Bypassing Negative Epistasis on Yield in Tomato Imposed by a Domestication Gene

Sebastian Soyk; Zachary H. Lemmon; Matan Oved; Josef Fisher; Katie L. Liberatore; Soon Ju Park; Anna Goren; Ke Jiang; Alexis Ramos; der Knaap, Esther van der Knaap; Eck, Joyce Van Eck; Dani Zamir; Yuval Eshed; Zachary B. Lippman

doi:10.1016/j.cell.2017.04.032

Bypassing Negative Epistasis on Yield in Tomato Imposed by a Domestication Gene

Sebastian Soyk, Zachary H. Lemmon, Matan Oved, Josef Fisher, Katie L. Liberatore, Soon Ju Park, Anna Goren, Ke Jiang, Alexis Ramos, der Knaap, Esther van der Knaap, Eck, Joyce Van Eck, Dani Zamir, Yuval Eshed, Zachary B. Lippman

Department of Plant and Environmental Sciences

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

Selection for inflorescence architecture with improved flower production and yield is common to many domesticated crops. However, tomato inflorescences resemble wild ancestors, and breeders avoided excessive branching because of low fertility. We found branched variants carry mutations in two related transcription factors that were selected independently. One founder mutation enlarged the leaf-like organs on fruits and was selected as fruit size increased during domestication. The other mutation eliminated the flower abscission zone, providing “jointless” fruit stems that reduced fruit dropping and facilitated mechanical harvesting. Stacking both beneficial traits caused undesirable branching and sterility due to epistasis, which breeders overcame with suppressors. However, this suppression restricted the opportunity for productivity gains from weak branching. Exploiting natural and engineered alleles for multiple family members, we achieved a continuum of inflorescence complexity that allowed breeding of higher-yielding hybrids. Characterizing and neutralizing similar cases of negative epistasis could improve productivity in many agricultural organisms.

Original language	English
Pages (from-to)	1142-1155
Number of pages	14
Journal	Cell
Volume	169
Issue number	6
Early online date	18 May 2017
DOIs	https://doi.org/10.1016/j.cell.2017.04.032
State	Published - 1 Jun 2017

All Science Journal Classification (ASJC) codes

General Biochemistry,Genetics and Molecular Biology

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@article{c3647418d8e64e57b3f2dfc97b7d3ea3,

title = "Bypassing Negative Epistasis on Yield in Tomato Imposed by a Domestication Gene",

abstract = "Selection for inflorescence architecture with improved flower production and yield is common to many domesticated crops. However, tomato inflorescences resemble wild ancestors, and breeders avoided excessive branching because of low fertility. We found branched variants carry mutations in two related transcription factors that were selected independently. One founder mutation enlarged the leaf-like organs on fruits and was selected as fruit size increased during domestication. The other mutation eliminated the flower abscission zone, providing “jointless” fruit stems that reduced fruit dropping and facilitated mechanical harvesting. Stacking both beneficial traits caused undesirable branching and sterility due to epistasis, which breeders overcame with suppressors. However, this suppression restricted the opportunity for productivity gains from weak branching. Exploiting natural and engineered alleles for multiple family members, we achieved a continuum of inflorescence complexity that allowed breeding of higher-yielding hybrids. Characterizing and neutralizing similar cases of negative epistasis could improve productivity in many agricultural organisms.",

author = "Sebastian Soyk and Lemmon, {Zachary H.} and Matan Oved and Josef Fisher and Liberatore, {Katie L.} and Park, {Soon Ju} and Anna Goren and Ke Jiang and Alexis Ramos and {van der Knaap}, {der Knaap, Esther} and {Van Eck}, {Eck, Joyce} and Dani Zamir and Yuval Eshed and Lippman, {Zachary B.}",

