Infrared spectra of 6-thioguanine tautomers. An experimental and theoretical approach

Spectrochimica Acta Part A 58 (2002) 1793– 1808 www.elsevier.com/locate/saa

Infrared spectra of 6-thioguanine tautomers. An experimental and theoretical approach Okuma E. Kasende * Faculte des Sciences, Uni6ersite de Kinshasa, B.P. 190, Kinshasa XI, Congo Received 27 August 2001; accepted 2 October 2001

Abstract Both amino-thiol N9H and amino-thiol N7H tautomeric forms of 6-thioguanine have been identified in approximately equal abundance in infrared studies of these molecules isolated in the hydrophobic environment of an argon matrix at 12 K. The relative concentrations of the amino-thiol N9H and amino-thiol N7H ([SH, N9H]/[SH, N7H]=KN9H − N7H = 1.0090.02) are estimated from the observed relative infrared absorbances. From these relative concentrations, the difference in the Gibbs free energy of these two tautomers (DG500 N9H − N7H = − 0.0129 0.005 kJ mol − 1) have been estimated. The infrared and Raman spectra of 6-thioguanine in solid state are also discussed in terms of hydrogen bonding and stacking interactions in the crystal which are not considered in the calculation. In an effort to interpret the experimental results, ab initio calculation of the infrared spectrum has been made for the amino-thione N7H tautomer at 3-21G level. Comparison with experimental spectra is of some help in the assignment of the infrared and Raman spectra for 6-thioguanine in the solid state. © 2002 Elsevier Science B.V. All rights reserved. Keywords: 6-Thioguanine; Tautomerism; Infrared spectrum; Raman spectrum; Matrix-isolation; Ab initio calculation

1. Introduction Thioguanine (TG) is a known metabolic inhibitor [1–3] with antitumor and antineoplastic activity used in cancer research [4 – 9]. One of its interesting features is that, similar to guanine [10 –13], a number of different tautomeric forms are possible. They are shown in Fig. 1. For the N9-substituted thioguanine, a residue of thioguanosine, only tautomers 2, 4, 6, 8, 10 and 12 are possible. * Tel.: +243-990-5757. E-mail address: [email protected] Kasende).

(O.E.

According to X-ray data [14] only the aminothione tautomer with the proton at N7 (scheme 2 in Fig. 1) is present in the crystal, in contrast to guanine for which the N9H oxo tautomer is detected [15]. However, the amino-thione N7H tautomer is not the most stable form predicted by recent ab initio calculations [16,17]. These calculations predict that the amino-thiol with the proton at N9 is the most stable tautomer [16,17]. The Leszczynski’s calculation at MP(full)/DZP level predicts the amino-thione N7H tautomer to be less stable by 1.8 kJ mol − 1 than the most stable amino-thiol form (scheme 3 in Fig. 1)[16]. Such a discrepancy between the theoretical prediction of

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O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

the relative stability and X-ray data is the effect of hydrogen bonding and stacking interactions in the crystal which are not considered in the calculation. The amino-thione N7H tautomer (scheme 2), identified in the crystal by the X-ray experiment, has the lowest calculated dipole moment (1.78 D) [16] of any of the thioguanine tautomers shown in Fig. 1. The largest dipole moment (7.42 D) [16]) is predicted for the amino-thione N9H tautomer (scheme 2 in Fig. 1). The presence of the least polar tautomer in the crystal instead of one of the more polar forms is indeed very surprising. It must be a result of packing in the crystal to fulfill the best hydrogen bonding pattern between the molecules in the crystal, and clearly overpowers the electrostatic dipole– dipole forces usually thought to dictate the predominant tautomer expected in a polar medium. In view of these differences between predictions

from the calculation and the structures observed from the X-ray studies, it is particularly interesting to establish experimentally which tautomer(s) of TG is/are present in the absence of hydrogen bonding and stacking interactions. Because of the difficulty of studies of TG in the gas phase, related to its high melting point and possible thermal decomposition, and because of very low solubility of TG in any inert solvent, the only practical way to study isolating TG is in an inert, rigid, argon matrix. The environment in the inert Ar matrix is non-perturbing and close to that in the vapor state; that is, the conditions of the TG molecules are equivalent to those for which calculations have been performed. The main goal of this study is to establish experimentally which tautomers are present in an inert argon matrix and to verify existing ab initio results.

