A nano-positioning system for macromolecular structural analysis

Muschielok, Adam; Andrecka, Joanna; Jawhari, Anass; Brückner, Florian; Cramer, Patrick; Michaelis, Jens

doi:10.1038/nmeth.1259

Cited by 198 publications

(250 citation statements)

References 33 publications

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“…Therefore, the variance of the FRET efficiency distribution in the TD-A1 experiment is much smaller for the tetramer than for the dimer. Several groups have recently developed tools to calculate an accurate distribution of the distance between the donor and acceptor by appropriate modeling of fluorophores and linkers for macromolecules with well-defined structures (64)(65)(66)(67)(68)(69). This calculation may allow for a more quantitative comparison.…”

Section: Discussionmentioning

confidence: 99%

Oligomerization of the tetramerization domain of p53 probed by two- and three-color single-molecule FRET

Chung

Meng

Kim

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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We describe a method that combines two-and three-color singlemolecule FRET spectroscopy with 2D FRET efficiency-lifetime analysis to probe the oligomerization process of intrinsically disordered proteins. This method is applied to the oligomerization of the tetramerization domain (TD) of the tumor suppressor protein p53. TD exists as a monomer at subnanomolar concentrations and forms a dimer and a tetramer at higher concentrations. Because the dissociation constants of the dimer and tetramer are very close, as we determine in this paper, it is not possible to characterize different oligomeric species by ensemble methods, especially the dimer that cannot be readily separated. However, by using single-molecule FRET spectroscopy that includes measurements of fluorescence lifetime and two-and three-color FRET efficiencies with corrections for submillisecond acceptor blinking, we show that it is possible to obtain structural information for individual oligomers at equilibrium and to determine the dimerization kinetics. From these analyses, we show that the monomer is intrinsically disordered and that the dimer conformation is very similar to that of the tetramer but the C terminus of the dimer is more flexible.single-molecule spectroscopy | three-color FRET | intrinsically disordered protein | p53 oligomerization | fluorescence lifetime I t is well known that intrinsically disordered proteins (IDPs) can fold into different structures when attaching to their binding targets. This structural flexibility and binding promiscuity are required for the formation of protein-protein interaction networks in various biological processes such as signal transduction and gene transcription (1-3). On the other hand, some IDPs selfassemble and form oligomers, many of which are implicated in the development of diseases such as Alzheimer's disease (amyloid-β protein) (4, 5) and Parkinson's disease (α-synuclein) (6). An ensemble of these oligomers with different sizes and conformations is not easy to separate, and therefore, their characterization is very difficult. However, single-molecule spectroscopy can be a very powerful tool because it can probe subpopulations in a mixture without the need for separation. Single-molecule spectroscopy has been successfully used for characterizing individual molecular states such as the folded and unfolded states of proteins (7-9), intermediate states (10, 11), and transition paths (12-17) and for identifying specific molecular species and complexes (18)(19)(20)(21)(22). In this paper, we describe the development of a singlemolecule fluorescence method that probes individual oligomers in a mixture, characterizes their conformations, and determines oligomerization kinetics.We have used two-and three-color Förster resonance energy transfer (FRET) spectroscopy. Compared with two-color FRET that monitors a single distance, three-color FRET can determine three distances and therefore has great potential to obtain 3D structural information for a molecule or a molecular complex. Multicolor FRET has been d...

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Section: Discussionmentioning

confidence: 99%

Oligomerization of the tetramerization domain of p53 probed by two- and three-color single-molecule FRET

Chung

Meng

Kim

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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“…Several methods have been developed to account for this uncertainty. These methods include Bayesian statistical methods and molecular dynamics modeling to calculate a region that the fluorophore attached to the protein will likely occupy during the excited-state lifetime (30,31). Although these computational methods improve the ability to estimate the location of the fluorophore in space, an experimental method that precludes the use of computation to find backbone positions would be advantageous.…”

Section: Discussionmentioning

confidence: 99%

Short-distance probes for protein backbone structure based on energy transfer between bimane and transition metal ions

Taraska

Puljung

Zagotta

2009

Proc. Natl. Acad. Sci. U.S.A.

