The making of a chloroplast

Since its endosymbiotic beginning, the chloroplast has become fully integrated into the biology of the host eukaryotic cell. The exchange of genetic information from the chloroplast to the nucleus has resulted in considerable co-ordination in the activities of these two organelles during all stages of plant development. Here, we give an overview of the mechanisms of light perception and the subsequent regulation of nuclear gene expression in the model plant Arabidopsis thaliana, and we cover the main events that take place when proplastids differentiate into chloroplasts. We also consider recent findings regarding signalling networks between the chloroplast and the nucleus during seedling development, and how these signals are modulated by light. In addition, we discuss the mechanisms through which chloroplasts develop in different cell types, namely cotyledons and the dimorphic chloroplasts of the C4 plant maize. Finally, we discuss recent data that suggest the specific regulation of the light-dependent phases of photosynthesis, providing a means to optimize photosynthesis to varying light regimes

Plastid tubules in higher plants: an analysis of form and function

Besides photosynthesis, plastids are responsible for starch storage, fatty acid biosynthesis and nitrate metabolism. Our understanding of plastids can be improved with observation by microscopy, but this has been hampered by the invisibility of many plastid types. By targeting green fluorescent protein (GFP) to the plastid in transgenic plants, the visualisation of plastids has become routinely possible. Using GFP, motile, tubular protrusions can be observed to emanate from the plastid envelope into the surrounding cytoplasm. These structures, called stromules, vary considerably in frequency and length between different plastid types, but their function is poorly understood. During tomato fruit ripening, chloroplasts in the pericarp cells differentiate into chromoplasts. As chlorophyll degrades and carotenoids accumulate, plastid and stromule morphology change dramatically. Stromules become significantly more abundant upon chromoplast differentiation, but only in one cell type where plastids are large and sparsely distributed within the cell. Ectopic chloroplast components inhibit stromule formation, whereas preventing chloroplast development leads to increased numbers of stromules. Together, these findings imply that stromule function is closely related to the differentiation status, and thus role, of the plastid in question. In tobacco seedlings, stromules in hypocotyl epidermal cells become longer as plastids become more widely distributed within the cell, implying a plastid density-dependent regulation of stromules. Co-expression of fluorescent proteins targeted to plastids, mitochondria and peroxisomes revealed a close spatio-temporal relationship between stromules and other organelles. Stromule and plastid fusion could not be induced under conditions which promote substantial fusion of mitochondria. Data are presented suggesting that organelles may be able to pass between cells, and an experiment was designed to test this possibility in the C4 photosynthetic cells of maize. Inhibitor studies have shown that stromule and plastid movement is dependent on the actin cytoskeleton and the ATPase activity of myosin. An Arabidopsis gene, CHUP1, is responsible for chloroplast relocation in response to light intensity and encodes a chloroplast-localised actin-binding protein. To assess whether this protein is involved in stromule movement, CHUP1 was down-regulated with RNAi. Whilst plants with reduced CHUP1 expression exhibited a chup1 mutant phenotype, no significant effect on stromules was discovered. It was thus concluded that chloroplast relocation and stromule formation are two independent processes that employ different actin-dependent mechanisms. It is proposed that stromules act primarily to increase the plastid surface area in response to a number of developmental and environmental factors

Plastid tubules in higher plants: an analysis of form and function

Besides photosynthesis, plastids are responsible for starch storage, fatty acid biosynthesis and nitrate metabolism. Our understanding of plastids can be improved with observation by microscopy, but this has been hampered by the invisibility of many plastid types. By targeting green fluorescent protein (GFP) to the plastid in transgenic plants, the visualisation of plastids has become routinely possible. Using GFP, motile, tubular protrusions can be observed to emanate from the plastid envelope into the surrounding cytoplasm. These structures, called stromules, vary considerably in frequency and length between different plastid types, but their function is poorly understood. During tomato fruit ripening, chloroplasts in the pericarp cells differentiate into chromoplasts. As chlorophyll degrades and carotenoids accumulate, plastid and stromule morphology change dramatically. Stromules become significantly more abundant upon chromoplast differentiation, but only in one cell type where plastids are large and sparsely distributed within the cell. Ectopic chloroplast components inhibit stromule formation, whereas preventing chloroplast development leads to increased numbers of stromules. Together, these findings imply that stromule function is closely related to the differentiation status, and thus role, of the plastid in question. In tobacco seedlings, stromules in hypocotyl epidermal cells become longer as plastids become more widely distributed within the cell, implying a plastid density-dependent regulation of stromules. Co-expression of fluorescent proteins targeted to plastids, mitochondria and peroxisomes revealed a close spatio-temporal relationship between stromules and other organelles. Stromule and plastid fusion could not be induced under conditions which promote substantial fusion of mitochondria. Data are presented suggesting that organelles may be able to pass between cells, and an experiment was designed to test this possibility in the C4 photosynthetic cells of maize. Inhibitor studies have shown that stromule and plastid movement is dependent on the actin cytoskeleton and the ATPase activity of myosin. An Arabidopsis gene, CHUP1, is responsible for chloroplast relocation in response to light intensity and encodes a chloroplast-localised actin-binding protein. To assess whether this protein is involved in stromule movement, CHUP1 was down-regulated with RNAi. Whilst plants with reduced CHUP1 expression exhibited a chup1 mutant phenotype, no significant effect on stromules was discovered. It was thus concluded that chloroplast relocation and stromule formation are two independent processes that employ different actin-dependent mechanisms. It is proposed that stromules act primarily to increase the plastid surface area in response to a number of developmental and environmental factors

