Your search keyword '"Bisballe, Niels"' showing total 8 results

1. Parallel Proteomic and Transcriptomic Microenvironment Mapping (μMap) of Nuclear Condensates in Living Cells.

Author

Knutson SD, Pan CR, Bisballe N, Bloomer BJ, Raftopolous P, Saridakis I, and MacMillan DWC

Subjects

Humans, HeLa Cells, Cell Nucleus metabolism, Cell Nucleus chemistry, RNA metabolism, RNA chemistry, Proteomics methods, Transcriptome

Abstract

Cellular activity is spatially organized across different organelles. While several structures are well-characterized, many organelles have unknown roles. Profiling biomolecular composition is key to understanding function but is difficult to achieve in the context of small, dynamic structures. Photoproximity labeling has emerged as a powerful tool for mapping these interaction networks, yet maximizing catalyst localization and reducing toxicity remains challenging in live cell applications. Here, we disclose a new intracellular photocatalyst with minimal cytotoxicity and off-target binding, and we utilize this catalyst for HaloTag-based microenvironment-mapping (μMap) to spatially catalog subnuclear condensates in living cells. We also specifically develop a novel RNA-focused workflow (μMap-seq) to enable parallel transcriptomic and proteomic profiling of these structures. After validating the accuracy of our approach, we generate a spatial map across the nucleolus, nuclear lamina, Cajal bodies, paraspeckles, and PML bodies. These results provide potential new insights into RNA metabolism and gene regulation while significantly expanding the μMap platform for improved live-cell proximity labeling in biological systems.

Published

2025

2. Development of a General Organophosphorus Radical Trap: Deoxyphosphonylation of Alcohols.

Author

Bissonnette NB, Bisballe N, Tran AV, Rossi-Ashton JA, and MacMillan DWC

Abstract

Here we report the design of a general, redox-switchable organophosphorus alkyl radical trap that enables the synthesis of a broad range of C( sp 3 )-P(V) modalities. This "plug-and-play" approach relies upon in situ activation of alcohols and O═P(R 2 )H motifs, two broadly available and inexpensive sources of molecular complexity. The mild, photocatalytic deoxygenative strategy described herein allows for the direct conversion of sugars, nucleosides, and complex pharmaceutical architectures to their organophosphorus analogs. This includes the facile incorporation of medicinally relevant phosphonate ester prodrugs.

Published

2024

3. Triplet States of Cyanostar and Its Anion Complexes.

Author

Edhborg F, Olesund A, Tripathy V, Wang Y, Sadhukhan T, Olsson AH, Bisballe N, Raghavachari K, Laursen BW, Albinsson B, and Flood AH

Abstract

The design of advanced optical materials based on triplet states requires knowledge of the triplet energies of the molecular building blocks. To this end, we report the triplet energy of cyanostar ( CS ) macrocycles, which are the key structure-directing units of small-molecule ionic isolation lattices (SMILES) that have emerged as programmable optical materials. Cyanostar is a cyclic pentamer of covalently linked cyanostilbene units that form π-stacked dimers when binding anions as 2:1 complexes. The triplet energies, E T , of the parent cyanostar and its 2:1 complex around PF 6 - are measured to be 1.96 and 2.02 eV, respectively, using phosphorescence quenching studies at room temperature. The similarity of these triplet energies suggests that anion complexation leaves the triplet energy relatively unchanged. Similar energies (2.0 and 1.98 eV, respectively) were also obtained from phosphorescence spectra of the iodinated form, I-CS , and of complexes formed with PF 6 - and IO 4 - recorded at 85 K in an organic glass. Thus, measures of the triplet energies likely reflect geometries close to those of the ground state either directly by triplet energy transfer to the ground state or indirectly by using frozen media to inhibit relaxation. Density functional theory (DFT) and time-dependent DFT were undertaken on a cyanostar analogue, CSH , to examine the triplet state. The triplet excitation localizes on a single olefin whether in the single cyanostar or its π-stacked dimer. Restriction of the geometrical changes by forming either a dimer of macrocycles, ( CSH ) 2 , or a complex, ( CSH ) 2 ·PF 6 - , reduces the relaxation resulting in an adiabatic energy of the triplet state of 2.0 eV. This structural constraint is also expected for solid-state SMILES materials. The obtained T 1 energy of 2.0 eV is a key guide line for the design of SMILES materials for the manipulation of triplet excitons by triplet state engineering in the future.