Fig. 1. Structure of the tautomeric forms of 6-thioguanine.

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

We used matrix isolation infrared spectroscopy as the experimental method to determine which tautomeric forms occur for the isolated molecules. This technique has proven to be the most useful procedure for studies of the tautomeric equilibria for a number of pyrimidine and purine bases [18]. The infrared spectrum of TG isolated in an argon matrix is compared with infrared spectra calculated at the HF/6-31 G (d, p) level for aminothione and amino-thiol tautomers shown in schemes 1–4 in Fig. 1. Such a comparison is very helpful in establishing which tautomers are present in the matrix sample. Verification and additional assignments are achieved by comparing the infrared spectra of matrix-isolated TG with infrared spectra for several related model compounds.

2. Methods

2.1. Experimental The experimental procedure and conditions for preparing the matrix-isolated samples and studying the infrared spectra were the same as those described by Person et al. [19]. The infrared spectra were recorded with a Nicolet Model 740 FTIR spectrometer at 1 cm − 1 resolution. The matrix sample was obtained by passing argon gas over the subliming sample of TG (from Sigma) and condensing the resulting gaseous mixture onto a cold (about 12 K) CsI window mounted in a closed cycle He cryostat (Displex model CSA 202E). The infrared spectrum of a polycrystalline sample was recorded for a solid sample dispersed in KBr with the same Nicolet FTIR instrument at 1 cm − 1 resolution. The Raman spectrum was taken for a polycrystalline powder sample of TG placed in a small cavity (about 0.5 mm radius) in an aluminum block and recorded on a Brucker model 66 FTIR spectrometer equipped with the Raman station (FRA 106) using the near infrared line (1.064 mm) from a Cw Nd-YAG laser (CVI Laser Co.) as the exciting line, operated at 4 cm − 1 resolution.

1795

2.2. Calculation Ab initio calculations of the vibrational spectra were carried out using the GAUSSIAN 86 program [20] with a split valence 6-31 G (d, p) basis set. The geometries of the tautomers were optimized by the gradient procedure [21], without requiring the restriction of planarity for the molecules. The frequencies calculated for all the non-planar structures were real, whereas those for planar structures have one imaginary frequency, showing that the structure corresponds to a saddle point in the potential energy. In the nonplanar structures the amino group nitrogen atom lies above the purine ring plane (2° or 0.05 A, ). Relatively large deviations (30° or 0.4 A, ) from the molecular plane were calculated for the hydrogen atoms of the amino group.

3. Results and discussion Fig. 2 shows a comparison of the experimental spectrum of matrix-isolated TG with the calculated spectra of four tautomers of TG. The reason for starting the discussion with such a comparison is to find out how much the spectra of these tautomers differ from each other and what chances we may have to distinguish one tautomer from the other. At this point we shall focus our attention only on the stronger bands, which should be well identified in the experimental spectrum. As seen in Fig. 2 the most dramatic differences between the calculated spectra for different tautomers occur in the following regions: 3560– 3510; 3430–3400; 1550–1400; 1360–1290 cm − 1. Examining both the experimental and calculated spectra one can see that the experimental spectrum is most closely related to the calculated spectra of the two amino-thiol tautomers, suggesting that these two species are predominant in the matrix sample. In Fig. 3 we present a more detailed comparison of the experimental spectrum of the isolated molecule (spectra c) with the calculated spectra of the two amino-thiol tautomers (spectrum a and b) and with the equally weighted sum of the latter (spectrum d).

1796

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

Fig. 2. Comparison of the experimental spectrum of matrix isolated TG with the calculated spectra of amino-thiol N9H (SH, N9H), amino-thiol N7H (SH, N7H), amino-thione N9H (CS, N9H) and amino-thione N7H (CS, N7H) tautomers of 6-thioguanine using a 3-21G basis set.

