Your search keyword '"Marcus AH"' showing total 86 results

1. Plant-wide modelling and analysis of WWTP temperature dynamics for sustainable heat recovery from wastewater

Author

Magnus Arnell, Marcus Ahlström, Christoffer Wärff, Ramesh Saagi, and Ulf Jeppsson

Subjects

energy and heat balance, mathematical modelling, resource recovery, temperature, wastewater heat recovery, wastewater treatment plant, Environmental technology. Sanitary engineering, TD1-1066

Abstract

Wastewater heat recovery upstream of wastewater treatment plants (WWTPs) poses a risk to treatment performance, i.e. the biological processes. In order to perform a sustainability analysis, a detailed prediction of the temperature dynamics over the WWTP is needed. A comprehensive set of heat balance equations was included in a plant-wide process model and validated for the WWTP in Linköping, Sweden, to predict temperature variations over the whole year in a temperate climate. A detailed model for the excess heat generation of biological processes was developed. The annual average temperature change from influent to effluent was 0.78 °C with clear seasonal variations; 45% of the temperature change arises from processes other than the activated sludge unit. Hence, plant-wide energy modelling was necessary to predict in-tank temperature in the biological treatment steps. The energy processes with the largest energy gains were solar radiation and biological processes, while the largest losses were from conduction, convection and atmospheric radiation. Tanks with large surface areas have a significant impact on the heat balance regardless of biological processes. Simulating a 3 °C lower influent temperature, the temperature in the activated sludge unit dropped by 2.8 °C, which had a negative impact on nitrogen removal. HIGHLIGHTS The annual average temperature change (ΔT) was +0.78 °C from influent to effluent.; Biological processes had the largest energy contribution.; 45% of ΔT arises from other processes than activated sludge. Hence, plant-wide energy modelling is necessary.; ΔT shows strong seasonal variation in colder climates. Dynamic parameters are necessary.; Tanks with large open surface areas have significant impact on the heat balance.;

Published

2021

2. Pathways of Lead Contamination for the Brigham and Women's Hospital Longitudinal Lead Study

Author

Menton, RG, primary, Burgoon, DA, additional, and Marcus, AH, additional

3. Estimating the Contribution of Lead-Based Paint to Soil Lead, Dust Lead, and Childhood Blood Lead

Author

Marcus, AH, primary and Elias, RW, additional

4. Effectiveness of struvite precipitation and ammonia stripping for recovery of phosphorus and nitrogen from anaerobic digestate: a systematic review

Author

Dag Lorick, Biljana Macura, Marcus Ahlström, Anders Grimvall, and Robin Harder

Subjects

Circular economy, Wastewater treatment, Manure management, Environmental sciences, GE1-350

Abstract

Abstract Background A regular supply of nutrients such as nitrogen and phosphorus to agriculture is needed for global food security, and increased recycling of nutrients back to agriculture from organic waste streams is necessary for increased rural–urban sustainability. Anaerobic digestion of sewage sludge and agricultural wastes is widely applied to stabilize the substrate and capture some of its energetic value via biogas production. Anaerobic digestate is a concentrated source of nutrients to which nutrient recovery technologies can be applied. By combining anaerobic digestion and nutrient recovery technologies on the digestate, both energy and nutrient recovery can be achieved. Two promising technologies that could increase nutrient recycling from different types of wastewater are struvite precipitation and ammonia stripping. This review examined the effectiveness of these ecotechnologies for the recovery of nitrogen and phosphorus from anaerobic digestate with the aim of reducing the impact of waste on the environment. Methods We searched for academic and grey literature published after 2013. Searches were performed in 5 bibliographic databases in English, in the search engine Google Scholar in English, Swedish, Finnish and Polish, and across a range of organisational websites in English, Swedish, Finnish and Polish. Eligibility screening was conducted at two levels: ‘title and abstract’ and ‘full text’. Included eligible studies were subject to a critical appraisal that assessed external and internal study validity. We extracted information on study characteristics, intervention, comparators, effect modifiers, and measured outcomes. Data synthesis included narrative synthesis of each study of sufficient validity. We performed quantitative synthesis on a subset of studies. Review findings The review included 30 studies on struvite precipitation and 8 studies on ammonia stripping. Both pH and Mg:PO4 ratio were found to have a clear influence on the effectiveness of struvite precipitation process (and thus nutrient removal rates). The response to pH was found to be non-linear, resembling a bell curve with a maximum around pH 9.5. Mg:PO4 ratio was found to have a positive effect on removal up to a ratio as high as 4:1. However, it should be noted that high removal efficiencies were sometimes achieved at a ratio as low as 1:1 as well. Although the effects of pH and Mg:PO4 ratio were clear, the model developed could not accurately predict removal based on these two parameters alone. Studies on ammonia stripping were relatively heterogeneous. Due to the small size of the evidence base, and the heterogeneity between studies, no conclusions are presented regarding the influence of different process parameters on the outcome of ammonia stripping. Conclusions In conclusion, when performed under the right conditions (i.e. pH around 9.5 and Mg:PO4 ratio of at least 1:1), available evidence suggests that struvite precipitation is an effective technology for the recovery of nutrients from the liquid phase of anaerobic digestate. The evidence base is limited for ammonia stripping. We provided suggestions of which data to report in future studies.

Published

2020

5. Probabilistic classification of anti‐SARS‐CoV‐2 antibody responses improves seroprevalence estimates

Author

Xaquin Castro Dopico, Sandra Muschiol, Nastasiya F Grinberg, Soo Aleman, Daniel J Sheward, Leo Hanke, Marcus Ahl, Linnea Vikström, Mattias Forsell, Jonathan M Coquet, Gerald McInerney, Joakim Dillner, Gordana Bogdanovic, Ben Murrell, Jan Albert, Chris Wallace, and Gunilla B Karlsson Hedestam

Subjects

antibody responses, antibody testing, COVID‐19, probability, SARS‐CoV‐2, serology, Immunologic diseases. Allergy, RC581-607

Abstract

Abstract Objectives Population‐level measures of seropositivity are critical for understanding the epidemiology of an emerging pathogen, yet most antibody tests apply a strict cutoff for seropositivity that is not learnt in a data‐driven manner, leading to uncertainty when classifying low‐titer responses. To improve upon this, we evaluated cutoff‐independent methods for their ability to assign likelihood of SARS‐CoV‐2 seropositivity to individual samples. Methods Using robust ELISAs based on SARS‐CoV‐2 spike (S) and the receptor‐binding domain (RBD), we profiled antibody responses in a group of SARS‐CoV‐2 PCR+ individuals (n = 138). Using these data, we trained probabilistic learners to assign likelihood of seropositivity to test samples of unknown serostatus (n = 5100), identifying a support vector machines‐linear discriminant analysis learner (SVM‐LDA) suited for this purpose. Results In the training data from confirmed ancestral SARS‐CoV‐2 infections, 99% of participants had detectable anti‐S and ‐RBD IgG in the circulation, with titers differing > 1000‐fold between persons. In data of otherwise healthy individuals, 7.2% (n = 367) of samples were of uncertain serostatus, with values in the range of 3‐6SD from the mean of pre‐pandemic negative controls (n = 595). In contrast, SVM‐LDA classified 6.4% (n = 328) of test samples as having a high likelihood (> 99% chance) of past infection, 4.5% (n = 230) to have a 50–99% likelihood, and 4.0% (n = 203) to have a 10–49% likelihood. As different probabilistic approaches were more consistent with each other than conventional SD‐based methods, such tools allow for more statistically‐sound seropositivity estimates in large cohorts. Conclusion Probabilistic antibody testing frameworks can improve seropositivity estimates in populations with large titer variability.

Published

2022

6. sOrTES: A Supportive Tool for Stochastic Scheduling of Manual Integration Test Cases

Author

Sahar Tahvili, Rita Pimentel, Wasif Afzal, Marcus Ahlberg, Eric Fornander, and Markus Bohlin

Subjects

Software testing, integration testing, test optimization, decision support systems, stochastic test scheduling, manual testing, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The main goal of software testing is to detect as many hidden bugs as possible in the final software product before release. Generally, a software product is tested by executing a set of test cases, which can be performed manually or automatically. The number of test cases which are required to test a software product depends on several parameters such as the product type, size, and complexity. Executing all test cases with no particular order can lead to waste of time and resources. Test optimization can provide a partial solution for saving time and resources which can lead to the final software product being released earlier. In this regard, test case selection, prioritization, and scheduling can be considered as possible solutions for test optimization. Most of the companies do not provide direct support for ranking test cases on their own servers. In this paper, we introduce, apply, and evaluate sOrTES as our decision support system for manual integration of test scheduling. sOrTES is a Python-based supportive tool which schedules manual integration test cases which are written in a natural language text. The feasibility of sOrTES is studied by an empirical evaluation which has been performed on a railway use-case at Bombardier Transportation, Sweden. The empirical evaluation indicates that around 40 % of testing failure can be avoided by using the proposed execution schedules by sOrTES, which leads to an increase in the requirements coverage of up to 9.6%.

