A structural biology perspective on bioactive small molecules and their plant targets

Structural biology efforts in recent years have generated numerous co-crystal structures of bioactive small molecules interacting with their plant targets. These studies include the targets of various phytohormones, pathogen-derived effectors, herbicides and other bioactive compounds. Here we discuss that this collection of structures contains excellent examples of nine collective observations: molecular glues, allostery, inhibitors, molecular mimicry, promiscuous binding sites, unexpected electron densities, natural selection at atomic resolution, and applications in structure-guided mutagenesis and small molecule design.     

Identification and validation of bioactive small molecule target through phenotypic screening

For effective bioactive small molecule discovery and development into new therapeutic drug, a systematic screening and target protein identification is required. Different from the conventional screening system, herein phenotypic screening in combination with multi-omics-based target identification and validation (MOTIV) is introduced. First, phenotypic screening provides visual effect of bioactive small molecules in the cell or organism level. It is important to know the effect on the cell or organism level since small molecules affect not only a single target but the entire cellular mechanism within a cell or organism. Secondly, MOTIV provides systemic approach to discover the target protein of bioactive small molecule. With the chemical genomics and proteomics approach of target identification methods, various target protein candidates are identified. Then network analysis and validations of these candidates result in identifying the biologically relevant target protein and cellular mechanism. Overall, the combination of phenotypic screening and MOTIV will provide an effective approach to discover new bioactive small molecules and their target protein and mechanism identification.     

Plant production systems for bioactive small molecules

Bioactive small molecules are important dietary components of food, as well as being widely used in diverse industrial sectors, from flavours, fragrances and sweeteners through to natural pesticides and pharmaceuticals. Plants already manufacture many of these bioactives, but often in yields that are not commercially competitive. There are a variety of new pathway engineering, cell culture and molecular breeding strategies in use and in development to improve yield and the robust supply of bioactives in planta. In the future, biorefining applications are likely to play a significant role in providing chemical intermediates for bioactive production from biomass feedstocks.     

Chemical-genomic profiling: systematic analysis of the cellular targets of bioactive molecules

Chemical-genomic (CG) profiling of bioactive compounds is a powerful approach for drug target identification and mode of action studies. Within the last decade, research focused largely on the development and application of CG approaches in the model yeast Saccharomyces cerevisiae. The success of these methods has sparked interest in transitioning CG profiling to other biological systems to extend clinical and evolutionary relevance. Additionally, CG profiling has proven to enhance drug-synergy screens for developing combinatorial therapies. Herein, we briefly review CG profiling, focusing on emerging cross-species technologies and novel drug-synergy applications, as well as outlining needs within the field.     

Identification of small molecules that modify the protein folding activity of heat shock protein 70

Molecular chaperones, such as heat shock protein 70 (Hsp70) and its bacterial ortholog DnaK, play numerous important roles in protein folding. In vitro, this activity can be observed by incubating purified chaperones with denatured substrates and measuring the recovery of properly folded protein. In an effort to rapidly identify small molecules that modify this folding activity, we modified an existing method for use in 96-well plates. In this assay, denatured firefly luciferase was treated with a mixture of DnaK and prospective chemical modulators. The luminescence of refolded luciferase was used to follow the reaction progress, and counterscreens excluded compounds that target luciferase; thus, hits from these screens modify protein folding via their effects on the function of the chaperone machine. Using this platform, we screened a pilot chemical library and found five new inhibitors of DnaK and one compound that promoted folding. These chemical probes may be useful in studies aimed at understanding the many varied roles of chaperones in cellular protein folding. Moreover, this assay provides the opportunity to rapidly screen for additional compounds that might regulate the folding activity of Hsp70.     

