Anson Dang scite author profile

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.

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Mapping DNA conformations and interactions within the binding cleft of bacteriophage T4 single-stranded DNA binding protein (gp32) at single nucleotide resolution

Camel

Jose

Meze

et al. 2020

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In this study, we use single-stranded DNA (oligo-dT) lattices that have been position-specifically labeled with monomer or dimer 2-aminopurine (2-AP) probes to map the local interactions of the DNA bases with the nucleic acid binding cleft of gp32, the single-stranded binding (ssb) protein of bacteriophage T4. Three complementary spectroscopic approaches are used to characterize these local interactions of the probes with nearby nucleotide bases and amino acid residues at varying levels of effective protein binding cooperativity, as manipulated by changing lattice length. These include: (i) examining local quenching and enhancing effects on the fluorescence spectra of monomer 2-AP probes at each position within the cleft; (ii) using acrylamide as a dynamic-quenching additive to measure solvent access to monomer 2-AP probes at each ssDNA position; and (iii) employing circular dichroism spectra to characterize changes in exciton coupling within 2-AP dimer probes at specific ssDNA positions within the protein cleft. The results are interpreted in part by what we know about the topology of the binding cleft from crystallographic studies of the DNA binding domain of gp32 and provide additional insights into how gp32 can manipulate the ssDNA chain at various steps of DNA replication and other processes of genome expression.

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Sub-millisecond conformational transitions of short single-stranded DNA lattices by photon correlation single-molecule FRET

Israels

Albrecht

Dang

et al. 2021

Preprint

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Thermally-driven conformational fluctuations (or 'breathing') of DNA plays 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 functional and 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 F&oumlrster Resonance Energy Transfer (smFRET) experiments to investigate the backbone fluctuations of short (ss) oligo- oligo(dT)n templates within DNA constructs that can also serve as models for ss-dsDNA junctions. Such junctions, as well as the attached ssDNA sequences, are involved in the binding of ssDNA binding (ssb) proteins that control and integrate the mechanisms of DNA replication complexes. We have used these data to determine multi-order time-correlation functions (TCFs) and probability distribution functions (PDFs) that characterize the kinetic and thermodynamic behavior of the system. We find that the oligo(dT)n tails of ss-dsDNA constructs inter-convert, on sub-millisecond 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 a 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.

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Sub-microsecond Single-Molecule FRET Studies of Single-Stranded DNA Conformation Fluctuations Mediated by Single-Stranded DNA Binding Proteins

Israels

Dang

Hippel

et al. 2020

Biophysical Journal

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Epidermal growth factor receptor (EGFR) is a membrane protein that controls critical cellular functions including adhesion, invasion and proliferation. Gene amplification in the EGFR or overexpression of the receptor in cell surface has been implicated in various neurodegenerative diseases and cancers. Binding of a ligand in the extracellular domain dictates vast and varied conformational changes in each part of the intracellular domain. The domain interactions and time sequence of these conformational changes which collectively influence cellular response have been largely unexplored, due to the challenge associated with isolating full-length EGFR in near native environment and difficulties associated with isolating individual conformational states. In this project, we isolate functional full-length monomeric EGFR within membrane nanodisc, a lipid bilayer encircled by an ApoA1 belting protein by employing cell-free expression. Using single-molecule Forster resonance energy transfer (FRET), we measure conformational states of individual full-length EGFR upon extracellular ligand binding. Our results provide mechanistic picture of signal transduction mechanism across the full-length EGFR protein with single-protein resolution.

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Mapping Interactions of Single-Stranded (SS) DNA with the SS-DNA Binding Protein (GP32) of the T4 DNA Replication Complex at Specific Nucleotide Residue Positions

Camel

Dang

Meze

et al. 2018

Biophysical Journal

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Anson Dang

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

Mapping DNA conformations and interactions within the binding cleft of bacteriophage T4 single-stranded DNA binding protein (gp32) at single nucleotide resolution

Sub-millisecond conformational transitions of short single-stranded DNA lattices by photon correlation single-molecule FRET

Sub-microsecond Single-Molecule FRET Studies of Single-Stranded DNA Conformation Fluctuations Mediated by Single-Stranded DNA Binding Proteins

Mapping Interactions of Single-Stranded (SS) DNA with the SS-DNA Binding Protein (GP32) of the T4 DNA Replication Complex at Specific Nucleotide Residue Positions

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