Abstract
The new complexes , (3), , (6), (7), (8), (9) and (10) are reported, where LH is 4,6-diamino-1-hydro-5-hydroxy-pyrimidine-2-thione. The complexes were characterized by elemental analyses, physical techniques (molar conductivity, room-temperature magnetic susceptibility), and spectroscopic (IR, Raman, UV/VIS/ligand field, NMR, mass) methods. The ligand is in its thione form and behaves as a bidentate chelate with the deprotonated (hydroxyl) oxygen and the nitrogen of one amino group as donor atoms. Oxobridged dinuclear (1, 2) and various mononuclear (3–10) structures are assigned for the complexes in the solid state. The metal ion coordination geometries are octahedral (1–6, 9, 10) or square planar (7, 8). The free ligand LH and complexes 1, 4, 7, and 8 were assayed in vitro for antimicrobial activity against two bacterial and two fungal cultures.
1. Introduction
2-Mercaptopyrimidine nucleotides have been detected in Escherichia Coli sRNA and yeast tRNA; it has been found that they inhibit the synthesis of tRNA, thus acting as antitumour and antithyroid agents [1]. A similar inhibitory effect has been observed for pyrimidine-2-thione (I in Scheme 1) and its derivatives, which also show pronounced in vitro bacteriostatic activity [1]. Metal complexes of pyrimidine-2-thione or its pyrimidine-2-thiol tautomeric form [1, 2] and its amino [2, 3] or hydroxy [4–6] derivatives have been prepared and studied (for representative ligands see Scheme 1). Such complexes exhibit rich structural chemistry, and interesting thermal, magnetic, sorptive, and biological properties. However, the coordination chemistry of ligands based on the 2-mercaptopyrimidine moiety and containing both hydroxy and amino substituents on the pyrimidine ring is completely unkown.
We now describe here the preparation and characterization of the first metal complexes of 4,6-diamino-5-hydroxy-2-mercaptopyrimidine (LH, Scheme 2). We also report the antimicrobial activity of the free ligand and four representative complexes against two bacteria and two fungi. This work can be considered as a continuation of our interest on the coordination chemistry of derivatized pyrimidines [7].
2. Experiments
All reagents were purchased from Merck and Alfa/Aesar. [IrC is commercially available. [PdC(phen) was prepared by the reaction of [PdC and 1,10-phenanthroline in O/EtOH. [ReOC was synthesized as previously reported [8]. DMSO used in conductivity measurements was dried over molecular sieves. The DMSO- protons (NMR) were referenced using TMS. Warning: perchlorate salts are potentially explosive; such compounds should be used in small quantities and treated with utmost care at all times. Elemental analyses (C, H, N, S) were performed by the University of Ioannina (Greece) Microanalytical Unit with an EA 1108 Carlo-Erba analyzer. The water content of the complexes was also confirmed by TG/DTG measurements performed on a Shimadzu Thermogravimetric Analyzer TGA-50. IR spectra were recorded on a Matson 5000 FT-IR spectrometer with samples prepared as KBr pellets. Far-IR spectra were recorded on a Bruker IFS 113 v FT spectrometer with samples prepared as polyethylene pellets. FT Raman data were collected on a Bruker IFS 66 v interferometer with an FRA 106 Raman module, a CW Nd: YAG laser source, and a liquid nitrogen-cooled Ge detector. Solution electronic spectra were recorded using a Unicam spectrophotometer. Solid-state (diffuse reflectance, DRS) electronic spectra in the 300–800 nm range were recorded on a Varian Cary 3 spectrometer equipped with an integration sphere. NMR studies were performed on a Varian Gemini WM-200 spectrometer. NMR spectra were recorded with a Varian Mercury equipment [ref. (ext.)]. Mass spectra were recorded on a Matson 5988 MS spectrometer. Conductivity measurements were carried out at room temperature on a YSI, model 32 conductivity bridge using solutions. Room temperature magnetic susceptibility measurements were performed using a Johnson Matthey magnetic balance standardized with HgCo diamagnetic corrections were estimated using Pascal’s constants.
