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Research Article - (2014) Volume 0, Issue 0

Thermal Properties, Antimicrobial Activity of Azo Complexes and Ultrastructure Study of Some Affected Bacteria

Abou-Dobara MI1, El-Sonbati AZ2*, Diab MA2, El-Bindary AA2 and Sh M Morgan2
1Botany Department, Faculty of Science, Damietta University, Damietta, Egypt
2Chemistry Department, Faculty of Science, Damietta University, Damietta, Egypt
*Corresponding Author: El-Sonbati AZ, Chemistry Department, Faculty of Science, Damietta University, Damietta, Egypt, Tel: +201060081581, Fax: +20 572403868 Email:

Abstract

A series of copper (II) complexes of bidentate azo rhodanine ligands (HLn) have been synthesized and characterized. The IR spectral and thermogravimetric analysis are used to characterize the isolated complexes. X-ray diffraction patterns show polycrystalline nature for as-synthesized ligand HL2 and its complex. Quantum chemical parameters, absolute hardness, global electrophilicity and additional electronic charge were calculated for HLn. Copper(II) complexes (1-4) are tested against four local bacterial species; namely two Gram positive bacteria (Staphylococcus aureus and Bacillus cereus) and two Gram negative bacteria (Escherichia coli and Klebsiella pneumoniae) and against four local fungal species (Aspergillus niger, Fusarium oxysporium, Penicillium italicum and Alternaria alternata). The tested complexes have good antibacterial activity against Staphylococcus aureus and Escherichia coli and have low antifungal activity against Aspergillus niger, Fusarium oxysporium and Alternaria alternata. We found that the complex (3) is more active than other complexes against Staphylococcus aureus and Escherichia coli as expected from Hammett’s substituent coefficients (σR). Ultrastructure studies of the affected Staphylococcus aureus and Escherichia coli confirmed that complex (3) has bactericidal effect.

Keywords: Azodye rhodanine derivatives, Antimicrobial activity of Cu(II) complexes, Transmission electronic micrograph, Thermodynamic parameters, Hammett?s substituent coefficients (σ,R)

Introduction

Azodyes play also an important role in inorganic chemistry, as they easily form stable complexes with most transition metal ions [1-5]. The behavior of azodye complexes have attracted the attention of the bioinorganic chemists, since a number of these complexes are recognized to serve as models for biologically important species [3-7].

Azo compound based on rhodanine, play a central role as chelating agents for a large numbers of metal ions, as they form a stable sixmember ring after complexation with a metal ion and also it could be used as analytical reagents [8,9]. The complex-formation equilibria have been reported for several kinds of rhodanine derivatives [10-13]. Potentiometry, conductivity and spectroscopy measurements on the coordination ability biologically important azo derivatives have shown that their complexes are very stable.

Chemical properties of rhodanine and its derivatives are of interest due to coordination capacity also widely prepared and studied several metal complexes of rhodanine azodyes due to their unusual magnetic properties and relevance to biological system [1,2,14,15]. Rhodanine and its derivatives are known to possess biological activities such as anticancer, antimiotic, antidiabetic, antibacterial, hypocholesterolemic, antiperlipemic, antiviral and antidiabetic in nature and also reported rhodanine derivatives as Hepatitis C Virus (HCV) protease inhibitor [16-19]. The antimicrobial activity results of rhodanine azo compounds have been compared with the standard antibacterial and antifungal drugs and the results showed that most of these ligands are good antibacterial agents against Bacillus cereus and Staphylococcus aureus and antifungal agents against Aspergillus niger and Fusarium oxysporium [14].

The aim of the present work is the synthesis of Cu(II) complexes of bidentate azo rhodanine ligands (HLn). The IR spectral and thermogravimetric analysis are used to characterize the purpose of structural elucidation. The activation thermodynamic parameters were calculated using Coats–Redfern and Horowitz-Metzger methods. Study of the antimicrobial activity of Cu(II) complexes as well as the ultrastructural effect of complex (3) on Staphylococcus aureus and Escherichia coli were recorded.

Experimental

The structures of the ligands can exist in three tautomeric forms as shown in Figure 1.

microbial-biochemical-technology-rhodanine

Figure 1: Geometry optimized structures of the investigated ligands (HLn).

Preparation of complexes

A hot ethanolic solution containing the azodyes (HLn) was mixed with a hot ethanolic solution of Cu(OAc)2.H2O (1 mmol) [4]. The mixture was then refluxed on a water bath for ~10 h and allowed to cool whereby the solid complexes were separated, which filtered off, washed several times with ethanol, dried and kept in a desiccator over dried CaCl2.

