Current Medicinal Chemistry - Volume 26, Issue 13, 2019

Background: Aurora A (AurA) kinase is a key mitotic protein implicated in cancer. Several small molecule inhibitors targeting the ATP binding site of this enzyme are in various stages of clinical development. However, these inhibitors can result in selectivity and drug resistance problems. Allosteric inhibition of kinases using small molecules is an alternative strategy to target these enzymes selectively and these could serve as the seeds for next generation medicines. This review discusses the developments in the non-ATP site binding small molecule inhibitors of AurA and their prospect as future therapeutics. Discussion: Allosteric targeting of AurA kinase using small molecules is relatively a new strategy, and only a handful of research work has been reported. Two patents and three papers pertaining to allosteric targeting of AurA kinase using small molecules were covered in this review. Topics discussed include, identification of small molecule inhibitors targeting AurA- Targeting Protein for Xenopus kinesin-like protein 2 (TPX2) interaction, anacardic acid - a natural product ligand that selectively modulates AurA activity in the presence of Aurora B kinase, and identification of felodipine as an uncompetitive inhibitor of AurA using Surface Enhanced Raman Spectroscopy (SERS) technique. Conclusion: Allosteric targeting of therapeutically relevant enzymes using small molecules is a burgeoning research area. New techniques such as fragment-based ligand discovery, SERS methods, etc., are expanding to identify the allosteric site binding ligands. Research in this area is expected to deliver fruitful outcome in terms of novel therapeutics against AurA kinase as well as other therapeutically relevant enzymes.

Influenza viruses are severe human pathogens that pose persistent threat to public health. Each year more people die of influenza virus infection than that of breast cancer. Due to the limited efficacy associated with current influenza vaccines, as well as emerging drug resistance from small molecule antiviral drugs, there is a clear need to develop new antivirals with novel mechanisms of action. The influenza virus polymerase complex has become a promising target for the development of the next-generation of antivirals for several reasons. Firstly, the influenza virus polymerase, which forms a heterotrimeric complex that consists of PA, PB1, and PB2 subunits, is highly conserved. Secondly, both individual polymerase subunit (PA, PB1, and PB2) and inter-subunit interactions (PA-PB1, PB1- PB2) represent promising drug targets. Lastly, growing insight into the structure and function of the polymerase complex has spearheaded the structure-guided design of new polymerase inhibitors. In this review, we highlight recent progress in drug discovery and assay development targeting the influenza virus polymerase complex and discuss their therapeutic potentials.

Polyethyleneimine (PEI) is well-known as a non-viral gene delivery vector, especially for oligonucleotide delivery. However, its clinical applications are significantly limited due to its high cationic charge, lack of specificity, and interaction with the proteins and nontarget cells in the biological fluids, resulting in high cytotoxicity, poor stability and low transfection efficiency for oligonucleotides transporting. It has been shown that the molecular weight (MW) of PEI, degree of branching, N/P ratio, buffer capacity, oligonucleotide structure, culture medium pH, serum, presence or absence of and method of preparation make a significant difference in the cytoxicity, stability, and transfection efficiency for the PEI-based oligonucleotides delivery systems. Ligands, hydrophobic, hydrophilic, and amphiphilic modification of PEI have been investigated to reduce the cytoxicity and improve the stability, the transfection efficiency, and therapeutic effect. Moreover, various intelligent modifications of PEI, such as pH-responsive (hydrazone bond) and redox sensitive linkers (disulfide bond) can control oligonucleotides release and have attracted much attention. In general, more efficient oligonucleotide delivery can be achieved by the introduction of modifications to PEI and by optimization of parameters of PEI or PEI-based formulations.

Sustained-release systems made by biodegradable polymers for protein and peptide drug delivery have received considerable attention by academic researchers and major pharmaceutical companies around the world. Various types of biodegradable materials, including natural and synthetic polymers, have been applied to form protein and peptide drug carriers. Among these material candidates, poly lactic acid (PLA) and poly lactic-co-glycolic acid (PLGA) are the most commonly used biodegradable materials in the development of protein and peptide microspheres. In addition, many microsphere preparation technologies, including spray drying, coacervation, multiple emulsion solvent evaporation method and microporous membrane emulsification have been developed for microspheres preparation. In this review, we particularly summarize and briefly introduce the materials and methods that are used to fabricate microspheres as protein delivery systems. The existing opportunities and challenges for successful protein delivery are also discussed.

Background: The increasing threats of antibiotic resistance urge the need for developing new approaches to combat bacterial infections including those caused by Staphylococcus aureus (S. aureus). Unlike conventional antibiotics that aim to kill bacteria or inhibit their growth, targeting bacterial virulence may be a promising alternative approach, which imposes less selective pressure for antibiotic resistance in future generations. Objective: Our goal is to provide a systematic review about developing high-throughput screening (HTS) strategies for the identification of inhibitors targeting virulence of S. aureus. We also describe an overview of virulence regulatory pathways for potential antivirulence targets. Methods: We focus on five potential targets or target families, including agr quorum sensing system, SarA/MgrA protein family, sortase A, Clp protease and eukaryotic-like Ser/Thr phosphatase (Stp1). For each target, we introduce its role in virulence regulation, summarize the HTS approaches that are used to identify novel anti-virulence inhibitors, and discuss the advantages and disadvantages of these strategies. Conclusion: The discovery of anti-virulence inhibitors via HTS underlines the promising potential of anti-virulence therapy for S. aureus. The development of HTS strategies can facilitate the identification of novel anti-virulence inhibitors for combating S. aureus infection, and may also advance our understanding on virulence regulation in S. aureus.

