A study on the growth of Salvinia molesta Mitchell in relation to light and temperature

The effects of light intensity and temperature on the growth of Salvinia molesta Mitchell were studied under shade and full sunlight conditions. Growth, in terms of increase in fresh weight and number of offshoots produced was significantly different (P<0.001) under the two light conditions; it was highest under shade during May–July, and in August–September under full sunlight. Mean relative growth rate (RGR) varied from 0.01 to 0.07 g g^?1 day^?1. Increase in the fresh weight had a significant positive nonlinear relationship with light intensity and atmospheric temperature. However, since there was a significant positive relationship between temperature and light intensity, it was not possible to separate their effects through regression analysis.     

Influence of Temperature, Oxygen, and pH on a Metalimnetic Population of Oscillatoria rubescens

Planktonic Oscillatoria spp. often inhabit depths of thermally stratified lakes in which gradients of physical and chemical factors occur. Measurements of photosynthetic rate or photosynthetic carbon metabolism were used to evaluate the importance of vertical gradients of temperature, oxygen, and pH upon Oscillatoria rubescens in Crooked Lake, Ind. At the low light intensities experienced in situ, neither photosynthetic rate nor relative incorporation of carbon dioxide into low-molecular-weight compounds, polysaccharide, or protein was affected by temperature. At a 10-fold-higher light intensity, the photosynthetic rate increased as temperature increased; most of the additional carbon accumulated as polysaccharide. Polysaccharide which was synthesized at high light intensity and temperature was respired when the organisms were placed in the dark, but was not used for protein biosynthesis. When O. rubescens was shifted from high light to low light, a fraction of the polysaccharide was metabolized into protein. Adaptation to growth at lower temperatures by O. rubescens cultures resulted in a decrease in the maximum photosynthetic rate. Oxygen inhibited photosynthesis by only 10 to 15% at concentrations typically found in the lake. The photosynthetic rates at pH values which occurred in Crooked Lake were all near the maximum. Thus, gradients of temperature, oxygen, or pH are not likely to significantly affect the distribution of O. rubescens in Crooked Lake, given the low light intensity at which O. rubescens grows and the range of values for those factors in the lake.     

Effects of Environmental Factors on Toxicity of a Cyanobacterium (Microcystis aeruginosa) under Culture Conditions

Effects of light intensity, temperature, and nutrients on the toxicity of Microcystis aeruginosa were investigated, using a toxic strain which kills mice. A marked change in toxicity was observed in the light intensity experiment, and slight changes were observed to be caused by temperature and phosphorus deficiency.     

Effect of light and temperature on monoterpenoid yield and composition in Satureja douglasii

Light intensity and day temperature were identified as principal modifying factors of monoterpenoid composition and yield in individuals of Satureja douglasii. The individuals represent compositional type and clinial patterns of infraspecific compositional variation. The lack of compositional interconversion confirms the tight genetic control of biosynthesis which results in these infraspecific patterns. There was marked influence by light intensity on monoterpenoid yield per leaf dry weight and by day temperature on yield per leaf. Low light intensity reduced leaf dry weight but had little effect on the amount of monoterpenoids per leaf whereas low day temperature increased both leaf weight and yield per leaf, compared to high light and day temperature effects. Day temperature modification of yield per leaf was related to modification of composition.     

Effects of Light Intensity on the Flight Behaviour of Adult <Emphasis Type="Italic">Tirumala limniace</Emphasis> (Cramer) (Lepidoptera: Nymphalidae: Danainae)

Light intensity significantly affects insect flight behaviour. Mating of butterflies is significantly associated with flight frequency. However, no research has elucidated the effects of light intensity on butterfly flight. Thus, a clear understanding of the effects of light intensity on flight has significant theoretical implications for the cultivation and utilization of butterflies. We observed the flight behaviour of adult Tirumala limniace (Cramer) exposed to light intensities from 243 to 2240 lx and measured the frequency of flight, take-off rhythm, thoracic temperature excess (△T) when perching and flying, and the tendency for thoracic temperature to increase. Results showed that high-intensity light significantly increased flight activity, and males were more active than females under similar light intensities; strong light (1280–2240 lx) resulted in female and male butterflies taking flight earlier compared with weak light (243–864 lx); and a similar pattern was observed for flight duration, with flights by males being significantly longer than those by females at 864–2240 lx; △T of adults flying in strong light was significantly higher than in weak light, whereas the thoracic temperature of perching adults was similar to the air temperature. Compared with other light intensities, the equilibrium thoracic temperature of adults exposed to 2240 lx was higher, and the time to reach it was shorter; in addition, the △T and rate of thoracic temperature increase were higher and achieved more quickly, respectively. Thus, of the 243–2240 lx range, 2240 lx was the most optimal light intensity for adult T. limniace flight and captive rearing.     

