elsevier; 2010. p. 49–73.