119

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The structure and dynamics of proteins underlies the workings of virtually every biological process. Existing biophysical methods are inadequate to measure protein structure at atomic resolution, on a rapid time scale, with limited amounts of protein, and in the context of a cell or membrane. FRET can measure distances between two probes, but depends on the orientation of the probes and typically works only over long distances comparable with the size of many proteins. Also, common probes used for FRET can be large and have long, flexible attachment linkers that position dyes far from the protein backbone. Here, we improve and extend a fluorescence method called transition metal ion FRET that uses energy transfer to transition metal ions as a reporter of short-range distances in proteins with little orientation dependence. This method uses a very small cysteine-reactive dye monobromobimane, with virtually no linker, and various transition metal ions bound close to the peptide backbone as the acceptor. We show that, unlike larger fluorophores and longer linkers, this donor-acceptor pair accurately reports shortrange distances and changes in backbone distances. We further extend the method by using cysteine-reactive metal chelators, which allow the technique to be used in protein regions of unknown secondary structure or when native metal ion binding sites are present. This improved method overcomes several of the key limitations of classical FRET for intramolecular distance measurements.fluorescence ͉ peptides ͉ FRET F luorescence resonance energy transfer (FRET) occurs when excitation energy is transferred from a donor fluorophore to an acceptor dye through weak dipole-dipole resonance interactions (1, 2). FRET is extremely sensitive to the distance between the two dyes, with the transfer rate inversely proportional to the sixth power of the distance between them. This steep distance dependence has suggested that FRET could be used as a spectroscopic ruler on the molecular scale (3, 4). In addition to distance, five other factors influence the rate of energy transfer: (i) the overlap of the donor's and acceptor's excitation and absorbance spectra, respectively; (ii) the refractive index of the solvent; (iii) the relative orientation of the dyes; (iv) the quantum yield of the donor; and (v) the extinction coefficient of the acceptor.Although FRET is sensitive to the distance between probes, several factors have prevented the widespread use of FRET to easily map backbone distances within proteins. First, most commonly used FRET pairs have R 0 values (distance at which FRET efficiency is 50%) between Ϸ30 and 60 Å and are only able to measure distances between Ϸ20 and 80 Å. Thus, to accurately measure distances, the probes must be separated by large distances relative to the size of many proteins. Also, the large size of many dyes and their long attachment linkers position fluorophores far from the backbone of the protein. These flexible linkers also increase the conformational space sampled by the dye (4, 5). Becau...

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“…The data are analyzed using Bayesian parameter estimation to generate a probability density function for the unknown position (i.e., the position of the antennae dye molecule). 16 Yeast RNAP II open complexes containing TBP, TFIIB, TFIIF, RNAP II, and heteroduplex DNA (i.e., contains an engineered bubble around the transcription start site) were studied using a NPS. 15 Downstream DNA in open complexes was found to fluctuate between two locations: within and above the RNAP II cleft.…”

Section: Smfret Elucidates Structural Changes In Open Complexes and Ementioning

confidence: 99%

“…18 This discrepancy could potentially arise from differing experimental conditions, such as ion concentrations. 19 Interestingly, a NPS study found that in the absence of TFIIB, exiting RNA was more likely to contact the dock domain of RNAP II, but upon addition of TFIIB, the contact shifted toward the Rpb4-Rpb7 subunits, 16 suggesting that this switch could be regulated during early transcription.…”

Section: Smfret Elucidates Structural Changes In Open Complexes and Ementioning

confidence: 99%

Single molecule studies of RNA polymerase II transcription in vitro

Horn¹,

Goodrich

Kugel³

2014

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A nano-positioning system for macromolecular structural analysis

Cited by 198 publications

References 33 publications

Oligomerization of the tetramerization domain of p53 probed by two- and three-color single-molecule FRET

Oligomerization of the tetramerization domain of p53 probed by two- and three-color single-molecule FRET

Short-distance probes for protein backbone structure based on energy transfer between bimane and transition metal ions

Single molecule studies of RNA polymerase II transcription in vitro

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