1066. In Vitro and in Vivo Antimicrobial Activity of Cefiderocol and Comparators against Achromobacter spp

Abstract Background Achromobacter spp. is intrinsically resistant to multiple antibiotics, and the treatment options are limited. Cefiderocol (CFDC), a siderophore cephalosporin approved in US and EU, is active against a wide variety of aerobic Gram-negative bacteria, including carbapenem-resistant strains. In this study, in vitro and in vivo antibacterial activity of CFDC against Achromobacter spp. was evaluated. Methods A total of 334 global isolates collected by IHMA from 39 countries in 2015-2019 were used. Minimum inhibitory concentrations (MICs) of CFDC and comparators were determined by broth microdilution method using iron-depleted CAMHB or CAMHB, respectively, as recommended by CLSI guidelines. In vivo efficacy of CFDC was compared with meropenem (MEM), piperacillin-tazobactam (PIP/TAZ), ceftazidime (CAZ), and ciprofloxacin (CIP) in a neutropenic murine lung infection model (n=5), and compared with MEM in a immunocompetent rat lung infection model (n=3-7) caused by 2 A. xylosoxydans. In the murine model, treatment was given 2, 5, and 8 hours post-infection, and the numbers of viable cfu in lungs were determined 24 hours post-infection. In the rat model, the humanized PK in plasma resulting from CFDC 2 g every 8 h (3-h infusion) or meropenem 1 g every 8 h (0.5-h infusion) were recreated via continuous intravenous infusion for 4 days, following which cfu in lungs were determined. Results CFDC showed in vitro activity with MIC50/90 of 0.06/0.5 µg/mL against 334 Achromobacter spp. Only 7 isolates (2.1%) had MICs > 4 µg/mL. These were the lowest values among all compound tested (Table). In the murine model, CFDC caused > 1.5 log10 decrease of viable cfu in lungs at 100 mg/kg dose (%fT >MIC: < 50%) from baseline control against both of strains (CFDC MIC: 0.5 and 2 µg/mL) (P< 0.05). No decrease of cfu in lungs was observed for the comparators at 100 mg/kg (MEM, PIP/TAZ, CAZ, and CIP MICs were >16, >64, >32, and >8 µg/mL, respectively). In the rat model, humanized CFDC dosing reduced the viable cfu by >1 log10 CFU/lung compared with baseline controls (P< 0.05). MEM showed no significant activity. In vitro activity of CFDC and comparator agents against Achromobacter spp. 334 Achromobacter spp. isolates collected from 2015 and 2019. The majority of isolates tested were A. xylosoxidans (312/334; 93.4%), followed by A. insolitus (11/334; 3.3%), Achromobacter sp. (8/334; 2.4%), A. denitrificans (2/334; 0.6%), and A. piechaudii (1/334; 0.3%). Conclusion CFDC showed potent in vivo efficacy reflecting in vitro activity against A. xylosoxidans. The results suggested that CFDC has the potential to be an effective therapeutic option for Achromobacter spp. infections. Disclosures Ryuichiro Nakai, MSc, Shionogi TechnoAdvance Research & Co., Ltd. (Employee) Ayaka makino, BSc, Shionogi TechnoAdvance Research & Co., Ltd. (Employee) Toriko Yoshitomi, -, Shionogi TechnoAdvance Research & Co., Ltd. (Employee) Rio Nakamura, BSc, Shionogi TechnoAdvance Research & Co., Ltd. (Employee) Meredith Hackel, PhD MPH, IHMA (Employee)Pfizer, Inc. (Independent Contractor) Miki Takemura, MS, SHIONOGI & CO., LTD. (Employee) Daniel F. Sahm, PhD, IHMA (Employee)Pfizer, Inc. (Independent Contractor) Yoshinori Yamano, PhD, Shionogi (Employee)

