Effects of Quality, Intensity, and Duration of Light Breaks during a Long Night on Dormancy in Blue Spruce (Picea pungens Engelm.) Seedlings

Blue spruce (Picea pungens Engelm.) seedlings grow continuously when exposed to photoperiods exceeding 16 hours and enter dormancy within 4 weeks under photoperiods of 12 hours or less. Dormancy was prevented under 12-hour photoperiods by 2-hour light breaks of red light (1.70 μw/cm² at 650 nm) or high intensity white light (2,164.29 μw/cm² at 400 to 800 nm) given in the middle of the 12-hour night, and by continuous low intensity white light (204.76 μw/cm² at 400 to 800 nm). Two-hour light breaks of far red light (1.80 μw/cm² at 730 nm), red light followed by far red light, or low intensity white light were not effective in delaying dormancy. The results imply that the phytochrome system mediates the photoperiodic control of dormancy in blue spruce seedlings. The similarity of results obtained using the low intensity, long duration as against the high intensity, short duration light treatments suggests that the law of reciprocity applies in this response.     

Effects of Light Intensity on Tracheid Dimensions in Picea sitchensis

In seedlings of Picea sitchensis grown in constant conditions,or within older trees in the field, light intensity had no neteffect on the wall thickness of tracheids produced at the samepoint in time. This appears to be due to a balanced regulatorysystem, effects of light intensity on rate of accumulation ofwall volume per leaf being offset by differences in rate ofxylem increment, and differences in wall material per tracheidbeing nullified in their effects on wall thickness by effectson tracheid diameter. Mean tracheid wall thickness across the growth ring increasedwith light intensity, due to increase in proportion of late-woodassociated with the longer duration of cambial activity at higherlight intensity, duration of wall thickening increasing duringthe season. Duration of wall thickening did not vary with lightintensity. The rate of increase in wall volume was limited by light intensity(and hence possibly by substrate availability) at all lightintensities in the field, but in seedlings in controlled conditionsthe rate of wall production was no greater at 20 000 lx thanat 6700 lx.     

Developmental Changes in Composition and Morphology of Cuticular Waxes on Leaves and Spikes of Glossy and Glaucous Wheat (Triticum aestivum L.)

The glossy varieties (A14 and Jing 2001) and glaucous varieties (Fanmai 5 and Shanken 99) of wheat (Triticum aestivum L.) were selected for evaluation of developmental changes in the composition and morphology of cuticular waxes on leaves and spikes. The results provide us with two different wax development patterns between leaf and spike. The general accumulation trend of the total wax load on leaf and spike surfaces is first to increase and then decrease during the development growth period, but these changes were caused by different compound classes between leaf and spike. Developmental changes of leaf waxes were mainly the result of variations in composition of alcohols and alkanes. In addition, diketones were the third important contributor to the leaf wax changes in the glaucous varieties. Alkanes and diketones were the two major compound classes that caused the developmental changes of spike waxes. For leaf waxes, β- and OH-β-diketones were first detected in flag leaves from 200-day-old plants, and the amounts of β- and OH-β-diketones were significantly higher in glaucous varieties compared with glossy varieties. In spike waxes, β-diketone existed in all varieties, but OH-β-diketone was detectable only in the glaucous varieties. Unexpectedly, the glaucous variety Fanmai 5 yielded large amounts of OH-β-diketone. There was a significant shift in the chain length distribution of alkanes between early stage leaf and flag leaf. Unlike C₂₈ alcohol being the dominant chain length in leaf waxes, the dominant alcohol chain length of spikes was C₂₄ or C₂₆ depending on varieties. Epicuticular wax crystals on wheat leaf and glume were comprised of platelets and tubules, and the crystal morphology changed constantly throughout plant growth, especially the abaxial leaf crystals. Moreover, our results suggested that platelets and tubules on glume surfaces could be formed rapidly within a few days.     

