光照对大豆叶片苯丙氨酸裂解酶(PAL)基因表达及异黄酮合成的调节

异黄酮是大豆体内特别是种子中积累的一类重要的次生代谢产物,它具有特殊的生物效能。本实验在不同水平（RNA/酶/产物）上研究不同光照条件对大豆叶片异黄酮合成过程中的第一个关键酶苯丙氨酸氨基裂解酶（PAL）基因表达的影响。研究发现,在光照条件下pal表达量比黑暗条件下高,而且其影响程度与品种有关系,种子中异黄酮含量低的品种表现更敏感;其mRNA的合成受红光、蓝光、紫外光的促进,其中紫外光最有效;随着处理时间的延长,mRNA的量和酶活性增加;但是在异黄酮的积累水平上,随着紫外光照射时间的延长,表达量有所下降。     

光照对大豆叶片苯丙氨酸裂解酶(PAL)基因表达及异黄酮合成的调节

异黄酮是大豆体内特别是种子中积累的一类重要的次生代谢产物,它具有特殊的生物效能。本实验在不同水平（ＲＮＡ／酶／产物）上研究不同光照条件对大豆叶片异黄酮合成过程中的第一个关键酶苯丙氨酸氨基裂解酶（ＰＡＬ）基因表达的影响。研究发现,在光照条件下ｐａｌ表达量比黑暗条件下高,而且其影响程度与品种有关系,种子中异黄酮含量低的品种表现更敏感;其ｍＲＮＡ的合成受红光、蓝光、紫外光的促进,其中紫外光最有效;随着处     

Inhibition or initiation of a radical polymerization reaction by an ultraviolet-induced enzymatic process

alpha-Chymotrypsin was modified to a light-controllable enzyme derivative by acylating active serine 195 residue with a cinnamoyl group or analogue. Upon UV irradiation the acylgroup could be isomerized, leading to release of the inhibiting group. Enzymatic activity could thus be regulated by means of UV light. A full 100% inhibition of the enzymatic activity could not be reached by the cinnamoyl derivative. Only posttreatment with diisopropylfluorophosphate yields a fully inactive enzyme derivative. The shelf-life of the inhibited enzyme was rather poor. Only freeze-dried samples could be used for several months without significant recovery of activity. Adapting the sensitivity of the system to visible light seems limited to the size of an enzyme's active site. Combination of the enzymatic system producing an inhibitor or an initiator with a polymerization reaction can result in a photographic process with a higher amplification factor.     

Light product of photoreactive 6-azido-FAD bound to deflavo-milk xanthine oxidase.

Xanthine oxidase from milk was reconstituted with the photoreactive flavin, 6-azido-FAD. While irradiation of the reconstituted enzyme under anaerobic conditions yielded 6-amino-FAD as a light product, aerobic irradiation resulted in formation of an unknown product, which gave the enzyme almost the same activity as that of the native enzyme. The light product could be extracted from the enzyme without breakdown and was found to be highly fluorescent. Upon treatment with phosphodiesterase, this light product was converted to the FMN form. The absorption spectrum of the FMN form has a peak at 464 nm, a shoulder at 450 nm in the visible region, and two peaks at 260 and 298 nm in the UV. Irradiation of free 6-azido-3-methyllumiflavin in the presence of a saturating concentration of oxygen yielded a light product whose absorbance and fluorescence spectra were very similar to those of the light product extracted from the enzyme, suggesting that the two had undergone some common photochemical change at the same place in the isoalloxazine ring. Analysis of the light product of 6-azido-3-methyllumiflavin with 1H NMR and FAB mass spectrometry suggested its possible structure with a new five-membered ring, C(6) = N-O-CH = C(7), adjacent to the benzene ring of the flavin.     

