Self-Assembly and Multifaceted Bioactivity of a Silver(I) Quinolinate Coordination Polymer

Coordination polymers have emerged as a new class of potent biologically active agents due to a variety of important characteristics such as the presence of bioactive metal centers and linkers, low toxicity, stability, tailorable structures, and bioavailability. The research on intermediate metabolites has also been explored with implications toward the development of selective anticancer, antimicrobial, and antiviral therapeutic strategies. In particular, quinolinic acid (H2quin) is a recognized metabolite in kynurenine pathway and potent neurotoxic molecule, which has been selected in this study as a bioactive building block for assembling a new silver(I) coordination polymer, [Ag(Hquin)(μ-PTA)]n·H2O (1). This product has been prepared from silver oxide, H2quin, and 1,3,5-triaza-7-phosphaadamantane (PTA), and fully characterized by standard methods including single-crystal X-ray diffraction. Compound 1 has revealed distinctive bioactive features, namely (i) a remarkable antiviral activity against herpes simplex virus type 1 (HSV-1) and adenovirus 36 (Ad-36), (ii) a significant antibacterial activity against clinically important bacteria (Staphylococcus aureus, Escherichia coli, and Pseudomonas aeruginosa), and (iii) a selective cytotoxicity against HeLa (human cervix carcinoma) cell line. The present work widens a growing family of bioactive coordination polymers with potent antiviral, antibacterial, and antiproliferative activity.


■ INTRODUCTION
Infectious diseases and particularly those of a viral genesis are responsible for igniting most of the global pandemics. Influenza, smallpox, rabies, and Ebola viruses have been harvesting a death toll for centuries and contributed to the deaths of millions of people around the globe. 1−5 Other infectious agents such as herpes simplex virus (HSV) and human coronaviruses and adenoviruses are ubiquitous and cause numerous diseases, including recurrent keratitis, mild and severe respiratory tract infections, encephalitis, ocular and gastrointestinal tract disorders, and neonatal HSV infections. 1−5 Despite a huge progress in vaccination, medical technologies, and therapies, treatment of these infections is often just symptomatic without any approved antiviral treatment protocols. Even now, we are defenseless facing the COVID-19 outbreak due to limited antiviral treatment options. 1−3 Therefore, the identification and development of new antiviral chemicals and treatment approaches is a subject of paramount importance for modern society.
Coordination compounds 6−8 and especially coordination polymers (CPs) 2,9−12 built from biocidal metal nodes and/or bioactive organic ligands represent a promising route for developing new metal-based antiviral materials and metallodrugs. Because of some structural and physicochemical fractures, CPs can exhibit an interesting therapeutic outcome with a potential synergic effect of its various components. An assembly of biologically active metal ions and biorelevant organic pillars (metabolic intermediates) into metal−organic network provides an appealing way for designing new bioactive materials. 8−12 A particularly interesting example of such a biorelevant pillar concerns quinolinic acid (H 2 quin, pyridine-2,3-dicarboxylic acid), which is the main downstream metabolite in the kynurenine pathways in mammals and in aspartate pathways in bacteria and plants. 13 An appropriate level of this bioligand in cerebrospinal fluids is crucial for correct functioning of the nervous system and preventing the development of multiple sclerosis Huntington's and Alzheimer's diseases. On the other hand, perturbations in kynurenine pathways involving a production of H 2 quin and alterations of its concentration are observed in specific neoplastic and viral diseases. 13 −21 In the inflammatory changed cellular microenvironment, quinolinic acid can potentially exert a poisonous effect on the abnormal cancer cells and viruses initiating their programed death. This property of H 2 quin can especially be considered for developing alternative anticancer and antiviral therapies. 14−21 Moreover, the complexation of quinolinic acid with bioactive metals such as silver can significantly reduce the overall toxicity of H 2 quin on not-perturbated cells, leading to an enhanced bioactivity of the obtained coordination compounds. However, parameters such as poor light and thermal stability, limited shelf life, and/or inadequate solubility and stability in the biological medium (e.g., PBS: phosphate buffered saline) pose obstacles on the development of new silver(I) coordination compounds and their medicinal applications. 22 −26 In contrast to discrete metal complexes, some silver(I)-based coordination polymers represent improved stability and release properties, thus also gaining an impetus for applications in anticancer and antimicrobial treatment. 27−29 In particular, water-soluble cagelike aminophosphine ligands such as PTA (1,3,5-triaza-7-phosphaadamantane) and its various derivatives constitute an appealing class of linkers for designing bioactive coordination polymers. 30−32 Notable examples of such silver-(I)-based compounds with potent and diverse bioactivity were reported in our previous studies. 33−40 Within this context and following our major goal in exploring the chemistry and biofunctional applications of silver−PTA coordination polymers, herein we report the self-assembly synthesis, characterization, spectroscopic and structural features, and antiviral, antimicrobial, and antiproliferative properties of a new silver(I) coordination polymer derived from PTA and quinolinic acid, [Ag(Hquin)(μ-PTA)] n ·H 2 O (1).