note = "EMBO Long-Term Fellowship [ALTF 1589-2014]; National Science Foundation [IOS-1523423]; Next-Generation BioGreen 21 Program (SSAC) [PJ01188301]; National Science Foundation Plant Genome Research Program [IOS-1564366, IOS-1237880]; European Research Council-Advanced Grant entitled YIELD [ERC-294691]; US-Israel Binational Agricultural Research & Development fund (BARD) [IS-4818-15]We thank all members of the Lippman lab for valuable discussions. We thank C. Brooks, A. Krainer, and J. Dalrymple for technical support, P. Keen for assistance with tomato transformation, T. Mulligan, S. Vermylen, and S. Qiao from CSHL, and staff from Cornell University's Long Island Horticultural Research and Extension Center for assistance with plant care. We thank I. Zemach for assistance with constructing populations for hybrid breeding and help with data collection. We thank J. Bonnet (Syngenta), M. Barineau (Lipman Seeds), D. Drost and C. Braun (Monsanto), F. Millenaar and I. Stein (Bayer Crop Science), S. Hutton (University of Florida), and T. Ariizumi (University of Tsukuba) for providing seed, tissue, and DNA samples. This research was supported by an EMBO Long-Term Fellowship (ALTF 1589-2014) to S.S., a National Science Foundation Postdoctoral Research Fellowship in Biology Grant (IOS-1523423) to Z.H.L., the Next-Generation BioGreen 21 Program (SSAC, PJ01188301) to S.J.P., the National Science Foundation Plant Genome Research Program (IOS-1564366) to E.v.d.K., a European Research Council-Advanced Grant entitled YIELD (ERC-294691) to D.Z., the US-Israel Binational Agricultural Research & Development fund (BARD, IS-4818-15) to Z.B.L. and Y.E., and the National Science Foundation Plant Genome Research Program (IOS-1237880) to J.V.E. and Z.B.L. We thank all members of the Lippman lab for valuable discussions. We thank C. Brooks, A. Krainer, and J. Dalrymple for technical support, P. Keen for assistance with tomato transformation, T. Mulligan, S. Vermylen, and S. Qiao from CSHL, and staff from Cornell University's Long Island Horticultural Research and Extension Center for assistance with plant care. We thank I. Zemach for assistance with constructing populations for hybrid breeding and help with data collection. We thank J. Bonnet (Syngenta), M. Barineau (Lipman Seeds), D. Drost and C. Braun (Monsanto), F. Millenaar and I. Stein (Bayer Crop Science), S. Hutton (University of Florida), and T. Ariizumi (University of Tsukuba) for providing seed, tissue, and DNA samples. This research was supported by an EMBO Long-Term Fellowship (ALTF 1589-2014) to S.S., a National Science Foundation Postdoctoral Research Fellowship in Biology Grant (IOS-1523423) to Z.H.L., the Next-Generation BioGreen 21 Program (SSAC, PJ01188301) to S.J.P., the National Science Foundation Plant Genome Research Program (IOS-1564366) to E.v.d.K., a European Research Council-Advanced Grant entitled YIELD (ERC-294691) to D.Z., the US-Israel Binational Agricultural Research & Development fund (BARD, IS-4818-15) to Z.B.L. and Y.E., and the National Science Foundation Plant Genome Research Program (IOS-1237880) to J.V.E. and Z.B.L.",

year = "2017",

month = jun,

day = "1",

doi = "10.1016/j.cell.2017.04.032",

language = "الإنجليزيّة",

volume = "169",

pages = "1142--1155",

journal = "Cell",

issn = "0092-8674",

publisher = "Elsevier B.V.",

number = "6",

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TY - JOUR

T1 - Bypassing Negative Epistasis on Yield in Tomato Imposed by a Domestication Gene

AU - Soyk, Sebastian

AU - Lemmon, Zachary H.

AU - Oved, Matan

AU - Fisher, Josef

AU - Liberatore, Katie L.

AU - Park, Soon Ju

AU - Goren, Anna

AU - Jiang, Ke

AU - Ramos, Alexis

AU - van der Knaap, der Knaap, Esther

AU - Van Eck, Eck, Joyce

AU - Zamir, Dani

AU - Eshed, Yuval

AU - Lippman, Zachary B.