Photo-induced unfolding and inactivation of bovine carbonic anhydrase in the presence of a photoresponsive surfactant

Photoreversible changes in the conformation and enzymatic activity of bovine carbonic anhydrase have been investigated as a function of photoresponsive surfactant concentration and light conditions. The light-responsive surfactant undergoes a photoisomerization from the relatively hydrophobic trans isomer under visible light to the relatively hydrophilic cis isomer upon UV illumination, providing a means to photoreversibly control enzyme–surfactant interactions. Small-angle neutron scattering and dynamic light scattering measurements, along with fluorescence spectroscopy, indicate that carbonic anhydrase unfolds upon addition of the surfactant under visible light, while only a small degree of unfolding is observed under UV light. Therefore, the enzyme is completely inactivated in the presence of the trans surfactant, while 40% of the native activity is preserved under UV light, providing a photoreversible “on/off switch” of enzyme activity. Small-angle neutron scattering data provide details of the in vitro conformational changes of the enzyme in response to the photosurfactant and light, with the enzyme found to aggregate as a result of photosurfactant-induced unfolding. Fourier transform infrared (FT-IR) spectroscopy further provides information on the secondary structure changes of the protein in the presence of photosurfactant.     

Preparation of photo-crosslinkable cinnamate modified hyaluronic acid for immobilization of horseradish peroxidase

In this work, a photo-responsive hydrogel membrane based on cinnamate-modified hyaluronic acid (HA-CM) was developed and safely cross-linked under UV light curing. The obtained material was effectively utilized for immobilization of horseradish peroxidase (HRP) enzyme via encapsulation and entrapment strategy with efficiency above 95%. The prepared HA-CM biopolymer was investigated before the UV curing using instrumental and spectral techniques including Fourier transform infrared (FTIR) and nuclear magnetic resonance (NMR). During the UV irradiation, the progress of the cross-linking reaction was monitored by the UV–vis light spectroscopy. In addition, when the photo-induced cross-linking had accomplished, the morphological appearance of the hydrogel membrane was recorded using a scanning electron microscope (SEM). The HRP immobilized in HA-CM membranes displayed remarkable stability against the environmental pH changes especially under alkaline media and shift the optimum pH to 8 compared to the free HRP, which exhibited the highest activity at pH 7. Also, the entrapped enzyme was able to preserve above 85% of its catalytic activity at higher temperature values where the free enzyme had deactivated by approximately 50%. Moreover, HA-CM-HRP maintained 87% of its activity after 10 sequential reuse cycles, which indicate the economic value of the employed immobilization strategy.     

In vivo adenylate cyclase activity in ultraviolet- and gamma-irradiated Escherichia coli

The incorporation of [14C]adenine into the cyclic AMP fraction by whole cells of Escherichia coli B/r was taken as a measure of the in vivo adenylate cyclase activity. This activity was significantly inhibited by irradiation of the cells either with 60Co gamma-rays or with UV light from a germicidal lamp, suggesting inhibition of cyclic AMP synthesis. The incubation of cells after irradiation with lower doses (50-100 Gy) of gamma-rays produced a significant increase of in vivo adenylate cyclase activity, whereas there was no significant change after higher doses (150 Gy and above). Dark incubation of cells after irradiation with UV light (54 J m-2) led to recovery of enzyme activity to the level measured in unirradiated cells. Thus it appears that the catabolite repression of L-arabinose isomerase induced by UV light, as well as gamma-irradiation, is due to reduced cyclic AMP synthesis in irradiated cells.     

Mammalian mitochondrial endonuclease activities specific for ultraviolet-irradiated DNA.

Mitochondrial forms of uracil DNA glycosylase and UV endonuclease have been purified and characterized from the mouse plasmacytoma cell line, MPC-11. As in other cell types, the mitochondrial uracil DNA glycosylase has properties very similar to those of the nuclear enzyme, although in this case the mitochondrial activity was also distinguishable by extreme sensitivity to dilution. Three mitochondrial UV endonuclease activities are also similar to nuclear enzymes; however, the relative amounts of these enzyme activities in the mitochondria is significantly different from that in the nucleus. In particular, mitochondria contain a much higher proportion of an activity analogous to UV endonuclease III. Nuclear UV endonuclease III activity is absent from XP group D fibroblasts and XP group D lymphoblasts have reduced, but detectable levels of the mitochondrial form of this enzyme. This residual activity differs in its properties from the normal mitochondrial form of UV endonuclease III, however. The presence of these enzyme activities which function in base excision repair suggests that such DNA repair occurs in mitochondria. Alternatively, these enzymes might act to mark damaged mitochondrial genomes for subsequent degradation.     