Synthesis.
A new aqua-soluble silver(I) CP [Ag(Hquin)(μ-PTA)] n ·H 2 O (1) was self-assembled by using a mixed-ligand synthetic approach (Scheme 1), namely by reacting silver(I) oxide, quinolinic acid (H 2 quin), and 1,3,5-triaza-7-phosphaadamantane (PTA) in water/methanol medium at ∼25°C. The product was isolated in a microcrystalline form and characterized by standard methods, including the single-crystal and powder X-ray diffraction analyses. The latter shows a good match between the experimental and simulated patterns, thus confirming a phase purity of the obtained product ( Figure S1, Supporting Information).
The IR spectrum of 1 indicates the characteristic ν as (COO) and ν s (COO) bands of carboxylate groups in the 1700−1365 cm −1 region ( Figure S2). The Δν value of 229 (Δν refers to a calculated frequency difference between ν as and ν s ) is in good agreement with the data observed for unidentate carboxylate ligands. 41 There are also typical ν(C−X) (X = P, N) bands at 1400−500 cm −1 associated with the coordinated PTA moieties. The 1 H NMR spectrum of 1 in D 2 O exhibits a set of signals expected for the aromatic protons of quinolinic acid along with the methylene protons of PTA ligands ( Figure S3). The 31 P{ 1 H} NMR spectrum reveals a broad singlet at δ − 75.4 that is consistent with the presence of the coordinated PTA in solution ( Figure S4).
Compound 1 is air and light stable in the solid state. It is also stable in the D 2 O solution for at least several days. The solution stability of 1 (25°C, pD = 6.25, D 2 O) was monitored over time intervals of 0, 1, and 7 days by 31 P{ 1 H} and 1 H NMR spectroscopy, indicating no appreciable spectral changes under these conditions ( Figures S3−S6). However, 1 is less stable in DMSO-d 6 and slowly decomposes, as attested by an evolving PTAO peak in the 31 P{ 1 H}NMR spectrum after 1 day ( Figure S7). The observed molar conductivities of 1 measured in H 2 O and DMSO solutions are 14.35 and 2.07 mS m 2 mol −1 , respectively, and thereby indicate its electrolyte nature.
