Your search keyword '"Steffen FD"' showing total 10 results

1. FRET-guided modeling of nucleic acids.

Author

Steffen FD, Cunha RA, Sigel RKO, and Börner R

Subjects

RNA chemistry, Manganese chemistry, DNA chemistry, Single Molecule Imaging methods, Fluorescence Resonance Energy Transfer, Nucleic Acid Conformation, Molecular Dynamics Simulation, Riboswitch

Abstract

The functional diversity of RNAs is encoded in their innate conformational heterogeneity. The combination of single-molecule spectroscopy and computational modeling offers new attractive opportunities to map structural transitions within nucleic acid ensembles. Here, we describe a framework to harmonize single-molecule Förster resonance energy transfer (FRET) measurements with molecular dynamics simulations and de novo structure prediction. Using either all-atom or implicit fluorophore modeling, we recreate FRET experiments in silico, visualize the underlying structural dynamics and quantify the reaction coordinates. Using multiple accessible-contact volumes as a post hoc scoring method for fragment assembly in Rosetta, we demonstrate that FRET can be used to filter a de novo RNA structure prediction ensemble by refuting models that are not compatible with in vitro FRET measurement. We benchmark our FRET-assisted modeling approach on double-labeled DNA strands and validate it against an intrinsically dynamic manganese(II)-binding riboswitch. We show that a FRET coordinate describing the assembly of a four-way junction allows our pipeline to recapitulate the global fold of the riboswitch displayed by the crystal structure. We conclude that computational fluorescence spectroscopy facilitates the interpretability of dynamic structural ensembles and improves the mechanistic understanding of nucleic acid interactions., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2024

2. A new twist on PIFE: photoisomerisation-related fluorescence enhancement.

Author

Ploetz E, Ambrose B, Barth A, Börner R, Erichson F, Kapanidis AN, Kim HD, Levitus M, Lohman TM, Mazumder A, Rueda DS, Steffen FD, Cordes T, Magennis SW, and Lerner E

Subjects

Fluorescence Resonance Energy Transfer, DNA chemistry, Proteins chemistry

Abstract

PIFE was first used as an acronym for protein-induced fluorescence enhancement, which refers to the increase in fluorescence observed upon the interaction of a fluorophore, such as a cyanine, with a protein. This fluorescence enhancement is due to changes in the rate of cis / trans photoisomerisation. It is clear now that this mechanism is generally applicable to interactions with any biomolecule. In this review, we propose that PIFE is thereby renamed according to its fundamental working principle as photoisomerisation-related fluorescence enhancement, keeping the PIFE acronym intact. We discuss the photochemistry of cyanine fluorophores, the mechanism of PIFE, its advantages and limitations, and recent approaches to turning PIFE into a quantitative assay. We provide an overview of its current applications to different biomolecules and discuss potential future uses, including the study of protein-protein interactions, protein-ligand interactions and conformational changes in biomolecules., (Creative Commons Attribution license.)

Published

2023

3. A new twist on PIFE: photoisomerisation-related fluorescence enhancement.

Author

Ploetz E, Ambrose B, Barth A, Börner R, Erichson F, Kapanidis AN, Kim HD, Levitus M, Lohman TM, Mazumder A, Rueda DS, Steffen FD, Cordes T, Magennis SW, and Lerner E

Abstract

PIFE was first used as an acronym for protein-induced fluorescence enhancement, which refers to the increase in fluorescence observed upon the interaction of a fluorophore, such as a cyanine, with a protein. This fluorescence enhancement is due to changes in the rate of cis/trans photoisomerisation. It is clear now that this mechanism is generally applicable to interactions with any biomolecule and, in this review, we propose that PIFE is thereby renamed according to its fundamental working principle as photoisomerisation-related fluorescence enhancement, keeping the PIFE acronym intact. We discuss the photochemistry of cyanine fluorophores, the mechanism of PIFE, its advantages and limitations, and recent approaches to turn PIFE into a quantitative assay. We provide an overview of its current applications to different biomolecules and discuss potential future uses, including the study of protein-protein interactions, protein-ligand interactions and conformational changes in biomolecules.

Published

2023

4. B- and T-cell acute lymphoblastic leukemias evade chemotherapy at distinct sites in the bone marrow.

Author

Barz MJ, Behrmann L, Capron D, Zuchtriegel G, Steffen FD, Kunz L, Zhang Y, Vermeerbergen IJ, Marovca B, Kirschmann M, Zech A, Nombela-Arrieta C, Ziegler U, Schroeder T, Bornhauser B, and Bourquin JP

Subjects

Humans, Bone Marrow, Antineoplastic Combined Chemotherapy Protocols therapeutic use, Tumor Microenvironment, Precursor T-Cell Lymphoblastic Leukemia-Lymphoma drug therapy, Leukemia, Biphenotypic, Acute, Precursor Cell Lymphoblastic Leukemia-Lymphoma drug therapy, Precursor B-Cell Lymphoblastic Leukemia-Lymphoma drug therapy, Burkitt Lymphoma drug therapy