Measurements

Elemental microanalyses of the separated complexes were determined on Automatic Analyzer CHNS Vario ELIII, Germany. X-ray diffraction analyses of the powder HL2 and its complex [Cu(L2)(OAc) (OH2)].2H2O (4) were performed at room temperature by a Philips X-ray diffractometer equipped with utilized monochromatic Cu Kα radiation (λ=1.5418 Å). The X-ray tube voltage and current were 40 kV and 30 mA, respectively. The 1H NMR spectrum was obtained with a JEOL FX90 Fourier transform spectrometer with DMSO-d6 as the solvent and TMS as an internal reference. The infrared spectra were recorded as KBr discs using a Perkin-Elmer 1340 spectrophotometer. The magnetic moment of the prepared solid complexes was determined at room temperature using the Gouy’s method. Mercury(II) (tetrathiocyanato) cobalt(II), [Hg{Co(SCN)4}], was used for the calibration of the Gouy’s tubes. Diamagnetic corrections were calculated from the values given by Selwood [20] and Pascal’s constants. Magnetic moments were calculated using the equation, μeff=2.84 [TχM coor]1/2. Thermogravimetric Analysis (TGA) measurements were investigated using Simultaneous Thermal Analyzer (STA) 6000 with scan rate 15°C/min under dynamic nitrogen atmosphere in the temperature range from 50 to 800°C.

The molecular structures of the investigated compounds were optimized initially with PM3 semiempirical method so as to speed up the calculations. The resulting optimized structures were fully reoptimized using ab initio Hartree–Fock (HF) [21] with 6-31G basis set. The molecules were built with the Gauss View 3.09 and optimized using Gaussian 03W program [22]. The corresponding geometries were optimized without any geometry constraints for full geometry optimizations. Frequency calculation was executed successfully, and no imaginary frequency was found, indicating minimal energy structures.

Microbiological investigation

For this investigation the agar well diffusion method was applied [14]. The antibacterial activities of the investigated complexes were tested against two local Gram positive bacterial species (Bacillus cereus and Staphylococcus aureus) and two local Gram negative bacterial species (Escherichia coli and Klebsiella pneumoniae) on nutrient agar medium. Also, the antifungal activities were tested against four local fungal species (Aspergillus niger, Alternaria alternata, Penicillium italicum and Fusarium oxysporium) on DOX agar medium. The concentrations of each solution were 50 μg/ml, 100 μlg/ml and 150 μg/ ml. By using a sterile cork borer (10 mm diameter), wells were made in agar medium plates previously seeded with the test microorganism. 200 μl of each compound was applied in each well. The agar plates were kept at 4°C for at least 30 min. to allow the diffusion of the compound to agar medium. The plates were then incubated at 37°C or 30°C for bacteria and fungi, respectively. The diameters of inhibition zone were determined after 24 h and 7 days for bacteria and fungi, respectively. Penicillin and miconazole were used as reference substances against bacteria and fungi, respectively.

For electron microscopic study, 18 hour of Staphylococcus aureus and Escherichia coli were subjected to 150 μg/ml of complex (3) for 2 hours. Also, normal bacteria and DMF treated bacteria were included. After that, bacterial cells were centrifuged and washed with distilled water. Bacteria were fixed with formalin-glutaraldehyde fixative (4F1G) in 0.1 M phosphate buffer pH 7.4. After rinsing in the buffer, samples were post-fixed in 2% OsO4 for 2 h at 4°C in the same buffer. The cells were washed and dehydrated at 4°C through a graded series of ethanol. Cells were then treated with propylene oxide solution and embedded in a mixture of 1:1 of Epon-Araldite for 1 h. Polymerization was done in the oven at 65°C for 24 h. Ultrathin sections (50 μm) were cut on ultratome (Model LKB), then mounted on copper grids, double stained with uranyl acetate and lead citrate and investigated on a JEOL 100CX TEM.

Morphometric analyses

Morphometric analyses were achieved by using UTHSCSA Image tool software for windows version 3.

Statistical analysis

All the data of morphometric analysis was expressed as Mean ± SE. The statistical significance was evaluated by ANOVA using SPSS Version 10 and the individual comparison were obtained by LSD method at 0.05 significant levels.

Results and Discussion

Structure of the ligand

The geometrical structures of the investigated ligands (HLn) with the optimized bond lengths are shown in Figure 2. The optimized molecular structures, the highest occupied molecular orbital (HOMO) and the lowest unoccupied molecular orbital (LUMO) of the investigated ligands (HLn) are shown in Figure 3.

microbial-biochemical-technology-investigated

Figure 2: Geometry optimized structures of the investigated ligands (HLn).

microbial-biochemical-technology-molecular

Figure 3: HOMO and LUMO molecular orbital of ligands (HLn).

