Your search keyword '"Kaley McCluskey"' showing total 16 results

1. DNA replication origins retain mobile licensing proteins

Author

Humberto Sánchez, Kaley McCluskey, Theo van Laar, Edo van Veen, Filip M. Asscher, Belén Solano, John F. X. Diffley, and Nynke H. Dekker

Subjects

Science

Abstract

Eukaryotic DNA replication is regulated to ensure copying of the genome (only) once per cell cycle. Here the authors, using optical trapping and confocal microscopy, demonstrate the dynamics of the origin recognition complex and subsequent intermediates that lead up to the loading of an MCM helicase onto DNA.

Published

2021

2. Principles and best practices of optimizing a micromirror-based multicolor TIRF microscopy system

Author

Kaley McCluskey and Nynke H. Dekker

Subjects

Single-molecule fluorescence microscopy, Micromirror, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, TIRF, CoSMoS, Atomic and Molecular Physics, and Optics, (co)Localization microscopy, Electronic, Optical and Magnetic Materials

Abstract

TIRF (Total Internal Reflection Fluorescence) microscopy is a powerful tool for measuring the intra- and intermolecular dynamics of fluorescently-labeled single molecules. As TIRF measurements move to more complex biological systems with more fluorescent probes, the multi-band-pass dichroic that separates excitation from emission becomes limiting for the microscope’s detection efficiency. To avoid this, multicolor colocalization-based experiments can employ “micromirror” (mm)TIRF, which replaces the dichroic with two 45°-angled rod mirrors that control the TIR excitation beam(s). Whereas a dichroic spectrally separates excitation and emission wavelengths, the micromirrors act to spatially separate the excitation beams from the collected emission photons within the objective lens itself. Comprehensive control of the TIR beam in mmTIRF can yield excellent signal to noise, and hence data quality, but at the price of increased optical complexity. Here, we introduce the theory behind these additional optical components and provide practical advice from our experience on the best way to set up, align, optimize, and maintain a mmTIRF instrument. We also demonstrate the practical effects of small misalignments to illustrate both the optimized signal quality and the degree of accuracy required to achieve it. We hope that this guide increases the accessibility of this type of instrumentation and helps researchers use it to produce data of the highest quality possible.

Published

2023

3. Unprecedented tunability of riboswitch structure and regulatory function by sub-millimolar variations in physiological Mg2+

Author

Adrien Chauvier, Julien Boudreault, Patrick St-Pierre, Pascale B. Beauregard, Adrien Rizzi, Kaley McCluskey, J. Carlos Penedo, Cibran Perez-Gonzalez, Daniel A. Lafontaine, University of St Andrews. School of Physics and Astronomy, University of St Andrews. Biomedical Sciences Research Complex, and University of St Andrews. Centre for Biophotonics

Subjects

Riboswitch, RNA Folding, Transcription, Genetic, QH301 Biology, Aptamer, NDAS, Biology, Ligands, 010402 general chemistry, 01 natural sciences, QH301, 03 medical and health sciences, Gene expression, Fluorescence Resonance Energy Transfer, RNA and RNA-protein complexes, Genetics, Magnesium, 030304 developmental biology, Regulation of gene expression, 0303 health sciences, Ligand, RNA, Gene Expression Regulation, Bacterial, 0104 chemical sciences, Förster resonance energy transfer, Biophysics, Function (biology), Bacillus subtilis

