HFR1, a phytochrome A-signalling component,acts in a separate pathway from HY5, downstream of COP1 in Arabidopsis thaliana

HFR1, a basic helix-loop-helix protein, is known to be required for a subset of phytochrome A (phyA)-dependent photoresponses. To investigate the role of HFR1 in light signalling, we have examined the genetic interaction between HFR1 and HY5, a positive regulator of light signalling, and COP1, a repressor of photomorphogenesis. Double mutant analysis suggests that HFR1 mediates phyA-dependent inhibition of hypocotyl elongation independently of HY5. HFR1 was shown to be necessary for a subset of cop1-triggered photomorphogenic phenotypes in the dark, including inhibition of hypocotyl elongation, gravitropic hypocotyl growth, and expression of the light-inducible genes CAB and RBCS. Phenotypic analysis of the triple mutant cop1hy5hfr1 indicated that both HFR1 and HY5 are required for cop1-mediated photomorphogenic seedling development in darkness, consistent with their additive roles in phyA-dependent signalling. Taken together, these results suggest that HFR1 might act downstream of COP1, in a separate pathway from HY5, to mediate photomorphogenesis in Arabidopsis.     

Arabidopsis Mutants Lacking Blue Light-Dependent Inhibition of Hypocotyl Elongation

We have isolated a new class of photomorphogenic mutants in Arabidopsis. Hypocotyl elongation is not inhibited in the mutant seedlings by continuous blue light but is inhibited by far red light, indicating that these mutations are phenotypically different from the previously isolated long hypocotyl (hy) mutants. Complementation analysis indicated that recessive nuclear mutations at three genetic loci, designated blu1, blu2, and blu3, can result in the blu mutant phenotype and that these mutants are genetically distinct from other long hypocotyl mutants. The BLU genes appear to be important only during seedling development because the blu mutations have little effect on mature plants, whereas hypocotyl elongation and cotyledon expansion are altered in seedlings. The genetic separation of the blue and far red sensitivities of light-induced hypocotyl inhibition in the blu and hy mutants demonstrates that two photosensory systems function in this response.     

Expression of calmodulin genes in wild type and calmodulin mutants of Arabidopsis thaliana under heat stress

Calmodulin (CaM), a calcium-regulated protein, regulates the activity of a number of key enzymes and plays important roles in cellular responses to environmental changes. The Arabidopsis thaliana genome contains nine calmodulin (CAM) genes. To understand the role of specific CAM genes in heat stress, the steady-state level of mRNA for the nine CAM genes in root and shoot tissues of seedlings grown at normal growth temperature (25 °C) and during heat stress at 42 °C for 2 h was compared in T-DNA insertional mutant lines of 7 CAM genes and the wild type using gene specific primers and RT-PCR. Compared to growth at 25 °C, the mRNA levels of all CAM genes were up-regulated in both root and shoot after heat treatment with the notable exception of CAM5 in root and shoot, and CAM1 in shoot where the mRNA levels were reduced. At 25 °C all cam mutants showed varying levels of mRNA for corresponding CAM genes with the highest levels of CAM5 gene mRNA being found in cam5-1 and cam5-3. CAM5 gene mRNA was not observed in the cam5-4 allele which harbors a T-DNA insertion in exon II. The level of respective CAM gene mRNAs were reduced in all cam alleles compared to levels in wild type except for increased expression of CAM5 in roots and shoots of cam5-1 and cam5-3. Compared to wild type, the level of mRNA for all CAM genes varied in each cam mutant, but not in a systematic way. In general, any non-exonic T-DNA insertion produced a decrease in the mRNA levels of the CAM2 and CAM3 genes, and the levels of CAM gene mRNAs were the same as wild type or lower in the cam1, cam4, cam5-2, and cam6-1 non-exonic mutant alleles. However, the level of mRNA for all genes except CAM2 and CAM3 genes was up-regulated in all cam2 and cam3 alleles and in the cam5-1 and cam5-3 alleles. During heat stress at 42 °C the level of CAM gene mRNAs were also variable between insertional mutants, but the level of CAM1 and CAM5 gene mRNAs were consistently greater in response to heat stress in both root and shoot. These results suggest differential tissue-specific expression of CAM genes in root and shoot tissues, and specific regulation of CAM gene mRNA levels by heat. Each of the CAM genes appears to contain noncoding regions that play regulatory roles resulting in interaction between CAM genes leading to changes in specific CAM gene mRNA levels in Arabidopsis. Only exonic insertion in CAM5 gene resulted in a loss-of-function of CAM5 gene among the mutants we surveyed in this study.     

Phytochrome chromophore deficiency leads to overproduction of jasmonic acid and elevated expression of jasmonate-responsive genes in Arabidopsis

An Arabidopsis mutant line named hy1-101 was isolated because it shows stunted root growth on medium containing low concentrations of jasmonic acid (JA). Subsequent investigation indicated that even in the absence of JA, hy1-101 plants exhibit shorter roots and express higher levels of a group of JA-inducible defense genes. Here, we show that the hy1-101 mutant has increased production of JA and its jasmonate-related phenotype is suppressed by the coi1-1 mutation that interrupts JA signaling. Gene cloning and genetic complementation analyses revealed that the hy1-101 mutant contains a mutation in the HY1 gene, which encodes a heme oxygenase essential for phytochrome chromophore biosynthesis. These results support a hypothesis that phytochrome chromophore deficiency leads to overproduction of JA and activates COI1-dependent JA responses. Indeed, we show that, like hy1-101, independent alleles of the phytochrome chromophore-deficient mutants, including hy1-100 and hy2 (CS68), also show elevated JA levels and constant expression of JA-inducible defense genes. We further provide evidence showing that, on the other hand, JA inhibits the expression of a group of light-inducible and photosynthesis-related genes. Together, these data imply that the JA-signaled defense pathway and phytochrome chromophore-mediated light signaling might have antagonistic effects on each other.     

