Cyanomethylquinolones as a New Class of Potential Multitargeting Broad-Spectrum Antibacterial Agents.

This work identified a class of cyanomethylquinolones (CQs) and their carboxyl analogues as potential multitargeting antibacterial candidates. Most of the prepared compounds showed high antibacterial activities against most of the tested bacteria, exhibiting lower MIC values (0.125-2 µg/mL) than those of clinical norfloxacin, ciprofloxacin, and clinafloxacin. The low hemolysis, drug resistance, and cytotoxicity, as well as good predictive pharmacokinetics of active CQs and carboxyl analogues revealed their development potential. Furthermore, they could eradicate the established biofilm, facilitating bacterial exposure to these antibacterial candidates. These active compounds could induce bacterial death through multitargeting effects, including intercalating into DNA, up-regulating reactive oxygen species, damaging membranes directly, and impeding metabolism. Moreover, the highly active cyclopropyl CQ 15 exhibited more effective in vivo anti-MRSA potency than ciprofloxacin. These findings highlight the potential of CQs and their carboxyl analogues as multitargeting broad-spectrum antibacterial candidates for treating intractable bacterial infections.

Discovery of benzopyridone cyanoacetates as new type of potential broad-spectrum antibacterial candidates.

Unique benzopyridone cyanoacetates (BCs) as new type of promising broad-spectrum antibacterial candidates were discovered with large potential to combat the lethal multidrug-resistant bacterial infections. Many prepared BCs showed broad antibacterial spectrum with low MIC values against the tested strains. Some highly active BCs exhibited rapid sterilization capacity, low resistant trend and good predictive pharmacokinetic properties. Furthermore, the highly active sodium BCs (NaBCs) displayed low hemolysis and cytotoxicity, and especially octyl NaBC 5g also showed in vivo potent anti-infective potential and appreciable pharmacokinetic profiles. A series of preliminary mechanistic explorations indicated that these active BCs could effectively eliminate bacterial biofilm and destroy membrane integrity, thus resulting in the leakage of bacterial cytoplasm. Moreover, their unique structures might further bind to intracellular DNA, DNA gyrase and topoisomerase IV through various direct noncovalent interactions to hinder bacterial reproduction. Meanwhile, the active BCs also induced bacterial oxidative stress and metabolic disturbance, thereby accelerating bacterial apoptosis. These results provided a bright hope for benzopyridone cyanoacetates as potential novel multitargeting broad-spectrum antibacterial candidates to conquer drug resistance.

Comprehensive Insights into Medicinal Research on Imidazole-Based Supramolecular Complexes.

The electron-rich five-membered aromatic aza-heterocyclic imidazole, which contains two nitrogen atoms, is an important functional fragment widely present in a large number of biomolecules and medicinal drugs; its unique structure is beneficial to easily bind with various inorganic or organic ions and molecules through noncovalent interactions to form a variety of supramolecular complexes with broad medicinal potential, which is being paid an increasing amount of attention regarding more and more contributions to imidazole-based supramolecular complexes for possible medicinal application. This work gives systematical and comprehensive insights into medicinal research on imidazole-based supramolecular complexes, including anticancer, antibacterial, antifungal, antiparasitic, antidiabetic, antihypertensive, and anti-inflammatory aspects as well as ion receptors, imaging agents, and pathologic probes. The new trend of the foreseeable research in the near future toward imidazole-based supramolecular medicinal chemistry is also prospected. It is hoped that this work provides beneficial help for the rational design of imidazole-based drug molecules and supramolecular medicinal agents and more effective diagnostic agents and pathological probes.

Azolylpyrimidinediols as Novel Structural Scaffolds of DNA-Groove Binders against Intractable Acinetobacter baumannii.

