Breaking antimicrobial resistance by disrupting extracytoplasmic protein folding.

Antimicrobial resistance in Gram-negative bacteria is one of the greatest threats to global health. New antibacterial strategies are urgently needed, and the development of antibiotic adjuvants that either neutralize resistance proteins or compromise the integrity of the cell envelope is of ever-growing interest. Most available adjuvants are only effective against specific resistance proteins. Here, we demonstrate that disruption of cell envelope protein homeostasis simultaneously compromises several classes of resistance determinants. In particular, we find that impairing DsbA-mediated disulfide bond formation incapacitates diverse ß-lactamases and destabilizes mobile colistin resistance enzymes. Furthermore, we show that chemical inhibition of DsbA sensitizes multidrug-resistant clinical isolates to existing antibiotics and that the absence of DsbA, in combination with antibiotic treatment, substantially increases the survival of Galleria mellonella larvae infected with multidrug-resistant Pseudomonas aeruginosa. This work lays the foundation for the development of novel antibiotic adjuvants that function as broad-acting resistance breakers.

Antibiotics, like penicillin, are the foundation of modern medicine, but bacteria are evolving to resist their effects. Some of the most harmful pathogens belong to a group called the 'Gram-negative bacteria', which have an outer layer ­ called the cell envelope ­ that acts as a drug barrier. This envelope contains antibiotic resistance proteins that can deactivate or repel antibiotics or even pump them out of the cell once they get in. One way to tackle antibiotic resistance could be to stop these proteins from working. Proteins are long chains of building blocks called amino acids that fold into specific shapes. In order for a protein to perform its role correctly, it must fold in the right way. In bacteria, a protein called DsbA helps other proteins fold correctly by holding them in place and inserting links called disulfide bonds. It was unclear whether DsbA plays a role in the folding of antibiotic resistance proteins, but if it did, it might open up new ways to treat antibiotic resistant infections. To find out more, Furniss, Kaderabkova et al. collected the genes that code for several antibiotic resistance proteins and put them into Escherichia coli bacteria, which made the bacteria resistant to antibiotics. Furniss, Kaderabkova et al. then stopped the modified E. coli from making DsbA, which led to the antibiotic resistance proteins becoming unstable and breaking down because they could not fold correctly. Further experiments showed that blocking DsbA with a chemical inhibitor in other pathogenic species of Gram-negative bacteria made these bacteria more sensitive to antibiotics that they would normally resist. To demonstrate that using this approach could work to stop infections by these bacteria, Furniss, Kaderabkova et al. used Gram-negative bacteria that produced antibiotic resistance proteins but could not make DsbA to infect insect larvae. The larvae were then treated with antibiotics, which increased their survival rate, indicating that blocking DsbA may be a good approach to tackling antibiotic resistant bacteria. According to the World Health Organization, developing new treatments against Gram-negative bacteria is of critical importance, but the discovery of new drugs has ground to a halt. One way around this is to develop ways to make existing drugs work better. Making drugs that block DsbA could offer a way to treat resistant infections using existing antibiotics in the future.

Molecular and epidemiological investigation of a colistin-resistant OXA-23-/NDM-1-producing Acinetobacter baumannii outbreak in the Southwest Indian Ocean Area.

Dual resistance to colistin and carbapenems is a milestone reached by certain extensively-drug resistant (XDR) Gram-negative bacteria. This study describes the first outbreak of XDR colistin- and carbapenem-resistant OXA-23-/NDM-1-producing Acinetobacter baumannii (CCRAB) in the European overseas territory of Reunion Island (France, Indian Ocean). Between April 2019 and June 2020, 13 patients admitted to the University Hospital of Reunion Island were involved in the outbreak, of whom eight were infected and six died. The first case was traced to a medical evacuation from Mayotte Island (Comoros archipelago). An epidemiological link could be established for 11 patients. All of the collected CCRAB isolates showed the same resistance profile and co-produced intrinsic ß-lactamases OXA-69 and ADC-191, together with acquired carbapenem-hydrolysing ß-lactamases OXA-23 and NDM-1. A mutation likely involved in colistin resistance was detected in the two-component system PmrAB (D82N in PmrA). All of the isolates were found to belong to STPas1/STOx231 clonal complex and were phylogenetically indistinguishable. Their further characterization by whole-genome sequence analyses (whole-genome multi-locus sequence typing, single nucleotide polymorphisms) provided hints about the transmission pathways. This study pleads for strict application of control and prevention measures in institutions where the risk of imported XDR bacteria is high.

