Are there associations between grain-filling rate and photosynthesis in the flag leaves of field-grown rice?

Rate of grain filling in terms of dry mass accumulated per panicle per day was measured in field-grown rice in the dry season in the Philippines and compared to rates of light-saturated photosynthesis per unit leaf area (P(max)) measured at 350 micro l l(-1) CO(2) for 21 d after flowering. Five new plant type (tropical japonica) varieties (NPT) and one indica variety (IR72) were used and these gave some variation in rates and patterns of grain filling. A rapid grain-filling phase (RGFP) occurred approximately 10 d after flowering in most varieties. There was no consistent relationship in any variety between the rate of grain-filling and P(max) and chlorophyll content, both of which remained mostly unchanged throughout grain filling. Significant declines in the amount of total leaf protein and ribulose bisphosphate carboxylase-oxygenase (Rubisco) occurred, but these did not occur at the same time as the RGFP in all varieties. A decrease in the ratio of chlorophyll a/b preceded these changes and a transient rise in chlorophyll content was also observed in four varieties at this time. There was no significant change in leaf non-structural carbohydrate content during or following the RGFP. It is concluded that the decline in Rubisco and protein content in NPT was not reflected in photosynthetic activity. Hence in these field experiments Rubisco accumulated to a level in excess of photosynthetic requirements, serving as a store of nitrogen for grain filling.     

Are there physiological and biochemical adaptations of metabolism in deep-sea animals?

From the earliest observations of deep-sea animals, it was obvious that they differed in many ways from shallower-living relatives. Over the years, there has been speculation that deep-sea animals have unusually low rates of biological activity; numerous adaptive scenarios explaining this have ben offered. However, these speculations and scenarios have rarely been tested due to the difficulty of data collection and the inevitable confounding of a number of major variables which covary with depth. In recent years, study of the metabolic properties of animals of several phyla from widely differing deep-sea habitats, including the hydrthermal vents, has made it possible, using comparative approaches, to test hypotheses concerning the metabolic adaptations of deep-sea animals.     

Are there multiple circadian clocks in plants?

