Your search keyword '"Carell, T."' showing total 12 results

1. Author Correction: Isoform-specific and ubiquitination dependent recruitment of Tet1 to replicating heterochromatin modulates methylcytosine oxidation.

Author

Arroyo M, Hastert FD, Zhadan A, Schelter F, Zimbelmann S, Rausch C, Ludwig AK, Carell T, and Cardoso MC

Published

2023

2. Isoform-specific and ubiquitination dependent recruitment of Tet1 to replicating heterochromatin modulates methylcytosine oxidation.

Author

Arroyo M, Hastert FD, Zhadan A, Schelter F, Zimbelmann S, Rausch C, Ludwig AK, Carell T, and Cardoso MC

Subjects

Animals, CCAAT-Enhancer-Binding Proteins genetics, Cytosine metabolism, DNA Methylation, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Heterochromatin genetics, Humans, Mice, Mixed Function Oxygenases genetics, Mixed Function Oxygenases metabolism, Protein Isoforms genetics, Protein Isoforms metabolism, Protein Serine-Threonine Kinases, Proto-Oncogene Proteins genetics, Proto-Oncogene Proteins metabolism, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, Ubiquitination, 5-Methylcytosine metabolism, Dioxygenases metabolism

Abstract

Oxidation of the epigenetic DNA mark 5-methylcytosine by Tet dioxygenases is an established route to diversify the epigenetic information, modulate gene expression and overall cellular (patho-)physiology. Here, we demonstrate that Tet1 and its short isoform Tet1s exhibit distinct nuclear localization during DNA replication resulting in aberrant cytosine modification levels in human and mouse cells. We show that Tet1 is tethered away from heterochromatin via its zinc finger domain, which is missing in Tet1s allowing its targeting to these regions. We find that Tet1s interacts with and is ubiquitinated by CRL4(VprBP). The ubiquitinated Tet1s is then recognized by Uhrf1 and recruited to late replicating heterochromatin. This leads to spreading of 5-methylcytosine oxidation to heterochromatin regions, LINE 1 activation and chromatin decondensation. In summary, we elucidate a dual regulation mechanism of Tet1, contributing to the understanding of how epigenetic information can be diversified by spatio-temporal directed Tet1 catalytic activity., (© 2022. The Author(s).)

Published

2022

3. Synthesis and structure elucidation of the human tRNA nucleoside mannosyl-queuosine.

Author

Hillmeier M, Wagner M, Ensfelder T, Korytiakova E, Thumbs P, Müller M, and Carell T

Subjects

Animals, Anticodon, Galactose chemistry, Galactose metabolism, Humans, Mannose chemistry, Mass Spectrometry, Mice, Nucleoside Q chemistry, Nucleosides chemistry, RNA, Transfer chemistry, Mannose metabolism, Nucleoside Q metabolism, Nucleosides metabolism, RNA, Transfer metabolism

Abstract

Queuosine (Q) is a structurally complex, non-canonical RNA nucleoside. It is present in many eukaryotic and bacterial species, where it is part of the anticodon loop of certain tRNAs. In higher vertebrates, including humans, two further modified queuosine-derivatives exist - galactosyl- (galQ) and mannosyl-queuosine (manQ). The function of these low abundant hypermodified RNA nucleosides remains unknown. While the structure of galQ was elucidated and confirmed by total synthesis, the reported structure of manQ still awaits confirmation. By combining total synthesis and LC-MS-co-injection experiments, together with a metabolic feeding study of labelled hexoses, we show here that the natural compound manQ isolated from mouse liver deviates from the literature-reported structure. Our data show that manQ features an α-allyl connectivity of its sugar moiety. The yet unidentified glycosylases that attach galactose and mannose to the Q-base therefore have a maximally different constitutional connectivity preference. Knowing the correct structure of manQ will now pave the way towards further elucidation of its biological function., (© 2021. The Author(s).)

