Substituted Benzoxadiazoles as Fluorogenic Probes: A Computational

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Substituted Benzoxadiazoles as Fluorogenic Probes: A Computational Study of Absorption and Fluorescence Alex Brown,*,† Tsz Yan Ngai,† Marie A. Barnes,† Jessie A. Key,‡ and Christopher W. Cairo*,‡ †

Department of Chemistry and ‡Alberta Ingenuity Centre for Carbohydrate Science, Department of Chemistry, University of Alberta, Edmonton, Alberta, Canada, T6G 2G2 ABSTRACT: General chemical strategies which provide controlled changes in the emission or absorption properties of biologically compatible fluorophores remain elusive. One strategy employed is the conversion of a fluorophoreattached alkyne (or azide) to a triazole through a copper-catalyzed azide
alkyne coupling (CuAAC) reaction. In this study, we have computationally examined a series of structurally related 2,1,3-benzoxadiazole (benzofurazan) fluorophores and evaluated changes in their photophysical properties upon conversion from alkyne (or azide) to triazole forms. We have also determined the photophysical properties for a known set of benzoxadiazole compounds. The absorption and emission energies have been determined computationally using time-dependent density functional theory (TD-DFT) with the Perdew, Burke, and Ernzerhof exchange-correlation density functional (PBE0) and the 6-31+G(d) basis set. The TD-DFT results consistently agreed with the experimentally determined absorption and emission wavelengths except for certain compounds where charge-transfer excited states occurred. In addition to determining the absorption and emission wavelengths, simple methods for predicting relative quantum yields previously derived from semiempirical calculations were reevaluated on the basis of the new TD-DFT results and shown to be deficient. These results provide a necessary framework for the design of new substituted benzoxadiazole fluorophores.

’ INTRODUCTION Small molecule fluorophores are essential probes for cell biology and chemical biology.1 An ideal probe will possess properties including the following: (i) spectral resolution from other fluorophores, (ii) a large extinction coefficient and quantum yield (brightness), and (iii) resistance to photobleaching. A wide variety of organic frameworks are currently employed as fluorophores for biochemical studies,2 and the toolkit for introducing these labels into biomolecules continues to expand.3 Yet, chromophores with tailored properties could enable multicolor, FRET, and single-molecule experiments.4,5 Fluorogenic probes—chromophores that become fluorescent under specific conditions—are exceptionally useful but are difficult to design a priori.6
9 An improved theoretical understanding of fluorescent and fluorogenic probes would allow for the design of optimized chromophores. Our groups have been interested in developing a theoretical understanding of commonly employed fluorogenic probes using electronic structure calculations. A number of groups have examined the utility of Cu-catalyzed azide
alkyne coupling (CuAAC), and the resulting triazole functionality, as a method for perturbing fluorophore properties.10 Zhou and Farhni first reported the application of the CuAAC as a fluorogenic strategy using a coumarin dye.9 The triazole product of the CuAAC reaction,11
14 in some systems, provides a means to alter the spectral properties of the initial azide or alkyne.9,15
17 Subsequent formation of the triazole can increase emission intensity or change emission wavelength—properties desirable in fluorogenic probes. In some examples, fluorogenic probes were identified using combinatorial strategies,15 highlighting the need for improved predictive strategies. We previously generated a series of coumarin-derived r 2011 American Chemical Society

triazoles and quantified their photophysical properties.18 We found that these dyes were very sensitive to groups at the 7-position as exhibited by hydroxy- to ethynyl-substitution and subsequent triazole formation—sensitivity at the 7-position has been reported previously.15 We found that the absorbance properties of this series were well-described by time-dependent density functional theory (TD-DFT)—perhaps not surprising considering the benchmark TD-DFT study of substituted coumarins.19 In subsequent work, we have also generated a series of benzoxadiazole-derived fluorophores with pendant azide, alkyne, alkyl, and triazole groups.20 This set of fluorophores contains a unique range of photophysical properties. In this study, we identified dyes which were fluorogenic upon CuAAC, and, remarkably, we also identified dyes which became quenched after CuAAC. Thus, these compounds present an ideal data set for the theoretical description of both excited-state electronic structure and corresponding geometry. The electronic structure of benzoxadiazole (often referred to as benzofurazan in the literature) chromophores have been previously studied by a variety of computational methods.21
27 Uchiyama et al. have experimentally measured the photophysical properties of a large number of 4-substituted, 5-substituted, and 4,7-disubstituted benzoxadiazole compounds in a wide variety of solvents, and they have supported their experimental work with semiempirical electronic structure computations.21
26 Experimental and computational studies of eleven 4-monosubstituted Received: August 17, 2011 Revised: November 14, 2011 Published: December 02, 2011 46