UV-B and UV-C induction of NADP-malic enzyme in tissues of different cultivars of Phaseolus vulgaris (bean)

The effects of the treatment of different tissues of three bean cultivars (Pinto, Vilmorin and Arroz) with ultra‐violet (UV) UV‐B and UV‐C radiation and red light on the activity, quantity and RNA levels of NADP‐malic enzyme (NADP‐ME) were determined. Exposure to UV‐B radiation for 8 h caused a marked increase of NADP‐ME from leaves, stems and roots in the three cultivars studied. A similar induction was observed in the leaves and stems after 8 h of exposure under UV‐C, but not in the roots, suggesting that a different signal might be acting to induce the expression of NADP‐ME after UV‐B and UV‐C exposure. In contrast, red light was ineffective in inducing NADP‐ME in either tissue, so the regulation of the expression of this enzyme is phytocrome‐independent. The activity of superoxide dismutase, ascorbate peroxidase, catalase and peroxidase was also different in plants treated with UV‐B, UV‐C and photosynthetically active radiation, suggesting that various pathways may be acting in the regulation of these enzymes by UV‐B and UV‐C. Reactive oxygen species (ROS) were also required for UV‐B induction of NADP‐ME, as the addition of ascorbic acid before UV‐B treatment prevented NADP‐ME induction, whereas salicylic acid was not effective in inducing the enzyme, showing that NADP‐ME induction by UV‐B is ROS dependent but salicylic acid independent.     

Reversible control of enzyme-inhibitor interactions with light illumination using a photoresponsive surfactant

The effects of a photoresponsive surfactant and light illumination on the complex formed between ribonuclease A (RNase A) and a protein ribonuclease inhibitor (RI) have been investigated to develop a light-based technique to reactivate an enzyme through surfactant-induced dissociation of the enzyme-inhibitor complex. The photoresponsive surfactant undergoes a photoisomerization from the relatively hydrophobic trans isomer under visible light to the relatively hydrophilic cis isomer upon UV illumination, providing a means to reversibly control protein-inhibitor interactions. In the absence of surfactant, RI binds tightly to RNase A through noncovalent interactions, which inhibits the enzyme activity. Upon addition of the surfactant under visible light, RNase A is reactivated, regaining ~75% of the native activity in the absence of RI. In the presence of the surfactant under UV light, however, the enzyme remains inhibited. Fluorescence spectroscopy, dynamic light scattering, and circular dichroism spectroscopy reveal that RI dramatically unfolds upon addition of the trans form of the surfactant, while RNase A does not undergo noticeable structural changes under the same conditions. This indicates that RNase A reactivation occurs through dissociation of the enzyme-inhibitor complex arising from surfactant-induced unfolding of the inhibitor. As a result, photoresponsive surfactant and light illumination can be used as a novel light-based technique to dissociate enzyme-inhibitor complexes and, thus, reactivate an inhibited enzyme.     

Ultraviolet Light Inhibition of Phytochrome-Induced Flavonoid Biosynthesis and DNA Photolyase Formation in Mustard Cotyledons (Sinapis alba L.)

In cotyledons of etiolated mustard (Sinapis alba L.) seedlings, phytochrome-far-red-absorbing form-induced flavonoid biosynthesis was found to be inhibited by short-term ultraviolet (UV) irradiations. UV inhibition was shown for the synthesis of quercetin, anthocyanin, and also for the accumulation of the mRNA for chalcone synthase, the key enzyme of this pathway. The UV effect was more pronounced on flavonoid biosynthesis, a process that selectively occurs in the epidermal layers, than on the synthesis of mRNA for chlorophyll a/b-binding protein localized in the mesophyll tissue. These UV inhibitory effects were accompanied by cyclobutane pyrimidine dimer (CPD) formation showing a linear fluence-response relationship. CPD formation and UV inhibition of flavonoid biosynthesis was found to be partially reversible by blue/UV-A light via DNA photolyase (PRE), allowing photoreactivation of the DNA by splitting of CPDs, which are the cause of the UV effect. Like flavonoid formation PRE was also induced by the far-red-absorbing form of phytochrome and induction was inhibited by UV. A potential risk of inhibition, in response to solar UV-B irradiation, was shown for anthocyanin formation. This inhibition, however, occurred only if photoreactivation was experimentally reduced. The PRE activity present in the etiolated seedlings (further increasing about 5-fold during light acclimatization) appears to be sufficient to prevent the persistence of CPDs even under conditions of high solar irradiation.     

