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Modulating plant growth–metabolism coordination for sustainable agriculture

Abstract

Enhancing global food security by increasing the productivity of green revolution varieties of cereals risks increasing the collateral environmental damage produced by inorganic nitrogen fertilizers. Improvements in the efficiency of nitrogen use of crops are therefore essential; however, they require an in-depth understanding of the co-regulatory mechanisms that integrate growth, nitrogen assimilation and carbon fixation. Here we show that the balanced opposing activities and physical interactions of the rice GROWTH-REGULATING FACTOR 4 (GRF4) transcription factor and the growth inhibitor DELLA confer homeostatic co-regulation of growth and the metabolism of carbon and nitrogen. GRF4 promotes and integrates nitrogen assimilation, carbon fixation and growth, whereas DELLA inhibits these processes. As a consequence, the accumulation of DELLA that is characteristic of green revolution varieties confers not only yield-enhancing dwarfism, but also reduces the efficiency of nitrogen use. However, the nitrogen-use efficiency of green revolution varieties and grain yield are increased by tipping the GRF4–DELLA balance towards increased GRF4 abundance. Modulation of plant growth and metabolic co-regulation thus enables novel breeding strategies for future sustainable food security and a new green revolution.

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Fig. 1: DELLA accumulation inhibits growth, nitrogen response and nitrogen uptake of rice and wheat GRVs.
Fig. 2: GRF4 regulates rice \({{\bf{NH}}}_{{\bf{4}}}^{{\boldsymbol{+}}}\) uptake and growth response to nitrogen availability.
Fig. 3: GRF4 regulates expression of multiple nitrogen-metabolism genes.
Fig. 4: Competitive GRF4–GIF1–SLR1 interactions coordinate \({{\bf{NH}}}_{{\bf{4}}}^{{\boldsymbol{+}}}\) uptake and assimilation.
Fig. 5: Increased GRF4 abundance boosts grain yield and NUE of rice and wheat GRVs without increasing mature plant height.

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Acknowledgements

We thank J. F. Ma for comments on this manuscript. This research was supported by grants from the National Key Research and Development Program of China (2016YFD0100401, 2016YFD0100706 and 2016YFD0100901), National Natural Science Foundation of China (91635302), Chinese Academy of Sciences (XDA08010101) and by the Biological and Biotechnological Sciences Research Council (UK) ‘Newton Fund’ Rice Research Initiative grant BB/M011224/1.

Reviewer information

Nature thanks B. Hirel, M. Matsuoka and the other anonymous reviewer(s) for their contribution to the peer review of this work.

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Authors and Affiliations

Authors

Contributions

S.L. performed most of the experiments; Y.Ti. and S.L. conducted QTL analysis; S.L., J.Z. and K.W. constructed near isogenic lines; S.L., Y.Y. and Q.L. performed field experiments; Y.To., M.H. and H.L. characterized the phenotypes of transgenic wheat plants; J.Y. performed haplotype analysis; N.P.H. and X.F. designed experiments; N.P.H. and X.F. wrote the manuscript. All authors discussed the results and contributed to the manuscript.

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Correspondence to Xiangdong Fu.

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Extended data figures and tables

Extended Data Fig. 1 Allelic variation at the GRF4 locus affects GRF4 mRNA abundance and root \({}^{{\bf{15}}}{{\bf{NH}}}_{{\bf{4}}}^{{\boldsymbol{+}}}\) uptake.

