Hanyou 3015: a water-saving and drought-resistance rice cultivar for dry cultivation in southern China

Mengchen, Li; Wang, Feiming; Zhang, Jianfeng; Luo, Xingxing; Liu, Guolan; Yu, Xinqiao; Zhang, Anning; Luo, Lijun

doi:10.1590/1984-70332024v24n1c10

Abstract

Hanyou 3015 is a new Indica hybrid of water-saving and drought-resistance rice (WDR), combining rapid maturation and high yield potential. Whole genome sequencing results show that Hanyou 3015 carries many superior alleles that could explain its drought tolerance, high water use efficiency, rapid maturation, and wide adaptability.

Keywords:
Rice; breed; water-saving and drought-resistance rice; whole genome sequencing; drought tolerances

INTRODUCTION

Rice is the main food grain crop in China, and more than one-half of the population eats rice as the staple food. Consequently, providing for security of the rice supply becomes very necessary. However, rice production in China continues to face many challenges, such as drought and flooding (Luo et al. 2019Luo LJ, Mei HW, Yu XQ, Xia H, Chen L, Liu HY, Zhang AN, Xu K, Wei HB, Liu GL, Wang FM, Liu Y, Ma XS, Lou QJ, Feng FJ, Zhou LJ, Chen SJ, Yan M, Liu ZC, Bi JG, Li TF, Li MS2019 Water-saving and drought-resistance rice: from the concept to practice and theory. Molecular Breeding 39:145). The water shortage in agriculture in China is about 30 billion cubic meters, and the annual agricultural losses caused by water shortage are more than 150 billion yuan. The first aspect of these challenges is that rice growing is the largest user of agricultural water, representing about 70% of the total water used in agriculture in China and consuming about 50% of all the water used in the country (Luo et al. 2019, Zhang et al. 2022Zhang AN, Liu Y, Wang FM, Kong DY, Bi JG, Zhang FY, Luo XX, Wang JH, Liu JL, Luo LJ, Yu XQ2022 Molecular breeding of water-saving and drought-resistant rice for blast and bacterial blight resistance. Plants 11:2641). Drought is the most significant environmental stress in rice production. The occurrence of drought periods throughout the growth period of rice often leads to direct reductions in yield, especially during the reproductive growth period. Drought affects about 42 million hectares of rice in rainfed fields around the world annually, with yield reductions of up to 35% (Lanceras et al. 2004Lanceras JC, Pantuwan G, Jongdee B, Toojinda T2004 Quantitative trait loci associated with drought tolerance at reproductive stage in rice. Plant Physiology 135:384-399, Yue et al. 2006Yue B, Xue WY, Xiong LZ, Yu XQ, Luo LJ, Cui KH, Jin DM, Xing YZ, Zhang QF2006 Genetic basis of drought resistance at reproductive stage in rice: separation of drought tolerance from drought avoidance. Genetics 172:1213-1228). Secondly, the excessive use of irrigation water and the use of chemical fertilizers and pesticides in rice production have resulted in significant agricultural pollution and massive emissions of greenhouse gases, such as methane. For that reason, our aim is to breed water-saving and drought-resistance rice (WDR), which facilitates a new low-carbon, energy-saving, and environmentally friendly rice production system, mitigating the contradiction between supply and demand of water resources in China (Yu et al. 2016Yu XQ, Liu GL, Li MS, Pan ZQ, Zhang AN, Zhu JG, Luo LJ2016 Hanyou 73, a new water-saving and drought-resistant hybrid rice combination. Hybrid Rice 31:79-81).

