Methane emissions from the Nord Stream subsea pipeline leaks.

The amount of methane released to the atmosphere from the Nord Stream subsea pipeline leaks remains uncertain, as reflected in a wide range of estimates. A lack of information regarding the temporal variation in atmospheric emissions has made it challenging to reconcile pipeline volumetric (bottom-up) estimates with measurement-based (top-down) estimates. Here we simulate pipeline rupture emission rates and integrate these with methane dissolution and sea-surface outgassing estimates to model the evolution of atmospheric emissions from the leaks.

Subcellular Localization and Mitotic Interactome Analyses Identify SIRT4 as a Centrosomally Localized and Microtubule Associated Protein.

The stress-inducible and senescence-associated tumor suppressor SIRT4, a member of the family of mitochondrial sirtuins (SIRT3, SIRT4, and SIRT5), regulates bioenergetics and metabolism via NAD-dependent enzymatic activities. Next to the known mitochondrial location, we found that a fraction of endogenous or ectopically expressed SIRT4, but not SIRT3, is present in the cytosol and predominantly localizes to centrosomes. Confocal spinning disk microscopy revealed that SIRT4 is found during the cell cycle dynamically at centrosomes with an intensity peak in G and early mitosis.

Translational Imaging Spectroscopy for Proximal Sensing.

Proximal sensing as the near field counterpart of remote sensing offers a broad variety of applications. Imaging spectroscopy in general and translational laboratory imaging spectroscopy in particular can be utilized for a variety of different research topics. Geoscientific applications require a precise pre-processing of hyperspectral data cubes to retrieve at-surface reflectance in order to conduct spectral feature-based comparison of unknown sample spectra to known library spectra.

Spatio-temporal regulation of the human licensing factor Cdc6 in replication and mitosis.

To maintain genome stability, the thousands of replication origins of mammalian genomes must only initiate replication once per cell cycle. This is achieved by a strict temporal separation of ongoing replication in S phase, and the formation of pre-replicative complexes in the preceding G1 phase, which "licenses" each origin competent for replication. The contribution of the loading factor Cdc6 to the timing of the licensing process remained however elusive due to seemingly contradictory findings concerning stabilization, degradation and nuclear export of Cdc6.

Localization of MLH3 at the centrosomes.

Mutations in human DNA mismatch repair (MMR) genes are commonly associated with hereditary nonpolyposis colorectal cancer (HNPCC). MLH1 protein heterodimerizes with PMS2, PMS1, and MLH3 to form MutLα, MutLβ, and MutLγ, respectively. We reported recently stable expression of GFP-linked MLH3 in human cell lines.

Negative regulation of mitochondrial transcription by mitochondrial topoisomerase I.

Mitochondrial topoisomerase I is a genetically distinct mitochondria-dedicated enzyme with a crucial but so far unknown role in the homeostasis of mitochondrial DNA metabolism. Here, we present data suggesting a negative regulatory function in mitochondrial transcription or transcript stability. Deficiency or depletion of mitochondrial topoisomerase I increased mitochondrial transcripts, whereas overexpression lowered mitochondrial transcripts, depleted respiratory complexes I, III and IV, decreased cell respiration and raised superoxide levels.

Stable expression of MutLγ in human cells reveals no specific response to mismatched DNA, but distinct recruitment to damage sites.

The human DNA mismatch repair (MMR) gene family comprises four MutL paralogues capable of forming heterodimeric MutLα (MLH1-PMS2), MutLβ (MLH1-PMS1), and MutLγ (MLH1-MLH3) protein complexes. Human MutL subunits PMS2 and MLH3 contain an evolutionarily conserved amino acid motif DQHA(X)2E(X)4E identified as an endonucleolytic domain capable of incising a defective DNA strand. PMS2 of MutLα is generally accepted to be the sole executor of endonucleolytic activity, but since MLH3 was shown to be able to perform DNA repair at low levels in vitro, our aim was to investigate whether or not MLH3 is activated as a backup under MutLα-deficient conditions.