As seen in this figure the calculated spectra a and b are nearly identical in most spectral regions. The most pronounced differences are observed near 1499, 1260 and 513 cm − 1. Separately neither calculated spectrum a nor b agrees with the experimental spectrum. However, the sum of the spectra a and b resembles the experimental spectrum very closely and this suggests very strongly, or even proves, that these two amino-thiol tautomers of TG strongly predominate in the matrix-isolated sample. The experimental spectrum of isolated molecule shows rather a complex structure in the region of the SH stretching mode (Fig. 4) which could be explained as arising due to Fermi resonance between the fundamental of SH stretching mode and some suitable overtone/combination. However, comparing the calculated spectra of the two amino-thiol tautomers (specta a and b) taken together and the experimental spectrum (spectrum c), suggests that these two amino-thiol tautomers are predominant in the matrix-isolated sample. The analysis of the different regions of the

experimental spectrum and the corresponding regions of the calculated spectra, provides the assignment of the experimental lines to the normal modes of each amino-thiol tautomer. This assignment is given in Table 1, where experimental and calculated frequencies and intensities together with the potential energy distributions are collected. Using experimental values of the integrated absorbencies for the characteristic vibrations of each tautomer (e.g. the NH2 asymmetric and symmetric stretching modes) with the calculated values of the absolute intensities for the corresponding modes, we have estimated the equilibrium constant K(T) K(T)=

[tautomer:SH, N9H] [tautomer:SH, N7H]

and the difference in the Gibbs free energy (DG) of these two tautomers DG = − RT ln K(T)

WN

3558 3490 3433 3049 2599 1631

1593 1582

1546 1454

1390

1366 1353

Q

1

2 3

4 5 6

7

8

9

10

11

12

13

b

Calculation (cm−1)

Amino-thiol N9H

124

6

204

230

27

485

395

3 1 458

129 99

63

AIR (km mol−1)

e

AmH15 s(51+) AmH16 s(49−) N9H s(100+) AmH16 s(51−) AmH16 s(49−) C8H s(99−) SH s(100+) N3C4 s(32+) N1C6 s(11+) C5C4 s(10−) HNH sci(72−) CNH2 s(15−) C6C5 s(17−) N7C8 s(17+) C5C4 s(16+) C2N3 s(11−) N1C2 s(10+) N7C8 s(49+) C2N3 s(10+) CNH2 s(13+) N1C6 s(12+) HNH sci(12−) N9C4 s(10+) CNH2 s(20−) N1C6 s(18+) C5C4 s(13−) N9H be(33+) C8N9 s(21+) C6C5 s(16+) N9C4 s(16−) N1C6 s(12+) C5N7 s(11−) N9H be(11+)

PED

1353

1366

1395

1459

1577

1599

2605 1622

3485 3456

3574

WN

c

(cm−1)

Experiment (Ar)

26

7

17

17

93

14

17

117 121 37

109 127

53

IIR

a

d

1333

1380

1596

1460

1507

1583

1590

3042 2605 1626

3498 3427

3548

WNb (cm−1)

Calculation

52

327

101

134

119

443

371

6 2 382

124 83

57

AIR (km mol−1)

Amino-thiol N7H

N7H be(24−) N7C8 s(17+) C2Am s(15−) C5C4 s(15+) N1C6 s(14−) C5N7 s(18−) C5C4 s(13+) C8H be(13−)

C8N9 s(43+) C8H be(19−) C2N3 s(16+) N1C6 s(13−) N7H be(13+)

AmH15 s(52−) AmH16 s(48+) N7H s(100−) AmH16 s(52−) AmH15 s(48−) C8H s(99−) SH s(100−) C6C5 s(25+) N3C4 s(17−) C2N3 s(13+) HNH sci(75+) C2Am s(12+) C5C4 s(26+) N3C4 s(20−) N1C2 s(13+)

PEDe

1388 1386 1310 1313

1404

1463

1499

1573 1571

1597

2600 1619

3491 3449

3564

WNc (cm−1)

27

29

38

4

13

9

9

125 117 19

68 124

52

IIRd

Experiment (Ar)a

Table 1 Wavenumbers (WN), infrared integrated intensities, AIR, infrared integrated relative intensities, IIR and potential energy distributions (PED) for amino-thiol N9H and amino-thiol N7H tautomers

