Engineering 6-phosphogluconate dehydrogenase improves grain yield in heat-stressed maize

Camila Ribeiro; Tracie A. Hennen-Bierwagen; Alan M. Myers; Kenneth Cline; A. Mark Settles

doi:10.1073/pnas.2010179117

Edited by Brian A. Larkins, University of Nebraska, Lincoln, NE, and approved November 3, 2020 (received for review May 20, 2020)

Significance

Heat stress reduces yield in maize by affecting the number of kernels that develop and the accumulation of seed storage molecules during grain fill. Climate change is expected to increase frequency and duration of high-temperature stress, which will lower grain yields. Here we show that one enzyme in central carbon metabolism is sensitive to high temperatures. By providing a heat-resistant form of the enzyme in the correct subcellular compartment, a larger number of kernels develop per plant during heat stress in the field. This genetic improvement could be included as part of integrated approaches to mitigate yield losses due to climate change.

Abstract

Endosperm starch synthesis is a primary determinant of grain yield and is sensitive to high-temperature stress. The maize chloroplast-localized 6-phosphogluconate dehydrogenase (6PGDH), PGD3, is critical for endosperm starch accumulation. Maize also has two cytosolic isozymes, PGD1 and PGD2, that are not required for kernel development. We found that cytosolic PGD1 and PGD2 isozymes have heat-stable activity, while amyloplast-localized PGD3 activity is labile under heat stress conditions. We targeted heat-stable 6PGDH to endosperm amyloplasts by fusing the Waxy1 chloroplast targeting the peptide coding sequence to the Pgd1 and Pgd2 open reading frames (ORFs). These WPGD1 and WPGD2 fusion proteins import into isolated chloroplasts, demonstrating a functional targeting sequence. Transgenic maize plants expressing WPGD1 and WPGD2 with an endosperm-specific promoter increased 6PGDH activity with enhanced heat stability in vitro. WPGD1 and WPGD2 transgenes complement the pgd3-defective kernel phenotype, indicating the fusion proteins are targeted to the amyloplast. In the field, the WPGD1 and WPGD2 transgenes can mitigate grain yield losses in high–nighttime-temperature conditions by increasing kernel number. These results provide insight into the subcellular distribution of metabolic activities in the endosperm and suggest the amyloplast pentose phosphate pathway is a heat-sensitive step in maize kernel metabolism that contributes to yield loss during heat stress.

Footnotes

↵¹Present address: Citrus Research and Education Center, University of Florida, Lake Alfred, FL 33850.
↵²To whom correspondence may be addressed. Email: settles{at}ufl.edu.

Author contributions: C.R., K.C., and A.M.S. designed research; C.R., T.A.H.-B., A.M.M., and A.M.S. performed research; T.A.H.-B., A.M.M., K.C., and A.M.S. contributed new reagents/analytic tools; C.R. and A.M.S. analyzed data; and C.R., A.M.M., and A.M.S. wrote the paper.
Competing interest statement: The University of Florida has filed a US patent application entitled “Mitigation of maize heat stress with recombinant 6-phosphogluconate dehydrogenase.” Named inventors are C.R. and A.M.S.
This article is a PNAS Direct Submission.
This article contains supporting information online at https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2010179117/-/DCSupplemental.

Data Availability.

All study data are included in the article and SI Appendix.

Published under the PNAS license.

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Proceedings of the National Academy of Sciences: 117 (52)

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[1] ↵
United Nations Department of Economic and Social Affairs
, World Population Prospects 2019: Highlights (United Nations, 2019).

[2] United Nations Department of Economic and Social Affairs

[3] ↵
Organisation for Economic Co-Operation Development (OECD) and Food and Agriculture Organization (FAO)
, “Cereals” in OECD-FAO Agricultural Outlook 2016-2025 (OECD, Paris, 2016), vol. 7, pp. 98–123.
OpenUrl

[4] Organisation for Economic Co-Operation Development (OECD) and Food and Agriculture Organization (FAO)

[5] ↵
E. Hawkins et al
., Increasing influence of heat stress on French maize yields from the 1960s to the 2030s. Glob. Change Biol. 19, 937–947 (2013).
OpenUrl

[6] E. Hawkins et al

[7] ↵
A. Raza et al
., Impact of climate change on crops adaptation and strategies to tackle its outcome: A review. Plants (Basel) 8, 34 (2019).
OpenUrl

[8] A. Raza et al

[9] ↵
F. Gong,
X. Wu,
H. Zhang,
Y. Chen,
W. Wang
, Making better maize plants for sustainable grain production in a changing climate. Front. Plant Sci. 6, 835 (2015).
OpenUrl