Published

2019

7. Molecular Dynamical and Quantum Mechanical Exploration of the Site-Specific Dynamics of Cy3 Dimers Internally Linked to dsDNA.

Author

Sorour MI, Kistler KA, Marcus AH, and Matsika S

Subjects

Carbocyanines chemistry, Dimerization, DNA chemistry, Molecular Dynamics Simulation, Quantum Theory

Abstract

Performing spectroscopic measurements on biomolecules labeled with fluorescent probes is a powerful approach to locating the molecular behavior and dynamics of large systems at specific sites within their local environments. The indocarbocyanine dye Cy3 has emerged as one of the most commonly used chromophores. The incorporation of Cy3 dimers into DNA enhances experimental resolution owing to the spectral characteristics influenced by the geometric orientation of excitonically coupled monomeric units. Various theoretical models and simulations have been utilized to aid in the interpretation of the experimental spectra. In this study, we employ all-atom molecular dynamics simulations to study the structural dynamics of Cy3 dimers internally linked to the dsDNA backbone. We used quantum mechanical calculations to derive insights from both the linear absorption spectra and the circular dichroism data. Furthermore, we explore potential limitations within a commonly used force field for cyanine dyes. The molecular dynamics simulations suggest the presence of four possible Cy3 dimeric populations. The spectral simulations on the four populations show one of them to agree better with the experimental signatures, suggesting it to be the dominant population. The relative orientation of Cy3 in this population compares very well with previous predictions from the Holstein-Frenkel Hamiltonian model.

Published

2024

8. Spectroscopic approaches for studies of site-specific DNA base and backbone 'breathing' using exciton-coupled dimer-labeled DNA.

Author

Marcus AH, Matsika S, Heussman D, Sorour MI, Maurer J, Albrecht CS, Enkhbaatar L, Herbert P, Kistler KA, and von Hippel PH

Abstract

DNA regulation and repair processes require direct interactions between proteins and DNA at specific sites. Local fluctuations of the sugar-phosphate backbones and bases of DNA (a form of DNA 'breathing') play a central role in such processes. Here we review the development and application of novel spectroscopic methods and analyses - both at the ensemble and single-molecule levels - to study structural and dynamic properties of exciton-coupled cyanine and fluorescent nucleobase analogue dimer-labeled DNA constructs at key positions involved in protein-DNA complex assembly and function. The exciton-coupled dimer probes act as 'sensors' of the local conformations adopted by the sugar-phosphate backbones and bases immediately surrounding the dimer probes. These methods can be used to study the mechanisms of protein binding and function at these sites.

Published

2024

9. Using transition density models to interpret experimental optical spectra of exciton-coupled cyanine (iCy3)2 dimer probes of local DNA conformations at or near functional protein binding sites.

Author

Heussman D, Enkhbaatar L, Sorour MI, Kistler KA, von Hippel PH, Matsika S, and Marcus AH

Subjects

Protein Binding, Nucleic Acid Conformation, Circular Dichroism, Binding Sites, DNA chemistry, Molecular Probes

Abstract

Exciton-coupled chromophore dimers are an emerging class of optical probes for studies of site-specific biomolecular interactions. Applying accurate theoretical models for the electrostatic coupling of a molecular dimer probe is a key step for simulating its optical properties and analyzing spectroscopic data. In this work, we compare experimental absorbance and circular dichroism (CD) spectra of 'internally-labeled' (iCy3)2 dimer probes inserted site-specifically into DNA fork constructs to theoretical calculations of the structure and geometry of these exciton-coupled dimers. We compare transition density models of varying levels of approximation to determine conformational parameters of the (iCy3)2 dimer-labeled DNA fork constructs. By applying an atomistically detailed transition charge (TQ) model, we can distinguish between dimer conformations in which the stacking and tilt angles between planar iCy3 monomers are varied. A major strength of this approach is that the local conformations of the (iCy3)2 dimer probes that we determined can be used to infer information about the structures of the DNA framework immediately surrounding the probes at various positions within the constructs, both deep in the duplex DNA sequences and at sites at or near the DNA fork junctions where protein complexes bind to discharge their biological functions., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2024

10. Two-photon excitation two-dimensional fluorescence spectroscopy (2PE-2DFS) of the fluorescent nucleobase 6-MI.

Author

Albrecht CS, Scatena LF, von Hippel PH, and Marcus AH

Abstract

Base stacking is fundamentally important to the stability of double-stranded DNA. However, few experiments can directly probe the local conformations and conformational fluctuations of the DNA bases. Here we report a new spectroscopic approach to study the local conformations of DNA bases using the UV-absorbing fluorescent guanine analogue, 6-methyl isoxanthopterin (6-MI), which can be used as a site-specific probe to label DNA. In these experiments, we apply a two-photon excitation (2PE) approach to two-dimensional fluorescence spectroscopy (2DFS), which is a fluorescence-detected nonlinear Fourier transform spectroscopy. In 2DFS, a repeating sequence of four collinear laser pulses (with center wavelength ~ 675 nm and relative phases swept at radio frequencies) is used to excite the lowest energy electronic-vibrational (vibronic) transitions of 6-MI (with center wavelength ~ 340 nm). The ensuing low flux fluorescence is phase-synchronously detected at the level of individual photons and as a function of inter-pulse delay. The 2PE transition pathways that give rise to electronically excited state populations include optical coherences between electronic ground and excited states and non-resonant (one-photon-excited) virtual states. Our results indicate that 2PE-2DFS experiments can provide information about the electronic-vibrational spectrum of the 6-MI monomer, in addition to the conformation-dependent exciton coupling between adjacent 6-MI monomers within a (6-MI) 2 dimer. In principle, this approach can be used to determine the local base-stacking conformations of (6-MI) 2 dimer-substituted DNA constructs.

Published

2024

11. Studies of DNA breathing in exciton-coupled (iCy3) 2 dimer-labeled DNA constructs by polarization-sweep single-molecule fluorescence (PS-SMF) microscopy.

Author

Maurer J, Albrecht CS, Herbert P, Heussman D, Chang A, von Hippel PH, and Marcus AH

Abstract

Local fluctuations of the sugar-phosphate backbones and bases of DNA (a form of DNA 'breathing') play a central role in the assembly of protein-DNA complexes. We present a single-molecule fluorescence method to sensitively measure the local conformational fluctuations of exciton-coupled cyanine [(iCy3) 2 ] dimer-labeled DNA fork constructs in which the dimer probes are placed at varying positions relative to the DNA fork junction. These systems exhibit spectroscopic signals that are sensitive to the local conformations adopted by the sugar-phosphate backbones and bases immediately surrounding the dimer probe label positions. The (iCy3) 2 dimer has one symmetric (+) and one anti-symmetric (-) exciton with respective transition dipole moments oriented perpendicular to one another. We excite single molecule samples using a continuous-wave, linearly polarized laser with its polarization direction rotated at a frequency of 1 MHz. The ensuing fluorescence signal is modulated as the laser polarization alternately excites the symmetric and anti-symmetric excitons of the (iCy3) 2 dimer probe. Phase-sensitive detection of the signal at the photon-counting level provides information about the distribution of local conformations and conformational dynamics. We analyze our data using a kinetic network model, which we use to parametrize the free energy surface of the system. In addition to observing DNA breathing at and near ss-dsDNA junctions, the approach can be used to study the effects of proteins that bind and function at these sites.

Published

2024

12. Studies of DNA 'Breathing' by Polarization-Sweep Single-Molecule Fluorescence Microscopy of Exciton-Coupled (iCy3) 2 Dimer-Labeled DNA Fork Constructs.

Author

Maurer J, Albrecht CS, Herbert P, Heussman D, Chang A, von Hippel PH, and Marcus AH

Subjects

Molecular Conformation, Spectrometry, Fluorescence, Microscopy, Fluorescence, DNA metabolism, DNA Replication

Abstract

Local fluctuations of the sugar-phosphate backbones and bases of DNA (often called DNA 'breathing') play a variety of critical roles in controlling the functional interactions of the DNA genome with the protein complexes that regulate it. Here, we present a single-molecule fluorescence method that we have used to measure and characterize such conformational fluctuations at and near biologically important positions in model DNA replication fork constructs labeled with exciton-coupled cyanine [(iCy3) 2 ] dimer probes. Previous work has shown that the constructs that we tested here exhibit a broad range of spectral properties at the ensemble level, and these differences can be structurally and dynamically interpreted using our present methodology at the single-molecule level. The (iCy3) 2 dimer has one symmetric (+) and one antisymmetric (-) exciton, with the respective transition dipole moments oriented perpendicular to one another. We excite single-molecule samples using a continuous-wave linearly polarized laser, with the polarization direction continuously rotated at the frequency of 1 MHz. The ensuing fluorescence signal is modulated as the laser polarization alternately excites the symmetric and antisymmetric excitons of the (iCy3) 2 dimer probe. Phase-sensitive detection of the modulated signal provides information about the distribution of local conformations and the conformational interconversion dynamics of the (iCy3) 2 probe. We find that at most construct positions that we examined, the (iCy3) 2 dimer-labeled DNA fork constructs can adopt four topologically distinct conformational macrostates. These results suggest that in addition to observing DNA breathing at and near ss-dsDNA junctions, our new methodology should be useful to determine which of these pre-existing macrostates are recognized by, bind to, and are stabilized by various genome-regulatory proteins.