2.1. Preparation of the Complexes
An aqueous
solution (5 ) of [Mo
(0.24 g, 1.0 mmol) was added to a solution of LH (0.16 g, 1.0 mmol) in EtOH (25 ). The obtained slurry was heated and the resulting orange solution
was refluxed for 4 hours, during which time an orange precipitate is formed. The solid was collected by
filtration, washed with ethanol (2 ) and diethyl ether (2 5 )
and dried in vacuo. The yield
was 35% (based on the metal). Elemental
analytical calculation for
Mo: C,
15.00; H, 2.50; N, 17.50; S, 10.00% found that C, 14.98; H, 2.82; N, 17.51; S, 9.87%; (DMSO): 3 S .
Using [
and following exactly the same procedure as that described for complex 1, a bright yellow material was
isolated. The yield was 50% (based on the metal). Elemental analytical calculation for W:
C, 11.77; H, 1.96; N, 13.73; S, 7.85% found that C, 11.62; H, 1.90; N, 13.77; S, 7.95%; (DMSO): 2 S .
Solid
(0.12 g, 0.46 mmol) was added to a solution of NaCMe (0.62 g, 7.5 mmol) in water (30 ). Solid LH (0.24 g, 1.5 mmol) was then added
and the resultant reaction mixture was refluxed for 12 hours. The deep brown
solid formed was collected by filtration while the reaction mixture was hot,
washed with hot water, and dried in vacuo. The yield was 30% (based on the
metal). Elemental analytical calculation for Ru:
C, 20.46; H, 3.41;N, 23.88; S,13.64% found that C, 20.32; H,
3.05; N, 23.57; S, 13.21%; (DMSO):
1 S .
Using
and following the same procedure as that described for complex 3, a reddish brown material was
isolated. The yield was 60% (based on the metal). Elemental analytical calculation for Rh:
C, 23.61; H, 3.12; N, 27.55; S, 15.74% found that C, 23.73; H, 3.11; N, 26.36; S, 14.98%;
(DMSO): 6 S .
Using [IrC and
following the same procedure as that described for complex 3, a yellow solid was isolated. The yield was 25% (based on the
metal). Elemental analytical calculation for Ir:
C, 21.14; H, 2.50; N, 24.66; S, 14.09% found that C, 21.33; H, 2.64; N, 24.75; S, 13.85%; (DMSO): 5 S .
A hot ethanolic
solution (20 ) of LH (0.25 g, 1.6 mmol) was added to a solution
of
(0.21 g, 0.8 mmol) in 6 M HCl (15 ). The resultant
orange solution was refluxed for 4 hours and to this was added a solution of
PP (0.43 g, 1.6 mmol) in hot ethanol (15 ). The new
solution was refluxed for a further 3 hours and filtered, and its volume decreased in vacuo to give a red-brown solid.
The solid was collected by filtration, washed with hot water (2 x 2 mL) and hot
ethanol (2 x 3 ), and dried in vacuo. The yield was 25% (based on the metal). Elemental analytical calculation for Rh:
C, 49.05; H, 4.09; N, 10.41; S, 3.30% found that C, 48.79; H, 4.09; N, 10.44;
S, 3.46%; (DMSO): 48 S .
To a stirred
slurry of LH (0.16 g, 1.0 mmol) in methanol (15 ) was added an
aqueous solution (15 ) of [PdC (0.16 g, 0.5 mmol). The resulting suspension was stirred at for 60 hours
and the brown solid formed was collected by filtration, washed with water (5
3 ) and cold methanol (2 5 ), and dried in air. The
yield (based on the metal) was 50%. Elemental analytical
calculation for Pd:
C,21.03; H, 3.07; N, 24.54; S, 14.02% found that C, 21.23; H, 3.22; N, 24.85;
S, 14.21%; (DMSO): 9 S .