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benzoxadiazole compounds in various solvents suggest that the differences in quantum yield in nonpolar solvents are due to the probability of nonradiative coupling between S1 and T2, which corresponds to the S1 to T2 energy gap.21 The energy gaps were determined at the parametrized model no. 3, complete-active space configuration interaction (PM3-CAS/CI) level of semiempirical theory. For nine 5-substituted benzoxadiazoles the main nonradiative process was proposed to be photoreaction from an excited singlet state; in this case, the quantum yield increased with increasing S1 to S2 energy gaps as determined at the Austin model 1-CAS/CI (AM1-CAS/CI) level of theory.22 For one set of ten 4,7-disubstituted benzoxadiazoles, fluorescence quantum yields were found to be correlated to the S1 to T2 energy gap computed at the PM3-CAS/CI level of theory.23,24 Other experimental and theoretical work on a larger number of 4,7-disubstituted benzoxadiazole compounds (70 in total) suggested a relationship between the relative fluorescence intensity and the Hammett constants of the substituent groups at the 4- and 7-positions.25 A follow-up study on the same set of 4,7-disubstituted benzoxadiazole compounds suggested that the fluorescence characteristics are determined by the total of electron densities on the skeleton and the dipole moment directed from the 4- to the 7-position.26 More recently, Tsuji et al. used TD-DFT, configuration interaction singles (CIS), and symmetry-adapted cluster configuration interaction (SAC-CI) methods to examine theoretically the gas-phase absorption and emission of nine benzoxadiazole compounds. These values were compared with experimental measurements in cyclohexane.27 Tsuji et al. suggest using CIS excitedstate structures with either TD-DFT or SAC-CI energies as the most suitable method to determine fluorescence wavelengths. While each of these approaches has provided a working model for subsets of the benzoxadiazoles, we sought to develop a uniform approach to modeling the electronic structure of these compounds on the basis of TD-DFT. On the basis of the utility and prevalence of CuAAC, we chose to emphasize azide-, alkyne-, and triazolesubstituted compounds relevant for biomolecular conjugations. Theoretical determination of excitation and emission spectra by TD-DFT requires a judicious choice of functional; see, for example, the benchmark studies of Jacquemin and co-workers.19,28
34 Selection must balance the nature of the excitation (valence, Rydberg, and/or charge transfer) and the properties in which one is interested in estimating, e.g., absorption only or absorption and emission. Here, we chose to utilize the hybrid Perdew, Burke, and Ernzerhof exchange-correlation density functional (PBE0)35
37 as it has been shown to perform well for a variety of excited-state properties and can equally well describe ground-state properties. TD-DFT results appear to be less basis set dependent than postHartree
Fock methods,19,29 and, thus, the relatively modest 6-31+G(d) basis38 has been chosen in order to provide a compromise between accuracy and computational speed. This paper reports a computational study of the photophysical properties of a number of mono- and disubstituted benzoxadiazole compounds (see Figure 1 for the backbone structure). In the present work, we intended to assess the use of TD-DFT for predicting the properties of known compounds to validate its use in guiding the design of new substituted benzoxadiazole compounds for labeling strategies.

Figure 1. Chemical structure of a 2,1,3-benzoxadiazole (benzofurazan) skeleton.