The ESI-MS data ( Figures S8 and S9) reveled the presence in solution of two characteristic cationic species, namely [Ag(PTA) 2 ] + and [Ag 2 (PTA) 2 (Hquin)] + . Both fragments exhibit high intensity and expected isotopic distribution. On the basis of these observations, we can conclude that the 1D polymeric chain structure of 1 is maintained in solid state, while in solution the compound dissociates into stable lower mass fragments. This is also in agreement with the data observed for other reported [Ag(PTA)(carboxylate)] n coordination polymers. 37,38 Crystal Structure. The structure of 1 comprises a silver(I) center, a μ-PTA linker, a terminal Hquin − ligand, and a crystallization water molecule (Figure 1a). The Ag1 center is four-coordinate and is bound by the N and P donors from two μ-PTA moieties and a pair of N and O atoms from the Hquin − ligand, resulting in a distorted tetrahedral {AgPN 2 O} environment. The μ-PTA linkers combine two Ag1 centers into a linear 1D coordination polymer chain with a shortest Ag···Ag separation of 6.8252(3) Å that is equal to the b unit cell parameter (Figure 1b). From a topological perspective, such a chain can be classified within a 2C1 type (Figure 1c) 35,37,38 Antiviral Properties. Both compounds 1 and H 2 quin lower the enveloped HSV virus titer by 6.25 and 5.50 log, respectively (Table 1), indicating a total viral killing effect. This effect is up to 2 orders of magnitude higher if compared to acyclovir (4 log reduction, equivalent to ≥99.99% inactivation), which is a common drug to treat herpes. In the case of nonenveloped Ad-36 virus, a decrease of 4 log in virus titer was observed when using 1 and H 2 quin. Given the absence of officially registered drugs against adenoviruses, [Co(NH 3 ) 6 ]Cl 3 was selected as a positive control on account of being the most promising compound in the therapy of adenoviral infections. 4 However, under the influence of [Co(NH 3 ) 6 ]Cl 3 , the virus level decreases only by 3 log (99.9% reduction). Although quinolinic acid is a neurotoxin because of its highly virucidal properties, it seems appropriate to consider the use of H 2 quin to treat viral infections.
It is also interesting to note that a combination of silver ions with H 2 quin in 1 results in even superior activity against HSV. Because 1 can inactivate the enveloped herpes virus, it may also be effective against other enveloped viruses, such as orthomyxoviridae (human and animal influenza viruses), coronaviridae (including SARS-CoV), flaviviridae, and poxviridae as well as blood-borne viruses including HBV, HCV, and HIV. Moreover, the virucidal efficacy of 1 against the Scheme 1. Simplified Representation for the Self-Assembly Synthesis of 1 Inorganic Chemistry pubs.acs.org/IC Article nonenveloped adenovirus, which is more resistant to disinfection than the enveloped viruses, makes this compound promising as a potential drug or disinfectant. Hence, an approach to treat viral infections with H 2 quin derivatives is completely innovative. So far, the role of quinolinate phoshoribosyltransferase (QPRT), an enzyme that catalyzes the formation of nicotinate mononucleotide from 5-phosphoribosyl 1-pyrophosphate (PRPP) and quinolinic acid, has been considered. 42 Wang et al. described QPRT as an antiviral host factor against virus infection in the course of hepatitis C. 43 H 2 quin along with 3-HK (3-hydroxyanthranilic acid), 3-HAA (3-hydroxyanthranilic acid), or KYNA (kynurenic acid) are intermediate products of the kynurenine pathway. Interestingly, the concentration of H 2 quin increases with sustained activation of the immune system. However, no clear explanation for this correlation has been found so far. 44 It is undeniable that higher levels of H 2 quin appear as a result of a viral infection, and at the same time, we have proven in vitro that H 2 quin is virucidal. This may indicate that an increased concentration of H 2 quin is a form of defense against the pathogen.
