Photocontrol of seed germination in Impatiens wallerana Hook. f.

General characteristics of light sensitivity of Impatients wallerana seeds were investigated. Germination was absolutely dependent on light, irrespective of temperature. High percentages of germination were obtained by exposure to long periods of illumination or, alternatively, to several repeated short irradiations with red light. In this case, responsiveness to light was not altered by increasing either the initial incubation period in darkness or the dark intervals between short exposures. Effects of red light were reversed by far-red light, thus demonstrating the involvement of phytochrome. Evidence was presented for an interactive effect, of unknown physiological nature between red and far-red light on the germination of the seeds.Abbreviations P_r phytochrome, red light absorbing form - Pfr phytochrome far-red absorbing form     

Photocontrol of Parasitism in a Parasitic Flowering Plant, Cuscuta japonica Chois, Cultured in Vitro

Far-red light induced mutual and self parasitism of Cuscutajaponica in vitro. Blue light was less effective than far-redlight because of its weak effect on induction of haustoria,although it stimulated mutual twining of stems. No parasitismwas observed under white or red light, or in darkness. (Received August 5, 1994; Accepted February 9, 1995)     

Light-Stimulated Apical Hook Opening in Wild-Type Arabidopsis thaliana Seedlings

Apical hook opening and cotyledon unfolding are characteristic responses that occur during deetiolation of dicotyledonous seedlings. Light-stimulated apical hook opening and cotyledon unfolding in etiolated Arabidopsis thaliana seedlings appears to involve the activities of multiple photosensory systems. Red, far-red, and blue light are all effective in stimulating these responses in Arabidopsis. Stimulation of hook opening by red light and low fluence blue light is inductive, far-red reversible, and exhibits reciprocity, as is characteristic of many low fluence-dependent phytochrome-mediated responses. Far-red and high-fluence blue light appear to stimulate hook opening and cotyledon unfolding through high-irradiance-response systems during long-term light treatments. Although a phytochrome high-irradiance-response system presumably mediates the responses in far-red light, the responses to high-fluence blue light may be mediated by a blue light-specific photosensory system.     

藻类的光控发育

藻类发育的许多方面受光的调控,且多种多样的光受体参与藻类的光形态建成过程。本文就近年来藻类光形态建成领域的研究进展简要综述,内容以海洋藻类为主,主要包括光周期、非光周期控制的藻类发育类型,以及藻类的光受体的种类及分子特性,并兼顾与高等植物的相关特性进行比较。     

Photocontrol of germination in Amaranthus caudatus

Summary Germination of Amaranthus caudatus is inhibited by light, far-red being the most effective part of the spectrum. At temperatures of 25° and below there is a low final germination percentage under continuous far-red whereas above 25° there is only a delaying effect. In the presence of a saturating concentration of gibberellic acid (GA₃) at 25° seeds germinate under continuous far-red although they are delayed. At 25° seeds exposed to 48 hr far-red fail to germinate when transferred to darkness. This induced dormancy can be broken by a single short exposure to red light given at any time after the far-red illumination. This effect of short red can be reversed by a subsequent short period of far-red indicating that the seeds are phytochrome controlled. Although most seeds have escaped from the reversing effect of short far-red after an intervening dark period of 5 hours, germination is greatly reduced by continuous far-red at this time. Results of exposing seeds to varying periods of far-red before and after dark imbibition are interpreted in terms of a continual production of phytochrome in its active P _fr form and a requirement for P _fr action over a long period of time. Effects of intermittent and continuous low intensity far-red on the inhibition of germination provides further evidence for a low energy photoreaction involving phytochrome. Effects on Germination Index of continuous illumination with various light sources maintaining different P _fr /P _total ratios have been investigated. The results suggest that the proportion of phytochrome in the P _fr form is the most important factor in the regulation of germination. A scheme for the phytochrome control of germination in Amaranthus caudatus is presented and possible explanations for the dependence on P _fr /P _total ratio are discussed.Holder of a Science Research Council Studentship.     

Identification of Tinospora cordifolia (Willd.) Miers ex Hook F & Thomas using RAPD markers

Identified germplasm is an important component for efficient and effective management of plant genetic resources. Traditionally, plant identification has relied on morphological characters like growth habit, floral morphology like flower colour and other characteristics of the plant. Studies were undertaken for identification and genetic variation within 15 clones of Tinospora cordifolia through random amplified polymorphic DNA (RAPD) markers. Analysis was made using forty decamer primers. Out of them, 15 primers were selected and used for identification and genetic relationships within 15 clones. A total of 138 distinct DNA fragments ranging from 0.2 to 3.2 kb were amplified using 15 selected random primers. The genetic similarity was evaluated on the basis of presence or absence of bands. The genetic distance was very close within the clones. Thus, these RAPD markers have the potential for identification of species and characterization of genetic variation within the population. This study will be helpful to know the genetic background of the medicinal plants with high commercial value, and also provides a major input into conservation biology.     