Impact of human autoantibodies on β1-adrenergic receptor conformation, activity, and internalization.

Aims: Autoantibodies against second extracellular loops of β(1)-adrenergic receptors frequent in dilated cardiomyopathy confer myocardial dysfunction presumably via cAMP stimulation. Here, we investigate the autoantibody impact on receptor conformation and function.

Methods And Results: IgG was prepared from patients with dilated cardiomyopathy, matched healthy donors (10 each) or commercial IgG preparations (2).

Target genes of Topoisomerase IIβ regulate neuronal survival and are defined by their chromatin state.

Topoisomerases are essential for DNA replication in dividing cells, but their genomic targets and function in postmitotic cells remain poorly understood. Here we show that a switch in the expression from Topoisomerases IIα (Top2α) to IIβ (Top2β) occurs during neuronal differentiation in vitro and in vivo. Genome-scale location analysis in stem cell-derived postmitotic neurons reveals Top2β binding to chromosomal sites that are methylated at lysine 4 of histone H3, a feature of regulatory regions.

XRCC4 controls nuclear import and distribution of Ligase IV and exchanges faster at damaged DNA in complex with Ligase IV.

Non-homologous end-joining (NHEJ) is one major pathway for the repair of double-stranded DNA breaks in mammals. Following break recognition, alignment and processing, broken DNA ends are finally rejoined by the essential DNA Ligase IV. In the cell, Ligase IV is unable to function without its constitutive interaction partner XRCC4 and becomes unstable when it is missing, and it has been assumed that XRCC4 may also be required for recruitment of Ligase IV to repair sites.

53BP1 and MDC1 foci formation in HT-1080 cells for low- and high-LET microbeam irradiations.

An improved assessment of the biological effects and related risks of low doses of ionizing radiation is currently an important issue in radiation biology. Irradiations using microbeams are particularly well suited for precise and localized dose depositions, whereas recombinant cell lines with fluorescent proteins allow the live observation of radiation-induced foci. Living cells of the fibrosarcoma cell line HT-1080 stably expressing 53BP1 or full-length reconstituted MDC1 fused to Green Fluorescent Protein (GFP) were irradiated with protons and α-particles of linear energy transfers (LETs) of 15 and 75 keV/μm, respectively.

Genotoxicity of dietary, environmental and therapeutic topoisomerase II poisons is uniformly correlated to prolongation of enzyme DNA residence.

Scope: DNA damage by genistein and etoposide is determined by the half-life of topoisomerase II-DNA linkage induced [Bandele O. J. and Osheroff N.

Repair of DNA damage induced by the mycotoxin alternariol involves tyrosyl-DNA phosphodiesterase 1.

Alternariol (AOH) was reported recently to act as a topoisomerase poison. To underline the relevance of topoisomerase targeting for the genotoxic properties of AOH, we addressed the question whether human tyrosyl-DNA phosphodiesterase 1 (TDP1), an enzyme vital to the repair of covalent DNA-topoisomerase adducts, affects AOH-mediated genotoxicity. The relevance of TDP1 activity on AOH-induced genotoxicity was investigated by the comet assay in human cells overexpressing GFP chimera of TDP1 or the inactive mutant TDP1(H263A) as well as in cells subjected to siRNA-mediated knock-down of endogenous TDP1.

Mitotic chromosomes are constrained by topoisomerase II-sensitive DNA entanglements.

We have analyzed the topological organization of chromatin inside mitotic chromosomes. We show that mitotic chromatin is heavily self-entangled through experiments in which topoisomerase (topo) II is observed to reduce mitotic chromosome elastic stiffness. Single chromosomes were relaxed by 35% by exogenously added topo II in a manner that depends on hydrolysable adenosine triphosphate (ATP), whereas an inactive topo II cleavage mutant did not change chromosome stiffness.

Adaptation of topoisomerase I paralogs to nuclear and mitochondrial DNA.