Distribution of bacteriochlorophyll between the pigment-protein complexes of the sulfur photosynthetic bacterium <Emphasis Type="Italic">Allochromatium minutissimum</Emphasis> depending on light intensity at different temperatures

Variation of the distribution of bacteriochlorophyll a (BChl a) between external antenna (LH2) and core complexes (LH1 + RC) of the photosynthetic membrane of the sulfur bacterium Allochromatium minutissimum was studied at light intensities of 5 and 90 Wt/m² in the temperature range of 12–43°C. The increase of light intensity was shown to result in a 1.5-to 2-times increase of a photosynthetic unit (PSU). PSU sizes pass through a maximum depending on growth temperature, and the increase of light intensity (5 and 90 Wt/m²) results in a shift of the maximal PSU size to higher temperatures (15 and 20°C, respectively). In the narrow temperature interval of ～14–17°C, the ratio of light intensity to PSU size is typical of phototrophs: lower light intensity corresponds to larger PSU size. The pattern of PSU size change depending on light intensity was shown to differ at extreme growth temperatures (12°C and over 35°C). The comparison of Alc. minutissimum PSU size with the data on Rhodobacter capsulatus and Rhodopseudomonas palustris by measuring the effective optical absorption cross-section for the reaction of photoinhibition of respiration shows a two to four times greater size of light-harvesting antenna for Alc. minutissimum, which seems to correspond to the maximum possible limit for purple bacteria.     

Influence of light intensity,temperature and humidity on photosynthesis and transpiration ofSasa nipponica andArundinaria pygmaea

Photosynthesis and transpiration were simultaneously measured under different light intensity, temperature and humidity conditions inSasa nipponica andArundinaria pygmaea grown in exposed and shaded habitats. Both species showed a saturated light curve for photosynthetic rate. The saturation point was lower in shaded plants. The apparent quantum yields were larger inS. nipponica and in shaded plants, while the maximum photosynthesis was higher inA. pygmaea and exposed plants. The temperature response of photosynthesis showed an optimum curve in both species. The optinum temperatures were 20 C inS. nipponica and 25 C inA. pygmaea. The influence of humidity on photosynthesis was insignificant for both species. The responses of transpiration to light intensity and relative humidity showed a saturated curve and an optimal one, respectively. There was a significant relationship between transpiration and stomatal frequency, both of which were higher inS. nipponica, while water use efficiency was higher inA. pygmaea. These results suggest thatS. nipponica adapts itself better to shaded, low temperature and less water stress habitats as compared withA. pygmaea.     

Effects of long-term action of high temperature and high light on the activity and energy interaction of both photosystems in tomato plants

The acclimation to high light, elevated temperature, and combination of both factors was evaluated in tomato (Solanum lycopersicum cv. M82) by determination of photochemical activities of PSI and PSII and by analyzing 77 K fluorescence of isolated thylakoid membranes. Developed plants were exposed for six days to different combinations of temperature and light intensity followed by five days of a recovery period. Photochemical activities of both photosystems showed different sensitivity towards the heat treatment in dependence on light intensity. Elevated temperature exhibited more negative impact on PSII activity, while PSI was slightly stimulated. Analysis of 77 K fluorescence emission and excitation spectra showed alterations in the energy distribution between both photosystems indicating alterations in light-harvesting complexes. Light intensity affected the antenna complexes of both photosystems stronger than temperature. Our results demonstrated that simultaneous action of high-light intensity and high temperature promoted the acclimation of tomato plants regarding the activity of both photosystems in thylakoid membranes.     

Anthesis and pollen dispersal of holcus lanatus L. and Festuca rubra L. in relation to climate factors

Anthesis and pollen dispersal of H. lanatus and F. rubra were related to climate factors during a field investigation on Schiermonnikoog. In both species the anthesis showed a diurnal periodicity and could be connected to air temperature, relative air humidity, and light intensity. In the pollen release of both species no daily periodicity was found. This pollen release appears to be dependent on neither the temperature nor the light intensity. It could be related to only one of the measured climate factors, viz. the relative air humidity. It was discussed that anthesis is an active process based on physiological and ecological properties of the plant, whereas the pollen dispersal is only a mechanical process.     