To a stirred
yellow slurry of [PdC(phen) (0.18 g, 0.5 mmol) in a methanol/benzene
solvent mixture (15 , 3:2 v/v) was added a solution of KOH (0.055 g, 1.0 mmol) in methanol (15 ). Solid LH (0.08 g, 0.5 mmol) was
added to the reaction mixture which soon dissolved. The solution was filtered
and stirred for 48 hours at room temperature. During this time, a brown
precipitate formed which was collected by filtration, washed with water (1 )
and methanol (), and dried in air. The yield was 40% (based
on the ligand). Elemental analytical calculation for Pd:
C, 21.03; H, 3.07; N, 24.54; S, 14.02% found that C, 21.23; H, 3.22; N, 24.85;
S, 14.21%; (DMSO): 77 S .
To a stirred slurry of [ReOC
(0.25 g, 0.2 mmol) in ethanol (30 ) was added solid LH (0.057 g,
0.4 mmol). The solid soon dissolved and stirred at for 5 hours.
The brown solution deposited a brown microcrystalline solid which was collected
by filtration, washed with ethanol (), and dried in vacuo. The yield was 65% (based on
the metal). Elemental analytical calculation for Re:
C, 38.34; H, 3.07; N, 13.76; S, 7.86% found that C, 38.37; H, 3.11; N, 13.87;
S, 7.98%; (DMSO):
46 S .
Solid LH (0.08 g, 0.5 mmol) was added to a
stirred solution of
(0.25 g, 0.5 mmol) in methanol (10 ). The solid soon dissolved.
The resultant yellow solution was filtered and refluxed for 4 hours, during
which time a red microcrystalline solid was precipitated. The product was
collected by filtration, washed with methanol (5 ) and diethyl
ether (2 5 ), and dried in
vacuo. The yield was 55% (based on the metal). Elemental analytical calculation for U:
C,16.44; H, 1.71; N, 19.18; S, 10.96% found that C, 16.35; H, 2.02; N, 18.98;
S, 10.86%; (DMSO): 11 S .
2.2. Antimicrobial Activity
The bacterial strains (S. aureus and P. aeruginosa) were grown in Nutrient agar slants and the fungal strains (A. niger and C. albicans) were grown in Sabouraud dextrose agar slants. The viable bacterial cells were swabbed onto Nutrient agar plates, while the fungal spores onto Sabouraud dextrose agar plates. The free ligand and complexes 1, 4, 7 were dissolved in DMSO, while complex 8 was dissolved in with 10, 20, 50, and 100 mg/mL concentrations. The blank was DMSO in saline buffer. The bacterial and fungal plates were incubated for 36 and 72 hours, respectively, and the activity of the compounds was estimated by measuring the diameter of the inhibition zone (the affected zone by the compounds) around the respective zone (the normal place in the agar). The incubation temperature was .
3. Results and Discussion
3.1. Synthetic Comments and Physical Characterization
The preparative reactions for selected complexes can be represented by the stoichiometric equations (1)–(7); no attempts were made to optimize the yields,
The metal is reduced during the preparation of complexes 3 and 5 although the reactions are performed in air. The redox reaction may be facilitated by the reducing character of LH, the products from the oxidation of the ligand remaining in the solution. Thus, LH possibly plays two roles in the reactions, that is, the role of the ligand and that of the reducing agent. It is well known that Ru(III) can undergo reduction reactions and that the ion is a convenient one-electron oxidant [9]. The use of a base (KOH) in the preparation of 8 is necessary to obtain the complex in pure form; otherwise, the produced aqueous HCl decomposes the compound.
Complexes 1–5, 7 and 10 are nonelectrolytes in DMSO [10]. Complexes 7 and 10 exhibit slightly increased molar conductivity values in DMSO. Since DMSO is a good donor solvent, this may be due to the partial displacement of one ligand by two DMSO molecules. Assuming an equilibrium between the neutral and the resulting cationic complex, this displacement changes the electrolyte type of the compound explaining the increased value [10]. From the molar conductivities in DMSO (complexes 6 and 9) and DMF (complex 8), it is concluded that compounds 6, 8, and 9 behave as electrolytes, supporting their ionic formulation [10]. All the complexes are diamagnetic, as expected [9]. It should be mentioned at this point that the bonding in the unit of 9 causes sufficient splitting of the (in ) set that diamagnetism occurs through the configuration .