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808 1797

WN

1299

1190

1171

1073

1036

1028

940

907

893 885

Q

14

15

16

17

18

19

20

21

22

23

b

Calculation (cm−1)

Amino-thiol N9H

Table 1 (Continued)

95

3

11

15

18

27

11

11

59

18

AIR (km mol−1)

e

R5 def1(44+)

C8H owa(103−)

R5 def1(20+) C6S s(16−) C5C4 s(13+) N1C2 s(13+) C2N2 s(12+) CNH2 s(10+) C6SH be(68+)

N1C2 s(22−) NH2 ro(15+) N9C4 s(14+) C6Sh be(12−) C6S be(12−) C8N9 s(61+) N9H be(27−)

NH2 ro(43−) C2N3 s(28−)

N1C6 s(20+) N3C4 s(17−) N1C2 s(13−) NH2 ro(12−) C8H be(26−) C5N7 s(21+) R6 def1(20+)

C8H be(41+) C5N7 s(18+) N7C8 s(10−)

PED

906

840

917

956

1027

1036

1058

1188

1198

1298

WN

c

(cm−1)

Experiment (Ar)

2

1

7

16

92

1

9

3

49

71

IIR

a

d

883

901

920

940

1018

1082

1085

1158

1178

1288

WNb (cm−1)

Calculation

67

13

23

3

6

29

24

13

64

135

AIR (km mol−1)

Amino-thiol N7H

C6S s(18+) C5C4 s(17−) R5 def1(14−) C2N3 s(11−) R5 def1(44+) C6SH be(23+) C6SH be(51−)

N1C2 s(30−) N9C4 s(18+) NH2 ro(11−) C6SH be(10−) C8H owa(104−)

R6 def1(23+) C5N7 s(21+) C8H be(20−) N9C4 s(10−) NH2 ro(33+) C2N3 s(24−) N7C8 s(13−) N7C8 s(46+) N7H be(19+)

C8N9 s(26+) C8H be(25+) N7H be(12+) N9C4 s(10−) NH2 ro(21−) N1C6 s(19−) N3C4 s(12+)

PEDe

903

888

938

1020

1084

1088

1183

1186

1263

WNc (cm−1)

6

2

11

1

4

5

14

9

17

29

IIRd

Experiment (Ar)a

1798 O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

WN

805

797

733

641

617

611

532

505 496 468 406 339

Q

24

25

26

27

28

29

30

31

32

33

34

35

b

Calculation (cm−1)

Amino-thiol N9H

Table 1 (Continued)

4

5

10

164

9

3

1

7

6

9

11

51

AIR (km mol−1)

e

NH15 owa(45+) NH16 owa(43+) C6S s(39+) R6 def2(36−) R5 ode3(45+) R6 ode1(34−) R5 ode1(23−) R6 ode2(10−)

C2Am owa(47+) R5 ode2(39−) R5 ode1(35−) R5 ode2(65−) R5 ode1(49+) C6S owa(14+) R5 def2(32+) C6C5 s(17+) C2N be(15−) R6 def3(10+) R5 ode3(46+) C6S owa(43−) R6 ode2(14−) R6 def2(27+) N9C4 s(16+) R6 def1(10+) R6 def3(49+) C2N be(12+) N9H owa(97−)

C6S s(12+) C2Am owa(26−) R6 odel(22+) R5 ode2(19−) R5 ode1(13−) R6 def1(19−) C5N7 s(16+) R5 def(12−)

PED

–

426

513

510

552

598

638

645

730

815

791

WN

c

(cm−1)

Experiment (Ar)

1

3

2

2

4

11

1

3

28

1

3

2

IIR

a

d

354

371

403

451

507

539

580

616

632

739

795

802

WNb (cm−1)

Calculation

56

331

12

16

7

3

1

1

1

3

14

52

AIR (km mol−1)

Amino-thiol N7H

R5 ode1(79−) C6S owa(31−) R5 ode2(14+) R5 def2(31−) C2Am be(15−) C6C5 s(15−) R6 def3(12−) R5-R6 owa(57−) C6S owa(21+) R6 ode2(14+) R6 def2(26−) N9C4 s(18−) R6 def1(10−) R6 def3(48−) C2Am be(10+) NH16 owa(59−) NH15 owa(32−) C6S s(39−) R6 def2(34+) NH15 owa(48+) NH16 owa(19−) R5-R6 owa(17−) N7H owa(17−) NH15 owa(17−) R6 ode1(16+)

