Synthesis, Characterization, Antimicrobial, DNA Cleavage, and In Vitro Cytotoxic Studies of Some Metal Complexes of Schiff Base Ligand Derived from Thiazole and Quinoline Moiety

A novel Schiff base ligand N-(4-phenylthiazol-2yl)-2-((2-thiaxo-1,2-dihydroquinolin-3-yl)methylene)hydrazinecarboxamide (L) obtained by the condensation of N-(4-phenylthiazol-2-yl)hydrazinecarboxamide with 2-thioxo-1,2-dihydroquinoline-3-carbaldehyde and its newly synthesized Cu(II), Co(II), Ni(II), and Zn(II) complexes have been characterized by elemental analysis and various spectral studies like FT-IR, 1H NMR, ESI mass, UV-Visible, ESR, TGA/DTA, and powder X-ray diffraction studies. The Schiff base ligand (L) behaves as tridentate ONS donor and forms the complexes of type [ML(Cl)2] with square pyramidal geometry. The Schiff base ligand (L) and its metal complexes have been screened in vitro for their antibacterial and antifungal activities by minimum inhibitory concentration (MIC) method. The DNA cleavage activity of ligand and its metal complexes were studied using plasmid DNA pBR322 as a target molecule by gel electrophoresis method. The brine shrimp bioassay was also carried out to study the in vitro cytotoxicity properties for the ligand and its metal complexes against Artemia salina. The results showed that the biological activities of the ligand were found to be increased on complexation.


Introduction
Schiff bases are important classes of ligands that coordinate with metal ions via azomethine nitrogen and have been studied extensively because of increasing recognition of their role in biological system [1]. The Schiff bases containing ONS donor atoms act as superior chelating agents for the transition and nontransition metal ions and showed remarkable biological activities [2,3]. Coordination of these compounds with metal ions, such as copper and nickel, often enhance their activities [4]. Bonding between azomethine nitrogen and metal ion was found to be important for biological activity. Several azomethines were reported to possess important antibacterial [5], antifungal [6], anticancer [7], and diuretic activities [8].
A lot of work has been done on the synthesis of compounds using substituted thiazole and quinoline moieties [31,32]. Literature survey reveals that not much work has been carried out on Schiff base ligand derived from 2-thioxo-1, 2dihydroquinoline-3-carbaldehyde. In view of the above findings and in continuation of our research work on synthesis and characterization of new Schiff base ligands and their metal complexes, we hereby report the synthesis of a novel Schiff base ligand N-(4-phenylthiazol-2yl)-2-((2thiaxo-1,2-dihydroquinolin-3-yl)methylene) hydrazine carboxamide (L) and its Cu(II), Co(II), Ni(II), and Zn(II)

Preparation of Cu(II), Co(II), Ni(II) and Zn(II) Complexes.
Hot ethanolic solution (15 mL) of the respective metal chlorides (0.001 mol) and the Schiff base ligand (0.001 mol) in ethanol (30 mL) were refluxed for about 4-5 h on a water bath and the pH of the reaction mixture was adjusted ca. 7.0-7.5 by adding alcoholic solution of sodium acetate (0.5 g). The reaction mixture was cooled to room temperature and poured in to distilled water. Metal chelates separated were collected by filtration, washed with sufficient quantity of distilled water then with hot ethanol, and finally dried in a desiccator over anhydrous calcium chloride at room temperature. (C 20 (C 20  (1) Agar Well Diffusion Assay. In vitro antibacterial and antifungal activities of synthesized Schiff base ligand (L) and its Cu(II), Co(II), Ni(II), and Zn(II) complexes were determined by standard agar well diffusion assay. Mueller-Hinton agar media were used for antibacterial studies. The pure dehydrated Mueller-Hilton agar (38 g) dissolved in 1000 mL of distilled water. The pure cultures of the bacterial strains Enterobacter aerogenes and Pseudomonas aeruginosa were subcultured by inoculating in the nutrient broth and were incubated at 37 ∘ C for about 18 h. The agar plates were prepared by using the above media and wells were dug with the help of 6 mm sterile metallic cork borer. Each plate was inoculated with 18 h old bacterial culture (100 L) using a micropipette and spread uniformly using bent glass rod on each plate. Different concentrations of the test compounds (100, 50, and 25 g mL −1 ) were incorporated into the wells using micropipette and the plates were kept for incubation at 37 ∘ C for 24 h. After the completion of incubation period, the diameters of the inhibition zones generated by each test compound against bacterial growth were measured using antibiogram zone measuring scale. The experiment done in triplicate and the average values were calculated for antibacterial activity.