Abstract

Riboswitches are cis-acting regulatory RNA biosensors that rival the efficiency of those found in proteins. At the heart of their regulatory function is the formation of a highly specific aptamer–ligand complex. Understanding how these RNAs recognize the ligand to regulate gene expression at physiological concentrations of Mg2+ ions and ligand is critical given their broad impact on bacterial gene expression and their potential as antibiotic targets. In this work, we used single-molecule FRET and biochemical techniques to demonstrate that Mg2+ ions act as fine-tuning elements of the amino acid-sensing lysC aptamer's ligand-free structure in the mesophile Bacillus subtilis. Mg2+ interactions with the aptamer produce encounter complexes with strikingly different sensitivities to the ligand in different, yet equally accessible, physiological ionic conditions. Our results demonstrate that the aptamer adapts its structure and folding landscape on a Mg2+-tunable scale to efficiently respond to changes in intracellular lysine of more than two orders of magnitude. The remarkable tunability of the lysC aptamer by sub-millimolar variations in the physiological concentration of Mg2+ ions suggests that some single-aptamer riboswitches have exploited the coupling of cellular levels of ligand and divalent metal ions to tightly control gene expression.

Published

2019

4. Global correction of optical distortions in multicolor single-molecule microscopy using Zernike polynomial gradients

Author

Nynke H. Dekker, Wouter Wesselink, Carlas Smith, Edo van Veen, Filip M. Asscher, Kaley McCluskey, and Jelmer Cnossen

Subjects

Physics, 0303 health sciences, business.industry, Zernike polynomials, 010402 general chemistry, 01 natural sciences, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, 03 medical and health sciences, symbols.namesake, Single Molecule Microscopy, Optics, symbols, business, 030304 developmental biology

Abstract

Accurate image alignment is critical in multicolor single-molecule fluorescence microscopy. Global alignment using affine transformations leaves residual errors due to the nonlinearity of the distortions, which decreases the effective field of view. Subsequent local refinement demands either large amounts of reference data and processing time or specialized imaging techniques like active stabilization. Here, we present a global alignment method, S/T polynomial decomposition, that uses sums of Zernike polynomial gradients to decompose the distortion between two images, correcting both linear and nonlinear distortions simultaneously. With minimal reference data, we gain diagnostic information about the distortion and achieve a colocalization accuracy comparable to local registration methods across the entire field of view.

Published

2021

5. Single- and multi-photon shaped illumination for light-sheet fluorescence microscopy (Conference Presentation)

Author

Javier Tello, David E. K. Ferrier, Federico M. Gasparoli, Jonathan Nylk, Kaley McCluskey, Sanya Aggarwal, Adrià Escobet-Montalbán, Kishan Dholakia, Miguel A. Preciado, Frank J. Gunn-Moore, Michael Mazilu, Zhengyi Yang, and Pengfei Liu

Subjects

Presentation, Optics, Materials science, Photon, business.industry, Light sheet fluorescence microscopy, media_common.quotation_subject, business, media_common

Published

2019

6. Light-sheet microscopy with attenuation-compensated propagation-invariant beams

Author

Jonathan, Nylk, Kaley, McCluskey, Miguel A, Preciado, Michael, Mazilu, Zhengyi, Yang, Frank J, Gunn-Moore, Sanya, Aggarwal, Javier A, Tello, David E K, Ferrier, and Kishan, Dholakia

Subjects

SciAdv r-articles, Optics, Research Articles, Research Article, Applied Physics

Abstract

Tailoring beams to overcome attenuation allows light-sheet microscopy to image at greater depth with enhanced contrast., Scattering and absorption limit the penetration of optical fields into tissue. We demonstrate a new approach for increased depth penetration in light-sheet microscopy: attenuation-compensation of the light field. This tailors an exponential intensity increase along the illuminating propagation-invariant field, enabling the redistribution of intensity strategically within a sample to maximize signal and minimize irradiation. A key attribute of this method is that only minimal knowledge of the specimen transmission properties is required. We numerically quantify the imaging capabilities of attenuation-compensated Airy and Bessel light sheets, showing that increased depth penetration is gained without compromising any other beam attributes. This powerful yet straightforward concept, combined with the self-healing properties of the propagation-invariant field, improves the contrast-to-noise ratio of light-sheet microscopy up to eightfold across the entire field of view in thick biological specimens. This improvement can significantly increase the imaging capabilities of light-sheet microscopy techniques using Airy, Bessel, and other propagation-invariant beam types, paving the way for widespread uptake by the biomedical community.

