Staphylococcus aureus in Non-Cystic Fibrosis Bronchiectasis: Prevalence and Genomic Basis of High Inoculum ß-Lactam Resistance.

Rationale: The pathobiology of Staphylococcus aureus in non-cystic fibrosis bronchiectasis (nCFB) is poorly defined. When present at high density or "inoculum," some methicillin-sensitive S. aureus (MSSA) can inefficiently degrade antistaphylococcal ß-lactam antibiotics via BlaZ penicillinases (termed the "inoculum effect" [IE]). Given the high burden of organisms in bronchiectatic airways, this is particularly relevant. Objectives: Drawing from a prospectively collected biobank, we sought to understand the prevalence, natural history, potential for transmission, and antibiotic resistance profiles among nCFB-derived MSSA isolates. Methods: All individuals attending a regional consultancy nCFB clinic with sputum collected between 1981 and 2017 were considered, and those with one or more S. aureus-positive cultures composed the cohort. Each individual's most recent biobank isolate was subjected to whole-genome sequencing (including the blaZ gene), antibacterial susceptibility testing, and comparative ß-lactam testing at standard (5 × 105 colony-forming unit [cfu]/ml) and high (5 × 107 cfu/ml) inocula to assess for the IE and pronounced IE. Results: Seventy-four (35.4%) of 209 individuals had one or more sputum samples with S. aureus (68 MSSA, 6 methicillin-resistant S. aureus). Those with S. aureus infection were more likely to be female. Among 60 of 74 MSSA isolates subjected to whole-genome sequencing, no evidence of transmission was identified, although specific multilocus sequence typing types were prevalent, including ST-1, ST-15, ST-30, and ST-45. Antibiotic resistance was uncommon, except for macrolides (∼20%). Among the 60 MSSA samples, the prevalence of IE and pronounced IE was observed to be drug specific: meropenem (0% and 0%, respectively), cefepime (3% and 5%, respectively), ceftazidime (8% and 0%, respectively), cloxacillin (12% and 0%, respectively), cefazolin (23% and 0%, respectively), and piperacillin-tazobactam (37% and 17%, respectively). The cefazolin IE was associated with blaZ type A (P < 0.01) and ST-30 (P < 0.01), whereas the piperacillin-tazobactam IE was associated with type C blaZ (P < 0.001) and ST-15 (P < 0.05). Conclusions:S. aureus infection was common, although no evidence of transmission was apparent in our nCFB cohort. Although routine susceptibility testing did not identify significant resistance, inoculum-related resistance was found to be relevant for commonly used nCFB antibiotics, including cefazolin and piperacillin-tazobactam. Given previous associations between IEs and negative patient outcomes, further work is warranted to understand how this phenotype impacts nCFB disease progression.

Assessment of the combination of doripenem plus a fluoroquinolone against non-susceptible Acinetobacter baumannii isolates from nosocomial pneumonia patients.

Carbapenem- and fluoroquinolone-non-susceptible Acinetobacter baumannii were obtained from four nosocomial pneumonia patients who were clinically cured following combination therapy with doripenem/levofloxacin or ciprofloxacin. In vitro synergy of doripenem/levofloxacin or ciprofloxacin was evaluated using time-kill analysis. In vivo synergy was tested using a mouse lethal infection model. In time-kill studies, doripenem and levofloxacin were both bactericidal when tested at Cmax; at ½Cmax, the combination showed synergy up to 8 hours. Ciprofloxacin, alone or combined with doripenem, was not bactericidal. For mouse septicemia, doripenem (100 mg/kg) was ≥90% effective in preventing death in all four isolates. Levofloxacin (200 mg/kg) was 73% effective, and ciprofloxacin (35 mg/kg) was ineffective in preventing death. At lower drug concentrations, increased efficacy was observed for doripenem/levofloxacin, but not for doripenem/ciprofloxacin. Overall, the results suggest that a doripenem/levofloxacin combination may have clinical utility in treating some non-susceptible A. baumannii infections.

New antibiotic agents and approaches to treat biofilm-associated infections.

IMPORTANCE OF THE FIELD: Current antibiotics have classically been developed to treat infections involving planktonic bacterial populations in acute infection settings and are typically ineffective in the eradication of bacteria in biofilm-associated, persistent infections. The paucity of effective current treatment options and the growing population of susceptible patients with indwelling medical devices and materials are key factors that substantiate the need for new agents effective in the prevention or eradication of biofilms. AREAS COVERED IN THIS REVIEW: Published patents relating to biofilm-active agents were identified in SciFinder(®) for the period January 2005 through March 2010 and representative patents selected with an emphasis on agents claimed for the prophylaxis or treatment of bacterial biofilm infections. WHAT THE READER WILL GAIN: The review provides a basic understanding of the medical challenges posed by biofilm-associated infections, and summarizes claims describing novel therapeutic approaches in the management of biofilm infections. TAKE HOME MESSAGE: Treatment of biofilm-associated infections with existing approved therapies remains a significant medical challenge. In the near term, new agents demonstrating bactericidal activity against bacteria within biofilms will be most readily incorporated into existing treatment paradigms. Alternative approaches that impact biofilm formation or dispersion are promising, but remain to be validated clinically.

New C25 carbamate rifamycin derivatives are resistant to inactivation by ADP-ribosyl transferases.

A novel series of 3-morpholino rifamycins in which the C25 acetate group was replaced by a carbamate group were prepared and found to exhibit significantly improved antimicrobial activity than rifampin against Mycobacterium smegmatis. Further characterization of such compounds suggests that relatively large groups attached to the rifamycin core via a C25 carbamate linkage prevent inactivation via ribosylation of the C23 alcohol as catalyzed by the endogenous rifampin ADP-ribosyl transferase of M. smegmatis. SAR studies of the C25 carbamate rifamycin series against M. smegmatis and other bacteria are reported.