Using permeation guidelines to design new antibiotics—A PASsagE into <i>Pseudomonas aeruginosa</i>
Brett N. Cain, Paul J. Hergenrother
Abstract
Dear Editor, The ability to employ small molecules to kill pathogenic bacteria and prevent serious illness or death has been one of mankind's greatest advances, as before the advent of the first antibiotics (salvarsan, penicillin) approximately 30% of deaths in the United States and United Kingdom were due to bacterial infections.1 This shield against disease, however, is weakening as resistance to approved antibiotics rises. Worryingly, no new class of antibiotics with activity against gram-negative bacteria has been approved by the FDA in over 55 years,2 with Pseudomonas aeruginosa being of particular concern. Multidrug-resistant P. aeruginosa is classified as a “serious threat” by the CDC and there are only four antibiotic classes regularly used to treat P. aeruginosa infections (β-lactams, aminoglycosides, fluoroquinolones, and polymyxins).3, 4 This dearth of therapeutic options makes the occurrence of drug-resistant P. aeruginosa even more troubling, and three of these drug classes (aminoglycosides, fluoroquinolones, and polymyxins) have serious toxicity concerns. As it stands approximately 85 000 deaths globally were attributed to antibiotic-resistant P. aeruginosa in 2019 alone, placing it among the six most deadly pathogens.5 Gram-negative pathogens are notorious for being difficult to penetrate with small molecules, and P. aeruginosa is particularly problematic in this regard, as it does not possess general diffusion porins and has many general and promiscuous efflux pumps.6, 7 Accordingly, a primary challenge in the development of new therapeutics for P. aeruginosa is achieving effective drug concentrations inside the cell, where many valuable antibacterial targets exist.8 To address this challenge, we have recently disclosed general permeation guidelines for P. aeruginosa, facilitating the design of small molecules that hijack the bacterium's self-promoted uptake pathway and gain intracellular access.9 For this work, the intracellular accumulation of individual members from a large and diverse compound collection was determined using an LC–MS/MS assay.10 Testing a diverse array of small molecules was critical for success, ensuring the results were not limited to compound classes possessing antibacterial activity. In addition to more typical drug-like small molecules, the collection contained novel, natural-product-like compounds constructed via the “complexity-to-diversity” approach.11 After experimentally measuring individual accumulation values for 345 compounds, the resulting data were interpreted with the help of a random forest classification model that pointed to certain characteristics associated with positive charge and hydrogen bond donation as important for P. aeruginosa accumulation. Specifically, compounds with appropriate positive polar surface area (Q_VSA_PPOS ≥ 80) and/or a positive formal charge (FC ≥ .98), as well as sufficient hydrogen bond donor surface area (HBDSA ≥ 23) have a high likelihood of accumulating in P. aeruginosa.9 The general permeation guidelines for P. aeruginosa can now be compared and contrasted with permeation guidelines disclosed in 2017 for another gram-negative pathogen, Escherichia coli.12 While there are similarities, the differences in the described physicochemical characteristics are linked back to differences in bacterial physiology (Figure 1). The guidelines pertaining to E. coli—the eNTRy rules12, 13—are rooted in optimizing small molecule entry through its major water-filled transport proteins called porins. In brief, the 2017 study found that the presence of an ionizable nitrogen on a compound with low three-dimensionality and high rigidity enabled accumulation in E. coli.12 The spatial characteristics of rigidity and globularity are important for traversing the narrow porin channel constriction zone, which ranges from approximately 7 to 11 angstroms.14 The critical presence of an ionizable nitrogen has been traced to its ability to engage in favourable electrostatic interactions with negatively-charged amino acids that line the porin constriction zone.12, 15-17 The P. aeruginosa permeation guidelines9—dubbed here the PASsagE rules (Pseudomonas aeruginosa Self-promoted Entry)—in contrast provide guidance for tailoring small molecules to productively access the self-promoted uptake pathway for entry into the cell, consistent with recent work from the Bumann lab suggesting that porins are not important for antibiotic uptake in P. aeruginosa.18 Notably, and in contrast with the eNTRy rules, the PASsagE rules have no flexibility and shape requirements, and instead appear to optimize favourable interactions of the small molecule with the gram-negative outer membrane through sufficient