Quantum chemical parameters of ligands are obtained from calculations such as energy of the highest occupied molecular orbital, EHOMO, energy of the lowest unoccupied molecular orbital, ELUMO, energy gap, ΔE, and dipole moment, μ, as presented in Table 1. Additional parameters such as separation energies, ΔE, absolute electronegativities, χ, chemical potentials, Pi, absolute hardness, η, absolute softness, σ, global electrophilicity, ω, global softness, S, and additional electronic charge, ΔNmax, have been calculated according to the following equations [4,23]:

Compound EHOMO (a.u) ELUMO (a.u) E (a.u) µ  (D) T.E
(a.u)
χ
  (a.u)
η 
(a.u)
σ  (a.u)-1 Pi 
(a.u)

(a.u)-1
ω   (a.u) ΔNmax
HL1 -0.327 0.048 0.375 5.358 -1491.580 0.139 0.188 5.333 -0.139 2.667 0.052 0.744
HL2 -0.337 0.047 0.384 4.554 -1416.775 0.145 0.192 5.208 -0.145 2.604 0.055 0.755
HL3 -0.348 0.044 0.432 3.950 -1377.752 0.152 0.196 5.102 -0.152 2.551 0.059 0.776
HL4 -0.355 0.034 0.389 2.001 -1836.627 0.161 0.195 5.141 -0.161 2.571 0.066 0.825
HL5 -0.367 -0.004 0.363 3.712 -1581.099 0.186 0.182 5.509 -0.186 2.755 0.095 1.022

Table 1: The calculated quantum chemical parameters of the investigated ligands (HLn<).

image                                                                                              (1)    

image                                                                                         (2)    

image                                                                                        (3)

image,image                                                                                (4)

image,image                                                                            (5)

image                                                                       (6)

The lower value of energy gap (ΔE), indicates the more stable ligand and highly reactive than the other ligands [24]. The concepts of the parameters χ and Pi are related to each other. The inverse of the global hardness is designated as the softness [4]. From the obtained data (Table 1) we can deduced that:

Absolute hardness (η) and softness (σ) are important properties to measure the molecular stability and reactivity. The values of ΔNmax for HLn are calculated and found to be in the range 0.744-1.022 dependent on the nature of the substituent. They tend to the increase according to the following order p-(OCH332). This is in accordance with that expected from Hammett’s constant coefficients (σR) as shown in Figure 4.

microbial-biochemical-technology-substituent

Figure 4: The relation between Hammett’s substituent coefficients (σR) versus ΔNmax for ligands (HLn).HOMO and LUMO molecular orbital of ligands (HLn).

1H NMR spectra

The 1H NMR spectra of azodye rhodanine derivatives are in agreement with the proposed structures. Signal for CH (~4.42 ppm), favoring formation of an intramolecular hydrogen bond with the– N-N–(azodye) group. Electron-withdrawing substituents reduce the intramolecular hydrogen bond as indicated by the marked shift of the hydroxyl signal to higher field in the p-NO2 and p-Cl compounds. Electron-donating substituents give the opposite effect, arising from the increasing basicity of the azo-nitrogen. The broad signals assigned to the OH protons at ~11.36-11.88 ppm are not affected by dilution.

Infrared spectra of ligands (HLn)

The infrared spectra of ligands (HLn) give two bands at ~3200-3040 cm-1 due to asymmetric and symmetric stretching vibrations of N-H group and intramolecular hydrogen bonding NH…O systems (Figure 1D), respectively.

The broad absorption band located at ~3400 cm-1 is assigned to νOH. The low frequency bands indicate that the hydroxy hydrogen atom is involved in keto ↔ enol (A↔B) tautomerism through hydrogen bonding (Figure 1C).

The infrared spectra of ligands shows medium broad band located at ~3460cm-1 due the stretching vibration of some sort of hydrogen of hydrogen bonding. El-Sonbati et al. [4,25-27] made detailed studies for the different types of hydrogen bonding which are favorable to exist in the molecule under investigation:

1) Intramolecular hydrogen bond between the nitrogen atom of the –N-N- system and hydrogen atom of the hydroxy hydrogen atom (Figure 1C). This is evident by the presence of a broad band centered at 3460 cm-1.

2) Hydrogen bonding of the OH…N type between the hydroxy hydrogen atom and the N-ph group (Figure 1C).

3) Intermolecular hydrogen bonding is possible forming cyclic dimer through NH…O-C (G), OH…N-N (F) or OH…OH (E) (Figure 1).

Infrared spectra of complexes and nature of coordination

The bonding of the metal ion to the ligand can be clarified by comparing the IR-spectra of the complexes with those of the ligands.

In the IR spectra of all metal complexes (1-4) a number of changes are observed:

1) The appearance of a new bands around ~ 3380 cm-1 and two sharp bands at ~ 715 and 420 cm-1, the latter two can be assigned to the wagging and rocking modes of vibration of the water molecule, respectively, [28] in the prepared complexes (1-4) may be taken as a strong evidence for the presence of coordinated water.

2) The N-N stretching frequency of the azo groups is shifted to lower frequency by ~15-25 cm-1, due to the involvement of one of the azo nitrogen atoms in coordination with metal ion [2-4]. This lowering of frequency can be explained by the transfer of electrons from nitrogen atom to the Cu(II) ion due to coordination.

3) In solution and in the presence of Cu(II) ions these compounds exist in a tautomerism equilibrium [4,5] A↔B↔C (Figure 1). The tautomeric form (C) react with metal ions by loss of phenolic proton as mononegative chelating agents producing of CO/OH mode of the free ligands [4,29].

4) Furthermore, the bands in the regions 545-560 and 420-428 cm-1 can be assigned to the stretching modes of the metal to ligand bonds, υ(Cu–O) and υ(Cu–N) for 1:1 (M:L) complexes, respectively, [4]. Absence of υ(M-S) band in the far IR spectra gives added evidence for the non-participation of ring sulphur atom in bond formation.