Published

2017

7. An integrated perspective on RNA aptamer ligand-recognition models: clearing muddy waters

Author

J. Carlos Penedo and Kaley McCluskey

Subjects

0301 basic medicine, Riboswitch, Computer science, Aptamer, Perspective (graphical), General Physics and Astronomy, RNA, Nanotechnology, Computational biology, Aptamers, Nucleotide, Ligand (biochemistry), Ligands, RNA Motifs, Intrinsically Disordered Proteins, 03 medical and health sciences, 030104 developmental biology, RNA Aptamers, Gene expression, Nucleic Acid Conformation, Physical and Theoretical Chemistry

Abstract

Riboswitches are short RNA motifs that sensitively and selectively bind cognate ligands to modulate gene expression. Like protein receptor-ligand pairs, their binding dynamics are traditionally categorized as following one of two paradigmatic mechanisms: conformational selection and induced fit. In conformational selection, ligand binding stabilizes a particular state already present in the receptor's dynamic ensemble. In induced fit, ligand-receptor interactions enable the system to overcome the energetic barrier into a previously inaccessible state. In this article, we question whether a polarized division of RNA binding mechanisms truly meets the conceptual needs of the field. We will review the history behind this classification of RNA-ligand interactions, and the way induced fit in particular has been rehabilitated by single-molecule studies of RNA aptamers. We will highlight several recent results from single-molecule experimental studies of riboswitches that reveal gaps or even contradictions between common definitions of the two terms, and we will conclude by proposing a more robust framework that considers the range of RNA behaviors unveiled in recent years as a reality to be described, rather than an increasingly unwieldy set of exceptions to the traditional models.

Published

2017

8. Probing neural tissue with airy light-sheet microscopy: investigation of imaging performance at depth within turbid media

Author

Kishan Dholakia, Sanya Aggarwal, Javier Tello, Jonathan Nylk, Kaley McCluskey, Brown, Thomas G., Cogswell, Carol J., Wilson, Tony, EPSRC, University of St Andrews. School of Physics and Astronomy, University of St Andrews. School of Medicine, and University of St Andrews. Biomedical Sciences Research Complex

Subjects

0301 basic medicine, Materials science, Image quality, QH301 Biology, Airy beam, NS, Tissue imaging, Biomaterials, QH301, 03 medical and health sciences, Optics, Microscopy, LSM, QC, Light-sheet microscopy, business.industry, Scattering, Resolution (electron density), Turbid media, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, QC Physics, 030104 developmental biology, Radiology Nuclear Medicine and imaging, Light sheet fluorescence microscopy, RC0321, business, RC0321 Neuroscience. Biological psychiatry. Neuropsychiatry, Beam (structure), Neuroscience, Gaussian beam

Abstract

Funding: UK Engineering and Physical Sciences Research Council under grant EP/J01771X/1 (KD), the 'BRAINS' 600th anniversary appeal, and Dr. E. Killick; The Northwood Trust and The RS Macdonald Charitable Trust (JAT); Royal Society Leverhulme Trust Senior Fellowship (KD). Light-sheet microscopy (LSM) has received great interest for fluorescent imaging applications in biomedicine as it facilitates three-dimensional visualisation of large sample volumes with high spatiotemporal resolution whilst minimising irradiation of, and photo-damage to the specimen. Despite these advantages, LSM can only visualize superficial layers of turbid tissues, such as mammalian neural tissue. Propagation-invariant light modes have played a key role in the development of high-resolution LSM techniques as they overcome the natural divergence of a Gaussian beam, enabling uniform and thin light-sheets over large distances. Most notably, Bessel and Airy beam-based light-sheet imaging modalities have been demonstrated. In the single-photon excitation regime and in lightly scattering specimens, Airy-LSM has given competitive performance with advanced Bessel-LSM techniques. Airy and Bessel beams share the property of self-healing, the ability of the beam to regenerate its transverse beam profile after propagation around an obstacle. Bessel-LSM techniques have been shown to increase the penetration-depth of the illumination into turbid specimens but this effect has been understudied in biologically relevant tissues, particularly for Airy beams. It is expected that Airy-LSM will give a similar enhancement over Gaussian-LSM. In this paper, we report on the comparison of Airy-LSM and Gaussian-LSM imaging modalities within cleared and non-cleared mouse brain tissue. In particular, we examine image quality versus tissue depth by quantitative spatial Fourier analysis of neural structures in virally transduced fluorescent tissue sections, showing a three-fold enhancement at 50 μm depth into non-cleared tissue with Airy-LSM. Complimentary analysis is performed by resolution measurements in bead-injected tissue sections. Publisher PDF

