Antibiotic resistance has been declared one of the three greatest threats to human health by the World Health Organization. Infections caused by multi-drug resistant (MDR) bacterial pathogens create substantial health and economic impacts on society due to the lack of effective therapeutic options created by the rapid acquisition of resistance and stagnant antibiotic development programs. This lack of treatment options is particularly relevant for MDR Gram-negative pathogens, such as Pseudomonas aeruginosa, Acinetobacter baumanii and Klebsiella pneumoniae, which have shown a great propensity to thwart antibiotic treatments and standard hospital disinfection procedures. Agile Sciences is developing a novel class of small molecules, based on a 2-aminoimidazole (2-AI) scaffold, that substantially increase the susceptibility of MDR bacteria to antibiotic therapies. As an adjuvant therapy to current antibiotics, the 2-AI molecules have the potential to provide a much improved treatment option for MDR Gram-negative bacterial infections. Phase I equivalent work has displayed the potential of 2-AI compounds as antibiotic potentiating agents against MDR Gram-negative bacterial pathogens. Our efforts have shown that: 1) two lead compounds, AGL- 503 and AGL-553, are able to lower the antibiotic MIC values against MDR Gram-negative bacteria; 2) an AGL-503-meropenem combination therapy has the ability to enhance survival and decrease bacterial burden (compared to meropenem alone) in a MDR P. aeruginosa acute lung infection model; 3) 2-AI compounds possess favorable safety and pharmaceutical profiles; and 4) 2-AI compounds act via a novel mechanism of action that retards antimicrobial resistance. Collectively, this data provides strong support for a continued development program to define the potential therapeutic utility of the 2-AI class of molecules as an antibiotic combination therapy for treating infections caused by MDR Gram-negative bacteria. In Phase II, we will focus development of the 2-AI class of molecules to address the substantial unmet need posed by MDR Gram-negative bacterial infections. First, in Aim 1, we will identify the optimal antibiotic combinations for the lead 2-AI compounds against P. aeruginosa, K. pneumoniae, and A. baumanii. The optimal combinations will be evaluated for pharmacodynamics using the mouse thigh infections mode. In Aim 2, the off-target effects of AGL-503 and AGL-553 will be evaluated through off-target panel screens and characterizations of target binding. The 2-AI-antibitoic combination with the most promising results in Aim 1 will be evaluated for safety and efficacy in pneumonia and urinary tract infection murine models. The efforts in Aim 3 will inform the target product profile (TPP) of the candidate compound, and preliminary scale-up work will be performed to facilitate transfer of the synthetic route of the compound to a contract manufacturing organization. At the conclusion of this two-year grant, Agile Sciences will have declared an IND candidate compound and defined the TPP so as to facilitate follow-on IND-enabling studies.
Public Health Relevance Statement: Public Health Relevance: The prevalence of multidrug resistant bacterial infections is growing rapidly, and these infections are increasingly difficult to treat with existing antibiotics Agile Sciences is developing a new class of small molecules that act via a novel mode of action to enhance the ability of antibiotics to treat infections caused by Gram-negative antibiotic resistant bacteria.
NIH Spending Category: Antimicrobial Resistance; Biodefense; Emerging Infectious Diseases; Infectious Diseases; Lung; Pneumonia; Pneumonia & Influenza
Project Terms: Acinetobacter; Acinetobacter baumannii; Acute; Address; Adjuvant Therapy; Antibiotic Resistance; Antibiotic Therapy; Antibiotics; Antimicrobial Resistance; Bacteria; Bacterial Infections; Bacterial Interference; base; Binding; Binding Proteins; Centers for Disease Control and Prevention (U.S.); Cessation of life; Chemosensitization; combat; Combined Antibiotics; Combined Modality Therapy; Contracts; Crystallography; Data; Defense Mechanisms; Development; Disinfection; disorder prevention; drug candidate; Drug Kinetics; Drug resistance; drug resistant bacteria; economic impact; Evaluation; exhaust; Formulation; Future; Goals; Gram-Negative Bacteria; Gram-Negative Bacterial Infections; Grant; Health; Health Care Costs; health economics; Hospitals; Human; improved; in vivo; Infection; Investigational Drugs; Klebsiella pneumonia bacterium; Lead; Lung; Maximum Tolerated Dose; Meropenem; Metabolic; Minimum Inhibitory Concentration measurement; Modeling; mouse model; Multi-Drug Resistance; multidrug-resistant Pseudomonas aeruginosa; Mus; novel; OmpR protein; pathogen; Performance; Pharmacodynamics; Pharmacologic Substance; Phase; Plasma Proteins; Pneumonia; pre-clinical; Predisposition; Prevalence; Procedures; Program Development; programs; Property; Pseudomonas aeruginosa; Resistance; Route; Safety; scaffold; scale up; Science; signal processing; small molecule; Societies; Structure; System; Technology; Therapeutic; Thigh structure; Urinary tract infection; Work; World Health Organization
