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A model for the description of proton collisions from molecules composed of atoms such as hydrogen, carbon, nitrogen, oxygen and phosphorus (H, C, N, O, P) was recently extended to treat collisions with multiply charged ions with a focus on net ionization. Here we complement the work by focusing on net capture. The ion–atom collisions are computed using the two-center basis generator method. The atomic net capture cross sections are then used to assemble two models for ion–molecule collisions: An independent atom model (IAM) based on the Bragg additivity rule (labeled IAM-AR), and also the so-called pixel-counting method (IAM-PCM) which introduces dependence on the orientation of the molecule during impact. The IAM-PCM leads to significantly reduced capture cross sections relative to IAM-AR at low energies, since it takes into account the overlap of effective atomic cross sectional areas. We compare our results with available experimental and other theoretical data focusing on water vapor (H2O), methane (CH4) and uracil (C4H4N2O2). For the water molecule target we also provide results from a classical-trajectory Monte Carlo approach that includes dynamical screening effects on projectile and target. For small molecules dominated by a many-electron atom, such as carbon in methane or oxygen in water, we find a saturation phenomenon for higher projectile charges (q=3) and low energies, where the net capture cross section for the molecule is dominated by the net cross section for the many-electron atom, and the net capture cross section is not proportional to the total number of valence electrons.
An important measure in pain research is the intensity of nociceptive stimuli and their cortical representation. However, there is evidence of different cerebral representations of nociceptive stimuli, including the fact that cortical areas recruited during processing of intranasal nociceptive chemical stimuli included those outside the traditional trigeminal areas. Therefore, the aim of this study was to investigate the major cerebral representations of stimulus intensity associated with intranasal chemical trigeminal stimulation. Trigeminal stimulation was achieved with carbon dioxide presented to the nasal mucosa. Using a single‐blinded, randomized crossover design, 24 subjects received nociceptive stimuli with two different stimulation paradigms, depending on the just noticeable differences in the stimulus strengths applied. Stimulus‐related brain activations were recorded using functional magnetic resonance imaging with event‐related design. Brain activations increased significantly with increasing stimulus intensity, with the largest cluster at the right Rolandic operculum and a global maximum in a smaller cluster at the left lower frontal orbital lobe. Region of interest analyses additionally supported an activation pattern correlated with the stimulus intensity at the piriform cortex as an area of special interest with the trigeminal input. The results support the piriform cortex, in addition to the secondary somatosensory cortex, as a major area of interest for stimulus strength‐related brain activation in pain models using trigeminal stimuli. This makes both areas a primary objective to be observed in human experimental pain settings where trigeminal input is used to study effects of analgesics.
Background: Enhancers play a fundamental role in orchestrating cell state and development. Although several methods have been developed to identify enhancers, linking them to their target genes is still an open problem. Several theories have been proposed on the functional mechanisms of enhancers, which triggered the development of various methods to infer promoter–enhancer interactions (PEIs). The advancement of high-throughput techniques describing the three-dimensional organization of the chromatin, paved the way to pinpoint long-range PEIs. Here we investigated whether including PEIs in computational models for the prediction of gene expression improves performance and interpretability.
Results: We have extended our TEPIC framework to include DNA contacts deduced from chromatin conformation capture experiments and compared various methods to determine PEIs using predictive modelling of gene expression from chromatin accessibility data and predicted transcription factor (TF) motif data. We designed a novel machine learning approach that allows the prioritization of TFs binding to distal loop and promoter regions with respect to their importance for gene expression regulation. Our analysis revealed a set of core TFs that are part of enhancer–promoter loops involving YY1 in different cell lines.
Conclusion: We present a novel approach that can be used to prioritize TFs involved in distal and promoter-proximal regulatory events by integrating chromatin accessibility, conformation, and gene expression data. We show that the integration of chromatin conformation data can improve gene expression prediction and aids model interpretability.