On the basis of all these data, the molecular structure of the Cu(II) complexes could be suggested based on :

i) the presence of anion, ii) the disappearance of C=O, iii) the coordination of azo-group iv) the presence of water.

According to the structure shows in Figure 5 and analytical data in Table 2, the ligand (HLn) takes its usual anionic form (Ln) to chelate Cu(II) through N– of azo group with enol group (Figure 1C) as the potential binding sites. The analytical data agree satisfactory with the expected formulae represented as given in Figure 5.

Complex μeff
B.M.
Calc. (Exp.)%
C H S M
[Cu(L1)(OAc)(OH2)].2H2O (1) 1.83 32.54
(32.47)
3.84
(3.72)
9.49
(9.13)
14.46
(14.07)
14.36
(14.06)
[Cu(L3)(OAc)(OH2)].2H2O (2) 1.85 33.76
(33.60)
3.99
(3.82)
9.85
(9.46)
15.01
(14.86)
14.90
(14.72)
[Cu(L5)(OAc)(OH2)].2H2O(3) 1.87 32.00
(31.86)
3.64
(3.44)
10.18
(9.87)
15.51
(15.27)
15.40
(15.17)
[Cu(L2)(OAc)(OH2)].2H2O (4) 1.84 28.51
(28.40)
3.02
(2.89)
9.07
(8.78)
13.82
(13.65)
13.72
(13.47)

Table 2: Analytical and magnetic moments of Cu(II) complexes.

microbial-biochemical-technology-complexes

Figure 5: The structure of the Cu(II) complexes.

Magnetic measurements and electronic spectra were conducted in order to obtain information about the geometry of the complexes. The magnetic susceptibility values (1.83-1.87 B.M.) which was consistent with presence of a single unpaired electron [4]. This behavior suggest square planar geometry for the Cu(II) complexes [4].

The analytical data of ligands and their complexes agree satisfactory with the expected formulae represented as given in structures (Figures 1 and 5).

X-ray diffraction

The X-ray diffraction, XRD, patterns of the as-synthesized ligand HL2 and complex (4) powder forms are shown in Figure 6. Many peaks are observed which indicate the polycrystalline nature of the assynthesized ligand HL2 and complex (4). The average crystallite size (ξ) can be determined using by Debye-Scherrer equation [30-32]:

image       

microbial-biochemical-technology-diffraction

Figure 6: X-ray diffraction patterns for a) HL2 and b) [Cu(L2)(OAc)(OH2)].2H2O powder forms.

where λ is X-ray of wavelength (1.541874 Å), K is constant taken as 0.95 for azo compounds [31], β1/2 is the full width at half maximum height and θ is Bragg angle. The dislocation density, δ, is the number of dislocation lines per unit area of the crystal. The value of δ is related to the average particle diameter (ξ) by the relation [32,33]:

image

The values of ξ are calculated and found to be 283 and 180 nm for HL2 and complex (4), respectively. The values of δ are 1.25×10-5 and 3.09×10-5 nm-2 for HL2 and complex (4), respectively.

Thermal analyses

Thermogravimetric analysis of ligands (HLn): The Thermogravimetric Analysis (TGA) data of ligands (HLn) is represented in Table 3. The Differential Scanning Calorimetry (DSC) curves exhibit a series of thermal changes during the increase of temperature. The TGA and DSC curves for HLn (where n=1, 3 and 5) are shown in Figure 7.

Compound First stage Second  stage Third  stage Remaining Weight after 650°C
Temperature
(°C)
Weight loss (%) Temperature 
(°C)
Weight loss (%) Temperature 
(°C)
Weight loss (%)
HL1 200 61.9 320 38.1 - - Ash
HL3 145 59.8 400 39.9 - - Ash
HL5 112 5.4 225 33.6       284 58.7 Ash

Table 3: Weight losses percentage of HL1, HL3 and HL5.

microbial-biochemical-technology-thermographs

Figure 7: TGA and DSC thermo graphs for (a) HL1, (b) HL3 and (c) HL5.

The DSC curves for HLn are shown in Figure 7(a-c). For the HL1 ligand the recorded DSC curve show only one exothermic peak at 220°C. Simultaneously, the recorded DSC curve of the HL3 ligand show two exothermic and endothermic peaks at 190°C and 180°C, respectively, while the recorded DSC curve of the HL5 ligand show two exothermic and endothermic peaks at 245°C and 120°C, respectively [34].

Thermogravimetric analysis of complexes: The thermal analysis of the Cu(II) complexes was studied by TGA technique to give more information on the structure of the investigated complexes. The TGA data for the [CuLn(OAc)(OH2)].2H2O complexes (n=1,2,3, and 5) are summarized in Table 4. It can be seen that the TGA curves of the complexes [CuLn(OAc)(OH2)].2H2O complexes, pointed to that the dehydration process of two lattice occurs within the temperature range ~ 45-189°C. However, the dehydration of one coordinated H2O and one acetate group take place in one step and in the temperature range ~ 189-331°C as shown in Figure 8.

