Sarahmi Ishida

Repression of shoot growth, a bZIP transcriptional activator, regulates cell elongation by controlling the level of gibberellins.

Cell expansion, a developmental process regulated by both endogenous programs and environmental stimuli, is critically important for plant growth. Here, we report the isolation and characterization of RSG (for repression of shoot growth), a transcriptional activator with a basic leucine zipper (bZIP) domain. To examine the role of RSG in plant development, we generated transgenic tobacco plants expressing a dominant-negative form of RSG, which repressed the activity of full-length RSG. In transgenic plants, this expression severely inhibited stem internode growth, specifically cell elongation. These plants also had less endogenous amounts of the major active gibberellin (GA) in tobacco, GA1. Applying GAs restored the dwarf phenotypes of transgenic tobacco plants that expressed the dominant-negative form of RSG. To investigate the function of RSG in the regulation of the endogenous amounts of GAs, we identified a target for RSG. RSG bound and activated the promoter of Arabidopsis GA3, one of the genes encoding enzymes involved in GA biosynthesis. Moreover, the dominant-negative form of RSG decreased expression of the GA3 homolog in transgenic tobacco plants. Our results show that RSG, a bZIP transcriptional activator, regulates the morphology of plants by controlling the endogenous amounts of GAs.

Involvement of 14-3-3 Signaling Protein Binding in the Functional Regulation of the Transcriptional Activator REPRESSION OF SHOOT GROWTH by Gibberellins

REPRESSION OF SHOOT GROWTH (RSG) is a tobacco (Nicotiana tabacum) transcriptional activator with a basic Leu zipper domain that regulates endogenous amounts of gibberellins (GAs) by the control of a GA biosynthetic enzyme. The 14-3-3 signaling proteins have been suggested to suppress RSG by sequestering it in the cytoplasm. Here, we show that RSG phosphorylation on Ser-114 is important for 14-3-3 binding. We found that GA levels regulate the intracellular localization of RSG. RSG translocated into the nucleus in response to a reduction in GA levels. GA treatment could reverse this nuclear accumulation. The GA-induced disappearance of RSG–green fluorescent protein from the nucleus did not depend on protein degradation. By contrast, the mutant RSG (S114A) that could not bind to 14-3-3 continued to be localized predominantly in the nucleus after GA application. Analysis of the mRNA levels of GA biosynthetic genes showed that the feedback regulation of the GA 20-oxidase gene was inhibited in transgenic plants expressing a dominant negative form of RSG. Our results suggest that RSG is negatively modulated by GAs by 14-3-3 binding and might be involved in GA homeostasis.

A Tobacco Calcium-Dependent Protein Kinase, CDPK1, Regulates the Transcription Factor REPRESSION OF SHOOT GROWTH in Response to Gibberellins

The homeostasis of gibberellins (GAs) is maintained by negative feedback in plants. REPRESSION OF SHOOT GROWTH (RSG) is a tobacco (Nicotiana tabacum) transcriptional activator that has been suggested to play a role in GA feedback by the regulation of GA biosynthetic enzymes. The 14-3-3 signaling proteins negatively regulate RSG by sequestering it in the cytoplasm in response to GAs. The phosphorylation on Ser-114 of RSG is essential for 14-3-3 binding of RSG. Here, we identified tobacco Ca2+-dependent protein kinase (CDPK1) as an RSG kinase that promotes 14-3-3 binding to RSG by phosphorylation of Ser-114 of RSG. CDPK1 interacts with RSG in a Ca2+-dependent manner in vivo and in vitro and specifically phosphorylates Ser-114 of RSG. Inhibition of CDPK repressed the GA-induced phosphorylation of Ser-114 of RSG and the GA-induced nuclear export of RSG. Overexpression of CDPK1 inhibited the feedback regulation of a GA 20-oxidase gene and resulted in sensitization to the GA biosynthetic inhibitor. Our results suggest that CDPK1 decodes the Ca2+ signal produced by GAs and regulates the intracellular localization of RSG.

