Green Light Drives CO2 Fixation Deep within Leaves

Maximal ^l4CO₂-fixation in spinach occurs in the middle of thepalisade mesophyll [Nishio et al. (1993) Plant Cell 5: 953],however, ninety percent of the blue and red light is attenuatedin the upper twenty percent of a spinach leaf [Cui et al. (1991)Plant Cell Environ. 14: 493]. In this report, we showed thatgreen light drives ¹⁴CO₂-fixation deep within spinach leavescompared to red and blue light. Blue light caused fixation mainlyin the palisade mesophyll of the leaf, whereas red light drovefixation slightly deeper into the leaf than did blue light.¹⁴CO₂-fixation measured under green light resulted in less fixationin the upper epidermal layer (guard cells) and upper most palisademesophyll compared to red and blue light, but led to more fixationdeeper in the leaf than that caused by either red or blue light.Saturating white, red, or green light resulted in similar maximal¹⁴CO₂-fixation rates, whereas under the highest irradiance ofblue light given, carbon fixation was not saturated, but itasymptotically approached the maximal ¹⁴CO₂-fixation rates attainedunder the other types of light. The importance of green lightin photosynthesis is discussed. ¹Supported in part by grants from Competitive Research GrantsOffice, U.S. Department of Agriculture (Nos. 91-37100-6672 and93-37100-8855).     

Physiological role of anthocyanin accumulation in common hazel juvenile leaves

Common hazel (Corylus avellana L., Fusca rubra Dipp.) juvenile leaves from the periphery of the canopy and thus subjected to high fluxes of solar radiation are characterized by red coloration due to anthocyanin accumulation disappearing in mature leaves. To elucidate the physiological role of anthocyanin accumulation, the interrelations between anthocyanin content, a degree of attenuation by the pigments of the light reaching the photosynthetic apparatus (PSA), and PSA tolerance to photoinhibition in C. avellana juvenile leaves were studied. Absorption spectra were calculated taking into account the light losses due to reflection by the leaf. The analysis of the spectra showed that, in red common hazel leaves accumulating high amounts of anthocyanins in the vacuoles of the upper and lower epidermal cells, up to 95% of visible radiation entering the leaf blade was absorbed by these pigments. The rate of the linear electron transport (ETR) in the chloroplast electron transport chain (ETC) was closely correlated with the anthocyanin content (r ² = 0.87). In red leaves, the saturation of ETR dependence on irradiance was observed at the higher values of PAR than in green leaves. In red juvenile leaves, this value was close to that in mature green leaves tolerant to high light. There were no differences between red and green leaves in the level of non-photochemical quenching, the content of violaxanthin cycle pigments, a degree of their de-epoxidation under natural illumination and at irradiation with high PAR fluxes. Basing on the data obtained, one may conclude that anthocyanins in C. avellana juvenile leaves serve PSA photoprotection, preventing injury of immature PSA with excessive fluxes of PAR.     

Changes of Anatomical Features, Photosynthesis and Ribulose Bisphosphate Carboxylase-Oxygenase Content of Mango Leaves

Changes in anatomical and physiological features, includingchanges in amount per unit area of anthocyanin and chlorophyll,in leaves of seedling mango (Mangifera indica L. cv. Irwin)trees were determined to understand what controls the rate ofphotosynthesis (Pn) at various stages of development. The youngleaves of seedling trees contained high concentrations of anthocyanin.During enlargement of leaves, the disappearance of anthocyaninand the accumulation of chlorophyll occurred concomitantly;the anthocyanin content began to decrease markedly once theleaf area had reached a maximum. During the early period ofleaf development, the thickness of mesophyll tissue decreasedtemporarily, but when the length of the leaf reached half thatof a mature leaf, the mesophyll began to thicken again. Smallstarch grains appeared in the chloroplasts of the young leavesand chloroplast nucleoids (ct-nuclei) were distributed throughoutthe chloroplasts. When leaves matured, ct-nuclei were displacedto the periphery of chloroplasts because of the accumulationof large starch grains. Compared with young leaves, green andmature leaves contained greater concentrations of ribulose bisphosphatecarboxylase-oxygenase (RuBisCO) protein. The results of immunocytochemicalexamination of RuBisCO under the light microscope reflectedthe results of electrophoresis measurements of RuBisCO. Pn waslow during the chocolate-coloured stage of early leaf development.In green and mature leaves Pn was higher; the average Pn was7·6 mg CO₂ dm^-2 h^-1 under light at intensities above500 µmol m^-2 s^-1.Copyright 1995, 1999 Academic Press Mangifera indica L., mango leaf, chloroplast nucleoids, chloroplast ultrastructure, starch accumulation, anthocyanin, chlorophyll, DAPI staining, SDS-PAGE, immunocytochemical technique     