Extragenic Suppressors of the Arabidopsis Det1 Mutant Identify Elements of Flowering-Time and Light-Response Regulatory Pathways

Light regulation of seedling morphogenesis is mediated by photoreceptors that perceive red, far-red, blue and UV light. Photomorphogenetic mutants of Arabidopsis have identified several of the primary photoreceptors, as well as a set of negative regulators of seedling photomorphogenesis, including DET1, that appear to act downstream of the photoreceptors. To study the regulatory context in which DET1 acts to repress photomorphogenesis, we used a simple morphological screen to isolate extragenic mutations in six loci, designated ted (for reversal of the det phenotype), that partially or fully suppress the seedling morphological phenotype of det1-1. Genetic analyses indicate that mutations in the ted4 and ted5 loci identify new alleles of the previously described photomorphogenetic loci hy1 and hy5, respectively. Molecular analyses indicate that the ted mutations partially suppress the dark-grown gene expression phenotype of det1-1, and that the mechanism of suppression does not involve direct remediation of the splicing defect caused by the det1-1 mutation. The ted mutations also partially suppress the light-grown morphological phenotype of mature det1-1 plants, and ted1 and ted2 suppress a daylength insensitivity phenotype of det1. TED1, TED2 and TED3 are newly described genes, whose function appears closely associated with that of DET1. In addition, alleles of ted1 are associated with a moderate late-flowering phenotype, suggesting that TED1 plays a role in the pathways that regulate both seedling morphogenesis and the initiation of flowering.     

camR, a negative regulator locus of the cytochrome P-450cam hydroxylase operon.

A 4.27-kilobase insert from a HindIII DNA library of Pseudomonas putida carrying the CAM plasmid allowed coordinate expression of genes camD and camC under control of camR, an upstream regulator. The camC gene specifies cytochrome P-450cam, and camD specifies the 5-exo-alcohol dehydrogenase. A 1.38-kilobase deletion from the insert results in the constitutive expression of genes camC and camD; transformation in trans restores the substrate control, indicating that camR is a negative regulator.     

Multiple heme oxygenase family members contribute to the biosynthesis of the phytochrome chromophore in Arabidopsis

The oxidative cleavage of heme by heme oxygenases (HOs) to form biliverdin IXalpha (BV) is the committed step in the biosynthesis of the phytochrome (phy) chromophore and thus essential for proper photomorphogenesis in plants. Arabidopsis (Arabidopsis thaliana) contains four possible HO genes (HY1, HO2-4). Genetic analysis of the HY1 locus showed previously that it is the major source of BV with hy1 mutant plants displaying long hypocotyls and decreased chlorophyll accumulation consistent with a substantial deficiency in photochemically active phys. More recent analysis of HO2 suggested that it also plays a role in phy assembly and photomorphogenesis but the ho2 mutant phenotype is more subtle than that of hy1 mutants. Here, we define the functions of HO3 and HO4 in Arabidopsis. Like HY1, the HO3 and HO4 proteins have the capacity to synthesize BV from heme. Through a phenotypic analysis of T-DNA insertion mutants affecting HO3 and HO4 in combination with mutants affecting HY1 or HO2, we demonstrate that both of the encoded proteins also have roles in photomorphogenesis, especially in the absence of HY1. Disruption of HO3 and HO4 in the hy1 background further desensitizes seedlings to red and far-red light and accelerates flowering time, with the triple mutant strongly resembling seedlings deficient in the synthesis of multiple phy apoproteins. The hy1/ho3/ho4 mutant can be rescued phenotypically and for the accumulation of holo-phy by feeding seedlings BV. Taken together, we conclude that multiple members of the Arabidopsis HO family are important for synthesizing the bilin chromophore used to assemble photochemically active phys.     

G-protein complex mutants are hypersensitive to abscisic acid regulation of germination and postgermination development

Abscisic acid (ABA) plays regulatory roles in a host of physiological processes throughout plant growth and development. Seed germination, early seedling development, stomatal guard cell functions, and acclimation to adverse environmental conditions are key processes regulated by ABA. Recent evidence suggests that signaling processes in both seeds and guard cells involve heterotrimeric G proteins. To assess new roles for the Arabidopsis (Arabidopsis thaliana) Galpha subunit (GPA1), the Gbeta subunit (AGB1), and the candidate G-protein-coupled receptor (GCR1) in ABA signaling during germination and early seedling development, we utilized knockout mutants lacking one or more of these components. Our data show that GPA1, AGB1, and GCR1 each negatively regulates ABA signaling in seed germination and early seedling development. Plants lacking AGB1 have greater ABA hypersensitivity than plants lacking GPA1, suggesting that AGB1 is the predominant regulator of ABA signaling and that GPA1 affects the efficacy of AGB1 execution. GCR1 acts upstream of GPA1 and AGB1 for ABA signaling pathways during germination and early seedling development: gcr1 gpa1 double mutants exhibit a gpa1 phenotype and agb1 gcr1 and agb1 gcr1 gpa1 mutants exhibit an agb1 phenotype. Contrary to the scenario in guard cells, where GCR1 and GPA1 have opposite effects on ABA signaling during stomatal opening, GCR1 acts in concert with GPA1 and AGB1 in ABA signaling during germination and early seedling development. Thus, cell- and tissue-specific functional interaction in response to a given signal such as ABA may determine the distinct pathways regulated by the individual members of the G-protein complex.