Abstract

Persistence of residual disease after induction chemotherapy is a strong predictor of relapse in acute lymphoblastic leukemia (ALL). The bone marrow microenvironment may support escape from treatment. Using three-dimensional fluorescence imaging of ten primary ALL xenografts we identified sites of predilection in the bone marrow for resistance to induction with dexamethasone, vincristine and doxorubicin. We detected B-cell precursor ALL cells predominantly in the perisinusoidal space at early engraftment and after chemotherapy. The spatial distribution of T-ALL cells was more widespread with contacts to endosteum, nestin+ pericytes and sinusoids. Dispersion of T-ALL cells in the bone marrow increased under chemotherapeutic pressure. A subset of slowly dividing ALL cells was transiently detected upon shortterm chemotherapy, but not at residual disease after chemotherapy, challenging the notion that ALL cells escape treatment by direct induction of a dormant state in the niche. These lineage-dependent differences point to niche interactions that may be more specifically exploitable to improve treatment.

Published

2023

5. Chemical Dual End-Labeling of Large Ribozymes.

Author

Ahunbay E, Steffen FD, Zelger-Paulus S, and Sigel RKO

Subjects

Electron Spin Resonance Spectroscopy methods, Fluorescence Resonance Energy Transfer, Fluorescent Dyes chemistry, RNA chemistry, RNA genetics, Spin Labels, RNA, Catalytic genetics

Abstract

Fast and efficient site-specific labeling of long RNAs is one of the main bottlenecks limiting distance measurements by means of Förster resonance energy transfer (FRET) or electron paramagnetic resonance (EPR) spectroscopy. Here, we present an optimized protocol for dual end-labeling with different fluorophores at the same time meeting the restrictions of highly labile and degradation-sensitive RNAs. We describe in detail the dual-labeling of a catalytically active wild-type group II intron as a typical representative of long functional RNAs. The modular procedure chemically activates the 5'-phosphate and the 3'-ribose for bioconjugation with a pair of fluorophores, as shown herein, or with spin labels. The mild reaction conditions preserve the structural and functional integrity of the biomacromolecule and results in covalent, dual-labeled RNA in its pre-catalytic state in yields suitable for both ensemble and single-molecule FRET experiments., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2022

6. FRETraj: integrating single-molecule spectroscopy with molecular dynamics.

Author

Steffen FD, Sigel RKO, and Börner R

Subjects

Single Molecule Imaging, Ecosystem, Fluorescent Dyes chemistry, Molecular Dynamics Simulation, Fluorescence Resonance Energy Transfer

Abstract

Summary: Quantitative interpretation of single-molecule FRET experiments requires a model of the dye dynamics to link experimental energy transfer efficiencies to distances between atom positions. We have developed FRETraj, a Python module to predict FRET distributions based on accessible-contact volumes (ACV) and simulated photon statistics. FRETraj helps to identify optimal fluorophore positions on a biomolecule of interest by rapidly evaluating donor-acceptor distances. FRETraj is scalable and fully integrated into PyMOL and the Jupyter ecosystem. Here, we describe the conformational dynamics of a DNA hairpin by computing multiple ACVs along a molecular dynamics trajectory and compare the predicted FRET distribution with single-molecule experiments. FRET-assisted modeling will accelerate the analysis of structural ensembles in particular dynamic, non-coding RNAs and transient protein-nucleic acid complexes., Availability and Implementation: FRETraj is implemented as a cross-platform Python package available under the GPL-3.0 on Github (https://github.com/RNA-FRETools/fretraj) and is documented at https://RNA-FRETools.github.io/fretraj., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author(s) 2021. Published by Oxford University Press.)

Published

2021

7. Metal ions and sugar puckering balance single-molecule kinetic heterogeneity in RNA and DNA tertiary contacts.

Author

Steffen FD, Khier M, Kowerko D, Cunha RA, Börner R, and Sigel RKO

Subjects

DNA genetics, Exons, Fluorescence Resonance Energy Transfer, Introns, Ions chemistry, Kinetics, Nucleic Acid Conformation, RNA genetics, Single Molecule Imaging, DNA chemistry, Magnesium chemistry, RNA chemistry, Sugars chemistry

Abstract

The fidelity of group II intron self-splicing and retrohoming relies on long-range tertiary interactions between the intron and its flanking exons. By single-molecule FRET, we explore the binding kinetics of the most important, structurally conserved contact, the exon and intron binding site 1 (EBS1/IBS1). A comparison of RNA-RNA and RNA-DNA hybrid contacts identifies transient metal ion binding as a major source of kinetic heterogeneity which typically appears in the form of degenerate FRET states. Molecular dynamics simulations suggest a structural link between heterogeneity and the sugar conformation at the exon-intron binding interface. While Mg 2+ ions lock the exon in place and give rise to long dwell times in the exon bound FRET state, sugar puckering alleviates this structural rigidity and likely promotes exon release. The interplay of sugar puckering and metal ion coordination may be an important mechanism to balance binding affinities of RNA and DNA interactions in general.