We have reported that Arabidopsis might have genetically distinct circadian oscillators in multiple cell-types.¹ Rhythms of CHLOROPHYLL A/B BINDING PROTEIN2 (CAB2) promoter activity are 2.5 h longer in phytochromeB mutants in constant red light and in cryptocrome1 cry2 double mutant (hy4-1 fha-1) in constant blue light than the wild-type.² However, we found that cytosolic free Ca²⁺ ([Ca²⁺]_cyt) oscillations were undetectable in these mutants in the same light conditions.¹ Furthermore, mutants of CIRCADIAN CLOCK ASSOCIATED1 (CCA1) have short period rhythms of leaf movement but have arrhythmic [Ca²⁺]_cyt oscillations. More important, the timing of cab1-1 (toc1-1) mutant has short period rhythms of CAB2 promoter activity (∼21 h) but, surprisingly, has a wild-type period for circadian [Ca²⁺]_cyt oscillations (∼24 h). In contrast, toc1-2, a TOC1 loss-of-function mutant, has a short period of both CAB2 and [Ca²⁺]_cyt rhythms (∼21 h). Here we discuss the difference between the phenotypes of toc1-1 and toc1-2 and how rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations might be regulated differently.Key words: circadian rhythms, TOC1, multiple oscillators, CAB2, Ca²⁺ signalling, arabidopsis, circadian [Ca²⁺]_cyt oscillations, aequorin, luciferase, central oscillatorThe plant circadian clock controls a multitude of physiological processes such as photosynthesis, organ and stomatal movements and transition to reproductive growth. A plant clock that is correctly matched to the rhythms in the environment brings about a photosynthetic advantage that results in more chlorophyll, more carbon assimilation and faster growth.³ One of the first circadian clock mutants to be described in plants was the short period timing of cab1-1 (toc1-1), which was identified using the rhythms of luciferase under a CHLOROPHYLL A/B BINDING PROTEIN2 (CAB2) promoter as a marker for circadian period.⁴Circadian rhythms of both CAB2 promoter activity and cytosolic-free Ca²⁺ ([Ca²⁺]_cyt) oscillations depend on the function of a TOC1, CIRCADIAN CLOCK ASSOCIATED1 and LATE ELONGATED HYPOCOTYL (TOC1/CCA1/LHY) negative feedback loop.⁵ In tobacco seedlings, CAB2:luciferase (CAB2:luc) rhythms and circadian [Ca²⁺]_cyt oscillations can be uncoupled in undifferentiated calli.⁶ In Arabidopsis, we reported that toc1-1 has different periods of rhythms of CAB2 promoter activity (∼21 h) and circadian [Ca²⁺]_cyt oscillations (∼24 h). The mutant allele toc1-1 has a base pair change that leads to a full protein that has an amino acid change from Ala to Val in the CCT domain (CONSTANS, CONSTANS-LIKE and TOC1).⁷ On the other hand, the mutant toc1-2 has short period of both rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations (∼21 h).^1,7 This allele has a base pair change that results in changes to preferential mRNA splicing, resulting in a truncated protein with only 59 residues.⁷ Thus, the mutated CCT domain in toc1-1 might lead to the uncoupling of rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations while the absence of TOC1 in toc1-2 causes the shortening of the period of both rhythms. Indeed, zeitlupe-1 (ztl-1) mutants, that have higher levels of TOC1, have long periods of both rhythms of CAB2 promoter activity and circadian [Ca²⁺]_cyt oscillations.¹ The biochemical function of the CCT domain is unknown but it is predicted to play an important role in protein-protein interactions⁸ and nuclear localization.⁹One model to explain the period difference of CAB2:luc expression and circadian [Ca²⁺]_cyt oscillation is that the toc1-1 mutation has uncoupled two oscillators in the same cell. Uncoupled oscillators are a predicted outcome of certain mutations in the recently described three-loop mathematical model.^10–11 However, both rhythms of TOC1 and CCA1/LHY expression, which would be in uncoupled oscillators accordingly to the model, are described as short-period in toc1-1.⁵ Thus, we have favored the model in which CAB2:luc expression and circadian [Ca²⁺]_cyt oscillation are reporting cell-types with different oscillators that are affected differently by toc1-1.It is possible that TOC1 could interact with a family of cell-type specific proteins. The interaction of TOC1 with each member of the family could be affected differently by the mutation in the CCT domain (Fig. 1). Two-hybrid assays have shown that TOC1 interacts with PIF proteins (PHYTOCHROME INTERACTING FACTOR3 and PIF4) and related PIL proteins (PIF3-LIKE PROTEIN 1, PIL2, PIL5 and PIL6).⁸ In fact, TOC1 interaction with both PIF3 and PIL1 is stronger when the N-terminus receiver domain is taken out and the CCT domain is left intact.⁸ Thus, it is possible that TOC1 and different PIF/PIL proteins interact to regulate the central oscillator. This interaction could be impaired by the Ala to Val change in the toc1-1 mutation, leading to the period shortening. However, lines misexpressing PIF3, PIL1 and PIL6 showed no changes in their circadian rhythms.