Innovative Strategies for the Synthesis of Biologically Active Small Molecules

The post genomic era, set the challenge to develop drugs that target an ever-growing list of proteins associated with diseases. However, an increase in the number of drugs approved every year is nowadays still not observed. To overcome this gap, innovative approaches should be applied in drug discovery for target validation, and at the same time organic synthetic chemistry has to find new fruitful strategies to obtain biologically active small molecules not only as therapeutic agents, but also as diagnostic tools to identify possible cellular targets. In this context, in view of the multifactorial mechanistic nature of cancer, new chimeric molecules, which can be either antitumor lead candidates, or valuable chemical tools to study molecular pathways in cancer cells, were developed using a multitarget-directed drug design strategy. According to this approach, the desired hybrid compounds were obtained by combining in a single chemical entity SAHA analogues, targeting histone deacetylases (HDACs), with substituted stilbene or terphenyl derivatives able to block cell cycle, to induce apoptosis and cell differentiation and with Sorafenib derivative, a multikinase inhibitor. The new chimeric derivatives were characterized with respect to their cytotoxic activity and their effects on cell cycle progression on leukemia Bcr-Abl-expressing K562 cell lines, as well as their HDACs inhibition. Preliminary results confirmed that one of the hybrid compounds has the desired chimeric profile. A distinct project was developed in the laboratory of Dr Spring, regarding the synthesis of a diversity-oriented synthesis (DOS) library of macrocyclic peptidomimetics. From a biological point of view, this class of molecules is extremely interesting but underrepresented in drug discovery due to the poor synthetic accessibility. Therefore it represents a valid challenge for DOS to take on. A build/couple/pair (B/C/P) approach provided, in an efficient manner and in few steps, the structural diversity and complexity required for such compounds.

Synthesis of Biologically Active Small Molecules: Different Approaches to Drug Design

In the past years, genome biology had disclosed an ever-growing kind of biological targets that emerged as ideal points for therapeutic intervention. Nevertheless, the number of new chemical entities (NCEs) translated into effective therapies employed in the clinic, still not observed. Innovative strategies in drug discovery combined with different approaches to drug design should be searched for bridge this gap. In this context organic synthetic chemistry had to provide for effective strategies to achieve biologically active small molecules to consider not only as potentially drug candidates, but also as chemical tools to dissect biological systems. In this scenario, during my PhD, inspired by the Biology-oriented Synthesis approach, a small library of hybrid molecules endowed with privileged scaffolds, able to block cell cycle and to induce apoptosis and cell differentiation, merged with natural-like cores were synthesized. A synthetic platform which joined a Domino Knoevenagel-Diels Alder reaction with a Suzuki coupling was performed in order to reach the hybrid compounds. These molecules can represent either antitumor lead candidates, or valuable chemical tools to study molecular pathways in cancer cells. The biological profile expressed by some of these derivatives showed a well defined antiproliferative activity on leukemia Bcr-Abl expressing K562 cell lines. A parallel project regarded the rational design and synthesis of minimally structurally hERG blockers with the purpose of enhancing the SAR studies of a previously synthesized collection. A Target-Oriented Synthesis approach was applied. Combining conventional and microwave heating, the desired final compounds were achieved in good yields and reaction rates. The preliminary biological results of the compounds, showed a potent blocking activity. The obtained small set of hERG blockers, was able to gain more insight the minimal structural requirements for hERG liability, which is mandatory to investigate in order to reduce the risk of potential side effects of new drug candidates.

Synthesis of new bioactive β-lactam compounds

New biologically active β-lactams were designed and synthesized, developing novel antibiotics and enzymatic inhibitors directed toward specific targets. Within a work directed to the synthesis of mimetics for RGD (Arg-Gly-Asp) sequence able to interact with αvβ3 and α5β1-type integrins, new activators were developed and their Structure-Activity Relationships (SAR) analysis deepened, enhancing their activity range towards the α4β1 isoform. Moreover, to synthesize novel compounds active both against bacterial infections and pulmonary conditions of cystic fibrosis patients, new β-lactam candidates were studied. Among the abundant library of β-lactams prepared, mainly with antioxidant and antibacterial double activities, it was identified a single lead to be pharmacologically tested in vivo. Its synthesis was optimized up to the gram-scale, and pretreatment method and HPLC-MS/MS analytical protocol for sub-nanomolar quantifications were developed. Furthermore, replacement of acetoxy group in 4-acetoxy-azetidinone derivatives was studied with different nucleophiles and in aqueous media. A phosphate group was introduced and the reactivity exploited using different hydroxyapatites, obtaining biomaterials with multiple biological activities. Following the same kind of reactivity, a small series of molecules with a β-lactam and retinoic hybrid structure was synthesized as epigenetic regulators. Interacting with HDACs, two compounds were respectively identified as an inhibitor of cell proliferation and a differentiating agent on steam cells. Additionally, in collaboration with Professor L. De Cola at ISIS, University of Strasbourg, some new photochemically active β-lactam Pt (II) complexes were designed and synthesized to be used as bioprobes or theranostics. Finally, it was set up and optimized the preparation of new chiral proline-derived α-aminonitriles through an enantioselective Strecker reaction, and it was developed a chemo-enzymatic oxidative method for converting alcohols to aldehydes or acid in a selective manner, and amines to relative aldehydes, amides or imines. Moreover, enzymes and other green chemistry methodologies were used to prepare Active Pharmaceutical Ingredients (APIs).