Mineral composition and growth of Colorado spruce (Picea pungens) seedlings under calcareous soil conditions

Summary Field studies were conducted to assess the mineral nutrition and growth of Colorado spruce (Picea pungens Engln) seedlings (2–4 yr) from provenances selected for superior growth on calcareous prairie soils. Tissue nutrient concentrations and response to nitrogen were determined by use of foliar analysis and growth pattern studies. Soil conditions ranged from 7.6–7.8 for pH, 12–23% for total CaCO₃, and 5–6% for active CaCO₃. Foliage mineral composition showed relatively low phosphorus (0.09–0.15%) and high calcium (0.45–1.52%) assimilation. Seasonal growth and seedling response to added nitrogen was not adversely affected by the calcareous soil condition. Levels of nitrogen in the foliage required for optimum growth ranged from 1.5–2.0% and were similar to that of other conifer species.     

Morphogenesis in Schizophyllum commune. I. Effects of White Light

Reproductive differentiation in the basidiomycete Schizophyllum commune Fr. is initiated by plasmogamy and reciprocal nuclear migration and is terminated by the production of basidiospores. The work reported here has analyzed several factors that affect 2 sequential steps in reproductive differentiation: A) the formation of aggregated masses of cells, and B) the subsequent differentiation of fruiting bodies. The 2 steps are both photosensitive: A) light accelerates the formation of aggregated masses of cells; B) a short exposure of light induces nonaggregated dikaryotic cells to form mature fruiting bodies in the dark.     

The Perception and Misperception of Specular Surface Reflectance

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Highlights? Investigated why irrelevant scene attributes influence perception of surface gloss ? Found gloss judgments exhibit complex interactions between illumination and 3D shape ? Four proximal cues can account for interactions between light field, shape, and gloss ? Suggests that these cues mediate the perception and misperception of gloss     

光照对蛋鸡生理学特征影响的研究进展

本文综述了光照对蛋鸡生理学特征影响的研究进展,主要涉及光照周期、光照强度和光色对蛋鸡个体生长发育、存活、摄食、生长、繁殖等方面的研究进展,以期为我国进行该领域的研究和指导养殖实践提供一定的参考     

Fuel Pellets from Wheat Straw: The Effect of Lignin Glass Transition and Surface Waxes on Pelletizing Properties

The utilization of wheat straw as a renewable energy resource is limited due to its low bulk density. Pelletizing wheat straw into fuel pellets of high density increases its handling properties but is more challenging compared to pelletizing woody biomass. Straw has a lower lignin content and a high concentration of hydrophobic waxes on its outer surface that may limit the pellet strength. The present work studies the impact of the lignin glass transition on the pelletizing properties of wheat straw. Furthermore, the effect of surface waxes on the pelletizing process and pellet strength are investigated by comparing wheat straw before and after organic solvent extraction. The lignin glass transition temperature for wheat straw and extracted wheat straw is determined by dynamic mechanical thermal analysis. At a moisture content of 8%, transitions are identified at 53°C and 63°C, respectively. Pellets are pressed from wheat straw and straw where the waxes have been extracted from. Two pelletizing temperatures were chosen??one below and one above the glass transition temperature of lignin. The pellets compression strength, density, and fracture surface were compared to each other. Pellets pressed at 30°C have a lower density and compression strength and a tendency to expand in length after the pelletizing process compared to pellets pressed at 100°C. At low temperatures, surface extractives have a lubricating effect and reduce the friction in the press channel of a pellet mill while no such effect is observed at elevated temperatures. Fuel pellets made from extracted wheat straw have a slightly higher compression strength which might be explained by a better interparticle adhesion in the absence of hydrophobic surface waxes.     

Gametogenesis in Chlamydomonas eugametos: I. Light Requirements

Male and female mating types of Chlamydomonas eugametos Moewus show an absolute light requirement for gametogenesis. Increasing light intensity from 0.3 to 1.2 mw cm⁻² during nitrogen starvation (a precondition for gametogenesis) caused an increase in gametogenesis throughout a 28-hour period. Gametogenesis was measured by determining the percentage of paired cells after a 1-hour mixing period. Light requirements for the male and female differed. There was a 9-hour lag period in gametogenesis in the male, but no lag in the female. Gametogenesis was reduced 50% in the female and 90% in the male when 6.0 μm 3-(3,4-dichlorophenyl)-1, 1-dimethyl-urea was in the N-starvation medium. Sodium acetate, 1.8 mm, in the N-starvation medium increased gametogenesis in both mating types and eliminated the 9-hour lag in the male for cells irradiated for 3, 6, 9, 12, 15, 18, or 23 hours during the last part of a 23-hour N-starvation period. Sodium acetate concentrations higher than 1.8 mm inhibited the mating process. 3-(3,4-Dichlorophenyl)-1, 1-dimethylurea inhibition of gametogenesis was decreased in the male but increased in the female, when sodium acetate was added to the N-starvation medium. These results indicate a nonphotosynthetic as well as a photosynthetic role for light in the gametogenesis of both mating types. Also, the male will not undergo gametogenesis unless a required amount of energy is provided either in the medium or through photosynthesis.     