Monanchocidin A From Subarctic Sponges of the Genus Monanchora and Their Promising Selectivity Against Melanoma in vitro

© Copyright © 2020 Gogineni, Oh, Waters, Kelly, Stone and Hamann. Marine sources have long been known for their potential to produce unique skeletons and various biological activities. Fractionation of the ethanol extracts of an undescribed species of Monanchora Carter, 1883 and a specimen closely comparable to Monanchora pulchra (Lambe, 1894/1895) (Class Demospongiae, Order Poecilosclerida, Family Crambeidae), yielded a known compound, monanchocidin A. Monanchocidin A, a secondary metabolite, showed very modest antibacterial, antifungal, and antiprotozoal activities with IC50 values ranging between 255.75 and 7288.92 μM. Monanchocidin A also exhibited potent selective activity for the melanoma panel in the NCI cancer cell screening panel

Digital Image Correlation Data Processing and Analysis Techniques to Enhance Test Data Assessment and Improve Structural Simulations

The NASA Shell Buckling Knockdown Factor Project (SBKF) was established in 2007 by the NASA Engineering and Safety Center (NESC) with the primary goal to develop new analysis-based buckling design factors (a.k.a. knockdown factors) and high-fidelity buckling simulations for selected launch-vehicle-like cylindrical shell structures. A series of tests are being conducted on large-scale metallic and composite cylindrical shells in order to provide validation data for these new factors and simulations. However, the validation of these new factors and simulations is quite demanding and requires test data that is commensurate with their fidelity. Traditional instrumentation, such as linear variable displacement transducers (LVDTs) and electrical-resistance strain gages serve a critical role in providing accurate displacement and strain measurements in these tests, but only allow for data to be recorded at a select number of point locations and are not sufficient to provide all the necessary validation data. Advanced measurement technologies can be used effectively to complement traditional instrumentation and gather additional data required to validate these structural simulations. In particular, three-dimensional digital image correlation (DIC) was implemented during SBKF cylinder testing to characterize the full-field displacement and strain behavior. Commercially available VIC-3DTM software and user-written data processing scripts were used to generate valuable data and insight into the complex buckling response of the cylinders that otherwise would be impossible to gather using traditional instrumentation. In addition, the measured data from DIC was used to verify measured test data obtained from other instrumentation, enhance test and analysis correlation, and help identify the root cause of anomalous test results that may have gone unexplained if only traditional instrumentation was used. Selected test results that demonstrate the use of DIC on the SBKF cylinders are presented and a portion of the data processing methods are described

Compressed gas domestic aerosol valve design using high viscous product

Most of the current universal consumer aerosol products using high viscous product such as cooking oil, antiperspirants, hair removal cream are primarily used LPG (Liquefied Petroleum Gas) propellant which is unfriendly environmental. The advantages of the new innovative technology described in this paper are: i. No butane or other liquefied hydrocarbon gas is used as a propellant and it replaced with Compressed air, nitrogen or other safe gas propellant. ii. Customer acceptable spray quality and consistency during can lifetime iii. Conventional cans and filling technology There is only a feasible energy source which is inert gas (i.e. compressed air) to replace VOCs (Volatile Organic Compounds) and greenhouse gases, which must be avoided, to improve atomisation by generating gas bubbles and turbulence inside the atomiser insert and the actuator. This research concentrates on using “bubbly flow” in the valve stem, with injection of compressed gas into the passing flow, thus also generating turbulence. The new valve designed in this investigation using inert gases has advantageous over conventional valve with butane propellant using high viscous product (> 400 Cp) because, when the valving arrangement is fully open, there are negligible energy losses as fluid passes through the valve from the interior of the container to the actuator insert. The use of valving arrangement thus permits all pressure drops to be controlled, resulting in improved control of atomising efficiency and flow rate, whereas in conventional valves a significant pressure drops occurs through the valve which has a complex effect on the corresponding spray

