Time-series transcriptomics reveals that AGAMOUS-LIKE22 affects primary metabolism and developmental processes in drought-stressed arabidopsis

Ulrike Bechtold; Christopher A. Penfold; Dafyd J. Jenkins; Roxane Legaie; Jonathan D. Moore; Tracy Lawson; Jack S.A. Matthews; Silvere R.M. Vialet-Chabrand; Laura Baxter; Sunitha Subramaniam; Richard Hickman; Hannah Florance; Christine Sambles; Deborah L. Salmon; Regina Feil; Laura Bowden; Claire Hill; Neil R. Baker; John E. Lunn; Bärbel Finkenstädt; Andrew Mead; Vicky Buchanan-Wollaston; Jim Beynon; David A. Rand; David L. Wild; Katherine J. Denby; Sascha Ott; Nicholas Smirnoff; Philip M. Mullineaux

doi:10.1105/tpc.15.00910

Time-series transcriptomics reveals that AGAMOUS-LIKE22 affects primary metabolism and developmental processes in drought-stressed arabidopsis

Ulrike Bechtold
, Christopher A. Penfold
, Dafyd J. Jenkins
, Roxane Legaie
, Jonathan D. Moore
, Tracy Lawson
, Jack S.A. Matthews
, Silvere R.M. Vialet-Chabrand
, Laura Baxter
, Sunitha Subramaniam
, Richard Hickman
, Hannah Florance
, Christine Sambles
, Deborah L. Salmon
, Regina Feil
, Laura Bowden
, Claire Hill
, Neil R. Baker
, John E. Lunn
, Bärbel Finkenstädt

Andrew Mead, Vicky Buchanan-Wollaston, Jim Beynon, David A. Rand, David L. Wild, Katherine J. Denby, Sascha Ott, Nicholas Smirnoff, Philip M. Mullineaux

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

Abstract

In Arabidopsis thaliana, changes in metabolism and gene expression drive increased drought tolerance and initiate diverse drought avoidance and escape responses. To address regulatory processes that link these responses, we set out to identify genes that govern early responses to drought. To do this, a high-resolution time series transcriptomics data set was produced, coupled with detailed physiological and metabolic analyses of plants subjected to a slow transition from well-watered to drought conditions. A total of 1815 drought-responsive differentially expressed genes were identified. The early changes in gene expression coincided with a drop in carbon assimilation, and only in the late stages with an increase in foliar abscisic acid content. To identify gene regulatory networks (GRNs) mediating the transition between the early and late stages of drought, we used Bayesian network modeling of differentially expressed transcription factor (TF) genes. This approach identified AGAMOUS-LIKE22 (AGL22), as key hub gene in a TF GRN. It has previously been shown that AGL22 is involved in the transition from vegetative state to flowering but here we show that AGL22 expression influences steady state photosynthetic rates and lifetime water use. This suggests that AGL22 uniquely regulates a transcriptional network during drought stress, linking changes in primary metabolism and the initiation of stress responses.

Original language	English (US)
Pages (from-to)	345-366
Number of pages	22
Journal	Plant Cell
Volume	28
Issue number	2
DOIs	https://doi.org/10.1105/tpc.15.00910
State	Published - Feb 2015
Externally published	Yes

ASJC Scopus subject areas

Plant Science

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10.1105/tpc.15.00910

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Bechtold, U., Penfold, C. A., Jenkins, D. J., Legaie, R., Moore, J. D., Lawson, T., Matthews, J. S. A., Vialet-Chabrand, S. R. M., Baxter, L., Subramaniam, S., Hickman, R., Florance, H., Sambles, C., Salmon, D. L., Feil, R., Bowden, L., Hill, C., Baker, N. R., Lunn, J. E., ... Mullineaux, P. M. (2015). Time-series transcriptomics reveals that AGAMOUS-LIKE22 affects primary metabolism and developmental processes in drought-stressed arabidopsis. Plant Cell, 28(2), 345-366. https://doi.org/10.1105/tpc.15.00910

Bechtold, U, Penfold, CA, Jenkins, DJ, Legaie, R, Moore, JD, Lawson, T, Matthews, JSA, Vialet-Chabrand, SRM, Baxter, L, Subramaniam, S, Hickman, R, Florance, H, Sambles, C, Salmon, DL, Feil, R, Bowden, L, Hill, C, Baker, NR, Lunn, JE, Finkenstädt, B, Mead, A, Buchanan-Wollaston, V, Beynon, J, Rand, DA, Wild, DL, Denby, KJ, Ott, S, Smirnoff, N & Mullineaux, PM 2015, 'Time-series transcriptomics reveals that AGAMOUS-LIKE22 affects primary metabolism and developmental processes in drought-stressed arabidopsis', Plant Cell, vol. 28, no. 2, pp. 345-366. https://doi.org/10.1105/tpc.15.00910

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title = "Time-series transcriptomics reveals that AGAMOUS-LIKE22 affects primary metabolism and developmental processes in drought-stressed arabidopsis",

abstract = "In Arabidopsis thaliana, changes in metabolism and gene expression drive increased drought tolerance and initiate diverse drought avoidance and escape responses. To address regulatory processes that link these responses, we set out to identify genes that govern early responses to drought. To do this, a high-resolution time series transcriptomics data set was produced, coupled with detailed physiological and metabolic analyses of plants subjected to a slow transition from well-watered to drought conditions. A total of 1815 drought-responsive differentially expressed genes were identified. The early changes in gene expression coincided with a drop in carbon assimilation, and only in the late stages with an increase in foliar abscisic acid content. To identify gene regulatory networks (GRNs) mediating the transition between the early and late stages of drought, we used Bayesian network modeling of differentially expressed transcription factor (TF) genes. This approach identified AGAMOUS-LIKE22 (AGL22), as key hub gene in a TF GRN. It has previously been shown that AGL22 is involved in the transition from vegetative state to flowering but here we show that AGL22 expression influences steady state photosynthetic rates and lifetime water use. This suggests that AGL22 uniquely regulates a transcriptional network during drought stress, linking changes in primary metabolism and the initiation of stress responses.",

author = "Ulrike Bechtold and Penfold, \{Christopher A.\} and Jenkins, \{Dafyd J.\} and Roxane Legaie and Moore, \{Jonathan D.\} and Tracy Lawson and Matthews, \{Jack S.A.\} and Vialet-Chabrand, \{Silvere R.M.\} and Laura Baxter and Sunitha Subramaniam and Richard Hickman and Hannah Florance and Christine Sambles and Salmon, \{Deborah L.\} and Regina Feil and Laura Bowden and Claire Hill and Baker, \{Neil R.\} and Lunn, \{John E.\} and B{\"a}rbel Finkenst{\"a}dt and Andrew Mead and Vicky Buchanan-Wollaston and Jim Beynon and Rand, \{David A.\} and Wild, \{David L.\} and Denby, \{Katherine J.\} and Sascha Ott and Nicholas Smirnoff and Mullineaux, \{Philip M.\}",

year = "2015",

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doi = "10.1105/tpc.15.00910",

language = "English (US)",

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AU - Bechtold, Ulrike

AU - Penfold, Christopher A.

AU - Jenkins, Dafyd J.

AU - Legaie, Roxane

AU - Moore, Jonathan D.

AU - Lawson, Tracy

AU - Matthews, Jack S.A.

AU - Vialet-Chabrand, Silvere R.M.

AU - Baxter, Laura

AU - Subramaniam, Sunitha

AU - Hickman, Richard

AU - Florance, Hannah

AU - Sambles, Christine

AU - Salmon, Deborah L.

AU - Feil, Regina

AU - Bowden, Laura

AU - Hill, Claire

AU - Baker, Neil R.

AU - Lunn, John E.

AU - Finkenstädt, Bärbel

AU - Mead, Andrew

AU - Buchanan-Wollaston, Vicky

AU - Beynon, Jim

AU - Rand, David A.

AU - Wild, David L.

AU - Denby, Katherine J.

AU - Ott, Sascha

AU - Smirnoff, Nicholas

AU - Mullineaux, Philip M.

PY - 2015/2

Y1 - 2015/2

N2 - In Arabidopsis thaliana, changes in metabolism and gene expression drive increased drought tolerance and initiate diverse drought avoidance and escape responses. To address regulatory processes that link these responses, we set out to identify genes that govern early responses to drought. To do this, a high-resolution time series transcriptomics data set was produced, coupled with detailed physiological and metabolic analyses of plants subjected to a slow transition from well-watered to drought conditions. A total of 1815 drought-responsive differentially expressed genes were identified. The early changes in gene expression coincided with a drop in carbon assimilation, and only in the late stages with an increase in foliar abscisic acid content. To identify gene regulatory networks (GRNs) mediating the transition between the early and late stages of drought, we used Bayesian network modeling of differentially expressed transcription factor (TF) genes. This approach identified AGAMOUS-LIKE22 (AGL22), as key hub gene in a TF GRN. It has previously been shown that AGL22 is involved in the transition from vegetative state to flowering but here we show that AGL22 expression influences steady state photosynthetic rates and lifetime water use. This suggests that AGL22 uniquely regulates a transcriptional network during drought stress, linking changes in primary metabolism and the initiation of stress responses.

AB - In Arabidopsis thaliana, changes in metabolism and gene expression drive increased drought tolerance and initiate diverse drought avoidance and escape responses. To address regulatory processes that link these responses, we set out to identify genes that govern early responses to drought. To do this, a high-resolution time series transcriptomics data set was produced, coupled with detailed physiological and metabolic analyses of plants subjected to a slow transition from well-watered to drought conditions. A total of 1815 drought-responsive differentially expressed genes were identified. The early changes in gene expression coincided with a drop in carbon assimilation, and only in the late stages with an increase in foliar abscisic acid content. To identify gene regulatory networks (GRNs) mediating the transition between the early and late stages of drought, we used Bayesian network modeling of differentially expressed transcription factor (TF) genes. This approach identified AGAMOUS-LIKE22 (AGL22), as key hub gene in a TF GRN. It has previously been shown that AGL22 is involved in the transition from vegetative state to flowering but here we show that AGL22 expression influences steady state photosynthetic rates and lifetime water use. This suggests that AGL22 uniquely regulates a transcriptional network during drought stress, linking changes in primary metabolism and the initiation of stress responses.

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VL - 28

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JO - Plant Cell

JF - Plant Cell

IS - 2

ER -

Time-series transcriptomics reveals that AGAMOUS-LIKE22 affects primary metabolism and developmental processes in drought-stressed arabidopsis

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