A unique class of antibacterial azolylpyrimidinediols (APDs) and their analogues were developed. Some synthesized compounds showed excellent bacteriostatic potency; especially, triazolylpyrimidinediol (triazolyl PD) 7a exhibited good anti-Acinetobacter baumannii potential with a low MIC of 0.002 mmol/L. Triazolyl PD 7a with inconspicuous cytotoxicity and hemolytic activity could eradicate the established biofilm, showed low resistance, and exhibited favorable drug-likeness. Mechanistic explorations revealed that compound 7a without membrane-targeting ability could decrease metabolic activity, interact with DNA through groove binding action to block DNA replication rather than intercalate into and cleave DNA, and thus inhibit bacterial growth. Further computations displayed that the low EHOMO and large energy gap might help triazolyl PD 7a binding to biological targets more easily. Moreover, compound 7a gave appreciable in vivo pharmacokinetic properties and pharmacodynamics. These findings of azolylpyrimidinediols as novel structural scaffolds of DNA-groove binders might imply a large promise for the treatments of Acinetobacter baumannii infection.

Unique iminotetrahydroberberine-corbelled metronidazoles as potential membrane active broad-spectrum antibacterial agents.

In an effort for fighting with dreadful drug resistance, iminotetraberberine was hybridized with metronidazole to construct a unique type of potential broad-spectrum antibacterial iminotetrahydroberberine-corbelled metronidazoles. Some prepared hybrids exerted promising inhibitory effects against the tested microorganisms in comparison to the natural berberine, clinical metronidazole and norfloxacin. Noticeably, phenyl oxime derivative 8e displayed a broad antibacterial spectrum with a quite low MIC value of 0.024 mM against P. aeruginosa, being 63-, 62- and 2-fold to berberine, metronidazole and norfloxacin, respectively. The active compound 8e with low cytotoxicity under effective bacteriostatic concentration could decrease biofilm viability and show much lower trend to induce the resistant development than norfloxacin in the tested period. Mechanism investigation showed that compound 8e could disturb the bacterial membrane to lead to the leakage of cellular contents, thus exerting potent antibacterial potency. It was also revealed that compound 8e could interact with penicillin binding protein via multi-site non-covalent binding in docking simulation. The above results manifested that iminotetrahydroberberine-corbelled metronidazoles might bring hope for the exploitation of new broad-spectrum antibacterial agents with a membrane-destruction mechanism.

Pyrimidine-conjugated fluoroquinolones as new potential broad-spectrum antibacterial agents.

Pyrimidine-conjugated fluoroquinolones were constructed to cope with the dreadful resistance. Most of the target pyrimidine derivatives effectively suppressed the growth of the tested strains, especially, 4-aminopyrimidinyl compound 1c showed a broad antibacterial spectrum and low cytotoxicity and exhibited superior antibacterial potency against Enterococcus faecalis with a low MIC of 0.25 µg/mL to norfloxacin and ciprofloxacin. The active compound 1c with fast bactericidal potency could inhibit the formation of biofilms and showed much lower trend for the development of drug-resistance than norfloxacin and ciprofloxacin. Further exploration revealed that compound 1c could prompt ROS accumulations in bacterial cells and interact with DNA to form a DNA-1c complex, thus facilitating bacterial death. ADME analysis indicated that compound 1c possessed favorable drug-likeness and promising pharmacokinetic properties. These results demonstrated that pyrimidine-conjugated fluoroquinolones held hope as potential antibacterial candidates and deserve further study.

[Soil microfauna diversity among Cunninghamia lanceolata plantations based on pyrosequencing].

In order to study the function of soil microfauna and its responses to environmental changes, we used metagenome analyses of the 18S rDNA gene region to identify differences in microfauna diversity and community structure among fifteen soil samples belonging to five different Cunninghamia lanceolate plantations. The plantations were located in Youxian County, Hunan Province in central China. The trees in these plantations were of different ages (3, 13, and 26 years) and belonged to different ecological successions (first, second, and third successions). The total dataset comprised 94922 high quality sequences with an average length of 436 bp. The dominant taxonomic groups across all samples were Chordata, Annelida, Arthropoda, Nematoda, Rotifera and Platyhelminthes with each accounting for 60.8%, 24.0%, 7.4%, 3.6%, 1.5% and 1.2% of the sequences, respectively. There were significant differences in ACE index and Shannon index among the five plantations. The lowest diversity of soil microfauna was in the 13-year old plantation of the first ecological succession. The correlation analysis showed that both ACE and available potassium concentration were negatively correlated to the Chaol index. However, there were no significant correlations between the Shannon, Simpson indices and the physical-chemical properties of soil. Overall, the Jaccard's similarity coefficient was less than 0.4 among samples at each site, and significant differences were found among plantations.