Published

2023

13. Unravelling the Origin of the Vibronic Spectral Signatures in an Excitonically Coupled Indocarbocyanine Cy3 Dimer.

Author

Sorour MI, Marcus AH, and Matsika S

Abstract

The indocarbocyanine Cy3 dye is widely used to probe the dynamics of proteins and DNA. Excitonically coupled Cy3 dimers exhibit very unique spectral signatures that depend on the interchromophoric geometrical orientation induced by the environment, making them powerful tools to infer the dynamics of their surroundings. Understanding the origin of the dimeric spectral signatures is a necessity for an accurate interpretation of the experimental results. In this work, we simulate the vibronic spectrum of an experimentally well-studied Cy3 dimer, and we explain the origin of the experimental signatures present in its linear absorption spectrum. The Franck-Condon harmonic approximations, among other tests, are used to probe the factors contributing to the spectrum. It is found that the first peak in the absorption spectrum originates from the lower energy excitonic state, while the next two peaks are vibrational progressions of the higher energy excitonic state. The polar solvent plays a crucial role in the appearance of the spectrum, being responsible for the localized S 1 minimum, which results in an increased intensity of the first peak.

Published

2023

14. Studies of Local DNA Backbone Conformation and Conformational Disorder Using Site-Specific Exciton-Coupled Dimer Probe Spectroscopy.

Author

Marcus AH, Heussman D, Maurer J, Albrecht CS, Herbert P, and von Hippel PH

Subjects

Nucleic Acid Conformation, Spectrometry, Fluorescence, Phosphates, Sugars, DNA chemistry, DNA, Single-Stranded

Abstract

The processes of genome expression, regulation, and repair require direct interactions between proteins and DNA at specific sites located at and near single-stranded-double-stranded DNA (ssDNA-dsDNA) junctions. Here, we review the application of recently developed spectroscopic methods and analyses that combine linear absorbance and circular dichroism spectroscopy with nonlinear 2D fluorescence spectroscopy to study the local conformations and conformational disorder of the sugar-phosphate backbones of ssDNA-dsDNA fork constructs that have been internally labeled with exciton-coupled cyanine (iCy3) 2 dimer probes. With the application of these methods, the (iCy3) 2 dimer can serve as a reliable probe of the mean local conformations and conformational distributions of the sugar-phosphate backbones of dsDNA at various critical positions. The results of our studies suggest a possible structural framework for understanding the roles of DNA breathing in driving the processes of protein-DNA complex assembly and function.

Published

2023

15. JCP special topic on quantum light in physical chemistry and molecular spectroscopy.

Author

Marcus AH and Raymer MG

Subjects

Chemistry, Physical, Spectrum Analysis

Published

2022

16. Modeling the Electronic Absorption Spectra of the Indocarbocyanine Cy3.

Author

Sorour MI, Marcus AH, and Matsika S

Subjects

Chemical Phenomena, Molecular Structure, Solvents chemistry, Electronics, Vibration

Abstract

Accurate modeling of optical spectra requires careful treatment of the molecular structures and vibronic, environmental, and thermal contributions. The accuracy of the computational methods used to simulate absorption spectra is limited by their ability to account for all the factors that affect the spectral shapes and energetics. The ensemble-based approaches are widely used to model the absorption spectra of molecules in the condensed-phase, and their performance is system dependent. The Franck-Condon approach is suitable for simulating high resolution spectra of rigid systems, and its accuracy is limited mainly by the harmonic approximation. In this work, the absorption spectrum of the widely used cyanine Cy3 is simulated using the ensemble approach via classical and quantum sampling, as well as, the Franck-Condon approach. The factors limiting the ensemble approaches, including the sampling and force field effects, are tested, while the vertical and adiabatic harmonic approximations of the Franck-Condon approach are also systematically examined. Our results show that all the vertical methods, including the ensemble approach, are not suitable to model the absorption spectrum of Cy3, and recommend the adiabatic methods as suitable approaches for the modeling of spectra with strong vibronic contributions. We find that the thermal effects, the low frequency modes, and the simultaneous vibrational excitations have prominent contributions to the Cy3 spectrum. The inclusion of the solvent stabilizes the energetics significantly, while its negligible effect on the spectral shapes aligns well with the experimental observations.

Published

2022

17. Temperature-dependent local conformations and conformational distributions of cyanine dimer labeled single-stranded-double-stranded DNA junctions by 2D fluorescence spectroscopy.

Author

Heussman D, Kittell J, von Hippel PH, and Marcus AH

Subjects

Coloring Agents, Nucleic Acid Conformation, Phosphates, Spectrometry, Fluorescence, Sugars, Temperature, DNA, Single-Stranded chemistry, Quinolines

Abstract

DNA replication and the related processes of genome expression require binding, assembly, and function of protein complexes at and near single-stranded (ss)-double-stranded (ds) DNA junctions. These central protein-DNA interactions are likely influenced by thermally induced conformational fluctuations of the DNA scaffold across an unknown distribution of functionally relevant states to provide regulatory proteins access to properly conformed DNA binding sites. Thus, characterizing the nature of conformational fluctuations and the associated structural disorder at ss-dsDNA junctions is critical for understanding the molecular mechanisms of these central biological processes. Here, we describe spectroscopic studies of model ss-dsDNA fork constructs that contain dimers of "internally labeled" cyanine (iCy3) chromophore probes that have been rigidly inserted within the sugar-phosphate backbones of the DNA strands. Our combined analyses of absorbance, circular dichroism, and two-dimensional fluorescence spectroscopy permit us to characterize the local conformational parameters and conformational distributions. We find that the DNA sugar-phosphate backbones undergo abrupt successive changes in their local conformations-initially from a right-handed and ordered DNA state to a disordered splayed-open structure and then to a disordered left-handed conformation-as the dimer probes are moved across the ss-dsDNA junction. Our results suggest that the sugar-phosphate backbones at and near ss-dsDNA junctions adopt specific position-dependent local conformations and exhibit varying extents of conformational disorder that deviate widely from the Watson-Crick structure. We suggest that some of these conformations can function as secondary-structure motifs for interaction with protein complexes that bind to and assemble at these sites.

Published

2022

18. Accurate Modeling of Excitonic Coupling in Cyanine Dye Cy3.

Author

Sorour MI, Kistler KA, Marcus AH, and Matsika S

Abstract

Accurate modeling of excitonic coupling in molecules is of great importance for inferring the structures and dynamics of coupled systems. Cy3 is a cyanine dye that is widely used in molecular spectroscopy. Its well-separated excitation bands, high sensitivity to the surroundings, and the high energy transfer efficiency make it a perfect choice for excitonic coupling experiments. Many methods have been used to model the excitonic coupling in molecules with varying degrees of accuracy. The atomic transition charge model offers a high-accuracy and cost-effective way to calculating the excitonic coupling. The main focus of this work is to generate high-quality atomic transition charges that can accurately model the Cy3 dye's transition density. The transition density of the excitation of the ground to first excited state is calculated using configuration-interaction singles and time-dependent density functional theory and is benchmarked against the algebraic diagrammatic construction method. Using the transition density we derived the atomic transition charges using two approaches: Mulliken population analysis and charges fitted to the transition electrostatic potential. The quality of the charges is examined, and their ability to accurately calculate the excitonic coupling is assessed via comparison to experimental data of an artificial biscyanine construct. Theoretical comparisons to the supermolecule ab initio couplings and the widely used point-dipole approximation are also made. Results show that using the transition electrostatic potential is a reliable approach for generating the transition atomic charges. A high-quality set of charges, that can be used to model the Cy3 dye dimer excitonic coupling with high-accuracy and a reasonable computational cost, is obtained.

Published

2021

19. Entangled two-photon absorption by atoms and molecules: A quantum optics tutorial.

Author

Raymer MG, Landes T, and Marcus AH

Abstract

Two-photon absorption (TPA) and other nonlinear interactions of molecules with time-frequency-entangled photon pairs have been predicted to display a variety of fascinating effects. Therefore, their potential use in practical quantum-enhanced molecular spectroscopy requires close examination. This Tutorial presents a detailed theoretical study of one- and two-photon absorption by molecules, focusing on how to treat the quantum nature of light. We review some basic quantum optics theory and then we review the density-matrix (Liouville) derivation of molecular optical response, emphasizing how to incorporate quantum states of light into the treatment. For illustration, we treat in detail the TPA of photon pairs created by spontaneous parametric down conversion, with an emphasis on how quantum light TPA differs from that with classical light. In particular, we treat the question of how much enhancement of the TPA rate can be achieved using entangled states. This Tutorial includes a review of known theoretical methods and results as well as some extensions, especially the comparison of TPA processes that occur via far-off-resonant intermediate states only and those that involve off-resonant intermediate states by virtue of dephasing processes. A brief discussion of the main challenges facing experimental studies of entangled two-photon absorption is also given.