Purification and characterization of UV endonucleases I and II from murine plasmacytoma cells

Three endonucleases from murine plasmacytoma cells that specifically nick DNA which was heavily irradiated with ultraviolet (UV) light were resolved by Sephacryl S-200 column chromatography. Two of these, UV endonucleases I and II, were purified extensively. UV endonuclease I appears to be a monomeric protein with a molecular mass of 43 kDa; UV endonuclease II has an S value of 2.9 S, with a corresponding molecular mass estimated at 28 kDa. Both enzymes act as a class I AP endonuclease, cleaving phosphodiester bonds via a beta-elimination mechanism, so as to form an unsaturated deoxyribose at the 3' terminus. Both have thymine glycol DNA glycosylase activity and their substrate specificities generally appear to be overlapping but not identical. UV endonuclease I acts on both supercoiled and relaxed DNAs, whereas II acts only on supercoiled DNA. Both enzymes are active in EDTA, but have different optima for salt, pH, and Triton X-100. Each enzyme is also present in cultured diploid human fibroblasts.     

ADP is produced by firefly luciferase but its synthesis is independent of the light emitting properties

During experiments aimed at understanding the time course of appearance of reaction products in the Photinus pyralis luciferase system, an expected compound with a typical nucleotide UV spectrum was isolated. According to capillary electrophoresis (CE) analysis and 1H, 31P-NMR spectra, it was unambiguously found to be ADP, either with extracted or recombinant enzymes. The ADP synthesis was demonstrated by standard UV spectrophotometric methods and CE analysis. Also, the luciferase produced AMP and ATP from ADP. This reaction was completely inhibited by Ap(5)A at 250 nM and was independent of the light emitting properties of the enzyme. The only catalytic mechanism to explain the production of ADP is an intrinsic adenylate kinase activity of luciferase. The K(m) values of the AK activity are 0.3, 0.7, 0.06 mM for AMP, ADP, and ATP respectively. The multiple enzyme activities of luciferase may be partly responsible for the complex kinetics of light emission by changing the nucleotide concentrations.     

Multiple forms of an extracellular cyclic-AMP phosphodiesterase from Dictyostelium discoideum.

The extracellular cyclic-AMP phosphodiesterase of a mutant of Dictyostelium discoideum which accumulates this enzyme was found to exist in multiple forms. Using the isoelectric focusing technique the phosphodiesterase activity was distributed into three peaks with isoelectric points of 4.6, 6.5 and 8.3, designated as p4, p6 and p8. Gel filtration and sucrose gradient analysis showed that the p4 activity consisted of two forms of different sedimentation coefficients. At high enzyme concentrations, the heavy form was favored. Dilution of enzyme activity shifted the equilibrium toward the light form. Direct analysis by sucrose gradient sedimentation of all isoelectric forms demonstrated that besides p4, p6 activity also existed as a mixture of the heavy (9.7 S) and the light (5.4 S) components. In contrast, the p8 activity displayed only the light form. The heterogeneity of the p4 and p6 isoelectric forms was also observed by polyacrylamide gel electrophoresis. A procedure for a partial purification of the extracellular enzyme to about 70-fold is presented.     

