Light‐dependent changes of tomato glutamine synthetase in response to Pseudomonas syringae infection or phosphinothricin treatment

Glutamine synthetase (GS, EC 6.3.1.2), a key enzyme in nitrogen assimilation, was investigated in tomato ( Lycopersicon esculentum Mill. cv. Hellfrucht Frühstamm) leaves infected with Pseudomonas syringae pv. tomato (Pst) or treated with the herbicide phosphinothricin (PPT), an irreversible inhibitor of GS. GS activity decreased markedly when Pst infection occurred in illuminated leaves, but only a slight decrease in relation to control leaves was observed under non‐photosynthetic conditions. In leaves treated with PPT, a rapid inhibition of GS activity was observed under all experimental conditions. When bacterial infection or herbicide treatment was carried out in the light, cytosolic GS (GS1) appeared as the predominant GS polypeptide; however, under non‐photosynthetic conditions GS2 remained the most abundant molecular GS species as occurs in non‐stressed plants. These results suggest a close correlation between the photosynthetic process and changes in the relative proportions of GS polypeptides during infection or herbicide treatment. Ammonium has been described as an inducer of GS genes, but as ammonium accumulated during all treatments, other light‐dependent factors could be involved in GS regulation of stressed leaves.     

Light Harvesting and State Transitions in Cyanobacteria

Cyanobacteria are oxygenic phototrophic prokaryotes and are considered to be the ancestors of chloroplasts. Their photosynthetic machinery is functionally equivalent in terms of primary photochemistry and photosynthetic electron transport. Fluorescence measurements and other techniques indicate that cyanobacteria, like plants, are capable of redirecting pathways of excitation energy transfer from light harvesting antennae to both photosystems. Cyanobacterial cells can reach two energetically different states, which are defined as “State 1” (obtained after preferential excitation of photosystem I) and “State 2” (preferential excitation of photosystem II). These states can be distinguished by static and time resolved fluorescence techniques. One of the most important conclusions reached so far is that the presence of both photosystems, as well as certain antenna components, are necessary for state transitions to occur. Spectroscopic evidence suggests that changes in the coupling state of the light harvesting antenna complexes (the phycobilisomes) to both photosystems occur during state transitions. The finding that the phycobilisome complexes are highly mobile on the surface of the thylakoid membrane (the mode of interaction with the thylakoid membrane is essentially unknown), has led to the proposal that they are in dynamic equilibrium with both photosystems and regulation of energy transfer is mediated by changes in affinity for either photosystem.     

Isolation and characterization of Photosystem I from two strains of the marine oxychlorobacterium Prochlorococcus

Photosystem I (PS I) complexes from two strains of the marine photosynthetic prokaryote Prochlorococcus, MED4 (= clone CCMP1378) and SS120 (= clone CCMP1375), were isolated by centrifugation on sucrose gradients after detergent treatment. The PS I-enriched fractions of both strains contained about 100 chlorophyll molecules per P700. Electron microscopy showed that the PS I complexes were in a trimeric form. The characteristic long wavelength fluorescence emission of PS I at 77 K, currently observed in chloroplasts and most cyanobacteria was absent both in intact cells and in PS I preparations of both strains. The major proteins of the PS I-enriched fractions were identified immunologically as PsaA and PsaB. Two proteins with apparent molecular masses of about 21 and 25 kDa were present in PS I preparations of Prochlorococcus, whereas the small PS I subunits in cyanobacteria all have molecular masses below 18 kDa. The 25 kDa protein showed a strong cross-reaction with a heterologous antibody against PsaL. Relatedness of the 21 kDa protein to PsaF was demonstrated by internal protein sequencing. Although only trace amounts of the major divinyl-Chl a/b-binding antenna complexes were present in the PS I preparations, significant amounts of divinyl-Chl b were observed in this fraction. The putative organization of this Chl b in PS I is discussed.     

Impact of different meadow mowing techniques on field invertebrates

Low‐input meadows are now recognized for their high biodiversity value and form an integral element of many agri‐environmental schemes in Europe. Meadow mowing techniques, however, have become highly mechanized in recent decades and scientific knowledge on the direct impacts of these techniques on field fauna is based on very few and often poorly replicated studies. Yet these studies, despite their limitations, suggest that such impacts can be considerable. With a view to providing a more comprehensive experimental assessment, we evaluated the direct impacts of four different mowing techniques (hand motor mower with cutter bar, rotary mower cut at 9 cm and rotary mower cut at 6 cm with and without a conditioner) on wax invertebrate models and real caterpillars. The size of the organisms, their microhabitat, the tractor wheel effect and the cutting height were also investigated as factors that could potentially affect mowing‐caused mortality. Rotary mowers were found to be more damaging than motor bar mowers on caterpillars (37% vs. 20%), but only on one type of invertebrate wax‐model. Conditioners more than doubled damage to all wax‐models in the vegetation (in average from 11% to 30%) and increased caterpillar mortality from 38% to 69%. Larger organisms were more vulnerable than smaller organisms and ground organisms were strongly impacted by tractor wheels. While conditioner should not be used in meadows where conservation of the inhabiting fauna is of concern, we also recognize that there is no damage‐free mowing technique. We therefore advocate the importance of leaving uncut areas as a refuge for invertebrates.     