PBE0 functional35
37 with the standard Pople-style double-ζ basis sets,38 6-31+G(d), for all atoms. The vertical excitation energies at the ground-state equilibrium geometries were calculated with TD-DFT40
42 using the PBE0 functional and the 6-31+G(d) basis set. To determine the fluorescence wavelengths, the geometries of S1 excited states were optimized at the TD-DFT PBE0/6-31+G(d) level of theory. The S1fS0 energy gap at the optimized excited-state geometry was taken as the fluorescence wavelength. All calculations were carried out in the gas-phase and utilized C1 symmetry. The energies of the next highest lying singlet state, S2, and the second lowest lying triplet state, T2, were also determined using TD-DFT PBE0/6-31+G(d) in order to assess possible deactivation mechanisms leading to high (or low) quantum yields as suggested by Uchiyama and co-workers.21
23,25,26 While one could determine the lowest triplet-state energies using standard DFT, we wanted to determine a straightforward analysis method analogous to that using PM3-CAS/CI or AM1-CAS/ CI calculations as suggested earlier for benzoxadiazoles,21
23,25,26 and this analysis focused on the T2 energies rather than those of T1. All ground- and excited-state calculations were carried out with Turbomole43 using default convergence parameters except for finer numerical grids (designated as m4 in Turbomole) in the DFT and TD-DFT calculations. To verify the comparison of the gas-phase theoretical results with the experimental data, computations were carried out for a subset of all compounds considered using the polarizable continuum model (IEF-PCM)44,45 with parameters for n-hexane as implemented in Gaussian09.46 The ground-state geometries were optimized at the PCM-PBE0/6-31+G(d) level of theory. The absorption wavelengths were determined using TD-DFT with the same functional and basis set. For the determination of the fluorescence wavelengths, the geometry of the S1 excited state has been optimized47 using the state-specific PCM model.48,49

’ RESULTS AND DISCUSSION Computationally determined photophysical properties for compounds 1a
6b were compared with experimental absorption and fluorescence values as measured in n-hexane (dielectric constant, ε = 1.9). Additional experimental values were derived from a series of 4-substituted, 5-substituted, and 4,7-disubstituted benzoxadiazoles analyzed computationally using the PM3-CAS/CI and AM1-CAS/CI methods by Uchiyama and co-workers.21
23,25,26 We chose to focus on the 4-substituted and 5-substituted benzoxadiazoles which exhibit fluorescence in n-hexane.21,22 Absorption and emission properties for many of the monosubstituted and a single disubstituted (NBD-NHMe) species had been determined previously using TD-DFT and SAC-CI methods.27 In the present work, we have examined a set of new azide- (-N3) and ethynyl-substituted (-CtCH) benzoxadiazoles and their triazole forms produced via a CuAAC reaction.12,13 The structures of the substituents for these new compounds are given in Figure 2 and Figure 3 for the 5-substituted and the 4,7-disubstituted compounds, respectively. The synthesis and full characterization of

’ COMPUTATIONAL METHODS Ground-state geometries of the substituted benzoxadiazoles were optimized with density functional theory39 using the 47

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Figure 3. Substituents for 4,7-disubstituted benzoxadiazole compounds. R5 = R6 = H.

Table 1. Experimental21,22,24 (in n-Hexane) and Theoretical (Gas-Phase TD-DFT PBE0/6-31+G(d) and SAC-CI/6-31 +G(d)27) Absorption Wavelengths for a Set of Previously Reported 4-Substituted, 5-Substituted, and 4,7-Substituted Benzoxadiazoles (NR = Not Reported)

Figure 2. Substituents for 5-monosubstituted benzoxadiazole compounds. R4 = R6 = R7 = H.

these compounds has been reported elsewhere.20 To distinguish between the two sets of compounds, we will refer to the compounds of Uchiyama and co-workers as set A, and the azide-, ethynyl-, and triazole-substituted compounds of Key and Cairo will be called set B. While solvent plays an important role in influencing the photophysical properties of the benzoxadiazoles,20
23,25,26 we sought to determine whether computational methods provide an accurate assessment and prediction of these properties for the simplest comparative case of gas-phase calculations versus experimental measurements in n-hexane, a nonpolar solvent. We found that the absorption wavelengths were well-described by TD-DFT; however, the emission wavelengths were more challenging to interpret. We discuss previously explored models21
23,25,26 to predict the relative quantum yields in the context of the new TDDFT PBE0/6-31+G(d) results.