Photocontrol of anthocyanin biosynthesis in tomato

Juvenile anthocyanin biosynthesis has been studied in dark-grown seedlings of tomato (Lycopersicon esculentum Mill.) wild types (WTs) and photomorphogenic mutants. During a subsequent 24-hr period of monochromatic irradiation at different fluence rates of red light (R) the fluence-rate response relationships for induction of anthocyanin in all the WTs are similar, yet complex, showing a response at low fluence rates (LFRR) followed by a fluence rate-dependent high irradiance response (HIR). In the hypocotyl this response is restricted to the sub-epidermal layer of cells. The high-pigment-1 (hp-1) mutant exhibits a strong amplification of both response components. Theatroviolacea (atv) mutant shows strongest amplification of the HIR component. In contrast, a transgenic line overexpressing an oat phytochrome A gene (PHYA3 ⁺) shows a most dramatic amplification of the LFRR component. The far-red light (FR)-insensitive (fri) mutant, deficient in phytochrome A (phyA), lacks the LFRR component whilst retaining a normal HIR. The temporarily R-insensitive (tri) mutant, deficient in phytochrome B1 (phyB1) retains the LFRR, but lacks the HIR. Thehp-1,fri andhp-1,tri double mutant, exhibit amplified, yet qualitatively similar responses to the monogenicfri andtri mutants. Thefri,tri double mutant lacks both response components in R, but a residual response to blue light (B) remains. Similarly, theaurea (au) mutant deficient in phytochrome chromophore biosynthesis and presumably all phytochromes, lacks both response components in the R and FR regions of the spectrum. Experiments at other wavelengths demonstrate that while there is only a small response in the FR spectral region (729 nm) in tomato, there is an appreciable HIR response in the near FR at 704 nm, which is retained in thetri mutant. This suggests that the labile phyA pool participates in the HIR at this wavelength. The intense pigmentation (Ip) mutant appears to be specifically deficient in the B1 induced anthocyanin biosynthesis. Adult plants, grown under fluorescent light/dark cycles, show a reduction of anthocyanin content of young developing leaves upon application of supplemtary or end-of-day FR. The involvement of different phytochrome species in anthocyanin biosynthesis based on micro-injection studies into theau mutant and studies using type specific phytochrome mutants is discussed.     

The Role of Various Regions of the Bean Hypocotyl on Red Light-induced Hook Opening

Measurement of various zones on the concave half of etiolated Phaseolus vulgaris L. (cv. Black Valentine) hypocotyls has shown that growth at the basal portion of the elbow and the contiguous upper portion of the shank was stimulated earliest by red light. Growth of these two zones was unaffected by the tissue of the convex half but was inhibited by tissue distal to them. The inhibition was alleviated by the continuous presence of shank tissue below the growing zones. Based on cuts made halfway through the hypocotyl at positions above, below, or between the two zones of growth, it is suggested that cells at the inner portion of the upper shank control in some way the light-induced growth of the elbow cells directly above.     

Photocontrol of stem growth

Rapid and measurable growth rate changes that occur in seedling stems upon illumination serve as an excellent means to analyze signal transduction. Growth kinetic studies have shown how red, far-red and blue light signals are transduced via the solitary and/or coordinated action of known plant photoreceptors. These reports are consistent with current findings describing light-induced photoreceptor interaction and compartmentation.     

Photocontrol of anthocyanin formation in turnip seedlings

Summary The substitution of red or blue light for the first six hours of prolonged irradiation with far-red light reduced anthocyanin formation by about 60%; red or far-red light similarly substituted for blue light had little effect. It is concluded that the effects of prolonged irradiation with blue and far-red depend, in part at least, on different photoreceptors.The effects of pre-treatment with red or blue light also occurred when only short exposures to light were given, and were reversed by immediate brief exposures to far-red. The depressing effect of a short pre-irradiation treatment was largely prevented if seedlings were kept at low temperature or in an atmosphere of nitrogen in the dark period before transfer to the prolonged far-red treatment. The effect of the pre-irradiation treatment is attributed to enzymatic destruction of phytochrome following conversion to the P_FR form, and it is suggested that anthocyanin synthesis in far-red light largely depends on phytochrome, possibly due to the maintenance of a low level of P_FR in the tissue by the absorption tail of P_R in the far-red.A pre-irradiation treatment with red also decreased the inhibitory effect of far-red on hypocotyl elongation but did not change the response to blue light.