^12–16Open in a separate windowFigure 1Models of how the toc1-1 mutation might differently affect cell-type specific circadian oscillators. The single mutant toc1-1 have 21 h rhythms of CAB2 promoter activity and 24 h-rhythms of [Ca²⁺]_cyt oscillations. The toc1-1 mutation is a single amino acid change in the CCT domain. The CCT domain is involved in protein-protein interaction and/or nuclear localization. We have proposed that circadian oscillators with different periods are present in different cell-types. The luminescence generated by CAB2 promoter-drived luciferase (from the CAB2:luc) is probably originated in the epidermis and mesophyll cells. In this model, we propose that the mutation on the CCT domain impairs the mutated TOC1 interaction with the hypothetical protein Z in these cells-types. In contrast, in other cell-types, the mutated TOC1 still interacts with other hypothetical proteins (W), despite the mutation in the CCT domain. In those cell-types, the circadian oscillator could still run with a 24 h period for [Ca²⁺]_cyt rhythms (from the 35S:AEQ construct). One possible identity for Z and W are the members of the PHYTOCHROME INTERACTING FACTOR (PIF) related PIF3-LIKE (PIL) family.One possible explanation for the absence of alterations in the period of circadian rhythms in lines misexpressing PIF/PIL is that they only have roles in certain cell-types. As an example, PIL6 and PIF3 are involved with flowering time and hypocotyl growth in red light^12–15 while PIL1 and PIL2 are involved with hypocotyl elongation in shade-avoidance responses.¹⁶ Both hypocotyl growth and flowering time require cell-type specific regulation: vascular bundle cells in the case of the flowering time¹⁷ and the cells in the shoot in the case of the hypocotyl elongation.¹⁶ If TOC1 interaction with certain PIF/PIL is indeed cell-type specific, the mutated CCT domain found in the toc1-1 mutant could affect the clock in different ways, depending on the type of PIF/PIL protein expressed in each cell-type. Therefore, a question that arises is: which cell-types are sensitive to the toc1-1 mutation?There is evidence that CAB2 and CATALASE3 (CAT3) are regulated by two oscillators that respond differently to temperature signals.¹⁸ These genes might be regulated by two distinct circadian oscillators within the same tissues or a single cell.¹⁸ Interestingly, the spatial patterns of expression of CAB2 and CATALASE3 overlap in the mesophyll of the cotyledons.¹⁸ Furthermore, rhythms of CAB2 and CHALCONE SYNTHASE (CHS) promoter activity have different periods and they are equally affected by toc1-1 mutation.¹⁹ Whereas CAB2 is mainly expressed in the mesophyll cells, CHS is mainly expressed in epidermis and root cells.¹⁹ However, rhythms of AEQUORIN luminescence, which reports [Ca²⁺]_cyt oscillation, were insensitive to toc1-1 mutation and appear to come from the whole cotyledon.²⁰ One cell-type which is found in the whole cotyledon but is distinct from either mesophyll or epidermis cells is the vascular tissue and associated cells.Another approach to determine which cell-types are insensitive to toc1-1 mutation is to compare the toc1-1 and toc1-2 phenotypes. The period of circadian [Ca²⁺]_cyt oscillations is not the only phenotype that is different in toc1-1 and toc1-2 mutants. Rhythms in CAB2 promoter activity in constant red light are short period in toc1-1 but arrhythmic in toc1-2.^21,22 COLD, CIRCADIAN RHYTHM AND RNA BINDING 2/GLYCINE-RICH RNA BINDING PROTEIN 7 (CCR2/GRP7) is also arrhythmic in toc1-2 but short period in toc1-1 in constant darkness.^7,22 When the length of the hypocotyl was measured for both toc1-1 and toc1-2 plants exposed to various intensities of red light, only toc1-2 had a clear reduction in sensitivity to red light. Therefore, toc1-2 has long hypocotyl when maintained in constant red light while hypocotyl length in toc1-1 is nearly identical to that in the wild-type.²² These differences may allow us to separate which cell-types are sensitive to the toc1-1 mutation and which not.Hypocotyl growth is regulated by a large number of factors such as light, gravity, auxin, cytokinins, ethylene, gibberellins and brassinosteroids.²³ There is also a correlation between the size of the hypocotyl in red light and defects in the circadian signaling network.^24,25 The fact that toc1-1 has different hypocotyl sizes from toc1-2 suggests that circadian [Ca²⁺]_cyt oscillations could be involved in the light-dependent control of hypocotyl growth. Circadian [Ca²⁺]_cyt oscillations might encode temporal information to control cell expansion and hypocotyl growth.^26–28 toc1-1 have short-period rhythms of hypocotyl elongation, which indicates that the cells in the hypocotyl have a 21 h oscillator.²⁹ However, toc1-1 might also have a wild-type hypocotyl length in continuous red light because cells which generate the signal to regulate hypocotyl growth might have 24 h oscillators.The toc1-1 mutation was the first to be directly associated with the plant circadian clock, revitalizing the field of study.⁴ Now, by either uncoupling two feedback loops or by distinct TOC1 protein-protein interaction in different cell-types, toc1-1 has shown new properties of the circadian clock that may deepen our understanding of this system.     