[Co
Potato dextrose agar (PDA) media were used for the antifungal studies. The following ingredients were used to prepare the medium. Potatoes (sliced, washed, unpeeled 200 g), dextrose (20 g), agar (20 g) in 1000 mL distilled water.
The pure cultures Aspergillus niger and Aspergillus flavus were inoculated on PDA slants. These slants were incubated at 32 ∘ C for 7 days. To these 7-day-old slants of fungal strains, 10 mL of 0.1% tween-80 solution was added and the culture was scraped with sterile inoculating loop to get uniform spore suspension. The agar plates were prepared by using the above potato dextrose agar media and wells were dug with the help of 6 mm sterile metallic cork borer. Each plate was inoculated with 7-day-old spore suspension of each fungal culture (100 L) using a micropipette and spread uniformly using bent glass rod on each plates. Each well was incorporated with the test compound solution of different concentrations (100, 50, and 25 g mL −1 ). All the inoculated plates were incubated at 32 ∘ C for about 48 h. After the completion of incubation period, the diameters of the inhibition zones generated by each test compound against fungal growth were measured using antibiogram zone measuring scale. The experiment done in triplicate and the average values were calculated for antifungal activity.
(2) Minimum Inhibitory Concentration (MIC). Minimum inhibitory concentration (MIC) was defined as the lowest concentration where no visible turbidity was observed in the test tubes [34,35]. Minimum inhibitory concentration of the compounds was determined in nutrient agar plate by microdilution method according to the National Committee for Clinical Laboratory Standards [36]. Standardized suspension of test organisms (0.1 mL, 10 6 cfu/mL) and synthesized Schiff base ligand (L) and its Cu(II), Co(II), Ni(II), and Zn(II) complexes in different concentrations (100, 50, 25, 12.50, 6.25, 3.125, 1.563, 0.78, 0.39, and 0.195 g/mL) were taken in test tubes and test tubes with Gentamycin and Fluconazole as positive control for bacterial and fungal strains, respectively. DMSO is used as a negative control for antibacterial and antifungal, respectively. The bacterial tubes were incubated at 37 ∘ C for 18 h and fungal tubes were incubated at 32 ∘ C for 48 h. The lowest concentration that produced no visible bacterial growth compared with the control tubes was regarded as MIC.

DNA Cleavage Activity.
In order to study whether newly synthesized Schiff base ligand and its metal complexes could behave as DNA cleaving agents or not, they were examined using plasmid pBR322 DNA (Bangal re Genei, Bengaluru, Cat. No 105850) as a target molecule according to the literature method [37].
The cleavage activity of the test compounds was analyzed by agarose gel electrophoresis method. The 600 mg of agarose was dissolved in 60 mL of TAE buffer (4.84 g Tris base, pH 8.0, 0.5 M EDTA) by boiling. When the gel attains approximately 55 ∘ C, it was poured into the gel cassette fitted with comb. The gel was allowed to solidify and then carefully the comb was removed. The gel was placed in the electrophoresis chamber flooded with TAE buffer. Test compounds were prepared in DMSO (1 mg mL −1 ). The test compounds were added separately to the isolated plasmid pBR322 DNA (225 ng) and incubated for 2 h at 37 ∘ C. After the incubation period, the 20 L of DNA sample (mixed with bromophenol blue dye at a 1 : 1 ratio) was loaded carefully into the electrophoresis chamber wells along with standard DNA marker and a constant electricity of 50 V passed for about 30 min. The gel was removed carefully and stained with Ethidium bromide (EtBr) solution (10 g/mL) for 10-15 min. The bands were observed under UV transilluminator (UVP, Germany) and photographed to determine the extent of DNA cleavage, and the results were compared with those of a standard DNA marker.

