Flowering of Arabidopsis is regulated by several environmental and endogenous signals. An important integrator of these inputs is the FLOWERING LOCUS T (FT) gene, which encodes a small, possibly mobile protein. A primary response to floral induction is the activation of FT RNA expression in leaves. Because flowers form at a distant site, the shoot apex, these data suggest that FT primarily controls the timing of flowering. Integration of temporal and spatial information is mediated in part by the bZIP transcription factor FD, which is already expressed at the shoot apex before floral induction. A complex of FT and FD proteins in turn can activate floral identity genes such as APETALA1 (AP1).
The Ca 21-binding protein calmodulin mediates cellular Ca 21 signals in response to a wide array of stimuli in higher eukaryotes. Plants express numerous CaM isoforms. Transcription of one soybean (Glycine max) CaM isoform, SCaM-4, is dramatically induced within 30 min of pathogen or NaCl stresses. To characterize the cis-acting element(s) of this gene, we isolated an approximately 2-kb promoter sequence of the gene. Deletion analysis of the promoter revealed that a 130-bp region located between nucleotide positions 2858 and 2728 is required for the stressors to induce expression of SCaM-4. A hexameric DNA sequence within this region, GAAAAA (GT-1 cis-element), was identified as a core cis-acting element for the induction of the SCaM-4 gene. The GT-1 cis-element interacts with an Arabidopsis GT-1-like transcription factor, AtGT-3b, in vitro and in a yeast selection system. Transcription of AtGT-3b is also rapidly induced within 30 min after pathogen and NaCl treatment. These results suggest that an interaction between a GT-1 cis-element and a GT-1-like transcription factor plays a role in pathogen-and salt-induced SCaM-4 gene expression in both soybean and Arabidopsis.Plant cells, like animal cells, elevate their cytosolic free-calcium levels ([Ca 21 ] cyt ) with varying amplitude, frequency, and duration in response to a variety of external stimuli (Thomas et al., 1996; Berridge, 1997;McAinsh and Hetherington, 1998 -bound CaM transduces the signals into many cellular processes through modulation of a variety of CaM-binding proteins, including enzymes such as kinases, phosphatases, and nitric-oxide synthase, as well as receptors, ion channels, G-proteins, and transcription factors (Liao et al., 1996;Snedden and Fromm, 1998;Lee et al., 1999a;Zuhlke et al., 1999).In plant cells, in contrast to mammalian cells, multiple CaM genes code for a number of CaM isoforms. This has been shown in wheat (Triticum aestivum; Yang et al., 1996), potato (Solanum tuberosum; Takezawa et al., 1995;Poovaiah et al., 1996), and soybean (Glycine max; Lee et al., 1995a), among others. Over 30 genes encoding CaM isoforms are found in the Arabidopsis genome (The Arabidopsis Genome Initiative, 2000). We have recently cloned five CaM isoforms from soybean (SCaM-1-5). Although SCaM-1-3 are more than 90% identical to mammalian CaM, SCaM-4 and SCaM-5 exhibit only a 78% homology with SCaM-1 and are therefore the most divergent isoforms reported thus far in the plant and animal kingdoms. SCaM-4 is considered to be a bona fide CaM isoform based on the following characteristics. In its primary protein structure, SCaM-4 has four conserved putative EF-hands and a central linker region, hallmark structural features of CaM (Lee et al., 1995a). In addition, most of the nonconsensus amino acids occur outside the EF-hands, and the total number of Article, publication date, and citation information can be found at www.plantphysiol.org/cgi
The Hippo pathway regulates the self-renewal and differentiation of various adult stem cells, but its role in cell fate determination and differentiation during liver development remains unclear. Here we report that the Hippo pathway controls liver cell lineage specification and proliferation separately from Notch signalling, using mice and primary hepatoblasts with liver-specific knockout of Lats1 and Lats2 kinase, the direct upstream regulators of YAP and TAZ. During and after liver development, the activation of YAP/TAZ induced by loss of Lats1/2 forces hepatoblasts or hepatocytes to commit to the biliary epithelial cell (BEC) lineage. It increases BEC and fibroblast proliferation by up-regulating TGFβ signalling, but suppresses hepatoblast to hepatocyte differentiation by repressing Hnf4α expression. Notably, oncogenic YAP/TAZ activation in hepatocytes induces massive p53-dependent cell senescence/death. Together, our results reveal that YAP/TAZ activity levels govern liver cell differentiation and proliferation in a context-dependent manner.