positive polar charge and HBDSA. Antibacterial drug discovery requires the developing team to balance a range of attributes including target essentiality, homology with analogous human target(s), toxicity, and druggability.19 For projects centred around combatting gram-negative bacteria, cellular permeability is also a particularly salient attribute. Often, there is a discordance between target engagement and access to the target, which manifests in reduced activity in whole-cell assays. For example, many gram-positive antibiotics are in fact effective against P. aeruginosa when tested against genetically engineered permeability-defect strains.20 To this end, these new rules can provide guidance to development teams about what modifications to make to enhance the accumulation of candidate antibiotics analogous to the routine procedure of optimizing lead compounds for solubility and pharmacokinetic properties based on known, fundamental principles. For a typical small molecule lead there are moieties that are critical for target binding (pharmacophore), and tangential functionality (auxophore) that can be altered in the optimization of non-target related properties, such as toxicity or solubility.21 These newly disclosed permeation rules can now be used to guide auxophore modification for enhanced P. aeruginosa accumulation. The eNTRy rules, put forth in 2017, have already accelerated gram-negative antibacterial campaigns and delivered high accumulating and active antibiotics via modification of the auxophore in many different contexts.22-33 Often, the eNTRy rules are used in campaigns that are centred around a small molecule that already possesses the necessary spatial parameters but lacks the amine required for gram-negative uptake. Although other ionizable nitrogen moieties can be beneficial for E. coli accumulation,34 primary amines typically result in the largest accumulation increase and are thus typically preferred. While the PASsagE rules do require positive polar charge to be present, this can take many forms beyond a primary amine. This can be observed, retrospectively, by considering tetracyclines. Although tetracycline itself has activity against many prominent gram-negative pathogens, including E. coli, it has an elevated minimum inhibitory concentration against P. aeruginosa, partially explained by the differential accumulation of tetracycline in these two pathogens (Figure 2A).9 However, additions of a secondary amine, tertiary amine, and secondary amide produce tigecycline, a compound within the PASsagE rules and one that gains accumulation and whole cell antibiotic activity against P. aeruginosa (Figure 2A). Tetracycline and tigecycline have nearly equivalent activity against a permeability-defect strains of P. aeruginosa,9 suggesting that target engagement is similar between these two compounds; efflux could also play a role in the differential activity of these compounds.35 The liberation from shape and flexibility requirements, and the unmooring from a primary amine, offers the medicinal chemist considerably more freedom in the chemical moieties available to tailor a small molecule to become PASsagE-compliant. Assessment of a generic scaffold shows the variety of functional groups able to increase HBDSA and polar positive surface area (Figure 2B), with some moieties (e.g., guanidiniums) altering both parameters simultaneously. With no restriction on spatial parameters, and no need for a primary amine, there is significant flexibility in the types of functionalities that can be added to a compound and aid in P. aeruginosa accumulation. The futility of whole-cell screening of industrial-style compound collections against gram-negative bacteria has been well-documented.36-38 The reasons behind this are not a mystery, as the large compound screening collections used by most research groups (academia and pharmaceutical industry) lack members with traits enabling gram-negative cell penetration; for example, only .1% of compounds in the Chembridge Microformat Library possess a primary amine.39 As compounds predisposed to penetrate gram-negative bacteria are not present in standard screening collections, turning to other sources for novel chemical matter makes sense with recent successes in discovering interesting antibacterial leads through mining “unculturable” bacteria,40 examining natural products produced by eukaryotic symbionts,41 and using non-standard chemical matter.42 A complimentary approach is chemically modifying a non-permeable antibiotic with functional groups that enhance accumulation; accumulation rules will guide such modifications and facilitate development of potent antibiotics. We thank Morgan K. Gugger for Figure 1, and we thank the National Institutes of Health (NIH) (AI176523) for support. National Institutes of Health, Grant/Award Number: AI176523.