The Shanghai Agrobiological Gene Center has taken WDR from concept to theory and practice and has successively bred Huhan 15, Huyou 2, Hanyou 73, Hanyou 113, Huhan 549, and other WDRs (Luo et al. 2019Luo LJ, Mei HW, Yu XQ, Xia H, Chen L, Liu HY, Zhang AN, Xu K, Wei HB, Liu GL, Wang FM, Liu Y, Ma XS, Lou QJ, Feng FJ, Zhou LJ, Chen SJ, Yan M, Liu ZC, Bi JG, Li TF, Li MS2019 Water-saving and drought-resistance rice: from the concept to practice and theory. Molecular Breeding 39:145). These WDR varieties have been widely cultivated in southern China (Yu et al. 2016Yu XQ, Liu GL, Li MS, Pan ZQ, Zhang AN, Zhu JG, Luo LJ2016 Hanyou 73, a new water-saving and drought-resistant hybrid rice combination. Hybrid Rice 31:79-81, Liu et al. 2022Liu GL, Yu XQ, Liu Y, Zhang AN, Wang FM, Luo LJ2022 Review and prospect on development of water-saving and drought-resistance rice (WDR) varieties. Acta Agriculturae Shanghai 38:20-25). Yet, WDR currently faces many challenges, for example, excessive plant height, a long whole growth period, and high seed production costs. Therefore, we developed the new WDR hybrid combination Hanyou 3015, which was registered and released for commercial production by the national crop variety appraisal committee in 2020. Hanyou 3015, derived from the CMS (cytoplasmic male sterility) line Huhan 7A and the restorer line Hanhui 3015, has the advantages of the water-saving trait, drought tolerance, early maturity, high yield, and wide adaptability. Its traits, breeding program, and crop management technology are presented in this article.

MATERIAL AND BREEDING METHOD

Hanyou 3015, derived from the CMS line Huhan 7A and the restorer line Hanhui 3015, is a new Indica hybrid rice combination developed by Shanghai Agrobiological Gene Center. The overall breeding scheme of Hanyou 3015 is shown in Figure 1.

Figure 1
Breeding process and identification of drought tolerance of Hanyou 3015. A. The breeding pedigree. B. Screening for drought tolerance in the mountainous area of Zhejiang Province in F3 populations, and single plants with good drought tolerance were selected. C. Screening for drought tolerance during the dry season of Hainan in F4 strains, and the strains with good drought tolerance were selected. D. Hanyou 3015 - water treatment photo of the field. E. Hanyou 3015 - drought treatment photo of the field. F. The large-scale dry cultivation of Hanyou 3015 in Anhui Province, 2021. G. Hanyou 73 - water treatment photo of the field. H. Hanyou 73 - drought treatment photo of the field.

Huhan 7A, derived from the testcross of an elite single plant selected from the progeny of the cross between the water-saving and drought-resistance maintainer line Huhan 1B and the fragrant maintainer line ‘WuxiangB/NeixiangB’ to Huhan 1A, followed by successive backcrosses, is a high-quality CMS line in rice. It has water-saving and drought-resistance traits, stable male sterility, fine grain quality, high outcrossing rate, and strong lodging resistance.

Hanhui 3015, derived from the cross between Hanhui 3 and Huanghuazhan, is an elite Indica CMS rice restorer line. The parent of Hanhui 3 is water saving and drought-resistance and has strong lodging resistance, whereas the other parent, Huanghuazhan, is well adapted to the ecosystems of southern China and exhibits high yield with good grain quality. The F₁ generation was cultivated in the 2011 summer season, while F₂ seeds were harvested in the 2011 winter season. The F₃ generation was directly seeded in the upland area to screen for drought-resistance in the 2012 summer season, and single plants with good drought-resistance were selected. In 2012, the F₄ strains were cultivated during the dry season of Hainan to continue screening for drought tolerance, and the strains with good drought tolerance were selected. The seeds gave rise to the F₆ generation, grown in the 2013 cycle. Through crossing with CMS lines and identification of hybrid advantages, one of the elite F₆ inbred lines was selected and designated as Hanhui 3015 (Figure 1).