Published

2023

4. Utilizing Selective Chlorination to Synthesize New Triangulenium Dyes.

Author

Jensen JD, Bisballe N, Kacenauskaite L, Thomsen MS, Chen J, Hammerich O, and Laursen BW

Subjects

Chlorine, Fluorescence, Coloring Agents, Halogenation

Abstract

Functionalization of new sites on the triangulenium structure has been achieved by early-stage chlorination with N -chlorosuccinimide (NCS), giving rise to two new triangulenium dyes ( 1 and 3 ). By introducing the chlorine functionalities in the acridinium precursor, positions complementary to those previously obtained by electrophilic aromatic substitution on the final dyes are accessed. The chlorination is selective, giving only one regioisomer for both mono- and dichlorination products. For the monochlorinated acridinium compound, a highly selective ring-closing reaction was discovered, generating a single regioisomer of the cationic [4]helicene product. Further investigations into the mechanism of the [4]helicene formation lead to the first isolation of the previously proposed intermediate of the two-step S N Ar reaction, key to all aza-bridged triangulenium and helicenium systems. Late-stage functionalization of DAOTA + with NCS gave rise to a different dichlorinated compound ( 2 ). The fully ring closed chlorinated triangulenium dyes 1 , 2 , and 3 show a redshift in absorption and emission, while maintaining relatively high fluorescence quantum yields of 36%, 26%, and 41% and long fluorescence lifetimes of 15, 12.5, and 16 ns, respectively. Cyclic voltammetry shows that chlorination of the triangulenium dyes significantly lowers reduction potentials and thus allows for efficient tuning of redox and photoredox properties.

Published

2021

5. Assessing The Key Photophysical Properties of Triangulenium Dyes for DNA Binding by Alteration of the Fluorescent Core.

Author

Lewis BW, Bisballe N, Santella M, Summers PA, Vannier JB, Kuimova MK, Laursen BW, and Vilar R

Subjects

Electron Transport, Fluorescent Dyes analysis, Molecular Probes analysis, Molecular Probes chemistry, DNA analysis, DNA chemistry, Fluorescence, Fluorescent Dyes chemistry, G-Quadruplexes

Abstract

Four-stranded G-quadruplex (G4) DNA is a non-canonical DNA topology that has been proposed to form in cells and play key roles in how the genome is read and used by the cellular machinery. Previously, a fluorescent triangulenium probe (DAOTA-M2) was used to visualise G4s in cellulo, thanks to its distinct fluorescence lifetimes when bound to different DNA topologies. Herein, the library of available triangulenium probes is expanded to explore how modifications to the fluorescent core of the molecule affect its photophysical characteristics, interaction with DNA and cellular localisation. The benzo-bridged and isopropyl-bridged diazatriangulenium dyes, BDATA-M2 and CDATA-M2 respectively, featuring ethyl-morpholino substituents, were synthesised and characterised. The interactions of these molecules with different DNA topologies were studied to determine their binding affinity, fluorescence enhancement and fluorescence lifetime response. Finally, the cellular uptake and localisation of these optical probes were investigated. Whilst structural modifications to the triangulenium core only slightly alter the binding affinity to DNA, BDATA-M2 and CDATA-M2 cannot distinguish between DNA topologies through their fluorescence lifetime. It is argued theoretically and experimentally that this is due to reduced effectiveness of photoinduced electron transfer (PET) quenching. This work presents valuable new evidence into the critical role of PET quenching when using the fluorescence lifetime of triangulenium dyes to discriminate G4 DNA from duplex DNA, highlighting the importance of fine tuning redox and spectral properties when developing new triangulenium-based G4 probes., (© 2020 Wiley-VCH GmbH.)