Are there different velocity types of action potentials in higher plants?

The problem of paradoxically varying propagation velocities of action potentials in the conduction pathways of higher plants is considered. Possible reasons underlying this phenomenon are discussed.     

Origin of sucrose metabolism in higher plants: when,how and why?

Since the discovery of sucrose biosynthesis, considerable advances have been made in understanding its regulation and crucial role in the functional biology of plants. However, important aspects of this metabolism are still an enigma. Studies in cyanobacteria and the publication of the sequences of several complete genomes have recently significantly increased our knowledge of the structures of proteins involved in sucrose metabolism and given us new insights into their origin and further evolution.     

Does proline accumulated in leaves of water deficit stressed barley plants confine cell membrane injury? I. Free proline accumulation and membrane injury index in drought and osmotically stressed plants

The aim of this work was to examine the relationship between proline accumulation and membrane injury in barley leaves suffering from the effects of water deficit. Water deficit stress was induced by water withholding or by immersing the roots in polyethylene glycol (PEG 6000) solution of osmotic potential −1.5 MPa. The effect of water stress on proline accumulation and on membrane injury was evaluated in leaf blades of several barley genotypes. Substantial differences in proline accumulation and membrane injury indices among most of the genotypes investigated were observed. It was found that in drought stressed plants a higher ability to accumulate proline positively correlates with lower membrane injury. Whereas, in osmotically stressed plants the highest proline accumulation in the leaves was noticed in genotype with the largest membrane injury. The possible role of proline in membrane protection under conditions of slow-acting drought or shock-acting osmotic stress is discussed.     

Are there differences in immune function between continental and insular birds?

Generally, immune system architecture varies with different environments, which presumably reflect different pathogen pressures. Specifically, populations from relatively disease-free, oceanic islands are expected to exhibit reorganized immune systems, which might be characterized by attenuated responses, given the costs of immune function. Some insular animals exhibit an 'island syndrome,' including increased susceptibility to disease, and some insular populations have declined when they failed to resist infection by introduced pathogens. I measured eight indices of immune function (haemolysis, haemagglutination, concentration of haptoglobin and concentration of five leukocyte types) in 15 phylogenetically matched pairs of bird populations from North America and from the islands of Hawaii, Bermuda and the Galápagos. Immune responses were not attenuated in insular birds, and several indices, including the concentration of plasma haptoglobin, were elevated. Thus, I find no support for the specific hypothesis that depauperate parasite communities and the costs of immune defences select for reduced immune function. Instead, I suggest that life on islands leads to an apparent reorganization of immune function, which is defined by increases in defences that are innate and inducible. These increases might signal that systems of acquired humoral immunity and immunological memory are less important or dysfunctional in island populations.     

Are there symplastic connections between the endosperm and embryo in some angiosperms?—a lesson from the Crassulaceae family

It is believed that there is symplastic isolation between the embryo (new sporophyte) and the endosperm (maternal-parental origin tissue, which nourishes the embryo) in angiosperms. However, in embryological literature there are rare examples in which plasmodesmata between the embryo suspensor and endosperm cells have been recorded (three species from Fabaceae). This study was undertaken in order to test the hypothesis that plasmodesmata between the embryo suspensor and the endosperm are not so rare but also occur in other angiosperm families; in order to check this, we used the Crassulaceae family because embryogenesis in Crassulaceae has been studied extensively at an ultrastructure level recently and also we tread members of this family as model for suspensor physiology and function studies. These plasmodesmata even occurred between the basal cell of the two-celled proembryo and endosperm cells. The plasmodesmata were simple at this stage of development. During the development of the embryo proper and the suspensor, the structure of plasmodesmata changes. They were branched and connected with electron-dense material. Our results suggest that in Crassulaceae with plasmodesmata between the endosperm and suspensor, symplastic connectivity at this cell-cell boundary is still reduced or blocked at a very early stage of embryo development (before the globular stage). The occurrence of plasmodesmata between the embryo suspensor and endosperm cells suggests possible symplastic transport between these different organs, at least at a very early stage of embryo development. However, whether this transport actually occurs needs to be proven experimentally. A broader analysis of plants from various families would show whether the occurrence of plasmodesmata between the embryo suspensor and the endosperm are typical embryological characteristics and if this is useful in discussions about angiosperm systematic and evolution.     

Are there differences between proseriates and lower flatworms in ultrastructure of the nervous system?