Effects of cytochalasin B on cytokinesis in mouse blastomeres. I. Light microscopic study

Mouse blastomeres exposed to cytochalasin B (CB) at subsequent stages of cytokinesis become spherical within 5–15 min. This change of form is preceded by rapid constriction of the furrow and by shape changes in the nonfurrow region such as blebbing, surface expansion, and formation of additional constrictions. While rounding up of blastomeres is completed within a few minutes in CB, 0.5 hr is the minimal duration of treatment that prevents resumption of cytokinesis after removal from CB.     

An Analysis of the Growth of Young Tomato Plants in Water Culture at Different Light Integrals and CO2 Concentrations: I. Physiological Aspects

Young tomato plants were grown from germination in water cultureat light-flux densities from 6 to 110 W m^-2 (400–700 nm),daylengths from 8 to 24 h and CO₂ concentrations from 0.4 to2.2 g CO² m^-3 in controlled environment cabinets. The growth rates and net assimilation rates of 14–17-day-oldplants at the highest light integrals were appreciably greaterthan most values previously recorded for tomato, and diminishedwith time. Plants in the lowest light conditions had leaf arearatios five times larger than those in the highest light, attributablemainly to a difference in leaf dry weight/area. Such flexibilityin leaf area ratio has not previously been associated with ‘sun’plants such as the tomato. Relatively normal growth was obtained in continuous light, incontrast to most other reports. This may have been due to theuse of conditions which would minimise water stress. The efficiency of the conversion of incident light energy tochemical energy by the whole plant ranged from 15 per cent inseedlings in low continuous light to about 6 per cent, tendingto be higher in young plants in long days under CO₂ enrichment.The higher values are probably overestimates because of theexclusion of reflected light from the energy receipt values.     

Physiological Studies on Pea Tendrils : XIV. Effects of Mechanical Perturbation, Light, and 2-Deoxy-d-Glucose on Callose Deposition and Tendril Coiling

When excised tendrils of pea (Pisum sativum L. cv Alaska) are mechanically perturbed there is an immediate and transient increase in callose deposition in the sieve cells. Mechanical perturbation (MP) results in a coiling response in light-grown tendrils and in dark-adapted tendrils, provided, in the latter case, that they receive adequate illumination within a limited period of time after MP. In nonperturbed tendrils the number of callose deposits decreases to some minimum with increasing time in the dark, and their ability to coil in the dark in response to MP diminishes with time in the dark. The transient increase of callose deposition due to MP, however, occurs whether or not tendrils are dark adapted, and whether they receive light or are retained in the dark after MP. This indicates that if callose is directly involved in tendril coiling, then it exerts its effect on the sensory perception of the mechanical stimulus. In the present investigation, there is never tendril coiling without the transient increase in callose, and the time after MP at which the peak of callose deposition occurs precedes the time of the peak amount of coiling.     

Combined Effects of CO2 and Light on the N2-Fixing Cyanobacterium Trichodesmium IMS101: Physiological Responses