A Triboelectric Generator Based on Checker‐Like Interdigital Electrodes with a Sandwiched PET Thin Film for Harvesting Sliding Energy in All Directions

A triboelectric generator based on checker‐like interdigital electrodes (TEGC) with a sandwiched polyethylene terephthalate (PET) thin film that can convert translation kinetic energy in all directions to electricity is reported. The design of the sandwiched PET thin film can effectively avoid direct wear between metal electrodes and sliding panel. The mechanism of the TEGC is described in detail. The performance of the TEGC in different sliding directions is studied, indicating a maximum output power density of 1.9 W m^‐2 and open‐circuit voltage of 210 V achieved in the X or Y sliding direction. The TEGC is used to charge a 110 μF commercial capacitor to 5 V in 35 s and light up two light‐emitting diodes (LEDs) connected with the capacitor simultaneously. The TEGC based mouse pad and sliding panel are fabricated to harvest mouse operation energy to light up LEDs connected in antiparallel when the computer mouse operates a game. The TEGC has advantages of being flexible, light weight, durable, cost effective, and portable by folding or rolling into a small part. This work presents a significant progress toward the structure design of triboelectric generator for its practical applications.     

An ultrasonically enhanced inclined settler for microalgae harvesting

Microalgae have vast potential as a sustainable and scalable source of biofuels and bioproducts. However, algae dewatering is a critical challenge that must be addressed. Ultrasonic settling has already been exploited for concentrating various biological cells at relatively small batch volumes and/or low throughput. Typically, these designs are operated in batch or semicontinuous mode, wherein the flow is interrupted and the cells are subsequently harvested. These batch techniques are not well suited for scaleup to the throughput levels required for harvesting microalgae from the large‐scale cultivation operations necessary for a viable algal biofuel industry. This article introduces a novel device for the acoustic harvesting of microalgae. The design is based on the coupling of the acoustophoretic force, acoustic transparent materials, and inclined settling. A filtration efficiency of 70 ± 5% and a concentration factor of 11.6 ± 2.2 were achieved at a flow rate of 25 mL·min^?1 and an energy consumption of 3.6 ± 0.9 kWh·m^?3. The effects of the applied power, flow rate, inlet cell concentration, and inclination were explored. It was found that the filtration efficiency of the device is proportional to the power applied. However, the filtration efficiency experienced a plateau at 100 W L^?1 of power density applied. The filtration efficiency also increased with increasing inlet cell concentration and was inversely proportional to the flow rate. It was also found that the optimum settling angle for maximum concentration factor occurred at an angle of 50 ± 5°. At these optimum conditions, the device had higher filtration efficiency in comparison to other similar devices reported in the previous literature. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 31:414–423, 2015     

Modeling Harvest Intensity of Sooty Shearwater Chicks by Rakiura Māori in New Zealand

Abstract: Cultural evidence suggests that sooty shearwater (Puffinus griseus) chicks have been harvested by Rakiura Māori on islands in southern New Zealand since prehistoric times. Concerns exist that modern harvests may be impacting sooty shearwater abundance. We modeled human-related and ecological determinants of harvest (total no. of individuals harvested) of sooty shearwater chicks on 11 islands and examined the relationship between shearwater abundance and harvesting rates (chicks/hr) and harvester behavior throughout the harvesting season. Models best explaining variation in harvest between harvesting areas (manu), for both the early and late parts of the harvesting season, included harvester-days (included in all models with change in deviance information criteria [ΔDIC], ΔDIC < 8.36 and ΔDIC < 11.5, for the early and late periods, respectively). Other harvest determinants included shearwater density, size of the manu, and number of people helping harvesters (all included in the top 5 models within ΔDIC = 2.25 for the late period). Areas harvested by several families under a common-property harvesting system had higher harvest intensity for their size (24% points higher, 95% credible interval 11–36%) than those managed as an exclusive resource for one family. The slowest harvesters spent more time harvesting but on average only harvested 36% (95% credible interval 15–65%) and 34% (95% credible interval 12–63%) of the harvest taken by the fastest harvesters during the early and late periods, respectively. Our results highlight the possibility of elevated harvest intensity as the population of harvesters increases. However, our models suggested that a corresponding reduction in harvesting rate at low prey densities during the most productive period could potentially regulate harvest intensity. Future research will integrate these results into prospective shearwater demographic models to assess the utility of a range of harvesting strategies in ensuring harvest sustainability.     

具空间扩散的时变种群系统的最优捕获控制

讨论了一类时变种群扩散系统的最优捕获控制的非线性问题,证明了最优捕获控制的存在性,并给出了控制u（t,x）∈Uad为最优的必要条件和最优性组．