substituent

λexpt/nm

λTD‑DFT/nm

λSAC‑CI a/nm

4-NHCOMe

348

349

376

4-NMe2 4-SMe

403 362

387 384

408 400

4-NH2

376

367

408

4-SPh

362

363

NR

4-OMe

331

351

NR

5-NH2

349

336

374

5-NMe2

373

348

398

5-OMe

316

304

327

5-SMe 5-NHAc

345 329

336 320

333 NR

NBD-NHMe

422

383

451

—

14.7

22.8

MAE a

SAC-CI excitation energies calculated at DFT PBE0/6-31+G(d) ground-state geometries.

were compared with previously measured experimental values (set A; see Table 1). Table 1 also contains recently reported SACCI results for a smaller subset of benzoxadiazole compounds included in set A.27 Table 2 contains the theoretically determined, and experimentally measured, absorption wavelengths for the newly synthesized azide-, ethynyl-, and triazole benzoxadiazoles (set B). We include in our analysis the experimentally measured molar absorption coefficients (ε) for comparison to the

’ ABSORPTION WAVELENGTHS Computationally determined absorption wavelengths of 4-substituted, 5-substituted, and NBD-NHMe benzoxadiazoles 48

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Table 2. Experimental (in n-Hexane) and Theoretical (Gas-Phase TD-DFT PBE0/6-31+G(d)) Absorption Wavelengths for the 5-Substituted and 4,7-Substituted Benzoxadiazoles Synthesized in the Present Studya substituent

λexpt/nm

ε

λTD‑DFT/nm

f

5-Substituted Benzoxadiazoles 1a

289

24 300

292

0.0749

1b

289

11 200

290 b

0.0525

1c

278

500

301 c

0.0681

1d

277

2 400

296 c

0.0746

2a

325

9 000

325

0.1037

2b

318

18 900

314

0.1132

2c 3a

299 298

400 4 800

291 c 313

0.0884 0.0885

3b

324

9 000

321

0.1144

4a

375

30 500

367

0.3515

4b

380

21 900

398

0.2880

5a

410

17 100

383

0.3138

5b

504

28 300

374

0.3330

6a 6b

420 not soluble

12 200 NM

385 386

0.3218 0.3434

4,7-Disubstituted Benzoxadiazoles

MAE

Figure 4. Correlation between the experimentally observed absorption wavelengths (in n-hexane) and the gas-phase TD-DFT(PBE0)/ 6-31+G(d) values. Previously studied (circles) and new (squares) compounds are illustrated along with a linear fit to the data (R2 = 0.928).

We found that there is an excellent linear correlation between the calculated and experimental absorption λmax values; using the formula

12.6 d (21.0)

a

Also included are the experimental molar absorption coefficients and the theoretical oscillator strengths (f). See Figure 2 and Figure 3 for the identity of the compounds. b Absorption to S2. c Absorption to S3. d Excluding compound 5b.

λexpt ¼
48:105 þ 1:1502λTD


DFT

ð1Þ

provides an excellent fit to the data (R2 = 0.928; see Figure 4). The linear correlation can be used to correct the computed values to experimental ones. Indeed, when the corrected values are used, the MAE is 12.8 nm over all 25 compounds (with 5b excluded). Clearly, this does not represent a significant improvement over the “raw” TD-DFT results. By including the newly synthesized compounds found in set B, we increase the span of experimental absorption wavelengths from 316 to 422 nm (set A), to 277 to 504 nm (sets A and B). Although the TD-DFT results fail to reflect the longest wavelength absorption correctly, vide supra. Since one goal of the present study is to determine a useful computational method for screening potential fluorophores for labeling strategies, the use of gas-phase absorption values should be validated by comparison with values determined using PCM for solvation—although the high correlation (R2 = 0.928) with the experimental data suggests the use of gas-phase values is warranted. In Table 3 the absorption wavelengths as determined in n-hexane are presented for eight of the set B compounds. The average shift (relative to the theoretical gas-phase values) is 9 nm (0.08 eV) and the discrepancy is dominated by compounds 3b and 5b, which are both triazole-substituted compounds containing benzene rings. The main reason for the large shifts for these two compounds is due to changes in the molecular geometry in going from the gas to solution phase. However, the MAE for the n-hexane results is 11.4 nm and is slightly greater than the MAE of the gas-phase results,which is 9.4 nm for these eight compounds. There is also no change in the trends upon inclusion of solvent effects—for the gas-phase versus the PCM theoretical data R2 = 0.925. Therefore, for initial screening of compounds by absorption wavelength, gas-phase data are suitable. However, for detailed study of particular compounds, the solvent effects should be taken into account.