The Ca 2؉ signal is essential for the activation of plant defense responses, but downstream components of the signaling pathway are still poorly defined. Here we demonstrate that specific calmodulin (CaM) isoforms are activated by infection or pathogen-derived elicitors and participate in These results suggest that specific CaM isoforms are components of a SA-independent signal transduction chain leading to disease resistance.
Mitogen-activated protein kinase (MAPK) cascades are known to transduce plant defense signals, but the downstream components of the MAPK have as yet not been elucidated. Here, we report an MAPK from rice (Oryza sativa), BWMK1, and a transcription factor, OsEREBP1, phosphorylated by the kinase. The MAPK carries a TDY phosphorylation motif instead of the more common TEY motif in its kinase domain and has an unusually extended C-terminal domain that is essential to its kinase activity and translocation to the nucleus. The MAPK phosphorylates OsEREBP1 that binds to the GCC box element (AGCCGCC) of the several basic pathogenesis-related gene promoters, which in turn enhances DNA-binding activity of the factor to the cis element in vitro. Transient co-expression of the BWMK1 and OsEREBP1 in Arabidopsis protoplasts elevates the expression of the -glucuronidase reporter gene driven by the GCC box element. Furthermore, transgenic tobacco (Nicotiana tabacum) plants overexpressing BWMK1 expressed many pathogenesis-related genes at higher levels than wild-type plants with an enhanced resistance to pathogens. These findings suggest that MAPKs contribute to plant defense signal transduction by phosphorylating one or more transcription factors.Mitogen-activated protein kinase (MAPK) cascades are known to play essential roles in the signal transduction pathways involved in numerous eukaryotic cellular processes from cell division to cell death (Davis, 2000; Ligterink and Hirt, 2001). In the last few years, it has become apparent that MAPK cascades also play vital roles in signal transduction pathways of plants, including plant defense signaling (Innes, 2001; Tena et al., 2001; Zhang and Klessig, 2001). The Arabidopsis genome sequence has revealed the presence of 23 MAPK genes in the genome, which suggests that the MAPK cascades in plants may be quite complex.Accumulating lines of evidence indicate that plants rapidly activate MAPKs when exposed to a variety of abiotic and biotic stress stimuli (Ligterink et al., 1997; Zhang et al., 1998; Seo et al., 1999; Cardinale et al., 2000; Ichimura et al., 2000). These include pathogens, pathogen-derived elicitors, and defense-related second messengers. In tobacco (Nicotiana tabacum), two MAPKs, SIPK and WIPK, are activated by both various pathogen-related signals and diverse abiotic stresses, indicating that pathogen defense signaling is part of an integrated stress-signaling network in plants. Orthologs of SIPK and WIPK in Arabidopsis (AtMPK6 and AtMAPK3, respectively) and alfalfa (Medicago sativa; SIMK and SAMK, respectively) are also activated by both biotic and abiotic stresses (Seo et al., 1995; Zhang and Klessig, 1997; Nuhse et al., 2000). Recently, the MAPKK, NtMEK2, was identified to operate in the cascade upstream of SIPK and WIPK because a constitutively active NtMEK2 activates endogenous SIPK and WIPK molecules in transiently transformed tobacco cells. Furthermore, the constitutively active NtMEK2 induces hypersensitive cell death and the expression of defense genes (Yan...
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