Plant Cell

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The Arabidopsis U12-Type Spliceosomal Protein U11/U12-31K Is Involved in U12 Intron Splicing via RNA Chaperone Activity and Affects Plant Development
Plant Cell - Tập 22 Số 12 - Trang 3951-3962 - 2012
Kim, Won Yong, Jung, Hyun Ju, Kwak, Kyung Jin, Kim, Min Kyung, Oh, Seung Han, Han, Yeon Soo, Kang, Hunseung
N6-methyladenosine RNA methylation modulates liquid‒liquid phase separation in plants
Plant Cell - Tập 35 Số 9 - Trang 3205-3213 - 2023
Kang, Hunseung, Xu, Tao
The TIP GROWTH DEFECTIVE1 S-Acyl Transferase Regulates Plant Cell Growth in Arabidopsis
Plant Cell - Tập 17 Số 9 - Trang 2554-2563 - 2005
Piers A. Hemsley, Alison Kemp, Claire Grierson
Abstract TIP GROWTH DEFECTIVE1 (TIP1) of Arabidopsis thaliana affects cell growth throughout the plant and has a particularly strong effect on root hair growth. We have identified TIP1 by map-based cloning and complementation of the mutant phenotype. TIP1 encodes an ankyrin repeat protein with a DHHC Cys-rich domain that is expressed in roots, leaves, inflorescence stems, and floral tissue. Two homologues of TIP1 in yeast (Saccharomyces cerevisiae) and human (Homo sapiens) have been shown to have S-acyl transferase (also known as palmitoyl transferase) activity. S-acylation is a reversible hydrophobic protein modification that offers swift, flexible control of protein hydrophobicity and affects protein association with membranes, signal transduction, and vesicle trafficking within cells. We show that TIP1 binds the acyl group palmitate, that it can rescue the morphological, temperature sensitivity, and yeast casein kinase2 localization defects of the yeast S-acyl transferase mutant akr1Δ, and that inhibition of acylation in wild-type Arabidopsis roots reproduces the Tip1− mutant phenotype. Our results demonstrate that S-acylation is essential for normal plant cell growth and identify a plant S-acyl transferase, an essential research tool if we are to understand how this important, reversible lipid modification operates in plant cells.
Multicellular Compartmentation of Catharanthus roseus Alkaloid Biosynthesis Predicts Intercellular Translocation of a Pathway Intermediate
Plant Cell - Tập 11 Số 5 - Trang 887-900 - 1999
Benoit St‐Pierre, Felipe Vázquez‐Flota, Vincenzo De Luca
The Arabidopsis EIN3 Binding F-Box Proteins EBF1 and EBF2 Have Distinct but Overlapping Roles in Ethylene Signaling
Plant Cell - Tập 19 Số 2 - Trang 509-523 - 2007
Brad M. Binder, Joseph Walker, Jennifer M. Gagne, Thomas J. Emborg, Georg Hemmann, Anthony B. Bleecker, Richard D. Vierstra
Abstract Ethylene signaling in Arabidopsis thaliana converges on the ETHYLENE-INSENSITIVE3 (EIN3)/EIN3-Like (EIL) transcription factors to induce various responses. EIN3 BINDING F-BOX1 (EBF1) and EBF2 were recently shown to function in ethylene perception by regulating EIN3/EIL turnover. In the absence of ethylene, EIN3 and possibly other EIL proteins are targeted for ubiquitination and subsequent degradation by Cullin 1–based E3 complexes containing EBF1 and 2. Ethylene appears to block this ubiquitination, allowing EIN3/EIL levels to rise and mediate ethylene signaling. Through analysis of mutant combinations affecting accumulation of EBF1, EBF2, EIN3, and EIL1, we show that EIN3 and EIL1 are the main targets of EBF1/2. Kinetic analyses of hypocotyl growth inhibition in response to ethylene and growth recovery after removal of the hormone revealed that EBF1 and 2 have temporally distinct but overlapping roles in modulating ethylene perception. Whereas EBF1 plays the main role in air and during the initial phase of signaling, EBF2 plays a more prominent role during the latter stages of the response and the resumption of growth following ethylene removal. Through their coordinated control of EIN3/EIL1 levels, EBF1 and EBF2 fine-tune ethylene responses by repressing signaling in the absence of the hormone, dampening signaling at high hormone concentrations, and promoting a more rapid recovery after ethylene levels dissipate.