new class of peptidomimetics termed as "γ-AApeptides" was recently developed by our group. Similar to other peptidomimetics, γ-AApeptides are resistant to proteolytic degradation, and possess limitless potential to introduce chemically diverse functional groups. γ-AApeptides have shown great promise in biomedical applications. In this article, we will review a few examples of γ-AApeptides with biological potential. Certain γ-AApeptides can permeate cell membranes and therefore they can be used as potential drug carrier. γ-AApeptides can also bind to HIV RNA with high specificity and affinity, suggesting their potential application as anti-HIV agents. Moreover, they can mimic host-defense peptides and display potent and broad-spectrum activity towards a range of drug-resistant bacterial pathogens. They are also potential anti-cancer agents. For instance, they have shown great promise in targeted imaging of tumor in mouse model, and they are also capable of disrupting p53/DNA interactions, and thus antagonize STAT3 signaling pathway. Recently, from combinatorial screening, γ-AApeptides are identified to inhibit Aβ peptide aggregation, and thus they can be developed into potential anti- Alzheimer’s disease agent.

Peptide therapeutics has made tremendous progress in the past decade. Many of the inherent weaknesses of peptides which hampered their development as therapeutics are now more or less effectively tackled with recent scientific and technological advancements in integrated drug discovery settings. These include recent developments in synthetic organic chemistry, high-throughput recombinant production strategies, highresolution analytical methods, high-throughput screening options, ingenious drug delivery strategies and novel formulation preparations. Here, we will briefly describe the key methodologies and strategies used in the therapeutic peptide development processes with selected examples of the most recent developments in the field. The aim of this review is to highlight the viable options a medicinal chemist may consider in order to improve a specific pharmacological property of interest in a peptide lead entity and thereby rationally assess the therapeutic potential this class of molecules possesses while they are traditionally (and incorrectly) considered ‘undruggable’.

Background: The drug delivery by versatile types of self-assembled micelles for tumor treatment, which improved the diagnostic and therapeutic effectiveness, is advocated. However, despite the numerous advantages, applications of most micelle system have been retarded by low in vivo bio-stability which led to premature drug release and nonspecific tissue accumulation. To date, a range of chemistries has been introduced in intermolecular non-covalent/covalent crosslinking strategies for these dynamic nanostructures to produce robust functional nanoparticles with enhanced circulation stability and lower non-targeted organ toxicity. Objective: We focused on recent developments in crosslinking polymeric nanoparticles in cancer therapy. Methods: Types of chemistries used in the crosslinking strategies of the micelles are outlined and their enhanced drug delivery abilities are discussed. Results: We reviewed one hundred and nineteen papers and discussed in six aspect. More than 30 examples have been carefully discussed. Conclusion: Over the last decade, numerous of strategies for micelles crosslinking, such as disulfide coupling, free radical polymerization, physical interactions, chelation, and formation of microenvironment- responsive bonds, have been developed for enhancing micelles circulation stability, minimizing organ toxicity and achieving higher tumor targeting specificity. The application of these chemistries for micelle stabilizing might bring a new generation of versatile crosslinked micelles with enhanced therapeutic index and facilitate their further clinical translations.

Background: Stimuli-responsive carriers are a class of drug delivery systems which can change their physicochemical properties and/or structural conformations in response to specific stimuli. Although passive and active drug targeting has proved to reduce the side effects to normal cells, controlled intracellular drug release should be included in drug carriers to enhance the bioavailability of drugs at the disease site. Methods: This review focuses on several recent advances in the development of stimuli-responsive carriers for spatially and temporally controlled release of therapeutic agents in response to intracellular stimuli, such as pH, redox potential, reactive oxygen species, enzyme and temperature. Results: Among the different types of stimuli, pH-responsive carriers have been mostly used to design intracellular controlled release system. The sharp difference of redox potential between inside and outside cells is attributed to the high variation in concentration of glutathione. ROS-responsive carriers are gaining much attention for selective release of therapeutic agents by sensing oxidative conditions at different levels. The advantages of utilizing enzymes as the trigger of stimuli-responsive carriers include diverse types of enzymes, high selectivity of enzyme catalyzed reactions and the mild reaction conditions involved. Abnormal temperature is another unique stimulus and has been widely used to trigger controlled release of drug in tumor cells. Conclusion: Recent developments highlighted in this paper demonstrate that stimuli-responsive carriers possess great potential as a new platform for controlled intracellular drug release.

Background: Cancer continues to be a global burden, despite the advancement of various technological and pharmaceutical improvements over the past two decades. Methods for treating cancer include surgery, radiotherapy and chemotherapy in addition to other specialized techniques. On the other hand, medicinal plants have been traditionally employed either as the complementary medicine or dietary agents in the treatment and management of cancer. Medicinal plants are a rich source of secondary metabolites with interesting biological and pharmacological activities. Among these metabolites, glycosides are naturally occurring substances and have outstanding therapeutic potential and clinical utility. Methods: Different medical research engines such as, GoogleScholar, PubMed, SpringerLink, ScienceDirect were used to collect related literature on the subject matter. In this regard, only peer-reviewed journals were considered. Results: Emerging results showed that numerous glycosides isolated from various plants possessed marked anticancer activity against a variety of cancer cell lines. Accordingly, the aim of the present review is to shed light on the anticancer effects of glycosides, analyze possible mechanisms of action, and highlight the role of these natural agents as complementary and alternative medicine in combating and managing cancer. Conclusion: The glycosides isolated from different plants demonstrated potent cytotoxic effects against various cancer cell lines in initial preclinical studies. The anticancer effect was mediated through multiple mechanisms; however further detailed studies are needed to understand the full potential of glycosides for clinical utility.