In the last two decades, the repertoire of clinically effective antibacterials is shrinking due to the rapidly increasing of multi-drug-resistant pathogenic bacteria. New chemical classes with innovative mode of action are required to prevent a return to the pre-antibiotic era. We have recently reported the identification of a series of linear guanidine derivatives and their antibacterial properties. A batch of a promising candidate for optimization studies (compound 1) turned out to be a mixture containing two unknown species with a better biological activity than the pure compound. This serendipitous discovery led us to investigate the chemical nature of the unknown components of the mixture. Through MS analysis coupled with design and synthesis we found that the components were spontaneously generated oligomers of the original compound. Preliminary biological evaluations eventually confirmed the broad-spectrum antibacterial activity of this new family of molecules. Interestingly the symmetric dimeric derivative (2) exhibited the best profile and it was selected as lead compound for further studies.
The rise of antimicrobial-resistant phenotypes and the spread of the global pandemic of COVID-19 are worsening the outcomes of hospitalized patients for invasive fungal infections. Among them, candidiases are seriously worrying, especially since the currently available drug armamentarium is extremely limited. We recently reported a new class of macrocyclic amidinoureas bearing a guanidino tail as promising antifungal agents. Herein, we present the design and synthesis of a focused library of seven derivatives of macrocyclic amidinoureas, bearing a second phenyl ring fused with the core. Biological activity evaluation shows an interesting antifungal profile for some compounds, resulting to be active on a large panel of Candida spp. and C. neoformans. PAMPA experiments for representative compounds of the series revealed a low passive diffusion, suggesting a membrane-based mechanism of action or the involvement of active transport systems. Also, compounds were found not toxic at high concentrations, as assessed through MTT assays.
Gold-nanoparticle
(AuNP)-conjugated drugs represent a promising
and innovative antitumor therapeutic approach. In our study, we describe
the design, the synthesis, the preparation, and the characterization
of AuNPs conjugated with the pyrazolo[3,4-d]pyrimidine
derivative SI306, a c-Src inhibitor. AuNPs–SI306 showed a good
loading efficacy (65%), optimal stability in polar media and in human
plasma, and a suitable morphological profile: a ζ-potential
of −43.9 mV, a nanoparticle diameter of 48.6 nm, and a 0.441
PDI value. The antitumoral activity of AuNPs–SI306 was evaluated in vitro in the glioblastoma model, by the low-density growth
assay, and also in combination with radiotherapy (RT). Results demonstrated
that AuNPs had a basal radiosensitization ability and that AuNPs–SI306,
when used in combination with RT, were more effective in inhibiting
tumor cell growth with respect to AuNPs and free SI306.
Accepted 7 July 2020ABSTRACT
Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is the virus responsible for the known COVID-19 disease. Since currently no definitive therapies or vaccines for the SARS-CoV-2 virus are available, there is an urgent need to identify effective drugs against SARS-CoV-2 infection. One of the best-known targets available is the main protease of this virus, crucial for the processing of polyproteins codified by viral RNA. In this work, we used a computational virtual screening procedure for the repurposing of commercial drugs available in the DrugBank database as inhibitors of the SARS-CoV-2 main protease. Molecular docking calculations and molecular dynamics (MD) simulations have been applied. The computational model was validated through a self-docking procedure. The screening procedure highlighted five interesting drugs that showed a comparable or higher docking score compared to the crystallographic compound and maintained the protein binding during the MD runs. Amongst these drugs, Ritonavir has been used in clinical trials with patients affected by COVID-19 and Nelfinavir showed anti-SARS-CoV-2 activity. The five identified drugs could be evaluated experimentally as inhibitors of the SARS-CoV-2 main protease in view of a possible COVID-19 treatment.
Communicated by Ramaswamy H. Sarma
Enveloped viruses belong to a large class of pathogens responsible for multiple serious diseases. Their spread into new territories has been the cause of major epidemics throughout human history, including the Spanish flu in 1918 and the latest COVID-19 pandemic. Thanks to their outer membrane, consisting essentially of host lipids, enveloped viruses are more resistant to enzymes, and are also less susceptible to host immune defenses than their naked counterparts. Therefore, the development of effective approaches to combat enveloped virus infections represents a major challenge for antiviral therapy in the current century. This review focuses on the characteristics of enveloped viruses, their importance in the entry phase, drugs targeting envelope membrane-mediated entry, and those specifically designed to target the envelope. The broad-spectrum antiviral activity of these compounds can be attributed to their ability to affect the envelope, an essential structural feature common to several viruses. This makes this class of compounds agents of great interest when no specific drugs or vaccines are available to block viral infections.
Systemic fungal infections are, nowadays, of crucial importance and, thus, in the last decade, we explored the great potential of natural and synthetic guanylated compounds, a great amount of work that led to the development of new non-azole antifungal compounds bearing a macrocycle, endowed with potent antifungal activity. We planned many biological assays to evaluate this class, implying always greater amount of compounds needed. This triggered us to setup a convenient strategy to prepare, in an easy and affordable way, grams of compound to be tested in excellent overall yield.
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