Published

2021

4. Redirected nuclear glutamate dehydrogenase supplies Tet3 with α-ketoglutarate in neurons.

Author

Traube FR, Özdemir D, Sahin H, Scheel C, Glück AF, Geserich AS, Oganesian S, Kostidis S, Iwan K, Rahimoff R, Giorgio G, Müller M, Spada F, Biel M, Cox J, Giera M, Michalakis S, and Carell T

Subjects

Animals, Brain metabolism, Citric Acid Cycle, Dioxygenases genetics, Epigenomics, Gene Expression, Glutamate Dehydrogenase genetics, Glutamic Acid metabolism, HEK293 Cells, Humans, Ketoglutarate Dehydrogenase Complex metabolism, Metabolomics, Mice, Mice, Inbred C57BL, Mice, Knockout, Mitochondria metabolism, Neuronal Plasticity, Cell Nucleus enzymology, Cell Nucleus metabolism, Dioxygenases metabolism, Glutamate Dehydrogenase metabolism, Ketoglutaric Acids metabolism, Neurons metabolism

Abstract

Tet3 is the main α-ketoglutarate (αKG)-dependent dioxygenase in neurons that converts 5-methyl-dC into 5-hydroxymethyl-dC and further on to 5-formyl- and 5-carboxy-dC. Neurons possess high levels of 5-hydroxymethyl-dC that further increase during neural activity to establish transcriptional plasticity required for learning and memory functions. How αKG, which is mainly generated in mitochondria as an intermediate of the tricarboxylic acid cycle, is made available in the nucleus has remained an unresolved question in the connection between metabolism and epigenetics. We show that in neurons the mitochondrial enzyme glutamate dehydrogenase, which converts glutamate into αKG in an NAD + -dependent manner, is redirected to the nucleus by the αKG-consumer protein Tet3, suggesting on-site production of αKG. Further, glutamate dehydrogenase has a stimulatory effect on Tet3 demethylation activity in neurons, and neuronal activation increases the levels of αKG. Overall, the glutamate dehydrogenase-Tet3 interaction might have a role in epigenetic changes during neural plasticity.

Published

2021

5. Author Correction: Recent evolution of a TET-controlled and DPPA3/STELLA-driven pathway of passive DNA demethylation in mammals.

Author

Mulholland CB, Nishiyama A, Ryan J, Nakamura R, Yiğit M, Glück IM, Trummer C, Qin W, Bartoschek MD, Traube FR, Parsa E, Ugur E, Modic M, Acharya A, Stolz P, Ziegenhain C, Wierer M, Enard W, Carell T, Lamb DC, Takeda H, Nakanishi M, Bultmann S, and Leonhardt H

Published

2020

6. Recent evolution of a TET-controlled and DPPA3/STELLA-driven pathway of passive DNA demethylation in mammals.

Author

Mulholland CB, Nishiyama A, Ryan J, Nakamura R, Yiğit M, Glück IM, Trummer C, Qin W, Bartoschek MD, Traube FR, Parsa E, Ugur E, Modic M, Acharya A, Stolz P, Ziegenhain C, Wierer M, Enard W, Carell T, Lamb DC, Takeda H, Nakanishi M, Bultmann S, and Leonhardt H

Subjects

Animals, Biological Evolution, CCAAT-Enhancer-Binding Proteins metabolism, DNA Methylation, DNA-Directed DNA Polymerase metabolism, Epigenomics, Evolution, Molecular, Gene Expression Regulation, Genes, Regulator, Germ Cells metabolism, Mice, Ubiquitin-Protein Ligases metabolism, Chromatin metabolism, Chromosomal Proteins, Non-Histone genetics, Chromosomal Proteins, Non-Histone metabolism, DNA Demethylation, Mammals genetics, Pluripotent Stem Cells metabolism

Abstract

Genome-wide DNA demethylation is a unique feature of mammalian development and naïve pluripotent stem cells. Here, we describe a recently evolved pathway in which global hypomethylation is achieved by the coupling of active and passive demethylation. TET activity is required, albeit indirectly, for global demethylation, which mostly occurs at sites devoid of TET binding. Instead, TET-mediated active demethylation is locus-specific and necessary for activating a subset of genes, including the naïve pluripotency and germline marker Dppa3 (Stella, Pgc7). DPPA3 in turn drives large-scale passive demethylation by directly binding and displacing UHRF1 from chromatin, thereby inhibiting maintenance DNA methylation. Although unique to mammals, we show that DPPA3 alone is capable of inducing global DNA demethylation in non-mammalian species (Xenopus and medaka) despite their evolutionary divergence from mammals more than 300 million years ago. Our findings suggest that the evolution of Dppa3 facilitated the emergence of global DNA demethylation in mammals.