a, Positional cloning indicates the equivalence of GRF4 with qNGR2 (nitrogen-mediated growth response 2). Successive maps show progressive narrowing of focus of qNGR2 (red dot, using recombination break points and linked DNA markers) to an approximately 2.7-kb region on chromosome 2 flanked by molecular markers L17 and L18 and overlapping candidate gene LOC_02g47280 (also known as GRF4). The start ATG (nucleotide 1) and close TGA (nucleotide 3385) of GRF4 are shown, together with the protein-coding DNA sequence (thick black bars). The target site for miR396 is indicated by an asterisk. The structure of a CRISPR–Cas9-generated grf4 mutant 91-bp deletion allele spanning parts of exon 1 and intron 1 is shown. b, \({}^{15}{{\rm{NH}}}_{4}^{+}\) uptake rates of roots of BC2F2 progeny (derived from a NJ6 × NM73 cross) homozygous or heterozygous for GRF4NGR2 or GRF4ngr2 grown in high nitrogen supply (1.25 mM NH4NO3). Data are mean ± s.e.m. (n = 9). Different letters denote significant differences (P < 0.05) from a Duncan’s multiple range test. c, GRF4 mRNA abundance in plants (genotypes as shown) relative to the abundance in NJ6 (set to one). Data are mean ± s.e.m. (n = 3). Different letters denote significant differences (P < 0.05) from a Duncan’s multiple range test. d, Natural varietal GRF4 allelic variation. Nucleotide position relative to the GRF4 start ATG is shown in a. SNPs shared between varieties NM73, RD23 and TZZL1 are highlighted. Sequences representative of GRF4 promoter haplotypes A, B and C (see main text) are shown. e, GRF4 mRNA abundance in various rice varieties under the high nitrogen conditions (1.25 mM NH4NO3), GRF4 promoter haplotypes are indicated. Abundance data are all relative to the abundance of rice Actin2 mRNA. Data are mean ± s.e.m. (n = 3). Different letters denote significant differences (P < 0.05) from a Duncan’s multiple range test. f, Comparisons of GRF4 mRNA abundance in selected rice varieties grown in between high (HN, 1.25 mM NH4NO3) and low (LN, 0.375 mM NH4NO3) nitrogen conditions. Data are mean ± s.e.m. (n = 3). Abundance data are all relative to the high nitrogen condition (set to one). **P < 0.05 compared to high nitrogen in a two-sided Student’s t-test. g, Relative abundances of rice miR396 family members in NJ6 plants grown at different levels of nitrogen supply (0.15N, 0.1875 mM NH4NO3; 0.3N, 0.375 mM NH4NO3; 0.6N, 0.75 mM NH4NO3; 1N, 1.25 mM NH4NO3), shown relative to the abundance in plants grown in 1N conditions (set to one). Data are mean ± s.e.m. (n = 3). Different letters denote significant differences (P < 0.05) from a Duncan’s multiple range test.

Extended Data Fig. 2 Comparisons NJ6, NJ6-sd1 and NJ6-sd1-GRF4ngr2 isogenic line traits reveals that GRF4 regulates expression of \({{\bf{NH}}}_{{\bf{4}}}^{{\boldsymbol{+}}}\)-metabolism genes.

a, Mature plant height. Data are mean ± s.e.m. (n = 16). b, The number of tillers per plant. Data are mean ± s.e.m. (n = 16). c, The number of grains per panicle. Data are mean ± s.e.m. (n = 16). d, Flag-leaf width. Data are mean ± s.e.m. (n = 16). e, Culm (stem) width expressed as diameter of the uppermost internode. Data are mean ± s.e.m. (n = 16). f, Grain yield per plant. Data are mean ± s.e.m. (n = 220). g, Relative root abundance of AMT1.2 mRNA in NILs, genotypes as indicated. Abundances shown are relative to NJ6 plants (set to 1). Data are mean ± s.e.m. (n = 3). h, Root glutamine synthase (GS) activities. Data are mean ± s.e.m. (n = 3). i, Relative shoot abundance of Fd-GOGAT mRNA. Abundances shown are relative to NJ6 plants (set to 1). Data are mean ± s.e.m. (n = 3). j, Shoot glutamine synthase (GS) activities. Data are mean ± s.e.m. (n = 3). k–n, Flag–GRF4-mediated ChIP–PCR enrichment (relative to input) of GCGG-containing promoter fragments (marked with an asterisk) from AMT1.2, GS2, NADH-GOGAT2 and Fd-GOGAT promoters. Diagrams depict putative AMT1.2, GS2, NADH-GOGAT2 and Fd-GOGAT promoters and fragments (1–6). Data are mean ± s.e.m. (n = 3; panels k–n). an, Different letters denote significant differences (P < 0.05) from a Duncan’s multiple range test. o, GRF4 activates AMT1.2, GS2, NADH-GOGAT2 and Fd-GOGAT promoter–luciferase fusion constructs in transient transactivation assays. Data are mean ± s.e.m. (n = 3). **P < 0.05 compared to control group by two-sided Student’s t-tests.