Complexa Temp. range (ºC) Found mass loss (calc.) % Assignment
(1) 45-189 7.24 (8.13) Loss of two water molecules in outside of the coordination sphere.
189-331 16.67 (17.39) Loss of one coordinated water molecule and one coordinated acetate group.
331-506 24.43 (24.17) Further decomposition of a part of the ligand (C7H7O).
506-709 14.38 (14.46) Evolution of SO2 gas leaving CuO residue with contaminated carbon atoms.
(2) 45-178 7.91 (8.73) Loss of two water molecules in outside of the coordination sphere.
178-273 18.61 (18.66) Loss of one coordinated water molecule and one coordinated acetate group.
273-514 18.06 (18.42) Further decomposition of a part of the ligand (C6H4).
514-560 6.64 (6.79) Evolution of N2 gas.
560-640 15.43 (15.51) Evolution of SO2 gas leaving CuO residue with contaminated carbon atoms.
(3) 45-189 4.15 (7.87) Loss of two water molecules in outside of the coordination sphere.
189-288 16.72 (16.83) Loss of one coordinated water molecule and one coordinated acetate group.
288-400 10.46 (10.05) Evolution of NO2 gas.
400-592 13.72 (13.98) Evolution of SO2 gas.
  592-670 22.44 (22.73) Decomposition of a part of the ligand (C6H4N2) leaving CuO residue with contaminated carbon atoms.
(4) 40-189 5.22 (8.44) Loss of two water molecules in outside of the coordination sphere.
189-316 18.00 (18.05) Loss of one coordinated water molecule and one coordinated acetate group.
316-533 20.47 (21.33) Further decomposition of a part of the ligand (C7H7).
533-670 15.45 (15.00) Evolution of SO2 gas and CuO residue with contaminated carbon atoms.

aNumbers as given in Table 2

Table 4: Thermal analyses data of the Cu(II) complexes.

microbial-biochemical-technology-complexes

Figure 8: TGA curves for Cu(II) complexes.

Calculation of activation thermodynamic parameters

The thermodynamic activation parameters of decomposition processes of complexes namely activation energy (Ea), enthalpy (ΔH*), entropy (ΔS*), and Gibbs free energy change of the decomposition (ΔG*) are evaluated graphically by employing the Coast-Redfern [35] and Horowitz-Metzger [36] methods.

Coast-Redfern equation:

The Coast-Redfern equation, which is a typical integral method, can represent as:

image                                                         (7)

For convenience of integration, the lower limit T1 usually taken as zero. This equation on integration gives:

image                                                       (8)

A plot of left-hand side (LHS) against 1/T. Ea is the energy of activation and calculated from the slop and A in (s-1) from the intercept value. The entropy of activation ΔS* in (J K-1 mol-1) calculated by using the equation:

image                                                  (9)

where kB is the Boltzmann constant, h is the Plank’s constant and Ts is the TG peak temperature.

Horowitz-Metzger equation:

The Horowitz-Metzger equation is an illustrative of the approximation methods. These authors derived the relation:

image                                                (10)

when n = 1, the LHS of equation 10 would be log[-log(1-α)]. For a first order kinetic process, the Horowitz-Metzger equation may write in the form:

image                                               (11)

where θ=T-Ts, wγ=wα-w, wα=mass loss at the completion reaction; w=mass loss up to time t. The relation between log [log (wα/wγ)] and θ was found linear from the slope of which Ea was calculated. The preexponential factor, A, calculated from equation:

image                                                                         (12)

The entropy of activation, ΔS*, is calculated from equation 9. The enthalpy activation, ΔH*, and Gibbs free energy, ΔG*, calculated from:

image                                                                 (13)

image                                                              (14)

The calculated values of Ea, A, ΔS*, ΔH* and ΔG*for the decomposition steps for ligands (HLn) and their complexes (1-4) are summarized in Table 5. It is clear from these results that the change of substituent strongly affects the activation thermodynamic parameters.