[10] F. Gong,

[11] X. Wu,

[12] H. Zhang,

[13] Y. Chen,

[14] W. Wang

[15] ↵
S. K. Boehlein et al
., Effects of long-term exposure to elevated temperature on Zea mays endosperm development during grain fill. Plant J. 99, 23–40 (2019).
OpenUrl

[16] S. K. Boehlein et al

[17] ↵
R. Dolferus,
X. Ji,
R. A. Richards
, Abiotic stress and control of grain number in cereals. Plant Sci. 181, 331–341 (2011).
OpenUrl CrossRef PubMed

[18] R. Dolferus,

[19] X. Ji,

[20] R. A. Richards

[21] ↵
A. Bahaji et al
., Starch biosynthesis, its regulation and biotechnological approaches to improve crop yields. Biotechnol. Adv. 32, 87–106 (2014).
OpenUrl CrossRef PubMed

[22] A. Bahaji et al

[23] ↵
G. Spielbauer et al
., Robustness of central carbohydrate metabolism in developing maize kernels. Phytochemistry 67, 1460–1475 (2006).
OpenUrl CrossRef PubMed

[24] G. Spielbauer et al

[25] ↵
N. J. Kruger,
A. von Schaewen
, The oxidative pentose phosphate pathway: Structure and organisation. Curr. Opin. Plant Biol. 6, 236–246 (2003).
OpenUrl CrossRef PubMed

[26] N. J. Kruger,

[27] A. von Schaewen

[28] ↵
C. W. Stuber,
M. M. Goodman
, Inheritance, intracellular localization, and genetic variation of phosphoglucomutase isozymes in maize (Zea mays L.). Biochem. Genet. 21, 667–689 (1983).
OpenUrl CrossRef PubMed

[29] C. W. Stuber,

[30] M. M. Goodman

[31] ↵
J. Bailey-Serres,
J. Tom,
M. Freeling
, Expression and distribution of cytosolic 6-phosphogluconate dehydrogenase isozymes in maize. Biochem. Genet. 30, 233–246 (1992).
OpenUrl PubMed

[32] J. Bailey-Serres,

[33] J. Tom,

[34] M. Freeling

[35] ↵
J. Bailey-Serres,
M. T. Nguyen
, Purification and characterization of cytosolic 6-phosphogluconate dehydrogenase isozymes from maize. Plant Physiol. 100, 1580–1583 (1992).
OpenUrl Abstract/FREE Full Text

[36] J. Bailey-Serres,

[37] M. T. Nguyen

[38] ↵
G. Spielbauer et al
., Chloroplast-localized 6-phosphogluconate dehydrogenase is critical for maize endosperm starch accumulation. J. Exp. Bot. 64, 2231–2242 (2013).
OpenUrl CrossRef PubMed

[39] G. Spielbauer et al

[40] ↵
A. M. Settles et al
., Sequence-indexed mutations in maize using the UniformMu transposon-tagging population. BMC Genomics 8, 116 (2007).
OpenUrl CrossRef PubMed

[41] A. M. Settles et al

[42] ↵
W. He,
Y. Wang,
W. Liu,
C.-Z. Zhou
, Crystal structure of Saccharomyces cerevisiae 6-phosphogluconate dehydrogenase Gnd1. BMC Struct. Biol. 7, 38 (2007).
OpenUrl CrossRef PubMed

[43] W. He,

[44] Y. Wang,

[45] W. Liu,

[46] C.-Z. Zhou

[47] ↵
R. H. Averill,
J. Bailey-Serres,
N. J. Kruger
, Co-operation between cytosolic and plastidic oxidative pentose phosphate pathways revealed by 6-phosphogluconate dehydrogenase-deficient genotypes of maize. Plant J. 14, 449–457 (1998).
OpenUrl CrossRef

[48] R. H. Averill,

[49] J. Bailey-Serres,

[50] N. J. Kruger

[51] ↵
R. B. Klösgen,
H. Saedler,
J. H. Weil
, The amyloplast-targeting transit peptide of the waxy protein of maize also mediates protein transport in vitro into chloroplasts. Mol. Gen. Genet. 217, 155–161 (1989).
OpenUrl CrossRef PubMed

[52] R. B. Klösgen,

[53] H. Saedler,

[54] J. H. Weil

[55] ↵
R. B. Klösgen,
A. Gierl,
Z. Schwarz-Sommer,
H. Saedler
, Molecular analysis of the waxy locus of Zea mays. Mol. Gen. Genet. 203, 237–244 (1986).
OpenUrl CrossRef

[56] R. B. Klösgen,

[57] A. Gierl,

[58] Z. Schwarz-Sommer,

[59] H. Saedler

[60] ↵
J. Chen et al
., Dynamic transcriptome landscape of maize embryo and endosperm development. Plant Physiol. 166, 252–264 (2014).
OpenUrl Abstract/FREE Full Text

