Biosynthesis of Erythrina alkaloids in Erythrina crista-galli.

A precursor application system was developed to allow the study of Erythrina alkaloid formation in Erythrina crista-galli. Fruit wall tissue of this species was recognized as the major site of alkaloid biosynthesis. The application of radioactively and 13C-labelled potential precursors showed that the hitherto assumed precursor (S)-norprotosinomenine was not incorporated into the Erythrina alkaloids. In contrast, (S)-coclaurine as well as (S)-norreticuline were metabolized to erythraline and erythrinine, respectively, suggesting that a coclaurine-norreticuline pathway is operative in Erythrina alkaloid formation. Feeding of [1-13C]-labelled (S)-norreticuline with subsequent NMR spectroscopy demonstrated that the resulting erythraline was exclusively labelled at position C-10. Therefore, the participation of a symmetrical intermediate of the diphenoquinone type in Erythrina alkaloid biosynthesis can be excluded.     

Assessment of stress conditions in Quercus ilex L. leaves by O-J-I-P chlorophyll a fluorescence analysis

This reasearch, carried out within the MON.I.TO. programme (Intensive Monitoring of Forests in Tuscany, central Italy), was aimed at defining the stress conditions of two Quercus ilex woods at Colognole (CL) and Cala Violina (CV). In vivo chlorophyll fluorescence was measured for a whole year (1997 - 1998) using a portable 'continuous fluorescence' fluorimeter. The fluorescence parameters were calculated using the values at the steps 0-J-I-P of the polyphasic rising transient (this analysis is called JIP-test). Measurements were performed monthly, pre-dawn and midday. The findings revealed a condition of stress (drought and high temperatures) in the summer at CV during the central hours of the day, and a winter cold stress condition at CL observed in the pre-dawn measurements. At CV, summer stress was combined with processes of biologically regulated de-excitation; at CL, the winter stress appeared to be linked to structural damage affecting the photosynthetic apparatus. Results are discussed in relation to the existing literature on stress affecting Mediterranean vegetation, and to the findings reported in previous investigations in the same study areas.     

Analysis of temperature-jump chlorophyll fluorescence induction in plants.

A newly observed general chlorophyll fluorescence induction effect in plants is described. Fluorescence yield can rise through as many as four different phases (alpha, beta, gamma, ) in the dark, when intact cells or leaves are rapidly heated (within approx. 2.5 s) from 20 to 40-50 degrees C. An analysis of this temperature-jump fluorescence induction in Scenedesmus obliquus leads to the following: 1. Phase alpha is due to removal of S-quenching and appears to be related to heat deactivation of the water-splitting enzyme system. With prolonged heating, irreversibility of alpha upon recooling reflects irreversible damage to the water-splitting enzyme system. 2. beta is independent of the S-states and of the redox state of primary System II acceptor Q. It is suggested that beta parallels functional separation of Q from the System II trapping centre. This effect is highly reversible. 3. gamma and beta reflect reduction of primary System II acceptor Q by a heat-induced endogenous reductant, which is probably identical to hydrogenase. Critical temperatures for pronounced alpha and beta phases differ markedly in different plants. Possible correlations between temperature-jump fluorescence inductio, thylakoid membrane lipid composition, lipid phase transition and lipid-protein interactions are discussed.     

Leaf gas exchange characteristics and chlorophyll fluorescence of three wetland plants in response to long-term soil flooding

The effects of soil flooding on gas exchange and photosystem 2 (PS2) activity were analyzed in leaves of Phragmites australis, Carex cinerascens, and Hemarthria altissima. Pronounced decrease in net photosynthetic rate and stomatal conductance with flooding was found only in C. cinerascens. No significant changes in PS2 activity were observed in all three species which suggests that the photosynthetic apparatus was not damaged. Among the three species, H. altissima is better adapted to flooding than P. australis and C. cinerascens.     