Aztreonam plus Clavulanate, Tazobactam, or Avibactam for Treatment of Infections Caused by Metallo-ß-Lactamase-Producing Gram-Negative Bacteria.

Metallo-ß-lactamase (MBL)-producing Gram-negative bacteria are often extremely resistant, leading to a real therapeutic dead end. Here, we evaluated the in vitro and in vivo efficacy of aztreonam in combination with ceftazidime-avibactam, ceftolozane-tazobactam, or amoxicillin-clavulanate for the treatment of infections caused by MBL-producing Enterobacteriaceae, MBL-producing Pseudomonas aeruginosa, and extremely drug-resistant Stenotrophomonas maltophilia First, we report two clinical cases, namely, a urinary tract infection caused by an NDM-5-producing Escherichia coli isolate and a pulmonary infection caused by a S. maltophilia isolate efficiently treated with the association of aztreonam-ceftazidime-avibactam and aztreonam-amoxicillin-clavulanate, respectively. Then, a total of 50 MBL-producing Enterobacteriaceae isolates, 3 MBL-producing P. aeruginosa isolates, and 5 extremely drug-resistant S. maltophilia isolates were used to test aztreonam susceptibility in combination with ceftolozane-tazobactam, ceftazidime-avibactam, or amoxicillin-clavulanate. The Etest strip superposition method was used to determine the MICs of the aztreonam/inhibitor combinations. According to CLSI breakpoints, aztreonam susceptibility was fully restored for 86%, 20%, and 50% of the MBL-producing Enterobacteriaceae isolates when combined with ceftazidime-avibactam, ceftolozane-tazobactam, and amoxicillin-clavulanate, respectively. In P. aeruginosa, the aztreonam-ceftazidime-avibactam combination was the most potent, even though the reduction in MICs was at most 2-fold. With the 5 S. maltophilia isolates, aztreonam-ceftazidime-avibactam and aztreonam-amoxicillin-clavulanate were found to be equal (100% susceptibility). Overall, aztreonam-ceftazidime-avibactam was the most potent combination to treat infections caused by MBL producers compared with aztreonam-amoxicillin-clavulanate and aztreonam-ceftolozane-tazobactam. However, in many cases aztreonam-amoxicillin-clavulanate was found to be as efficient as aztreonam-ceftazidime-avibactam, offering the main advantage to be markedly cheaper. We also confirmed the validity of Etest superpositions as a very simple method to determine MICs of aztreonam combinations.

Genetic and biochemical characterization of OXA-405, an OXA-48-type extended-spectrum ß-lactamase without significant carbapenemase activity.

The epidemiology of carbapenemases worldwide is showing that OXA-48 variants are becoming the predominant carbapenemase type in Enterobacteriaceae in many countries. However, not all OXA-48 variants possess significant activity toward carbapenems (e.g., OXA-163). Two Serratia marcescens isolates with resistance either to carbapenems or to extended-spectrum cephalosporins were successively recovered from the same patient. A genomic comparison using pulsed-field gel electrophoresis and automated Rep-PCR typing identified a 97.8% similarity between the two isolates. Both strains were resistant to penicillins and first-generation cephalosporins. The first isolate was susceptible to expanded-spectrum cephalosporins, was resistant to carbapenems, and had a significant carbapenemase activity (positive Carba NP test) related to the expression of OXA-48. The second isolate was resistant to expanded-spectrum cephalosporins, was susceptible to carbapenems, and did not express a significant imipenemase activity, (negative for the Carba NP test) despite possessing a blaOXA-48-type gene. Sequencing identified a novel OXA-48-type ß-lactamase, OXA-405, with a four-amino-acid deletion compared to OXA-48. The blaOXA-405 gene was located on a ca. 46-kb plasmid identical to the prototype IncL/M blaOXA-48-carrying plasmid except for a ca. 16.4-kb deletion in the tra operon, leading to the suppression of self-conjugation properties. Biochemical analysis showed that OXA-405 has clavulanic acid-inhibited activity toward expanded-spectrum activity without significant imipenemase activity. This is the first identification of a successive switch of catalytic activity in OXA-48-like ß-lactamases, suggesting their plasticity. Therefore, this report suggests that the first-line screening of carbapenemase producers in Enterobacteriaceae may be based on the biochemical detection of carbapenemase activity in clinical settings.

In vivo acquired daptomycin resistance during treatment of methicillin-resistant Staphylococcus aureus endocarditis.

This clinical case reports the emergence of a daptomycin-resistant Staphylococcus aureus isolate during daptomycin treatment in a patient with right-sided infective endocarditis who had never been treated with vancomycin.