Published

2021

20. Submillisecond Conformational Transitions of Short Single-Stranded DNA Lattices by Photon Correlation Single-Molecule Förster Resonance Energy Transfer.

Author

Israels B, Albrecht CS, Dang A, Barney M, von Hippel PH, and Marcus AH

Subjects

DNA Replication, DNA-Binding Proteins metabolism, Nucleic Acid Conformation, Protein Binding, DNA, Single-Stranded, Fluorescence Resonance Energy Transfer

Abstract

Thermally driven conformational fluctuations (or "breathing") of DNA play important roles in the function and regulation of the "macromolecular machinery of genome expression." Fluctuations in double-stranded (ds) DNA are involved in the transient exposure of pathways to protein binding sites within the DNA framework, leading to the binding of regulatory proteins to single-stranded (ss) DNA templates. These interactions often require that the ssDNA sequences, as well as the proteins involved, assume transient conformations critical for successful binding. Here, we use microsecond-resolved single-molecule Förster resonance energy transfer (smFRET) experiments to investigate the backbone fluctuations of short [oligo(dT) n ] templates within DNA constructs that also serve as models for ss-dsDNA junctions. Such junctions, together with the attached ssDNA sequences, are involved in interactions with the ssDNA binding (ssb) proteins that control and integrate the functions of DNA replication complexes. We analyze these data using a chemical network model based on multiorder time-correlation functions and probability distribution functions that characterize the kinetic and thermodynamic behavior of the system. We find that the oligo(dT) n tails of ss-dsDNA constructs interconvert, on submillisecond time scales, between three macrostates with distinctly different end-to-end distances. These are (i) a "compact" macrostate that represents the dominant species at equilibrium; (ii) a "partially extended" macrostate that exists as minority species; and (iii) a "highly extended" macrostate that is present in trace amounts. We propose a model for ssDNA secondary structure that advances our understanding of how spontaneously formed nucleic acid conformations may facilitate the activities of ssDNA-associating proteins.

Published

2021

21. Quantifying the enhancement of two-photon absorption due to spectral-temporal entanglement.

Author

Landes T, Raymer MG, Allgaier M, Merkouche S, Smith BJ, and Marcus AH

Abstract

When a low flux of time-frequency-entangled photon pairs (EPP) illuminates a two-photon transition, the rate of two-photon absorption (TPA) can be enhanced considerably by the quantum nature of photon number correlations and frequency correlations. We use a quantum-theoretic derivation of entangled TPA (ETPA) and calculate an upper bound on the amount of quantum enhancement that is possible in such systems. The derived bounds indicate that in order to observe ETPA the experiments would need to operate at a combination of significantly higher rates of EPP illumination, molecular concentrations, and conventional TPA cross sections than are achieved in typical experiments.

Published

2021

22. Dinucleotides as simple models of the base stacking-unstacking component of DNA 'breathing' mechanisms.

Author

Beyerle ER, Dinpajooh M, Ji H, von Hippel PH, Marcus AH, and Guenza MG

Subjects

Circular Dichroism, Ions chemistry, Markov Chains, Models, Molecular, Sodium Chloride chemistry, Water chemistry, DNA chemistry, Dinucleoside Phosphates chemistry

Abstract

Regulatory protein access to the DNA duplex 'interior' depends on local DNA 'breathing' fluctuations, and the most fundamental of these are thermally-driven base stacking-unstacking interactions. The smallest DNA unit that can undergo such transitions is the dinucleotide, whose structural and dynamic properties are dominated by stacking, while the ion condensation, cooperative stacking and inter-base hydrogen-bonding present in duplex DNA are not involved. We use dApdA to study stacking-unstacking at the dinucleotide level because the fluctuations observed are likely to resemble those of larger DNA molecules, but in the absence of constraints introduced by cooperativity are likely to be more pronounced, and thus more accessible to measurement. We study these fluctuations with a combination of Molecular Dynamics simulations on the microsecond timescale and Markov State Model analyses, and validate our results by calculations of circular dichroism (CD) spectra, with results that agree well with the experimental spectra. Our analyses show that the CD spectrum of dApdA is defined by two distinct chiral conformations that correspond, respectively, to a Watson-Crick form and a hybrid form with one base in a Hoogsteen configuration. We find also that ionic structure and water orientation around dApdA play important roles in controlling its breathing fluctuations., (© The Author(s) 2021. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2021

23. Fluorescence-detected Fourier transform electronic spectroscopy by phase-tagged photon counting.

Author

Tamimi A, Landes T, Lavoie J, Raymer MG, and Marcus AH

Abstract

Fluorescence-detected Fourier transform (FT) spectroscopy is a technique in which the relative paths of an optical interferometer are controlled to excite a material sample, and the ensuing fluorescence is detected as a function of the interferometer path delay and relative phase. A common approach to enhance the signal-to-noise ratio in these experiments is to apply a continuous phase sweep to the relative optical path, and to detect the resulting modulated fluorescence using a phase-sensitive lock-in amplifier. In many important situations, the fluorescence signal is too weak to be measured using a lock-in amplifier, so that photon counting techniques are preferred. Here we introduce an approach to low-signal fluorescence-detected FT spectroscopy, in which individual photon counts are assigned to a modulated interferometer phase ('phase-tagged photon counting,' or PTPC), and the resulting data are processed to construct optical spectra. We studied the fluorescence signals of a molecular sample excited resonantly by a pulsed coherent laser over a range of photon flux and visibility levels. We compare the performance of PTPC to standard lock-in detection methods and establish the range of signal parameters over which meaningful measurements can be carried out. We find that PTPC generally outperforms the lock-in detection method, with the dominant source of measurement uncertainty being associated with the statistics of the finite number of samples of the photon detection rate.

Published

2020

24. Vitamin B12 measurements across neurodegenerative disorders.

Author

Luthra NS, Marcus AH, Hills NK, and Christine CW

Abstract

Background: Vitamin B12 deficiency causes a number of neurological features including cognitive and psychiatric disturbances, gait instability, neuropathy, and autonomic dysfunction. Clinical recognition of B12 deficiency in neurodegenerative disorders is more challenging because it causes defects that overlap with expected disease progression. We sought to determine whether B12 levels at the time of diagnosis in patients with Parkinson's disease (PD) differed from those in patients with other neurodegenerative disorders., Methods: We performed a cross-sectional analysis of B12 levels obtained around the time of diagnosis in patients with PD, Multiple System Atrophy (MSA), Dementia with Lewy Bodies (DLB), Alzheimer's disease (AD), Progressive Supranuclear Palsy (PSP), Frontotemporal Dementia (FTD), or Mild Cognitive Impairment (MCI). We also evaluated the rate of B12 decline in PD, AD, and MCI., Results: In multivariable analysis adjusted for age, sex, and B12 supplementation, we found that B12 levels were significantly lower at time of diagnosis in patients with PD than in patients with PSP, FTD, and DLB. In PD, AD, and MCI, the rate of B12 decline ranged from - 17 to - 47 pg/ml/year, much greater than that reported for the elderly population., Conclusions: Further studies are needed to determine whether comorbid B12 deficiency affects progression of these disorders., Competing Interests: Competing interestsThe authors declare that they have no competing interests., (© The Author(s) 2020.)

Published

2020

25. The Many Roles of Binding Cooperativity in the Control of DNA Replication.

Author

von Hippel PH and Marcus AH

Subjects

DNA, DNA Replication, DNA-Binding Proteins, Escherichia coli, Escherichia coli Proteins

Published

2019

26. Local DNA Base Conformations and Ligand Intercalation in DNA Constructs Containing Optical Probes.

Author

Ji H, Johnson NP, von Hippel PH, and Marcus AH

Subjects

Aminoacridines chemistry, Base Sequence, Computer Simulation, Electricity, Ligands, Models, Molecular, Xanthopterin chemistry, DNA chemistry, Intercalating Agents chemistry, Molecular Probes chemistry, Nucleic Acid Conformation

Abstract

Understanding local conformations of DNA at the level of individual nucleic acid bases and base pairs is important for elucidating molecular processes that depend on DNA sequence. Here, we apply linear absorption and circular dichroism measurements to the study of local DNA conformations, using the guanine base analog 6-methyl isoxanthopterin (6-MI) as a structural probe. We show that the spectroscopic properties of this probe can provide detailed information about the average local base and basepair conformations as a function of the surrounding DNA sequence. Based on these results we apply a simple theoretical model to calculate the circular dichroism spectra of 6-MI-substituted DNA constructs and show that our model can be used to extract information about how the local conformations of the 6-MI probe are influenced by the local base or basepair environment. We also use this probe to examine the pathway for the insertion (intercalation) of a tethered acridine ligand (9-amino-6-chloro methoxyacridine) into duplex DNA. We show that this model intercalator interacts with duplex DNA by a "displacement insertion intercalation" mechanism, whereby the acridine moiety is inserted into the DNA structure and displaces the base located opposite its attachment site. These findings suggest that site-specifically positioned base analog probes can be used to characterize the molecular and structural details of binding ligand effects on local base stacking and unstacking reactions in single- and double-stranded DNA and thus may help to define the molecular mechanisms of DNA-protein interactions that involve the site-specific intercalation of aromatic amino acid side chains into genomic DNA., (Copyright © 2019 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2019

27. Measuring local conformations and conformational disorder of (Cy3) 2 dimer labeled DNA fork junctions using absorbance, circular dichroism and two-dimensional fluorescence spectroscopy.