Non-photochemical quenching of chlorophyll a fluorescence in isolated chloroplasts under conditions of stressed photosynthesis

Non-photochemical quenching of chlorophyll a fluorescence after short-time light, heat and osmotic stress was investigated with intact chloroplasts from Spinacia oleracea L. The proportions of non-photochemical fluorescence quenching (q _N ) which are related (q _E ) and unrelated (q _I ) to the transthylakoid proton gradient (pH) were determined. Light stress resulted in an increasing contribution of q _Ito total q _N.The linear dependence of q. _Eand pH, as seen in controls, was maintained. The mechanisms underlying this type of quenching are obviously unaffected by photoin-hibition. In constrast, q _Ewas severely affected by heat and osmotic stress. In low light, the response of q _Eto changes in pH was enhanced, whereas it was reduced in high light. The data are discussed with reference to the hypothesis that q _Eis related to thermal dissipation of excitation energy from photosystem II. It is shown that q _Eis not only controlled by pH, but also by external factors.Abbreviations and symbols 9-AA 9-aminoacridine - F _o basic chlorophyll fluorescence - F _o variable chlorophyll fluorescence - L ₂ saturating light pulse - PS photosystem - q _E pH-dependent, non-photochemical quenching of fluorescence - q _I pH-independent, non-photochemical quenching - q _N entire non-photochemical quenching - q _Q photochemical quenching     

Spatial-temporal variations in rose leaves under water stress conditions studied by chlorophyll fluorescence imaging.

Spatial-temporal changes were examined by imaging chlorophyll (Chl) a fluorescence in four leaf areas, two central and two external of rose plants (Rosa x hybrida) cv. Grand Gala for 9 days, under progressive water stress. New fluorescence parameters based on the lake model have recently been used to determine Q(A) redox state and excitation energy fluxes in order to gain a better understanding of the mechanisms that occur under drought stress. Chlorophyll fluorescence images showed a spatial variation in the leaves. The lower values for F(o), F(M), phi(2), q(P) and q(L) were found in the internal leaf area while higher values of non-photochemical quenching calculated from Stern-Volmer quenching (NPQ) and phi(NPQ). phi(Po) were more homogeneous throughout leaf. Temporal changes were also observed during the experiment, a 10% decrease in relative water content (RWC) (between day 1 and 2), led to a decrease in photochemical quenching and an increase in non-photochemical processes. Chlorophyll fluorescence parameters were more or less constant till day 8. At the end of the experiment (day 9), energy dissipation by downregulation, electron transport and Q(A) redox state, decreased and phi(NO) increased to compensate the change. Chlorophyll fluorescence parameters based on the lake model q(L), phi(NPQ) and phi(NO) have been found more appropriate for estimating the fraction of open centres, the quantum yield of regulated energy dissipation in photosystem II (PSII) and the quantum yield of non-regulated energy dissipation in PSII, respectively. The F(s)/F(o) ratio is strongly correlated with NPQ and phi(NPQ) up to a RWC of 20%. This coincides with a greater decrease in photochemical quenching and non-photochemical quenching and an increase in phi(NO).     

A sialylation-sensitive cell-based in vitro bioassay for erythropoietin; incorporation of the galactose-binding Erythrina crista-galli lectin.

The in vivo biological activity of erythropoietin (Epo) is dependent on its being adequately sialylated. Current in vitro bioassays for Epo do not correlate with the in vivo bioassays as the former do not take into account the role the liver plays in clearing desialylated glycoproteins from the circulation. Here we describe a sialylation-sensitive cell-based Epo bioassay. In the first instance, Epo activity in vitro was measured using proliferation of AS-E2 cells, and in vivo using the polycythaemic mouse bioassay. Activity in vivo was progressively abolished by controlled desialylation, whereas activity in vitro was essentially unaffected. Incorporation of an incubation step with a solid-phase galactose-binding lectin (Erythrina crista-galli), effectively mimicking passage through the liver in vivo, renders the in vitro bioassay sensitive to desialylation, such that Epo desialylated almost to completion had <10% of the activity of untreated Epo. These studies offer proof of principle, that rational manipulation of in vitro bioassays can allow prediction of activity in vivo without the use of live animals.     

Mechanisms of non-photochemical chlorophyll fluorescence quenching in higher plants

The excitation energy of pigment molecules in photosynthetic antennae systems is utilised by photochemistry, partly it is thermally dissipated, and partly it is emitted as fluorescence. Changes in the quantum yield of chlorophyll (Chl) fluorescence reflect the changes in quantum yield of photochemical reaction and thermal dissipation of the excitation energy. Decrease of the Chl fluorescence quantum yield is called the Chl fluorescence quenching. The decrease of the quantum yield that is accompanied by photochemical reactions has been termed the photochemical quenching, and the decrease accompanied by thermal dissipation of the excitation energy is called the non-photochemical quenching. This review deals with mechanisms of the non-photochemical quenching.     