The aging process is characterized by a chronic, low‐grade inflammatory state, termed “inflammaging.” It has been suggested that macrophage activation plays a key role in the induction and maintenance of this state. In the present study, we aimed to elucidate the mechanisms responsible for aging‐associated changes in the myeloid compartment of mice. The aging phenotype, characterized by elevated cytokine production, was associated with a dysfunction of the hypothalamic–pituitary–adrenal (HPA) axis and diminished serum corticosteroid levels. In particular, the concentration of corticosterone, the major active glucocorticoid in rodents, was decreased. This could be explained by an impaired expression and activity of 11β‐hydroxysteroid dehydrogenase type 1 (11β‐HSD1), an enzyme that determines the extent of cellular glucocorticoid responses by reducing the corticosteroids cortisone/11‐dehydrocorticosterone to their active forms cortisol/corticosterone, in aged macrophages and peripheral leukocytes. These changes were accompanied by a downregulation of the glucocorticoid receptor target gene glucocorticoid‐induced leucine zipper (GILZ) in vitro and in vivo. Since GILZ plays a central role in macrophage activation, we hypothesized that the loss of GILZ contributed to the process of macroph‐aging. The phenotype of macrophages from aged mice was indeed mimicked in young GILZ knockout mice. In summary, the current study provides insight into the role of glucocorticoid metabolism and GILZ regulation during aging.
Acetogenic bacteria have gained much attraction in recent years as they can produce different biofuels and biochemicals from H2 plus CO2 or even CO alone, therefore opening a promising alternative route for the production of biofuels from renewable sources compared to existing sugar‐based routes. However, CO metabolism still raises questions concerning the biochemistry and bioenergetics in many acetogens. In this study, we focused on the two acetogenic bacteria Acetobacterium woodii and Thermoanaerobacter kivui which, so far, are the only identified acetogens harbouring a H2‐dependent CO2 reductase and furthermore belong to different classes of ‘Rnf’‐ and ‘Ech‐acetogens’. Both strains catalysed the conversion of CO into the bulk chemical acetate and formate. Formate production was stimulated by uncoupling the energy metabolism from the Wood–Ljungdahl pathway, and specific rates of 1.44 and 1.34 mmol g−1 h−1 for A. woodii ∆rnf and T. kivui wild type were reached. The demonstrated CO‐based formate production rates are, to the best of our knowledge, among the highest rates ever reported. Using mutants of ∆hdcr, ∆cooS, ∆hydBA, ∆rnf and ∆ech2 with deficiencies in key enzyme activities of the central metabolism enabled us to postulate two different CO utilization pathways in these two model organisms.
Precipitation extremes with devastating socioeconomic consequences within the South American Monsoon System (SAMS) are expected to become more frequent in the near future. The complexity in SAMS behavior, however, poses severe challenges for reliable future projections. Thus, robust paleomonsoon records are needed to constrain the high spatiotemporal variability in the response of SAMS rainfall to different climatic drivers. This study uses Ti/Ca ratios from X‐ray fluorescence scanning of a sediment core retrieved off eastern Brazilian to trace precipitation changes over the past 322 Kyr. The results indicate that despite the spatiotemporal complexity of the SAMS, insolation forcing is the primary pacemaker of variations in the monsoonal system. Additional modulation by atmospheric pCO2 suggests that SAMS intensity over eastern Brazil will be suppressed by rising CO2 emissions in the future. Lastly, our record reveals an unprecedented strong and persistent wet period during Marine Isotope Stage 6 driven by anomalously strong trade winds.
CO2 has been electrochemically reduced to the intermediate formate, which was subsequently used as sole substrate for the production of the polymer polyhydroxybutyrate (PHB) by the microorganism Cupriavidus necator. Faradaic efficiencies (FE) up to 54 % have been reached with Sn‐based gas‐diffusion electrodes in physiological electrolyte. The formate containing electrolyte can be used directly as drop‐in solution in the following biological polymer production by resting cells. 56 mg PHB L−1 and a ratio of 34 % PHB per cell dry weight were achieved. The calculated overall FE for the process was as high as 4 %. The direct use of the electrolyte as drop‐in media in the bioconversion enables simplified processes with a minimum of intermediate purification effort. Thus, an optimal coupling between electrochemical and biotechnological processes can be realized.