2.4.3.
In Vitro Cytotoxicity. The brine shrimp lethality bioassay has been chosen to evaluate the in vitro cytotoxic effect of the newly synthesized Schiff base ligand (L) and its Cu(II), Co(II), Ni(II), and Zn(II) complexes by using the protocol of Meyer et al. [38]. This is an efficient, rapid, inexpensive test and has a good correlation with cytotoxic activity.
Brine shrimp (Artemia salina) eggs were hatched in a shallow rectangular plastic dish (22 × 32 cm) filled with artificial seawater, which was prepared with a commercial salt mixture and double distilled water. An unequal partition was made in the plastic dish with the help of a perforated device. Approximately 50 mg of eggs were sprinkled into the large compartment, which was darkened while the minor compartment was open to ordinary light. After two days nauplii were collected by a pipette from the lighted side. A sample of the test compound was prepared by dissolving 20 mg of each compound in 2 mL of DMSO. From this stock solution 100, 50, and 25 g mL −1 were transferred to nine vials (three for each dilution were used for each test sample and LD 50 is the mean of three values) and one vial was kept as control having 2 mL of DMSO only. The solvent was allowed to evaporate overnight. After two days, when shrimp larvae were ready, 1 mL of seawater and 10 shrimps were added to each vial (30 shrimps/dilution) and the volume was adjusted with seawater to 10 mL per vial. After 24 h the number of survivors was counted. Data were analysed by a Finney computer program to determine the LD 50 values [39].

Results and Discussion
The reaction of Schiff base ligand (L) with Cu(II), Co(II), Ni(II), and Zn(II) ions in 1 : 1 ratio resulted in the complex of the type [ML(Cl) 2 ]. The physical and analytical data agree well with the proposed composition of Schiff base ligand and its Cu(II), Co(II), Ni(II), and Zn(II) complexes. The newly synthesized complexes are colored solids, stable in air, and insoluble in water and common organic solvents but completely soluble in DMF and DMSO. The molar conductance data of the complexes was measured in DMF at ca. 10 −3 M and all the complexes showed conductance in the range of 50-61 Ohm −1 cm 2 mol −1 at room temperature indicating nonelectrolytic nature of the complexes suggesting that the Cl − anion is coordinated to metal ion. This was further supported by the proposed general formula of the complexes based upon the results of elemental analysis (Table 1) and spectral data.
3.1. IR Spectra. IR spectrum of the ligand showed a high intensity band at 1688 cm −1 due to ](C=O) and three absorption bands at 3393, 3259, and 3119 cm −1 due to quinoline NH, amide NH, and NH attached to thiazole moiety, respectively.
A high intensity band observed at 1620 cm −1 is attributed to the azomethine ](C=N) vibration and a band at 1225 cm −1 to ](C=S) functioning at 2-position of quinoline moiety.
In order to study the binding mode of the Schiff base to the metal ion in complexes, the IR spectrum of the free ligand was compared with the spectra of the complexes. In the IR spectra of the complexes, medium intensity weak bands at 3366-3295, 3212-3189, and 3175-3089 cm −1 were due to quinoline NH, amide NH, and NH attached to thiazole moiety, respectively, which appeared at about the same region as in the case of ligand indicating their noninvolvement in coordination. The shift of amide carbonyl ](C=O) to lower frequency side about 55-32 cm −1 which appeared in the region 1656-1633 cm −1 in all the complexes confirms the coordination of oxygen atom of amide C=O with the metal ions as such without undergoing enolization [40]. The IR spectrum of all the complexes showed a shift of the azomethine ](C=N) band towards lower frequency side about 67-27 cm −1 and appeared in the region 1593-1553 cm −1 when compared with the free ligand indicating the coordination of the azomethine nitrogen to the metal ions [41]. The shift of band due to ](C=S) in all the complexes towards lower frequency side by 37-9 cm −1 when compared to the ligand, which appeared in the region 1215-1188 cm −1 , proves the coordination of the sulfur atom of quinoline 2-thione to metal ions. The formation of complex was further confirmed by the appearance of new bands in the regions 540-514, 485-448, 372-337, and 327-312 cm −1 in all the complexes due to skeletal metal-oxygen, metal-nitrogen, metal-sulfur, and metal-chloride vibrations, respectively. The important IR spectral data of the Schiff base ligand and its metal complexes are represented in Table 2

ESI Mass Spectral Data.
The ESI mass spectra of the Schiff base ligand (L) and its Co(II) and Ni(II) complexes are performed to determine their molecular weight and study their fragmentation pattern. The mass spectrum of ligand showed a peak recorded at / 406 (3.93%) due to M +• + 1 (Figure 1). This on loss of hydrogen radical gave a peak at / 405 (2.36%) which is equivalent to its molecular weight (M.W. = 405). Further, this molecular ion underwent fragmentation by two routes. First, on loss of SH radical, it gave a fragment ion peak recorded at / 372 (2.36%), followed by expulsion of C 10 H 6 N 2 molecule which gave a fragment ion peak  Bioinorganic Chemistry and Applications Table 2: IR spectral data of Schiff base ligand (L) and its metal complexes.

