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Research Article

Discovery of Genomic Regions and Candidate Genes for Awn Length Using QTL-seq in Rice (Oryza sativa L.)

Plant Breeding and Biotechnology 2023;11(4):271-277.
Published online: December 1, 2023

1Department of Plant Bioscience, Pusan National University, Miryang 50463, Korea

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*Corresponding author Soon-Wook Kwon, swkwon@pusan.ac.kr, Tel: +82-55-350-5506, Fax: +82-55-350-5509

These authors contributed equally.

• Received: November 20, 2023   • Revised: November 27, 2023   • Accepted: November 28, 2023

Copyright © 2023 by the Korean Society of Breeding Science

This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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  • Rice domestication has led to cultivated rice with no or short awns. Discovery of novel genes associated to awn length is of paramount importance for understanding the molecular mechanisms for the transformation of wild rice long awns to awnless cultivated rice. In this study, we employed Next-Generation Sequencing based QTL-seq approach to identify genomic regions associated with awn length using mapping population derived from a cross between awnless Tun Sart and awned Sobaekmangsudo. QTL-seq analysis identified two awn length QTLs viz. qAwn-4 (12.8-20.3 Mb) and qAwn-8 (22.3-27.2 Mb) on chromosome 4 and 8, respectively. Based on the sequence comparison between the two parents, Os04g0350700 (bHLH transcription factor) was postulated to be the candidate of Awn-4 gene. Further discovery of the novel genes in qAwn-8 interval will provide insights into the genetic architecture of awn length.
Rice is originated from wild rice (O. rufipogon Girff.) through domestication. This considerably changed the morpho-physiological characteristics of wild rice to in-crease cultivation efficiency, grain quality, and rice yield (Fuller et al. 2010; Huang et al. 2012). Compared to wild rice, cultivated rice typically exhibits favorable charac-teristics including erect growth, no or short awns, increased spikelet number per panicle, closed panicle, and reduced seed shattering and dormancy, all of which changed dramati-cally during domestication (Kovach et al. 2007; Sweeney and McCouch 2007).
Awn, a long extension of the lemma tip, helps seed dis-persal by wind and by sticking to human cloths or animal fur while providing seed protection from predators under natural conditions (Elbaum et al. 2007; Svizzero et al. 2019). In barley and wheat, awns also photosynthesize which contributes to grain filling (Abebe et al. 2009; Maydup et al. 2010; Guo and Schnurbusch 2016). In contrast, rice awns are not photosynthetically active because of the absence of chlorenchyma tissues (Toriba and Hirano 2014; Ntakirutimana and Xie 2019). Moreover, in agriculture, awns are inconvenient for harvesting, threshing, packing and storage (Takahashi et al. 1986). Hence, rice domesti-cation has led to cultivated rice with no or short awns (Luo et al. 2013).
Regent studies of the genetic mechanisms underlying the development of rice awns have suggested that awn devel-opment is a complex trait controlled by multiple genes. A total of 21 QTLs with major and minor effect on rice awn length in rice have been reported in the Gramene database (https://archive.gramene.org/). However, only a few major QTLs have been identified and characterized at the molecular level. An-1/RAE1 encodes a basic helix-loop-helix (bHLH) transcription factor that regulates the formation of awn primordia, cell division and grain length and reduces the grain number in wild rice (Luo et al. 2013). An-2/LABA1 encodes a cytokinin synthesis enzyme that promotes awn elongation by increasing cytokinin concentration in the awn primordia. It reduces the number of grains per panicle and tiller number per plant (Gu et al. 2015; Hua et al. 2015). RAE2/GAD1/GLA encodes a secreted signal peptide that regulates awn development as well as the number of grains per panicle and grain length (Bessho-Uehara et al. 2016; Jin et al. 2016; Zhang et al. 2019). The YABBY trans-cription factor DL, auxin responsive factor OsETTIN2, and RNA-dependent RNA polymerase SHL2 are also involved in awn formation (Toriba and Hirano 2014).
To identify novel genomic regions associated with awn length, we have performed QTL-seq (Takagi et al. 2013), a combination of bulk segregant analysis (BSA) and whole genome re-sequencing of DNA pools. An F2 population derived from a cross between Tun Sart (an awnless cul-tivar) and Sobaekmangsudo(an awned cultivar) were used. This study will provide a valuable genetic resource for future molecular breeding in rice.
Plant materials
Two japonica rice cultivars [awnless Tun Sart (IT 004483) and awned Sobaekmangsudo (IT 006737)] were used as parental lines to develop the 197 F2 population. [To simplify the following description, we represent Tun Sart as RWG-45 and Sobaekmangsudo as RWG-111]. RWG-45 and RWG-111 are part of the 137 KRICE_CORE pop-ulation (Kim et al. 2016) and both seeds were received from the Rural Development Administration (RDA) gene bank, Korea. F2 population was obtained from Pusan national University, Miryung, Korea.
Awn length evaluation
Phenotyping was carried out at Pusan University, Miryang, Korea using 197 individual F2 plants of RWG-45 × RWG-111. Three main panicles of each plant were used for pheno-typing and the awn length of the whole panicle was re-presented by the average of apical spikelets on each primary branch. Measuring the awn lengths was carried out two weeks after heading to avoid the awn breakage.
Construction of segregating pools
All young leaves of 197 individual F2 plants were col-lected separately for total genomic DNA extraction using CTAB method (Porebski et al. 1997), with minor modi-fications. The genomic DNA of 23 individuals with ex-tremely short awn (ESA) and 30 extremely long awn (ELA) were selected as two bulked pools of the F2 popula-tion. Isolated DNA was quantified using a Nanodrop spectrophotometer (Thermo Scientific, Wilmington, USA). Equal amounts of DNA from the ESA and ELA individuals were mixed.
QTL-seq analysis
Total genomic DNA was extracted from two bulked pools, and it was used to construct paired-end libraries with an insert size of 151 bp using TruSeq Nano DNA Kit (Illumina, San Diego, CA, USA). These libraries were sequenced using the Illumina NGS platform at Macrogen (Seoul, Korea). After sequencing, raw reads filtering was performed by fastp program (Chen et al. 2018). This data was aligned to the Nipponbare reference genome (IRGSP) by using the BWA program (Li and Durbin 2009). Samtools and GATK were used to clean the BAM file and for SNP variation calling, respectively (Li et al. 2009; McKenna et al. 2010). VCF file was filtered by vcftools (Danecek et al. 2011) to obtain high quality genotype data. The QTL-seq pipeline (QTL-seq version 2.1.3) (Takagi et al. 2013; Sugihara et al. 2022) was used for mapping the QTLs for Awn genes.
Prediction of candidate genes
To predict possible candidate genes associated with awn length, the following strategies were employed. First, we compared the DNA sequences of genes within the QTL regions between the two parents using the whole-genome DNA re-sequencing results to predict the candidate genes. Second, comparing the results with known genes/QTLs for awn length on 12 chromosomes in rice. Third, candidate genes were reselected according to their functional anno-tation from the rice genome database (http://rice.uga.edu/).
Evaluation of the awn length
The awn length of the two parental cultivars, RWG-45 and RWG-111 (Fig. 1A) along with their 197 F2 population (Fig. 1B), were evaluated two weeks after heeding. Sig-nificant difference of the awn length was observed between the two parents. The F2 population showed awn length variation from 0.3 to 112.5 mm (Fig. 1B). Among the 197 F2 individuals, 23 extremely short awn and 30 extremely long awn plants were selected to prepare the ESA-pool and ELA-pool, respectively, which were then used for DNA re-sequencing.
Whole-genome sequencing and SNP identification
We performed high-throughput genome sequencing using four samples including RWG-45, RWG-111, ESA-pool, ELA-pool and obtained a total of 238.9 million reads and 32.6 Gb of raw data (Table 1). After cleaning the data by fastp, the average GC content was 42.310% and the Q30 of all the samples reached more than 91%. The mapped ratios between samples and the Nipponbare genome were 98.34%, 98.93%, 98.89%, and 98.94%, respectively. Most samples except RWG-111 (81.92%) showed properly paired ratio higher than 94% and unmapped ratio of all the sam-ples was lower than 1.7%. The average genome-coverage depth was 22X and the genome coverage was higher than 98%. These results suggest that the resequencing quality is confirmed and they could be used for the following analysis.
We obtained a total of 735,910 variants those were including 583,569 SNPs and 152,341 indels from the sam-ples. Among the 1,213.9 K annotations, 619.6 K, 51.4 K, and 22.3 K were located at intergenic region, intron, and exon, respectively. 10.2 K and 8.4 K of the annotations lo-cated at the exon region were non-synonymous and syn-onymous, respectively (Table 2).
QTL-seq analysis and sequence comparison of the candidate genes
Two major peaks on chromosome 4 and 8 were iden-tified for awn length and named as qAwn-4 and qAwn-8, respectively (Fig. 2). The qAwn-4 was spanning 7.5-Mb (12.8-20.3 Mb) intervals on chromosome 4 and the accu-racy of this QTL was ascertained by a valid 99% Δ(SNP- index) significance level (Fig. 2A, Table 3). The other QTL, qAwn-8, was spanning 4.9-Mb (22.3-27.2 Mb) inter-vals on chromosome 8 and the accuracy of this QTL was ascertained by a valid 95% Δ(SNP-index) significance level (Fig. 2B, Table 3). The qAwn-4 coding region har-bored 1,352 SNPs and 302 indels, and the qAwn-8 coding region harbored 880 SNPs and 254 indels (data not shown).
Genomic sequence comparison was made between the two parents based on the genes that were previously reported on the identified QTL regions. The An-1 (Os04g0350700), a major gene that regulates awn development, was located in the qAwn-4 region. One SNP was identified in the second exon between awnless and awned plants in Os04g0350700 (Fig. 3). Another major gene RAE2 (Os08g0485500) was located in the qAwn-8 region. However, no nucleotide variants were found between awnless and awned plants indicating the existence of a novel gene contributing to awn length (data not shown). Further analysis will be performed to narrow down the candidate region and to discover the novel genes.
Morpho-physiological traits of wild species have been modified to meet human needs during crop domestication. Wild rice typically exhibits long awns that help in seed dispersal and provide protection from predators under nat-ural conditions. However, in agriculture, long awns are inconvenient for pre-harvesting and post-harvesting because of its structure. Hence, rice domestication has led to culti-vated rice with no or short awns. Recently, studies have been conducted to elucidate the genetic mechanisms under-lying the rice awn development. Although several genes/ QTLs associated with awn development have been detected, only a few major QTLs have been cloned and characterized at the molecular level.
To identify the novel QTLs for awn length, two DNA pools with extreme phenotypic difference were used to perform QTL-seq analysis. We used the Δ(SNP-index) algorithm approach to map QTL regions at the 95% or 99% significance level. Two highly significant peaks (qAwn-4 and qAwn-8) were detected on chromosome 4 and 8, with the former mapped between 12.8-20.3 Mb and the latter between 22.3-27.2 Mb (Fig. 2).
QTLs and genes for awn length on chromosome 4 and 8 have been previously reported. The An-1 encoding a bHLH transcription factor was identified from wild rice (O. rufipogon) and it regulates long awn formation (Luo et al. 2013). This gene was detected in qAwn-4 region. In chromosome 8, the location of qAwn-8 in the present study was containing the previously reported gene, RAE2 that encodes one member of the epidermal patterning factor-like protein (EFPL) family regulating awn formation (Bessho- Uehara et al. 2016; Jin et al. 2016; Zhang et al. 2019).
Comparison between the genomic sequences of the two parents revealed that one SNP difference in the coding region of An-1 (Fig. 3), in which +244-bp (A > G) changes the amino acid sequence, suggesting that this SNP might be involved in awn formation and elongation. However, no SNPs were found between the sequence of the two parents in the coding region of RAE2 suggesting that a novel gene associated to awn length might exist in the interval of qAwn-8 which warrants further exploration. Therefore, further discovery of the novel genes will provide insights into the genetic architecture of awn length.
This work was supported by the Rural Development Administration, Republic of Korea (RS-2022-RD010201). 
Fig. 1
Comparison of the awn phenotypes between RWG- 45 and RWG-111. (A) Phenotypic comparison of seed arrays from mature spikelets of RWG-45 (left) and RWG-111 (right). (B) Frequency distribution of the awn length in the F2 population (RWG-45 × RWG-111).
pbb-11-4-271-f1.jpg
Fig. 2
Single nucleotide polymorphism (SNP)-index charts. (A and B) SNP-index charts of awnless-pool (green), awned- pool (orange), and corresponding Δ(SNP-index) plots (blue) with 95-99% confidence interval borders of RWG-45 × RWG-111 for chromosome 4 (A) and chromosome 8 (B). Average values of Δ(SNP-index) are plotted with a 2 Mb sliding window and a 50 kb increment.
pbb-11-4-271-f2.jpg
Fig. 3
Sequence variation in an-1, awn-4, and Awn-4. The common variations among Nipponbare, RWG-45, and RWG-111 are indicated in this figure. Black bars represent introns and grey boxes represent coding regions. Bar = 1 kb.
pbb-11-4-271-f3.jpg
Table 1
Quantity of genome sequence obtained for each sample.
Table 1
Sample
ID
Total
reads
Total base GC
(%)
AT
(%)
Q20
(%)
Q30
(%)
Mapped
(%)
Properly
paired (%)
Unmapped
(%)
Average
depth
Genome
coverage (%)
RWG-045 31,616,276 3,190,458,278 39.8 60.2 97.0 92.1 98.34 94.18 1.66 10X 98.33
RWG-111 36,820,718 3,679,271,766 41.9 58.1 97.1 92.4 98.93 81.92 1.06 11X 98.50
ESA-pool 84,862,982 12,814,310,282 43.7 56.3 96.5 91.1 98.89 95.79 1.04 34X 99.98
ELA-pool 85,611,904 12,927,397,504 43.9 56.1 96.8 91.6 98.94 95.92 1.09 33X 99.98
Table 2
SNPs identified among two parents and two mixed pools.
Table 2
Type Number Ratio (%)
SNP 583,569 79.30
MNP 0 0
INS 75,284 10.23
DEL 77,057 10.47
3’UTR 11,772 0.97
5’UTR 8,661 0.71
Downstream 205,221 16.93
Exon 22,380 14.52
Intergenic 619,687 51.12
Intron 51,482 4.25
Splice site acceptor 75 0.01
Splice site donor 81 0.01
Splice site region 1,360 0.11
Transcript 79,433 6.55
Upstream 212,115 17.50
Missense 10,208 54.32
Nonsense 160 0.85
Silent 8,425 44.83
Table 3
QTLs associated with awn development identi-fied using QTL-seq.
Table 3
QTL name Chr. Start (Mb) End (Mb) Peak
qAwn-4 4 12.8 20.3 ‒0.6010
qAwn-8 8 22.3 27.2 ‒0.4153
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Discovery of Genomic Regions and Candidate Genes for Awn Length Using QTL-seq in Rice (Oryza sativa L.)
Plant Breed. Biotech.. 2023;11(4):271-277.   Published online December 1, 2023
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Discovery of Genomic Regions and Candidate Genes for Awn Length Using QTL-seq in Rice (Oryza sativa L.)
Plant Breed. Biotech.. 2023;11(4):271-277.   Published online December 1, 2023
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Discovery of Genomic Regions and Candidate Genes for Awn Length Using QTL-seq in Rice (Oryza sativa L.)
Image Image Image
Fig. 1 Comparison of the awn phenotypes between RWG- 45 and RWG-111. (A) Phenotypic comparison of seed arrays from mature spikelets of RWG-45 (left) and RWG-111 (right). (B) Frequency distribution of the awn length in the F2 population (RWG-45 × RWG-111).
Fig. 2 Single nucleotide polymorphism (SNP)-index charts. (A and B) SNP-index charts of awnless-pool (green), awned- pool (orange), and corresponding Δ(SNP-index) plots (blue) with 95-99% confidence interval borders of RWG-45 × RWG-111 for chromosome 4 (A) and chromosome 8 (B). Average values of Δ(SNP-index) are plotted with a 2 Mb sliding window and a 50 kb increment.
Fig. 3 Sequence variation in an-1, awn-4, and Awn-4. The common variations among Nipponbare, RWG-45, and RWG-111 are indicated in this figure. Black bars represent introns and grey boxes represent coding regions. Bar = 1 kb.
Discovery of Genomic Regions and Candidate Genes for Awn Length Using QTL-seq in Rice (Oryza sativa L.)

Quantity of genome sequence obtained for each sample.

Sample
ID
Total
reads
Total base GC
(%)
AT
(%)
Q20
(%)
Q30
(%)
Mapped
(%)
Properly
paired (%)
Unmapped
(%)
Average
depth
Genome
coverage (%)
RWG-045 31,616,276 3,190,458,278 39.8 60.2 97.0 92.1 98.34 94.18 1.66 10X 98.33
RWG-111 36,820,718 3,679,271,766 41.9 58.1 97.1 92.4 98.93 81.92 1.06 11X 98.50
ESA-pool 84,862,982 12,814,310,282 43.7 56.3 96.5 91.1 98.89 95.79 1.04 34X 99.98
ELA-pool 85,611,904 12,927,397,504 43.9 56.1 96.8 91.6 98.94 95.92 1.09 33X 99.98

SNPs identified among two parents and two mixed pools.

Type Number Ratio (%)
SNP 583,569 79.30
MNP 0 0
INS 75,284 10.23
DEL 77,057 10.47
3’UTR 11,772 0.97
5’UTR 8,661 0.71
Downstream 205,221 16.93
Exon 22,380 14.52
Intergenic 619,687 51.12
Intron 51,482 4.25
Splice site acceptor 75 0.01
Splice site donor 81 0.01
Splice site region 1,360 0.11
Transcript 79,433 6.55
Upstream 212,115 17.50
Missense 10,208 54.32
Nonsense 160 0.85
Silent 8,425 44.83

QTLs associated with awn development identi-fied using QTL-seq.

QTL name Chr. Start (Mb) End (Mb) Peak
qAwn-4 4 12.8 20.3 ‒0.6010
qAwn-8 8 22.3 27.2 ‒0.4153
Table 1 Quantity of genome sequence obtained for each sample.
Table 2 SNPs identified among two parents and two mixed pools.
Table 3 QTLs associated with awn development identi-fied using QTL-seq.