Complexes 1–10 are microcrystalline or powder-like, stable in the normal laboratory atmosphere, and soluble only in DMF and DMSO. We had hoped to structurally characterized one or two complexes by single-crystal X-ray crystallography (working mainly with DMF or DMF/MeCN), but were thwarted on numerous occasions by twinning problems or lack of single crystals. Thus, the characterization of the complexes is based on spectroscopic methods.
3.2. Electronic Spectra
The band at 335 nm in the DRS spectrum of 1 is assigned to an p–d LMCT transition and is characteristic of the moiety [11] in octahedral complexes. The transition appears at 337 nm as a shoulder in solution (DMSO). The DRS spectrum of 3 is indicative of its low-spin octahedral structure. The ground term is and the two spin-allowed transitions to and are observed at 565 and 420 nm, respectively [12]; the corresponding bands in DMSO are at 560 and 430 nm. The DRS spectra of the Rh(III) complexes 4 and 6 both exhibit bands at ~470 and ~380 nm; the spectra resemble those of other six-coordinate Rh(III) compounds and the bands are assigned as transitions from the ground state to the and upper states in octahedral symmetry in decreasing order of wavelength [12]. The lower wavelength band may also have a charge-transfer character. Both complexes exhibit an additional band in the blue region of the spectrum (~520 nm) which is responsible for their red-brown colors; a possible origin of this band is the singlet-triplet, spin-forbidden transition [12]. The spectrum of the Ir(III) complex 5 shows two bands at 380 and 335 nm, which have a similar interpretation; the transition is not observed. A weak shoulder in the spectrum of 9 is assigned to the transition in a octahedral environment, while an intense band at 375 nm most probably has an LMCT origin [12]. The ligand-field spectra of 7 and 8 are typical of a square planar environment around with a mixed N,O-ligation; the bands at 480, 375, and 330 nm are assigned [12] to the and transitions, respectively, under symmetry. The spectra in DMSO exhibit only two bands at 480 and 330 nm.
3.3. NMR Studies
Diagnostic NMR assignments (in DMSO-) for representative complexes are presented in Table 1. The study was based on comparison with the data obtained for diamagnetic complexes with similar ligands [7, 13, 14]. In all the spectra studied, the integration ratio of the signals is consistent with the assignments.
The spectrum of LH exhibits two singlets at 6.07 and 6.18 assigned to the –N(4)/–N(6) (for the numbering scheme see Scheme 2) amino hydrogens, respectively, and two relatively broad singlets at 7.43 and 9.13 due to the amide and hydroxyl protons –N(1)H– and –O(5)H, respectively. The appearance of these four peaks is consistent with the exclusive presence of the thione form of LH (Scheme 2) in solution. The proton of the hydroxyl group is not observed in the spectra of the complexes confirming its deprotonation and coordination to the metal ions. In the spectra of 1, 3, 4, and 6–8, the –N(1)H– signal undergoes a marginal shift to indicate the noninvolvement of this group in coordination; a relatively large downfield shift would be expected if coordination had occurred. In the same spectra, two signals appear for –N protons, as expected. The most pronounced variation in chemical shift is the downfield shift of one signal. Since more specific assignments of these two signals seem impossible, it is difficult to conclude which amino nitrogen is coordinated. NMR evidence for the presence of thione –thiol tautomerism in the metal complexes in solution was not found.
The NMR spectrum of 4 confirms that the three N,O-bidentate (vide infra) ligands are equivalent ( symmetry), and, therefore, the complex has the fac stereochemistry [15].