Topoisomerase I is essential for DNA metabolism in nuclei and mitochondria. In yeast, a single topoisomerase I gene provides for both organelles. In vertebrates, topoisomerase I is divided into nuclear and mitochondrial paralogs (Top1 and Top1mt).

Rapid and prolonged stalling of human DNA topoisomerase I in UVA-irradiated genomic areas.

DNA topoisomerase I appears to be involved in DNA damage and repair in a complex manner. The enzyme is required for DNA maintenance and repair, but it may also damage DNA through its covalently DNA-bound, catalytic intermediate. The latter mechanism plays a role in tumor cell killing by camptothecins, but seems also involved in oxidative cell killing and certain stages of apoptosis.

C-terminal regions of topoisomerase IIalpha and IIbeta determine isoform-specific functioning of the enzymes in vivo.

Topoisomerase II removes supercoils and catenanes generated during DNA metabolic processes such as transcription and replication. Vertebrate cells express two genetically distinct isoforms (alpha and beta) with similar structures and biochemical activities but different biological roles. Topoisomerase IIalpha is essential for cell proliferation, whereas topoisomerase IIbeta is required only for aspects of nerve growth and brain development.

TDP1 overexpression in human cells counteracts DNA damage mediated by topoisomerases I and II.

Tyrosyl DNA phosphodiesterase 1 (TDP1) is a repair enzyme that removes adducts, e.g. of topoisomerase I from the 3'-phosphate of DNA breaks.

Inferring a system model of subcellular topoisomerase II beta localization dynamics.

Measuring the mobility of proteins in living cells has become critical to many studies in cell biology and forms the basis for discussion on sub-cellular dynamics. Increasingly localization networks are being put together into compartment models to represent the exchange of molecules, represented mathematically as ordinary differential equations (ODE). The set-up is based on published literature, the "knowledge" of the investigator and 3D visualization of the data.

Enhanced processing of UVA-irradiated DNA by human topoisomerase II in living cells.

Solar UV light induces a variety of DNA lesions in the genome. Enhanced cleavage of such base modifications by topoisomerase II has been demonstrated in vitro, but it is unclear what will arise from an interplay of these mechanisms in the genome of a living cell exposed to UV light. To address this question, we have subjected cells expressing biofluorescent topoisomerase IIalpha or IIbeta to DNA base modifications inflicted by a UVA laser at 364 nm through a confocal microscope in a locally confined manner.

Distinct effects of topoisomerase I and RNA polymerase I inhibitors suggest a dual mechanism of nucleolar/nucleoplasmic partitioning of topoisomerase I.

Topoisomerase I is mostly nucleolar, because it plays a preeminent role in ribosomal DNA (rDNA) transcription. It is cleared from nucleoli following exposure to drugs stabilizing covalent DNA intermediates of the enzyme (e.g.

Residues 190-210 of human topoisomerase I are required for enzyme activity in vivo but not in vitro.

DNA-topoisomerase I (topo I) unwinds the DNA- double helix by cutting one strand and allowing rotation of the other. In vitro, this function does not require the N-terminal domain of the enzyme, which is believed to regulate cellular properties. To assess this role, we studied the cellular distribution and mobility of green fluorescent protein-chimera of human topo I lacking either the entire N-terminal domain or a portion of it.

Active, but not inactive, human centromeres display topoisomerase II activity in vivo.

Eukaryotic centromeres are composed of centromere DNA and the multiple proteins directly or indirectly associated with it. One important DNA-binding protein in the centromere is DNA topoisomerase II (topo II). In the genome in general, topo II has two functions, one structural and one enzymatic, the latter catalyzing DNA strand-passage reactions.

The N-terminal domain anchors human topoisomerase I at fibrillar centers of nucleoli and nucleolar organizer regions of mitotic chromosomes.

DNA topoisomerase I releases torsion stress created by DNA transcription. In principle, this activity is required in the nucleoplasm for mRNA synthesis and in the nucleoli for rRNA synthesis. Yet, topoisomerase I is mostly a nucleolar protein.