Similar stress responses are elicited by copper and ultraviolet radiation in the aquatic plant Lemna gibba: implication of reactive oxygen species as common signals.

Metals and ultraviolet (UV) radiation are two environmental stressors that can cause damage to plants. These two types of stressors often impact simultaneously on plants and both are known to promote reactive oxygen species (ROS) production. However, little information is available on the potential parallel stress responses elicited by metals and UV radiation. Using the aquatic plant Lemna gibba, we found that copper and simulated solar radiation (SSR, a light source containing photosynthetically active radiation (PAR) and UV radiation) induced similar responses in the plants. Both copper and SSR caused ROS formation. The ROS levels were higher when copper was combined with SSR than when applied with PAR. Higher concentrations of copper plus PAR caused toxicity as monitored by diminished growth and chlorophyll content. This toxicity was more pronounced when copper was combined with SSR. Because the generation of ROS was also higher when copper was combined with SSR, we attributed this enhanced toxicity to elevated levels of ROS. In comparison to PAR-grown plants, SSR treated plants exhibited elevated levels of superoxide dismutase (SOD) and glutathione reductase (GR). These enzyme levels were further elevated under both PAR and SSR when copper was added at concentrations that generated ROS. Interestingly, copper treatment in the absence of SSR (i.e. copper plus PAR) induced synthesis of the same flavonoids as those observed in SSR without copper. Finally, addition of either dimethyl thiourea or GSH (two common ROS scavengers) lowered in vivo ROS production, alleviated toxicity and diminished induction of GR as well as accumulation of UV absorbing compounds. Thus, the potential of ROS being a common signal for acclimation to stress by both copper and UV can be considered.

Interactions within a network of phytochrome, cryptochrome and UV-B phototransduction pathways regulate chalcone synthase gene expression in Arabidopsis leaf tissue.

The Arabidopsis gene encoding the key flavonoid biosynthesis enzyme chalcone synthase (CHS) is regulated by several environmental and endogenous stimuli. Here we dissect the network of light signalling pathways that control CHS expression in mature leaves using cryptochrome (cry) and phytochrome (phy) deficient mutants. The UV-A/blue light induction of CHS is mediated principally by cry1, but neither cry1 nor cry2 is involved in UV-B induction or in the UV-A and blue light signalling pathways that interact synergistically with the UV-B pathway to enhance CHS expression. Moreover, these synergistic responses do not require phyA or phyB. Phytochrome is a positive regulator of the cry1 inductive pathway, mediating distinct potentiation and coaction effects. A red light pretreatment enhances subsequent cry1-mediated CHS induction. This potentiation is unaltered in phyA and phyB mutants but much reduced in a phyA phyB double mutant, indicating that it requires principally phyA or phyB. In contrast, the cry1-mediated induction of CHS, without pretreatment, is much reduced in phyB but not phyA mutants, indicating coaction between cry1 and phyB. Further experiments with phy-deficient mutants demonstrate that phyB is a negative regulator of the UV-B inductive pathway. We further show that phyB acts upstream of the points of interaction of the UV-A and blue synergism pathways with the UV-B pathway. We propose that phyB functions to balance flux through the cry1 and UV-B signalling pathways.

Structural and biochemical basis for the UVB-induced alterations in epidermal barrier function.