AGF1, an AT-Hook Protein, Is Necessary for the Negative Feedback of AtGA3ox1 Encoding GA 3-Oxidase

Negative feedback is a fundamental mechanism of organisms to maintain the internal environment within tolerable limits. Gibberellins (GAs) are essential regulators of many aspects of plant development, including seed germination, stem elongation, and flowering. GA biosynthesis is regulated by the feedback mechanism in plants. GA 3-oxidase (GA3ox) catalyzes the final step of the biosynthetic pathway to produce the physiologically active GAs. Here, we found that only the AtGA3ox1 among the AtGA3ox family of Arabidopsis (Arabidopsis thaliana) is under the regulation of GA-negative feedback. We have identified a cis-acting sequence responsible for the GA-negative feedback of AtGA3ox1 using transgenic plants. Furthermore, we have identified an AT-hook protein, AGF1 (for the AT-hook protein of GA feedback regulation), as a DNA-binding protein for the cis-acting sequence of GA-negative feedback. The mutation in the cis-acting sequence abolished both GA-negative feedback and AGF1 binding. In addition, constitutive expression of AGF1 affected GA-negative feedback in Arabidopsis. Our results suggest that AGF1 plays a role in the homeostasis of GAs through binding to the cis-acting sequence of the GA-negative feedback of AtGA3ox1.

Alteration of Substrate Specificity: The Variable N-Terminal Domain of Tobacco Ca2+-Dependent Protein Kinase Is Important for Substrate Recognition

The variable N-terminal domain of CDPK1 is required for the recognition of the substrate RSG, which is a transcriptional activator involved in the gibberellin feedback regulation. This work opens the possibility of engineering the substrate specificity of CDPK by manipulation of the variable N-terminal domain, enabling a rational rewiring of cellular signaling pathways. Protein kinases are major signaling molecules that are involved in a variety of cellular processes. However, the molecular mechanisms whereby protein kinases discriminate specific substrates are still largely unknown. Ca2+-dependent protein kinases (CDPKs) play central roles in Ca2+ signaling in plants. Previously, we found that a tobacco (Nicotiana tabacum) CDPK1 negatively regulated the transcription factor REPRESSION OF SHOOT GROWTH (RSG), which is involved in gibberellin feedback regulation. Here, we found that the variable N-terminal domain of CDPK1 is necessary for the recognition of RSG. A mutation (R10A) in the variable N-terminal domain of CDPK1 reduced both RSG binding and RSG phosphorylation while leaving kinase activity intact. Furthermore, the R10A mutation suppressed the in vivo function of CDPK1. The substitution of the variable N-terminal domain of an Arabidopsis thaliana CDPK, At CPK9, with that of Nt CDPK1 conferred RSG kinase activities. This chimeric CDPK behaved according to the identity of the variable N-terminal domain in transgenic plants. Our results open the possibility of engineering the substrate specificity of CDPK by manipulation of the variable N-terminal domain, enabling a rational rewiring of cellular signaling pathways.

Scaffold Function of Ca2+-Dependent Protein Kinase: Tobacco Ca2+-DEPENDENT PROTEIN KINASE1 Transfers 14-3-3 to the Substrate REPRESSION OF SHOOT GROWTH after Phosphorylation

A Ca2+-dependent protein kinase not only phosphorylates a substrate but also acts as a scaffold that promotes the interaction between a phosphorylation product and its binding protein. A molecular mechanism to ensure signaling specificity is a scaffold. REPRESSION OF SHOOT GROWTH (RSG) is a tobacco (Nicotiana tabacum) transcription factor that is involved in gibberellin feedback regulation. The 14-3-3 proteins negatively regulate RSG by sequestering it in the cytoplasm in response to gibberellins. The N. tabacum Ca2+-dependent protein kinase NtCDPK1 was identified as an RSG kinase that promotes 14-3-3 binding of RSG by phosphorylation of RSG. CDPKs are unique sensor responders of Ca2+ that are only found in plants and some protozoans. Here, we report a scaffolding function of CDPK. 14-3-3 proteins bound to NtCDPK1 by a new mode. Autophosphorylation of NtCDPK1 was necessary for the formation of the binding between NtCDPK1 and 14-3-3 but not for its maintenance. NtCDPK1 formed a heterotrimer with RSG and 14-3-3. Furthermore, we found that NtCDPK1 transfers 14-3-3 to RSG after phosphorylation of RSG and that RSG dissociates from NtCDPK1 as a complex with 14-3-3. These results suggest that NtCDPK1 is an interesting scaffolding kinase that increases the specificity and efficiency of signaling by coupling catalysis with scaffolding on the same protein.