Conventional and combinatorial chlorophyll fluorescence imaging of tobamovirus-infected plants

We compared by chlorophyll (Chl) fluorescence imaging the effects of two strains of the same virus (Italian and Spanish strains of the Pepper mild mottle virus — PMMoV-I and-S, respectively) in the host plant Nicotiana benthamiana. The infection was visualized either using conventional Chl fluorescence parameters or by an advanced statistical approach, yielding a combinatorial set of images that enhances the contrast between control and PMMoV-infected plants in the early infection steps. Among the conventional Chl fluorescence parameters, the non-photochemical quenching parameter NPQ was found to be an effective PMMoV infection reporter in asymptomatic leaves of N. benthamiana, detecting an intermediate infection phase. The combinatorial imaging revealed the infection earlier than any of the standard Chl fluorescence parameters, detecting the PMMoV-S infection as soon as 4 d post-inoculation (dpi), and PMMoV-I infection at 6 dpi; the delay correlates with the lower virulence of the last viral strain.     

Nitrogen application improves gas exchange characteristics and chlorophyll fluorescence in maize hybrids under salinity conditions

The understanding of crop physiological responses to salinity stress is of paramount importance for selection of genotypes with improved tolerance to this stress. Maize (Zea mays L.) hybrids Pioneer 32B33 and Dekalb 979 were grown in pots and subjected to three levels of salinity under four nitrogen levels to determine the role of nitrogen under saline conditions. Salinity stress effects on gas exchange characteristics and chlorophyll fluorescence of maize hybrids were evaluated under semi-controlled conditions. Under salinity stress, the changes in the net photosynthetic rate (P _N), stomatal conductance (g _s), and transpiration rate (E) were similarly directed: all decreased and were lower than in control at the higher salinity level (10 dS/m). Water use efficiency was increased with increasing salinity since transpiration was stronger depressed by salt than photosynthesis. Plants subjected to the lower level of salinity did not differ from control in tested characteristics. Nitrogen application ameliorated the effects of salinity.     

Mechanisms of non-photochemical chlorophyll fluorescence quenching in higher plants

The excitation energy of pigment molecules in photosynthetic antennae systems is utilised by photochemistry, partly it is thermally dissipated, and partly it is emitted as fluorescence. Changes in the quantum yield of chlorophyll (Chl) fluorescence reflect the changes in quantum yield of photochemical reaction and thermal dissipation of the excitation energy. Decrease of the Chl fluorescence quantum yield is called the Chl fluorescence quenching. The decrease of the quantum yield that is accompanied by photochemical reactions has been termed the photochemical quenching, and the decrease accompanied by thermal dissipation of the excitation energy is called the non-photochemical quenching. This review deals with mechanisms of the non-photochemical quenching.     

Dimethoate-induced slow S to M chlorophyll a fluorescence transient in wheat plants

In eukaryotic oxygenic photosynthetic organisms (both plants and algae), the maximum fluorescence is at peak P, with peak M lying much lower, or being even absent. Thus, the PSMT phase, where S is semisteady state, and T is terminal state, is replaced by a monotonous P→T fluorescence decay. In the present study, we found that dimethoate-treated wheat plant leaves showed SM transient, whereas in the case of control plants monotonous P→T fluorescence decay occured. We suggest that this was partly due to quenching of fluorescence due to [H⁺], responsible for P to S (T) decay in control plants (Briantais et al. 1979) being replaced by state transition (state 2 to state 1) in dimethoate-treated plants (Kaňa et al. 2012).     

Growth, photosynthesis and chlorophyll fluorescence of sweet pepper plants as affected by the cultivation method

Different methods of sweet pepper cultivation (organic, integrated and conventional farming) were evaluated under greenhouse conditions. Organic treatment was defined as only 4‐kg manure application at the preplanting stage. Conventional and integrated treatments consisted of application of the manure dosage plus chemical fertiliser at 100% and 50% of the local farmers’ amount, respectively, to avoid nutrient depletion. Plant growth parameters such as shoot dry matter, total leaf area and leaf weight fraction were all reduced in the organic treatment compared with the conventional. Leaf expansion was dramatically reduced in the organic treatment 155 days after transplanting. Relative growth rates were significantly affected by the nitrogen concentration in each organ and were directly related to the cultivation method. Chlorophylls (a + b) contents in the leaves were reduced in the organic treatment and were directly correlated with the nondestructive quantification of chlorophylls using a portable chlorophyll meter. Net photosynthesis was also reduced in the organic treatment, but chlorophyll fluorescence was not affected. This study shows that biometric monitoring and fast and non‐invasive techniques of plant nutrient status analysis could help to improve growth as easy and useful tools to follow the nutrient status at different phenological stages, especially when no chemical fertilisers are applied.     