Buckling Test Results from the 8-Foot-Diameter Orthogrid-Stiffened Cylinder Test Article TA01

Results from the testing of cylinder test article SBKF-P2-CYLTA01 (referred to herein as TA01) are presented. The testing was conducted at the Marshall Space Flight Center (MSFC), November 1921, 2008, in support of the Shell Buckling Knockdown Factor (SBKF) Project.i The test was used to verify the performance of a newly constructed buckling test facility at MSFC and to verify the test article design and analysis approach used by the SBKF project researchers. TA01 is an 8-foot-diameter (96-inches), 78.0-inch long, aluminum-lithium (Al-Li), orthogrid-stiffened cylindrical shell similar to those used in current state-of-the-art launch vehicle structures and was designed to exhibit global buckling when subjected to compression loads. Five different load sequences were applied to TA01 during testing and included four sub-critical load sequences, i.e., loading conditions that did not cause buckling or material failure, and one final load sequence to buckling and collapse. The sub-critical load sequences consisted of either uniform axial compression loading or combined axial compression and bending and the final load sequence subjected TA01 to uniform axial compression. Traditional displacement transducers and strain gages were used to monitor the test article response at nearly 300 locations and an advanced digital image correlation system was used to obtain low-speed and high-speed full-field displacement measurements of the outer surface of the test article. Overall, the test facility and test article performed as designed. In particular, the test facility successfully applied all desired load combinations to the test article and was able to test safely into the postbuckling range of loading, and the test article failed by global buckling. In addition, the test results correlated well with initial pretest predictions

OPA1 deficiency accelerates hippocampal synaptic remodelling and age-related deficits in learning and memory

A healthy mitochondrial network is essential for the maintenance of neuronal synaptic integrity. Mitochondrial and metabolic dysfunction contributes to the pathogenesis of many neurodegenerative diseases including dementia. OPA1 is the master regulator of mitochondrial fusion and fission and is likely to play an important role during neurodegenerative events. To explore this, we quantified hippocampal dendritic and synaptic integrity and the learning and memory performance of aged Opa1 haploinsufficient mice carrying the Opa1Q285X mutation (B6; C3-Opa1Q285STOP; Opa1+/−). We demonstrate that heterozygous loss of Opa1 results in premature age-related loss of spines in hippocampal pyramidal CA1 neurons and a reduction in synaptic density in the hippocampus. This loss is associated with subtle memory deficits in both spatial novelty and object recognition. We hypothesize that metabolic failure to maintain normal neuronal activity at the level of a single spine leads to premature age-related memory deficits. These results highlight the importance of mitochondrial homeostasis for maintenance of neuronal function during ageing

Sharpea and Kandleria are lactic acid producing rumen bacteria that do not change their fermentation products when co-cultured with a methanogen

peer-reviewedSharpea and Kandleria are associated with rumen samples from low-methane-emitting sheep. Four strains of each genus were studied in culture, and the genomes of nine strains were analysed, to understand the physiology of these bacteria. All eight cultures grew equally well with d-glucose, d-fructose, d-galactose, cellobiose, and sucrose supplementation. d-Lactate was the major end product, with small amounts of the mixed acid fermentation products formate, acetate and ethanol. Genes encoding the enzymes necessary for this fermentation pattern were found in the genomes of four strains of Sharpea and five of Kandleria. Strains of Sharpea produced traces of hydrogen gas in pure culture, but strains of Kandleria did not. This was consistent with finding that Sharpea, but not Kandleria, genomes contained genes coding for hydrogenases. It was speculated that, in co-culture with a methanogen, Sharpea and Kandleria might change their fermentation pattern from a predominately homolactic to a predominately mixed acid fermentation, which would result in a decrease in lactate production and an increase in formation of acetate and perhaps ethanol. However, Sharpea and Kandleria did not change their fermentation products when co-cultured with Methanobrevibacter olleyae, a methanogen that can use both hydrogen and formate, and lactate remained the major end product. The results of this study therefore support a hypothesis that explains the link between lower methane yields and larger populations of Sharpea and Kandleria in the rumens of sheep

Access to primary percutaneous coronary intervention for ST-segment elevation myocardial infarction in Canada: a geographic analysis

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