Representasi Maskulinitas dan Budaya Populer dalam Iklan Pond’s Men

Iklan adalah sebuah informasi mengenai produk atau jasa yang dapat ditemukan di berbagai media, seperti media televisi, medial sosial, media cetak, dll. Penelitian tentang iklan Pond’s Men yang dibintangi oleh Rio Dewanto ini bertujuan untuk mengatahui makna denotasi, konotasi, mitos dalam iklan tersebut. Penelitian ini menggunakan metode analisis semiotika Roland Barthes. Hasil dari penelitian ini ialah di dalam iklan Pond’s Men Energy Charge laki-laki ditampilkan dalam representasi yang produktf, peduli akan kebersihan wajah, dan percaya diri ialah ciri khas pria yang maskulin.

Physiological and Molecular Responses in the Gill of the Swimming Crab Portunus trituberculatus During Long-Term Ammonia Stress

Ammonia is a common environmental stressor encountered during aquaculture, and is a significant concern due to its adverse biological effects on vertebrate and invertebrate including crustaceans. However, little information is available on physiological and molecular responses in crustaceans under long-term ammonia exposure, which often occurs in aquaculture practices. Here, we investigated temporal physiological and molecular responses in the gills, the main ammonia excretion organ, of the swimming crab Portunus trituberculatus following long-term (4 weeks) exposure to three different ammonia nitrogen concentrations (2, 4, and 8 mg l–1), in comparison to seawater (ammonia nitrogen below 0.03 mg l–1). The results revealed that after ammonia stress, the ammonia excretion and detoxification pathways were initially up-regulated. These processes appear compromised as the exposure duration extended, leading to accumulation of hemolymph ammonia, which coincided with the reduction of adenosine 5′-triphosphate (ATP) and adenylate energy charge (AEC). Considering that ammonia excretion and detoxification are highly energy-consuming, the depression of these pathways are, at least partly, associated with disruption of energy homeostasis in gills after prolonged ammonia exposure. Furthermore, our results indicated that long-term ammonia exposure can impair the antioxidant defense and result in increased lipid peroxidation, as well as induce endoplasmic reticulum stress, which in turn lead to apoptosis through p53-bax pathway in gills of the swimming crab. The findings of the present study further our understanding of adverse effects and underlying mechanisms of long-term ammonia in decapods, and provide valuable information for aquaculture management of P. trituberculatus.

The effect of blood cells retained in rat livers during static cold storage on viability outcomes during normothermic machine perfusion

In transplantation, livers are transported to recipients using static cold storage (SCS), whereby livers are exposed to cold ischemic injury that contribute to post-transplant risk factors. We hypothesized that flushing organs during procurement with cold preservation solutions could influence the number of donor blood cells retained in the allograft thereby exacerbating cold ischemic injury. We present the results of rat livers that underwent 24 h SCS after being flushed with a cold University of Wisconsin (UW) solution versus room temperature (RT) lactated ringers (LR) solution. These results were compared to livers that were not flushed prior to SCS and thoroughly flushed livers without SCS. We used viability and injury metrics collected during normothermic machine perfusion (NMP) and the number of retained peripheral cells (RPCs) measured by histology to compare outcomes. Compared to the cold UW flush group, livers flushed with RT LR had lower resistance, lactate, AST, and ALT at 6 h of NMP. The number of RPCs also had significant positive correlations with resistance, lactate, and potassium levels and a negative correlation with energy charge. In conclusion, livers exposed to cold UW flush prior to SCS appear to perform worse during NMP, compared to RT LR flush.

Acclimations to Cold and Warm Conditions Differently Affect the Energy Metabolism of Diapausing Larvae of the European Corn Borer Ostrinia nubilalis (Hbn.)

The European corn borer Ostrinia nubilalis is a pest species, whose fifth instar larvae gradually develop cold hardiness during diapause. The physiological changes underlying diapause progression and cold hardiness development are still insufficiently understood in insects. Here, we follow a complex of changes related to energy metabolism during cold acclimation (5°C) of diapausing larvae and compare this to warm-acclimated (22°C) and non-diapause controls. Capillary electrophoresis of nucleotides and coenzymes has shown that in gradually cold-acclimated groups concentrations of ATP/ADP and, consequently, energy charge slowly decrease during diapause, while the concentration of AMP increases, especially in the first months of diapause. Also, the activity of cytochrome c oxidase (COX), as well as the concentrations of NAD+ and GMP, decline in cold-acclimated groups, until the latter part of diapause, when they recover. Relative expression of NADH dehydrogenase (nd1), coenzyme Q-cytochrome c reductase (uqcr), COX, ATP synthase (atp), ADP/ATP translocase (ant), and prohibitin 2 (phb2) is supressed in cold-acclimated larvae during the first months of diapause and gradually increases toward the termination of diapause. Contrary to this, NADP+ and UMP levels significantly increased in the first few months of diapause, after gradual cold acclimation, which is in connection with the biosynthesis of cryoprotective molecules, as well as regeneration of small antioxidants. Our findings evidence the existence of a cold-induced energy-saving program that facilitates long-term maintenance of larval diapause, as well as gradual development of cold hardiness. In contrast, warm acclimation induced faster depletion of ATP, ADP, UMP, NAD+, and NADP+, as well as higher activity of COX and generally higher expression of all energy-related genes in comparison to cold-acclimated larvae. Moreover, such unusually high metabolic activity, driven by high temperatures, lead to premature mortality in the warm-acclimated group after 2 months of diapause. Thus, our findings strongly support the importance of low temperature exposure in early diapause for gradual cold hardiness acquisition, successful maintenance of the resting state and return to active development. Moreover, they demonstrate potentially adverse effects of global climate changes and subsequent increase in winter temperatures on cold-adapted terrestrial organisms in temperate and subpolar regions.

