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The discovery and implementation of antibiotics for clinical use was unquestionably the greatest medical breakthrough of the 20th century. However, the widespread misuse and overuse of these antibiotics, has led to the rapid emergence and spread of antibiotic resistance. The 'ESKAPE' pathogens (Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, and Enterobacter species) represent a critical threat in multidrug-resistant infections. The Gram-negative species (such as E. coli, K. pneumoniae, P. aeruginosa, and A. baumannii) are especially difficult to combat due to their dual-membrane and efficient efflux pumps, which limit the efficacy of many antibiotics. Despite significant efforts, no new antibiotic class with a new mechanism of action has been approved for Gram-negative pathogens in over five decades. New chemical classes of antibacterial compounds targeting distinct mechanisms within Gram-negative bacteria are therefore urgently called for. The studies outlined in this thesis addresses these challenges by designing and synthesising new antibacterial compounds of three distinct chemical classes, which interact with two unrealized targets, LepB and LpxH, in Gram-negative bacteria, including E. coli and K. pneumoniae.  This thesis investigates the effect of macrocyclization of type I signal peptidase (LepB) inhibitors by optimizing previously studied linear lipopeptide boronic acids and esters to address their cytotoxic and hemolytic liabilities while retaining activity. This resulted in the synthesis of first-in-class P2-P1' boronic ester-linked macrocycles with modest improvement of cytotoxicity but at the cost of reduced antibacterial activity (paper I). In another optimization attempt, isosteric modification of LepB inhibitors was explored by introducing the sulfonimidamide motif into oligopeptide boronic esters, displaying potent LepB inhibitors. Prior to the synthesis of these pseudopeptides novel methods were developed to introduce sulfonimidamides into peptides on solid-phase (paper II and paper III). These studies demonstrated the potential of sulfonimidamides to alter the drug properties and which was herein compared to a corresponding sulfonamide. Additionally, the thesis describes how a new series of LpxH inhibitors, meta-sulfonamidobenzamide-based sulfonyl piperazine derivatives, were identified and prepared. This resulted in inhibitors with wild-type activity without causing hemolysis, cell toxicity or inhibition of hERG ion channel (paper IV). In summary, strategies suitable for the synthesis and optimization of new antibacterial compounds targeting two distinct Gram-negative bacterial targets, LepB and LpxH, are described in this thesis. While there was no success in separating toxicity from antibacterial activity of the LepB inhibitors, these results highlight the challenge in this task and contribute to a better understanding of the structure-activity and toxicity relationships of such inhibitors and provide strategies that could be of use in antibacterial drug discovery. The identification of the meta-sulfonamidobenzamide derivatives offer promising LpxH-targeting hits with the potential for further development in future hit-to-lead antibacterial programs. 

New antibacterial compounds are urgently needed, especially for infections caused by the top-priority Gram-negative bacteria that are increasingly difficult to treat. Lipid A is a key component of the Gram-negative outer membrane and the LpxH enzyme plays an important role in its biosynthesis, making it a promising antibacterial target. Inspired by previously reported ortho-N-methyl-sulfonamidobenzamide-based LpxH inhibitors, novel benzamide substitutions were explored in this work to assess their in vitro activity. Our findings reveal that maintaining wild-type antibacterial activity necessitates removal of the N-methyl group when shifting the ortho-N-methyl-sulfonamide to the meta-position. This discovery led to the synthesis of meta-sulfonamidobenzamide analogs with potent antibacterial activity and enzyme inhibition. Moreover, we demonstrate that modifying the benzamide scaffold can alter blocking of the cardiac voltage-gated potassium ion channel hERG. Furthermore, two LpxH-bound X-ray structures show how the enzyme-ligand interactions of the meta-sulfonamidobenzamide analogs differ from those of the previously reported ortho analogs. Overall, our study has identified meta-sulfonamidobenzamide derivatives as promising LpxH inhibitors with the potential for optimization in future antibacterial hit-to-lead programs.

The ever-increasing number of bacteria resistant to the currently available antibacterial agents is a great medical problem today, and new antibiotics with novel mechanisms of action are urgently needed. Among the validated antibacterial drug targets against which new classes of antibiotics might be directed is bacterial type I signal peptidase (SPase I), an essential part of the Tat and Sec secretory systems. SPase I is responsible for the hydrolysis of the N-terminal signal peptides from proteins secreted across the cytoplasmic membrane and plays a key role in bacterial viability and virulence. This review focuses on the antibacterial activity of natural and synthetic SPase I inhibitors reported to date, namely beta-lactams, lipopeptides, and arylomycins, but also an example of SPase I activator was presented.