The ultrastructure of the CNS (central nervous system) in three species of the Proseriata — Archiloa unipunctata (O. Fabricius), Bothriomolus balticus (Meixner), and Promonotus schultzei (Meixner) — was studied and compared to that of the lower flatworms Stenostomum leucops (Catenulida) and Microstomum lineare (Macrostomida) in material available from our previous studies. Conventional electron microscopical fixation was used for A. unipunctata and B. balticus; the tannic-acid-incubation method (TARI), a method that reveals especially nonsynaptic exocytotic release of neuronal substances, was applied in study of P. schultzei.In general, the ultrastructural features of neurons and nerve fibers were similar in proseriates and lower flatworms. A striking feature common to both groups was the secretory appearance of all neurons. A significant difference between them is the occurrence, in the proseriates, of wrapping of neurons by glial cells. Heterogeneity in the population of neuronal vesicles and in structure of synapses in the proseriates are probably advanced characters; by contrast, S. leucops has relatively homogeneous vesicles and simple synapses. A gradual advancement from the state in the catenulids through that in the macrostomids to the proseriates seems to be reflected in the differentiation of synapses and the variability of neuronal vesicles. This probably reflects differences in functional demands but also evolutionary advancement.     

Is there a preferential interaction between cholesterol and tryptophan residues in membrane proteins?

Recently, several indications have been found that suggest a preferential interaction between cholesterol and tryptophan residues located near the membrane-water interface. The aim of this study was to investigate by direct methods how tryptophan and cholesterol interact with each other and what the possible consequences are for membrane organization. For this purpose, we used cholesterol-containing model membranes of dimyristoylphosphatidylcholine (DMPC) in which a transmembrane model peptide with flanking tryptophans [acetyl-GWW(LA)8LWWA-amide], called WALP23, was incorporated to mimic interfacial tryptophans of membrane proteins. These model systems were studied with two complementary methods. (1) Steady-state and time-resolved F?rster resonance energy transfer (FRET) experiments employing the fluorescent cholesterol analogue dehydroergosterol (DHE) in combination with a competition experiment with cholesterol were used to obtain information about the distribution of cholesterol in the bilayer in the presence of WALP23. The results were consistent with a random distribution of cholesterol which indicates that cholesterol and interfacial tryptophans are not preferentially located next to each other in these bilayer systems. (2) Solid-state 2H NMR experiments employing either deuterated cholesterol or indole ring-deuterated WALP23 peptides were performed to study the orientation and dynamics of both molecules. The results showed that the quadrupolar splittings of labeled cholesterol were not affected by an interaction with tryptophan-flanked peptides and, vice versa, that the quadrupolar splittings of labeled indole rings in WALP23 are not significantly influenced by addition of cholesterol to the bilayer. Therefore, both NMR and fluorescence spectroscopy results independently show that, at least in the model systems studied here, there is no evidence for a preferential interaction between cholesterol and tryptophans located at the bilayer interface.     

Are there trade-offs between pre- and post-fledging survival in black brent geese?

1.?The growth period is an important determinant of fitness later in life through its effects on first-year survival and future reproduction. Choices by adult females about where to rear their offspring strongly affect growth rates and offspring fitness in geese. 2.?Individual female black brent (Branta bernicla nigricans) tend to raise their broods in the same areas each year, and these areas are consistently ranked with respect to growth rates of goslings. Therefore, some females consistently rear their broods on areas resulting in lower post-fledging fitness. 3.?We explore the potential that growth rates of offspring (and associated fitness consequences) are traded off against other vital rates influencing fitness of either adult females or goslings. Growth of goslings primarily influences fitness after fledging, so one hypothesis is that survival before fledging, which is influenced by predation, is traded off against growth rates and post-fledging survival. 4.?We estimated pre-fledging and post-fledging survival for goslings reared on areas used by broods from the Tutakoke River black brent colony. We examined recaptures, recoveries by hunters and resightings of brent marked as goslings with webtags and standard leg rings. These data were analyzed using capture-mark-recapture models in program mark to derive separate estimates of pre- and post-fledging survival for 18 cohorts (1987-2004) of black brent goslings across seven brood rearing areas (BRAs). 5.?Estimates of pre-fledging survival probability varied from 0·00?±?0·00 (mean?±?95% confidence interval) to 0·92?±?0·1; and estimates of post-fledging survival probability varied from 0·00?±?0·00 to 1·00?±?0·08. Substantial variation existed both among BRAs and years but post-fledging survival declined substantially during the study. 6.?Pre- and post-fledging survival were positively correlated, exhibiting a quadratic relationship (?(post-fledging survival) =?1·00 (±0·47)x-0·83 (±0·480)x(2) , where x?=?pre-fledging survival). Therefore, we did not find a trade-off between pre- and post-fledging survival in black brent goslings across BRAs, suggesting that factors other than foraging conditions and predation on goslings must influence selection of BRAs.     