Function and Modulation of Expression of Auxin-Regulated Genes

Publisher Summary This chapter provides an overview of recent developments in the analysis of auxin-regulated genes, with emphasis on tobacco mesophyll protoplasts and tobacco BY-2 cells. Among the classical plant hormones, auxin is of foremost importance, as it has a dramatic effect on numerous aspects of plant growth and development. These include cell expansion, cell division, induction of adventitious roots, control of apical dominance, and plastic responses to fluctuations in environmental factors that include light and gravity. The expression of some regulatory genes involved in development and cell division is controlled by auxin. Three strategies can be used to gain insight into the mode of action of auxin at the molecular level. The first is a genetic approach. The second strategy is a biochemical approach, which is especially suitable for auxin-binding proteins. Structural and functional analysis of natural and synthetic auxins has suggested that auxin activity depends upon a fractional positive charge located at a favorable distance from the carboxyl group of the acetic acid moiety of the hormone. The third approach is to clone auxin-regulated genes and identify the functions of their products. A study of the hormonal activation of transcription of these genes should resolve the details of the signal transduction systems involved in this process.

Phosphorylation-independent binding of 14–3–3 to NtCDPK1 by a new mode

14–3–3 pproteins play essential roles in diverse cellular processes through the direct binding to target proteins. REPRESSION OF SHOOT GROWTH (RSG) is a tobacco (Nicotiana tabacum) transcription factor that is involved in gibberellin (GA) feedback regulation. The 14–3–3 proteins bind to RSG depending on the RSG phosphorylation of Ser-114 and negatively regulate RSG by sequestering it in the cytoplasm in response to GAs. The Ca2+-dependent protein kinase NtCDPK1 was identified as an RSG kinase that promotes 14–3–3 binding of RSG by phosphorylation of RSG. 14–3–3 weakly binds to NtCDPK1 by a new mode. The autophosphorylation of NtCDPK1 was necessary for the formation of the binding between NtCDPK1 and 14–3–3 but not for its maintenance. In this study, we showed that 14–3–3 binding to NtCDPK1 does not require the autophosphorylation when RSG was bound to NtCDPK1. These data suggest that 14–3–3 binds to an unphosphorylated motif in NtCDPK1 exposed by a conformational change in NtCDPK1 but not to a phosphate group generated by autophosphorylation of NtCDPK1.

The mechanism of substrate recognition of Ca2+-dependent protein kinases.

Ca2+-dependent protein kinases (CDPKs) are encoded by a multigene family and are thought to play central roles in Ca2+ signaling in plants. Although the primary structures of CDPK isoforms are highly conserved, several studies suggested a distinct physiological function for each CDPK isoform in plants. Hence, there should be mechanisms by which individual CDPK specifically recognizes its substrate. Recently, the variable N-terminal domain of NtCDPK1 was shown to play an essential role in the specific recognition of the substrate. Because the variable N-terminal domain of other CDPKs may also be involved in the substrate recognition, the search for interacting proteins of the variable N-terminal domain would provide important clues to identify the physiological substrates of each CDPK. Additionally, manipulation of the variable N-terminal domain may enable us to engineer the substrate specificity of CDPK, leading a rational rewiring of cellular signaling pathways.

CDPK1, a calcium-dependent protein kinase, regulates transcriptional activator RSG in response to gibberellins

The homeostasis of gibberellins (GAs) is maintained by negative-feedback regulation in plant cells. REPRESSION OF SHOOT GROWTH (RSG) is a transcriptional activator with a basic Leu zipper domain suggested to contribute GA feedback regulation by the transcriptional regulation of genes encoding GA biosynthetic enzymes. The 14-3-3 signaling proteins negatively regulate RSG by sequestering it in the cytoplasm in response to GAs. The phosphorylation on Ser-114 of RSG is essential for 14-3-3 binding of RSG; however, the kinase that catalyzes the reaction is unknown. Recently a Ca2+-dependent protein kinase (CDPK) was identified as an RSG kinase that promotes 14-3-3 binding of RSG by phosphorylation of the Ser-114 of RSG. Our results suggest that CDPK decodes the Ca2+ signal produced by GAs and regulates the intracellular localization of RSG in plant cells.