---

Zusammenfassung Die Anthocyanbildung war im langfristig gegebenen Dunkelrot bis zu etwa 60% reduziert, wenn die ersten 6 Std durch hellrote oder blaue Bestrahlung ersetzt wurden; Hellrot oder Dunkelrot in gleicher Weise im Dauerblaulicht substituiert waren praktisch wirkungslos. Daraus wird geschlossen, daß der Effekt einer Dauerbestrahlung mit Blau und Dunkelrot zum Teil jedenfalls, auf verschiedene Photorezeptoren zurückzuführen ist.Der Effekt einer Vorbehandlung mit hellrotem oder blauem Licht trat auch dann auf, wenn nur kurzfristige Bestrahlungen gegeben wurden und konnte durch unmittelbar nachfolgende kurze Dunkelrot-Belichtung wieder aufgehoben werden. Die Hemmung durch kurzfristige Vorbestrahlung konnte weitgehend verhindert werden, wenn die Keimlinge während der Dunkelperiode, vor der Übertragung in Dauerdunkelrot, bei tiefer Temperatur oder unter Stickstoff gehalten wurden. Der Vorbelichtungseffekt wird auf die enzymatische Destruktion von Phytochrom, nach der Umwandlung in die P_FR-Form, zurückgeführt und es wird vermutet, daß die Anthocyansynthese im Dauerdunkelrot weitgehend phytochromabhängig ist, wahrscheinlich durch die Aufrechterhaltung eines niedrigen P_FR Niveaus im Gewebe infolge der schwachen Absorption von P_R im Dunkelrot.Eine Vorbelichtung mit Hellrot verringerte ebenfalls die hemmende Wirkung von Dunkelrot auf das Hypokotylwachstum, war jedoch ohne Einfluß im Blaulicht.

     

Photocontrol of immobilized trypsin activity

Trypsin was coupled on an agarose gel which was modified with a spiropyran compound. The trypsin–spiropyran (agarose) gel showed reverse photochromism. The activity of the trypsin–spiropyran gel in the dark was 12% of that of native trypsin, and it was higher than that under visible light. The apparent Michaelis constant of the trypsin–spiropyran gel in the dark was larger than that under visible light. On the other hand, the maximum velocity in the dark was higher than that under visible light. The optimum pH of the trypsin–spiropyran gel in the dark was the same as that under visible light. Immobilized trypsin was stable in the pH range from 3 to 9. The trypsin–spiropyran gel was more stable against heat than the native trypsin.     

Photocontrol of anthocyanin formation in turnip seedlings

Summary The substitution of far-red for the first six hours of a prolonged irradiation with red light resulted in a large increase in anthocyanin yield, which was greater than the combined yields from far-red and red when the two treatments were given separately. When intermittent far-red irradiation was followed by a single short exposure to red, a considerable amount of anthocyanin was formed, although each treatment given separately had little effect. Four hours continuous far-red alone yielded some anthocyanin and also resulted in a further large increase in the effect of a short red treatment; this terminal red effect was fully reversible by a subsequent brief exposure to far-red. It is concluded that at least two photochemical reactions are involved in the responses to red and far-red, the first leading to the formation of substrate(s) used in the second reaction.When red light preceded exposure to the far-red/red irradiation sequence, the far-red enhancement effect was almost entirely lost and the anthocyanin yield approached that in red light. The effect of the red pre-irradiation treatment is attributed to destruction of phytochrome and it is suggested that phytochrome is the only pigment mediating anthocyanin synthesis in red and far-red. A possible interpretation is that the high-energy reaction in far-red and the low energy red/far-red reversible reaction are mediated by different forms of phytochrome.The substitution of blue for the first six hours of a prolonged irradiation with red light also resulted in a synergistic increase in anthocyanin yield; the enhancement effect of blue light was, however, not prevented by prior exposure to red. It is concluded that phytochrome is not the only pigment mediating the reactions occurring in blue light. The synergism between blue and red suggests that the high-energy reaction in blue light may lead to the production of substrates for phytochrome action.