The TomatoAux/IAATranscription FactorIAA9Is Involved in Fruit Development and Leaf Morphogenesis
Plant Cell - Tập 17 Số 10 - Trang 2676-2692 - 2005
Hua Wang, Brian Jones, Zhengguo Li, Pierre Frasse, Corinne Delalande, Farid Regad, Salma Chaabouni, Alain Lachaux, Jean‐Claude Pech, Mondher Bouzayen
AbstractAuxin/indole-3-acetic acid (Aux/IAA) proteins are transcriptional regulators that mediate many aspects of plant responses to auxin. While functions of most Aux/IAAs have been defined mainly by gain-of-function mutant alleles in Arabidopsis thaliana, phenotypes associated with loss-of-function mutations have been scarce and subtle. We report here that the downregulation of IAA9, a tomato (Solanum lycopersicum) gene from a distinct subfamily of Aux/IAA genes, results in a pleiotropic phenotype, consistent with its ubiquitous expression pattern. IAA9-inhibited lines have simple leaves instead of wild-type compound leaves, and fruit development is triggered before fertilization, giving rise to parthenocarpy. This indicates that IAA9 is a key mediator of leaf morphogenesis and fruit set. In addition, antisense plants displayed auxin-related growth alterations, including enhanced hypocotyl/stem elongation, increased leaf vascularization, and reduced apical dominance. Auxin dose–response assays revealed that IAA9 downregulated lines were hypersensitive to auxin, although the only early auxin-responsive gene that was found to be upregulated in the antisense lines was IAA3. The activity of the IAA3 promoter was stimulated in the IAA9 antisense genetic background, indicating that IAA9 acts in planta as a transcriptional repressor of auxin signaling. While no mutation in any member of subfamily IV has been reported to date, the phenotypes associated with the downregulation of IAA9 reveal distinct and novel roles for members of the Aux/IAA gene family.
The POLARIS Peptide of Arabidopsis Regulates Auxin Transport and Root Growth via Effects on Ethylene Signaling
Plant Cell - Tập 18 Số 11 - Trang 3058-3072 - 2006
Paul M. Chilley, Stuart A. Casson, Petr Tarkowski, N. Hawkins, Kevin L.-C. Wang, Patrick J. Hussey, Mike Beale, Joseph R. Ecker, Göran K. Sandberg, Keith Lindsey
Genetic Regulation of Fruit Development and Ripening
Plant Cell - Tập 16 Số suppl_1 - Trang S170-S180
James J. Giovannoni
Ethylene Biosynthesis and Signaling Networks
Plant Cell - Tập 14 Số suppl 1 - Trang S131-S151 - 2002
Kevin L.-C. Wang, Hai Li, Joseph R. Ecker
Multilevel Interactions between Ethylene and Auxin inArabidopsisRoots
Plant Cell - Tập 19 Số 7 - Trang 2169-2185 - 2007
Anna N. Stepanova, Jeonga Yun, Alla V. Likhacheva, José M. Alonso
AbstractHormones play a central role in the coordination of internal developmental processes with environmental signals. Herein, a combination of physiological, genetic, cellular, and whole-genome expression profiling approaches has been employed to investigate the mechanisms of interaction between two key plant hormones: ethylene and auxin. Quantification of the morphological effects of ethylene and auxin in a variety of mutant backgrounds indicates that auxin biosynthesis, transport, signaling, and response are required for the ethylene-induced growth inhibition in roots but not in hypocotyls of dark-grown seedlings. Analysis of the activation of early auxin and ethylene responses at the cellular level, as well as of global changes in gene expression in the wild type versus auxin and ethylene mutants, suggests a simple mechanistic model for the interaction between these two hormones in roots, according to which ethylene and auxin can reciprocally regulate each other's biosyntheses, influence each other's response pathways, and/or act independently on the same target genes. This model not only implies existence of several levels of interaction but also provides a likely explanation for the strong ethylene response defects observed in auxin mutants.
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