Project description:We designed an experiment to identify BAK1 interactors considering that it could be a coreceptor for the GOLVEN6 (GLV6) signaling peptide involved in lateral root organogenesis in Arabidopsis thaliana. A BAK1pro:BAK1-GFP/bak1-4 line crossed to an estradiol-inducible GLV6 overexpression line (BAK1pro:BAK1-GFP/bak1-4xiGLV6) was treated with mock or estradiol followed by affinity purification mass spectrometry (AP-MS) experiments using anti-GFP beads in microsomal-enriched fractions. Statistical analysis of estradiol-treated vs. mock seedlings did not reveal significant differences. Nevertheless, we remarked that regardless of the treatment, several LRR-RLKs co-eluted with BAK1-GFP, comprising known, as well as, unknown interactors. We confirmed interaction of BAK1 with these LRR-RLKs by BIFC and identified the PXC3 receptor as a BAK1 constitutive interactor, which was further verified by co-IP.

Project description:This model is from the article: Root gravitropism is regulated by a transient lateral auxin gradient controlled by a tipping-point mechanism. Band LR, Wells DM, Larrieu A, Sun J, Middleton AM, French AP, Brunoud G, Sato EM, Wilson MH, Péret B, Oliva M, Swarup R, Sairanen I, Parry G, Ljung K, Beeckman T, Garibaldi JM, Estelle M, Owen MR, Vissenberg K, Hodgman TC, Pridmore TP, King JR, Vernoux T, Bennett MJ. Proc Natl Acad Sci U S A.2012 Mar 20;109(12):4668-73 22393022, Abstract: Gravity profoundly influences plant growth and development. Plants respond to changes in orientation by using gravitropic responses to modify their growth. Cholodny and Went hypothesized over 80 years ago that plants bend in response to a gravity stimulus by generating a lateral gradient of a growth regulator at an organ's apex, later found to be auxin. Auxin regulates root growth by targeting Aux/IAA repressor proteins for degradation. We used an Aux/IAA-based reporter, domain II (DII)-VENUS, in conjunction with a mathematical model to quantify auxin redistribution following a gravity stimulus. Our multidisciplinary approach revealed that auxin is rapidly redistributed to the lower side of the root within minutes of a 90° gravity stimulus. Unexpectedly, auxin asymmetry was rapidly lost as bending root tips reached an angle of 40° to the horizontal. We hypothesize roots use a "tipping point" mechanism that operates to reverse the asymmetric auxin flow at the midpoint of root bending. These mechanistic insights illustrate the scientific value of developing quantitative reporters such as DII-VENUS in conjunction with parameterized mathematical models to provide high-resolution kinetics of hormone redistribution. This model corresponds to the full model described in the article.

Project description:This model is from the article: Root gravitropism is regulated by a transient lateral auxin gradient controlled by a tipping-point mechanism. Band LR, Wells DM, Larrieu A, Sun J, Middleton AM, French AP, Brunoud G, Sato EM, Wilson MH, Péret B, Oliva M, Swarup R, Sairanen I, Parry G, Ljung K, Beeckman T, Garibaldi JM, Estelle M, Owen MR, Vissenberg K, Hodgman TC, Pridmore TP, King JR, Vernoux T, Bennett MJ. Proc Natl Acad Sci U S A.2012 Mar 20;109(12):4668-73 22393022, Abstract: Gravity profoundly influences plant growth and development. Plants respond to changes in orientation by using gravitropic responses to modify their growth. Cholodny and Went hypothesized over 80 years ago that plants bend in response to a gravity stimulus by generating a lateral gradient of a growth regulator at an organ's apex, later found to be auxin. Auxin regulates root growth by targeting Aux/IAA repressor proteins for degradation. We used an Aux/IAA-based reporter, domain II (DII)-VENUS, in conjunction with a mathematical model to quantify auxin redistribution following a gravity stimulus. Our multidisciplinary approach revealed that auxin is rapidly redistributed to the lower side of the root within minutes of a 90° gravity stimulus. Unexpectedly, auxin asymmetry was rapidly lost as bending root tips reached an angle of 40° to the horizontal. We hypothesize roots use a "tipping point" mechanism that operates to reverse the asymmetric auxin flow at the midpoint of root bending. These mechanistic insights illustrate the scientific value of developing quantitative reporters such as DII-VENUS in conjunction with parameterized mathematical models to provide high-resolution kinetics of hormone redistribution. This model corresponds to the simplified model described in the article. It is assumed that, on the timescale of DII-VENUS degradation, the concentrations of auxin, TIR1/AFB, and their complexes can be approximated by quasi-steady-state expressions. This reduced the full model to a single ODE that describes how the DII-VENUS dynamics depend on the auxin influx and four parameter groupings.

Project description:Arabidopsis BAK1/SERK3, a co-receptor of leucine-rich repeat pattern recognition receptors (PRR), mediates pattern-triggered immunity (PTI). Genetic inactivation of BAK1 or BAK1-interacting receptors (BIR) causes cell death. We foundthat the TIR-NBS-LRR protein CONSTITUTIVE SHADE-AVOIDANCE 1 (CSA1) physically interacts with BIR3, but not with BAK1 and mediates ETI-type cell death in the absence of BAK1 and BIR3.

Project description:Plants have a large family of membrane receptor kinases (RKs) which sense extracellular signals to control plant growth, development, immunity, and stress response. The largest group of RKs contains an extracellular leucine-rich repeat (LRR) domain with over 200 members in Arabidopsis. However, the functional understanding of most of the LRR-RKs has been hampered by their genetic redundancy and the subtle phenotypes of RK overexpression. Here we show that the rapamycin-mediated heterodimerization of chimeric cytosolic kinase domains from receptor/co-receptor pairs in the plasma membrane can activate their downstream cellular signaling pathway, inducing the specific biological responses, including brassinosteroid, plant immunity, stomatal development, and lateral root development. This chemically controlled synthetic biology approach will be useful to investigate biological functions of LRR-RKs and their signaling pathways.

Project description:Recognition of microbial patterns and host derived damage signals by host pattern recognition receptors is a key step in immune activation in multicellular eukaryotes. Here we show how mutations in ethylene signaling and the coreceptor bak1 affect host immune responses triggered by elicitors. A 51 DNA microarray study using total RNA from Arabidopsis mutants (ein2-1, bak1-3, efr-1 and pepr1-1 pepr2-3) as well as wild type treated with elf18 or Pep2 with three biological replicates.

Project description:Recognition of microbial patterns and host derived damage signals by host pattern recognition receptors is a key step in immune activation in multicellular eukaryotes. Here we show how mutations in ethylene signaling and the coreceptor bak1 affect host immune responses triggered by elicitors.

Project description:Comparison of root gravitropism upon glucose treatment as compared to control in Arabidopsis

Project description:In the lateral root repression system described by Babé et al. (2012), the first asymetric divisions of pericycle cells preceding lateral root formation are repressed during water deficit treatments. During an 8-hr long treatment, an 8-mm long root segment is formed where LR formation has been repressed. The experiment was designed to monitor changes in gene expression during early events of LR formation in barley using this LR repression system.

Project description:To gain further insight into the root clock mechanism, we performed a mutagenesis screen in plants carrying DR5::Luciferase in combination with markers for subsequent LR organogenesis (pWOX5::ER-YFP and pSCR::ER-GFP12). Out of this screening, we identified a mutant with increased expression of DR5::Luciferase in the OZ and PBS distributed throughout the primary root axis without evident spacing. We further refer to this mutant as potent.