| Literature DB >> 34093696 |
James T P Matshwele1,2, Sebusi Odisitse1, Daphne Mapolelo3, Melvin Leteane3, Lebogang G Julius3, David O Nkwe4, Florence Nareetsile3.
Abstract
A new hexadentate 2-picolyl-polypyridyl-based ligand (Entities:
Year: 2021 PMID: 34093696 PMCID: PMC8163554 DOI: 10.1155/2021/5563209
Source DB: PubMed Journal: Bioinorg Chem Appl Impact factor: 7.778
Figure 1Synthetic routes for the ligand 2BUT (1) and ruthenium complexes: [Ru2(2BUT)(DMF)2(DPA)](BH4)4(3) and [Ru2(2BUT)(Cl)6] (4).
FTIR assignments for ligands and complexes.
| Compound | C-O (cm−1) | Ar-N (cm−1) | C=C (cm−1) | C-H (cm−1) | N-H (cm−1) |
|---|---|---|---|---|---|
| DPA | — | 1477 | 1529 | 3019 | 3179–3253 |
| 2BUT | 1230 | 1476 | 1508 | 2926 | — |
| [Ru2(2BUT)(DMF)2(DPA)](BH4)4 | 1244 | 1434 | 1504 | 2961 | — |
| [Ru2(2BUT)(Cl6] | 1245 | 1435 | 1508 | 2948 | — |
The vibrational spectroscopic data indicated all the functional groups for the ligands and the complexes. Also, it was seen that the ligand functional groups bound by the metal demonstrated a shift in the vibrational frequency, and this indicated that there is coordination.
Figure 2Ruthenium pulling electrons from the pyridyl nitrogen, therefore, reducing the electron density of the C=N bond together with the vibrational frequency of this bond as per Hooke's law.
Complexes and their associated electronic spectroscopy bands.
| Transitions | [Ru2(2BUT)(DMF)2(DPA)](BH4)4 | [Ru2(2BUT)(Cl)6] |
|---|---|---|
|
| < | < |
|
|
|
|
CT: charge transfer bands. The electronic spectral data indicated the complexes are low spin Ru(III) d and Ru(II) d complexes. Also, the molar absorptivity of the complexes' bands demonstrates that they are their true assigned transitions.
Figure 3Suspected weak Jahn–Teller distortions on complex 4 Note. The diagram is not to scale. The diagram demonstrates that the e orbitals transform under the a′ symmetry label while the t2 orbitals transform under the a′, a″, and a″; this observation suggests the weak Jahn–Teller distortion. This explains why the observed effective magnetic moment was a bit lower than the expected magnetic moment which is because of the unpaired electron not having orbital contribution from interacting with the other orbitals, thus having no effect on the magnetic moment.
Experimental and calculated elemental analysis of complexes.
| Compound molecular formula (according to EA data) | Experimental | Calculated |
|---|---|---|
| C: H: N | C: H: N | |
| [Ru2(2BUT)(DMF)2(DPA)](BH4)4] •0.9H2O | 56.89 : 6.33 : 13.59 | 56.5 : 6.45 : 13.98 |
| [Ru2(2BUT)(Cl)6] •0.6H2O | 45.66 : 3.70 : 7.50 | 45.26 : 3.9 : 7.92 |
Analytical data indicate the complexes only had impurity of water. The data also showed that the complexes' empirical formula is similar to the calculated data with very low differences.
Experimental and calculated mass analysis of complexes.
| Compounds | Adduct | Experimental | Calculated |
|---|---|---|---|
| C40H41N6O2 | [M+H]+ | 637.3412 | 637.8075 |
| C66H72N14O4Ru2 | [M+2Na-H]+ | 1372.7879 | 1373.3612 |
| C41H43Cl6N6O2Ru2 | [M+K]+ | 1104.5452 | 1103.9332 |
The mass spectrometric data indicate successful synthesis of the compounds. All the compounds were run on a positive ion mode with molecular ion peaks being observed with proton and metal adducts.
MIC of all active compounds.
| Microbe | Li[Ru(Cl)4(DPA) | [Ru2(2BUT)(DMF)2(DPA)](BH4)4] | [Ru2(2BUT)(Cl)6] | 2BUT | DPA (mg/mL) |
|---|---|---|---|---|---|
|
| 5.00 | 1.88 | 7.50 | 0.03 | 15.00 |
| MRSA | 0 | 2.50 | 0 | 0 | 15.00 |
|
| 10.00 | 7.50 | 10.00 | 20.00 | 1.88 |
| MDR | 0 | 0 | 0 | 0 | 0 |
Note: 0: not active. The compounds were assayed for their MIC towards S. aureus, K. pneumoniae, MRSA, and MDR K. pneumoniae. The assay revealed all complexes to display activity towards all non-drug-resistant bacteria. Only [Ru2(2BUT)(DMF)2(DPA)](BH4)4] complex displayed activity on MRSA together with the ligands. However, no compound indicated activity towards MDR K. pneumoniae. After this, the complexes were assayed for their bacterial growth inhibition using disc diffusion assay.
Zones of inhibition of all compounds.
| Microbe | Li[Ru(Cl)4(DPA) | [Ru2(2BUT)(DMF)2(DPA)](BH4)4] | [Ru2(2BUT)(Cl)6] | 2BUT | DPA (mm) |
|---|---|---|---|---|---|
|
| 9 | 8 | 8 | 8 | 9 |
| MRSA | 0 | 8 | 0 | 0 | 7 |
|
| 7 | 7 | 7 | 7 | 8 |
| MDR | 0 | 0 | 0 | 0 | 0 |
The disc diffusion assay was used to the ligands and complexes for their activity towards the three bacterial organisms S. aureus, K. pneumoniae, MRSA, and MDR K. pneumoniae. This was done after their MIC values were assayed to assess the extent to which the compounds inhibit the growth of the bacteria. Just as in the MIC assay, all the compounds indicated activity towards all non-drug-resistant bacteria while [Ru2(2BUT)(DMF)2(DPA)](BH4)4], [Ru2(2BUT)(Cl)6], 2BUT, and DPA had activity towards MRSA. No compounds showed activity on MDR K. pneumoniae.
Figure 4The mononuclear ruthenium (II/III) complexes reported in our previous work [6]. The difference with these analogues is that the complexes (3 and 4) in this paper are bridged by a four-member aliphatic chain. The chain in the mononuclear complexes does not connect to anything.
Figure 5DNA cleavage analysis on 0.8% agarose gel. Lane L, 1 kb ladder; C, control DNA; 1, complex 2; 3, BUT; 4, DPA; 6, complex 4; 8, complex 3. The gel indicates that all the complexes had DNA nuclease activity while the ligands did not cleave nor nuclease the DNA.