Published

2017

9. Fluorescence tools to investigate riboswitch structural dynamics

Author

J.C. Penedo, Euan Shaw, Daniel A. Lafontaine, Patrick St-Pierre, and Kaley McCluskey

Subjects

Riboswitch, Chemistry, Aptamer, Biophysics, Context (language use), Single-molecule FRET, Biochemistry, Fluorescence, Folding (chemistry), Förster resonance energy transfer, Structural Biology, Genetics, Molecular Biology

Abstract

Riboswitches are novel regulatory elements that respond to cellular metabolites to control gene expression. They are constituted of highly conserved domains that have evolved to recognize specific metabolites. Such domains, so-called aptamers, are folded into intricate structures to enable metabolite recognition. Over the years, the development of ensemble and single-molecule fluorescence techniques has allowed to probe most of the mechanistic aspects of aptamer folding and ligand binding. In this review, we summarize the current fluorescence toolkit available to study riboswitch structural dynamics. We fist describe those methods based on fluorescent nucleotide analogues, mostly 2-aminopurine (2AP), to investigate short-range conformational changes, including some key steady-state and time-resolved examples that exemplify the versatility of fluorescent analogues as structural probes. The study of long-range structural changes by Forster resonance energy transfer (FRET) is mostly discussed in the context of single-molecule studies, including some recent developments based on the combination of single-molecule FRET techniques with controlled chemical denaturation methods. This article is part of a Special Issue entitled: Riboswitches.

Published

2014

10. Enhancement of image quality and imaging depth with Airy light-sheet microscopy in cleared and non-cleared neural tissue

Author

Jonathan, Nylk, Kaley, McCluskey, Sanya, Aggarwal, Javier A, Tello, and Kishan, Dholakia

Subjects

ocis:(070.0070) Fourier optics and signal processing, ocis:(100.2980) Image enhancement, ocis:(180.2520) Fluorescence microscopy, ocis:(170.3880) Medical and biological imaging, ocis:(180.0180) Microscopy, ocis:(100.2960) Image analysis, Article

Abstract

We have investigated the effect of Airy illumination on the image quality and depth penetration of digitally scanned light-sheet microscopy in turbid neural tissue. We used Fourier analysis of images acquired using Gaussian and Airy light-sheets to assess their respective image quality versus penetration into the tissue. We observed a three-fold average improvement in image quality at 50 μm depth with the Airy light-sheet. We also used optical clearing to tune the scattering properties of the tissue and found that the improvement when using an Airy light-sheet is greater in the presence of stronger sample-induced aberrations. Finally, we used homogeneous resolution probes in these tissues to quantify absolute depth penetration in cleared samples with each beam type. The Airy light-sheet method extended depth penetration by 30% compared to a Gaussian light-sheet.