Spatial Probabilistic Mapping of Metabolite Ensembles in Mass Spectrometry Imaging

Mass spectrometry imaging (MSI) vows to enable simultaneous spatially-resolved investigation of hundreds of metabolites in tissue sections, but it still relies on poorly defined ion images for data interpretation. Here, we outline moleculaR, a computational framework in R, that introduces systematic probabilistic mapping and point-for-point statistical testing of metabolites in tissue to MSI. Beyond statistics, moleculaR allows for arithmetic operations within the same MS image and thereby, for instance, analysis and visualization of complex scores like the adenylate energy charge ([ATP]+0.5*[ADP])/ ([ATP]+[ADP]+[AMP]). moleculaR also enables collective molecular projections, for example of all potassium versus all sodium adducts for spatially-resolved investigation of ion milieus, or for surveys of lipid pathways or other user-defined biomolecular ensembles.

Quantum Study of Symmetrical/asymmetrical Chare/Energy Transfer in a Simple Candidate Molecular Switch

Based on molecular nanoelectronic knowledge, field-effect molecular electronic devices can be designed for use in nano-circuits. Therefore, in this study, a candidate field-effect molecular switch (isolated, M, and non-isolated, Au-M-Au/Au4-M-Au4, molecular systems) is studied, using density function/pseudopotential model (DFT/LANL2DZ). This molecular switch's switching mechanism (ON/OFF) we performed by applying an external electric field-effect. In this regard, some computational studies related to this molecular switch's electronic/vibrational transfer properties were investigated. Also, used from the quantum theory of atoms in the molecule (QTAIM), Landauer's theory (LT), and energy/charge transfer mechanisms were used at the atomic scale to predict this molecular switch's voltage-current (IV) behavior. Analysis of these results showed that when the intensity of the applied electric field increases to 0.008 au, the molecular switch is in the ON state. In addition, the role of gold electrodes on some of the electronic/vibrational properties of this molecular switch was investigated. Analysis of the results showed that gold electrodes play an essential role in the local distribution of charge and intramolecular energy and, consequently, the I/V diagram of this molecular switch. It is expected that such quantum-based research (without using numerical methods such as Green's function methods) could open new horizons in the quantum study of molecular parts at the atomic-intramolecular scale.

Transcriptional and Metabolic Profiling of Nicotinamide-Enhanced Natural Killer (NAM-NK) Cells (GDA-201)