Antibacterial Activity. Antibacterial properties of 1 were evaluated by using strains of three species representing clinically important bacteria, namely Staphylococcus aureus, Escherichia coli, and Pseudomonas aeruginosa. All the mentioned species were reported as expressing increasing resistance to clinically established antimicrobial therapies, 9,45,46 though the tested strains were not characterized as resistant or multiresistant. The normalized MIC values obtained for compound 1 ( Table 2) suggest its superior antimicrobial activity in comparison to AgNO 3 that was used as a reference antibacterial. Gram-negative bacteria (E. coli, P. aeruginosa) revealed a higher susceptibility to 1 if compared to a Gramnegative one (S. aureus). However, even in the latter case, the activity of 1 is almost 2-fold superior vs silver(I) nitrate. None of the ligands (H 2 quin, PTA) showed antimicrobial activity at a maximum concentration tested. This is also in agreement with prior data for PTA (MIC > 600 μg mL −1 ) 37 and H 2 quin (MIC > 1024 μg mL −1 ) 47 established for the same species of bacteria. The MIC values shown by 1 are comparable to those reported for other Ag-based CPs. 33−40 On the basis of the aforementioned findings, we can hypothesize that the antimicrobial properties of 1 are mainly associated with the action of Ag + ions, which might be strongly influenced by the type of coordination environment present and binding affinity of O-, N-, and P-donor ligands. However, further studies are   Inorganic Chemistry pubs.acs.org/IC Article required to shed light on the actual mechanism of antimicrobial action of compound 1. Cytotoxic Activity. The cytotoxicity effect of compound 1 against NHDF (normal human dermal fibroblasts), A549 (human lung carcinoma), and HeLa (human cervix carcinoma) cell lines was investigated by using MTT assay along with cisplatin and AgNO 3 as positive controls. After incubation period (72 h), a half-maximal inhibitory concentration (IC 50 ) was determined ( Table 3). The obtained data revealed a highly selective cytotoxic action of 1 against HeLa cells (IC 50 = 68.6 ± 7 μM) and its inactivity against human lung carcinoma (A549). The NHDF, used as a normal body tissue model, was significantly resistant when treated with 1. A lower cytotoxicity of 1 (93.8 ± 10.5 μM) in comparison with cisplatin (16.7 ± 2 μM) for normal body cell line shows that 1 might be a promising compound in anticancer treatment because its cytotoxicity against HeLa is higher than in normal body cell culture and is still lower than the same parameter of cisplatin (Table 3). This observation also proves the selective activity of this compound against various types of neoplasms. The different etiology and pathogenesis of human cervix carcinoma and human lung carcinoma probably will be helpful in explaining this phenomenon (inactivity against A549). A resistance of the latter cell for cisplatin and its potential sensitization ability represent a difficulty for in vitro studies, 48 similarly to human lung carcinoma resistance for chemotherapy. 49, 50 The lack of blood−brain barrier crossing together with the local administration of 1 can give promising results for further exploration, since there is low toxicity against not only central nervous system cells (quinolinic acid as neurotoxin) but also unaffected body tissues. Moreover, Walczak 44 suggested that an increase of the quinolinic acid concentration in tissues can be the result of the immune system activation and response against pathogen. Hence, it can be hypothesized that a specific coordination of quinolinate ligand by silver ion plays an important role in the cytotoxicity of 1.
Antioxidant Properties. The antioxidant behavior of 1 was investigated in the peroxidation of LinMe (methyl linoleate) in the micellar system; plots of oxygen uptake are shown in Figure 2. Autoxidation was initiated by addition of 10 mM water-soluble azo-initiator, 2,2′-azobis(2-amidinopropane) dihydrochloride (ABAP). We monitored the rates of peroxidation in the presence of 1, PTA, and H 2 quin ( Figure  2 and Figures S10−S13). The kinetic plots are substantially the same, which indicates that the tested compounds are kinetically neutral during the peroxidation of micelles initiated with ABAP, thus not exerting antioxidant or prooxidant activity.
Interaction of 1 with Human Serum Albumin. Human serum albumin (HSA) is one of the most important blood components that plays a main role in the binding and transport of numerous exo-and endogenous ligands such as fatty acids, hormones, toxic metabolites, metals, and drugs. Analysis of the protein interactions with drugs is very important from the pharmacological point of view. To determine the binding parameters between 1 and HSA, mode of action, and structural changes, we used circular dichroism (CD) and fluorescence spectroscopy techniques.
The fluorescence emission spectra of the HSA−1 system are shown in Figure 3. After excitation at 280 nm, human serum albumin reveals a strong fluorescence signal at 334.5 nm. Titration with compound 1 causes a decline of fluorescence signal intensity without a significant shift of the emission peak. This indicates that the interaction between HSA and 1 occurs, and there is no alteration of the microenvironment around the HAS's chromophore.