[61] J. Chen et al

[62] ↵
D. B. Lobell et al
., The critical role of extreme heat for maize production in the United States. Nat. Clim. Chang. 3, 497–501 (2013).
OpenUrl

[63] D. B. Lobell et al

[64] ↵
W. Schlenker,
M. J. Roberts
, Nonlinear temperature effects indicate severe damages to U.S. crop yields under climate change. Proc. Natl. Acad. Sci. U.S.A. 106, 15594–15598 (2009).
OpenUrl Abstract/FREE Full Text

[65] W. Schlenker,

[66] M. J. Roberts

[67] ↵
R. J. Jones,
S. Ouattar,
R. K. Crookston
, Thermal environment during endosperm cell division and grain filling in maize: Effects on kernel growth and development in vitro. Crop Sci. 24, 133–137 (1985).
OpenUrl

[68] R. J. Jones,

[69] S. Ouattar,

[70] R. K. Crookston

[71] ↵
P. D. Commuri,
R. J. Jones
, High temperatures during endosperm cell division in maize. Crop Sci. 41, 1122–1130 (2001).
OpenUrl CrossRef

[72] P. D. Commuri,

[73] R. J. Jones

[74] ↵
D. Lu et al
., Effects of heat stress during grain filling on the structure and thermal properties of waxy maize starch. Food Chem. 143, 313–318 (2014).
OpenUrl

[75] D. Lu et al

[76] ↵
D. Lu et al
., Effects of high temperature during grain filling under control conditions on the physicochemical properties of waxy maize flour. Carbohydr. Polym. 98, 302–310 (2013).
OpenUrl

[77] D. Lu et al

[78] ↵
L. I. Mayer,
R. Savin,
G. A. Maddonni
, Heat stress during grain filling modifies kernel protein composition in field-grown maize. Crop Sci. 56, 1890–1903 (2016).
OpenUrl

[79] L. I. Mayer,

[80] R. Savin,

[81] G. A. Maddonni

[82] ↵
L. M. Smith
, The heat is on: Maize pollen development after a heat wave. Plant Physiol. 181, 387–388 (2019).
OpenUrl FREE Full Text

[83] L. M. Smith

[84] ↵
E. Pacini,
R. Dolferus
, Pollen developmental arrest: Maintaining pollen fertility in a world with a changing climate. Front. Plant Sci. 10, 679 (2019).
OpenUrl

[85] E. Pacini,

[86] R. Dolferus

[87] ↵
R. Prasad et al
., Projected climate and agronomic implications for corn production in the northeastern United States. PLoS One 13, e0198623 (2018).
OpenUrl

[88] R. Prasad et al

[89] ↵
Y.-L. Ruan,
Y. Jin,
Y.-J. Yang,
G.-J. Li,
J. S. Boyer
, Sugar input, metabolism, and signaling mediated by invertase: Roles in development, yield potential, and response to drought and heat. Mol. Plant 3, 942–955 (2010).
OpenUrl CrossRef PubMed

[90] Y.-L. Ruan,

[91] Y. Jin,

[92] Y.-J. Yang,

[93] G.-J. Li,

[94] J. S. Boyer

[95] ↵
C. E. Bita,
T. Gerats
, Plant tolerance to high temperature in a changing environment: Scientific fundamentals and production of heat stress-tolerant crops. Front. Plant Sci. 4, 273 (2013).
OpenUrl CrossRef PubMed

[96] C. E. Bita,

[97] T. Gerats

[98] ↵
L. C. Hannah et al
., A shrunken-2 transgene increases maize yield by acting in maternal tissues to increase the frequency of seed development. Plant Cell 24, 2352–2363 (2012).
OpenUrl Abstract/FREE Full Text

[99] L. C. Hannah et al

[100] ↵
L. C. Hannah,
J. R. Shaw,
M. A. Clancy,
N. Georgelis,
S. K. Boehlein
, A brittle-2 transgene increases maize yield by acting in maternal tissues to increase seed number. Plant Direct 1, e00029 (2017).
OpenUrl

[101] L. C. Hannah,

[102] J. R. Shaw,

[103] M. A. Clancy,

[104] N. Georgelis,

[105] S. K. Boehlein

[106] ↵
N. M. Doll et al
., Transcriptomics at maize embryo/endosperm interfaces identifies a transcriptionally distinct endosperm subdomain adjacent to the embryo scutellum. Plant Cell 32, 833–852 (2020).
OpenUrl Abstract/FREE Full Text

[107] N. M. Doll et al

[108] ↵
G. M. Hoopes et al
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Engineering 6-phosphogluconate dehydrogenase improves grain yield in heat-stressed maize

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