Mapping QTLs for chlorophyll content and chlorophyll fluorescence in wheat under heat stress

Heat stress, one of the major abiotic stresses in wheat, affects chlorophyll fluorescence and chlorophyll content and thereby photosynthesis. To identify quantitative trait loci (QTLs) associated with these traits under terminal heat stress, 251 recombinant inbred lines (RILs) derived from a cross HD 2808/HUW510 were phenotyped. Using composite interval mapping, 40 QTLs were identified; 17 were related to conditions after timely sowing and 23 to heat stress after late sowing. The various parameters of chlorophyll fluorescence were associated with 23 QTLs, which were located on chromosomes 1A, 2A, 3A, and 2D and explained 3.67 to 18.04 % of phenotypic variation, whereas chlorophyll content was associated with 17 QTLs on chromosomes 2A, 2B, 2D, 5B, and 7A explaining 3.49 to 31.36 % of phenotypic variation. Most of the identified QTLs were clustered on chromosome 2D followed by 2A and 1A. The QTL Qchc.iiwbr-2A for chlorophyll content linked with marker gwm372 was stable over conditions and explained 3.81 to 18.05 % of phenotypic variation. In addition, 7 epistatic QTL pairs were also detected which explained 1.67 to 11.0 % of phenotypic variance. These identified genomic regions can be used in marker assisted breeding after validation for heat tolerance in wheat.     

Unequal distribution of DNA-containing organelles in generative and sperm cells of Erythrina crista-galli (Fabaceae)

The generative cell at anthesis in the mature pollen grain of Erythrina crista-galli (Fabaceae) was examined by 4,6-diamidino-2-phenylindole(DAPI)-fluorescence microscopy using the squash method. An unequal, polarized distribution of DNA-containing organelles (plastids and/or mitochondria) within the generative cell was observed in every mature pollen grain examined. Polarization of DNA-containing organelles is obvious when generative cells are freed and assume a spherical shape soon after microspore mitosis, as revealed by fluorescence-microscopic observations of specimens embedded in Technovit 7100 resin and thin-sectioned at different developmental stages. Early establishment of polarized localization of organelles in young generative cells of E. crista-galli and maintenance of this unequal distribution until pollen maturation strongly suggests that the organelles may still be clustered at pollen mitosis. Production of a dimorphic pair of sperm cells, as has been reported in Plumbago zeylanica, was observed in some pollen tubes germinated in vitro. The differentiation of the two sperm cells is discussed in relation to possible preferential double fertilization in angiosperms. Received: 28 July 1999 / Revision accepted: 8 November 1999     

Imaging chlorophyll a fluorescence reveals specific spatial distributions under different stress conditions

Chlorophyll a fluorescence has been adopted as a fast, non-invasive, and cheap method to detect stress effects in plants. The majority of these chl-fluorescence measurements have been carried out with ‘clamping’ fluorometers recording punctual chlorophyll a fluorescence at isolated parts of the leaf. However, this method is inherently limited in providing information on the homogeneity of responses to stresses at the leaf or whole plant level. Therefore the purpose of this study was to measure imaging chlorophyll a fluorescence and to compare the temporal and spatial distribution of this emission under allelochemical (2-3H-benzoxazolinone and 3,4-dihydroxybenzaldehyde), thermal and salt, and heavy metal (cadmium, copper and zinc) treatment in the model plant Arabidopsis thaliana (L.) Heynh. The results suggested different spatial distributions for each condition: the two allelochemicals showed inhibition spots at the edges of the oldest leaves and both did not affect the photosynthetic activity of young leaves; treatment with the three heavy metals revealed highly homogenous effects over the whole plant with a quite uniform decrease of maximum PSII efficiency (also in youngest leaves). On the contrary, temperature (heat and cold) and salt stress showed an initial decrease of fluorescence in the tissues around the vascular bundles that lasted between 2 and 3 h depending on the treatment. These irregularities in chlorophyll fluorescence make it difficult to correlate punctual measures (typical for clamping fluorometers) with the effect on the whole plant, ignoring effects that are evident when imaging is used. Therefore these results show that monitoring chlorophyll a fluorescence by imaging improves the measurement of stress effects on treated plants, suggesting that punctual fluorescence measurements do not always reveal the heterogeneity of the stress-related effects in treated plants.