Repression of photomorphogenesis in Arabidopsis thaliana requires activity of the COP9 signalosome (CSN), CDD, and COP1 complexes, but how these three complexes work in concert to accomplish this important developmental switch has remained unknown. Here, we demonstrate that Arabidopsis CULLIN4 (CUL4) associates with the CDD complex and a common catalytic subunit to form an active E3 ubiquitin ligase both in vivo and in vitro. The partial loss of function of CUL4 resulted in a constitutive photomorphogenic phenotype with respect to morphogenesis and light-regulated gene expression. Furthermore, CUL4 exhibits a synergistic genetic interaction with COP10 and DET1. Therefore, this CUL4-based E3 ligase is essential for the repression of photomorphogenesis. This CUL4-based E3 ligase appears to associate physically with COP1 E3 ligase and positively regulates the COP1-dependent degradation of photomorphogenesis-promoting transcription factors, whereas the CSN controls the biochemical modification of CUL4 essential for E3 activity. Thus, this study suggests a biochemical activity connection between CSN and CDD complexes in their cooperation with COP1 in orchestrating the repression of photomorphogenesis.
ORCID ID: 0000-0002-8800-2400 (V.R.)CULLIN4-RING E3 ubiquitin ligases (CRL4s) regulate key developmental and stress responses in eukaryotes. Studies in both animals and plants have led to the identification of many CRL4 targets as well as specific regulatory mechanisms that modulate their function. The latter involve COP10-DET1-DDB1 (CDD)-related complexes, which have been proposed to facilitate target recognition by CRL4, although the molecular basis for this activity remains largely unknown. Here, we provide evidence that Arabidopsis thaliana DET1-, DDB1-ASSOCIATED1 (DDA1), as part of the CDD complex, provides substrate specificity for CRL4 by interacting with ubiquitination targets. Thus, we show that DDA1 binds to the abscisic acid (ABA) receptor PYL8, as well as PYL4 and PYL9, in vivo and facilitates its proteasomal degradation. Accordingly, we found that DDA1 negatively regulates ABAmediated developmental responses, including inhibition of seed germination, seedling establishment, and root growth. All other CDD components displayed a similar regulatory function, although they did not directly interact with PYL8. Interestingly, DDA1-mediated destabilization of PYL8 is counteracted by ABA, which protects PYL8 by limiting its polyubiquitination. Altogether, our data establish a function for DDA1 as a substrate receptor for CRL4-CDD complexes and uncover a mechanism for the desensitization of ABA signaling based on the regulation of ABA receptor stability.
Genome-wide 70-mer oligonucleotide microarrays of rice (Oryza sativa) and Arabidopsis thaliana were used to profile genome expression changes during light-regulated seedling development. We estimate that the expression of ;20% of the genome in both rice and Arabidopsis seedlings is regulated by white light. Qualitatively similar expression profiles from seedlings grown under different light qualities were observed in both species; however, a quantitatively weaker effect on genome expression was observed in rice. Most metabolic pathways exhibited qualitatively similar light regulation in both species with a few species-specific differences. Global comparison of expression profiles between rice and Arabidopsis reciprocal best-matched gene pairs revealed a higher correlation of genome expression patterns in constant light than in darkness, suggesting that the genome expression profile of photomorphogenesis is more conserved. Transcription factor gene expression under constant light exposure was poorly conserved between the two species, implying a faster-evolving rate of transcription factor gene expression in light-grown plants. Organ-specific expression profiles during seedling photomorphogenesis provide genome-level evidence for divergent light effects in different higher plant organs. Finally, overrepresentation of specific promoter motifs in root-and leaf-specific light-regulated genes in both species suggests that these cis-elements are important for gene expression responses to light.
A growing body of evidence indicates that the most common cystic fibrosis-causing mutation, ⌬F508, alters the ability of the cystic fibrosis transmembrane conductance regulator (CFTR) protein to fold and transit to the plasma membrane. Here we present evidence that the ⌬F508 mutation affects a step on the folding pathway prior to formation of the ATP binding site in the nucleotide binding domain (NBD). Notably, stabilization of the native state with 4 mM ATP does not alter the temperature-dependent folding yield of the mutant ⌬F508 NBD1 in vitro. In contrast, glycerol, which promotes ⌬F508-CFTR maturation in vivo, increases the folding yield of NBD1⌬F and reduces the off pathway rate in vitro, although it does not significantly alter the free energy of stability. Likewise a second site mutation, R553M, which corrects the maturation defect in vivo, is a superfolder which counters the effects of ⌬F508 on the temperature-dependent folding yield in vitro, but does not significantly alter the free energy of stability. A disease-causing mutation, G551D, which does not alter the maturation of CFTR in vivo but rather its function as a chloride channel, and the S549R maturation mutation have no discernible effect on the folding of the domain. These results demonstrate that ⌬F508 is a kinetic folding mutation that affects a step early in the process, and that there is a significant energy barrier between the native state and the step affected by the mutation precluding the use of native state ligands to promote folding. The implications for protein folding in general are that the primary sequence may not necessarily simply define the most stable native structure, but rather a stable structure that is kinetically accessible.
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