theoretically determined oscillator strengths. The reported theoretical absorption wavelengths correspond to the transitions with the longest wavelength of significant oscillator strength (f > 0.025). In most cases, these transitions are to the lowest energy bright excited states (S0fS1). There are four notable exceptions where the strongest absorption is not to the lowest lying excited state: 1b with excitation to S2, 1c to S3, 1d to S3, and 2c to S3. Our TD-DFT results were consistent with previously reported27 TD-DFT results which included a subset of the same compounds (Table 1). The absorption wavelengths determined using TD-DFT PBE0/6-31+G(d) were in good agreement with the experimental data with a mean absolute error (MAE) of 14.7 nm for the previously reported compounds (set A; see Table 1) and 12.6 nm for the new compounds (set B; see Table 2). Extending the number of 4- and 5-substituted compounds considered in the present study results in a decreased MAE relative to a previous report.27 In evaluating the MAE for the newly synthesized compounds, we have omitted compound 5b. The maximum absorption coefficient of 5b is for an absorption at 504 nm, while TD-DFT predicts an absorption at 374 nm. Interestingly, there is an experimental absorption at 347 nm. Note that computation using an alternate range-separated hybrid functional (CAM-B3LYP) predicts an absorption at 371 nm; see the discussion regarding fluorescence for the choice of this functional. Therefore, we interpret the strong absorption at 504 nm to correspond to a state that is not well captured by DFT, e.g., involving double excitation. It has been suggested that a statistical analysis (linear regression) of TD-DFT calculated values can improve the agreement between computed and experimentally measured absorption wavelengths for particular classes of compounds.29 49

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Table 5. Experimental (in n-Hexane) Quantum Yields (Φf) and Theoretical (Gas-Phase TD-DFT PBE0/6-31+G(d)) Fluorescence Wavelengths for 5-Substituted and 4,7-Disubstituted Benzoxadiazoles Analyzed in the Present Studya

Table 3. Theoretical (n-Hexane PCM-TD-DFT PBE0/6-31 +G(d)) Absorption Wavelengths for a Subset of 5-Substituted and 4,7-Disubstituted Benzoxadiazoles Analyzed in the Present Studya λTD‑DFT/nm

substituent

shift/nm (eV)

substituent

5-Substituted Benzoxadiazoles

λexpt/nm

Φf

λTD‑DFT/nm

5-Substituted Benzoxadiazoles

2a

326

1 (0.02)

1a

NM

0

365

2b b

317

3 (0.03)

1b

NM

0

470

3a

319

6 (0.08)

1c

NM

0

572

3b

335

14 (0.16)

1d

NM

0

296

2a

424

0.01

376

2b

370

0.002

424

2c 3a

NM 406

0 0.008

489 365

3b

375

0.008

381

4,7-Disubstituted Benzoxadiazoles 372

4a 4b 5a

401 388

5b

407

MAE

11.4

5 (0.04) 3 (0.03) 5 (0.04) 33 (0.27) c

4,7-Disubstituted Benzoxadiazoles

a

Also, presented are the shifts relative to the gas-phase TD-DFT PBE0/ 6-31+G(d) results. See Figure 2 and Figure 3 for the identity of the compounds. b -C6H15 chain replaced with -CH3 c Excluding compound 5b.

Table 4. Experimental (in n-Hexane) and Theoretical (Gas-Phase TD-DFT PBE0/6-31+G(d) and SAC-CI/6-31 +G(d)27) Fluorescence Wavelengths for a Set of Previously Reported 4-Substituted, 5-Substituted, and 4,7-Substituted Benzoxadiazoles (NR = Not Reported) 21,22,24

substituent

λexpt/nm

λTD‑DFT/nm

4-NHCOMe

439

429

479

4-NMe2 4-SMe

513 433

486 484

544 389

4-NH2

500

470

479

4-SPh

457

597 b

NR

412

437

NR

5-NH2

422

406

475

5-NMe2

452

609 b,c

498

5-OMe

365

360

372

5-SMe 5-NHAc

392 383

443 373

397 NR

NBD-NHMe

500

443

532

MAE

28.9 d

522

0.03

4b

501