The Stern−Volmer equation is a universal tool to analyze the fluorescence quenching parameters of proteins. On the basis of eqs 1 and 2, we determined the mechanism and fluorescence quenching constants of the HSA−1 system.    (1) where F 0 and F are the relative fluorescence intensities of protein in the absence and presence of a quencher, respectively, K SV is the Stern−Volmer quenching constant, K q is the quenching rate constant, [Q] is the quencher concentration, and τ 0 is the average lifetime of a biomolecule without quencher (for HSA, τ 0 is 10 −8 s). The corresponding quenching constants K SV for the interaction between HSA and 1 are 5.15 × 10 3 and 5.42 × 10 3 M −1 at 310 and 298 K, respectively. It is clear that the K SV values decrease when temperature increases, and therefore we can conclude a static quenching fluorescence of albumin by 1 (Figure 4). This also reveals the formation of a nonfluorescent complex between 1 and HSA. The reverse effect is generally observed for dynamic quenching processes.
All calculated binding parameters are collected in Table S1. The number of binding sites and association constants between HSA and 1 were calculated based on eq 3. 51 where F 0 and F are the fluorescence intensities in the absence and presence of the quencher, respectively, K a is the binding constant, n is the number of binding sites, and [Q] is the total concentration of the quencher. The data collected in Table S1 and Figure 4 (inset) show that the binding constant values (K a ) decrease with an increase in temperature when the protein interacts with 1. This relationship indicates that 1 forms an unstable complex with the protein, which also undergoes a partial decomposition at higher temperatures. The N value approximates to 1, indicating that only one binding site in protein is accessible to compound 1. Under physiological conditions the binding constant of the system is 1.73 × 10 3 M −1 . It points a rather weak affinity of 1 to HSA, which is comparable with the K a value of the HSA−cisplatin system (K a = 8.52 × 10 2 M −1 ) and is lower in comparison to other metal complexes. 52−55 The Ross−Subramanian theory and eqs 4−6 were used to determine the acting forces and thermodynamic parameters in the HSA−1 system: In these equations, ΔH°, ΔS°, and ΔG°are the enthalpy, entropy, and free energy, respectively, K a is the binding constant at the corresponding temperature T [K], and R is the gas constant.
Usually four types of the binding forces between small molecules and biological macromolecules can be present in the interaction. These include electrostatic forces, hydrophobic and ionic interactions, and van der Waals forces as well as hydrogen bonds. Nevertheless, the contribution of the metal ion in the interaction cannot be excluded in the case of coordination compounds. Moreover, the hydrophobic forces may increase ΔH°and ΔS°. The hydrogen bonds and van der Waals interactions may decrease them, whereas the electrostatic forces usually make H°≈ 0 and S°> 0. In this context, both negative values of ΔH°and ΔS°indicate that intermolecular interactions play an important role in the binding process of 1 with HSA. Moreover, the negative values of ΔG°show that spontaneous processes occur in this system.
We used the circular dichroism technique to determine the effect of 1 on the protein secondary structure. In the intrinsic region (180−250 nm), the CD spectrum of the protein is characterized by two negative bands ( Figure S14). A more intense band at 209 nm and a broad and weak band around 221 nm can be assigned to α-helical structure and π → π*/n → π* transitions for the peptide bond, respectively. 56 Under the experimental conditions, 1 does not generate the CD signal, but as evident from Figure S14, the presence of the silver compound has an effect on the secondary structure of the albumin, causing some changes in the intensity of the protein negative band at 209 nm. The α-helical content of free HSA at 209 nm is equal to 67.23%. A decrease in α-helicity to ∼65.30% was observed after addition of 1 in the molar ratio of [HSA]/[Ag] = 1:10 or 1:20. This indicates that the binding of the ligand with the protein destroys a hydrogen binding network of HSA.
The changes in the protein secondary structure result from the interaction between 1 and HSA. The band intensities of HSA at 209 and 221 nm decreased with the negative Cotton effect through the binding of 1 without causing significant shifts of the peaks, thus clearly indicating that the compound induced a slight decrease in the α-helical structure content of the protein. Reagents concentrations were properly low, and any concentration effect can be excluded. Moreover, no changes in the negative bands at 209 and 221 nm on increasing the concentration of 1 were observed. From these results, it is evident that the effect of 1 on HSA caused secondary structural changes to the protein with a slight loss of the helical stability.  A multifaceted antiviral, antibacterial, and cytotoxicity behavior of 1 was investigated in detail, demonstrating its high antimicrobial and antiproliferative potential. In particular, antiviral tests revealed an unprecedented ability of 1 to kill herpes simplex virus type 1 (HSV-1) and adenovirus 36 (Ad-36) with a low toxicity to normal cells. Taking into account the antioxidant measurements, we can conclude that compound 1 is kinetically neutral, while its cytotoxic activity is not a result of its prooxidant properties.