Compounda Decomposition temperature (°C) Method Parameter Correlation coefficient
(r)
Ea
(KJ mol−1)
A
(s−1)
ΔS*
(J mol−1K−1)
ΔH*
(KJ mol−1)
ΔG*
(KJ mol−1)
HL1 211-346 CR 45.8 7.58×101 -214 41.2 159 0.99221
    HM 53.6 4.18×102 -200 49 159 0.99398
  498-624 CR 180 4.43×108 -87.9 174 247 0.99355
    HM 193 6.40×109 -65.8 186 241 0.99169
HL3 158-401 CR 46.9 7.11×101 -215 42.3 161 0.99322
    HM 48.4 1.17×102 -210 43.8 160 0.99788
  502-643 CR 162 2.34×107 -113 155 250 0.98442
    HM 173 2.50×108 -92.2 166 245 0.99156
HL5 225-271 CR 329 2.54×1030 333 325 151 0.99453
    HM 338 1.70×1032 367 333 142 0.99452
  443-630 CR 108 1.51×104 -173 101 242 0.99432
    HM 120 2.05×105 -152 113 236 0.9939
(1) 142-240 CR 70.9 5.53×105 -139 67.1 131 0.99122
    HM 80.8 1.40×107 -112 76.9 129 0.98595
  301-418 CR 102 1.31×106 -134 96.5 181 0.99104
    HM 114 2.10×107 -111 108 179 0.99064
(2) 127-372 CR 31.2 3.31×100 -240 26.9 152 0.99523
    HM 39.2 3.59×101 -220 34.9 150 0.98744
  496-715 CR 108 1.59×104 -173 101 254 0.98712
    HM 119 5.78×104 -163 112 255 0.98669
(3) 189-292 CR 106 3.74×108 -85.3 102 146 0.99596
    HM 115 7.73×109 -60.0 111 142 0.99460
  349-403 CR 235 9.36×1016 73.5 230 182 0.99590
    HM 250 2.09×1018 99.3 244 180 0.99435
(4) 142-399 CR 31.8 2.10×100 -244 27.3 160 0.99161
    HM 41.0 3.60×101 -220 36.5 156 0.98130
  599-715 CR 171 4.27×107 -108 163 264 0.98947
    HM 187 2.01×108 -95.4 179 268 0.99112

Table 5:Thermodynamic parameters of the thermal decomposition of HLn and their Cu(II) complexes.

The complex (3) is the highest value of Ea. This can be attributed to the fact that the effective charge experienced by the d-electrons increases due to the electron withdrawing p-substituent NO2 while it decreases by the electron donating character of OCH3 and CH3. This indicates that, the complex (3) is more thermally stable than the other complexes [4].

Antimicrobial activity of complexes

The antimicrobial activity of Cu(II) complexes of HLn were tested against some bacteria and fungi. More than one test organism was tested to increase the chance of detection of their antimicrobial activities. The used organisms in the present investigation included two Gram positive bacteria (B. cereus and S. aureus) and two Gram negative bacteria (E. coli and K. pneumoniae) in addition to four different kinds of fungi (A. niger, A. alternata, P. italicum and F. oxysporium).

The results of the antibacterial activity of the Cu(II) complexes of HLn (1-4) were recorded in Table 6. The complexes (1-4) have no antibacterial activity against Klebsiella pneumoniae and Bacillus cereus except complex (3) has low antibacterial activity against Bacillus cereus, while it in all used concentration was found to have high antibacterial activity against Staphylococcus aureus and Escherichia coli. Complex (4) was active only at concentration=150 μg/ml. We found that the complex [Cu(L5)(OAc)(OH2)].2H2O (3) is more active than other complexes, namely [Cu(L1)(OAc)(OH2)].2H2O (1), [Cu(L3)(OAc)(OH2)].2H2O (2) and [Cu(L2)(OAc)(OH2)].2H2O (4) against Staphylococcus aureus, Escherichia coli and Bacillus cereus and this is may be related to the nature of the p-substituent existing in the complexes. This can be attributed to the fact that the effective charge experienced by the d-electrons increased due to the electron withdrawing character of complex (3) while it decreased by the electrons donating character of complex (1). This is in accordance with that expected from Hammett’s substituent coefficients (σR) as shown in Figure 9. It is clear that the values of inhibition zone (mm) increase with increasing σR. It is important to note that the existence of a methyl and/or methoxy group enhances the electron density on the coordination sites and simultaneously decreases the values of inhibition zone. Staphylococcus aureus was affected by the complexes (2-4) (inhibition zone of complex (2)=3 and 3 mm at concentrations=100 and 150 μg/ml, respectively; inhibition zone of complex (3)=8, 9 and 10 mm at concentrations = 50, 100 and 150 μg/ml, respectively; inhibition zone of complex (4)=5 and 5 mm at concentration=100 and 150 μg/ml, respectively). Addition to that Escherichia coli was also affected by the complexes (1-4) (inhibition zone of complex (1)=4, 4 and 2 mm at concentrations=50, 100 and 150 μg/ml, respectively; inhibition zone of complex (2)=5, 5 and 4 mm at concentrations=50, 100 and 150 μg/ml, respectively; inhibition zone of complex (3)=4, 4 and 3 mm at concentrations=50, 100 and 150 μg/ ml, respectively; inhibition zone of complex (4)=5, 5 and 4 mm at concentrations=50, 100 and 150 μg/ml, respectively). The complex (3) is more active than penicillin against Staphylococcus aureus and Escherichia coli.