Compounds
Quinoline  recorded at / 218 (14.98%). This fragment ion on further expulsion of CO molecule gave a fragment ion peak at / 190 (100%) which is also a base peak. This base peak on loss of NH 2 radical gives a fragment ion peak recorded at / 174 (3.93%). The molecular ion underwent fragmentation in another route wherein it losses SH radical and C 10 H 5 N 2 radical simultaneously giving a fragment ion peak recorded at / 219 (2.36%). This fragment ion on further loss of NCO radical gave a fragment ion peak recorded at / 177 (38.58%). This schematic mass spectral fragmentation pattern of ligand is in consistency with its structure which is depicted in Scheme 2.
The ESI mass spectrum of Co(II) complex exhibited a peak due to M +• + 1 at / 534 (5.51%). This on loss of hydrogen radical gave a peak at / 533 (2.30%), which is equivalent to its molecular weight (M.W. = 533). This molecular ion underwent fragmentation by two routes. First, on simultaneous loss of chlorine molecule, N=C=S radical, C 9 H 5 radical, and C 8 H 5 N species gave a fragment ion peak recorded at / 177 (100%) which is also a base peak. In another route, the molecular ion peak on loss of N=C=S radical gave a fragment ion peak recorded at / 475 (35.43%). The schematic mass spectral fragmentation pattern of Co(II) complex of ligand is in consistency with its structure which is depicted in Scheme 3.
Similarly, the mass spectra of Ni(II) complex exhibited a peak at / 534 (4.72%) due to M +• + 1 (Figure 2). This is on loss of hydrogen radical gave the fragment ion peak recorded at / 533 (2.23%), which is equivalent to its molecular weight (M.W. = 533). Further this molecular ion underwent fragmentation by the loss of hydrogen radical and chlorine molecule simultaneously giving a fragment ion peak recorded at / 462 (29.92%). This on further loss of C 7 H 5 N molecule gave a fragment ion peak recorded at / 359 (3.14%), which underwent fragmentation by two routes. First, on loss of H-C≡C radical and two hydrogen radicals it simultaneously gave a fragment ion peak recorded at / 332 (21.25%), which on further expulsion of C=S molecule gave a fragment ion peak recorded at / 288 (6.29%). In another route, fragment ion peak recorded at / 359 (3.14%) on simultaneous loss of C 9 H 4 NS radical and C≡C-H radical gave a fragment ion peak recorded at / 177 (100%) which is also a base peak. The schematic mass spectral fragmentation pattern of Ni(II) is in consistency with its structure which is depicted in Scheme 4.
The magnetic moment value for Cu(II) complex was found to be 1.73 BM which is in the range of 1.71-1.76 BM, agreeing well with the spin value of S = 1/2, as usually observed for Cu(II) complex, which supports its square pyramidal geometry [46]. The magnetic moment value for Co(II) complex was found to be 4.31 BM which is in the range 4.3-4.6 BM, for five coordinate square pyramidal geometries of Co(II) complex [47]. The magnetic moment of Ni(II) complex was found to be 2.78 BM, which is well within the range known for five coordinated square pyramidal geometries of Ni(II) complex [45].

ESR Spectra.
In order to obtain further information about the stereochemistry and site of the metal-ligand bonding and determine the magnetic interaction in the metal complexes, the X-band ESR spectrum of Cu(II) complex has been recorded in the polycrystalline state at room temperature using DPPH as a standard. The ESR spectrum of Cu(II) complex exhibited a single broad signal (Figure 3) due to dipolar broadening and enhanced spin lattice relaxation. The ESR spectra of Cu(II) complex exhibited auxiliary symmetric  -tensor parameter with ‖ (2.16) > ⊥ (2.03) > 2.0023, indicating presence of unpaired electron in 2− 2 ground state characteristic of square pyramidal geometry. The averaged " " value for overall distortion is calculated using the equation: avg = (1/3)(2 ⊥ + ‖ ). The exchange interaction parameter is calculated using the equation: = ‖ − 2.0023/ ⊥ − 2.0023. According to Hathaway and Billing [48], if the value of is more than four, the exchange interaction between the Cu centres is negligible. In the present case the value of 5.01 confirms the that exchange interactions between Cu(II) centers in solid state are negligible [49].

