Raman spectroscopy–based insight into lipid droplets presence and contents in liver sinusoidal endothelial cells and hepatocytes

Liver sinusoidal endothelial cells (LSECs), a type of endothelial cells with unique morphology and function, play an important role in the liver hemostasis, and LSECs dysfunction is involved in the development of nonalcoholic fatty liver disease (NAFLD). Here, we employed Raman imaging and chemometric data analysis in order to characterize the presence of lipid droplets (LDs) and their lipid content in primary murine LSECs, in comparison with hepatocytes, isolated from mice on high‐fat diet. On NAFLD development, LDs content in LSECs changed toward more unsaturated lipids, and this response was associated with an increased expression of stearylo‐CoA desaturase‐1. To the best of our knowledge, this is a first report characterizing LDs in LSECs, where their chemical composition is analyzed along the progression of NAFLD at the level of single LD using Raman imaging.      

Development of a biotic index using stream macroinvertebrates to assess stress from deposited fine sediment

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Crystal Structure of Marburg Virus VP24

The VP24 protein plays an essential, albeit poorly understood role in the filovirus life cycle. VP24 is only 30% identical between Marburg virus and the ebolaviruses. Furthermore, VP24 from the ebolaviruses is immunosuppressive, while that of Marburg virus is not. The crystal structure of Marburg virus VP24, presented here, reveals that although the core is similar between the viral genera, Marburg VP24 is distinguished by a projecting β-shelf and an alternate conformation of the N-terminal polypeptide.     

Ecological Changes in Coyotes (Canis latrans) in Response to the Ice Age Megafaunal Extinctions

Coyotes (Canis latrans) are an important species in human-inhabited areas. They control pests and are the apex predators in many ecosystems. Because of their importance it is imperative to understand how environmental change will affect this species. The end of the Pleistocene Ice Age brought with it many ecological changes for coyotes and here we statistically determine the changes that occurred in coyotes, when these changes occurred, and what the ecological consequences were of these changes. We examined the mandibles of three coyote populations: Pleistocene Rancho La Brean (13–29 Ka), earliest Holocene Rancho La Brean (8–10 Ka), and Recent from North America, using 2D geometric morphometrics to determine the morphological differences among them. Our results show that these three populations were morphologically distinct. The Pleistocene coyotes had an overall robust mandible with an increased shearing arcade and a decreased grinding arcade, adapted for carnivory and killing larger prey; whereas the modern populations show a gracile morphology with a tendency toward omnivory or grinding. The earliest Holocene populations are intermediate in morphology and smallest in size. These findings indicate that a niche shift occurred in coyotes at the Pleistocene/Holocene boundary – from a hunter of large prey to a small prey/more omnivorous animal. Species interactions between Canis were the most likely cause of this transition. This study shows that the Pleistocene extinction event affected species that did not go extinct as well as those that did.     

The effects of global warming on Daphnia spp. population dynamics: a review

Various species of Daphnia usually play a key role in the food web of temperate freshwater systems. There is much evidence to show that climate change may influence Daphnia population dynamics, consequently altering both predator–prey interactions and the efficiency of algal biomass control in these ecosystems. This review will analyse and discuss the current knowledge on Daphnia responses to climate warming based on an analysis of selected papers. The presented results indicate that warming may have important direct and indirect effects on Daphnia biology and ecology via its influence on their life-history processes (metabolism, growth, reproduction) and the properties of their habitats. The plasticity of daphnids in terms of adaptive responses is generally high and includes phenotypic adaptations and changes in genotypes, although it also depends upon the strength of selection and the available genetic variation. The seasonal timing and magnitude of temperature increases are important for seasonal biomass fluctuations of Daphnia and similarly influence the potential synchrony of daphnids and phytoplankton succession (the timing hypothesis). In light of the most recent studies on this topic, even a minor warming during short but critical seasonal periods can cause factors that disturb Daphnia population dynamics to coincide, which may destabilize lake food webs by decoupling trophic interactions. Both winter and spring are important critical periods for determining future seasonal fluxes of Daphnia spp. and, consequently, the time of the clear-water phase and the occurrence and duration of Daphnia midsummer decline. Winter conditions may also affect the impact of fish predation on daphnids during summer months. However, the effects of global warming on Daphnia population dynamics and on ecosystem functioning are often difficult to predict due to their complexity and the presence of both antagonistic and synergistic drivers. Thus, the diverse responses of daphnids to climate anomalies depend on both biotic (predator abundance and seasonal phytoplankton succession) and abiotic factors (e.g. hydrodynamics, intensity and duration of thermal stratification, trophic state or geomorphology) of lakes, which are directly influenced by weather changes. The analysis and quantification of such complex interactions require the involvement of different kinds of specialists and the development of accurate research approaches, such as molecular genetic methods or mathematical modelling.     