R5 ode2(27+) C2Am owa(22+) R6 ode1(20−) R6 def1(15−) R5 ode(13+)) C5N7 s(13+) R5 def2(12−) R5 ode2(68−) C2Am owa(45+)

PEDe

422

519

548

574

603

730

816

791

WNc (cm−1)

3

1

4

2

6

8

1

4

1

1

4

2

IIRd

Experiment (Ar)a

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808 1799

309 303

291

227

183 158

125

36

37

38

39

40 41

42

b

(cm−1)

1

3 16

4

45

300

39

AIR (km mol−1)

e

R6 ode3(58−) R6 ode2(18−) SH tor(13−) R5 ode3(11−) C6S be(72−) R6 ode1(24−) R5 ode3(24−) C6S owa(18−) C2Am owa(13−) R5 ode2(11−) R6 ode3(52+) R6 ode3(51−) C6S owa(14+)

C2N be(44−) R5 def2(11 NH15 owa(36−) NH16 owa(32+) SH tor(21+) SH tor(63+) NH15 owa(14+) NH16 owa(10−)

PED

WN

c

(cm−1)

Experiment (Ar)

17

2 1

1

2

4

2

IIR

a

d

122

182 153

189

240

308

339

WNb (cm−1)

Calculation

22

3 14

14

6

13

122

AIR (km mol−1)

Amino-thiol N7H

C6S be(75+) R5-R6 owa(32−) R6 ode1(23−) C6S owa(12−) C2Am owa(11−) R5 ode2(51−) C6S owa(15+) R6 ode(53+) R6 ode2(51−) C6S owa(157)

R5 ode1(16+) NH16 owa(13+) N7H owa(74+) R5 ode1(22+) C2Am be(49+) R5 def2(11−) C6S s(10−) R6 ode3(41+) HS tor(27−) R6 ode2(23+) R5-R6 owa(16+) HS tor(62+) R6 ode3(27+)

PEDe

WNc (cm−1)

1

2 1

2

1

2

1

IIRd

Experiment (Ar)a

b

Dilute in argon matrix at 15 K. Wavenumbers scaled by a constant factor of 0.91. c Only the strongest band is given when multicomponent bands are observed. d Integrated relative intensities in unit chosen in such way that the observed intensity sum of the in-plane modes observed in the separated spectra of amino-thiol N9H or amino–thiol N7H tautomer is equal to the calculated intensity sum of these modes. e Abbreviations: s, stretching; be, bending; sci, scissoring; owa, out-of-plane wagging; ro, rocking; def, deformation; ode, out-of-plane deformation; tor, torsion.

a

WN

Q

Calculation

Amino-thiol N9H

Table 1 (Continued)

1800 O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

for T=500 K (227 °C) corresponding to the temperature of the gas phase equilibrium at which the sublimation took place. The values obtained are K(T) = 1.00 9 0.02 and DG = − 0.01290.005 kJ mol − 1. The small value of the difference in the Gibbs free energy indicates that both amino-thiol N9H and amino-thiol N7H tautomeric forms of TG have been identified in approximately equal abundance. To evaluate the effects of hydrogen bonding and stacking interactions on the spectrum of the TG molecule, we have also studied infrared and Raman spectra of the crystalline solid and compared with the infrared and Raman spectra calculated for the isolated tautomer (amino-thione N7H, shown in scheme 2 of Fig. 1) identified in the crystal by the X-ray study. These spectral data are collected in Table 2, where the wavenumbers, intensities and descriptions of the normal modes

1801

(potential energy distributions, PED) are summarized. The Raman and infrared spectra of TG have been investigated earlier experimentally [22] but a normal coordinate analysis has not been performed for the in-plane vibrational modes. Except for the CNH2 and CS stretching modes, the assignments proposed by Singh et al. [22] do not agree with ours based on the potential energy distribution. As the complexity of the spectra of nucleic acid bases makes the vibrational assignments rather difficult, assistance was also taken from the vibrational assignment made for 2-thiocytosine because in relation to hydrogen bonding the case of TG resembles that of 2-thiocytosine [23]. From the crystal structure of TG, Bugg and Thewalt have shown that the molecules form a tightly hydrogen bonded network with all eligible

Fig. 3. Comparison of the experimental spectrum of the isolated molecule (spectrum c) with the calculated spectra of the two amino-thiol tautomers (specta a and b) using a 3-21G basis set, and with the equally weighted sum of the latter (spectrum d).