---

Zusammenfassung Die Substitution der ersten 6 Std einer Hellrot-Dauerbestrahlung durch Dunkelrot führte zu einem starken Anstieg im Anthocyangehalt, der höher war als die Summe aus Dunkelrot und Hellrot, wenn beide Bestrahlungen getrennt gegeben wurden. Folgte auf intermittierende Dunkelrot-Bestrahlung eine einmalige Dosis Hellrot, bildete sich eine beträchtliche Menge Anthocyan, obwohl jede Bestrahlung für sich kaum wirksam war. 4 Std Dauerdunkelrot induzierten bereits meßbare Anthocyanbildung, die durch kurze Hellrot-Bestrahlung weiter gesteigert werden konnte; der Effekt dieser terminalen Dosis Hellrot konnte durch nachfolgende kurze Dunkelrot-Bestrahlung wieder rückgängig gemacht werden. Daraus wird geschlossen, daß wenigstens zwei photochemische Reaktionen bei Bestrahlung mit Hellrot und Dunkelrot ablaufen, wobei die erste Substrat(e) für die zweite produziert.Wurde vor einer Dunkelrot-Hellrot-Sequenz mit Hellrot bestrahlt, ging die fördernde Wirkung von Dunkelrot fast vollständig verloren und der Anthocyangehalt entsprach annähernd dem in Hellrot. Der Effekt der Hellrot-Vorbestrahlung wird auf die Destruktion von Phytochrom zurückgeführt und es wird vermutet, daß Phytochrom das einzige Pigment ist, das bei der Anthocyansynthese in Hellrot und Dunkelrot beteiligt ist. Eine mögliche Interpretation wäre, daß die Hochenergiereaktion in Dunkelrot und die Hellrot-Dunkelrot reversible Niederenergiereaktion durch verschiedene Formen von Phytochrom vermittelt werden.Die Substitution der ersten 6 Std einer Dauerbelichtung mit Hellrot durch Blau ergab ebenfalls eine synergistische Zunahme im Anthocyangehalt. Der fördernde Effekt von Blaulicht konnte jedoch durch Vorbestrahlung mit Hellrot nicht verhindert werden. Daraus wird geschlossen, daß Phytochrom nicht das einzige Pigment sein kann, das die Reaktionen in Blaulicht vermittelt. Der Synergismus zwischen Blau und Hellrot läßt vermuten, daß die Hochenergiereaktion in Blau zur Produktion von Substrat führt, mit dem Phytochrom reagieren kann.

     

Photocontrol of anthocyanin formation in turnip seedlings

Summary The insertion of a dark period during irradiation with far-red resulted in the occurrence of a second lag-phase in the synthesis of anthocyanin when the seedlings were returned to light. The length of this second lag-phase was similar, to the first. It is suggested that the action of far-red light may not involve gene activation but rather the formation of substrate(s); the lag-phase may arise from ratelimiting steps in the synthesis of anthocyanin pigment.     

Photocontrol of Spirodela intermedia flavonoids

Clone 115 of Spirodela intermedia W. Koch grown in Hutner's medium with sucrose produces the glycoflavones vitexin and orientin in darkness or in light of various wavelengths. The anthocyanin cyanidin-3-monoglucoside was present only after prolonged illumination of the plants with white or blue light. No cyanidin-glucoside was formed under constant red light. The substitution of red, blue, or far-red light for the last 24 hours of culture under constant white light reduced each flavonoid over those maintained in white light or given 24 hours of darkness. Reducing the light intensity from 900 to 400 ft-c of constant cool-white fluorescent light had no appreciable influence on vitexin (4′-hydroxyl) but markedly reduced orientin and cyanidin-glucoside (both 3′4′-hydroxyl). Substituting alternate 12-hour periods of light and darkness for continuous light reduced the glycoflavones approximately 50% while cyanidin-glucoside was reduced about 85%. Most responses to red, blue, or far-red light are consistent with a phytochrome-controlled promotion of vitexin synthesis.

The evidence suggests that in S. intermedia: A) Environmental conditions which elicit cyanidin-glucoside and glycoflavone synthesis are different since a prolonged illumination with white light is required for the former but not the latter. B) The availability of a 3′4′-hydroxyl precursor for orientin and anthocyanin probably limits their synthesis in low intensity light. Since vitexin is essentially unaltered under these conditions this also suggests that acetate or malonate units for the A-ring and the deamination products of aromatic amino acids for the B-ring and carbons of the C-ring are not limiting factors. C) Light controls the biosynthesis of flavonols in the same manner as glycoflavones; under all experimental conditions the synthesis of kaempferol paralleled vitexin while quercetin responded in the same manner as crientin.