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Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Schematic representation of the steps involved in the Monte Carlo simulation scheme.

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Presentation on theme: "Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Schematic representation of the steps involved in the Monte Carlo simulation scheme."— Presentation transcript:

1 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Schematic representation of the steps involved in the Monte Carlo simulation scheme for calculating the FRET efficiency of any arrangement of fluorophores. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

2 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. ExiFRET can be used to model FRET for fluorophores in a uniform distribution (b) or aggregated into clusters (a). Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

3 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. (a) FRET efficiency versus fluorophore separation for hosts distributed in a 2-D environment containing a single donor-acceptor pair for a series of different n-mer surface densities (noted next to each curve in units of ×10-3 Å 2). (b) ExiFRET can be used to quantify the contribution of inter- and intramolecular FRET to the total FRET efficiency, as shown for host proteins (n-mers) distributed in a environment containing a single donor-acceptor pair. The total FRET efficiency increases with increasing surface density due to the increasing likelihood of intermolecular FRET. The values of the key parameters are shown in the figure. A complete and representative input file for this and the subsequent figures is given on the website (www.exifret.com). Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

4 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. FRET in multimeric proteins. The FRET efficiency is plotted versus the radius of the multimer in 2-D for a situation in which each subunit has equal probability of holding a donor or an acceptor. Numbers next to each curve refer to the number of subunits in the multimer (n-mer size). The different mulitmers are shown on the right. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

5 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. FRET efficiency is plotted against donor probability for a series of oligomers of increasing n-mer size (given beside each curve) distributed in 2-D. The multimer radius in each case is chosen such that the FRET efficiency is 0.5 when the donor probability=0.5. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

6 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. FRET efficiency plotted against multimer radius for a set of pentameric proteins with different stoichiometries of donors and acceptors. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

7 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Plot of FRET efficiency versus donor probability for fluorophores arranged in pentamers that are uniformly distributed in 2-D. Solid line: radius r1 (38 Å ) was used to avoid overlapping the pentamers and r2 (50 Å ) was used to generate fluorophore coordinates and calculate the FRET efficiency by considering the size of the fluorophores. Dashed line: a single radius (r2) is used to generate the pentamer positions, fluorophore coordinates, and calculate the FRET efficiency. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

8 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Plots of FRET efficiency versus fluorophore separation for a series of tetramers distributed in 2-D with different labeling efficiencies, as shown beside each curve. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

9 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 8. The individual graphs are produced by changing the nmer_size and P_donor parameters. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

10 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 9. The individual graphs are produced by changing the labeling_efficiency parameter. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

11 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 10(a). The individual graphs are produced by varying the cluster, n_cluster, and radius_cluster parameters. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

12 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 10(b). The individual graphs are produced by varying the parameters n_clusters and radius_cluster. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

13 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 7. The individual graphs are produced by changing the da_stoichiometry, d_per_nmer and a_per_nmer parameters. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

14 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 6. The individual graphs are produced by changing the nmer_size and P_donor parameters radius_min and radius_max were changed such that the FRET efficiency=0.5 when P_donor=0.5. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

15 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 5. The individual graphs are produced by changing the nmer_size parameter. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

16 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 4. Case 3. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

17 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 4. Case 2. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

18 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 4. Case 1. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

19 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 3(b). (intramolecular FRET). Inter- and intramolecular FRET can be calculated using the da_stoichiometry and da_separate parameters (see also Fig. 4). Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

20 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. (a) Plots of FRET efficiency versus fluorophore surface density for randomly arranged fluorophores (unclustered) and fluorophores arranged in low- and high-density clusters. The absence of changes in FRET efficiency can be used to detect clusters, while the magnitude of the FRET efficiency determines the local concentration in the cluster. (b) FRET efficiency is plotted versus fluorophore surface density when either the cluster dimension is the same but the internal density is varied (lower line), or the internal density is fixed but the size of the cluster changes (upper line). Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

21 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. FRET efficiency versus fluorophore density for three different labeling protocols of hosts with two fluorophores distributed in 2-D. Comparisons of the FRET efficiencies of the three cases can be used to quantify the contributions of inter- and intramolecular FRET. (a) The total FRET efficiency for each case. (b) Inter- and intramolecular FRET for each case. Note that the intramolecular FRET is always 0 for case 3. Case 1: every site has equal probability of being a donor or acceptor (solid lines). Case 1 is modeled using dastoichiometry=false, daseparate=false. Case 2: each host has one donor and one acceptor (dashed lines). Case 2 is modeled using dastoichiometry=true, daseparate=false. Case 3: each host has either two donors or two acceptors (dot-dot-dashed lines). Case 2 is modeled using dastoichiometry=false, daseparate=true. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

22 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. Example input files for Fig. 3(a). The individual graphs are produced by changing the density_min and density_max parameters. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

23 Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. FRET efficiencies for fluorophores with constrained orientations. (a) FRET efficiency is plotted for a pair of fluorophores versus their orientational freedom (measured by the cone angle θ). In all cases, the transition dipole orientations are in parallel, but in the upper lines they are also in parallel to the direction of fluorophore separation, while in the lower lines they are perpendicular to this direction. Solid and dashed lines show results that assume a dynamic orientational-averaging regime, while dotted lines show equivalent results that assume static averages. (b) The FRET efficiency is plotted as a function of the angle between the mean transition dipole orientation of the donor and acceptor ( ϕ ) where the dipoles are perpendicular to the direction of their separation. Results are shown assuming the transition dipole can move within a cone of angle 0, 30, 60, and 90-deg. In all cases the cone angle θ, of the donor and acceptor are equal. Figure Legend: From: ExiFRET: flexible tool for understanding FRET in complex geometries J. Biomed. Opt. 2012;17(1):011005-1-011005-11. doi:10.1117/1.JBO.17.1.011005

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