Author

Heussman D, Kittell J, Kringle L, Tamimi A, von Hippel PH, and Marcus AH

Subjects

Circular Dichroism, Dimerization, Molecular Conformation, Spectrometry, Fluorescence, Carbocyanines chemistry, DNA chemistry

Abstract

The sugar-phosphate backbone of DNA near single-stranded (ss)-double-stranded (ds) junctions likely fluctuates within a broad distribution of conformations to permit the proper binding of genome regulatory proteins that function at these sites. In this work we use absorbance, circular dichroism (CD), and two-dimensional fluorescence spectroscopy (2DFS) to study the local conformations and conformational disorder within chromophore-labeled DNA constructs. These constructs employ dimers of the fluorescent chromophore Cy3 that are site-specifically incorporated into the sugar-phosphate backbones of DNA strands at ss-ds DNA fork junctions. We show that these data can be analyzed to determine the local conformations of the (Cy3)2 dimer, and the degree of conformational disorder. Our analysis employs an essential-state Holstein-Frenkel Hamiltonian model, which takes into account the internal electronic-vibrational motions within each Cy3 chromophore, and the resonant electronic interaction that couples the two chromophores together. Our results suggest that this approach may be applied generally to understand local backbone conformation and conformational disorder at ss-ds DNA fork junctions.

Published

2019

28. Temperature-dependent conformations of exciton-coupled Cy3 dimers in double-stranded DNA.

Author

Kringle L, Sawaya NPD, Widom J, Adams C, Raymer MG, Aspuru-Guzik A, and Marcus AH

Subjects

Dimerization, Models, Molecular, Spectrometry, Fluorescence, Carbocyanines chemistry, DNA chemistry, Temperature

Abstract

Understanding the properties of electronically interacting molecular chromophores, which involve internally coupled electronic-vibrational motions, is important to the spectroscopy of many biologically relevant systems. Here we apply linear absorption, circular dichroism, and two-dimensional fluorescence spectroscopy to study the polarized collective excitations of excitonically coupled cyanine dimers (Cy3) 2 that are rigidly positioned within the opposing sugar-phosphate backbones of the double-stranded region of a double-stranded (ds)-single-stranded (ss) DNA fork construct. We show that the exciton-coupling strength of the (Cy3) 2 -DNA construct can be systematically varied with temperature below the ds-ss DNA denaturation transition. We interpret spectroscopic measurements in terms of the Holstein vibronic dimer model, from which we obtain information about the local conformation of the (Cy3) 2 dimer, as well as the degree of static disorder experienced by the Cy3 monomer and the (Cy3) 2 dimer probe locally within their respective DNA duplex environments. The properties of the (Cy3) 2 -DNA construct we determine suggest that it may be employed as a useful model system to test fundamental concepts of protein-DNA interactions and the role of electronic-vibrational coherence in electronic energy migration within exciton-coupled bio-molecular arrays.

Published

2018

29. Using microsecond single-molecule FRET to determine the assembly pathways of T4 ssDNA binding protein onto model DNA replication forks.

Author

Phelps C, Israels B, Jose D, Marsh MC, von Hippel PH, and Marcus AH

Subjects

Bacteriophage T4 metabolism, DNA, Single-Stranded metabolism, DNA-Binding Proteins metabolism, Viral Proteins metabolism, Bacteriophage T4 chemistry, DNA, Single-Stranded chemistry, DNA-Binding Proteins chemistry, Fluorescence Resonance Energy Transfer, Viral Proteins chemistry

Abstract

DNA replication is a core biological process that occurs in prokaryotic cells at high speeds (∼1 nucleotide residue added per millisecond) and with high fidelity (fewer than one misincorporation event per 10 7 nucleotide additions). The ssDNA binding protein [gene product 32 (gp32)] of the T4 bacteriophage is a central integrating component of the replication complex that must continuously bind to and unbind from transiently exposed template strands during DNA synthesis. We here report microsecond single-molecule FRET (smFRET) measurements on Cy3/Cy5-labeled primer-template (p/t) DNA constructs in the presence of gp32. These measurements probe the distance between Cy3/Cy5 fluorophores that label the ends of a short (15-nt) segment of ssDNA attached to a model p/t DNA construct and permit us to track the stochastic interconversion between various protein bound and unbound states. The length of the 15-nt ssDNA lattice is sufficient to accommodate up to two cooperatively bound gp32 proteins in either of two positions. We apply a unique multipoint time correlation function analysis to the microsecond-resolved smFRET data obtained to determine and compare the kinetics of various possible reaction pathways for the assembly of cooperatively bound gp32 protein onto ssDNA sequences located at the replication fork. The results of our analysis reveal the presence and translocation mechanisms of short-lived intermediate bound states that are likely to play a critical role in the assembly mechanisms of ssDNA binding proteins at replication forks and other ss duplex junctions., Competing Interests: The authors declare no conflict of interest.

Published

2017

30. Using Multiorder Time-Correlation Functions (TCFs) To Elucidate Biomolecular Reaction Pathways from Microsecond Single-Molecule Fluorescence Experiments.

Author

Phelps C, Israels B, Marsh MC, von Hippel PH, and Marcus AH

Subjects

Bacteriophage T4 metabolism, DNA, Single-Stranded metabolism, DNA-Binding Proteins metabolism, Fluorescence Resonance Energy Transfer, Fluorescent Dyes chemistry, Kinetics, Staining and Labeling methods, Time Factors, Viral Proteins metabolism, Bacteriophage T4 chemistry, DNA, Single-Stranded chemistry, DNA-Binding Proteins chemistry, Optical Imaging methods, Single Molecule Imaging methods, Viral Proteins chemistry

Abstract

Recent advances in single-molecule fluorescence imaging have made it possible to perform measurements on microsecond time scales. Such experiments have the potential to reveal detailed information about the conformational changes in biological macromolecules, including the reaction pathways and dynamics of the rearrangements involved in processes, such as sequence-specific DNA "breathing" and the assembly of protein-nucleic acid complexes. Because microsecond-resolved single-molecule trajectories often involve "sparse" data, that is, they contain relatively few data points per unit time, they cannot be easily analyzed using the standard protocols that were developed for single-molecule experiments carried out with tens-of-millisecond time resolution and high "data density." Here, we describe a generalized approach, based on time-correlation functions, to obtain kinetic information from microsecond-resolved single-molecule fluorescence measurements. This approach can be used to identify short-lived intermediates that lie on reaction pathways connecting relatively long-lived reactant and product states. As a concrete illustration of the potential of this methodology for analyzing specific macromolecular systems, we accompany the theoretical presentation with the description of a specific biologically relevant example drawn from studies of reaction mechanisms of the assembly of the single-stranded DNA binding protein of the T4 bacteriophage replication complex onto a model DNA replication fork.

Published

2016

31. Single-molecule FRET studies of the cooperative and non-cooperative binding kinetics of the bacteriophage T4 single-stranded DNA binding protein (gp32) to ssDNA lattices at replication fork junctions.

Author

Lee W, Gillies JP, Jose D, Israels BA, von Hippel PH, and Marcus AH

Subjects

DNA Replication, DNA, Viral chemistry, Fluorescence Resonance Energy Transfer, Kinetics, Protein Binding, Sodium Chloride chemistry, Virus Replication, Bacteriophage T4, DNA, Single-Stranded chemistry, DNA-Binding Proteins chemistry, Viral Proteins chemistry

Abstract

Gene 32 protein (gp32) is the single-stranded (ss) DNA binding protein of the bacteriophage T4. It binds transiently and cooperatively to ssDNA sequences exposed during the DNA replication process and regulates the interactions of the other sub-assemblies of the replication complex during the replication cycle. We here use single-molecule FRET techniques to build on previous thermodynamic studies of gp32 binding to initiate studies of the dynamics of the isolated and cooperative binding of gp32 molecules within the replication complex. DNA primer/template (p/t) constructs are used as models to determine the effects of ssDNA lattice length, gp32 concentration, salt concentration, binding cooperativity and binding polarity at p/t junctions. Hidden Markov models (HMMs) and transition density plots (TDPs) are used to characterize the dynamics of the multi-step assembly pathway of gp32 at p/t junctions of differing polarity, and show that isolated gp32 molecules bind to their ssDNA targets weakly and dissociate quickly, while cooperatively bound dimeric or trimeric clusters of gp32 bind much more tightly, can 'slide' on ssDNA sequences, and exhibit binding dynamics that depend on p/t junction polarities. The potential relationships of these binding dynamics to interactions with other components of the T4 DNA replication complex are discussed., (© The Author(s) 2016. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2016

32. Sequence-Dependent Conformational Heterogeneity and Proton-Transfer Reactivity of the Fluorescent Guanine Analogue 6-Methyl Isoxanthopterin (6-MI) in DNA.

