Mini Reviews in Medicinal Chemistry - Volume 14, Issue 5, 2014

Cofilin-1 protein, which main function is to regulate actin cytoskeleton dynamics, appears to be involved with many steps in the neurotoxicity processes found in neurodegenerative diseases such as Alzheimer's disease (AD), Parkinson's disease (PD) and Huntington's disease (HD). As the dynamics of actin filaments play a major role in several cellular processes, the primary involvement of cofilin-1 dysfunctions in the pathophysiology of these disorders may be related to a cytoskeleton stress. However, recently cofilin-1 has also been related to other biological processes such as cell death by apoptosis. In both cases, ATP depletion associated with the presence of reactive species and other stressors regulate cofilin-1 by inducing the formation of aggregates composed primarily by actin and cofilin-1, known as cofilin/actin rods. These structures seem to be formed initially as a neuroprotective response to mitochondrial damage; but once the stressor persists they are thought to act as inducers of further impairments and loss of neuronal functions. Therefore, here we provide a brief overview of the current knowledge about the central role of cofilin/actin rods formation, where its dysregulation and malfunction might be the trigger to neurodegeneration.

Peptide Nucleic Acids (PNAs) are molecules combining structural features of proteins and nucleic acid. They resemble DNA or RNA by forming helical polyamides containing nitrogen bases attached to the backbone consisting of N-(2-aminoethyl)-glycine monomers, which mimics the alternating ribose-phosphodiester-backbone of a nucleic acid. Because PNAs bind exceptionally strong to complementary DNA or RNA sequences obeying Watson-Crick base paring, they became attractive candidates for antisense and antigen therapies. PNAs are also being tested as novel antibiotics, gene-activating agents, and as molecular probes for FISH and imaging or biosensors used in diagnostics. Although PNAs offer many exiting medical applications, improving their cellular uptake and developing specific delivery strategies is crucial for a successful entry in the clinic in the near future.

G protein-coupled receptors (GPCRs) constitute one of the largest classes of cell surface receptors. GPCR biology has been a subject of widespread interest owing to the functional relevance of these receptors and their potential importance in the development of new drugs. At present, over 30% of all launched drugs target these receptors. GPCRs have been considered for a long time to function as monomeric entities and the idea of GPCR dimerization and oligomerization was initially accepted with disbelief. However, a significant amount of experimental and molecular modeling evidence accumulated during the last several years suggests that the process of GPCRs dimer or oligomer formation is a general phenomenon, in some cases even essential for receptor function. Among the many methods to study GPCR dimerization and oligomerization, modern biophysical techniques such as those based on resonance energy transfer (RET) and particularly bioluminescence resonance energy transfer (BRET) have played a leading role. RET methods are commonly applied as non-destructive indicators of specific protein-protein interactions (PPIs) in living cells. Data from numerous BRET experiments support the idea that the process of GPCR oligomerization may be relevant in many physiological and pathological conditions. The application of BRET to the study of GPCRs is not only limited to the assessment of receptor oligomerization but also expands to the investigation of the interactions of GPCRs with other proteins, including G proteins, G protein-coupled receptor kinases, β-arrestins or receptor tyrosine kinases, as well as to the characterization of GPCR activation and signaling. In this review, we briefly summarize the fundaments of BRET, discuss new trends in this technology and describe the wide range of applications of BRET to study GPCRs.

Cannabinoid receptors, belonging to the superfamily of G-protein coupled receptors, play a major role in pathophysiology of a wide range of disparate diseases. Cannabinoid CB2 receptor, which mainly locates in peripheral tissues, represents as a promising drug target for the treatment of pain, osteoporosis, liver disorders, and so on without serious CNS side effects. In the past decades, the identification and optimization of selective ligands for the CB2 receptor has been a major objective in drug discovery. In the present review, we describe recent advances in the development of novel chemotypes of the CB2 receptor selective ligands, and give a simple discussion for the corresponding structureactivity relationships of them.

Ascorbic acid (AA), also known as vitamin C, was initially identified as the factor preventing the scurvy disease, and became very popular for its antioxidant properties. It is an important co-substrate of a large class of enzymes, and regulates gene expression by interacting with important transcription factors. AA is important in all stressful conditions that are linked to inflammatory processes and involve immunity. It has been known for decades that the persistence of an inflammatory stimulus is responsible for the onset of many diseases. AA is essential to stimulate the immune system by increasing the strength and protection of the organism. Therefore, its immunostimulant, antinflammatory, antiviral and antibacterial roles are well known, we have summarized its main functions in different types of diseases related to the immune system and chronic inflammation. We can conclude that AA, due to its effects and diversity of regulated pathways, is suitable for use in various fields of medicine including immunology, toxicology, radiobiology and others. AA is not preferable to be used as an isolated mode of treatment, but it can be co-applied as an adjuvant to regulate immunity, gene expression and other important physiological processes. However, we propose that future studies will take into consideration the research of new combinations of antioxidant natural substances and drugs.

Malaria, a devastating infectious disease caused by parasites of Plasmodium genera is transmitted from person to person through bites of infected mosquitoes. It generally traps underdeveloped nations with poor infrastructure and high population density. It has attracted considerable attention from academic institutions, pharmaceutical industries and government agencies but the efforts to eradicate this threat face a number of technical, economic, financial and institutional hurdles. In the absence of clinically proven vaccines to combat malaria, chemotherapy continues to be the best available option, although it suffers from a big loophole of resistance. Emergence of resistance is associated with the two phases of Plasmodium’s life cycle: asexual in humans and sexual in mosquito, which are intricate to target simultaneously. Consequently, the search for novel antimalarial agents is a never-ending task for scientists and chemists. This review aims at highlighting the currently used antimalarial agents, targets for the therapy and present scenario in the development of new antimalarial drugs to combat this global problem.