Oligopeptide boronates with a lipophilic tail are known to inhibit the type I signal peptidase in E. coli, which is a promising drug target for developing novel antibiotics. Antibacterial activity depends on these oligopeptides having a cationic modification to increase their permeation. Unfortunately, this modification is associated with cytotoxicity, motivating the need for novel approaches. The sulfonimidamide functionality has recently gained much interest in drug design and discovery, as a means of introducing chirality and an imine-handle, thus allowing for the incorporation of additional substituents. This in turn can tune the chemical and biological properties, which are here explored. We show that introducing the sulfonimidamide between the lipophilic tail and the peptide in a series of signal peptidase inhibitors resulted in antibacterial activity, while the sulfonamide isostere and previously known non-cationic analogs were inactive. Additionally, we show that replacing the sulfonamide with a sulfonimidamide resulted in decreased cytotoxicity, and similar results were seen by adding a cationic sidechain to the sulfonimidamide motif. This is the first report of incorporation of the sulfonimidamide functional group into bioactive peptides, more specifically into antibacterial oligopeptides, and evaluation of its biological effects.

Membrane proteins are frequently reconstituted in different detergents as a prerequisite to create a phospholipid environment reminiscent of their native environment. Different detergent characteristics such as their chain length and bond types could affect the structure and function of proteins. Yet, they are seldom taken into account when choosing a detergent for structural studies. Here, we explore the effect of different detergents and lipids with varying degrees of double- or single-bond composition on H-1-N-15 transverse relaxation optimized spectroscopy spectra of the outer membrane protein W (OmpW). We observed changes in nuclear magnetic resonance chemical shifts for OmpW reconstituted in micelles, bicelles, and nanodiscs, depending on their detergent/lipid composition. These results suggest that a careful evaluation of detergents is necessary, so as not to jeopardize the structure and function of the protein.

Many synthetic routes have been explored to make small molecule sulfonimidamides (SIAs), however, its introduction into larger molecules such as oligopeptides has not been studied before. We herein demonstrate three alternative and complementary methods for synthesis of SIA based pseudopeptides, on solid phase, using both on and off‐resin SIA‐synthesis, via sulfonimidoyl chlorides from sulfonamides, in high conversion. Beside evaluation of various resins such as 2‐CTC, Wang, and Rink amide‐ChemMatrix, the possibilities to further N‐functionalize and cyclize the SIA functionality on solid support are shown. The diastereomers of SIA containing pseudopeptides could in most cases be separated using normal reverse phase preparative HPLC. The solid phase SIA methodology has many advantages when it comes to handling and purification as compared to in solution, and will therefore enable exploration of the SIA group as isosteric substitutions and peptidomimetic building blocks in the development of drug‐like pseudopeptides in many ways. Of particular note these approaches facilitate combinatorial library synthesis as demonstrated herein.

Herein, we report the synthesis of novel sulfonimidamides (SIAs) based on amino acid building blocks using a one-pot method from tert-butyldiphenylsilyl-protected (TBDPS) sulfonamides, as well as exploration of orthogonal deprotection strategies. Among the several protecting groups investigated, TBDPS showed higher conversion, allowed UV detection and simple diastereomeric separation; in particular in combination with amino acid tert-butyl esters. Moreover, we applied the present method to synthesize cyclic five-membered acyl sulfonimidamides in two steps. The described synthesis of SIA-based amino acid building blocks in combination with the orthogonal protection groups provide access to unnatural amino acid building blocks useful for further incorporation into larger molecules, such as peptide-based transition-state analogues and peptidomimetics. The chirality of the SIA group, as well as its additional point of diversity provided by the extra NH group, creates opportunities for the development of unique compound libraries that explore new chemical space, which is of considerable importance for the pharmaceutical and agrochemical industry.

Type I signal peptidase, with its vital role in bacterial viability, is a promising but underexploited antibacterial drug target. In the light of steadily increasing rates of antimicrobial resistance, we have developed novel macrocyclic lipopeptides, linking P2 and P1' by a boronic ester warhead, capable of inhibiting Escherichia coli type I signal peptidase (EcLepB) and exhibiting good antibacterial activity. Structural modifications of the macrocyclic ring, the peptide sequence and the lipophilic tail led us to 14 novel macrocyclic boronic esters. It could be shown that macrocyclization is well tolerated in terms of EcLepB inhibition and antibacterial activity. Among the synthesized macrocycles, potent enzyme inhibitors in the low nanomolar range (e.g. compound 42f, EcLepB IC₅₀ = 29 nM) were identified also showing good antimicrobial activity (e.g. compound 42b, E. coli WT MIC = 16 μg/mL). The unique macrocyclic boronic esters described here were based on previously published linear lipopeptidic EcLepB inhibitors in an attempt to address cytotoxicity and hemolysis. We show herein that structural changes to the macrocyclic ring influence both the cytotoxicity and hemolytic activity suggesting that the P2 to P1' linker provide means for optimizing off-target effects. However, for the present set of compounds we were not able to separate the antibacterial activity and cytotoxic effect.