Identification of bioactive molecules by adipogenesis profiling of organic compounds

An important step in the postgenomic drug discovery is the construction of high quality chemical libraries that generate bioactive molecules at high rates. Here we report a cell-based approach to composing a focused library of biologically active compounds. A collection of bioactive non-cytotoxic chemicals was identified from a divergent library through the effects on the insulin-induced adipogenesis of 3T3-L1 cells, one of the most drastic and sensitive morphological alterations in cultured mammalian cells. The resulting focused library amply contained unique compounds with a broad range of pharmacological effects, including glucose-uptake enhancement, cytokine inhibition, osteogenesis stimulation, and selective suppression of cancer cells. Adipogenesis profiling of organic compounds generates a focused chemical library for multiple biological effects that are seemingly unrelated to adipogenesis, just as genetic screens with the morphology of fly eyes identify oncogenes and neurodegenerative genes.     

Minitags for small molecules: detecting targets of reactive small molecules in living plant tissues using 'click chemistry'

Small molecules offer unprecedented opportunities for plant research since plants respond to, metabolize, and react with a diverse range of endogenous and exogenous small molecules. Many of these small molecules become covalently attached to proteins. To display these small molecule targets in plants, we introduce a two-step labelling method for minitagged small molecules. Minitags are small chemical moieties (azide or alkyne) that are inert under biological conditions and have little influence on the membrane permeability and specificity of the small molecule. After labelling, proteomes are extracted under denaturing conditions and minitagged proteins are coupled to reporter tags through a 'click chemistry' reaction. We introduce this two-step labelling procedure in plants by studying the well-characterized targets of E-64, a small molecule cysteine protease inhibitor. In contrast to biotinylated E-64, minitagged E-64 efficiently labels vacuolar proteases in vivo . We displayed, purified and identified targets of a minitagged inhibitor that targets the proteasome and cysteine proteases in living plant cells. Chemical interference assays with inhibitors showed that MG132, a frequently used proteasome inhibitor, preferentially inhibits cysteine proteases in vivo . The two-step labelling procedure can be applied on detached leaves, cell cultures, seedlings and other living plant tissues and, when combined with photoreactive groups, can be used to identify targets of herbicides, phytohormones and reactive small molecules selected from chemical genetic screens.     

Interaction profiling methods to map protein and pathway targets of bioactive ligands

Recent advances in -omic profiling technologies have ushered in an era where we no longer want to merely measure the presence or absence of a biomolecule of interest, but instead hope to understand its function and interactions within larger signaling networks. Here, we review several emerging proteomic technologies capable of detecting protein interaction networks in live cells and their integration to draft holistic maps of proteins that respond to diverse stimuli, including bioactive small molecules. Moreover, we provide a conceptual framework to combine so-called ‘top-down’ and ‘bottom-up’ interaction profiling methods and ensuing proteomic profiles to directly identify binding targets of small molecule ligands, as well as for unbiased discovery of proteins and pathways that may be directly bound or influenced by those first responders. The integrated, interaction-based profiling methods discussed here have the potential to provide a unique and dynamic view into cellular signaling networks for both basic and translational biological studies.     

Proteomics accelerating the identification of the target molecule of bioactive small molecules

Failures in many drug development programs in the past decades were related to unspecified mechanism of action and poor pharmacokinetic (PK) properties. Recent developments are focused on well defined targets, improved PK profiles, however, not much is known about off-target effects, especially those responsible for diminishing drug activity. Steadily increasing application of proteomics in drug development should expose clinically relevant proteins for the analysis of drug effects, to show what group of patients will respond and who should not be treated with an agent.     

Discovery of selective bioactive small molecules by targeting an RNA dynamic ensemble

Current approaches used to identify protein-binding small molecules are not suited for identifying small molecules that can bind emerging RNA drug targets. By docking small molecules onto an RNA dynamic ensemble constructed by combining NMR spectroscopy and computational molecular dynamics, we virtually screened small molecules that target the entire structure landscape of the transactivation response element (TAR) from HIV type 1 (HIV-1). We quantitatively predict binding energies for small molecules that bind different RNA conformations and report the de novo discovery of six compounds that bind TAR with high affinity and inhibit its interaction with a Tat peptide in vitro (K(i) values of 710 nM-169 μM). One compound binds HIV-1 TAR with marked selectivity and inhibits Tat-mediated activation of the HIV-1 long terminal repeat by 81% in T-cell lines and HIV replication in an HIV-1 indicator cell line (IC(50) ～23.1 μM).     