The emission of floral scent from Lilium ‘siberia’ in response to light intensity and temperature

Floral scent is an important part of volatile compounds emitted from plants, and is influenced by many environmental factors. In this study, the floral scent emitted from Lilium ‘siberia’, a common breed of lily, was collected by dynamic headspace at different levels of light intensity (0, 100, 300, 600, 1,000, and 1,500 μmol m^?2 s^?1) and temperature (10, 20, 30, and 40 °C). Using the automated thermal desorption-gas chromatography/mass spectrometry (ATD-GC/MS) technique, the components and release amounts were subsequently identified to investigate the influence of light and temperature on the emission of floral scent. The results revealed that the numbers and release amounts of floral scent components were significantly influenced by light intensity and temperature, showing the similar pattern: first increasing and then decreasing. After light intensity treatment, the maximum numbers and release amounts mainly appeared at 600 and 1,000 μmol m^?2 s^?1. For temperature treatment, 30 °C resulted in the highest numbers and release amounts of the floral scent components. At different levels of light intensity and temperature, terpenoid compounds showed the highest numbers and release amounts among the component categories. α-Ocimene and linalool were the two terpenoid compounds with the highest release amounts, and accounted for the highest proportion. The results obtained provide evidence that both light intensity and temperature trigger the emission of floral scent. The particular response mechanisms must be investigated in future research.     

Phenology of Paralemanea annulata (Lemaneaceae,Rhodophyta) in an Ohio woodland stream

Paralemanea annulata, a member of Lemaneaceae (Batrachospermales, Rhodophyta) was investigated in a field study to monitor its seasonality and determine environmental parameters that play a role in its phenology. Macroscopic gametophytes were present during the months of December&#x2013;August, and percent cover dropped precipitously from June to July. Thalli had spermatangia present in all months except December and carposporophytes were observed in May and June. Audouinella hermannii thickly colonized the thalli March&#x2013;June. Lack of thalli from September&#x2013;November corresponded with low water and increased water temperature. New growth of gametophytes was first observed in December. Gametophyte percent cover showed a positive correlation with both current velocity and light intensity. A laboratory study was conducted in the winter and spring, which investigated growth in relation to temperature, daylength and light intensity. Thalli grew more slowly in the 5 &#x00B0;C treatments than the 15 &#x00B0;C treatments and no clear trends could be determined among the daylength and light intensity treatments. For all treatments, thalli grew more in the winter than the spring experiment.     

Photosynthetic Acclimation to Temperature in the Desert Shrub, Larrea divaricata: II. Light-harvesting Efficiency and Electron Transport

The response of photosynthetic electron transport and light-harvesting efficiency to high temperatures was studied in the desert shrub Larrea divaricata Cav. Plants were grown at day/night temperatures of 20/15, 32/25, or 45/33 C in rough approximation of natural seasonal temperature variations. The process of acclimation to high temperatures involves an enhancement of the stability of the interactions between the light-harvesting pigments and the photosystem reaction centers. As temperature is increased, the heat-induced dissociation of these complexes results in a decrease in the quantum yield of electron transport at limiting light intensity, followed by a loss of electron transport activity at rate-saturating light intensity. The decreased quantum yield can be attributed to a block of excitation energy transfer from chlorophyll b to chlorophyll a, and changes in the distribution of the excitation energy between photosystems II and I. The block of excitation energy transfer is characterized by a loss of the effectiveness of 480 nm light (absorbed primarily by chlorophyll b) to drive protochemical processes, as well as fluorescence emission by chlorophyll b.     

Influence of ecological conditions on magnesium and strontium content and ultrastructure of the calcareous skeleton ofBornetella sphaerica (Zarnadini), Dasycladales

The influence of temperature and light intensity on the ultrastructure of the calcareous skeleton of theBornetella sphaerica (Dasycladales) as well as on the incorporation of Mg and Sr into the skeleton was studied. Cells were grown in laboratory culture under various light and temperature conditions in a medium which allows them to calcify as they do in their natural habitat. The results are compared with general observations and measurements reported in the literature, especially with data on algae.     