The spectrum of 8 is indicative of the presence of one solution species containing coordinated phen, consisting of four resonances [16]. Assignments are as follows (the numbers in parentheses are the positions of the protons in the classical numbering scheme of 1,10-phenanthroline; inglet, doublet of doublets): 9.15 dd(2H; 2,9), 8.53 dd(2H; 4,7), 8.00s(2H; 5,6), and 7.81q(2H; 3,8). Considerable downfield coordination shifts, , are observed for all resonances, their values being 0.16, 0.27, 0.31, and 0.19 for the protons of the positions (2,9), (4,7), (5,6), and (3,8), respectively. These shifts are characteristic of coordinated phen [16].
The NMR spectrum of the Re(V) complex 9 in DMSO- consists of a sharp singlet at , a value which is typical for PP-containing oxorhenium(V) species [17].
3.4. Vibrational Spectra
Tentative assignments of selected IR ligand bands for complexes 1–10 and free LH are listed in Table 2. The assignments have been given by studying literature reports [3, 13, 14], comparing the spectrum of LH with the spectra of the complexes and by performing deuterium isotopic substitution experiments in few cases. As a general remark, we must emphasize that some stretching and deformation modes are coupled, so that the proposed assignments should be regarded as approximate descriptions of the vibrations.
In the region, the spectra of complexes 1–3 show one medium-intensity band at ~3420 attributed to the presence of coordinated water [13]. The same spectra exhibit, in addition to the relatively sharp band of coordinated water, a weaker broad continuous absorption covering the 3400–3200 region; this is apparently due to the simultaneous presence of crystal and coordinated water in these complexes [14]. In the spectra of 4–8, a medium broad absorption indicates the presence of exclusively crystal (lattice) water.
The absence of an IR or Raman band at ~2600 in the spectrum of free LH suggests that the ligand exists in its thione form (see Scheme 2) [18]. This is corroborated by the appearance of the medium () band at 1177 (this vibration appears as a strong peak at 1160 in the Raman spectrum) and the strong IR (N–H) band at 2970 (this vibration appears as a medium peak at ~3000 in the Raman spectrum); the broadness and low frequency of the latter IR band are both indicative of the involvement of the –NH– group in strong hydrogen bonding.
The medium IR band at 3305 in the spectrum of free LH is assigned to the (OH) vibration. This band does not appear in the spectra of the complexes indicating deprotonation of the –OH group and suggesting coordination of the resulting, negatively charged oxygen atom. The absence of large systematic shifts of the (N–H), (NH), (), ()/(), and () bands in the spectra of the complexes implies that there is no interaction between the ring nitrogen atoms or the exocyclic sulfur atom and the metal ions. The and bands are doubled in the spectra of the complexes. One band for each mode appears at almost the same wavenumber compared with the corresponding band in the spectrum of free LH, whereas the other band of each pair is significantly shifted to lower wavenumbers. This fact is a strong evidence for the presence of one coordinated and one “free” (i.e., uncoordinated) amino group per in the complexes [7].
The presence of coordinated PP groups in 6 and 9 is manifested by the strong IR bands at ~1100 and ~750 , attributed to the (P–C) and (CCH) vibrations, respectively [17]; the former band overlaps with the stetching vibration in the spectrum of the Rh(III) complex 6. In the spectrum of 8, the bands at 1627, 1591, 1510, 1485, and 1423 are due to the phen stretching vibrations [16]; these bands are at higher wavenumbers compared with the free phen indicating chelation. The bands at 854, 841, 743, and 725 are assigned to the (CH) vibrations of the coordinated phen [16].
