Dynamics of light and nitrogen distribution during grain filling within wheat canopy

In monocarpic species, during the reproductive stage the growing grains represent a strong sink for nitrogen (N) and trigger N remobilization from the vegetative organs, which decreases canopy photosynthesis and accelerates leaf senescence. The spatiotemporal distribution of N in a reproductive canopy has not been described in detail. Here, we investigated the role of the local light environment on the spatiotemporal distribution of leaf lamina N mass per unit leaf area (SLN) during grain filling of field-grown wheat (Triticum aestivum). In addition, in order to provide some insight into the coordination of N depletion between the different vegetative organs, N dynamics were studied for individual leaf laminae, leaf sheaths, internodes, and chaff of the top fertile culms. At the canopy scale, SLN distribution paralleled the light gradient below the flag leaf collar until almost the end of grain filling. On the contrary, the significant light gradient along the flag leaf lamina was not associated with a SLN gradient. Within the top fertile culms, the time course of total (alive + necrotic tissues) N concentration of the different laminae and sheaths displayed a similar pattern. Another common pattern was observed for internodes and chaff. During the period of no root N uptake, N depletion of individual laminae and sheaths followed a first-order kinetics independent of leaf age, genotype, or N nutrition. The results presented here show that during grain filling, N dynamics are integrated at the culm scale and strongly depend on the local light conditions determined by the canopy structure.     

Functional gamma-secretase inhibitors reduce beta-amyloid peptide levels in brain

To elucidate a role for the cytoskeletal protein actin in post-traumatic apoptotic cell death, the ability of actin-containing tissue extracts to inhibit exogenous DNase I was evaluated. In addition, cortical, hippocampal and thalamic extracts were examined for caspase-mediated actin cleavage and changes in actin polymerization state. Rats were anesthetized, subjected to lateral fluid percussion brain injury of moderate severity, and euthanized at 1 h, 6 h, 24 h, 1 week or 3 weeks post-injury (n = 3 per time-point). Tissue extracts from all brain regions of sham (uninjured) animals inhibited exogenous DNase I activity to a significant extent. However, inhibition of DNase I was significantly reduced at 1 h and 6 h in the injured hippocampus, and at 1 h, 6 h and 3 weeks in the thalamus. DNase I in cortical extracts of all injured animals was inhibited to a similar extent as that in uninjured animals. Actin fragments consistent with caspase-mediated proteolysis were observed in immunoblots of the injured hippocampus and thalamus at 1 h and 24 h, respectively, and were present up to 3 weeks post-injury. Transient actin hyperpolymerization was observed at 1 and 6 h post-injury in the thalamus and hippocampus, while actin depolymerization was observed at 1 and 3 weeks in the cortex and thalamus. Collectively our data suggest that DNase I disinhibition following brain trauma is associated predominantly with actin hyperpolymerization but also with actin depolymerization and concomitant caspase-mediated actin proteolysis.     

Comparative analysis of translation efficiencies of hepatitis C virus 5' untranslated regions among intraindividual quasispecies present in chronic infection: opposite behaviors depending on cell type

Hepatitis C virus (HCV) RNA translation initiation is dependent on the presence of an internal ribosome entry site (IRES) that is found mostly in its 5' untranslated region (5' UTR). While exhibiting the most highly conserved sequence within the genome, the 5' UTR accumulates small differences, which may be of biological and clinical importance. In this study, using a bicistronic dual luciferase expression system, we have examined the sequence of 5' UTRs from quasispecies characterized in the serum of a patient chronically infected with HCV genotype 1a and its corresponding translational activity. Sequence heterogeneity between IRES elements led to important changes in their translation efficiency both in vitro and in different cell cultures lines, implying that interactions of RNA with related transacting factors may vary according to cell type. These data suggest that variants occasionally carried by the serum prior to reinfection could be selected toward different compartments of the same infected organism, thus favoring the hypothesis of HCV multiple tropism.     

Focal adhesion kinase regulation by oxidative stress in different cell types

Focal adhesion kinase (FAK) is a tyrosine kinase ubiquitously expressed in cells. It was initially shown to be the initiator of focal adhesion formation in adherent cells, after its binding to integrins which induce its autophosphorylation. However, it can be also activated by a great variety of other stimuli able to act on different intracellular signaling. Reactive oxygen species (ROS), which have been shown to act as external or internal cell stimuli, induce tyrosine phosphorylation of FAK. Its autophosphorylation is followed by a submembranous localization which is crucial for many of the biological roles of FAK, including cell spreading, cell migration, cell proliferation, and prevention of apoptosis. It plays an important role in development of tumor cells, its regulation could be thus a way of impairing cell proliferation in cancer. We describe in this review the structure, activity, and functions of FAK in different cells and how ROS are able, like other stimuli, to induce its phosphorylation and modification of cell morphology and structure. The link between ROS and FAK activation could explain the role of ROS in mediating cell proliferation, cell migration, or apoptosis.     