Published

2020

7. Single molecule analysis reveals monomeric XPA bends DNA and undergoes episodic linear diffusion during damage search.

Author

Beckwitt EC, Jang S, Carnaval Detweiler I, Kuper J, Sauer F, Simon N, Bretzler J, Watkins SC, Carell T, Kisker C, and Van Houten B

Subjects

Biophysics methods, DNA Adducts chemistry, DNA Adducts metabolism, DNA Damage physiology, DNA Repair physiology, DNA-Binding Proteins metabolism, Humans, Microscopy, Atomic Force, Protein Binding, Ultraviolet Rays, DNA chemistry, DNA metabolism, Single Molecule Imaging methods, Xeroderma Pigmentosum Group A Protein chemistry, Xeroderma Pigmentosum Group A Protein metabolism

Abstract

Nucleotide excision repair (NER) removes a wide range of DNA lesions, including UV-induced photoproducts and bulky base adducts. XPA is an essential protein in eukaryotic NER, although reports about its stoichiometry and role in damage recognition are controversial. Here, by PeakForce Tapping atomic force microscopy, we show that human XPA binds and bends DNA by ∼60° as a monomer. Furthermore, we observe XPA specificity for the helix-distorting base adduct N-(2'-deoxyguanosin-8-yl)-2-acetylaminofluorene over non-damaged dsDNA. Moreover, single molecule fluorescence microscopy reveals that DNA-bound XPA exhibits multiple modes of linear diffusion between paused phases. The presence of DNA damage increases the frequency of pausing. Truncated XPA, lacking the intrinsically disordered N- and C-termini, loses specificity for DNA lesions and shows less pausing on damaged DNA. Our data are consistent with a working model in which monomeric XPA bends DNA, displays episodic phases of linear diffusion along DNA, and pauses in response to DNA damage.

Published

2020

8. Publisher Correction: Non-canonical nucleosides and chemistry of the emergence of life.

Author

Becker S, Schneider C, Crisp A, and Carell T

Abstract

The original version of this Article contained errors in the citations in the second, third and fourth sentences of the first paragraph of the 'Life and LUCA' section, which incorrectly read 'Its development is explained by Darwinian evolution, which must have begun with rudimentary "living" vesicles that at some point transitioned into what we call the last universal common ancestor (LUCA) 2 . LUCA is a hypothetical life form obtained from phylogenetic analysis from which all three kingdoms of life originated 3 . To our understanding, LUCA already possessed the capacity to synthesize specific building blocks such as amino acids, nucleotides and lipids 2 .' The correct version states '(LUCA) 1 ' in place of '(LUCA) 2 ', 'originated 2 ' instead of 'originated 3 ' and 'lipids 1 ' rather than 'lipids 2 '. This has been corrected in both the PDF and HTML versions of the Article.

Published

2019

9. Non-canonical nucleosides and chemistry of the emergence of life.

Author

Becker S, Schneider C, Crisp A, and Carell T

Subjects

Amino Acids chemistry, Atmosphere chemistry, Base Pairing, Models, Chemical, Molecular Structure, RNA chemical synthesis, RNA chemistry, Earth, Planet, Evolution, Chemical, Nucleosides chemistry, Origin of Life

Abstract

Prebiotic chemistry, driven by changing environmental parameters provides canonical and a multitude of non-canonical nucleosides. This suggests that Watson-Crick base pairs were selected from a diverse pool of nucleosides in a pre-Darwinian chemical evolution process.

Published

2018

10. Wet-dry cycles enable the parallel origin of canonical and non-canonical nucleosides by continuous synthesis.

Author

Becker S, Schneider C, Okamura H, Crisp A, Amatov T, Dejmek M, and Carell T

Subjects

Earth, Planet, Evolution, Chemical, Models, Chemical, Molecular Structure, Origin of Life, Biopolymers chemistry, Nucleosides chemistry, RNA chemistry, Water chemistry

Abstract

The molecules of life were created by a continuous physicochemical process on an early Earth. In this hadean environment, chemical transformations were driven by fluctuations of the naturally given physical parameters established for example by wet-dry cycles. These conditions might have allowed for the formation of (self)-replicating RNA as the fundamental biopolymer during chemical evolution. The question of how a complex multistep chemical synthesis of RNA building blocks was possible in such an environment remains unanswered. Here we report that geothermal fields could provide the right setup for establishing wet-dry cycles that allow for the synthesis of RNA nucleosides by continuous synthesis. Our model provides both the canonical and many ubiquitous non-canonical purine nucleosides in parallel by simple changes of physical parameters such as temperature, pH and concentration. The data show that modified nucleosides were potentially formed as competitor molecules. They could in this sense be considered as molecular fossils.