Author

Johnson NP, Ji H, Steinberg TH, von Hippel PH, and Marcus AH

Subjects

Protons, Xanthopterin chemistry, DNA chemistry, Fluorescent Dyes chemistry, Nucleic Acid Conformation, Xanthopterin analogs & derivatives

Abstract

The local conformations of individual nucleic acid bases in DNA are important components in processes fundamental to gene regulation. Fluorescent nucleic acid base analogues, which can be substituted for natural bases in DNA, can serve as useful spectroscopic probes of average local base conformation and conformational heterogeneity. Here we report excitation-emission peak shift (EES) measurements of the fluorescent guanine (G) analogue 6-methyl isoxanthoptherin (6-MI), both as a ribonucleotide monophosphate (NMP) in solution and as a site-specific substituent for G in various DNA constructs. Changes in the peak positions of the fluorescence spectra as a function of excitation energy indicate that distinct subpopulations of conformational states exist in these samples on time scales longer than the fluorescence lifetime. Our pH-dependent measurements of the 6-MI NMP in solution show that these states can be identified as protonated and deprotonated forms of the 6-MI fluorescent probe. We implement a simple two-state model, which includes four vibrationally coupled electronic levels to estimate the free energy change, the free energy of activation, and the equilibrium constant for the proton transfer reaction. These parameters vary in single-stranded and duplex DNA constructs, and also depend on the sequence context of flanking bases. Our results suggest that proton transfer in 6-MI-substituted DNA constructs is coupled to conformational heterogeneity of the probe base, and can be interpreted to suggest that Watson-Crick base pairing between 6-MI and its complementary cytosine in duplex DNA involves a "low-barrier-hydrogen-bond". These findings may be important in using the 6-MI probe to understand local base conformational fluctuations, which likely play a central role in protein-DNA and ligand-DNA interactions.

Published

2015

33. Electric Dipole Transition Moments and Solvent-Dependent Interactions of Fluorescent Boron-Nitrogen Substituted Indole Derivatives.

Author

Saif M, Widom JR, Xu S, Abbey ER, Liu SY, and Marcus AH

Subjects

Models, Chemical, Molecular Structure, Polyethylene chemistry, Quantum Theory, Spectrometry, Fluorescence, Boron chemistry, Indoles chemistry, Nitrogen chemistry, Solvents chemistry

Abstract

Fluorescent analogues of the indole side chain of tryptophan can be useful spectroscopic probes of protein-protein and protein-DNA interactions. Here we present linear dichroism and solvent-dependent spectroscopic studies of two fluorescent analogues of indole, in which the organic C═C unit is substituted with the isosteric inorganic B-N unit. We studied the so-called "external" BN indole, which has C2v symmetry, and the "fused" BN indole with Cs symmetry. We performed a combination of absorption and fluorescence spectroscopy, ultraviolet linear dichroism (UV-LD) in stretched poly(ethylene) (PE) films, and quantum chemical calculations on both BN indole compounds. Our measurements allowed us to characterize the degree of alignment for both molecules in stretched PE films. We thus determined the orientations and magnitudes of the two lowest energy electric dipole transition moments (EDTMs) for external BN indole, and the two lowest energy EDTMs for fused BN indole within the 30 000-45 000 cm(-1) spectral range. We compared our experimental results to those of quantum chemical calculations using standard density functional theory (DFT). Our theoretical predictions for the low-energy EDTMs are in good agreement with our experimental data. The absorption and fluorescence spectra of the external and the fused BN indoles are sensitive to solvent polarity. Our results indicate that the fused BN indole experiences much greater solvation interactions with polar solvents than does the external BN indole.

Published

2015

34. Quantum process tomography by 2D fluorescence spectroscopy.

Author

Pachón LA, Marcus AH, and Aspuru-Guzik A

Abstract

Reconstruction of the dynamics (quantum process tomography) of the single-exciton manifold in energy transfer systems is proposed here on the basis of two-dimensional fluorescence spectroscopy (2D-FS) with phase-modulation. The quantum-process-tomography protocol introduced here benefits from, e.g., the sensitivity enhancement ascribed to 2D-FS. Although the isotropically averaged spectroscopic signals depend on the quantum yield parameter Γ of the doubly excited-exciton manifold, it is shown that the reconstruction of the dynamics is insensitive to this parameter. Applications to foundational and applied problems, as well as further extensions, are discussed.

Published

2015

35. Coherent two-dimensional photocurrent spectroscopy in a PbS quantum dot photocell.

Author

Karki KJ, Widom JR, Seibt J, Moody I, Lonergan MC, Pullerits T, and Marcus AH

Abstract

Recently there has been growing interest in the role of coherence in electronic dynamics. Coherent multidimensional spectroscopy has been used to reveal coherent phenomena in numerous material systems. Here we utilize a recent implementation of coherent multidimensional spectroscopy--two-dimensional photocurrent spectroscopy--in which we detect the photocurrent from a PbS quantum dot photocell resulting from its interactions with a sequence of four ultrafast laser pulses. We observe sub-picosecond evolution of two-dimensional spectra consistent with multiple exciton generation. Moreover, a comparison with two-dimensional fluorescence spectra of the quantum dots demonstrates the potential of two-dimensional photocurrent spectroscopy to elucidate detailed origins of photocurrent generating electronic state coherence pathways. Since the measurement is based on detecting the photocell current in situ, the method is well suited to study the fundamental ultrafast processes that affect the function of the device. This opens new avenues to investigate and implement coherent optimization strategies directly within devices.

Published

2014

36. Internally labeled Cy3/Cy5 DNA constructs show greatly enhanced photo-stability in single-molecule FRET experiments.

Author

Lee W, von Hippel PH, and Marcus AH

Subjects

Circular Dichroism, Fluorescence Resonance Energy Transfer, Staining and Labeling, Thermodynamics, Carbocyanines chemistry, DNA Probes chemistry, Fluorescent Dyes chemistry

Abstract

DNA constructs labeled with cyanine fluorescent dyes are important substrates for single-molecule (sm) studies of the functional activity of protein-DNA complexes. We previously studied the local DNA backbone fluctuations of replication fork and primer-template DNA constructs labeled with Cy3/Cy5 donor-acceptor Förster resonance energy transfer (FRET) chromophore pairs and showed that, contrary to dyes linked 'externally' to the bases with flexible tethers, direct 'internal' (and rigid) insertion of the chromophores into the sugar-phosphate backbones resulted in DNA constructs that could be used to study intrinsic and protein-induced DNA backbone fluctuations by both smFRET and sm Fluorescent Linear Dichroism (smFLD). Here we show that these rigidly inserted Cy3/Cy5 chromophores also exhibit two additional useful properties, showing both high photo-stability and minimal effects on the local thermodynamic stability of the DNA constructs. The increased photo-stability of the internal labels significantly reduces the proportion of false positive smFRET conversion 'background' signals, thereby simplifying interpretations of both smFRET and smFLD experiments, while the decreased effects of the internal probes on local thermodynamic stability also make fluctuations sensed by these probes more representative of the unperturbed DNA structure. We suggest that internal probe labeling may be useful in studies of many DNA-protein interaction systems., (© The Author(s) 2014. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2014

37. Entangled photon-pair two-dimensional fluorescence spectroscopy (EPP-2DFS).

Author

Raymer MG, Marcus AH, Widom JR, and Vitullo DL

Subjects

Photons, Quantum Theory, Spectrometry, Fluorescence

Abstract

We introduce a new method, called entangled photon-pair two-dimensional fluorescence spectroscopy (EPP-2DFS), to sensitively probe the nonlinear electronic response of molecular systems. The method incorporates a separated two-photon ('Franson') interferometer, which generates time-frequency-entangled photon pairs, into the framework of a fluorescence-detected 2D optical spectroscopic experiment. The entangled photons are temporally shaped and phase-modulated in the interferometer, and are used to excite a two-photon-absorbing (TPA) sample, whose excited-state population is selectively detected by simultaneously monitoring the sample fluorescence and the exciting fields. In comparison to 'classical' 2DFS techniques, major advantages of this scheme are the suppression of uncorrelated background signals, the enhancement of simultaneous time-and-frequency resolution, the suppression of diagonal 2D spectral features, and the enhancement and narrowing of off-diagonal spectral cross-peaks that contain information about electronic couplings. These effects are a consequence of the pure-state field properties unique to a parametric down-conversion light source, which must be included in the quantum mechanical description of the composite field-molecule system. We numerically simulate the EPP-2DFS observable for the case of an electronically coupled molecular dimer. The EPP-2DFS spectrum is greatly simplified in comparison to its classical 2D counterpart. Our results indicate that EPP-2DFS can provide previously unattainable resolution to extract model Hamiltonian parameters from electronically coupled molecular dimers.