Simulating the effects of localized red:far-red ratio on tillering in spring wheat (Triticum aestivum) using a three-dimensional virtual plant model

The outgrowth of tiller buds in Poaceae is influenced by the ratio of red to far-red light irradiance (R:FR). At each point in the plant canopy, R:FR is affected by light scattered by surrounding plant tissues. This paper presents a three-dimensional virtual plant modelling approach to simulate local effects of R:FR on tillering in spring wheat (Triticum aestivum). R:FR dependence of bud outgrowth was implemented in a wheat model, using three hypothetical responses of bud extension to R:FR (unit step, curvilinear and linear response). Bud break occurred when a threshold bud length was reached. Simulations were performed for three plant population densities. In accordance with experimental observations, fewer tillers per plant were simulated for higher plant population densities. The linear and curvilinear responses caused a delay in the increase in tiller number compared with experimental data. The unit step response approached experimental results best. It is suggested that a model based on relatively simple relations can be used to simulate degree of tillering. This study has shown that the virtual plant approach is a promising tool with which to address crop morphological and ecological research questions where the determining factors act at the level of the individual plant organ.     

The interplay of pollination,costs of reproduction and plant size in maternal fertility limitation in perennial <Emphasis Type="Italic">Paeonia officinalis</Emphasis>

Although several factors can limit female fertility in perennial plants, rarely have they been jointly studied in a single species over several years. In this study we experimentally manipulate seed production and simultaneously analyse the potential contribution of pollen limitation, costs of reproduction and plant size to variation in seed output over a 3-year period in the perennial herb Paeonia officinalis, in southern France. Since this rare species is threatened by forest closure in many sites we also examine the causes of female fertility variation in relation to habitat closure (open habitat vs. woodland). P. officinalis has a partial self-incompatibility system and only very low ability for autonomous self pollination in the absence of pollinators. However, supplementary pollination of individual plants in three consecutive years did not significantly increase seed production above natural levels. Forest closure was associated with a decline in ovule and seed production, which again was not due to pollen limitation since supplementary pollination had no significant effect on seed set in the woodland habitat. Comparison of the maternal fertility of plants which were previously excluded from reproduction with those which were hand pollinated to maximise seed set in two previous years produced no evidence that seed production in year three is limited by costs associated with prior reproduction. Likewise, flowering probability was not related to prior seed production but was however positively related to plant size. The absence of any influence of pollen limitation or prior reproduction on seed production suggests that sub-maximal seed production in long-lived perennial herbs may be part of a size-dependent strategy that maximises life-time seed production and fitness without compromising survival.     

Effect of hexokinase activity on tomato root metabolism during prolonged hypoxia

Hypoxically induced tolerance to anoxia in roots of tomato (Solanum lycopersicum) was previously shown to depend on sucrose and the induction of sucrose synthase. In contrast to maize, root hexokinase (HXK) activities did not increase during hypoxia and glucose was unable to sustain glycolytic flux under anoxia. In this paper, we asked whether hypoxic metabolism in roots would be altered in transgenic tomato plants overexpressing either a plant (Arabidopsis) or a yeast (Saccharomyces cerevisiae) HXK and whether such modifications could be related to improved energy metabolism and consequently root tolerance under anoxia. Tomato plants grown hydroponically with shoots always maintained in air were submitted to a 7 d hypoxic treatment applied by stopping air bubbling. A combination of techniques including (1)H-nuclear magnetic resonance spectroscopy, RT-PCR and enzyme analyses was used to obtain a broad picture of hypoxic root metabolism. In normoxic conditions, HXK overexpression resulted in higher ADP and AMP levels only in roots of AtHXK1 transgenic plants. During hypoxic treatment, oxygen levels in the hydroponic tank decreased rapidly to 5 kPa within the first 2 d and then remained at 5 kPa throughout the 7 d experiment. Oxygen levels were similar at 5 and 20 cm below the water surface. A decline of the adenylate energy status was observed after 2 d of hypoxic treatment, with a further decrease by 7 d in roots of non-transgenic (WT) and ScHXK2, but not in AtHXK1 transgenic plants. Sucrose synthase activity increased to comparably higher levels at 7 d of hypoxic treatment in WT and ScHXK2 compared with AtHXK1 roots. Differences between WT and the transgenic plants are discussed with respect to the metabolic response to low (hypoxia) but not zero (anoxia) oxygen.