Recent studies on the diazotrophic cyanobacterium Trichodesmium erythraeum (IMS101) showed that increasing CO₂ partial pressure (pCO₂) enhances N₂ fixation and growth. Significant uncertainties remain as to the degree of the sensitivity to pCO₂, its modification by other environmental factors, and underlying processes causing these responses. To address these questions, we examined the responses of Trichodesmium IMS101 grown under a matrix of low and high levels of pCO₂ (150 and 900 μatm) and irradiance (50 and 200 μmol photons m⁻² s⁻¹). Growth rates as well as cellular carbon and nitrogen contents increased with increasing pCO₂ and light levels in the cultures. The pCO₂-dependent stimulation in organic carbon and nitrogen production was highest under low light. High pCO₂ stimulated rates of N₂ fixation and prolonged the duration, while high light affected maximum rates only. Gross photosynthesis increased with light but did not change with pCO₂. HCO₃⁻ was identified as the predominant carbon source taken up in all treatments. Inorganic carbon uptake increased with light, but only gross CO₂ uptake was enhanced under high pCO₂. A comparison between carbon fluxes in vivo and those derived from ¹³C fractionation indicates high internal carbon cycling, especially in the low-pCO₂ treatment under high light. Light-dependent oxygen uptake was only detected under low pCO₂ combined with high light or when low-light-acclimated cells were exposed to high light, indicating that the Mehler reaction functions also as a photoprotective mechanism in Trichodesmium. Our data confirm the pronounced pCO₂ effect on N₂ fixation and growth in Trichodesmium and further show a strong modulation of these effects by light intensity. We attribute these responses to changes in the allocation of photosynthetic energy between carbon acquisition and the assimilation of carbon and nitrogen under elevated pCO₂. These findings are supported by a complementary study looking at photosynthetic fluorescence parameters of photosystem II, photosynthetic unit stoichiometry (photosystem I:photosystem II), and pool sizes of key proteins in carbon and nitrogen acquisition.Human-induced climate change will significantly alter the marine environment within the next century and beyond. Future scenarios predict an increase from currently approximately 380 to about 750 to 1,000 μatm CO₂ partial pressure (pCO₂) in the atmosphere until the end of this century (Raven et al., 2005; Raupach et al., 2007). As the ocean takes up this anthropogenic CO₂, dissolved inorganic carbon (DIC) in the surface ocean increases while the pH decreases (Wolf-Gladrow et al., 1999). Rising global temperatures will increase surface ocean stratification, which may affect the light regime in the upper mixed layer as well as nutrient input from deeper waters (Doney, 2006). Uncertainties remain regarding both the magnitude of the physicochemical changes and the biological responses of organisms, including species and populations of the oceanic primary producers at the basis of the food webs.In view of potential ecological implications and feedbacks on climate, several studies have examined pCO₂ sensitivity in phytoplankton key species (Burkhardt and Riebesell, 1997; Riebesell et al., 2000; Rost et al., 2003; Tortell et al., 2008). Pronounced responses to elevated pCO₂ were observed in N₂-fixing cyanobacteria (Barcelos é Ramos et al., 2007; Hutchins et al., 2007; Levitan et al., 2007; Fu et al., 2008; Kranz et al., 2009), which play a vital role in marine ecosystems by providing a new source of biologically available nitrogen species to otherwise nitrogen-limited regions. Recent studies focused on the impact of different environmental factors on the filamentous Trichodesmium species, which is known for high abundance and the formation of massive blooms in tropical and subtropical areas (Capone et al., 2005; Mahaffey et al., 2005). Higher pCO₂ levels stimulated growth rates, biomass production, and N₂ fixation (Hutchins et al., 2007; Levitan et al., 2007; Kranz et al., 2009) and affected inorganic carbon acquisition of the cells (Kranz et al., 2009). While elevated sea surface temperatures are predicted to shift the spatial distribution of Trichodesmium species toward higher latitudes (Breitbarth et al., 2007), the combined effects of pCO₂ and temperature may favor this species and extend its niche even farther (Hutchins et al., 2007; Levitan et al., 2010a). An increase in the average light intensity, caused by the predicted shoaling of the upper mixed layer, may further stimulate photosynthesis and thus growth and N₂ fixation of Trichodesmium (Breitbarth et al., 2008). To our knowledge, the combined effects of light and pCO₂ have not been studied yet, although these environmental factors are likely to influence photosynthesis and other key processes in Trichodesmium.To understand the responses of an organism to changes in environmental conditions, metabolic processes must be studied. In Trichodesmium, photosynthetically generated energy (ATP and NADPH) is primarily used for the fixation of CO₂ in the Calvin-Benson cycle. A large proportion of this energy, however, is also required for the process of N₂ fixation via nitrogenase and for the operation of a CO₂-concentrating mechanism (CCM). The latter involves active uptake of inorganic carbon, which functions to increase the rate of carboxylation reaction mediated by Rubisco. This ancient and highly conserved enzyme is characterized by low affinities for its substrate CO₂ and a susceptibility to a competing reaction with oxygen (O₂) as substrate (Badger et al., 1998); the latter initiates photorespiration. As cyanobacterial Rubisco possesses one of the lowest CO₂ affinities among phytoplankton (Badger et al., 1998), a considerable amount of resources have to be invested to achieve sufficient rates of carbon fixation and to avoid photorespiration. A first step toward a mechanistic understanding of responses in Trichodesmium has been taken by Levitan et al. (2007), focusing on pCO₂ dependency of nitrogenase activity and photosynthesis. Subsequently, Kranz et al. (2009) described variations in CCM efficiency with pCO₂ and suggested that the observed plasticity in CCM regulation allowed energy reallocation under high pCO₂, which may explain the observed pCO₂-dependent changes in nitrogenase activity, growth, and elemental composition (Barcelos é Ramos et al., 2007; Hutchins et al., 2007; Levitan et al., 2007).In this study, we measured growth responses as well as metabolic key processes in Trichodesmium erythraeum (IMS101) under environmental conditions that likely alter the energy budget and/or energy allocation of the cell. Cultures were acclimated to a matrix of low and high pCO₂ (150 and 900 μatm) at two different light intensities (50 and 200 μmol photons m⁻² s⁻¹). For each of the four treatments, changes in growth rates, elemental ratios, and the accumulation of particulate carbon and nitrogen were measured. Metabolic processes (gross photosynthesis, CCM activity, and O₂ uptake) were obtained by means of membrane-inlet mass spectrometry (MIMS), while N₂ fixation was detected by gas chromatography. As these processes may vary over the diurnal cycle in Trichodesmium (Berman-Frank et al., 2001; Kranz et al., 2009), measurements were performed in the morning and around midday. The results on metabolic processes were accompanied by measurements of the fluorescence of PSII, ratios of the photosynthetic units (PSI:PSII), and pool sizes of key proteins involved in carbon and nitrogen fixation as well as assimilation (Levitan et al., 2010b).     