The hybrid combination of Hanyou 3015, derived from Huhan 7A and Hanhui 3015, was evaluated in the national yield test network: regional trials (2018 and 2019) and the value for cultivation and production trail (2019) in southern China. In addition, distinctness, uniformity, and stability testing (DUS) of Hanyou 3015 were performed at Ministry of Agriculture and Rural Affairs，Shanghai Sub-Center for Plant New Variety Tests in the 2018 and 2019 seasons so as to better understand the traits of the cultivar. Table 1 illustrates some of the signatures identified in the DUS assay. Hanyou 3015 was upright and compact, with green leaf sheath color; stem diameter was medium; stem length was 98.17 cm; and the basal leaf sheath was green. The flag leaf was semi-erect.

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Table 1. Agronomic
and morphological traits of the WDR cultivar Hanyou 3015 according to the distinctness, uniformity, and stability (DUS) tests performed during the 2018 and 2019 crop cycles in Shanghai

For identification and evaluation of new water-saving and drought-resistance rice varieties in southern China in terms of drought tolerance, high yield, yield stability, adaptability, tolerance, rice quality, and other important traits, the varieties were tested for two consecutive years in 13 district trials in nine provinces (cities). There were 13 district trials in 9 provinces (cities) of Hunan, Hubei, Shanghai, and others. The regional trials were arranged in completely randomized groups, with three replications and a plot area of 13.34 m². The yield test was conducted in a randomized arrangement with no replications and a plot area of 333.5 m².

PERFORMANCE OF HANYOU 3015

Hanyou 3015 can be grown in southern China as a one-season rice. Its performance for major agronomic traits in two-year regional trials is as follows: The line was sown in mid to late May up to early June, grown in medium fertility soil, with the effective number of spikes of 3,180,000 ha^-1 in underwater direct seeding and under drought treatment; and the whole growth period was 111.7 d. Plant height was 106.8 cm, and spike length was 23.2 cm; the total number of grains per spike was 146.2; the seed setting rate was 85.8%; and 1,000 seed weight was 26.2 g (Table 2).

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Table 2
Yield traits of Hanyou 3015 at the National regional trial

The drought-resistance index of Hanyou 3015 is referred to technical specification for identification of water-saving and drought-resistance rice varieties (NY/T2863-2015 of China). For drought-resistance, Figure 1 showed that Hanyou 3015 performs well under drought field conditions (Supplementary Table 1). The drought-resistance index of Hanyou 3015 was 0.984 and 0.805 in two consecutive years; the drought tolerance degree was 2 and 2; and the synthetic evaluation of drought-resistance indicated a drought-tolerant level.

The results of comprehensive evaluation of resistance to major diseases and pests in the national WDR regional trial in 2018-2019 indicated that the combined index of rice blast of Hanyou 3015 was 4.75 and 4.22 in the two years, and the bacterial blight resistance index was at level 5 and 7. Hanyou 3015 had an index of resistance to brown planthopper at level 7 and 9 in the two years, and the overall evaluation showed susceptibility to rice blast, susceptibility to bacterial blight, and high susceptibility to brown planthopper. As tested by the Quality Supervision and Testing Center for Rice and Products of the Ministry of Agriculture and Rural Affairs (Wuhan), the main quality indices of Hanyou 3015 were as follows: head rice percentage of 51.1%, length to width ratio of 3.4, chalkiness degree of 4.8%, Grade 2 translucency, alkali spreading value of 6.5, gel consistency of 53 mm, and amylose content of 16.6%. The comprehensive evaluation of rice quality of Hanyou 3015 was within the ordinary standard of the ministry (Table 3).

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Table 3
Rice quality traits of Hanyou 3015 at the National regional trial