1802

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

Fig. 4. Comparison of the experimental spectrum of the isolated molecule (spectrum c) with the calculated spectra of the two amino-thiol tautomers (spectrum a and b) taken together in the region of the SH stretching mode.

nitrogen and sulfur hydrogen bond donors and acceptors participating in the formation of hydrogen bonds [14]. The bases are hydrogen bonded around screw axes to form approximately planar ribbons running in the b direction. Within these ribbons each base is joined to the two adjacent bases by a total of six hydrogen bonds of N1H···N3, N2H···N9, N2H···S, N7H…S types [14]. Thus the assignments of the following modes of TG more sensitive to hydrogen bonding will be discussed: NH2, N1H, N7H, CNH2 and CS modes.

3.1. NH2 modes For the amino-thione N7H tautomer, the present calculation predicts antisymmetric and symmetric stretching modes of the NH2 group at 3512 and 3401 cm − 1, respectively. However, the presence of intermolecular hydrogen bonding is expected to

lower the magnitude of stretching modes of the NH2 group. In addition, the two NH bonds being not equivalent in the crystal structure of TG, the relation ws = 435.5+0.876was proposed for the NH2 group [24] is not satisfied by ws and was in the present case. Therefore, the first one, being bonded to a sulfur atom, is assigned to the absorption band observed at 3292 cm − 1 in the spectrum shown in Fig. 5, the second one, bonded to a nitrogen atom, is assigned to 3129 cm − 1 infrared frequency. The scissoring mode of the NH2 group gives rise to its characteristic frequency in the region 1600–1700 cm − 1 [23]. Therefore, the band observed at 1666 cm − 1 in the infrared spectrum and at 1663 cm − 1 in the Raman spectrum is assigned undoubtedly to the scissoring mode of the NH2 group. The rocking NH2 mode, usually appearing in the region 900–1150 cm − 1 for nucleic acid bases [25], has been assigned to infrared and

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

1803

Table 2 Wavenumbers (WN), Infrared integrated intensities, AIR, Raman integrated relative intensities, IRA, and potential energy distributions (PED) for amino-thione N7H tautomer Experiment-solid

Calculation b

(cm−1)

AIR (km/mol)

IRA

3512

62

16

2 3 4

3481 3429 3402

148 90 83

12 11 34

5 6

3051 1641

5 563

40 13

7 8

1595 1566

382 794

2 11

9

1532

40

11

10

1481

29

21

11

1427

164

17

12

1360

299

119

13

1347

7

22

14

1323

115

22

15

1252

137

34

16

1172

51

79

17

1163

78

17

18

1107

30

6

19

1086

35

9

Q

WN

1

d

PED

e

WNIR

AmH16 s(51−) AmH15 s(49+) N7H s(100−) N1H s(99−) AmH15 s(50+) AmH16 s(49+) C8H s(99−) C2N3 s(34−) HNH sci(19+) C2Am s(10+)

3292

HNH sci(55−) N1H be(34−) HNH sci(15+) C5C4 s(10+) N3C4 s(23+) C5C4 s(13−) C8N9 s(25+) C8H be(20−) N7H be(42−) N7C8 s(31+) C5C4 s(30+) C5C4 s(30+) N1C2 s(10−) N9C4 s(10−) C2Am s(22+) N1H be(19−) R6 def1(15−) C5N7 s(22+) N3C4 s(18−) C6C5 s(15−) C8N9 s(11+) C8N9 s(28−) C8H be(22−) N9C4 s(13+) C6C5 s(11−) N1C6 s(44−) C5N7 s(14+) C8H be(10−) N1C6 s(17+) N1H be(14−) R6 def1(13+) C8H be(10−) C6S s(10−) NH2 ro(45+) C2N3 s(17−) C2Am s(13−) N9C4 s(12+) N7C8 s(50+) N7H be(31+)

c

(cm−1)

a

AIR (km/mol)