Red light stimulates flowering and anthocyanin biosynthesis in American cranberry

Morphological responses of American cranberry (Vacciniummacrocarpon Ait, Ericaceae) to different light conditions (red,far-red, white light and sunlight) were examined. Root growth and development,stem elongation, leaf enlargement, de-etiolation of stem and leaf, flower budformation, and flowering of American cranberry were measured under each lightcondition and in the dark. It was found that red light promotes development ofroots and leaves, flowering, and de-etiolation of stem and leaf of Americancranberry. Stem elongation and etiolation of stem and leaf were shown infar-redlight and dark. Anthocyanin biosynthesis as phytochemical response in cranberryplants was most sensitive to red light. Estimation of anthocyanin levels indifferent parts of cranberry plant suggested that anthocyanins were presentonlyin red fruit skins, and not in peeled fruits, green fruits, green leaves, greenstems, roots and seeds.     

Attenuation of incident light in Galax urceolata (Diapensiaceae): concerted influence of adaxial and abaxial anthocyanic layers on photoprotection

Although anthocyanin coloration in lower (abaxial) leaf cells has been documented for numerous species, the functional significance of this character has not been comprehensively investigated according to habitat or leaf orientation. Here, we demonstrate that abaxial anthocyanin may function as a photoprotectant, similarly to its purported role in upper (adaxial) cells, in leaves vulnerable to high irradiance incident on abaxial surfaces. Spectral scans were derived for Galax urceolata leaves with the following phenotypes: abaxial or adaxial anthocyanin only, abaxial and adaxial anthocyanin, and no anthocyanin. To determine whether anthocyanins conferred protection from photoinhibition, maximum photosystem II efficiencies of red (anthocyanic) and green (acyanic) surfaces were compared during and after exposure to photoinhibitory conditions. Leaves were either positioned with their adaxial surfaces facing the light source or inverted to expose abaxial surfaces. Spectral scans showed increased absorptance of 500-600 nm wavelengths by red surfaces (consistent with the absorbance spectrum of anthocyanin), regardless of whether that surface was abaxial or adaxial. Leaves with anthocyanin in either illuminated surface were also photoinhibited less than leaves lacking anthocyanin in that surface. These results suggest that anthocyanic layers reduce absorbed sunlight in the mesophyll not only for adaxial surfaces, but also for the abaxial. Adaxial/abaxial anthocyanin plasticity may therefore be adaptive in high-light environments or during light-sensitive developmental stages where leaf orientation and/or substrate albedo are variable.     

南天竹不同叶色与若干生理生化指标关系的研究

本文研究南天竹不同叶色的叶片叶绿素、花青素、可溶性糖含量和气孔密度、POD、CAT活性的变化。结果表明,南天竹叶色差异与花青素、叶绿素含量有关,绿叶花青素含量低、叶绿素含量高;红叶则相反。此外,红叶下表皮气孔数目少,气孔小;绿叶气孔数目多,气孔大。红叶的可溶性糖含量明显高于绿叶,而POD和CAT活性低于绿叶。     