Synthesis and characterization of novel 1,2-oxazine-based small molecules that targets acetylcholinesterase

Thirteen 2-oxazine-based small molecules were synthesized targeting 5-lipoxygenase (LOX), and acetylcholinesterase (AChE). The test revealed that the newly synthesized compounds had potent inhibition towards both 5-LOX and AChE in lower micro molar concentration. Among the tested compounds, the most active compound, 2-[(2-acetyl-6,6-dimethyl-4-phenyl-5,6-dihydro-2H-1,2-oxazin-3-yl)methyl]-1H-isoindole-1,3(2H)-dione (2a) showed inhibitory activity towards 5-LOX and AChE with an IC₅₀ values of 1.88, and 2.5 μM, respectively. Further, the in silico molecular docking studies revealed that the compound 2a bound to the catalytic domain of AChE strongly with a highest CDOCKER score of −1.18 kcal/mol when compared to other compounds of the same series. Additionally, 2a showed a good lipophilicity (log P = 2.66), suggesting a potential ability to penetrate the blood–brain-barrier. These initial pharmacological data revealed that the compound 2a could serve as a drug-seed in developing anti-Alzheimer’s agents.     

Using small molecules to target protein phosphatases

The site specific functionalization of phosphate groups with amino acid side chains of substrate proteins represents one of the most important regulatory mechanisms of biological systems. Phosphorylation and dephosphorylation are reversibly catalyzed by protein kinases and protein phosphatases, and the aberrant regulation of these enzymes is associated with the onset and progression of various disease states such as cancer, diabetes, neurodegenerative and autoimmune disorders, making these proteins attractive targets for drug discovery. Here we report on strategies currently explored for the identification and development of various inhibitors directed against clinically relevant phosphatases. While over the last years, inhibition of phosphorylation has evolved into a key strategy in targeted therapies, the development of clinically relevant phosphatase inhibitors still faces major bottlenecks and is often plagued by limited selectivity and unfavorable pharmacokinetics. The reader will gain a better understanding of the importance of the field and its current limitations.     

Recent application of metagenomic approaches toward the discovery of antimicrobials and other bioactive small molecules

Bacteria grown in pure culture have been the starting point for the discovery of many of the antibacterials now in use. Metagenomics, which utilizes culture-independent methods to access the collective genomes of natural bacterial populations, provides a means of exploring the antimicrobials produced by the large collections of bacteria that are known to be present in the environment but remain recalcitrant to culturing. Both novel small molecule antibiotics and new antibacterially active proteins have been identified using metagenomic approaches. The recent application of metagenomics to the discovery of bioactive small molecules, small molecule biosynthetic gene clusters and antibacterially active enzymes is discussed here.     

A small RNA targets pokeweed antiviral protein transcript

Ribosome‐inactivating proteins (RIPs) are a class of plant defense proteins with N‐glycosidase activity (EC 3.2.2.22). Pokeweed antiviral protein (PAP) is a Type I RIP isolated from the pokeweed plant, Phytolacca americana, thought to confer broad‐spectrum virus resistance in this plant. Through a combination of standard molecular techniques and RNA sequencing analysis, we report here that a small RNA binds and cleaves the open reading frame of PAP mRNA. Additionally, sRNA targeting of PAP is dependent on jasmonic acid (JA), a plant hormone important for defense against pathogen infection and herbivory. Levels of small RNA increased with JA treatment, as did levels of PAP mRNA and protein, suggesting that the small RNA functions to moderate the expression of PAP in response to this hormone. The association between JA and PAP expression, mediated by sRNA299, situates PAP within a signaling pathway initiated by biotic stress. The consensus sequence of sRNA299 was obtained through bioinformatic analysis of pokeweed small RNA sequencing. To our knowledge, this is the first account of a sRNA targeting a RIP gene.