Published

2021

6. Rational Design of Bright Long Fluorescence Lifetime Dyad Fluorophores for Single Molecule Imaging and Detection.

Author

Kacenauskaite L, Bisballe N, Mucci R, Santella M, Pullerits T, Chen J, Vosch T, and Laursen BW

Abstract

Increasing demand for detecting single molecules in challenging environments has raised the bar for the fluorophores used. To achieve better resolution and/or contrast in fluorescence microscopy, it is now essential to use bright and stable dyes with tailored photophysical properties. While long fluorescence lifetime fluorophores offer many advantages in time-resolved imaging, their inherently lower molar absorption coefficient has limited applications in single molecule imaging. Here we propose a generic approach to prepare bright, long fluorescence lifetime dyad fluorophores comprising an absorbing antenna chromophore with high absorption coefficient linked to an acceptor emitter with a long fluorescence lifetime. We introduce a dyad consisting of a perylene antenna and a triangulenium emitter with 100% energy transfer from donor to acceptor. The dyad retained the long fluorescence lifetime (∼17 ns) and high quantum yield (75%) of the triangulenium emitter, while the perylene antenna increased the molar absorption coefficient (up to 5 times) in comparison to the free triangulenium dye. These triangulenium based dyads with significantly improved brightness can now be detected at the single molecule level and easily discriminated from bright autofluorescence by time-gated and other lifetime-based detection schemes.

Published

2021

7. What is Best Strategy for Water Soluble Fluorescence Dyes?-A Case Study Using Long Fluorescence Lifetime DAOTA Dyes*.

Author

Bisballe N and Laursen BW

Abstract

The lipophilic nature of organic dyes complicates their effectiveness in aqueous solutions. In this work we investigate three different strategies for achieving water-solubility of the diazaoxatriangulenium (DAOTA + ) chromophore: hydrophilic counter ions, aromatic sulfonation of the chromophore, and attachment of charged side chains. The long fluorescence lifetime (FLT, τ f =20 ns) of DAOTA + makes it a sensitive probe to analyze solvation and aggregation effects. Direct sulfonation of the chromophore was found to increase solubility drastically, but at the cost of greatly reduced quantum yields (QYs) due to enhanced non-radiative deactivation processes. The introduction of either cationic (4) or zwitterionic side chains (5), however, brings the FLT (τ f =18 ns) and QY (ϕ f =0.56) of the dye to the same level as the parent chromophore in acetonitrile. Time-resolved fluorescence spectroscopy also reveals a high resistance to aggregation and non-specific binding in a high loading of bovine serum albumin (BSA). The results clearly show that addition of charged flexible side chains is preferable to direct sulfonation of the chromophore core., (© 2020 Wiley-VCH GmbH.)

Published

2020

8. β-Sulfonamido Functionalized Aspartate Analogues as Excitatory Amino Acid Transporter Inhibitors: Distinct Subtype Selectivity Profiles Arising from Subtle Structural Differences.

Author

Hansen JC, Bjørn-Yoshimoto WE, Bisballe N, Nielsen B, Jensen AA, and Bunch L

Subjects

Biological Transport drug effects, Excitatory Amino Acid Transporter 1 metabolism, Excitatory Amino Acid Transporter 2, Excitatory Amino Acid Transporter 3 metabolism, Glutamate Plasma Membrane Transport Proteins metabolism, HEK293 Cells, Humans, Aspartic Acid analogs & derivatives, Aspartic Acid pharmacology, Excitatory Amino Acid Transporter 1 antagonists & inhibitors, Excitatory Amino Acid Transporter 3 antagonists & inhibitors, Glutamate Plasma Membrane Transport Proteins antagonists & inhibitors, Sulfonamides chemistry, Sulfonamides pharmacology

Abstract

In this study inspired by previous work on 3-substituted Asp analogues, we designed and synthesized a total of 32 β-sulfonamide Asp analogues and characterized their pharmacological properties at the excitatory amino acid transporter subtypes EAAT1, EAAT2, and EAAT3. In addition to several potent EAAT inhibitors displaying IC 50 values ∼1 μM at all three subtypes, this elaborate structure-activity relationship also identified analogues exhibiting distinct preferences or selectivities for specific transporter subtypes. Introduction of two fluorine atoms on the phenyl ring yielded analogue 4y that displayed an IC 50 of 0.8 μM at EAAT1 with a 14- and 9-fold preference over EAAT2 and EAAT3, respectively. Conversely, the m-CF 3 -phenyl analogue 4r was a potent selective EAAT2-inhibitor (IC 50 = 2.8 μM) exhibiting 30- and 50-fold selectivity over EAAT1 and EAAT3, respectively. In conclusion, even small structural differences in these β-sulfonamide Asp analogues provide analogues with diverse EAAT subtype selectivity profiles.

Published

2016