Thermal Studies.
In order to examine the thermal stability of the complexes, thermo gravimetric (TG) and differential thermal analyses (DTA) were carried out for Cu(II), Co(II), and Zn(II) complexes in static air at a temperature range between 40 to 750 ∘ C at the heating rate of 10 ∘ C min −1 . The proposed stepwise thermal degradation pattern of complexes with temperature and formation of metal oxides is given in Table 4. 3.6.1. Cu(II) Complex. TGA and DTA curves of Cu(II) complex ( Figure 4) showed that the complex is stable up to 237 ∘ C and no weight loss is observed before this temperature. The first stage of degradation occurred at 237.6 ∘ C, with the loss of the two chlorine atoms with a practical weight loss of 11.96% (Calc.12.99%). The resultant complex on further degradation gave a break at 291 ∘ C by the loss of NCS species of quinoline moiety with a practical weight loss of 11.41% (Calc. 12.37%). The resultant complex underwent third stage of decomposition at 341 ∘ C due to loss of C 9 H 7 molecule of quinoline and C 6 H 6 molecule of thiazole moiety simultaneously with a practical weight loss of 47.96% (Calc. 47.01%). Further, complex showed decomposition up to 493 ∘ C due to the loss of remaining organic moiety. The final weight of the residue corresponds to cupric oxide.

Co(II)
Complex. The thermogram of Co(II) complex showed first stage of decomposition due to loss of NCS species of quinoline moiety at 258 ∘ C with a practical weight loss of 9.66% (Calc. 10.86%). The resultant complex on further degradation gave a break at 320 ∘ C by the loss of C 8 H 6 molecule of quinoline moiety with a practical weight loss of 22.22% (Calc. 21.43%), which on further degradation gave a break at 458 ∘ C due to loss of remaining thiazole moiety (C 9 H 7 N 2 S), two chlorine atoms, and HC=N-N-NH group simultaneously with a practical weight loss of 78.02% (Calc. 76.75%). After this, the complex showed a gradual decomposition up to 697 ∘ C by the loss of remaining organic moiety. The final weight of the residue corresponds to cobalt oxide.

Zn(II)
Complex. The thermogram of Zn(II) complex showed first stage of decomposition due to loss of C 6 H 7 species of thiazole and two chlorine atoms at 270 ∘ C with a practical weight loss of 28.71% (Calc. 27.57%). This on further loss due to C 10 H 6 NS of quinoline and CH=CH molecule of thiazole moiety gave a break at 320 ∘ C with a practical weight loss of 51.58% (Calc. 50.58%). After this, the complex showed a gradual decomposition up to 351 ∘ C by the loss of remaining organic moiety. The final weight of the residue corresponds to respective metal oxide.