Published

2018

11. DNA hydroxymethylation controls cardiomyocyte gene expression in development and hypertrophy.

Author

Greco CM, Kunderfranco P, Rubino M, Larcher V, Carullo P, Anselmo A, Kurz K, Carell T, Angius A, Latronico MV, Papait R, and Condorelli G

Subjects

5-Methylcytosine metabolism, Animals, Cell Differentiation genetics, DNA-Binding Proteins metabolism, Dioxygenases, Enhancer Elements, Genetic genetics, Gene Knockdown Techniques, Genome, Mice, Inbred C57BL, Proto-Oncogene Proteins metabolism, Repetitive Sequences, Nucleic Acid genetics, Transcription, Genetic, 5-Methylcytosine analogs & derivatives, Cardiomegaly genetics, DNA Methylation, Gene Expression Regulation, Developmental, Myocytes, Cardiac metabolism

Abstract

Methylation at 5-cytosine (5-mC) is a fundamental epigenetic DNA modification associated recently with cardiac disease. In contrast, the role of 5-hydroxymethylcytosine (5-hmC)-5-mC's oxidation product-in cardiac biology and disease is unknown. Here we assess the hydroxymethylome in embryonic, neonatal, adult and hypertrophic mouse cardiomyocytes, showing that dynamic modulation of hydroxymethylated DNA is associated with specific transcriptional networks during heart development and failure. DNA hydroxymethylation marks the body of highly expressed genes as well as distal regulatory regions with enhanced activity. Moreover, pathological hypertrophy is characterized by a shift towards a neonatal 5-hmC distribution pattern. We also show that the ten-eleven translocation 2 (TET2) enzyme regulates the expression of key cardiac genes, such as Myh7, through 5-hmC deposition on the gene body and at enhancers. Thus, we provide a genome-wide analysis of 5-hmC in the cardiomyocyte and suggest a role for this epigenetic modification in heart development and disease.

Published

2016

12. Identification of novel DNA-damage tolerance genes reveals regulation of translesion DNA synthesis by nucleophosmin.

Author

Ziv O, Zeisel A, Mirlas-Neisberg N, Swain U, Nevo R, Ben-Chetrit N, Martelli MP, Rossi R, Schiesser S, Canman CE, Carell T, Geacintov NE, Falini B, Domany E, and Livneh Z

Subjects

Cell Line, DNA Repair, DNA-Directed DNA Polymerase genetics, DNA-Directed DNA Polymerase metabolism, Humans, Leukemia, Myeloid, Acute enzymology, Leukemia, Myeloid, Acute genetics, Nuclear Proteins genetics, Nucleophosmin, Protein Binding, Ultraviolet Rays, DNA Damage radiation effects, DNA Replication radiation effects, Leukemia, Myeloid, Acute metabolism, Nuclear Proteins metabolism

Abstract

Cells cope with replication-blocking lesions via translesion DNA synthesis (TLS). TLS is carried out by low-fidelity DNA polymerases that replicate across lesions, thereby preventing genome instability at the cost of increased point mutations. Here we perform a two-stage siRNA-based functional screen for mammalian TLS genes and identify 17 validated TLS genes. One of the genes, NPM1, is frequently mutated in acute myeloid leukaemia (AML). We show that NPM1 (nucleophosmin) regulates TLS via interaction with the catalytic core of DNA polymerase-η (polη), and that NPM1 deficiency causes a TLS defect due to proteasomal degradation of polη. Moreover, the prevalent NPM1c+ mutation that causes NPM1 mislocalization in ~30% of AML patients results in excessive degradation of polη. These results establish the role of NPM1 as a key TLS regulator, and suggest a mechanism for the better prognosis of AML patients carrying mutations in NPM1.

Published

2014