Published

2020

8. Stick, Flick, Click: DNA-guided Fluorescent Labeling of Long RNA for Single-molecule FRET.

Author

Steffen FD, Börner R, Freisinger E, and Sigel RKO

Subjects

Click Chemistry, DNA, Fluorescent Dyes, RNA, Fluorescence Resonance Energy Transfer

Abstract

Exploring the spatiotemporal dynamics of biomolecules on a single-molecule level requires innovative ways to make them spectroscopically visible. Fluorescence resonance energy transfer (FRET) uses a pair of organic dyes as reporters to measure distances along a predefined biomolecular reaction coordinate. For this nanoscopic ruler to work, the fluorescent labels need to be coupled onto the molecule of interest in a bioorthogonal and site-selective manner. Tagging large non-coding RNAs with single-nucleotide precision is an open challenge. Here we summarize current strategies in labeling riboswitches and ribozymes for fluorescence spectroscopy and FRET in particular. A special focus lies on our recently developed, DNA-guided approach that inserts two fluorophores through a stepwise process of templated functionality transfer and click chemistry.

Published

2019

9. Site-specific dual-color labeling of long RNAs for single-molecule spectroscopy.

Author

Zhao M, Steffen FD, Börner R, Schaffer MF, Sigel RKO, and Freisinger E

Subjects

Adenine chemistry, Adenine metabolism, Carbocyanines chemistry, Cobamides chemistry, Cobamides metabolism, DNA metabolism, Escherichia coli genetics, Escherichia coli metabolism, Fluorescence Resonance Energy Transfer, Fluorescent Dyes chemistry, Nucleic Acid Hybridization, Oligoribonucleotides chemical synthesis, Oligoribonucleotides chemistry, RNA metabolism, RNA Folding, DNA chemistry, Escherichia coli chemistry, RNA chemistry, Riboswitch, Staining and Labeling methods

Abstract

Labeling of long RNA molecules in a site-specific yet generally applicable manner is integral to many spectroscopic applications. Here we present a novel covalent labeling approach that is site-specific and scalable to long intricately folded RNAs. In this approach, a custom-designed DNA strand that hybridizes to the RNA guides a reactive group to target a preselected adenine residue. The functionalized nucleotide along with the concomitantly oxidized 3'-terminus can subsequently be conjugated to two different fluorophores via bio-orthogonal chemistry. We validate this modular labeling platform using a regulatory RNA of 275 nucleotides, the btuB riboswitch of Escherichia coli, demonstrate its general applicability by modifying a base within a duplex, and show its site-selectivity in targeting a pair of adjacent adenines. Native folding and function of the RNA is confirmed on the single-molecule level by using FRET as a sensor to visualize and characterize the conformational equilibrium of the riboswitch upon binding of its cofactor adenosylcobalamin. The presented labeling strategy overcomes size and site constraints that have hampered routine production of labeled RNA that are beyond 200 nt in length.

Published

2018

10. An atomistic view on carbocyanine photophysics in the realm of RNA.

Author

Steffen FD, Sigel RK, and Börner R

Subjects

Fluorescence Resonance Energy Transfer, Fluorescent Dyes chemistry, Magnesium chemistry, Microscopy, Fluorescence, Molecular Dynamics Simulation, Monte Carlo Method, Nucleic Acid Conformation, Potassium chemistry, Carbocyanines chemistry, RNA chemistry

Abstract

Carbocyanine dyes have a long-standing tradition in fluorescence imaging and spectroscopy, due to their photostability and large spectral separation between individual dye species. Herein, we explore the versatility of cyanine dyes to probe the dynamics of nucleic acids and we report on the interrelation of fluorophores, RNA, and metal ions, namely K + and Mg 2+ . Photophysical parameters including the fluorescence lifetime, quantum yield and dynamic anisotropy are monitored as a function of the nucleic acid composition, conformation, and metal ion abundance. Occasional excursions to a non-fluorescent cis-state hint at the remarkable sensitivity of carbocyanines to their local environment. Comparison of time-correlated single photon experiments with all-atom molecular dynamics simulations demonstrate that the propensity of photoisomerization is dictated by sterical constraints imposed on the fluorophore. Structural features in the vicinity of the dye play a crucial role in RNA recognition and have far-reaching implications on the mobility of the fluorescent probe. An atomic level description of the mutual interactions will ultimately benefit the quantitative interpretation of single-molecule FRET measurements on large RNA systems.

Published

2016