FUNCTIONAL GENE ANALYSIS OF HANYOU 3015

The respective SNPs of Huhan 7A and Hanhui 3015 were compared with those of Hanyou 3015, and the SNP loci consistent with Hanyou 3015 were ascertained. Next, the SNPs obtained in comparison of the two varieties were observed throughout the entire genome, and the differences in SNPs on different chromosome segments between the two parental species were also demonstrated. With the aim of analyzing functional genes in Hanyou 3015, Hanhui 3015, and Huhan 7A, genome-wide variation in the QTN loci was determined, and those loci associated with variation in functional traits were identified. The variation of the QTN loci in the whole genome was assessed, and gene loci leading to functional trait variation were found. Through the RiceNavi analysis (Wei et al. 2021Wei X, Qiu J, Yong K, Fan J, Zhang Q, Hua H, Liu J, Wang Q, Olsen KM, Han B, Huang Xh2021 A quantitative genomics map of rice provides genetic insights and guides breeding. Nature Genetics 53:243-253, Li et al. 2023Li Ql, Feng Q, Wang Hq, Kang Yh, Zhang Ch, Du M, Zhang Yh, Wang H, Chen J, Han B, Fang Y, Wang Ah2023 Genome-wide dissection of Quan 9311 a breeding process and application advantages. Rice Science 30:552-566), we found that Hanyou 3015 inherited the dominant alleles and co-dominant alleles of its parents Hanhui 3015 and Huhan 7A (Figure 2, Supplementary Table 2). Hanyou 3015 pyramided the superior alleles from Hanhui 3015, such as Rf3, NOG1, Hwi2ORF4, CYP78A13, GW8, Rf4, Rf1b, Hd17, D2, OsBRI1, APO1, TAC1, OsUGT706D1, Bph3, BPH29, and Xa3, as well as the superior alleles from Huhan 7A, namely, SaF, Sam, Rf2, GW7, Xa1, and OsTPP7.

Figure 2
Superior genes of Hanyou 3015 derived from Hanhui 3015 and Huhan 7A. The unique genes in Hanhui 3015 and Huhan7A are represented by yellow and green bars, respectively. The brown bar indicates the superior genes simultaneously contained in the two parent lines, and each bar represents a superior gene.

In examining the reasons for the excellent disease resistance and insect resistance of Hanyou 3015, the results showed that the brown planthopper resistance genes, such as Bph3 and BPH29, were inherited from Hanhui 3015. The genome of Hanyou 3015 retained the Xa1 mutant genotypes from Huhan 7A and the Xa3 mutant genotypes from Hanhui 3015. The rice blast resistance genes, RGA4 mutant genotypes from Huhan 7A, and the excellent disease resistance genes PiPR1, Pid2, Pid3, OsCERK1, and LHCB5 common to were inherited by Hanyou 3015; but most of these genes played an adjunct role of signal transmission in resisting the invasion of the pathogenic fungus. These genes contribute to rice blast resistance in Hanyou 3015.

For high rice quality and yield, Hanyou 3015 inherited superior genes from both parents, such as Badh2, a gene controlling rice fragrance, and GW7, a gene controlling grain length that are in Huhan 7A, and it retained CYP78A13 and GW8 that are in the genotype of Hanhui 3015. The activation of the CYP78A13 gene effectively adds value to the cells, and it has the potential to increase seed yield. GW8, also known as OsSPL16, increases both the length and width of the grain and improves its quality. Furthermore, the excellent genotypes OsLG3, GS3, GL3.2, and OsSPL13, shared by the two parents, have the effect of increasing the length and width of the grain. The gene NRT1.1B improves the nitrogen use efficiency of rice, and there is also the gene Gn1a, which increases the number of spikes on a single plant and thus improves rice yield.

CULTIVATION TECHNIQUES

In southern China, Hanyou 3015 could be grown in one rice season. In conformity with local ecological conditions, the number of seeds used for direct sowing in water is 15-22.5 kg ha^-1, and the number of seed used for direct sowing on dry land is 30-37.5 kg ha^-1. Recommendations are to mix the seeds with Thiacloprid, and then to sow sparingly and evenly. The level of fertilizer demand is medium, generally 150 kg ha^-1 of pure nitrogen, and a nitrogen, phosphorus, potassium dosage ratio of 1:0.5:0.7, making heavy application of bottom fertilization and timely application of tiller fertilization, and avoiding the late biased application of nitrogen fertilizer. Field water management in Hanyou 3015 is based on natural rainfall, and it doesn’t require establishment of a water layer; but when severe drought is encountered, especially during the seedling emergence stage, panicle differentiation stage, and filling stage, timely irrigation should be used to replenish water. Controlling weeds is a critical step in direct seeding of rice under dry conditions. First, 40% Benazolam closed weed control is sprayed in direct sowing in paddy fields, whereas pendimethalin and butachlor are applied in direct sowing in dry fields for closed weed control. Secondly, weeds are controlled by direct spraying of 50% quinclorac; and 10% cyhalofop-butyl is applied at the 3-leaf stage. Thirdly, in the late stage, noxious weeds are manually removed.