Ultraviolet light (UVR) induces a myriad of cutaneous changes, including delayed disruption of the permeability barrier with higher doses. To investigate the basis for the UVB-induced barrier alteration, we assessed the epidermal lamellar body secretory system at various time points before and after barrier disruption with a single high dose of UVB (7.5 MED) to murine epidermis. Morphological data were correlated with changes in epidermal proliferation and lipid synthesis, indicative of lamellar body generation. Twenty-four hours following UVB, the stratum corneum (SC) is normal, but a layer of abnormal, vacuolated, and lamellar body (LB)-deficient cells is present, immediately beneath the stratum granulosum (SG)/SC interface. Immediately subjacent to this band of damaged cells, normal keratinocytes that contain intact LBs are present. By 72 h, concomitant with the appearance of a barrier abnormality, extensively damaged cells persist at the SC/SG interface, and abnormal lamellar membrane structures appear in the lower SC. Upper stratum spinosum (SS) and lower SG cells appear normal, with increased numbers of LBs. A barrier abnormality is still present at 96 h, in association with membrane abnormalities in the lower SC interstices, but up to four normal appearing, subjacent SG cell layers are present. By 120 h, accelerated LB formation and precocious LB extrusion occur throughout the thickened SG; normal lamellar membranes are present in the lower SC; and barrier recovery is almost complete. Whereas, epidermal synthesis of the major barrier lipid species (i.e., cholesterol, fatty acids, and ceramides, including acylceramides) is reduced or unchanged at 24 and 48 h, it increases significantly 72 h after exposure to UVB. Therefore, the delayed disruption of the permeability barrier following acute UVB exposure results from the arrival of a band of lamellar body-incompetent (i.e., damaged) cells at the SG/SC interface. The subsequent, rapid recovery of the barrier, in turn, results from compensatory hyperplasia of subjacent, undamaged SS/SG cells, generating increased numbers and contents of LB. These results underscore the critical role of the stratum compactum in mediating barrier function, and suggest that beneficial therapeutic effects of UV exposure may be due to enhanced lipid production and barrier regeneration.

Radiation inactivation analysis of acyl-CoA:retinol acyltransferase and lecithin:retinol acyltransferase in rat liver.

Microsomes from liver and several other tissues esterify retinol through both fatty acyl-CoA-dependent and -independent reactions. Two activities, acyl-CoA:retinol acyltransferase (ARAT) and lecithin:retinol acyltransferase (LRAT) activities, have been characterized enzymatically but neither has yet been purified and characterized biochemically. We have used the method of radiation inactivation to determine the target sizes of ARAT and LRAT in intact microsomal membranes from rat liver. After exposure of frozen liver microsomes to ionizing radiation, the activity of ARAT decayed exponentially yielding a target size of 73 +/- 18 kDa (mean +/- SD, n = 6). The activity of LRAT was assayed both by monitoring the esterification of retinol bound to the cellular retinol-binding protein (CRBP) and of solvent-dispersed retinol. With both assays a single exponential was observed with radiation doses of 9 to 150 Mrads. The slopes obtained with both LRAT assays were similar, yielding target sizes of 52 +/- 10 kDa (n = 10) for the LRAT assay with CRBP-retinol and 56 +/- 7 kDa (n = 6) for the LRAT assay with dispersed retinol. These target sizes did not differ from each other but were significantly smaller than that of ARAT. These data provide the first physical evidence of the independent entities which catalyze the ARAT and LRAT reactions of liver microsomes.

Use of photoactivatable peptide substrates of Saccharomyces cerevisiae myristoyl-CoA:protein N-myristoyltransferase (Nmt1p) to characterize a myristoyl-CoA-Nmt1p-peptide ternary complex and to provide evidence for an ordered reaction mechanism.

Nmt1p (EC 2.3.1.97) catalyzes the transfer of myristate (C14:0) from coenzyme A to the N-terminal glycine residue of a variety of eukaryotic cellular and viral proteins. Our recent studies of the 455-amino acid Saccharomyces cerevisiae acyltransferase (Nmt1p) suggested that its mechanism of catalysis is ordered Bi Bi with myristoyl-CoA binding occurring prior to binding of peptide and release of CoA occurring prior to release of the myristoyl-peptide. The interaction between enzyme and peptide has now been examined in greater detail by using photoactivatable octapeptide substrates containing 125I-labeled azidosalicyclic acid attached via an amide bond to the gamma-amino group of a diaminobutyrate residue located at position 2 or the epsilon-amino group of a lysine residue located at position 8. The photopeptides can be specifically crosslinked to chymotryptic fragments of Nmt1p in the presence but not in the absence of a nonhydrolyzable myristoyl-CoA analog, S-(2-oxo)pentadecyl-CoA. Labeling of the chymotryptic fragments is markedly reduced when GLYASKLS, a high-affinity substrate derived from residues 2-9 of S. cerevisiae ADP-ribosylation factor 2, or ALYASKLS, a competitive inhibitor (for peptide), is added with the iodinated photopeptide. These findings suggest that peptide affinity for the acyl-CoA-Nmt1p binary complex is much greater than it is for apoNmt1p, consistent with the ordered Bi Bi mechanism ascribed to Nmt1p. Finally, automated sequential Edman degradation of these chymotryptic fragments suggests that the peptide binding domain of Nmt1p may be composed of elements from two protease-resistant domains, Arg42-Try219 and Thr220-Leu455.