Profiles of photosynthesis within red and green leaves of Quintinia serrata

We have measured photosynthesis at the cellular, tissue, and whole leaf levels to understand the role of anthocyanin pigments on patterns of light utilization. Profiles of chlorophyll fluorescence through sections of red and green leaves of Quintinia serrata showed that anthocyanins in the mesophyll restricted absorption of green light to the uppermost palisade mesophyll. The distribution was further restricted when anthocyanins were also present in the upper epidermis. Mesophyll cells located beneath a cyanic light-filter assumed the characteristic photosynthetic features of shade-adapted cells. As a result, red leaves showed a 23% reduction in CO₂ assimilation under light-saturating conditions, and a lower threshold irradiance for light-saturation, relative to those of green leaves. The photosynthetic characteristics of red leaves are comparable to those of shade-acclimated plants.     

Red leaf margins indicate increased polygodial content and function as visual signals to reduce herbivory in Pseudowintera colorata

Red-pigmented leaf margins are common, but their functional significance is unknown. We hypothesized that red leaf margins reduce leaf herbivory by signalling to herbivorous insects the presence of increased chemical defences. Leaves were collected from a natural population of Pseudowintera colorata. Margin size, herbivory damage, anthocyanin content and concentrations of polygodial, a sesquiterpene dialdehyde with antifeedant properties, were quantified. Feeding trials involving larvae of Ctenopseustis obliquana, a generalist herbivore, were conducted on red- and green-margined P. colorata leaves in darkness, or under white, green or red light. Leaves with wider red margins contained higher concentrations of polygodial and anthocyanins, and incurred less natural herbivory. In trials under white light, C. obliquana consumed disproportionately more green- than red-margined leaf laminae. Larvae exhibited no feeding preference when light was manipulated such that leaf colour discrimination was impaired. Red leaf margins provide a reliable and effective visual signal of chemical defence in P. colorata. Ctenopseustis obliquana larvae perceive and respond to the colour of the leaf margins, rather than to olfactory signals. Our study provides direct experimental evidence for aposematic coloration in red leaves.     

Association of red coloration with senescence of sugar maple leaves in autumn

We evaluated the association of red coloration with senescence in sugar maple (Acer saccharum Marsh.) leaves by assessing differences in leaf retention strength and the progression of the abscission layer through the vascular bundle of green, yellow, and red leaves of 14 mature open-grown trees in October 2002. Computer image analysis confirmed visual categorization of leaves as predominantly green, yellow or red, and chemical quantification of leaf pigment concentrations verified that leaf color reflected underlying differences in leaf biochemistry. Significantly lower chlorophyll concentrations within red and yellow leaves indicated that senescence was more advanced in leaves from these color categories relative to green leaves. Among leaf types, only red leaves contained high concentrations of anthocyanins. There were significant differences in leaf retention capacity among color categories, with the petioles of green leaves being the most firmly attached to twigs, followed by red and then yellow leaves. Microscopic analysis indicated that yellow leaves had the most advanced extension of the abscission layer through the vasculature, with green and red leaves having significantly less abscission layer progression than yellow. A more limited progression of the abscission layer through vascular bundles may be evidence of delayed leaf senescence that could extend resorption of mobile leaf constituents. Together, results from this study suggest an association between leaf anthocyanin content and functional delays in senescence.     

Effects of Green Light on the Chloroplasts of Spinach Leaf Discs

The development and photosynthetic capacity of chloroplastsformed in green light in cultured spinach leaf discs has beenstudied. At intensities of 4 to 6 mW cm^–2 green lightstimulates chloroplast replication to about the same extentas white, blue, and red light. However, practically no chloroplastreplication occurs in discs grown in low intensity green orwhite light but considerable chloroplast growth takes place.Ultrastructural studies have shown that these chloroplasts,which can be two to five times the area of control plastids(high intensity white light), have an essentially normal thylakoidsystem. Double isotope labelling experiments have establishedthat the synthesis of chloroplast ribosomal-RNA is similar incontrols and in discs grown in low intensity green or whitelight. On a per unit chlorophyll basis the CO₂ fixation rateof spinach discs grown in low intensity green (or white) lightsaturates with increasing light intensity or increasing CO₂concentration at values well below control discs. In this respecttheir photosynthetic characteristics bear a similarity to thoseof shade plants.     