Optimization of cultivation conditions for fatty acid composition and EPA production in the eustigmatophycean microalga Trachydiscus minutus

We determined the effects of cultivation conditions (nitrogen source, salinity, light intensity, temperature) on the composition of polyunsaturated fatty acids (PUFAs) and the production of eicosapentaenoic acid (EPA) in the laboratory cultured eustigmatophycean microalga, Trachydiscus minutus. T. minutus was capable of utilizing all nitrogen compounds tested (potassium nitrate, urea, ammonium nitrate, ammonium carbonate) with no differences in growth and only minor differences in fatty acid (FA) compositions. Ammonium carbonate was the least appropriate for lipid content and EPA production, while urea was as suitable as nitrates. Salinity (0.2 % NaCl) slightly stimulated EPA content and inhibited growth. Increasing salinity had a marked inhibitory effect on growth and PUFA composition; salinity at or above 0.8 % NaCl was lethal. Both light intensity and temperature had a distinct effect on growth and FA composition. The microalga grew best at light intensities of 470–1,070 μmol photons m^?2 s^?1 compared to 100 μmol photons m^?2 s^?1, and at 28 °C; sub-optimal temperatures (20, 33 °C) strongly inhibited growth. Saturated fatty acids increased with light intensity and temperature, whereas the reverse trend was found for PUFAs. Although the highest level of EPA (as a proportion of total FAs) was achieved at a light intensity of 100 μmol photons m^?2 s^?1 (51.1?± 2.8 %) and a temperature of 20 °C (50.9?±?0.8 %), the highest EPA productivity of about 30 mg L^?1?day^?1 was found in microalgae grown at higher light intensities, at 28 °C. Overall, for overproduction of EPA in microalgae, we propose that outdoor cultivation be used under conditions of a temperate climatic zone in summer, using urea as a nitrogen source.     

Temperature and plant adaptation. I. Interaction of temperature and light in the synthesis of chlorophyll in corn

The effect of temperature and light intensity have been studied in relation to the greening of etiolated corn (Zea mays cv. Pioneer 309-B) seedlings. Chlorophyll accumulation is rapid at high temperature (28°) under all conditions of light intensity. At low temperature (16°), and particularly in combination with high light intensity (3000-4500 ft-c), the accumulation of both chlorophyll and carotene is inhibited.

Low pigment content at 16° is not directly due to a block in the pigment synthesizing mechanism, but rather to the photodestruction of chlorophyll prior to its stabilization in the membrane structure of the chloroplast lamellae. The parallel reduction in carotene content at high light intensity is probably a contributing factor, because of its role in protecting chlorophyll from photodestruction. The greater severity of photo-oxidation of chlorophyll at low temperature in corn when compared with wheat, appears to be due to a slower rate of protochlorophyllide synthesis and subsequent esterification. Thus in corn at 16° there is a prolongation of the photosensitive stage during chlorophyll synthesis. Photo-oxidation at 16° has also been shown to be a function of the incident light energy, with the photosynthetic pigments acting as receptors for their own destruction.

In comparison with the behavior of corn, wheat seedlings green rapidly at high light intensity at both 16° and 28°. This contrasting temperature response with respect to chlorophyll synthesis may underlie a fundamental difference in adaptation of these 2 species to growth in the temperate zones of the world.

     

Effect of light and substratum complexity on microhabitat selection and activity of the ophiuroid Ophiopholis aculeata

We evaluated the effect of light intensity and substratum complexity on habitat preference and displacement speed of the ophiuroid Ophiopholis aculeata. The ophiuroid strongly preferred reduced light and to a lesser extent complex substrata. Further, displacement speed increased with light intensity and decreased with substratum complexity (ophiuroids were virtually immobile on darkened complex substrata). In the field, the density of exposed ophiuroids, with the disk out of a crevice, was always low, irrespective of the intensity of solar radiation. However, the extent to which they extended their arms (to feed) was inversely related to light intensity, as the number of suspension-feeding arms was low under direct sunlight, intermediate under indirect light and high at night. Field observations showed that the response to light was not modified when UV radiation was eliminated with a filter, and a laboratory experiment showed that white light intensity alone produced patterns similar to those observed in the field. O. aculeata may reduce arm extension with increasing light intensity to reduce the threat of visual predators, whose foraging efficiency increases with light intensity. However, visual predators are rare in our study site. We hypothesize that the large-scale larval dispersion of O. aculeata (due to the long pelagic phase) prevents ophiuroids from adapting to local conditions so that its response to light reflects adaptation to visual predators in other locations.     