CONCLUSION

Hanyou 3105 is an early-maturing and high-yielding indica hybrid rice combination with the water-saving trait, drought tolerance, early maturity, short stem, excellent agronomic traits, and wide adaptability. It is suitable for planting in Southern China as a single crop season rice and could also be planted in direct seeding in wheat stubble.

ACKNOWLEDGMENTS

We are thankful for financial support from the earmarked fund for the China Agriculture Research System-Rice (CARS-01), the Bill and Melinda Gates Foundation (INV-033236-3), and the National Key Research and Development Program of China (2018YFE0106200). The data that support the findings of this study are available from the corresponding author upon reasonable request.

REFERENCES

Lanceras JC, Pantuwan G, Jongdee B, Toojinda T2004 Quantitative trait loci associated with drought tolerance at reproductive stage in rice. Plant Physiology 135:384-399
Li Ql, Feng Q, Wang Hq, Kang Yh, Zhang Ch, Du M, Zhang Yh, Wang H, Chen J, Han B, Fang Y, Wang Ah2023 Genome-wide dissection of Quan 9311 a breeding process and application advantages. Rice Science 30:552-566
Liu GL, Yu XQ, Liu Y, Zhang AN, Wang FM, Luo LJ2022 Review and prospect on development of water-saving and drought-resistance rice (WDR) varieties. Acta Agriculturae Shanghai 38:20-25
Luo LJ, Mei HW, Yu XQ, Xia H, Chen L, Liu HY, Zhang AN, Xu K, Wei HB, Liu GL, Wang FM, Liu Y, Ma XS, Lou QJ, Feng FJ, Zhou LJ, Chen SJ, Yan M, Liu ZC, Bi JG, Li TF, Li MS2019 Water-saving and drought-resistance rice: from the concept to practice and theory. Molecular Breeding 39:145
Wei X, Qiu J, Yong K, Fan J, Zhang Q, Hua H, Liu J, Wang Q, Olsen KM, Han B, Huang Xh2021 A quantitative genomics map of rice provides genetic insights and guides breeding. Nature Genetics 53:243-253
Yu XQ, Liu GL, Li MS, Pan ZQ, Zhang AN, Zhu JG, Luo LJ2016 Hanyou 73, a new water-saving and drought-resistant hybrid rice combination. Hybrid Rice 31:79-81
Yue B, Xue WY, Xiong LZ, Yu XQ, Luo LJ, Cui KH, Jin DM, Xing YZ, Zhang QF2006 Genetic basis of drought resistance at reproductive stage in rice: separation of drought tolerance from drought avoidance. Genetics 172:1213-1228
Zhang AN, Liu Y, Wang FM, Kong DY, Bi JG, Zhang FY, Luo XX, Wang JH, Liu JL, Luo LJ, Yu XQ2022 Molecular breeding of water-saving and drought-resistant rice for blast and bacterial blight resistance. Plants 11:2641

Publication Dates

Publication in this collection
08 Mar 2024
Date of issue
2024

History

Received
21 Aug 2023
Accepted
19 Oct 2023
Published
20 Dec 2024

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Lanceras JC, Pantuwan G, Jongdee B, Toojinda T2004 Quantitative trait loci associated with drought tolerance at reproductive stage in rice. Plant Physiology 135:384-399

[2] Li Ql, Feng Q, Wang Hq, Kang Yh, Zhang Ch, Du M, Zhang Yh, Wang H, Chen J, Han B, Fang Y, Wang Ah2023 Genome-wide dissection of Quan 9311 a breeding process and application advantages. Rice Science 30:552-566