Because compound 1 can inactivate enveloped herpes virus, its efficacy against other enveloped viruses can be envisaged, including such families as orthomyxoviridae (human and animal influenza viruses), coronaviridae, flaviviridae, poxviridae, and blood-borne viruses (e.g., HBV, HCV, and HIV). Moreover, the virucidal efficacy of the CP 1 against the nonenveloped adenovirus, which is more resistant to disinfection than the enveloped viruses, makes this compound promising for consideration as a potential drug or disinfectant. In further research, it would be particularly interesting to investigate a mechanism that would explain the action of 1 as a virucidal agent.
The interaction of 1 with human serum albumin was also investigated by using fluorescence spectroscopy and CD methods. The results prove that the compound interacts with human serum albumin with moderate affinity and forms an unstable complex with the protein. Furthermore, the CD analysis demonstrates that 1 exerts some effect on the protein secondary structure and reduces the α-helix content.
Apart from widening the family of PTA-driven coordination polymers, 30−32 the present work also provides an important contribution to better understanding of different bioactivity features of such compounds, also revealing their significant potential toward development of novel antiviral and antimicrobial agents. These research lines deserve further development and extension to various combinations of silver centers with other types of carboxylic acid metabolites.

■ EXPERIMENTAL SECTION
Chemicals. All standard chemicals and solvents were obtained from commercial suppliers. Human serum albumin was acquired from Sigma-Aldrich (A3782, ≥99% purity). The protein stock solution with a concentration of 2 μM was prepared in PBS buffer (pH = 7.40). A stock solution of 1 (833 μM) was prepared by dissolving the compound in demineralized water. Protein concentration was calculated by using ε HSA = 42864 M −1 cm −1 at 280 nm. 57 PTA (1,3,5-triaza-7-phosphaadamantane) was synthesized according to a published method. 58,59 Analytical Methods. Bruker IFS 1113v (Germany) or BIO-RAD FTS3000MX (BIO-RAD, France) instruments (range 4000−400 cm −1 ) were used to measure the IR spectra (abbreviations: vs, very strong; s, strong; m, medium; w, weak; br, broad). Solution NMR spectra were recorded in D 2 O and DMSO-d 6 by using a Bruker 500/ 600 AMX spectrometer (Bruker BioSpin MRI GmbH, Germany) at ambient temperature (abbreviations: s, singlet; d, doublet; t, triplet, br, broad). 1 H chemical shifts (δ) are expressed in ppm relative to Si(Me) 4 , while δ( 31 P) shifts are relative to an external H 3 PO 4 (85% aqueous solution). ESI-MS(±) spectra were run on a Bruker MicroTOF-Q mass spectrometer with an ESI source by using ∼10 −3 M solutions of 1 in H 2 O/MeOH. The elemental analyzer Vario ELCube (Elementar Analysen systeme GmbH, Germany) was used for the determination of C, H, and N contents (Laboratory of Elemental Analysis at Faculty of Chemistry, University of Wrocław).
Synthesis of [Ag(Hquin)(μ-PTA)] n ·H 2 O (1). Silver(I) oxide (0.1 mmol, 23 mg), quinolinic acid (H 2 quin, 0.377 mmol, 63 mg), and PTA (0.2 mmol, 31 mg) were combined in a CH 3 CN/H 2 O (5 mL/5 mL) solution and stirred in air for 1 h to produce a white suspension. This was dissolved by a dropwise addition of an aqueous 1 M solution of NH 3 (until pH = 8; ∼0.8 mL). The obtained solution was filtered off, and the filtrate was left in a vial to slowly evaporate in air at room temperature. Colorless crystals (including those of X-ray quality) were formed in 1 week. These were then collected and washed with water and methanol and dried in air to give 1 in 40% yield, based on Ag 2 O. Compound 1 is soluble in H 2 O (S 25°≈ 0.5 mg mL −1 ) and DMSO (S 25°≈ 0.6 mg mL −1 ). Elemental analysis: Calculated for C 13  Stability Tests. In this procedure, compound 1 was introduced into a NMR tube and dissolved in 0.6 mL of D 2 O or DMSO-d 6 in air. The 31 P{ 1 H} and 1 H NMR spectra were monitored for several days at room temperature ( Figures S3−S7).