WNRA

3241 3051 3129

700

1635

150

1666 1618

510 1100

1663 1619

1546

81

1546

1483

77

1478

1436

42

1439

3105

1367

1375

299

1372

1259

1260

1231

1228

1143

1135

1201

1202

1105

1032

1033

c

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

1804 Table 2 (Continued)

Experiment-solid

Calculation Q

WN

20

b

(cm−1)

AIR (km/mol)

IRA

999

54

7

21

942

80

12

22 23

934 909

3 121

1 1

24

804

30

4

25

771

45

1

26

722

44

1

27

659

75

2

28

642

3

1

29

618

16

1

30

574

23

5

31

639

75

18

32

527

215

6

33

504

28

10

34 35

491 417

116 6

4 8

36

360

1

2

37

310

26

15

38 39

289 198

92 5

8 1

40

196

8

26

d

PED

e

C8H be(13−) NH2 ro(21−) N1C2 s(21−) N9C4 s(15+) R5 def1(23+) N1C2 s(20+) C6S s(20−) C8H owa(104−) R5 def1(48−) C6S s(14−) R6 def1(24+) C5N7 s(16−) R5 def2(12+) N3C4 s(10−) R5 ode2(80−) C2Am owa(12−) C2Am owa(64+) R5 ode2(35−) N1H owa(84+) C6S owa(18−) R5 ode1(85−) C6S owa(15−) R5 def2(26−) C2Am be(14−) C6C5 s(12−) R5 ode3(44+) C6S owa(42−) R6 ode2(13−) R6 ode1(11+) NH16 owa(23+) N9C4 s(12−) R6 def2(12−) NH16 owa(57−) R6 def3(13−) R6 def3(41−) C2Am s(11+) N7H owa(87−) R6 def2(53+) C6S s(25−) R5 ode1(45+) R6 ode1(29+) R5 ode1(29+) C2Am owa(11+) R6 ode2(10+) C2Am be(42−) R5 def2(11+) NH15 owa(10−) NH15 owa(78−) R6 ode3(68−) R6 ode2(28−) R5 ode3(19−) C6S be(70−)

WNIR

c

(cm−1)

a

AIR (km/mol)

WNRA

972

972

942

921

925 841

921

838

838

777

776

719

715 657 648

621

572

575

563

824 525 570 418 409 369

362

570 234

215

c

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

1805

Table 2 (Continued) Calculation Q

WN

41

42

Experiment-solid b

(cm−1)

AIR (km/mol)

IRA

148

15

3

128

13

0

d

PED

e

WNIR

c

(cm−1)

R6 ode3(34+) R5 ode3(17−) R5 ode1(15+) R6 ode2(11−) C2Am owa(10−) R6 ode1(45−) R6 ode9(41+) R6 ode3(25−) C6S owa(18−)

a

AIR (km/mol)

WNRA

c

135

a Polycrystalline powder sample dispersed in KBr for infrared measurements or pressed into a rotating cell for Raman measurements. b Wavenumbers scaled by a constant factor of 0.91. c Only the strongest band is given when multicomponent bands are observed. d Integrated relative intensities in unit chosen in such way that the observed intensity sum of the in-plane modes observed in the separated spectra of amino-thiol N9H or amino-thiol N7H tautomer is equal to the calculated intensity sum of these modes. e Abbreviations: s, stretching; be, bending; sci, scissoring; owa, out-of-plane wagging; ro, rocking; def, deformation; ode, out-of-plane deformation; tor, torsion.

Raman bands observed at 972 cm − 1. The wagging and torsion (NH2) modes are respectively associated with infrared bands at 777 and 621 cm − 1. In fact the torsion and wagging (NH2) modes arise due to out-of-plane and in-plane coupling of the two NH out-of-plane bending motions of the NH2 group. In addition, the presence of intermolecular hydrogen bonding is expected to raise the magnitude of the torsion (NH2) mode.