Published

2013

38. Biography of Michael D. Fayer.

Author

Marcus AH, Berg MA, and Zheng J

Published

2013

39. Tribute to Michael D. Fayer.

Author

Marcus AH, Berg MA, and Zheng J

Published

2013

40. Fifty years of DNA "breathing": Reflections on old and new approaches.

Author

von Hippel PH, Johnson NP, and Marcus AH

Subjects

Nucleic Acid Conformation, Spectrum Analysis, DNA chemistry, Nucleic Acid Denaturation

Abstract

The coding sequences for genes, and much other regulatory information involved in genome expression, are located 'inside' the DNA duplex. Thus the "macromolecular machines" that read-out this information from the base sequence of the DNA must somehow access the DNA "interior." Double-stranded (ds) DNA is a highly structured and cooperatively stabilized system at physiological temperatures, but is also only marginally stable and undergoes a cooperative "melting phase transition" at temperatures not far above physiological. Furthermore, due to its length and heterogeneous sequence, with AT-rich segments being less stable than GC-rich segments, the DNA genome 'melts' in a multistate fashion. Therefore the DNA genome must also manifest thermally driven structural ("breathing") fluctuations at physiological temperatures that should reflect the heterogeneity of the dsDNA stability near the melting temperature. Thus many of the breathing fluctuations of dsDNA are likely also to be sequence dependent, and could well contain information that should be "readable" and useable by regulatory proteins and protein complexes in site-specific binding reactions involving dsDNA "opening." Our laboratory has been involved in studying the breathing fluctuations of duplex DNA for about 50 years. In this "Reflections" article we present a relatively chronological overview of these studies, starting with the use of simple chemical probes (such as hydrogen exchange, formaldehyde, and simple DNA "melting" proteins) to examine the local stability of the dsDNA structure, and culminating in sophisticated spectroscopic approaches that can be used to monitor the breathing-dependent interactions of regulatory complexes with their duplex DNA targets in "real time.", (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

41. Single-molecule FRET and linear dichroism studies of DNA breathing and helicase binding at replication fork junctions.

Author

Phelps C, Lee W, Jose D, von Hippel PH, and Marcus AH

Subjects

Algorithms, Bacteriophage T4 genetics, Bacteriophage T4 metabolism, Carbocyanines chemistry, DNA chemistry, DNA genetics, DNA metabolism, DNA, Single-Stranded chemistry, DNA, Single-Stranded genetics, DNA, Single-Stranded metabolism, DNA, Viral chemistry, DNA, Viral genetics, Fluorescent Dyes chemistry, Kinetics, Models, Genetic, Models, Molecular, Nucleic Acid Conformation, Protein Multimerization, Viral Proteins chemistry, Viral Proteins genetics, DNA Replication, DNA, Viral metabolism, Fluorescence Resonance Energy Transfer methods, Viral Proteins metabolism

Abstract

DNA "breathing" is a thermally driven process in which base-paired DNA sequences transiently adopt local conformations that depart from their most stable structures. Polymerases and other proteins of genome expression require access to single-stranded DNA coding templates located in the double-stranded DNA "interior," and it is likely that fluctuations of the sugar-phosphate backbones of dsDNA that result in mechanistically useful local base pair opening reactions can be exploited by such DNA regulatory proteins. Such motions are difficult to observe in bulk measurements, both because they are infrequent and because they often occur on microsecond time scales that are not easy to access experimentally. We report single-molecule fluorescence experiments with polarized light, in which tens-of-microseconds rotational motions of internally labeled iCy3/iCy5 donor-acceptor Förster resonance energy transfer fluorophore pairs that have been rigidly inserted into the backbones of replication fork constructs are simultaneously detected using single-molecule Förster resonance energy transfer and single-molecule fluorescence-detected linear dichroism signals. Our results reveal significant local motions in the ∼100-μs range, a reasonable time scale for DNA breathing fluctuations of potential relevance for DNA-protein interactions. Moreover, we show that both the magnitudes and the relaxation times of these backbone breathing fluctuations are significantly perturbed by interactions of the fork construct with a nonprocessive, weakly binding bacteriophage T4-coded helicase hexamer initiation complex, suggesting that these motions may play a fundamental role in the initial binding, assembly, and function of the processive helicase-primase (primosome) component of the bacteriophage T4-coded DNA replication complex.

Published

2013

42. Temperature-dependent conformations of a membrane supported zinc porphyrin tweezer by 2D fluorescence spectroscopy.

Author

Widom JR, Lee W, Perdomo-Ortiz A, Rappoport D, Molinski TF, Aspuru-Guzik A, and Marcus AH

Subjects

Dimerization, Models, Molecular, Phosphorylcholine chemistry, Spectrometry, Fluorescence, Liposomes chemistry, Metalloporphyrins chemistry, Molecular Conformation, Temperature

Abstract

We studied the equilibrium conformations of a zinc porphyrin tweezer composed of two carboxylphenyl-functionalized zinc tetraphenyl porphyrin subunits connected by a 1,4-butyndiol spacer, which was suspended inside the amphiphilic regions of 1,2-distearoyl-sn-glycero-3-phosphocholine (DSPC) liposomes. By combining phase-modulation two-dimensional fluorescence spectroscopy (2D FS) with linear absorbance and fluorimetry, we determined that the zinc porphyrin tweezer adopts a mixture of folded and extended conformations in the membrane. By fitting an exciton-coupling model to a series of data sets recorded over a range of temperatures (17-85 °C) and at different laser center wavelengths, we determined that the folded form of the tweezer is stabilized by a favorable change in the entropy of the local membrane environment. Our results provide insights toward understanding the balance of thermodynamic factors that govern molecular assembly in membranes.

Published

2013

43. A single-molecule view of the assembly pathway, subunit stoichiometry, and unwinding activity of the bacteriophage T4 primosome (helicase-primase) complex.

Author

Lee W, Jose D, Phelps C, Marcus AH, and von Hippel PH

Subjects

Adenosine Triphosphatases metabolism, DNA chemistry, DNA metabolism, Fluorescence Resonance Energy Transfer, Models, Molecular, Probability, Bacteriophage T4 enzymology, DNA Helicases metabolism, DNA Primase metabolism

Abstract

Single-molecule fluorescence resonance energy transfer (smFRET) methods were used to study the assembly pathway and DNA unwinding activity of the bacteriophage T4 helicase-primase (primosome) complex. The helicase substrates used were surface-immobilized model DNA replication forks "internally" labeled in the duplex region with opposed donor/acceptor (iCy3/iCy5) chromophore pairs in the lagging and leading strands. The time dependence of the smFRET signals was monitored during the unwinding process, and helicase rates and processivities were measured as a function of GTP concentration. This smFRET approach was also used to investigate the subunit stoichiometry of the primosome and the assembly pathway required to form functional and fully active primosome-DNA complexes. We confirmed that gp41 helicase monomer subunits form stable hexameric helicases in the presence of GTP and that the resulting (gp41)(6) complexes bind only weakly at DNA fork junctions. The addition of a single subunit of gp61 primase stabilized the resulting primosome complex at the fork and resulted in fully active and processive primosome helicases with gp41:gp61 subunit ratios of 6:1, while higher and lower subunit ratios substantially reduced the primosome unwinding activity. The use of alternative assembly pathways resulted in a loss of helicase activity and the formation of metastable DNA-protein aggregates, which were easily detected in our smFRET experiments as intense light-scattering foci. These single-molecule experiments provide a detailed real-time visualization of the assembly pathway and duplex DNA unwinding activity of the T4 primosome and are consistent with more indirect equilibrium and steady state results obtained in bulk solution studies.

Published

2013

44. Solution conformation of 2-aminopurine (2-AP) dinucleotide determined by ultraviolet 2D fluorescence spectroscopy (UV-2D FS).

Author

Widom JR, Johnson NP, von Hippel PH, and Marcus AH

Abstract

We have observed the conformation-dependent electronic coupling between the monomeric subunits of a dinucleotide of 2-aminopurine (2-AP), a fluorescent analog of the nucleic acid base adenine. This was accomplished by extending two-dimensional fluorescence spectroscopy (2D FS) - a fluorescence-detected variation of 2D electronic spectroscopy - to excite molecular transitions in the ultraviolet (UV) regime. A collinear sequence of four ultrafast laser pulses centered at 323 nm was used to resonantly excite the coupled transitions of 2-AP dinucleotide. The phases of the optical pulses were continuously swept at kilohertz frequencies, and the ensuing nonlinear fluorescence was phase-synchronously detected at 370 nm. Upon optimization of a point-dipole coupling model to our data, we found that in aqueous buffer the 2-AP dinucleotide adopts an average conformation in which the purine bases are non-helically stacked (center-to-center distance R 12 = 3.5 Å ± 0.5 Å, twist angle θ 12 = 5° ± 5°), which differs from the conformation of such adjacent bases in duplex DNA. These experiments establish UV-2D FS as a method for examining the local conformations of an adjacent pair of fluorescent nucleotides substituted into specific DNA or RNA constructs, which will serve as a powerful probe to interpret, in structural terms, biologically significant local conformational changes within the nucleic acid framework of protein-nucleic acid complexes.