Do leaves contribute to the abscisic acid present in the xylem sap of ‘draughted’ sunflower plants?

Abstract. The root systems of 30-d-old sunflower plants were treated with polyethylene glycol (PEG; osmotic potential - 1.0MPa) for 2h, causing mild and transient wilting. Ten minutes before this treatment was applied, half the plants were defoliated. At varying times after the imposition of the PEG 'drought stimulus', the plant stems were cut and the sap exudate was collected and analysed for abscisic acid (ABA), using an elisa method. When stems were cut 2.25h after the treatments were applied, the ABA concentration in the sap of the controls did not vary with time: the mean concentration was 10.7 ± 1.0μ, mol m⁻³. However, in the treated plants, the first sample contained 78.1 ± 10.1 μmol m⁻³, decreasing to 13.6 ± 2.8 μmol m⁻³ over 8.75h. Defoliation did not affect the ABA concentration in the sap. When stems were cut at varying times (up to 25h) after treatment, the PEG treatment again caused an immediate increase in the ABA concentration in the sap, from 20 ± 1 to 136 ± 21 μmol m⁻³. However, defoliation reduced this increase, but only in plants sampled 4–25h after treatment. We conclude that, after the PEG treatment to the roots, the initial increase of the ABA content of sap, and its attenuation with time, may be ascribed to synthesis in the roots whereas, thereafter, ABA derived from the leaves makes a major contribution to the ABA found in the xylem sap.     

Is trehalose-6-phosphate a regulator of sugar metabolism in plants?

It has recently emerged that many higher plants can synthesize trace amounts of trehalose. In arabidopsis disruption of the first step of trehalose synthesis, catalysed by trehalose-6-phosphate synthase (TPS), has lethal consequences, demonstrating an important physiological role. It is not yet clear what the precise function of trehalose synthesis is, but there is mounting evidence that trehalose-6-phosphate is implicated in the regulation of sugar metabolism. Further work is necessary to confirm this hypothesis and determine the underlying mechanism.     

Are polyamines involved in the induction and regulation of the Crassulacean acid metabolism?

Leaves of plants with Crassulacean acid metabolism (CAM) were analyzed for variation in the content of polyamines in connection with the metabolism of malic acid in the dark and in the light, and with the induction of full-CAM activity. Under conditions (long days) resulting in extremely low CAM activity, young leaves of K. blossfeldiana have very low content in the polyamine-precursor arginine and in putrescine. The content in these two substances was increased dramatically by full-CAM induction with short days. During the course of the night/day cycle two peaks of putrescine content were observed in leaves of Kalanchoe blossfeldiana Poelln. Tom Thumb performing full-CAM operation: a large increase occurs toward the end of the day and the first half of the night, and its kinetics corresponds to the increase in the rate of malic acid synthesis; another peak, very sharp, appears during the first hours of the day, concomitant with the time of release of malic acid from the vacuole into the cytoplasm. In the case of Bryophyllum daigremontianum Berger similar variations were observed for the content in spermidine. These results support the hypothesis that polyamines could be involved in countering the tendency toward acidification of the cytoplasm at those moments of CAM operation at which the local concentration of malic acid is increased (i.e., during active synthesis in the dark and during the efflux from the vacuole in the light).Abbreviation CAM Crassulacean acid metabolism     

Are contents of Rubisco, soluble protein and nitrogen in flag leaves of rice controlled by the same genetics?

