Bradley C. Doak

Structural and conformational determinants of macrocycle cell permeability

Macrocycles are of increasing interest as chemical probes and drugs for intractable targets like protein-protein interactions, but the determinants of their cell permeability and oral absorption are poorly understood. To enable rational design of cell-permeable macrocycles, we generated an extensive data set under consistent experimental conditions for more than 200 non-peptidic, de novo-designed macrocycles from the Broad Institutes diversity-oriented screening collection. This revealed how specific functional groups, substituents and molecular properties impact cell permeability. Analysis of energy-minimized structures for stereo- and regioisomeric sets provided fundamental insight into how dynamic, intramolecular interactions in the 3D conformations of macrocycles may be linked to physicochemical properties and permeability. Combined use of quantitative structure-permeability modeling and the procedure for conformational analysis now, for the first time, provides chemists with a rational approach to design cell-permeable non-peptidic macrocycles with potential for oral absorption.

Structure and Function of the Oxidoreductase DsbA1 from Neisseria meningitidis

Neisseria meningitidis encodes three DsbA oxidoreductases (NmDsbA1-NmDsbA3) that are vital for the oxidative folding of many membrane and secreted proteins, and these three enzymes are considered to exhibit different substrate specificities. This has led to the suggestion that each N. meningitidis DsbA (NmDsbA) may play a specialized role in different stages of pathogenesis; however, the molecular and structural bases of the different roles of NmDsbAs are unclear. With the aim of determining the molecular basis for substrate specificity and how this correlates to pathogenesis, we undertook a biochemical and structural characterization of the three NmDsbAs. We report the 2.0-A-resolution crystal structure of the oxidized form of NmDsbA1, which adopted a canonical DsbA fold similar to that observed in the structures of NmDsbA3 and Escherichia coli DsbA (EcDsbA). Structural comparisons revealed variations around the active site and candidate peptide-binding region. Additionally, we demonstrate that all three NmDsbAs are strong oxidases with similar redox potentials; however, they differ from EcDsbA in their ability to be reoxidized by E. coli DsbB. Collectively, our studies suggest that the small structural differences between the NmDsbA enzymes and EcDsbA are functionally significant and are the likely determinants of substrate specificity.

Design and Evaluation of the Performance of an NMR Screening Fragment Library

The design of a suitable library is an essential prerequisite to establish a fragment-based screening capability. Several pharmaceutical companies have described their approaches to establishing fragment libraries; however there are few detailed reports of both design and analysis of performance for a fragment library maintained in an academic setting. Here we report our efforts towards the design of a fragment library for nuclear magnetic resonance spectroscopy-based screening, demonstrate the performance of the library through analysis of 14 screens, and present a comparison to previously reported fragment libraries.

Application of Fragment‐Based Screening to the Design of Inhibitors of Escherichia coli DsbA

The thiol-disulfide oxidoreductase enzyme DsbA catalyzes the formation of disulfide bonds in the periplasm of Gram-negative bacteria. DsbA substrates include proteins involved in bacterial virulence. In the absence of DsbA, many of these proteins do not fold correctly, which renders the bacteria avirulent. Thus DsbA is a critical mediator of virulence and inhibitors may act as antivirulence agents. Biophysical screening has been employed to identify fragments that bind to DsbA from Escherichia coli. Elaboration of one of these fragments produced compounds that inhibit DsbA activity in vitro. In cell-based assays, the compounds inhibit bacterial motility, but have no effect on growth in liquid culture, which is consistent with selective inhibition of DsbA. Crystal structures of inhibitors bound to DsbA indicate that they bind adjacent to the active site. Together, the data suggest that DsbA may be amenable to the development of novel antibacterial compounds that act by inhibiting bacterial virulence.

Drug discovery beyond the rule of 5 - opportunities and challenges

Targets that are ‘difficult-to-drug’ typically have binding sites that are large, highly lipophilic or polar, flexible, flat or featureless [1]. They contain few opportunities for high affinity interaction with drugs that comply with Lipinski’s rule of 5 [2] (Ro5) and are currently modulated with biologicals such as native proteins or antibodies. However, with few exceptions, biologicals lack cell permeability and can therefore not be used for intracellular targets nor can they be delivered orally. Unfortunately, many novel, potential drug targets identified through the rapid advances in genomics and proteomics are intracellular and may well be ‘difficult-to-drug’ with Ro5 compliant ligands, just as some established target classes. Development of approaches for modulation of difficult targets is therefore a key priority in efforts to deliver innovative medicines and to improve the efficacy of drug discovery.

Design of a Fragment-Screening Library

Herein we describe a method for the design, purchase, and assembly of a fragment-screening library from a list of commercially available compounds. The computational tools used in assessment of compound properties as well as the workflow for compound selection are provided for reference as implemented in commercially available software that is free and accessible to most academic users. The workflow can be modified as necessary to generate a fit-for-purpose fragment library with the desired compound property profiles. An analytical process for assessing the quality, identity, and suitability of a purchased fragment for inclusion in a screening collection is described. Results from our in-house library are presented as an example of compound progression through this quality control process.

Cyclophilin Succumbs to a Macrocyclic Chameleon

Targets that have large and groove-shaped binding sites, such as cyclophilin, are difficult to drug with small molecules. Macrocycles of natural product origin can be ideal starting points for such targets as illustrated by the transformation of sanglifehrin A into an orally bioavailable potential candidate drug. Optimization benefits from development of convergent, modular synthetic routes in combination with structure and property based methods for lead optimization.

Opportunities and guidelines for discovery of orally absorbed drugs in beyond rule of 5 space

Recent years have seen a dramatic increase in the number of drugs approved in chemical space outside of Lipinskis rule of 5, that is in what has been termed beyond rule of 5 (bRo5) space. The development of three major classes of oral drugs that treat HIV and HCV infections and the growing evidence that novel, difficult targets can be accessed has prompted research into understanding design of drugs displaying cell permeability, solubility and ultimately oral bioavailability in bRo5 space. Studies have found a consistent outer property limit for a reasonable chance of de novo designing oral bioavailability. In addition, several property-based guidelines, along with incorporation of chameleonic features, have emerged as strategies to aid design in bRo5 space. A more detailed understanding of the complex and environment dependent conformational landscape will likely be the focus of the next generation of guidelines allowing property predictions of ever more complex compounds. By pushing the boundaries of current orally designable chemical space we hope that discoveries will be made for fundamental science and also for discovery of novel therapeutics.