Chloroplast biogenesis — Correlation between structure and function

Chloroplast biogenesis is a multistage process leading to fully differentiated and functionally mature plastids. Complex analysis of chloroplast biogenesis was performed on the structural and functional level of its organization during the photoperiodic plant growth after initial growth of seedlings in the darkness. We correlated, at the same time intervals, the structure of etioplasts transforming into mature chloroplasts with the changes in the photosynthetic protein levels (selected core and antenna proteins of PSI and PSII) and with the function of the photosynthetic apparatus in two plant species: bean (Phaseolus vulgaris L.) and pea (Pisum sativum L). We selected these plant species since we demonstrated previously that the mature chloroplasts differ in the thylakoid organization. We showed that the protein biosynthesis as well as photosynthetic complexes formation proceeds gradually in both plants in spite of periods of darkness. We found that both steady structural differentiation of the bean chloroplast and reformation of prolamellar bodies in pea were accompanied by a gradual increase of the photochemical activity in both species. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.     

Different diatoms induce contrasting effects on the reproductive success of the copepod Temora stylifera

Four diatoms, Thalassiosira rotula (THA), Thalassiosira weissflogii (TWEI), Skeletonema costatum (SKE) and Phaeodactylum tricornutum (PHA), and one dinoflagellate Prorocentrum minimum (PRO, control diet), were tested during the course of 14-day laboratory experiments examining the effects of these algae on the fecundity and egg viability in the copepod Temora stylifera. All algae were provided at the same mean carbon concentrations of 0.98 μg C ml⁻¹ to normalize the effects due to differences in diatom size and nutrient concentrations, at least with regards to carbon, so that variations in egg production and hatching viability were presumably due to other chemical constituents of the cells. Our results show that only PRO supported high reproductive success, with stable egg production rates and egg viability close to 100%. By contrast, all four diatoms negatively impacted egg production and hatching success, with varying degrees of suppression. The two diets SKE and PHA induced dramatic effects on reproductive success; SKE was the worst diet with naupliar production ceasing altogether within only 3 days. With PHA, fecundity never reached zero, but at the end of the experiments, initial egg production rates had dropped to 6.6% of initial rates, and viability had declined to zero within 7 days. The two Thalassiosira species mainly affected egg viability, so that after 14 days of feeding, a decrease of 90% had occurred. However, egg production rates were high and were reduced only by 15-24% towards the end of the experiments. In terms of potential recruitment rates, even though PRO induced high mean naupliar production, a slight decrease was observed during the first 5 days, likely due to the time required for T. stylifera to acclimate to PRO. After day 5, potential recruitment rate was higher, comparable to in situ values. THA and TWEI inhibited potential recruitment up to 90-100%, but these effects were not evident over a short-term period, denoting the importance of introducing the time factor when evaluating diatom effects on copepod production. With the other two diatom diets, SKE and PHA, recruitment was zero after 2 and 6 days, respectively. Experiments testing the effects of unsaturated aldehydes in THA (2-trans-4-trans-decadienal) and SKE (2-trans-4-trans-octadienal and 2-trans-4-trans-heptadienal) on the hatching viability of T. stylifera indicate that diatom-derived aldehydes may differ in terms of biological activity. Of the three molecules tested, decadienal had somewhat stronger effects on hatching success, with total blockage occurring at concentrations of 2.0 μg ml⁻¹; the concentrations to induce total blockage by octadienal and heptadienal were somewhat higher and ≥2.5 μg ml⁻¹. We suggest that the greater biological activity of SKE in terms of cell blockage may thus be due to the presence of antimitotic compounds other than these unsaturated aldehydes.     

The Stream Inlet to a Shallow Bay of a Drinking Water Reservoir,a ‘Hot‐Spot’ for Microcystis Blooms Initiation

Stream inlets into shallow bays of reservoirs and lakes may be ‘hot‐spots’ for toxic cyanobacterial bloom initiation. These ‘hot‐spots’ may be connected with the permanent inflow of high nutrient concentrations from the catchment, optimal physical conditions (wind protected areas) that occur in shallow areas and/or ineffective top‐down control. Four sampling sites along a transect from stream to reservoir in a shallow bay of Sulejow Reservoir (Poland) were studied to test the above hypothesis, comprising a transition zone between lotic and pelagic habitats. Investigations showed that stream inlet into shallow bay acted as incubator for Microcystis blooms. The nutrient level, especially phosphorus, was identified as the major cause of cyanobacterial bloom growth. The increase of Microcystis biomass strongly correlated with increasing microcystin concentrations, however, a relationship with microcystin content was not observed. Toxicity of bloom demonstrated seasonal variability, reaching its maximum at the initial phase of bloom. (© 2008 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

The utility of 18F-FDG PET/CT in brain tumours diagnosis

BackgroundThe purpose of the study was to discuss whether 2-deoxy-2-[18F]fluoro-D-glucose positron emission tomography/computed tomography (¹⁸F-FDG PET/CT) study protocol should include brain imaging.Materials and methodsAnalysis of international societies recommendations compared with the original data obtained in over 1000 consecutive torso and brain ¹⁸F-FDG PET/CT studies collected in 2010.ResultsAccording to the international societies recommendations, the ¹⁸F-FDG should not be the radiotracer of choice considering the brain region PET/CT study. However, it can be performed as an additional brain imaging tool. Based on at least a 3-year follow-up, we detected 8 cases of suspicious brain findings and no primary lesion among over 1000 consecutive torso and brain 18F-FDG PET/CT scans performed in 2010. However, in 5 out of 8 patients, the brain lesion was the only metastasis detected, affecting further therapy.ConclusionsThe ¹⁸F-FDG PET/CT study may help detect malignant brain lesions and, therefore, including brain region imaging into the study protocol should be considered.