Intra-species variation in transient accumulation of leaf anthocyanins in Cistus creticus during winter: evidence that anthocyanins may compensate for an inherent photosynthetic and photoprotective inferiority of the red-leaf phenotype

Leaf color in some individuals of Cistus creticus turns transiently to red during winter, while neighboring individuals occupying the same site remain green. We have examined whether anthocyanin accumulation can be associated with variations in photosynthetic and/or photoprotective characteristics between the two phenotypes, rendering the red phenotype more vulnerable to photoinhibition and, accordingly, needing additional protection in the form of anthocyanins. Towards this aim, maximum (pre-dawn) and effective (mid-day) PSII photochemical efficiencies, xanthophyll cycle pool sizes and leaf nitrogen contents were seasonably followed, encompassing both the green (spring, summer, autumn) and the red (winter) period of the year. Moreover, the distribution of the two phenotypes in exposed and shaded sites was assessed. The frequency of red individuals was considerably higher in fully exposed sites, pointing to a photoprotective function of leaf anthocyanins. Yet, the assumption was not corroborated by pre-dawn PSII yield measurements, since both phenotypes displayed similar high values throughout the year and a similar drop during winter. However, the red phenotype was characterized by lower light-saturated PSII yields, xanthophyll cycle pool sizes and leaf nitrogen, during both the green and the red period of the year. Based on this correlative evidence, we suggest that winter redness in C. creticus may compensate for an inherent photosynthetic and photoprotective inferiority, possibly through a light screen and/or an antioxidant function of leaf anthocyanins.     

Anthocyanin Influence on Water Proton NMR Relaxation Times and Water Contents in Leaves of Evergreen Woody Plants During the Winter

An investigation was made to determine the effect of anthocyaninin red-colored evergreen leaves during the mid-winter on waterproton NMR relaxation times (T₁). Water contents, anthocyanincontentsand histologic localization of red-coloration in mesophyllswere determined by using both red-colored and green leaves fromthe same branches of Rhododendron, Viburnum and Mahonia, respectively.Although the decrease of water contents in the red-colored leavesin Mahonia was insignificant, decreases in the former two specieswere clearly observable. T₁ differences between red-coloredand green leaves for the three species were insignificant. Increasesof anthocyanin contents and histologic localization of red colorationin mesophylls for the red-colored leaves were more pronouncedin Rhododendron and Viburnum than in Mahonia. These observationssuggest that the pronounced increases of histologic localizationof red-colored mesophyll cells and anthocyanin contents in red-coloredleaves for the former two species contribute to maintenanceof T₁ relaxation times in spite of the marked decrease of watercontents in leaves. It is assumed that the increase of localizationareas of red-colored parenchymatous cells in mesophylls is moreeffective than the total contents of anthocyanins in leavestowards the maintenance of the T₁ level in red-colored leaves,and this appears to be dependent on the vacuolar compartmentationof anthocyanin in mesophyll cells. (Received August 3, 1991; Accepted December 12, 1991)     

Photomorphogenesis, Photosynthesis, and Early Growth of Primary Leaves of Phaseolus vulgaris

The response of leaf tissue to white, blue, red, and far-redlight has been examined. Leaves on plants grown in darknessshow increased cell number, cell volume, and area when exposedto long periods (up to 48 h) of low-intensity red, blue, orfar-red radiation. This is believed to be a photomorphogenicresponse which does not involve photosynthesis. Leaves fromplants exposed to white light during germination do not usuallyrespond to red, blue, or far-red light. An exception to thiswas found for leaf discs which showed a larger increase in areathan the dark controls following exposure to far-red light for24 h. Leaf tissue from light-grown plants responds to high-intensitywhite light, probably through photosynthesis. Discs cut fromdark-grown plants and cultured in white light grow equally wellin air and CO₂-free conditions. Application of the photosyntheticinhibitor DCMU reduces growth and chlorophyll formation, however. It is concluded that light, perhaps acting through the phytochromemechanism, has initially a number of morphogenic effects includinginitiation of development of the photosynthetic apparatus. Theresponses to photomorphogenically active radiation do not persistand light effects through photosynthesis are rapidly initiatedand dominate the later stages of leaf growth.     