Cloning and characterization of a chalcone synthase gene from mustard and its light-dependent expression.

Genomic DNA from mustard was cloned in EMBL4 and screened for chalcone synthase (CHS) genes using a heterologous cDNA probe from parsley. Two clones which hybridized with the parsley cDNA probe were isolated. They showed different restriction patterns. One clone was sequenced and identified as a CHS gene by sequence comparison with published CHS sequences. The sequence of the coding region is 1188 bp, and encodes a protein of 43 kDa. The start-point of transcription was determined by primer extension. The sequence of 0.9 kbp at the 5' end of the transcription start and part of the noncoding 3' of this gene were also determined. The coding sequence is interrupted by a single intron of 523 bp. The coding and the noncoding 5' sequence of this gene was compared with CHS genes from other species. A very high homology was found with the Arabidopsis CHS coding region. A sequence motif (CACGTGT) which is present in most rbcS and all CHS upstream regions, and which specifically binds a protein factor from plant nuclear extracts, is also present in the upstream region of the mustard CHS gene. Measurements of CHS transcript levels show that phytochrome controls expression of this gene in cotyledons of mustard seedlings; however, blue/UV-light photoreceptors control expression in later stages of development.

Functional size of acyl coenzyme A:diacylglycerol acyltransferase by radiation inactivation.

Rat liver acyl coenzyme A:diacylglycerol acyltransferase, an intrinsic membrane activity associated with the endoplasmic reticulum, catalyzes the terminal and rate-limiting step in triglyceride synthesis. This enzyme has never been purified nor has its gene been isolated. Inactivation by ionizing radiation and target analysis were used to determine its functional size in situ. Monoexponential radiation inactivation curves were obtained which indicated that a single-sized unit of 72 +/- 4 kDa is required for expression of activity. The size corresponds only to the protein portion of the target and may represent one or several polypeptides.

Target size analysis by radiation inactivation of carnitine palmitoyltransferase activity and malonyl-CoA binding in outer membranes from rat liver mitochondria.

The functional molecular sizes of the protein(s) mediating the carnitine palmitoyltransferase I (CPT I) activity and the [14C]malonyl-CoA binding in purified outer-membrane preparations from rat liver mitochondria were determined by radiation-inactivation analysis. In all preparations tested the dose-dependent decay in [14C]malonyl-CoA binding was less steep than that for CPT I activity, suggesting that the protein involved in malonyl-CoA binding may be smaller than that catalysing the CPT I activity. The respective sizes computed from simultaneous analysis for molecular-size standards exposed under identical conditions were 60,000 and 83,000 DA for malonyl-CoA binding and CPT I activity respectively. In irradiated membranes the sensitivity of CPT activity to malonyl-CoA inhibition was increased, as judged by malonyl-CoA inhibition curves for the activity in control and in irradiated membranes that had received 20 Mrad radiation and in which CPT activity had decayed by 60%. Possible correlations between these data and other recent observations on the CPT system are discussed.

Inducible in vivo DNA footprints define sequences necessary for UV light activation of the parsley chalcone synthase gene.

We began characterization of the protein--DNA interactions necessary for UV light induced transcriptional activation of the gene encoding chalcone synthase (CHS), a key plant defense enzyme. Three light dependent in vivo footprints appear on a 90 bp stretch of the CHS promoter with a time course correlated with the onset of CHS transcription. We define a minimal light responsive promoter by functional analysis of truncated CHS promoter fusions with a reporter gene in transient expression experiments in parsley protoplasts. Two of the three footprinted sequence 'boxes' reside within the minimal promoter. Replacement of 10 bp within either of these 'boxes' leads to complete loss of light responsiveness. We conclude that these sequences define the necessary cis elements of the minimal CHS promoter's light responsive element. One of the functionally defined 'boxes' is homologous to an element implicated in regulation of genes involved in photosynthesis. These data represent the first example in a plant defense gene of an induced change in protein--DNA contacts necessary for transcriptional activation. Also, our data argue strongly that divergent light induced biosynthetic pathways share common regulatory units.