The vibrational spectra of the inorganic “parts” of complexes 1, 2, 6, 9, and 10 are also diagnostic. The IR spectrum of 6 exhibits a strong band at ~1100 and a medium band at 624 due to the and modes of the uncoordinated ion [19], respectively, the former having also (P–C) character [17]. In the 1000–750 region, the spectra of 1 and 2 show bands characteristic of the cis- units and the M–O–M core (o, W) [20, 21]. The IR bands at 930 and 912 in 1 are assigned to the and modes, respectively [19, 20]; the corresponding Raman bands appear at 910 and 896 . As expected [19], the symmetric mode is weak in the IR spectrum and strong in the Raman spectrum, while the opposite applies for the asymmetric mode. The appearance of two stretching bands is indicative of the cis configuration [19]. The strong IR band at 745 is assigned to the o–O–Mo) mode [20], indicating the presence of a - group. The , , and –O–W) bands appear at 945, 922, and 755 , respectively, in the IR spectrum of complex 2 [19, 21]; the and Raman bands are at 940 and 917 , respectively. The and modes are at higher wavenumbers when compared to those of the analogous Mo(VI) complex 1, suggesting [21] that the cis- group has some “triple” bond character [21]. In the spectra of 9, the band attributed to ν (R) appears at 956 (IR) and 968 (Raman) [17, 19]. The IR spectrum of the uranyl complex 10 exhibits only one stretching band, that is, , at 940 (not observed in the Raman spectrum) indicating its linear transdioxo configuration [19]. The mode appears as a strong Raman peak at 905 , and, as expected, the corresponding IR band is very weak. The bands at 345 and 298 in the far-IR spectrum of 7 are assigned to the (Pd–) and (Pd-O) vibrations, respectively. The appearance of one band for each mode ( and under ) is consistent with a trans structure [19].
3.5. Antimicrobial Activity Studies
The free ligand LH and its complexes 1, 4, 7, and 8 were assayed in vitro for antimicrobial activity against two bacterial (S. aureus and P. aeruginosa) and two fungal (A. niger and C. albicans) cultures. The hot plate diffusion method was adopted for the activity measurements [22]. Results are listed in Tables 3 and 4.
In general, the Pd(II) complexes 7 and 8 were found to have higher efficacy than 1, 4, and LH at the measured concentrations. The water-soluble complex 8 is the most active against the pathogens studied. It is remarkable that the antifungal activity of 8 is comparable with, or even better than, the activity of the antifungal drug nystatin, and this may be due to the simultaneous presence of phen and in the complex. The activity of the Pd(II) complexes 7 and 8 is tentatively attributed to their inhibition of the DNA replication (by interacting with enzyme prosthetic groups and altering the microbial metabolism) and their ability to form hydrogen bonds with the cell wall and cell constituents [23]. The weaker activity of 4 is noteworthy; the reason for this is not clear.
4. Conclusions
The M/LH general reaction system fulfilled its promise as a source of interesting complexes. From the overall evidence presented before, it seems that the ligand behaves as a bidentate chelate in all the prepared complexes with the deprotonated oxygen and most probably the amino nitrogen of the position 6 of the pyrimidine ring being the donor atoms, see Scheme 3. However, the participation of the amino nitrogen of the position 4 of the ring cannot be ruled out. The nonparticipation of the sulfur atom in coordination in complexes 7 and 8 may be seen as unusual given the soft character of Pd(II) in the context of the HSAB concept.
The chelate effect (a stable chelating ring with the participation of the sulfur atom cannot be formed due to the geometry of ) seems to govern the thermodynamic stability of these complexes. The proposed gross schematic structures for 1–10 are shown in Figure 1. Due to the fact that single-crystal, X-ray crystallographic studies are not available, few structural features (e.g., the symmetric structures of 1–3, 6, 7, and 10) are tentative. The metal ions adopt octahedral (1–6, 9, 10) or square planar (7, 8) stereochemistries.
Finally, complexes 1, 4, 7, and 8 are new welcome additions in the growing family of metal complexes with antimicrobial activity.
The results described in this report represent the initial study of the coordination chemistry of LH and the biological activity of its complexes. Further studies with 3d-metal ions are in progress.
Acknowledgments
The authors thank Dr. Constantinos Milios (University of Edinburgh, UK) and Professor H. O. Desseyn (University of Antwerp, Belgium) for providing them with the NMR spectrum of 9 and far-IR/Raman spectra of some complexes.