Correlation between melanogenic and catalase activity in in vitro human melanocytes: a synergic strategy against oxidative stress

UV-induced DNA damage can lead to melanoma, the most dangerous form of skin cancer. Understanding the mechanisms employed by melanocytes to protect against UV is therefore a key issue. In melanocytes, catalase is the main enzyme responsible for degrading hydrogen peroxide and we have previously shown that that low basal levels of catalase activity are associated with the light phototype in in vitro and ex vivo models. Here we investigate the possible correlation between its activity and melanogenesis in primary cultures of human melanocytes. We show that while the total melanin concentration is directly correlated to the level of pigmentation, the more the degree of pigmentation increased, the lower the proportion of pheomelanin present. Moreover, in human melanocytes in vitro, catalase-specific mRNA, protein and enzymatic activity were all directly correlated with total cellular melanin content. We also observed that immediately after a peroxidative treatment, the increase in reactive oxygen species was inversely associated with pigmentation level. Darkly pigmented melanocytes therefore possess two protective strategies represented by melanins and catalase activity that are likely to act synergistically to counteract the deleterious effects of UV radiation. By contrast, lightly pigmented melanocytes possess lower levels of melanogenic and catalase activity and are therefore more susceptible to accumulate damage after UV exposition.     

Analysis of photoernzymatic repair of UV lesions in DNA by single light flashes. XI. Light-induced activation of the yeast photoreactivating enzyme

Photoreactivating enzyme (PRE) from yeast (as semi-crude extract, or in highly purified form) shows increased activity if its is illuminated with near UV or short wavelength visible light prior to its use for photoenzymatic repair of UV-induced pyrimidine dimers in transforming DNA in vitro. This effect results from an alternation in PRE molecules changing those with low activity in the light-dependent step of the reaction to a higher activity. Light-induced activation of PRE preparations is slowly lost by dark storage for several hours to 1 day (faster at 23°C than at 5°C), but can be recovered repeatedly by renewed preillumination. The action spectrum for these preillumination effects generally resembles that for the photoenzymatic repair reaction itself, having its maximum in the same 355–385 nm region as the latter, but light of somewhat longer wavelengths (546 nm) is still effective. Preilluminated PRE is also more stable to thermal inactivation (65°C) than untreated enzyme.     

Change in the reaction of the antioxidant system of wheat sprouts after UV-irradiation of seeds

The response of the antioxidant system of sprouts of wheat Triticum aestivum L. to preliminary irradiation of seeds with UV light was studied. The dependence of lipid peroxidation and the extent of antioxidant activity on the duration of irradiation was studied. It was shown that low doses of UV radiation (5-15 min) stimulate the antioxidant protection of green wheat sprouts grown for eight days. Increasing the irradiation time to 30-60 min leads to the inhibition of lipid peroxidation by the antioxidant system. A more prolonged irradiation of seeds with UV light (for 1-6 h) led to an increase in the level of lipid peroxidation in sprouts. However, 1-2-day-old sprouts from seeds irradiated for 5-6 h, adapted themselves to the influence due to the compensatory mechanisms. By the 8th day of germination of preliminarily irradiated seeds, the content of antioxidants and malone dialdehyde returned to the norm. The dynamics of activity of peroxidase in seeds irradiated with low doses of UV light for 30 min was studied. It was found that on the third day of seed germination, a decrease in peroxidase activity followed by its slight increase occurred. The maximum activity of the enzyme in the endosperm was observed on day 5-6, and in roots and green sprouts, on day 3-5 of germination. It was concluded that antioxidants and peroxidase are involved in the compensatory mechanisms of inhibition of free radicals formed upon UV irradiation of seeds.     

Ultraviolet irradiation of DNA: a way of generating partial digests for rapid restriction site mapping

UV-irradiation of DNA can inhibit the activity of certain restriction endonucleases because of thymine dimer formation within the enzyme recognition sequence. The number of sites affected depends upon the dose of UV, thus making it easier to control the extent of enzyme digestion than by either limiting the digestion time, or the amount of enzyme. Restriction-site maps of bacteriophage lambda recombinants are readily produced by labelling DNA using a radioactive oligonucleotide that is complementary to either the left or right cohesive end of lambda, irradiating the DNA with UV light, limit digesting with the appropriate enzyme, and calculating the size of the fragments detected after gel electrophoresis and autoradiography.