X-ray Crystallography. Single crystal data collection was performed on a Xcalibur diffractometer (Oxford Diffraction) with a Sapphire2 CCD detector, equipped with an Oxford Cryosystems open-flow nitrogen cryostat, by using ω-scan and a graphitemonochromated Mo Kα (λ = 0.71073 Å) radiation. Cell refinement, data reduction, analysis, and absorption correction were performed with CrysAlis PRO (Rigaku Oxford Diffraction) software. 60 The structure was solved by direct methods with SHELXT-2014/5 and refined with full-matrix least-squares techniques on F 2 with SHELXL-2018/3. 61,62 Direct solution in the correct space group P2 1 /n was unsuccessful. The structure was solved in the space group P n , and then the symmetry was transformed to P2 1 /n by using the ADDSYM feature of the PLATON program. 63,64 The H3 atom on the COOH functionality was placed on O3 atom on the basis of the C−O carboxylate distances. The O3−H3 distance was restrained to 0.97 Å. The O−H bond distances in the water molecule O1W were restrained to 0.85 Å and H1···H2 separation to 1.38 Å. All other hydrogen atoms were placed at calculated positions and refined by using the model with U iso = 1.2U eq .
Crystal Data for 1. Cytotoxicity Assay. The scheme of cytotoxicity assay consisted in enzymatic reduction of soluble tetrazolium salt in metabolically active cells into insoluble purple formazan (MTT test). The concentration of tetrazolium dye was measured colorimetrically by using a spectrophotometric microplate reader (Multiscan Go, Thermo Fisher, USA). The cell cultures were inserted into 96-well plates (Eppendorf, Germany) in a concentration of 105 cells per well. Compound 1 was dissolved in culture medium and diluted to reach the concentration of 100, 50, 20, 10, 5, 2, and 1 μg/mL and then added to cell cultures and incubated in standard conditions (37°C with a constant flow of 5% CO 2 ) for 72 h. After a proper incubation period, the cytotoxicity of 1 was evaluated by using MTT assay (Sigma, Germany). In the MTT procedure, 20 μL of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (1 mg/mL) was added to each well and subsequently incubated for 4 h at 37°C. The lysis buffer (80 μL) provoked a destruction of cell membranes, which was monitored by spectrophotometric analysis measuring the optical density (OD) of solution. The following formula was used to estimate the viability of investigated cell cultures: cell viability (%) = (average OD for test group/average OD for control group) × 100. The untreated cells were used as a negative control and doxorubicin (a cytostatic routinely used in therapy) was applied as a positive control. 65 Antiviral Assay. . This standard describes a quantitative suspension test for the evaluation of virucidal activity in the medical area (phase 2/step 1), mixing 1 part by volume of test virus suspension (0.1 mL of 1 × 10 8 TCID 50 Ad-36 virus or HSV), 1 part by volume of interfering substance (0.1 mL of PBS), and 8 parts by volume of disinfectant (investigated compounds in a concentration of 10 mg/mL). At specified contact times (60 min), aliquots were taken, and serial dilutions up to 10 −8 of each mixture were prepared. In eight repeats, 50 μL of each dilution was added to the microtiter plate containing a monolayer of confluent A549 or HeLa cells. The plates were observed daily for up to 4 days for the development of viral cytopathic effect by using an inverted microscope (Olympus Corp., Germany; Axio Observer, Carl Zeiss MicroImaging GmbH). Additionally, according to the same procedure, acyclovir (against HSV) or [Co(NH 3 ) 6 ]Cl 3 (against Ad36) was tested as a control. Then, residual infectivity was determined. According to PN-EN 14476, a disinfectant is considered as having virucidal effectiveness if within the recommended exposure time the titer is reduced by ≥4 log 10 steps (inactivation ≥99.99%).