Investigating the inhibition of anti-apoptotic BCL-2 family proteins in pediatric cancer cells
(2020)
Cancer is amongst the leading causes of death in childhood. Rhabdomyosarcoma (RMS) is the most frequently occurring soft tissue sarcoma in children and adolescents. It presumably arises from mesenchymal progenitors of skeletal muscle cells and presents with different subtypes that differ both histologically and genetically. Osteosarcoma (OS) and Ewing sarcoma (ES) are the most frequently diagnosed pediatric bone tumors. Even though the prognosis of these cancer entities improved significantly during recent decades, the survival rates are currently stagnating. Especially, dismal prognosis of relapsed and metastasizing cases of these malignancies urgently call for novel treatment options. BCL-2 proteins are vital guardians that control intrinsic apoptosis. Furthermore, it was shown that BCL-2 proteins critically regulate apoptosis in pediatric solid tumors. BH3 mimetics are small molecules that bind and inhibit anti-apoptotic BCL-2 proteins. They have already been investigated as cancer therapeutics for several years and show first encouraging clinical results. Therefore, we hypothesized that targeting BCL-2, MCL-1 and BCL-XL might be a promising approach to treat RMS, OS and ES.
In this study, we aimed to comprehensively evaluate the potential of anti-apoptotic BCL-2 family proteins as therapeutic targets for pediatric solid tumors such as RMS, OS and ES.
Notably, RMS, OS and ES cells largely expressed the most relevant BCL-2 family protein members. However, cells were widely insensitive to single pharmacological inhibition of either BCL-XL, BCL-2 or MCL-1 by A-1331852, ABT-199 and S63845, respectively. This finding was independent of their BCL-2 family protein expression levels. Significantly, co-administration of A-1331852 and S63845 induced cell death in RMS, OS and ES cell lines in a highly synergistic manner. Transient silencing of MCL-1 and/or BCL-XL verified the co-dependency of RMS cells on these proteins for survival. Importantly, A-1331852/S63845 co-treatment was more efficient in causing cell death in RMS, OS and ES cells than either inhibitor combined with ABT-199. Efficacy of A-1331852/S63845 co-treatment could be additionally demonstrated in a primary sample of pediatric malignant epithelioid mesothelioma.
Mechanistically, concomitant A-1331852/S63845 treatment mediated rapid intrinsic apoptosis involving swift loss of the mitochondrial outer membrane potential as well as activation of caspases-3, -8 and -9. An observed caspase dependent loss of MCL-1 might further amplify the A-1331852/S63845 triggered pro-death signaling. Furthermore, we identified BAX and BAK as key mediators of apoptosis caused by dual inhibition of MCL-1 and BCL-XL. A-1331852/S63845 induced cell death was relying on BAX and/or BAK in a cell line dependent manner. Interestingly, treatment with A-1331852 and S63845 liberated BAK from its interaction with MCL-1 and BCL-XL. Moreover, BAX and BAK were activated and interacted with each other to form a pore in the outer mitochondrial membrane. Further, in RD cells BIM and NOXA partially contributed to A-1331852/S63845 mediated cell death. Consistently, in this cell line BIM and NOXA were disrupted from their binding to BCL-XL and MCL-1 by A-1331852 and S63845, respectively. However, BH3 only proteins were not involved in A-1331852/S63845 induced cell death in Kym-1 cells. Therefore, we concluded that BH3 only proteins played only a marginal and cell line dependent role in mediating cell death caused by MCL-1 and BCL-XL co-repression.
Notably, A-1331852/S63845 co-treatment spared non-malignant fibroblasts, myoblasts and peripheral blood mononuclear cells, which suggests a therapeutic window for its application in vivo. Besides, we could demonstrate that sequential BH3 mimetic treatment still significantly induced cell death, albeit to minor extents compared to its dual administration. Importantly, we successfully evaluated concomitant treatment with A-1331852 and S63845 in multicellular RMS spheroids and in an in vivo embryonic chicken model of RMS. These findings stress the high transcriptional relevance of A-1331852/S63845 as an emerging novel cancer regimen.
Collectively, the thesis at hand explored the great potential of co-treatment with A-1331852 and S63845 in pediatric solid tumors and unveiled the underlying molecular mechanisms of cell death in RMS. Together, the current investigations support further preclinical and clinical studies to evaluate the effect of dual MCL-1 and BCL-XL targeting in pediatric solid tumors.