  Complexa   Concentration Gram positive bacteria Gram negative bacteria
Bacillus cereus Staphylococcus aureus Escherichia coli Klebsiella pneumoniae
   (1) 50 µg/ml -ve -ve 4 -ve
100 µg/ml -ve -ve 4 -ve
150 µg/ml -ve -ve 2 -ve
  (2) 50 µg/ml -ve -ve 5 -ve
100 µg/ml -ve 3 5 -ve
150 µg/ml -ve 3 4 -ve
  (3) 50 µg/ml 1 8 4 -ve
100 µg/ml 1 9 4 -ve
150 µg/ml 1 10 3 -ve
  (4) 50 µg/ml -ve -ve 5 -ve
100 µg/ml -ve 5 5 -ve
150 µg/ml 2 5 4 -ve
  Penicillin 50 µg/ml 1 2 1 -ve
100 µg/ml 3 2 3 -ve
150 µg/ml 3 2 3 -ve

aNumbers as given in Table 2

Table 6: Antibacterial activity data of Cu(II) complexes. The results were recorded as the diameter of inhibition zone (mm).

microbial-biochemical-technology-hammetts

Figure 9: The relation between Hammett’s substituent coefficients (σR) versus inhibition zone (mm) for Cu(II) complexes (In case of using concentration a=50 μg/ml, b=100 μg/ml and c=150 μg/ml against S. aureus).

Comparative analysis for antibacterial study of complexes (1- 4) is shown in Figure 10. It is observed that the complex (3) is more potent antibacterial than the other complexes. This enhancement in antibacterial activity is rationalized on the basis of the partial sharing of the positive charge of metal ions with donor groups [37,38]. This may support the argument that some type of biomolecular binding to the metal ions or interchelation or electrostatic interactions causes the inhibition of biological synthesis. So it can be concluded that some complexes exhibits higher antimicrobial activity than the free ligand [39].

microbial-biochemical-technology-antibacterial

Figure 10: Comparative analysis for antibacterial activity of the Cu(II) complexes for concentration a)=50 μg/ml, b) =100 μg/ml and c)=150 μg/ml.

The results of the examination of antifungal activity of the complexes (1-4) were recorded in Table 7. The results revealed that the complexes (1-4) have no antifungal activity against Fusarium oxysporum and Penicillium italicum, while they were found to have low antifungal activity against Aspergillus niger and Alternaria alternate coli.

Complexa Concentration (µg/ml) Aspergillus niger Fusarium oxysporum Alternaria
alternata
Penicilliumitalicum
  (1) 50 µg/ml -ve -ve -ve -ve
100 µg/ml -ve -ve -ve -ve
150 µg/ml -ve -ve -ve -ve
  (2) 50 µg/ml 1 -ve 1 -ve
100 µg/ml 1 -ve 1 -ve
150 µg/ml -ve -ve -ve -ve
  (3) 50 µg/ml -ve -ve 1 -ve
100 µg/ml -ve -ve 1 -ve
150 µg/ml 2 -ve 2 -ve
  (4) 50 µg/ml -ve -ve -ve -ve
100 µg/ml 3 -ve 2 -ve
150 µg/ml 4 -ve 3 -ve
  Miconazole 50 µg/ml 1 2 5 1
100 µg/ml 3 3 6 1
150 µg/ml 4 3 6 2

aNumbers as given in Table 2

Table 7: Antifungal activity data of Cu(II) complexes. The results were recorded as the diameter of inhibition zone (mm).

The results of the Transmission Electronic Micrograph (TEM) comparative study on the morphology and internal ultrastuctures of normal and complex (3) treated E. coliand S. aureus; provided strong evidence that complex (3) is stressful and toxic for the bacterial cells. In general, the cytomorphic changes; in both treated E. coliand S. aureus; appears mainly in the cell wall. In the case of S. aureus and complex (3) as well as DMF treatments resulted in significant morphometric changes including cell size reduction and cell wall thickening as presented in Table 8. These changes enabled S. aureusto keep its internal components in stable condition as shown in Figure 11; under the DMF stress; similar to normal cell (Figure 12). Although DMF seems to accelerate cell division, complex (3) treated bacteria showed normal division rate in the examined field (Figure 12). This appearance may be a result to high death rate after treating with complex (3).

Treatment Escherichia coli Staphylococcus aureus
Cell length (nm) Cell width (nm) Distance between cell wall & cell membrane (nm) Cell diameter (nm) Cell wall thickness (nm)
Control 474.7 ± 30.7 243.3 ± 5.5 17.6 ± 1.9 334.9 ± 18.7 14.6 ± 1
DMF 465.8 ± 11.4 249.3 ± 2.8 19.5 ± 0.6 274.2 ± 16* 19 ± 1.1*
Complex (3) 438.9 ± 35 252.6 ± 3.5 29.5 ± 0.6* 268.8 ± 2.4* 18.7 ± 0.4*

*Significant different at 0.05 significance level.

Table 8: Morphometric analysis of bacterial cell treated with complex (3).

microbial-biochemical-technology-ribosomes

Figure 11: TEM photograph of S. aureus treated with DMF illustrating decreased size of cocci cells (long black arrow), Electron-dense boundary cell wall increased in thickness (short black arrow), numerous ribosomes (long white arrow), Electron-dense granules (short white arrow) and increased number of cells forming division septa (arrow head). [Specimen fixed in 4F1G solution and double stained with uranyl acetate and lead citrate, scale bar=100 nm].

microbial-biochemical-technology-homogenous

Figure 12: TEM photograph of normal S. aureus illustrating different size of cocci cells, normal thin Electron-dense cell walls (long black arrow), homogenous Electron-dense cytoplasm (long white arrow), normal division (short black arrow) and numerous ribosomes (arrow head). [Specimen fixed in 4F1G solution and double stained with uranyl acetate and lead citrate, scale bar=100 nm].