Published

2013

45. Electronic transition moments of 6-methyl isoxanthopterin--a fluorescent analogue of the nucleic acid base guanine.

Author

Widom JR, Rappoport D, Perdomo-Ortiz A, Thomsen H, Johnson NP, von Hippel PH, Aspuru-Guzik A, and Marcus AH

Subjects

DNA, B-Form chemistry, Models, Chemical, Molecular Structure, Spectrophotometry, Ultraviolet, Xanthopterin chemistry, Fluorescent Dyes chemistry, Xanthopterin analogs & derivatives

Abstract

Fluorescent nucleic acid base analogues are important spectroscopic tools for understanding local structure and dynamics of DNA and RNA. We studied the orientations and magnitudes of the electric dipole transition moments (EDTMs) of 6-methyl isoxanthopterin (6-MI), a fluorescent analogue of guanine that has been particularly useful in biological studies. Using a combination of absorption spectroscopy, linear dichroism (LD) and quantum chemical calculations, we identified six electronic transitions that occur within the 25,000-50,000 cm(-1) spectral range. Our results indicate that the two experimentally observed lowest-energy transitions, which occur at 29,687 cm(-1) (337 nm) and 34,596 cm(-1) (289 nm), are each polarized within the plane of the 6-MI base. A third in-plane polarized transition is experimentally observed at 47,547 cm(-1) (210 nm). The theoretically predicted orientation of the lowest-energy transition moment agrees well with experiment. Based on these results, we constructed an exciton model to describe the absorption spectra of a 6-MI dinucleotide-substituted double-stranded DNA construct. This model is in good agreement with the experimental data. The orientations and intensities of the low-energy electronic transitions of 6-MI reported here should be useful for studying local conformations of DNA and RNA in biologically important complexes.

Published

2013

46. Compressed Sensing for Multidimensional Spectroscopy Experiments.

Author

Sanders JN, Saikin SK, Mostame S, Andrade X, Widom JR, Marcus AH, and Aspuru-Guzik A

Abstract

Compressed sensing is a processing method that significantly reduces the number of measurements needed to accurately resolve signals in many fields of science and engineering. We develop a two-dimensional variant of compressed sensing for multidimensional spectroscopy and apply it to experimental data. For the model system of atomic rubidium vapor, we find that compressed sensing provides an order-of-magnitude (about 10-fold) improvement in spectral resolution along each dimension, as compared to a conventional discrete Fourier transform, using the same data set. More attractive is that compressed sensing allows for random undersampling of the experimental data, down to less than 5% of the experimental data set, with essentially no loss in spectral resolution. We believe that by combining powerful resolution with ease of use, compressed sensing can be a powerful tool for the analysis and interpretation of ultrafast spectroscopy data.

Published

2012

47. Conformation and electronic population transfer in membrane-supported self-assembled porphyrin dimers by 2D fluorescence spectroscopy.

Author

Perdomo-Ortiz A, Widom JR, Lott GA, Aspuru-Guzik A, and Marcus AH

Subjects

Dimerization, Electron Transport, Magnesium chemistry, Models, Molecular, Phosphatidylcholines chemistry, Spectrometry, Fluorescence, Lipid Bilayers chemistry, Porphyrins chemistry

Abstract

Two-dimensional fluorescence spectroscopy (2D FS) is applied to determine the conformation and femtosecond electronic population transfer in a dimer of magnesium meso tetraphenylporphyrin. The dimers are prepared by self-assembly of the monomer within the amphiphilic regions of 1,2-distearoyl-sn-glycero-3-phosphocholine liposomes. A theoretical framework to describe 2D FS experiments is presented, and a direct comparison is made between the observables of this measurement and those of 2D electronic spectroscopy (2D ES). The sensitivity of the method to varying dimer conformation is explored. A global multivariable fitting analysis of linear and 2D FS data indicates that the dimer adopts a "bent T-shaped" conformation. Moreover, the manifold of singly excited excitons undergoes rapid electronic dephasing and downhill population transfer on the time scale of ∼95 fs. The open conformation of the dimer suggests that its self-assembly is favored by an increase in entropy of the local membrane environment.

Published

2012

48. Characterization of the 6-methyl isoxanthopterin (6-MI) base analog dimer, a spectroscopic probe for monitoring guanine base conformations at specific sites in nucleic acids.

Author

Datta K, Johnson NP, Villani G, Marcus AH, and von Hippel PH

Subjects

DNA Replication, Dimerization, Guanine chemistry, Nucleic Acid Conformation, Spectrometry, Fluorescence, Spectrophotometry, Ultraviolet, Xanthopterin chemistry, DNA chemistry, Fluorescent Dyes chemistry, Xanthopterin analogs & derivatives

Abstract

We here characterize local conformations of site-specifically placed pairs of guanine (G) residues in RNA and DNA, using 6-methyl isoxanthopterin (6-MI) as a conformational probe. 6-MI is a base analog of G and spectroscopic signals obtained from pairs of adjacent 6-MI residues reflect base-base interactions that are sensitive to the sequence context, local DNA conformation and solvent environment of the probe bases. CD signals show strong exciton coupling between stacked 6-MI bases in double-stranded (ds) DNA; this coupling is reduced in single-stranded (ss) DNA sequences. Solvent interactions reduce the fluorescence of the dimer probe more efficiently in ssDNA than dsDNA, while self-quenching between 6-MI bases is enhanced in dsDNA. 6-MI dimer probes closely resemble adjacent GG residues, in that these probes have minimal effects on the stability of dsDNA and on interactions with solvent additive betaine. They also serve as effective template bases, although further polymerase-dependent extension of DNA primers past 6-MI template bases is significantly inhibited. These probes are also used to monitor DNA 'breathing' at model replication forks. The 6-MI dimer probe can serve in many contexts as a useful tool to investigate GG conformations at specific sites within the nucleic acid frameworks of functioning macromolecular machines in solution.

Published

2012

49. Conformation of self-assembled porphyrin dimers in liposome vesicles by phase-modulation 2D fluorescence spectroscopy.

Author

Lott GA, Perdomo-Ortiz A, Utterback JK, Widom JR, Aspuru-Guzik A, and Marcus AH

Subjects

Computational Biology, Liposomes metabolism, Models, Biological, Porphyrins metabolism, Protein Conformation, Protein Multimerization physiology, Spectrometry, Fluorescence methods

Abstract

By applying a phase-modulation fluorescence approach to 2D electronic spectroscopy, we studied the conformation-dependent exciton coupling of a porphyrin dimer embedded in a phospholipid bilayer membrane. Our measurements specify the relative angle and separation between interacting electronic transition dipole moments and thus provide a detailed characterization of dimer conformation. Phase-modulation 2D fluorescence spectroscopy (PM-2D FS) produces 2D spectra with distinct optical features, similar to those obtained using 2D photon-echo spectroscopy. Specifically, we studied magnesium meso tetraphenylporphyrin dimers, which form in the amphiphilic regions of 1,2-distearoyl-sn-glycero-3-phosphocholine liposomes. Comparison between experimental and simulated spectra show that although a wide range of dimer conformations can be inferred by either the linear absorption spectrum or the 2D spectrum alone, consideration of both types of spectra constrain the possible structures to a "T-shaped" geometry. These experiments establish the PM-2D FS method as an effective approach to elucidate chromophore dimer conformation.

Published

2011

50. Actin polymerization driven mitochondrial transport in mating S. cerevisiae.

Author

Senning EN and Marcus AH

Subjects

Actins chemistry, Actins genetics, Biological Transport physiology, Cell Membrane physiology, Cell Membrane ultrastructure, Cytoskeleton physiology, Cytoskeleton ultrastructure, Fourier Analysis, Kinetics, Microscopy, Fluorescence, Microtubules physiology, Microtubules ultrastructure, Mitochondria genetics, Mitochondria ultrastructure, Mutation, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae physiology, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Sequence Deletion, Spectroscopy, Fourier Transform Infrared, Actins metabolism, Mitochondria physiology, Saccharomyces cerevisiae genetics

Abstract

The dynamic microenvironment of cells depends on macromolecular architecture, equilibrium fluctuations, and nonequilibrium forces generated by cytoskeletal proteins. We studied the influence of these factors on the motions of mitochondria in mating S. cerevisiae using Fourier imaging correlation spectroscopy (FICS). Our measurements provide detailed length-scale dependent information about the dynamic behavior of mitochondria. We investigate the influence of the actin cytoskeleton on mitochondrial motion and make comparisons between conditions in which actin network assembly and disassembly is varied either by using disruptive pharmacological agents or mutations that alter the rates of actin polymerization. Under physiological conditions, nonequilibrium dynamics of the actin cytoskeleton leads to 1.5-fold enhancement of the long-time mitochondrial diffusion coefficient and a transient subdiffusive temporal scaling of the mean-square displacement (MSD proportional, variant tau (alpha), with alpha = 2/3). We find that nonequilibrium forces associated with actin polymerization are a predominant factor in driving mitochondrial transport. Moreover, our results lend support to an existing model in which these forces are directly coupled to mitochondrial membrane surfaces.

Published

2010