低温弱光对以色列番茄幼苗生长及生理指标的影响

用以色列引进品种F-044和安徽省地区主栽品种皖红3号番茄为材料,研究在不同低温(10℃/5℃)弱光(60μm ol.m-2.s-1)处理下及恢复过程中,番茄幼苗生长及生理指标的变化。结果表明:各处理指标变化趋势相同;10℃低温弱光处理后,番茄幼苗生长势、叶片叶绿素含量及超氧物歧化酶(SOD)、过氧化氢酶(CAT)活性下降,而过氧化物酶(POD)活性、丙二酶(MDA)含量,根冠比上升。各指标在恢复期内均能恢复到对照水平;5℃低温弱光胁迫后,F-044仅地上部分干物质积累受胁迫影响,根冠比上升了14.97%,而皖红3号因地下干物质积累减少显著,根冠比则下降了27.74%;各处理下F-044的各项指标变化、恢复情况均显著好于皖红3号,低温弱光耐性强于皖红3号。     

长期喷施ABA对云杉幼苗生长和生理特性的影响

采用单因素盆栽实验,通过叶面喷施5、10、15和20mg·L^-1 4个浓度的ABA溶液,研究了长期外源ABA处理对云杉（Piceaasperata）幼苗生长及生理特性的影响。5年的研究结果表明：长期不同浓度ABA处理显著影响了云杉幼苗的多种生长及生理生化指标。当ABA浓度为5、10和15mg·L^-1叫时有利于云杉幼苗根重、茎重和总生物量的积累,并且提高了叶片中可溶性蛋白和脯氨酸的含量,降低了MDA含量：20mg·L^-1 ABA处理使幼苗的叶重、总生物量、脯氨酸及可溶性糖含量显著下降,明显增加了叶片中MDA含量。此外,各浓度ABA处理均显著降低了云杉幼苗的株高、叶绿素含量以及SOD和APX活性。本研究结果显示,长期ABA处理对云杉幼苗生长和生理特性的影响与所喷施的ABA浓度有关,长期高浓度ABA（20mg·L^-1）处理不利于云杉幼苗生长。