For complex (3) could damage some sites in the thickening cell wall as shown in Figure 13. Moreover, complex (3) treatment led to completely lysis of some cell walls leaving the cell contents as spherical aggregates (Figure 13). Regarding to E. coli, DMF treatment didn’t result in any significant cytomorphological as shown in Figures 14 and 15 or morphometric changes. Also, complex (3) treatment didn’t result in any significant morphometric changes in the cell size (Table 8). Whereas it was found to significantly increase electron-lucent region between cell wall and cell membrane by more than 30% of its normal length (Table 8) demonstrating on detachment of the cell wall from the plasma membrane. This action appears to be sequenced by lysis of some sites in the cell wall and led to rough irregular cell wall as shown in Figure 16. In general, the final effect of complex (3) appears as granular cell contents exude from the damaged membrane (Figures 13 and 16) which confirmed that complex (3) has bactericidal effect against both bacteria.

microbial-biochemical-technology-thickness

Figure 13: TEM photograph of S. aureus treated with complex (3) illustrating cocci cells, Electron-dense cell wall increased in thickness with some damaged sites (long black arrow), granular cell contents appear to be exuding from the damaged membrane (short black arrow) and some cells without boundary cell walls (long white arrow). [Specimen fixed in 4F1G solution and double stained with uranyl acetate and lead citrate, scale bar=100 nm].

microbial-biochemical-technology-homogenous

Figure 14: TEM photograph of normal E. coli showing rod shaped cells, normal smooth continuous cell wall (short black arrow) and cell membrane (long black arrow), homogenous Electron-dense cytoplasm (short white arrow), normal electron-lucent region between cell wall and cell membrane (long white arrow) and normal cell division (arrow head). [Specimen fixed in 4F1G solution and double stained with uranyl acetate and lead citrate, scale bar=100 nm].

microbial-biochemical-technology-continuous

Figure 15: TEM photograph of E. coli treated with DMF showing rod shaped cells, normal smooth continuous cell wall (short black arrow) and cell membrane (long black arrow), homogenous Electron-dense cytoplasm (short white arrow), normal electron-lucent region between cell wall and cell membrane (long white arrow). [Specimen fixed in 4F1G solution and double stained with uranyl acetate and lead citrate, scale bar=100 nm].

microbial-biochemical-technology-damaged

Figure 16: TEM photograph of E. coli treated with complex (3) showing rod cells with rough irregular cell wall (short black arrow), increased electron-lucent region between cell wall and cell membrane (long black arrow) and granular cell contents appear to be exuding from the damaged membrane (white arrow). [Specimen fixed in 4F1G solution and double stained with uranyl acetate and lead citrate, scale bar=100 nm].

Morphological changes of organisms under stressful conditions are the most visible parameters of bacterial adaptation. The changes in morphology as an adaptive response to adverse environmental conditions have already been reported with several bacterial species [40-43].

In the present investigation, the cell morphology of complex (3) treated cells of studied bacteria as observed by TEM indicated malformed bacteria with rough and wrinkled cell surface. Furthermore, septal region showed slight swelling due to the formation of intercalating cells.

Conclusion

The results obtained can be summarized as follows:

i. The data revealed that the coordination geometry around Cu(II) in all complexes exhibit a trans square planar by NO.

ii. It is found that the change of substituent affects the thermal properties of azodye rhodanine derivatives and their Cu(II) complexes.

iii. The biological activity of Cu(II) complexes are tested against a number of Gram-positive and Gram-negative bacteria. The results showed that some of the complexes have a well considerable activity against some of the organisms.

iv. The tested complexes have good antibacterial activity against Staphylococcus aureus and Escherichia coli and have low antifungal activity against Aspergillus niger, Fusarium oxysporium and Alternaria alternata.

v. The complex (3) is more active than other complexes (1), (2) and (4) against Staphylococcus aureus and Escherichia coli.

vi. Our results of the TEM comparative study on the morphology and internal ultrastructures, complex (3) has bactericidal effect against Staphylococcus aureus and Escherichia coli.

Acknowledgements

The authors would like to thank Prof. Dr. Nabila El-Sayed Abdel Meguid Prof. Emeritus of Cytology and Cytochemistry, Zoology Department, Faculty of Science, Alexandria University, Egypt and Miss N.F. Omar, Botany Department, Faculty of Science, Damietta University, Egypt for her help during testing antimicrobial activity

References

Citation: Abou-Dobara MI, El-Sonbati AZ, Diab MA, El-Bindary AA, Morgan SM (2014) Thermal Properties, Antimicrobial Activity of Azo Complexes and Ultrastructure Study of Some Affected Bacteria. J Microbial Biochem Technol S3:006.

Copyright: © 2014 Abou-Dobara MI, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited