Hit-and-run transcriptional control by bZIP1 mediates rapid nutrient signaling in Arabidopsis

Significance Cellular signals evoke rapid and broad changes in gene regulatory networks. To uncover these network dynamics, we developed an approach able to monitor primary targets of a transcription factor (TF) based solely on gene regulation, in the absence of detectable binding. This enabled us to follow the transient propagation of a nitrogen (N) nutrient signal as a direct impact of the master TF Basic Leucine Zipper 1 (bZIP1). Unexpectedly, the largest class of primary targets that exhibit transient associations with bZIP1 is uniquely relevant to the rapid and dynamic propagation of the N signal. Our ability to uncover this transient network architecture has revealed the “dark matter” of dynamic N nutrient signaling in plants that has previously eluded detection. The dynamic nature of gene regulatory networks allows cells to rapidly respond to environmental change. However, the underlying temporal connections are missed, even in kinetic studies, as transcription factor (TF) binding within at least one time point is required to identify primary targets. The TF-regulated but unbound genes are dismissed as secondary targets. Instead, we report that these genes comprise transient TF–target interactions most relevant to rapid signal transduction. We temporally perturbed a master TF (Basic Leucine Zipper 1, bZIP1) and the nitrogen (N) signal it transduces and integrated TF regulation and binding data from the same cell samples. Our enabling approach could identify primary TF targets based solely on gene regulation, in the absence of TF binding. We uncovered three classes of primary TF targets: (i) poised (TF-bound but not TF-regulated), (ii) stable (TF-bound and TF-regulated), and (iii) transient (TF-regulated but not TF-bound), the largest class. Unexpectedly, the transient bZIP1 targets are uniquely relevant to rapid N signaling in planta, enriched in dynamic N-responsive genes, and regulated by TF and N signal interactions. These transient targets include early N responders nitrate transporter 2.1 and NIN-like protein 3, bound by bZIP1 at 1–5 min, but not at later time points following TF perturbation. Moreover, promoters of these transient targets are uniquely enriched with cis-regulatory motifs coinherited with bZIP1 binding sites, suggesting a recruitment role for bZIP1. This transient mode of TF action supports a classic, but forgotten, “hit-and-run” transcription model, which enables a “catalyst TF” to activate a large set of targets within minutes of signal perturbation.

[1]  Albertha J. M. Walhout,et al.  What does biologically meaningful mean? A perspective on gene regulatory network validation , 2011, Genome Biology.

[2]  Gabriel Krouk,et al.  Modeling the global effect of the basic-leucine zipper transcription factor 1 (bZIP1) on nitrogen and light regulation in Arabidopsis , 2010, BMC Systems Biology.

[3]  M. Müller,et al.  The nitrogen response of a barley C-hordein promoter is controlled by positive and negative regulation of the GCN4 and endosperm box. , 1993, The Plant journal : for cell and molecular biology.

[4]  Rodrigo A. Gutiérrez,et al.  VirtualPlant: A Software Platform to Support Systems Biology Research1[W][OA] , 2009, Plant Physiology.

[5]  Y. Benjamini,et al.  Quantitative Trait Loci Analysis Using the False Discovery Rate , 2005, Genetics.

[6]  J. Sheen,et al.  Arabidopsis mesophyll protoplasts: a versatile cell system for transient gene expression analysis , 2007, Nature Protocols.

[7]  S. McDade,et al.  Profiling of the BRCA1 transcriptome through microarray and ChIP-chip analysis , 2011, Nucleic acids research.

[8]  Gloria Coruzzi,et al.  Genomic Analysis of the Nitrate Response Using a Nitrate Reductase-Null Mutant of Arabidopsis1[w] , 2004, Plant Physiology.

[9]  Jennifer R. Harris,et al.  Limitations and possibilities of low cell number ChIP-seq , 2012, BMC Genomics.

[10]  K. Struhl,et al.  Saturation mutagenesis of the yeast his3 regulatory site: requirements for transcriptional induction and for binding by GCN4 activator protein. , 1986, Science.

[11]  Lonnie R. Welch,et al.  AGRIS: the Arabidopsis Gene Regulatory Information Server, an update , 2010, Nucleic Acids Res..

[12]  Imre,et al.  REGIA, An EU Project on Functional Genomics of Transcription Factors From Arabidopsis Thaliana , 2002, Comparative and functional genomics.

[13]  Vincent Colot,et al.  Profiling histone modification patterns in plants using genomic tiling microarrays , 2005, Nature Methods.

[14]  K. Birnbaum,et al.  Positive Fluorescent Selection Permits Precise, Rapid, and In-Depth Overexpression Analysis in Plant Protoplasts1[C][OA] , 2009, Plant Physiology.

[15]  Rongchen Wang,et al.  Microarray Analysis of the Nitrate Response in Arabidopsis Roots and Shoots Reveals over 1,000 Rapidly Responding Genes and New Linkages to Glucose, Trehalose-6-Phosphate, Iron, and Sulfate Metabolism1[w] , 2003, Plant Physiology.

[16]  Kazuki Saito,et al.  Members of the LBD Family of Transcription Factors Repress Anthocyanin Synthesis and Affect Additional Nitrogen Responses in Arabidopsis[W][OA] , 2009, The Plant Cell Online.

[17]  W. Liang,et al.  TM4 microarray software suite. , 2006, Methods in enzymology.

[18]  Y. Onodera,et al.  A Rice Functional Transcriptional Activator, RISBZ1, Responsible for Endosperm-specific Expression of Storage Protein Genes through GCN4 Motif* , 2001, The Journal of Biological Chemistry.

[19]  Filip Rolland,et al.  A central integrator of transcription networks in plant stress and energy signalling , 2007, Nature.

[20]  Mylène Brunelle,et al.  LRH-1 governs vital transcriptional programs in endocrine-sensitive and -resistant breast cancer cells. , 2014, Cancer research.

[21]  Rodrigo A Gutiérrez,et al.  Systems approach identifies an organic nitrogen-responsive gene network that is regulated by the master clock control gene CCA1 , 2008, Proceedings of the National Academy of Sciences.

[22]  Gabriel Krouk,et al.  TARGET: a transient transformation system for genome-wide transcription factor target discovery. , 2013, Molecular plant.

[23]  Mikael Bodén,et al.  MEME Suite: tools for motif discovery and searching , 2009, Nucleic Acids Res..

[24]  M. Margis-Pinheiro,et al.  New insights into aluminum tolerance in rice: the ASR5 protein binds the STAR1 promoter and other aluminum-responsive genes. , 2014, Molecular plant.

[25]  Mark B Gerstein,et al.  Dynamic and complex transcription factor binding during an inducible response in yeast. , 2009, Genes & development.

[26]  Yann LeCun,et al.  Predictive network modeling of the high-resolution dynamic plant transcriptome in response to nitrate , 2010, Genome Biology.

[27]  M. Rudnicki,et al.  Faculty Opinions recommendation of Genome-wide protein-DNA binding dynamics suggest a molecular clutch for transcription factor function. , 2012 .

[28]  M. Hudson,et al.  Rapid, Organ-Specific Transcriptional Responses to Light Regulate Photomorphogenic Development in Dicot Seedlings1[C][W][OA] , 2011, Plant Physiology.

[29]  Jong-Chan Hong,et al.  The arabidopsis bZIP1 transcription factor is involved in sugar signaling, protein networking, and DNA binding. , 2010, Molecular plant.

[30]  Rahul Satija,et al.  The TAGteam motif facilitates binding of 21 sequence-specific transcription factors in the Drosophila embryo. , 2012, Genome research.

[31]  G. Coruzzi,et al.  Cell-specific nitrogen responses mediate developmental plasticity , 2008, Proceedings of the National Academy of Sciences.

[32]  T. Eulgem,et al.  FORCA, a promoter element that responds to crosstalk between defense and light signaling , 2009, BMC Plant Biology.

[33]  R. Ferl,et al.  Characterization of a maize G-box binding factor that is induced by hypoxia. , 1995, The Plant journal : for cell and molecular biology.

[34]  Klaus Harter,et al.  Heterodimers of the Arabidopsis Transcription Factors bZIP1 and bZIP53 Reprogram Amino Acid Metabolism during Low Energy Stress[W] , 2011, Plant Cell.

[35]  Steven Rothstein,et al.  Genetic analysis of Arabidopsis GATA transcription factor gene family reveals a nitrate-inducible member important for chlorophyll synthesis and glucose sensitivity. , 2005, The Plant journal : for cell and molecular biology.

[36]  M. Hendriks,et al.  The sucrose regulated transcription factor bZIP11 affects amino acid metabolism by regulating the expression of ASPARAGINE SYNTHETASE1 and PROLINE DEHYDROGENASE2. , 2007, The Plant journal : for cell and molecular biology.

[37]  J. Eeckhoute,et al.  Pioneer factors: directing transcriptional regulators within the chromatin environment. , 2011, Trends in genetics : TIG.

[38]  Dennis Shasha,et al.  A Systems Approach Uncovers Restrictions for Signal Interactions Regulating Genome-wide Responses to Nutritional Cues in Arabidopsis , 2009, PLoS Comput. Biol..

[39]  Ziv Bar-Joseph,et al.  Temporal transcriptional response to ethylene gas drives growth hormone cross-regulation in Arabidopsis , 2013, eLife.

[40]  J. Keilwagen,et al.  Toward the identification and regulation of the Arabidopsis thaliana ABI3 regulon , 2012, Nucleic acids research.

[41]  D. Shasha,et al.  A Gene Expression Map of the Arabidopsis Root , 2003, Science.

[42]  Sjef Smeekens,et al.  Two-hybrid protein-protein interaction analysis in Arabidopsis protoplasts: establishment of a heterodimerization map of group C and group S bZIP transcription factors. , 2006, The Plant journal : for cell and molecular biology.

[43]  K. Hiratsu,et al.  The Arabidopsis thaliana STYLISH1 Protein Acts as a Transcriptional Activator Regulating Auxin Biosynthesis[C][W] , 2010, Plant Cell.

[44]  P. Bickel,et al.  Systematic evaluation of factors influencing ChIP-seq fidelity , 2012, Nature Methods.

[45]  N. Bolduc,et al.  Unraveling the KNOTTED1 regulatory network in maize meristems. , 2012, Genes & development.

[46]  W. Schaffner A hit-and-run mechanism for transcriptional activation? , 1988, Nature.

[47]  S. Batzoglou,et al.  Genome-Wide Analysis of Transcription Factor Binding Sites Based on ChIP-Seq Data , 2008, Nature Methods.

[48]  M. Biggin Animal transcription networks as highly connected, quantitative continua. , 2011, Developmental cell.

[49]  Philippe Collas,et al.  μChIP—a rapid micro chromatin immunoprecipitation assay for small cell samples and biopsies , 2008, Nucleic acids research.

[50]  V. Colot,et al.  Nuclear retention of the transcription factor NLP7 orchestrates the early response to nitrate in plants , 2013, Nature Communications.

[51]  Mineko Konishi,et al.  Arabidopsis NIN-like transcription factors have a central role in nitrate signalling , 2013, Nature Communications.

[52]  Timothy R. Hughes,et al.  Mapping Yeast Transcriptional Networks , 2013, Genetics.