Antibacterial Studies. The antibacterial activity of 1 and ligands (PTA and H 2 quin) was evaluated by using the method of serial dilutions according to Grove and Randall. 66−68 Two reference strains, Staphylococcus aureus PCM 2054 (= ATCC 25923) and Escherichia coli PCM 2057 (= ATCC 25922), were obtained from the Polish Collection of Microorganisms of the Institute of Immunology and Experimental Therapy in Wroclaw. A clinical strain of Pseudomonas aeruginosa of veterinary origin, identified as previously described, was also used. 37 Microbial inocula were prepared by using an overnight culture of each strain. These were diluted (1:1000) by using an antibiotic broth (AB). Working dilutions of the tested substances in AB were prepared in 48-well plates to achieve the final concentrations of the substances ([μg mL −1 ]: 60,50,40,30,20,10,9,8,7, 6, 5, 4, 3, 2, and 1) after combining 0.9 mL of the working dilution and 0.1 mL of microbial inoculum. Broth sterility and growth controls were performed. The inoculated 48-well plates were incubated at 37°C for 24 h. The minimum inhibitory concentration (MIC, μg mL −1 ) was defined as the lowest concentration of the compound that fully inhibited the growth of bacteria. For comparison, the MIC values were normalized for the molar content of silver and are represented in a nmol mL −1 scale. PTA and H 2 quin show no antimicrobial activity at the maximum concentration tested.
Preparation of Micelles. Micelles were prepared by using a previously described procedure. 69 To a glass test tube, 10 μL of methyl linoleate (LinMe) and 5.5 mL of 16 mM Triton X-100 were added and shaken on Vortex for 1 min. Next, 5.5 mL of buffer (pH 7.0) was introduced, and the mixture was shaken again for 1 min. The final concentration of lipid and surfactant in the micellar system was 2.74 mM LinMe and 8 mM Triton X-100. Buffer composition: pH 7.0 phosphate (25 mM KH 2 PO 4 ; 14.5 mM NaOH).
Antioxidant Measurements. The antioxidant behavior of 1 and H 2 quin was measured by monitoring the rate of peroxidation in a heterogeneous model system (micelles). The uptake of dissolved oxygen in micelles during peroxidation was performed at 37°C by using a Biological Oxygen Monitor equipped with a Clark-type oxygen electrode. To a glass chamber containing a magnetic stirrer, 5 mL of a micellar solution (pH 7.0) was added and then saturated with oxygen. Next, the electrodes were placed inside the chambers, and a peroxidation was initiated by injecting the ABAP solution (final concentration: 10 mM). After 10% of oxygen consumption, 10 μL of the solution of studied compounds was added (final concentration was 1 μM). The influence of tested compounds on the peroxidation was determined graphically. Because of the neutrality of studied compounds (no changes in plots after addition of compounds) to peroxidation of micelles, kinetic parameters were not determined.
Fluorescence Spectroscopy. Fluorescence measurements were performed by using a Jasco 8200 spectrofluorometer and a 1.0 cm quartz cell. The widths of excitation and emission slits were set at 5.0 nm. The excitation wavelength was set at 280 nm, and the emission was recorded in the 300−500 nm range. Phosphate-buffered saline (PBS, pH = 7.4) was used as a blank. The fluorescence studies were performed by manually titrating 2 mL of HSA (human serum albumin) solution with 10 μL of 1. The samples were measured after 5 min incubation at 298 and 310 K. The final concentrations of the protein and 1 during titration experiment were calculated by using eqs 7 and 8:  The Supporting Information is available free of charge at https://pubs.acs.org/doi/10.1021/acs.inorgchem.1c02110. PXRD patterns ( Figure S1), IR, NMR, and MS spectra ( Figures S2−S9), separated plots of oxygen uptake Inorganic Chemistry pubs.acs.org/IC Article