N1 - EMBO Long-Term Fellowship [ALTF 1589-2014]; National Science Foundation [IOS-1523423]; Next-Generation BioGreen 21 Program (SSAC) [PJ01188301]; National Science Foundation Plant Genome Research Program [IOS-1564366, IOS-1237880]; European Research Council-Advanced Grant entitled YIELD [ERC-294691]; US-Israel Binational Agricultural Research & Development fund (BARD) [IS-4818-15]We thank all members of the Lippman lab for valuable discussions. We thank C. Brooks, A. Krainer, and J. Dalrymple for technical support, P. Keen for assistance with tomato transformation, T. Mulligan, S. Vermylen, and S. Qiao from CSHL, and staff from Cornell University's Long Island Horticultural Research and Extension Center for assistance with plant care. We thank I. Zemach for assistance with constructing populations for hybrid breeding and help with data collection. We thank J. Bonnet (Syngenta), M. Barineau (Lipman Seeds), D. Drost and C. Braun (Monsanto), F. Millenaar and I. Stein (Bayer Crop Science), S. Hutton (University of Florida), and T. Ariizumi (University of Tsukuba) for providing seed, tissue, and DNA samples. This research was supported by an EMBO Long-Term Fellowship (ALTF 1589-2014) to S.S., a National Science Foundation Postdoctoral Research Fellowship in Biology Grant (IOS-1523423) to Z.H.L., the Next-Generation BioGreen 21 Program (SSAC, PJ01188301) to S.J.P., the National Science Foundation Plant Genome Research Program (IOS-1564366) to E.v.d.K., a European Research Council-Advanced Grant entitled YIELD (ERC-294691) to D.Z., the US-Israel Binational Agricultural Research & Development fund (BARD, IS-4818-15) to Z.B.L. and Y.E., and the National Science Foundation Plant Genome Research Program (IOS-1237880) to J.V.E. and Z.B.L. We thank all members of the Lippman lab for valuable discussions. We thank C. Brooks, A. Krainer, and J. Dalrymple for technical support, P. Keen for assistance with tomato transformation, T. Mulligan, S. Vermylen, and S. Qiao from CSHL, and staff from Cornell University's Long Island Horticultural Research and Extension Center for assistance with plant care. We thank I. Zemach for assistance with constructing populations for hybrid breeding and help with data collection. We thank J. Bonnet (Syngenta), M. Barineau (Lipman Seeds), D. Drost and C. Braun (Monsanto), F. Millenaar and I. Stein (Bayer Crop Science), S. Hutton (University of Florida), and T. Ariizumi (University of Tsukuba) for providing seed, tissue, and DNA samples. This research was supported by an EMBO Long-Term Fellowship (ALTF 1589-2014) to S.S., a National Science Foundation Postdoctoral Research Fellowship in Biology Grant (IOS-1523423) to Z.H.L., the Next-Generation BioGreen 21 Program (SSAC, PJ01188301) to S.J.P., the National Science Foundation Plant Genome Research Program (IOS-1564366) to E.v.d.K., a European Research Council-Advanced Grant entitled YIELD (ERC-294691) to D.Z., the US-Israel Binational Agricultural Research & Development fund (BARD, IS-4818-15) to Z.B.L. and Y.E., and the National Science Foundation Plant Genome Research Program (IOS-1237880) to J.V.E. and Z.B.L.

PY - 2017/6/1

Y1 - 2017/6/1

N2 - Selection for inflorescence architecture with improved flower production and yield is common to many domesticated crops. However, tomato inflorescences resemble wild ancestors, and breeders avoided excessive branching because of low fertility. We found branched variants carry mutations in two related transcription factors that were selected independently. One founder mutation enlarged the leaf-like organs on fruits and was selected as fruit size increased during domestication. The other mutation eliminated the flower abscission zone, providing “jointless” fruit stems that reduced fruit dropping and facilitated mechanical harvesting. Stacking both beneficial traits caused undesirable branching and sterility due to epistasis, which breeders overcame with suppressors. However, this suppression restricted the opportunity for productivity gains from weak branching. Exploiting natural and engineered alleles for multiple family members, we achieved a continuum of inflorescence complexity that allowed breeding of higher-yielding hybrids. Characterizing and neutralizing similar cases of negative epistasis could improve productivity in many agricultural organisms.

AB - Selection for inflorescence architecture with improved flower production and yield is common to many domesticated crops. However, tomato inflorescences resemble wild ancestors, and breeders avoided excessive branching because of low fertility. We found branched variants carry mutations in two related transcription factors that were selected independently. One founder mutation enlarged the leaf-like organs on fruits and was selected as fruit size increased during domestication. The other mutation eliminated the flower abscission zone, providing “jointless” fruit stems that reduced fruit dropping and facilitated mechanical harvesting. Stacking both beneficial traits caused undesirable branching and sterility due to epistasis, which breeders overcame with suppressors. However, this suppression restricted the opportunity for productivity gains from weak branching. Exploiting natural and engineered alleles for multiple family members, we achieved a continuum of inflorescence complexity that allowed breeding of higher-yielding hybrids. Characterizing and neutralizing similar cases of negative epistasis could improve productivity in many agricultural organisms.

UR - http://www.scopus.com/inward/record.url?scp=85019361528&partnerID=8YFLogxK

U2 - 10.1016/j.cell.2017.04.032

DO - 10.1016/j.cell.2017.04.032

M3 - مقالة

SN - 0092-8674

VL - 169

SP - 1142

EP - 1155

JO - Cell

JF - Cell

IS - 6

ER -

Bypassing Negative Epistasis on Yield in Tomato Imposed by a Domestication Gene

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