Interaction between saline stress and photoinhibition of photosynthesis in the freshwater green algae Chlamydomonas reinhardtii. Implications for glycerol photoproduction

Light intensity is the main limiting factor for the photosynthetic bioconversion of CO₂ into glycerol which takes place when Chlamydomonas reinhardtii cells are exposed to saline stress conditions. Although productivity increases with light intensity for low irradiances, a strong inhibition is observed for high light intensity values. Saline stress enhances the damage caused by excess of light on the photosynthetic apparatus. The aim of this work is to evaluate the effect of high light intensity and saline stress on photosynthetic activity, cell growth and glycerol photoproduction by C. reinhardtii. The effect of light intensity on C. reinhardtii cells was studied immediately after transfer to a saline medium and after 24 h of adaptation to saline stress conditions. The influence of light intensity on the glycerol production rate was also evaluated for C. reinhardtii cultured in bioreactors of different radius. The factors that significantly affected photoinhibition were light intensity, cell density, radius of the bioreactor and time of exposure to the high light intensity. Our results suggest that bioreactors with a high surface/volume ratio will enable the achievement of high productivities with relatively low light intensities on the surface and will miminise the photoinhibition effect.     

Production of cyanopeptolins,anabaenopeptins, and microcystins by the harmful cyanobacteria Anabaena 90 and Microcystis PCC 7806

This study investigated the effects of light intensity, temperature, and phosphorus limitation on the peptide production of the cyanobacteria Microcystis PCC 7806 and Anabaena 90. Microcystis PCC 7806 produced two microcystin variants and three cyanopeptolins, whereas Anabaena 90 produced four microcystin variants, three anabaenopeptins, and two anabaenopeptilides. Microcystin and cyanopeptolin contents varied by a factor 2–3, whereas the anabaenopeptins and anabaenopeptilides of Anabaena varied more strongly. Under phosphorus limitation, peptide production rates increased with the specific growth rate. The response of peptide production to light intensity and temperature was more complex: in many cases peptide production decreased with specific growth rate. We observed compensatory changes of different peptide variants: decreased cyanopeptolin A and C contents were accompanied by increased cyanopeptolin 970 contents, and decreased anabaenopeptin A and C contents were accompanied by increased anabaenopeptilide 90B contents. Compensatory dynamics in peptide production may enable cyanobacteria to sustain stable peptide levels in a variable environment.     

Hsp60 protein pattern in coral is altered by environmental changes in light and temperature

The heat shock protein Hsp60 exhibited marked oscillation during a 12-hour day period when the coral Turbinaria reniformis was maintained in the laboratory under constant conditions of light (200 μE) and temperature (27 °C). A biphasic pattern of Hsp60 was apparent, punctuated by a low protein level at the midpoint of the 12-hour day period. Oscillation of Hsp60 was also apparent when coral was kept in darkness in lieu of a scheduled light period. The pattern of Hsp60 was altered when coral was exposed to increased light intensity (400 μE) or temperature elevation (32 °C). These observations suggest that Hsp60 in coral exhibits oscillation that is altered by increased light and temperature elevation.     

Ecological Consequences of Long-Term Exposure of Anabaena variabilis (Cyanophyceae) to Shifts in Environmental Factors

Cultures of Anabaena variabilis were exposed to different light intensities, and the time course of photoadaptation was measured by photosynthetic rate and changes in pigmentation. A shift down in intensity of 284 μEin · m⁻² · sec⁻¹ caused a temporary decrease in the photosynthetic response followed by gradual adaptation to the new conditions. Final chlorophyll a and carotenoid concentrations were reached after 1 day, although other physiological indicators showed that adaptation required 4 days. The parameter I_k was shown to be the best indicator of photoadaptation. A shift up in light intensity of the same magnitude also required 4 days for complete photoadaptation by the culture, although chlorophyll and carotenoid concentrations stabilized within 1 day. A shift down in light intensity of 392 μEin · m⁻² · sec⁻¹ resulted in a temporary attempt to adapt followed by collapse of the population. This demonstrates an apparent threshold in the magnitude of the shift in light intensity which will permit successful adaptation. Simultaneous changes in light intensity and temperature also adversely affected culture populations. Our observations present a possible cause for the decline or prevention of an algal bloom under a fluctuating light regime and suggest that it may be possible to predict this decline as a result of synoptic weather patterns or hydrodynamic influences.