Published

2016

11. Using sm-FRET and denaturants to reveal folding landscapes

Author

Euan, Shaw, Patrick, St-Pierre, Kaley, McCluskey, Daniel A, Lafontaine, and J Carlos, Penedo

Subjects

RNA Folding, Base Sequence, Metals, Riboswitch, Adenine, Molecular Sequence Data, Fluorescence Resonance Energy Transfer, Animals, Humans, Nucleic Acid Conformation, RNA, Aptamers, Nucleotide, Nucleic Acid Denaturation

Abstract

RNA folding studies aim to clarify the relationship among sequence, tridimensional structure, and biological function. In the last decade, the application of single-molecule fluorescence resonance energy transfer (sm-FRET) techniques to investigate RNA structure and folding has revealed the details of conformational changes and timescale of the process leading to the formation of biologically active RNA structures with subnanometer resolution on millisecond timescales. In this review, we initially summarize the first wave of single-molecule FRET-based RNA techniques that focused on analyzing the influence of mono- and divalent metal ions on RNA function, and how these studies have provided very valuable information about folding pathways and the presence of intermediate and low-populated states. Next, we describe a second generation of single-molecule techniques that combine sm-FRET with the use of chemical denaturants as an emerging powerful approach to reveal information about the dynamics and energetics of RNA folding that remains hidden using conventional sm-FRET approaches. The main advantages of using the competing interplay between folding agents such as metal ions and denaturants to observe and manipulate the dynamics of RNA folding and RNA-ligand interactions is discussed in the context of the adenine riboswitch aptamer.

Published

2014

12. Fluorescence tools to investigate riboswitch structural dynamics

Author

Patrick, St-Pierre, Kaley, McCluskey, Euan, Shaw, J C, Penedo, and D A, Lafontaine

Abstract

Riboswitches are novel regulatory elements that respond to cellular metabolites to control gene expression. They are constituted of highly conserved domains that have evolved to recognize specific metabolites. Such domains, so-called aptamers, are folded into intricate structures to enable metabolite recognition. Over the years, the development of ensemble and single-molecule fluorescence techniques has allowed to probe most of the mechanistic aspects of aptamer folding and ligand binding. In this review, we summarize the current fluorescence toolkit available to study riboswitch structural dynamics. We fist describe those methods based on fluorescent nucleotide analogues, mostly 2-aminopurine (2AP), to investigate short-range conformational changes, including some key steady-state and time-resolved examples that exemplify the versatility of fluorescent analogues as structural probes. The study of long-range structural changes by Förster resonance energy transfer (FRET) is mostly discussed in the context of single-molecule studies, including some recent developments based on the combination of single-molecule FRET techniques with controlled chemical denaturation methods. This article is part of a Special Issue entitled: Riboswitches.

Published

2014

13. Using sm-FRET and Denaturants to Reveal Folding Landscapes

Author

Patrick St-Pierre, Euan Shaw, Daniel A. Lafontaine, J. Carlos Penedo, and Kaley McCluskey

Subjects

Folding (chemistry), Riboswitch, Förster resonance energy transfer, Chemistry, Aptamer, Biophysics, RNA, Context (language use), Nanotechnology, Single-molecule FRET, Nucleic acid structure

Abstract

RNA folding studies aim to clarify the relationship among sequence, tridimensional structure, and biological function. In the last decade, the application of single-molecule fluorescence resonance energy transfer (sm-FRET) techniques to investigate RNA structure and folding has revealed the details of conformational changes and timescale of the process leading to the formation of biologically active RNA structures with subnanometer resolution on millisecond timescales. In this review, we initially summarize the first wave of single-molecule FRET-based RNA techniques that focused on analyzing the influence of mono- and divalent metal ions on RNA function, and how these studies have provided very valuable information about folding pathways and the presence of intermediate and low-populated states. Next, we describe a second generation of single-molecule techniques that combine sm-FRET with the use of chemical denaturants as an emerging powerful approach to reveal information about the dynamics and energetics of RNA folding that remains hidden using conventional sm-FRET approaches. The main advantages of using the competing interplay between folding agents such as metal ions and denaturants to observe and manipulate the dynamics of RNA folding and RNA-ligand interactions is discussed in the context of the adenine riboswitch aptamer.