The Influence of Temperature on Photosynthesis and Transpiration in ten Temperate Grass Varieties Grown in four Different Environments

The influence of temperature on photosynthesis and transpirationwas studied in ten varieties of Lolium perenne, L. multiflorum,Dactylis glomerata, and Festuca arundinacea from three climaticorigins grown in three different controlled environments (15?C, 72 W m^-2 visible irradiation, 16-h photoperiod; 25 ?C, 72W m^-2 visible irradiation, 16-h photoperiod; and 25 ?C, 180W m^-2 visible irradiation, 16-h photoperiod) and in the glasshousein July/August. The optimum temperature for photosynthesis was influenced primarilyby growth environment; growth at low temperature (15 ?C) resultedin a low optimum temperature, which differed little from varietyto variety. The maximum CO₂-exchange rate was influenced bygrowth environment and by variety. Within a variety, plantsgrown at higher light intensity or lower temperature had a greaterCO₂-exchange rate. Seven varieties showed a negative correlationbetween the optimum leaf temperature and the maximum CO₂-exchangerate. Activation energies for photosynthesis were influencedby growth environment only. There were marked varietal differences in the values of leafresistances (r_a + r_t) obtained from transpiration data at theoptimum leaf temperature for CO₂ exchange. In Lolium, and Dactylisthe Mediterranean varieties had higher leaf resistances thanthe Northern varieties with the maritime varieties intermediate.In general the Dactylis varieties had higher resistances thanthe corresponding Lolium and Festuca varieties. Only at highgrowth temperatures was (r_a+r_l) insensitive to temperature;otherwise an activation energy of about 10 kcal/mole was observed.A negative correlation was found between mean varietal diffusionresistances (r_a+r_l), and corresponding maximum CO₂-exchangerates.     

The Role of Phytochrome in Anthocyanin Synthesis in Seedlings of Vigna radiata (L.) Wilczek

Previously, it has been demonstrated that the red light-inducedanthocyanin accumulation in mung bean seedlings is mediatedby phytochrome [Dumortier and Vendrig Z. Pflanzenphysiol. 87:313 (1978)]. In this paper the importance of phytochrome forthe accumulation of anthocyanins in seedlings of mung beanswas studied in non-irradiated seedlings and in seedlings irradiatedwith 5 min R. A short FR-irradiation given early after sowing reduced theamount of anthocyanins which were normally found in non-irradiatedseedlings. This indicates that P_FR may be important for at leastpart of the anthocyanin synthesis in the dark. As for the redlight-mediated anthocyanin accumulation, irradiation appearedto be most effective when given to seedlings at the age of 36–48hr. Although the seedlings were sensitive to red light irradiationbefore that time, they were not able to synthesize anthocyaninsuntil they had reached the age of 36 hr. Complete escape ofred/far-red reversibility occurred only when far-red was given12 hr after red, although partial escape could be observed witha shorter time-interval. Furthermore, the time-course of anthocyaninaccumulation after a two-fold R-irradiation was compared withthe effect of a single R-exposure. From the results could beconcluded that the pattern of anthocyanin accumulation is dependenton the time during which P_FR is present in the seedlings. Theseexperiments also indicate that P_FR not only plays a role inthe synthesis of anthocyanins but probably also in their degradation. The results of our study show that phytochrome is importantfor anthocyanin accumulation in non-irradiated mung bean seedlingsas well as in R-irradiated, and that it probably is also involvedin the degradation of the pigment. (Received January 18, 1982; Accepted April 30, 1982)