Genetic relations among the contents of Rubisco, soluble protein and total leaf nitrogen (N) in leaves of rice (Oryza sativa L.) were studied by quantitative trait loci (QTL) analysis with a population of backcross inbred lines (BILs) of japonica Nipponbarexindica Kasalath. The ratio of Rubisco to total leaf N in leaves is the main target in improving photosynthetic N-use efficiency in plants. QTLs controlling Rubisco content were not detected near QTLs for total leaf N content. These results indicate that contents of Rubisco and total leaf N are controlled by different genetics. QTLs that controlled the ratio of Rubisco to total leaf N (CORNs) were detected. These results suggest that some mechanism(s) may be involved in determining this ratio, while the contents of Rubisco and total leaf N are controlled in other ways. In elite BILs, the ratios of Rubisco to total leaf N were higher than those of both parents. These results suggest a good possibility of improving N-use efficiency by CORNs in cultivated rice. A QTL controlling Rubisco content was mapped near a QTL for soluble protein content on chromosome 8 at 5 d after heading and on chromosome 9 at 25 d. In each chromosome region, the peaks of both QTLs overlapped accurately, giving a high possibility of pleiotropic effects by the same genes. Different QTLs controlling soluble protein or Rubisco were detected from those detected at 5 d or 25 d after heading. This suggests that these traits are genetically controlled depending on the growth stages of leaves.     

Are sucrosyl-oligosaccharides synthesized in mesophyll protoplasts of mature leaves of Cucumis melo?

Biosynthesis of sucrosyl-oligosaccharides (raffinose, stachyose) was traced in source leaves of Cucumis melo after ¹⁴C-photoassimilation. The main carbon compound exported was ¹⁴C-labeled stachyose. No oligosaccharide synthesis was detected in young, importing leaves. Mesophyll protoplasts, isolated from mature leaves which had previously photosynthesized ¹⁴CO₂, did not contain ¹⁴C-oligosaccharides but contained [¹⁴C]-sucrose and ¹⁴C-hexoses. Isolated minor-vein-enriched fractions from the same leaves, however, showed nearly 30% of the ¹⁴C of the neutral fraction to be in oligosaccharides. Isolated, viable mesophyll protoplasts incubated with NaH¹⁴CO₃ also failed to incorporate radioactivity into oligosaccharides, although sucrose and galactinol synthesis was unimpaired. Galactinolsynthase activity in leaf extracts and in mesophyll protoplasts was 16.8 mol·h^-1·mg^-1 protein and 13.8 mol·h^-1·mg^-1 protein, respectively. Galactosyltransferase (EC 2.4.1.67), which synthesizes stachyose from raffinose and galactinol, had an activity of 50 nmol·h^-1·mg^-1 protein in leaf extracts and was also present in the minor-vein-enriched fraction, but could not be detected in mesophyll protoplast lysates. The results indicate that mesophyll cells may not be the site of stachyose synthesis although precursor compounds like sucrose and galactinol are synthesized there.Abbreviation HPLC high-performance liquid chromatography     

Ascorbate and glutathione metabolism in two sunflower cell lines of differing α-tocopherol biosynthetic capability

The natural antioxidants, tocopherols and ascorbate (ASC), are of great interest in terms of human health, because of their role in the prevention of chronic diseases. In cell metabolism, tocopherols are the major lipid-soluble antioxidants, whereas ASC and glutathione (GSH) are hydro-soluble antioxidants. These three metabolites cooperate in scavenging for oxygen radicals and protecting cell membranes. ASC and GSH are required in the process of regeneration of tocopherol from its α-cromanoxyl radical, while, GSH donates electrons for the reduction of dehydroascorbate (DHA), the fully oxidised form of ASC. Two cell lines of sunflower (Helianthus annuus L. cv Gloriasol) with differing capability to synthesise α-tocopherol were identified. In spite of the differing content of α-tocopherol (almost threefold higher in the high synthesising cell line, HT, than in the low synthesising one, LT), the cell lines have comparable growth curves. In the cells collected in the stationary phase, the ASC and GSH pools are also significantly higher in the HT cells than in the LT cells. On the other hand, the enzymes responsible for H₂O₂ scavenging and ASC and GSH recycling had higher activity in the LT than in the HT cells. The cooperation between the three antioxidant systems in the maintenance of the cellular redox balance is discussed, as well as the possible utilisation of the HT cell line for the in vitro production of natural antioxidants.