Published

2014

14. Single-molecule fluorescence of nucleic acids

Author

Kaley, McCluskey, Euan, Shaw, Daniel A, Lafontaine, and J Carlos, Penedo

Subjects

Spectrometry, Fluorescence, Fluorescence Resonance Energy Transfer, Nanotechnology, Nucleic Acid Conformation, RNA, DNA, Fluorescence

Abstract

Single-molecule fluorescence studies of nucleic acids are revolutionizing our understanding of fundamental cellular processes related to DNA and RNA processing mechanisms. Detailed molecular insights into DNA repair, replication, transcription, and RNA folding and function are continuously being uncovered by using the full repertoire of single-molecule fluorescence techniques. The fundamental reason behind the stunning growth in the application of single-molecule techniques to study nucleic acid structure and dynamics is the unmatched ability of single-molecule fluorescence, and mostly single-molecule FRET, to resolve heterogeneous static and dynamic populations and identify transient and low-populated states without the need for sample synchronization. New advances in DNA and RNA synthesis, post-synthetic dye-labeling methods, immobilization and passivation strategies, improved dye photophysics, and standardized analysis methods have enabled the implementation of single-molecule techniques beyond specialized laboratories. In this chapter, we introduce the practical aspects of applying single-molecule techniques to investigate nucleic acid structure, dynamics, and function.

Published

2013

15. Single-Molecule Fluorescence of Nucleic Acids

Author

J. Carlos Penedo, Kaley McCluskey, Daniel A. Lafontaine, and Euan Shaw

Subjects

chemistry.chemical_compound, Förster resonance energy transfer, Nucleic acid quantitation, Transcription (biology), Chemistry, DNA repair, Nucleic acid, Computational biology, Nucleic acid structure, Single-molecule experiment, DNA

Abstract

Single-molecule fluorescence studies of nucleic acids are revolutionizing our understanding of fundamental cellular processes related to DNA and RNA processing mechanisms. Detailed molecular insights into DNA repair, replication, transcription, and RNA folding and function are continuously being uncovered by using the full repertoire of single-molecule fluorescence techniques. The fundamental reason behind the stunning growth in the application of single-molecule techniques to study nucleic acid structure and dynamics is the unmatched ability of single-molecule fluorescence, and mostly single-molecule FRET, to resolve heterogeneous static and dynamic populations and identify transient and low-populated states without the need for sample synchronization. New advances in DNA and RNA synthesis, post-synthetic dye-labeling methods, immobilization and passivation strategies, improved dye photophysics, and standardized analysis methods have enabled the implementation of single-molecule techniques beyond specialized laboratories. In this chapter, we introduce the practical aspects of applying single-molecule techniques to investigate nucleic acid structure, dynamics, and function.

Published

2013

16. Structure and Functional Dynamics of Fluoride-Sensing Riboswitches

Author

Kaley McCluskey and J. Carlos Penedo

Subjects

Riboswitch, Messenger RNA, Conformational change, endocrine system, Biophysics, Biology, chemistry.chemical_compound, Förster resonance energy transfer, Biochemistry, chemistry, Transcription (biology), Gene expression, Gene, Fluoride, human activities

Abstract

Riboswitches are gene-regulatory RNA motifs located in the 5' untranslated regions of certain bacterial mRNA's. Riboswitches regulate gene expression by binding a metabolite related to the downstream gene, causing a conformational change that alters the accessibility of the gene for either transcription or translation. An important class of riboswitches that bind fluoride (F-) has been identified recently in bacteria and archaea, shedding light on how these organisms regulate internal fluoride concentrations to mitigate toxicity. The crystal structure of the fluoride riboswitch from Thermophilus petrophila shows a binding pocket in which the F- ion is coordinated by three Mg2+ ions. However, how ligand recognition and RNA folding are coupled to selectively encapsulate F- is not fully understood. Here, single-molecule TIRF microscopy and FRET are used to gain insights into the functional dynamics of fluoride riboswitches. Individual fluorescently-labelled fluoride riboswitches are immobilized on a quartz microscope slide, and the change in FRET efficiency between the fluorophors is used to study the ligand-binding mechanism and other cation- or denaturant-dependent structural transitions.