Powder X-Ray Diffraction Studies. The synthesized
Cu(II), Co(II), Ni(II), and Zn(II) complexes of Schiff base ligand (L) were soluble in some polar organic solvents (DMSO and DMF). The crystals that are suitable for single crystal studies are not obtained. In order to test the degree of crystallinity of the synthesized metal complexes, we obtained the powder X-ray diffraction pattern of the above complexes. The X-ray diffraction of Cu(II), Co(II), Ni(II), and Zn(II) complexes was scanned in the range 3-80 ∘ ( ) at wave length 1.54Å. In all the complexes, the trend of the curves decreases from maximum to minimum intensity indicating the amorphous nature of the complexes in the present metal-ligand formation.
The X-ray diffraction pattern of Cu(II) complex records eight reflections between the range 3-80 ∘ (2 ), which arise from diffraction of X-ray by the plane of the complex (Figure 5). The interplanar spacing ( -values) has been calculated by using Bragg's equation: = 2 sin . The unit cell calculations have been done for cubic symmetry from the all-important peaks and the methods yielded ℎ (Miller indices) unit cell parameter values and depicted in Table 5. The observed interplanar -spacing values have been compared with the calculated ones and found to be in good agreement. The ℎ 2 + 2 + 2 values are 1, 21, 25, 37, 53, 66, 81, and 92. It was observed that the presence of forbidden number 92 indicates that the Cu(II) complex may belong to hexagonal or tetragonal system. The X-ray diffraction pattern of Ni(II) complex records nine reflections between the range 3-80 ∘ (2 ), which arise from diffraction of X-ray by the plane of the complex (Figure 6). The interplanar spacing ( -values) has been calculated by using Bragg's equation: = 2 sin . The unit cell calculations have been done for cubic symmetry from the all-important peaks and the methods yielded ℎ (Miller indices) unit cell parameter values depicted in Table 6. The observed interplanar -spacing values have been compared with the calculated ones and found to be in good agreement. The ℎ 2 + 2 + 2 values are 1, 19, 23, 33, 43, 47, 72, 75, and 78. It was observed that the presence of forbidden numbers 23, 43, and 47 indicates that the Ni(II) complex may belong to hexagonal or tetragonal system.      0  10  20  30  40  50  60  70  80  90  100  110  120  130  140  150  160  170  180  190  200  210  220  230  240  250  260  270  280  290  300   3  10  20  30  40  50  60  70 70  80  90  100  110  120  130  140  150  160  170  180  190  200  210  220  230  240  250  260  270  280  290  300   3  10  20  30  40  50  60  70 Table 7.
The MIC values indicated that all the complexes exhibited promising results compared to the ligand against mentioned microorganisms, and this activity is found to be enhanced on coordination with the metal ions. This enhancement in the activity may be rationalized on the basis that ligands mainly possess C=N bond. The enhanced activity of the complexes over the ligand can be explained on the basis of chelation theory [50,51]. It is observed that, in a complex, the positive charge of the metal is partially shared with the donor atoms present in the ligand, and there may be -electron delocalization over the whole chelate [52]. This increases the lipophilic character of the metal chelate and favors its permeation through the lipoid layer of the bacterial membranes. The heterocyclic Schiff bases with different functional groups have greater tendency to interact with nucleoside bases even after complexation with metal ion or with the essential metal ions present in the biosystem can act as a promising bactericides because they always tend to interact with enzymatic functional groups in order to achieve higher coordination numbers [53]. There are also other factors which increase the activity, namely, solubility, conductivity, and bond length between the metal and the ligand.

DNA Cleavage
Activity. The interaction of plasmid pBR322 DNA with newly synthesized ligand L and its Cu(II), Co(II), Ni(II), and Zn(II) complexes was studied using agarose gel electrophoresis method. The gel picture showing the cleavage of plasmid pBR322 DNA is depicted in Figure 7. The characterization of DNA recognition by transition metal complex has been aided by the DNA cleavage chemistry associated with redox-active or photo activated metal complexes [54]. The electrophoresis analysis clearly revealed that the ligand and its metal complexes have acted on DNA because of a difference in molecular weight between the control and the treated DNA samples. The difference was observed in the bands of lanes of complexes compared with the control DNA of pBR322 due to the relaxation of circular DNA into linear form. This shows that the control DNA alone does not show any apparent cleavage, whereas the ligand and its metal complexes do show. In the present study, the Ethedium bromide (EtBr) stained banding pattern of plasmid pBR322 DNA was tested with newly synthesized ligand and its metal complexes. In the present case, the ligand and its Cu(II), Co(II), and Zn(II) complex showed complete cleavage of super coiled DNA and the Ni(II) complex showed

In Vitro Cytotoxicity.
All the synthesized compounds were screened for their cytotoxicity (brine shrimp bioassay) using the protocol of Meyer et al. [38]. From the data recorded in Table 8, it is evident that all the newly synthesized metal complexes exhibited potent activity when compared to the free ligand. The Co(II) and Ni(II) complexes displayed significant potent cytotoxic activity as LD 50

Conclusions
The newly synthesized Schiff base ligand N-(4-phenylthiazol-2yl)-2-((2-thiaxo-1,2-dihydroquinolin-3-yl)methylene)hydrazinecarboxamide behaves as tridentate ONS donor and forms the complexes of type [ML(Cl) 2 ]. With the help of various physicochemical and spectroscopic methods such as IR, 1 H NMR, UV-Visible, and ESR, the square pyramidal geometries of the Cu(II), Co(II), Ni(II), and Zn(II) complexes have been proposed (Figure 8). The newly synthesized metal complexes showed good antimicrobial activity when compared to the free ligand. The DNA cleavage activity of all the synthesized compounds showed the cleavage of plasmid DNA pBR 322 and the cytotoxicities of Co(II) and Ni(II) complexes indicate potent cytotoxic agents that might become potent anticancer agent in clinical trials.