[3] Liu GL, Yu XQ, Liu Y, Zhang AN, Wang FM, Luo LJ2022 Review and prospect on development of water-saving and drought-resistance rice (WDR) varieties. Acta Agriculturae Shanghai 38:20-25

[4] Luo LJ, Mei HW, Yu XQ, Xia H, Chen L, Liu HY, Zhang AN, Xu K, Wei HB, Liu GL, Wang FM, Liu Y, Ma XS, Lou QJ, Feng FJ, Zhou LJ, Chen SJ, Yan M, Liu ZC, Bi JG, Li TF, Li MS2019 Water-saving and drought-resistance rice: from the concept to practice and theory. Molecular Breeding 39:145

[5] Wei X, Qiu J, Yong K, Fan J, Zhang Q, Hua H, Liu J, Wang Q, Olsen KM, Han B, Huang Xh2021 A quantitative genomics map of rice provides genetic insights and guides breeding. Nature Genetics 53:243-253

[6] Yu XQ, Liu GL, Li MS, Pan ZQ, Zhang AN, Zhu JG, Luo LJ2016 Hanyou 73, a new water-saving and drought-resistant hybrid rice combination. Hybrid Rice 31:79-81

[7] Yue B, Xue WY, Xiong LZ, Yu XQ, Luo LJ, Cui KH, Jin DM, Xing YZ, Zhang QF2006 Genetic basis of drought resistance at reproductive stage in rice: separation of drought tolerance from drought avoidance. Genetics 172:1213-1228

[8] Zhang AN, Liu Y, Wang FM, Kong DY, Bi JG, Zhang FY, Luo XX, Wang JH, Liu JL, Luo LJ, Yu XQ2022 Molecular breeding of water-saving and drought-resistant rice for blast and bacterial blight resistance. Plants 11:2641

Descriptor	Phenotype
Flag leaf	Semi-erect
Leaf blade pubescence	Absent
Leaf ligule length	Medium
Leaf sheath color	Green
Culm length (cm)	Medium to long (98.17)
Panicle length (cm)	Medium to long (25.83)
Presence of awns	Absent
Spikelet stigma color	White
Spikelet glume color	Pale yellow
Length of hulled grains (mm)	8.39
Number of grains per spike	230.5
Seed setting rate (%)	93.33
Thousand seed weight (g)	26.9

Variety	Year	Yield (kg ha^-1)	Effective panicles (1000 ha^-1)	Plant height (cm)	Number of seeds per spike	Seed setting rate (%)	Thousand seed weight (g)
Hanyou 3015	2018	8,227.4	2910	106.9	150.3	86.7	26.8
Hanyou 3015	2019	8,251.2	3465	106.6	142.1	85.0	25.6
Hanyou 73	2018	7,924.5	2490	114.3	178.8	86.8	29.4
Hanyou 73	2019	7,850.3	2790	112.8	161.9	87.2	28.7

Variety	Year	Brown rice percentage (%)	Head rice percentage (%)	Chalkiness degree (%)	Translucency	Alkali spreading value	Gel consistency (mm)	Amylose content (%)	Ratio of length and width
Hanyou 3015	2018	70.5	53.6	6.3	2	4.5	67	14.9	3.3
Hanyou 3015	2019	80.0	51.1	4.8	2	6.5	53	16.6	3.4
Hanyou 73	2018	72.3	55.9	3.5	2	5.0	75	14.6	3.2
Hanyou 73	2019	80.6	40.8	3.8	1	6.5	65	14.3	3.4

Brasil

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Hanyou 3015: a water-saving and drought-resistance rice cultivar for dry cultivation in southern China

Abstract

INTRODUCTION

MATERIAL AND BREEDING METHOD

PERFORMANCE OF HANYOU 3015

FUNCTIONAL GENE ANALYSIS OF HANYOU 3015

CULTIVATION TECHNIQUES

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History