3.2. N1H modes The HF/6-31G assignments attribute N7H and N1H stretching modes to 3481 and 3428 cm − 1, respectively. Despite the presence of intermolecular hydrogen bonding lowering the magnitude of N7H and N1H stretching modes, there is no confusion possible in the assignment of N1H and N7H stretching modes in experimental spectra. X-ray crystal structure [14] shows the presence of intermolecular NH···N and NH···S hydrogen bonds for N7H and N1H groups of 2.97 and 3.33 A, length,

respectively. Considering the Pimentel relation between OH or NH band shifts and hydrogen bond length, the N1H bond being bonded to the nitrogen atom in the crystal structure is expected to be observed in lower frequency than the N7H bond, which is bonded to the sulfur atom. Thus the shoulder observed around 3051 cm − 1, near the superimposed band situated at 3129 cm − 1, in the infrared spectrum (Fig. 5) is attributed to N1H stretching mode. The N1H in-plane bending mode is assigned to the infrared band at 1618 cm − 1 and Raman band at 1619 cm − 1. The band observed at 719 cm − 1 in the infrared spectrum and 715 cm − 1 in the Raman spectrum could be attributed to the N1H out-of-plane bending mode.

3.3. N7H modes The very weak absorption situated around 3241 cm − 1, between the bands 3292 and 3129 cm − 1, in the spectrum of Fig. 5 has been assigned to the N7H

Fig. 5. Comparison of the experimental infrared and Raman spectra of solid TG with the calculated spectra of the amino-thione N7H tautomer using 3-21G basis set, in the region of NH2, N7H, N1H and CH stretching modes (3600 – 2800 cm − 1).

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O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

Fig. 5.

O.E. Kasende / Spectrochimica Acta Part A 58 (2002) 1793–1808

stretching mode. The N7H in-plane bending mode has been attributed to the infrared band at 1436 cm − 1 and Raman band at 1439 cm − 1. The absorption band at 570 cm − 1 has been associated with the N7H out-of-plane bending mode. It is worth noting that NH2, N1H and N7H stretching modes are not observed in the Raman spectrum (Fig. 5). The unique band observed at 3105 cm − 1 in this region in this region of the Raman spectrum is ascribed to the CH stretching mode.

3.4. CNH2 modes According to the crystal structure of TG the CNH2 bond (1.313 A, ) is shorter than the corresponding bond in 2-thiocytosine (1.333 A, ) [26]. The CNH2 stretching mode is, therefore, expected to appear at higher frequency than in 2-thiocytosine. For TG, we assigned to this mode the infrared frequency 1375 cm − 1 corresponding to Raman frequency 1372 cm − 1, in agreement with the assignment proposed by Singh and Yadav [22]. The calculated CNH2 stretching mode has the frequency 1347 cm − 1. In the 2-thiocytosine infrared spectrum this mode has been assigned to the frequency 1369 cm − 1. The CNH2 in-plane bending and out-ofplane bending modes are tentatively assigned in the Raman spectrum to the bands at 362 and 135 cm − 1, respectively.

3.5. CS stretching mode The CS stretching mode is among the most interesting modes as this is involved in the intermolecular hydrogen bonding which plays a very important role in the biological activities of this molecule [1]. In TG crystal structure [14], the sulfur atom accepts hydrogen bonds from N7H and NH2 of two different molecules; the lengths of these hydrogen bonds are 3.30 and 3.33 A, , respectively. By comparison to the case of 2thiocytosine in which the CS stretching mode has been assigned to the infrared band at 1200 cm − 1, in the TG infrared spectrum, this mode is assigned to the band at 1201 cm − 1 corresponding to the Raman band at 1202 cm − 1 in spite the low frequency 1163 cm − 1 predicted by our

1807

calculation. This assignment agrees with the previous assignment [22].

Acknowledgements The author is grateful to Ambassade 6an het Koninkrijk der Nederlanden (Kinshasa, Congo) for its financial support. I also wish to acknowledge Professor W.B. Person and Dr K. Szczepaniak-Person (University of Florida, USA) for experimental assistance and helpful discussions. Finally, I appreciate the hospitality and support provided by Professor D. de Waal at the University of Pretoria, Republic of South Africa, where the final version of this paper was completed.

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