Extended Data Fig. 3 GRF4 regulates expression of multiple \({{\bf{NO}}}_{{\bf{3}}}^{{\boldsymbol{-}}}\) metabolism genes.

a, Relative abundance of NRT1.1B, NRT2.3a and NPF2.4 mRNAs that encode \({{\rm{NO}}}_{3}^{-}\) uptake transporters. Abundances shown are relative to NJ6 (set to 1). Data are mean ± s.e.m. (n = 3). b, Relative abundances of NIA1, NIA3 and NiR1 mRNAs that encode \({{\rm{NO}}}_{3}^{-}\)-assimilation enzymes. Abundances shown are relative to NJ6 (set to 1). Data are mean ± s.e.m. (n = 3). c–h, Flag–GRF4-mediated ChIP–PCR enrichment (relative to input) of GCGG-containing fragments (marked with asterisks) from promoters of NRT1.1B (c), NRT2.3a (d) and NPF2.4 (e) genes that encode \({{\rm{NO}}}_{3}^{-}\)-uptake transporters and NIA1 (f), NIA3 (g) and NiR1 (h) genes that encode \({{\rm{NO}}}_{3}^{-}\)-assimilation enzymes. Data are mean ± s.e.m. (n = 3). ah, Different letters denote significant differences (P < 0.05) from a Duncan’s multiple range test. i, GRF4 activates NRT1.1B, NRT2.3a, NPF2.4, NIA1, NIA3 and NiR1 promoter–luciferase fusion constructs in transient transactivation assays. Data are mean ± s.e.m. (n = 3) in all panels. P values are from a two-sided Student’s t-test.

Extended Data Fig. 4 GA promotes glutamine synthase and nitrate reductase activities.

a, Glutamine synthase activities in roots of two-week-old rice plants treated with 100 μM GA (GA3) and/or 2 μM PAC, genotypes as indicated. b, Glutamine synthase activities in shoots of plants treated with GA and/or PAC, genotypes and treatments as indicated in a. c, Nitrate reductase activities in shoots of plants treated with GA and/or PAC, genotypes and treatments as indicated in a. ac, Data are mean ± s.e.m. (n = 3); P values are from two-sided Student’s t-tests.

Extended Data Fig. 5 BiFC visualization of SLR1–GIF1–GRF4 interactions.

a, Details of constructs expressing GRF4 and variants deleted for specific domains. GRF4 contains the QLQ and WRC domains, positions as indicated. b, BiFC assays. Constructs expressing GRF4 or deletion variants (shown as in a) tagged with the N terminus of YFP were co-transformed into tobacco leaf epidermal cells, together with constructs expressing GIF1 or SLR1 tagged with the C terminus of YFP, respectively. Scale bars, 60 μm. c, BiFC assays. Constructs expressing GRF1 or related GRFs and GIFs family proteins tagged with the N terminus of YFP were co-transformed into tobacco leaf epidermal cells together with a construct expressing SLR1 tagged with the C terminus of YFP. Scale bar, 60 μm. b, c, Images of BiFC assays are representative of three experiments performed independently with similar results.

Extended Data Fig. 6 SLR1 inhibits GRF4–GIF1 self-promotion of GRF4 mRNA and GRF4 protein abundance.

a, GFR4 mRNA abundance, plant genotypes as indicated. Abundances shown are relative to NJ6 (set to 1). b, The effects of GA and PAC on GRF4 mRNA abundance in two-week-old NJ6 plants. Abundances shown are relative to the water treatment control (set to 1). c, ChIP–PCR GRF4-mediated enrichment (relative to input) of GCGG-containing GRF4 promoter fragments (marked with asterisks). d, GRF4-activated promotion of transcription from the GRF4 gene promoter-luciferase reporter construct is enhanced by GIF1 and inhibited by SLR1. Luciferase/renilla activity shown relative to the empty vector control (set to 1). ad, Data are mean ± s.e.m. (n = 3). Different letters denote significant differences (P < 0.05) from Duncan’s multiple range tests. e, GRF4 abundance (as detected by an anti-GRF4 antibody), plant genotypes as indicated. HSP90 serves as loading control. Blots are representative of three experiments performed independently with similar results.

Extended Data Fig. 7 The GRF4–SLR1 antagonism regulates carbon assimilation and plant growth.