trimethoprim-sulfamethoxazole (T/S) is considered to be the first-line therapy for Stenotrophomonas pneumonia. Cefiderocol (CFDC) is a new parenteral siderophore cephalosporin that is transported through the outer cell membrane as a siderophore mimic that then inhibits Gram-negative cell wall biosynthesis. CFDC has potent activity in vitro against S. maltophilia; however, little is known about its in vivo activity against Stenotrophomonas pneumonia in immunocompromised hosts. We therefore studied CFDC in comparison to TS in the persistently neutropenic rabbit model of Stenotrophomonas pneumonia. This rabbit model, in contrast to conventional murine models, reflects the human pattern of infection more accurately over time.
Methods. We initially studied the plasma pharmacokinetics of CFDC in non-infected and infected animals. Stenotrophomonas pneumonia was established by direct endotracheal inoculation of S. maltophilia 1×10 10 CFUs for tracheobronchial colonization that evolved into bronchopneumonia. Experimental groups consisted of CFDC, T/S, and untreated controls (UC). Rabbits received CFDC at 120 mg/kg IV Q8h and T/S at 5 mg/kg IV Q12h. Profound persistent neutropenia was maintained with cytosine arabinoside. Treatment was continued for 10 days.
Results. There were no significant differences between non-infected and infected rabbits in CFDC pharmacokinetics. Rabbits treated with CFDC and T/S demonstrated significant decreases of residual pulmonary and BAL bacterial burden vs UC (p≤0.001). CFDC achieved full clearance of S. maltophilia from lung tissue and BAL. This antibacterial activity coincided with significant reduction of lung weights (marker of organism-mediated pulmonary injury) in the CFDC group vs T/S and UC (p< 0.01). Survival was prolonged in the CFDC treatment group with 87% survival in comparison to that of T/S (25%) and UC (0%) (p< 0.01).

Session: P-61. Novel Agents
Background. Achromobacter spp. is intrinsically resistant to multiple antibiotics, and the treatment options are limited. Cefiderocol (CFDC), a siderophore cephalosporin approved in US and EU, is active against a wide variety of aerobic Gram-negative bacteria, including carbapenem-resistant strains. In this study, in vitro and in vivo antibacterial activity of CFDC against Achromobacter spp. was evaluated.
Methods. A total of 334 global isolates collected by IHMA from 39 countries in 2015-2019 were used. Minimum inhibitory concentrations (MICs) of CFDC and comparators were determined by broth microdilution method using iron-depleted CAMHB or CAMHB, respectively, as recommended by CLSI guidelines. In vivo efficacy of CFDC was compared with meropenem (MEM), piperacillin-tazobactam (PIP/TAZ), ceftazidime (CAZ), and ciprofloxacin (CIP) in a neutropenic murine lung infection model (n=5), and compared with MEM in a immunocompetent rat lung infection model (n=3-7) caused by 2 A. xylosoxydans. In the murine model, treatment was given 2, 5, and 8 hours post-infection, and the numbers of viable cfu in lungs were determined 24 hours post-infection. In the rat model, the humanized PK in plasma resulting from CFDC 2 g every 8 h (3-h infusion) or meropenem 1 g every 8 h (0.5-h infusion) were recreated via continuous intravenous infusion for 4 days, following which cfu in lungs were determined.
In vitro activity of CFDC and comparator agents against Achromobacter spp.
Conclusion. CFDC showed potent in vivo efficacy reflecting in vitro activity against A. xylosoxidans. The results suggested that CFDC has the potential to be an effective therapeutic option for Achromobacter spp. infections.
Disclosures Background. Invasive fungal infections account for a high burden of morbidity and mortality. This is aggravated because of the toxicity and resistance problems associated to current antifungal drugs, which in whole target only a handful of fungal molecules. In this scenario, new target identification and drug design, together with drug repurposing, represent promising strategies.
Methods. We aim to identify and test in vitro potential new therapeutic targets in fungi. Our strategy consists in identifying fungal proteins with active sites (meaning the set of residues lining the binding pocket) that are similar, but not identical!, to sites of proteins from the human pharmacolome. A high structural similarity with a human counterpart allows validation of the fungal target using cross-reactive inhibitors of the human protein. On the other hand, a few amino acid differences in the binding pocket produce local topological and chemical changes that create a "design space" for new specific inhibitors of the fungal target.
Results. Applying our own bioinformatics approach and taking advantage of the >200 available crystal structures of proteins of the human pharmacolome in complex with inhibitors, we have identified ca. 30 proteins in several fungal species of the genera Histoplasma, Candida, Criptococcus, Aspergillus and Fusarium, whose binding sites share at least 70% amino acid identity with their similar binding pockets in human pharmaceutical targets. So far we have assayed in vitro, in seven different fungal species, ca. 60 known inhibitors of around twenty of the orthologous human proteins. Some of the tested inhibitors have been previously assayed in different species in drug repurposing screenings, while others, to our knowledge, have not been yet tested. Over a dozen of these compounds, targeting eight different protein targets, showed IC50 values in the micromolar order in one or across several species. In general, yeasts were more significantly affected than molds.
Conclusion. Our results point to new potential fungal targets that can be exploited for the design of new antifungal agents. Ongoing work by our group aims to identify, by virtual screening, specific inhibitors for several of these potential targets.
Disclosures. All Authors: No reported disclosures