Adoptive transfer of NK cells is a promising immunotherapeutic modality, however limited NK cell persistence and proliferation in vivo have historically been barriers to clinical success. Nicotinamide (NAM), an allosteric inhibitor of NAD-dependent enzymes, has been shown to preserve cell function and prevent differentiation in ex vivo culture of NK (NAM-NK) and other cells. Clinical responses were observed in a Phase 1 trial of NAM-NK (GDA-201) in patients with refractory non-Hodgkin lymphoma (Bachanova, et. al., Blood 134:777, 2019). We now use transcriptional and metabolic profiling to characterize the mechanisms underlying the activity of NAM-NK. CD3 negative lymphocytes obtained from healthy donors were cultured for 14 days with IL-15 in the presence or absence of NAM (7 mM). Next generation sequencing (NGS), liquid chromatography-mass spectrometry (LC-MS)-based metabolite quantification, and glycolytic/mitochondrial respiration measurements were performed. Transcriptome and pathway enrichment analyses were performed with Ingenuity Pathway Analysis software. Extracted cellular and medium metabolites were analyzed on a Thermo Q-Exactive Plus mass spectrometer coupled with a Vanquish UHPLC system. Extracellular acidification (ECAR) and oxygen consumption rates (OCR) were quantified using a Seahorse Extracellular Flux Analyzer. Glycolysis/citric acid cycle (TCA) rates were measured using isotope-labelled glucose incorporation assays. Transcriptome analyses defined 1,204 differentially expressed (DE) genes in NAM-NK vs. control NK. Biological/functional enrichment and pathway analyses of DE-genes predicted upregulation of cell cycle, DNA replication (CDK4/CDKN2D, CyclinD/E, MAD2L), RNA transcription, translation (SMN1/2, ABCF1, EIF4B, RPL13, RPS6), protein synthesis (EIF2, PABPC1, SOS, 60S complex) mitochondrial energy metabolism (NDUFB8, ATP5G2/E, COX7B/C) migration, homing (CD62L, CD44, DNAM1), and cytokine/chemokine response (IL18R, CXCR3, CCR5, XCL1, SOCS3, LFA1) pathways, with concomitant downregulation of cell exhaustion, senescence (BATF1, FOXP1, STAT1, CD86, LGALS9, LAG3), apoptosis, necrosis (CASP1, MDM2, IKK3), stress response (CALR, HSP90, HSPH1), and lymphoid cellular maturation (IL-2Ra, CD40L, GATA3) pathways in NAM-NK. Metabolomic analyses showed a significant increase of intracellular NAD, NADH, NADP, NADPH, high-energy triphosphates (ATP, UTP, GTP) and overall energy charge ([ATP+0.5*ADP]/[ATP+ADP+AMP]) in NAM-NK. Cellular metabolic fitness analyses revealed increased basal and ATP-linked respiration, mitochondrial maximal respiratory capacity, and glycolytic capacity in NAM-NK compared to control NK. In addition, NAM increased the rate of glucose incorporation into TCA cycle intermediates (acetyl-CoA, succinyl-CoA), consistent with a more rapid glycolysis rate, increased TCA cycling, and improved glucose consumption efficiency. Taken together, results of transcriptome, metabolomic, mitochondrial respiration, and glycolytic rate analyses suggest that NAM pleiotropically modulates key cellular metabolic functions in ex vivo-expanded NK cells, resulting in increased response to cytokine stimulation and enhanced potency. NAM inhibits differentiation, cellular stress, and exhaustion pathways that are typically activated in culture. Moreover, NAM increases cellular metabolic fitness, energy charge, and efficiency of glucose consumption, potentially imparting a protective effect against oxidative stress in the tumor microenvironment. These data offer insight into the mechanism of improved persistence, proliferation, and cytotoxicity observed in in vivo and clinical studies of GDA-201. Disclosures Yackoubov: Gamida Cell: Current Employment. Pato: Gamida Cell: Current Employment. Rifman: Gamida Cell: Current Employment. Cohen: Gamida Cell: Current Employment. Hailu: Gamida Cell: Current Employment. Persi: Gamida Cell: Current Employment. Berhani-Zipori: Gamida Cell: Current Employment. Edri: Gamida Cell: Current Employment. Peled: Biokine Therapeutics Ltd: Current Employment; Gamida Cell: Research Funding. Cichocki: Gamida Cell: Research Funding; Fate Therapeutics, Inc: Patents & Royalties, Research Funding. Rabinowitz: Gamida Cell: Research Funding. Lodie: Gamida Cell: Current holder of stock options in a privately-held company, Ended employment in the past 24 months. Adams: Gamida Cell: Current Employment. Simantov: Gamida Cell: Current Employment. Geffen: Gamida Cell: Current Employment.

An Explanation Based on Energy-Related Changes for Blue Mussel Mytilus edulis Coping With Seawater Acidification

As ocean acidification (OA) is gradually increasing, concerns regarding its ecological impacts on marine organisms are growing. Our previous studies have shown that seawater acidification exerted adverse effects on physiological processes of the blue mussel Mytilus edulis, and the aim of the present study was to obtain energy-related evidence to verify and explain our previous findings. Thus, the same acidification system (pH: 7.7 or 7.1; acidification method: HCl addition or CO2 enrichment; experimental period: 21d) was set up, and the energy-related changes were assessed. The results showed that the energy charge (EC) and the gene expressions of cytochrome C oxidase (COX) reflecting the ATP synthesis rate increased significantly after acidification treatments. What’s more, the mussels exposed to acidification allocated more energy to gills and hemocytes. However, the total adenylate pool (TAP) and the final adenosine triphosphate (ATP) in M. edulis decreased significantly, especially in CO2 treatment group at pH 7.1. It was interesting to note that, TAP, ATP, and COXs gene expressions in CO2 treatment groups were all significantly lower than that in HCl treatment groups at the same pH, verifying that CO2-induced acidification exhibited more deleterious impacts on M. edulis, and ions besides H+ produced by CO2 dissolution were possible causes. In conclusion, energy-related changes in M. edulis responded actively to seawater acidification and varied with different acidification conditions, while the constraints they had at higher acidification levels suggest that M. edulis will have a limited tolerance to increasing OA in the future.