It's raining, it's porin : Fragment ligation of OmpF ion channels was achieved by using the split Psp‐GBD Pol intein; this allowed reconstitution of active trimeric porin. In combination with cysteine modification at an internal position, the porin's conductance properties were altered.
Treating African trypanosomiasis : The synthesis and biological evaluation of novel 1‐alkyloxy and 1‐benzyloxyadamantano 2‐guanylhydrazones, their 1‐dioxa congeners and two 1‐benzyladamantano 2‐guanylhydrazones is reported. Preliminary structure–activity relationship data were elucidated and lead compounds suitable for further optimization were discovered.
The role of β‐aminovinyl ketones as synthetic intermediates has been well categorised, but recent developments have shown an interesting array of applications and new chemotherapeutic potential, both in the preparation of biologically active heterocycles and as pharmacophores in their own right.
Coculture control : We report a combined photochemical and electroactive self‐assembled monolayer (SAM)‐based substrate strategy to generate a coculture platform with spatial and temporal control of cell–cell interactions. These dynamic substrates can present a variety of ligands on the surface for biospecific interactions between the ligands and cell surface receptors. Photopatterning enables the ligands to be immobilized in patterns and even gradients.
Copper‐induced structural rearrangements of Aβ40 structure and its redox properties are described in this study. Electrochemical and fluorescent methods are used to characterise the behaviour of Aβ–Cu species. The data suggest that time‐dependent folding of Aβ–Cu species may cause changes in the redox potentials.
Zinc‐dependent metalloproteinases such as matrix metalloproteinases (MMPs) and A disintegrin and metalloproteinases (ADAMs) are potential therapeutic targets in many diseases. To better understand their complex role in health and disease, new methodology for activity determination is under development. This concept gives an overview of the available methods for activity‐based proteomic research on these enzymes.
An iterative analogue library synthesis strategy rapidly developed comprehensive SAR for the mGluR5 ago‐potentiator ADX‐47273. This effort identified key substituents in the 3‐position of oxadiazole that engendered either mGluR5 ago‐potentiation or pure mGluR5 positive allosteric modulation. The mGluR5 positive allosteric modulators identified possessed the largest fold shifts (up to 27.9‐fold) of the glutamate CRC reported to date as well as providing improved physiochemical properties.
Choosing chloro : By reshaping the catalytic pocket of a catechol 1,2‐dioxygenase through a structural route alternative to evolution, novel engineered chlorocatechol dioxygenase‐like enzymes were obtained. Variants show an inversion of specificity with a preference for 4‐chlorocatechol and activity on the rarely recognised substrate 4,5‐dichlorocatechol.
Discovering RNA–protein interactions : A library of photoMet‐containing peptides was synthesized by using an Arg‐ and Leu‐rich α‐helical amphiphilic peptide. Irradiation of mixtures of these peptides and Rev‐responsive element (RRE) hairpin RNA promoted formation of covalent adducts. Analysis of one adduct showed that U26 in the bulged stem is responsible for covalent bond formation with the carbene intermediate. This strategy can provide important structural information about RNA–peptide interactions.
Through construction of an iminosugar library and in situ cell‐based screening, several iminosugar compounds with the ability to stimulate IFN‐γ secretion in vitro were discovered. Among these compounds, one was able to strongly induce IFN‐γ secretion and showed remarkable antibacterial effects in vivo.
Magic Mn–salen metallozyme : The design of an original, artificial, inorganic, complex‐protein adduct, has led to a better understanding of the synergistic effects of both partners. The exclusive formation of sulfoxides by the hybrid biocatalyst, as opposed to sulfone in the case of the free inorganic complex, highlights the modulating role of the inorganic‐complex‐binding site in the protein.
Matrix refolded : The formation of inclusion bodies, which are amorphous aggregates of misfolded insoluble protein, during recombinant protein expression, is one of the biggest bottlenecks in protein science. We report a stepwise, rational optimization procedure for refolding of insoluble proteins (see scheme). In comparison to refolding in‐solution, this parallelized, matrix‐assisted approach allows the refolding of various proteins in a fast and efficient manner.
Bivalent modulators of P‐glycoprotein : A small library of flavonoid homodimers and heterodimers was synthesized, and their in vitro activity in reversing paclitaxel resistance was evaluated along with structure–activity relationships. SAR trends indicate that flavonoid dimers with nonpolar, hydrophobic, less bulky substituents generally show more potent reversing activity. This will help guide future efforts in the search for more potent compounds.
A QSAR model for the prediction of CNS activity was developed and validated based on data from an in‐house database of “drug‐like” compounds. The model has demonstrated its applicability for novel chemical structures and its usefulness for the design of CNS‐focused compound libraries.
FRETting about MBP : Position‐specific incorporation of fluorescent groups is a useful method for analysis of the functions and structures of proteins. Here we demonstrate that position‐specific incorporation of fluorescent non‐natural amino acids in response to expanded codons enables us to detect ligand‐binding activity of maltose‐binding protein (MBP) through fluorescence resonance energy transfer (FRET) and ligand‐dependent fluorescence quenching.
The glycosylation of neuroactive peptides is a promising strategy to treat neurological and psychiatric disorders. Herein we investigated the effects of site‐specific glycosylation of neurotensin (NT). The glycosylated analogues have low‐nanomolar affinities and agonist activities toward NTS1, and suppress seizures with sub‐picomolar potency. Our work points to a new research direction of exploring BBB‐permeable NT analogues as potential first‐in‐class antiepileptic drugs.
The synthesis of 2′,2′‐difluoro KRN7000 is described. In vivo evaluation demonstrates that this fluorinated glycolipid induces CD1d‐dependent TCR activation of NKT cells, with a bias towards Th2 cytokine production.
Molecules that inhibit store‐operated calcium entry (SOCE) are potentially useful immunomodulating agents. The identification of proteins involved in this pathway may further enable the identification of selective inhibitors. Herein we document some examples of the small‐molecule inhibitors of SOCE that have been reported to date. We also describe methods that were used to characterize the mechanism of action of these inhibitors.
Choosing the right compounds to synthesise from large virtual combinatorial libraries is a current challenge for the pharmaceutical industry. Herein we describe a highly optimised method that aligns lead‐like properties with compound diversity. The methods are illustrated by considering a two‐dimensional library based on the interesting spirocyclic bis‐azetidine template.
6‐Amino‐6‐deoxy‐5,6‐di‐ N ‐( N ′‐octyliminomethylidene)nojirimycin , a reducing analogue of N‐nonyl‐1‐deoxynojirimycin, proved to be a potent and very selective inhibitor of β‐glucosidases, including human acid β‐glucosidase. Structural studies of the enzyme–inhibitor complex showed a binding mode in which the anomeric hydroxy group is accommodated in the “wrong” α configuration.