a, b, Relative shoot abundances of carbon-fixation gene mRNAs. Abundances of transcripts of genes regulating photosynthesis (a), sucrose metabolism and transport/phloem loading (b) in NJ6, NJ6-sd1 and NJ6-sd1-GRF4ngr2 plants. Abundances in NJ6 and NJ6-sd1-GRF4ngr2 are expressed relative to NJ6-sd1 (set to 1). c, ChIP–PCR assays. Diagrams depict the PsbS1, TPS1 and SWEET11 promoters and regions used for ChIP–PCR, and GCGG-containing promoter fragment (marked with asterisks) enrichment (relative to input). ac, Data are mean ± s.e.m. (n = 3). d, Transactivation assays. The luciferase/renilla activity obtained from a co-transfection with an empty effector construct and indicated reporter constructs was set to 1. Data are mean ± s.e.m. (n = 9). e, Immunoblot detection of Lhca1, Lhca3, Lhca4, Lhcb2, PsaD and PsaE using antibodies as shown in genotypes as indicated. HSP90 serves as loading control. Blots are representative of three experiments performed independently with similar results. f–i, Comparisons of photosynthetic rates (f), biomass (g), carbon content (h) and C:N ratio (i) in NJ6, NJ6-sd1 and NJ6-sd1-GRF4ngr2 plants. Data are mean ± s.e.m. (n = 30). j, Relative shoot abundances of mRNAs transcribed from cell-cycle regulatory genes in NJ6, NJ6-sd1 and NJ6-sd1-GFR4ngr2 plants. Transcription is relative to NJ6-sd1 plants (set to 1). Data are mean ± s.e.m. (n = 3). k, ChIP–PCR assays. Diagrams depict the cycA1.1 and cdc2Os-3 promoters and regions (GCGG-containing fragment marked with asterisks) used for ChIP–PCR. Data are mean ± s.e.m. (n = 3). l, Transactivation assays from the cycA1.1and cdc2Os-3 promoters. Data are mean ± s.e.m. (n = 12). ad, fl, Different letters denote significant differences (P < 0.05) from Duncan’s multiple range tests.

Extended Data Fig. 8 Natural allelic variation at GRF4 is associated with variation in plant and grain morphology and grain yield performance.

a, DNA polymorphisms in the promoter region of GRF4. Green-shaded regions indicate the three unique SNP variations associated with phenotypic variation in NM73 and RD23. b–f, Box plots for plant height (b), grain length (c), grain width (d), the number of grains per panicle (e) and grain yield performance (f) of rice varieties carrying different GRF4 promoter haplotypes (Hap. A, B or C). All data are from plants grown under normal paddy-field fertilization conditions22. Data are mean ± s.e.m. (Hap. A, n = 74; Hap. B, n = 28; Hap. C, n = 123). The violin plot was constructed in R. bf, Different letters indicate statistically significant differences between groups (P < 0.05) from a Tukey’s honestly significant difference (HSD) test.

Extended Data Fig. 9 Agronomic traits displayed by 9311 and 9311-GRF4ngr2 plants grown at varying nitrogen fertilization levels.

a, b, Flag leaf width (a) and culm width of the uppermost internode (b) at varying levels of nitrogen fertilization. c, d, \({}^{15}{{\rm{NH}}}_{4}^{+}\) (c) and \({}^{15}{{\rm{NO}}}_{3}^{-}\) (d) uptake rates of four-week-old plants grown with varying nitrogen supply (0.15N, 0.1875 mM NH4NO3; 0.3N, 0.375 mM NH4NO3; 0.6N, 0.75 mM NH4NO3; 1N, 1.25 mM NH4NO3). eh, The number of grains per panicle (e), 1,000-grain weight (f), harvest index (g) and dry biomass per plant (h) at varying levels of nitrogen fertilization. ah, Data are mean ± s.e.m. (n = 30); P values are from two-sided Student’s t-tests.

Extended Data Fig. 10 Growth, nitrogen uptake and grain yield performance of WYJ7-dep1-1 and transgenic WYJ7-dep1-1 plants carrying the 35S::GRF4ngr2–GFP construct at varying levels of nitrogen fertilization.

a, Mature plant heights. Scale bar, 15 cm. The picture is representative of three experiments performed independently with similar results. bd, Root uptake rates for \({}^{15}{{\rm{NH}}}_{4}^{+}\) (b), \({}^{15}{{\rm{NO}}}_{3}^{-}\) (c), and \({}^{15}{{\rm{NH}}}_{4}^{+}\) and \({}^{15}{{\rm{NO}}}_{3}^{-}\) combined (d) of four-week-old rice plants grown in low nitrogen (0.3N, 0.375 mM NH4NO3) and high nitrogen (1N, 1.25 mM NH4NO3) conditions. Data are mean ± s.e.m. (n = 9). ei, Mature plant height (e), heading date (f), the number of tillers per plant (g), the number of grains per panicle (h) and grain yield per plant (i) at varying levels of nitrogen fertilization. ei, Data shown as mean ± s.e.m. (n = 30). bi, P values are from two-sided Student’s t-tests.

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Li, S., Tian, Y., Wu, K. et al. Modulating plant growth–metabolism coordination for sustainable agriculture. Nature 560, 595–600 (2018). https://doi.org/10.1038/s41586-018-0415-5

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