Role of Pseudomonas aeruginosa mifSR Two-Component System in Antibiotic Resistance and Biofilm Formation

Pseudomonas aeruginosa is an opportunistic pathogen found in a wide variety of environments. It is one of the leading causes of morbidity and mortality in cystic fibrosis patients, and one of the main sources of nosocomial infections in the United States. One of the most prominent features of this pathogen is its wide resistance to antibiotics. P. aeruginosa employs a variety of mechanisms including efflux pumps and the expression of B-lactamases to overcome antibiotic treatment. Two chromosomally encoded lactamases, ampC and poxB, have been identified in P. aeruginosa. Sequence analyses have shown the presence of a two-component system (TCS) called MifSR (MifS-Sensor and MifR-Response Regulator), immediately upstream of the poxAB operon. It is hypothesized that the MifSR TCS is involved in B-lactam resistance via the regulation of poxB. Recently, the response regulator MifR has been reported to play a crucial role in biofilm formation, a major characteristic of chronic infections and increased antibiotic resistance. In this study, mifR and mifSR deletion mutants were constructed, and compared to the wild type parent strain PAOl for differences in growth and B-lactam sensitivity. Results obtained thus far indicate that mifR and mifSR are not essential for growth, and do not confer B-lactam resistance under the conditions tested. This study is significant because biofilm formation and antibiotic resistance are two hallmarks of P. aeruginosa infections, and finding a link between these two may lead to the development of improved treatment strategies.

Role of AmpR and alginate production in Pseudomonas aeruginosa biofilm antibiotic resistance associated with cystic fibrosis

Pseudomonas aeruginosa is an ubiquitous Gram-negative opportunistic pathogen that is commonly found in nosocomial infections, immunocompromised patients and burn victims. In addition, P. aeruginosa colonizes the lungs of cystic fibrosis patients, leading to chronic infection, which inevitably leads to their demise. In this research, I analyzed the factors contributing to P. aeruginosa antibiotic resistance, such as the biofilm mode of growth, alginate production, and 13-lactamase synthesis. Using the biofilm eradication assay (MBEC™ assay), I exposed P. aeruginosa to B-lactams (piperacillin, ceftazidime, and cefotaxime ), aminoglycosides ( amikacin, tobramycin and gentamicin), and a fluoroquinolone ( ciprofloxacin) at various concentrations. I analyzed the effects of biofilm on P. aeruginosa antibiotic resistance, and confirmed that the parent strain PAO 1 biofilms cells were > 100 times more resistant than planktonic (freefloating) cells. The constitutively alginate-producing strain PDO300 exhibited an altered resistance pattern as compared to the parent strain P AO 1. Finally, the role of AmpR, the regulator of ampC-encoded 13-lactamase expression was analyzed by determining the resistance of the strain carrying a mutation in the ampR gene and compared to the parent strain PAOl. It was confirmed that the loss of ampR contributes to increased antibiotic resistance.

Multiplex PCR for Assessment of Tetracycline Resistance (tet) Genes in Antibiotic-Resistant Soil Bacteria and the Ecological Implications

Antibiotics are becoming increasingly prevalent in bacterial communities due to clinical and agricultural misuse and overuse in their environment. As exposure increases, so does the incidence of microbial resistance. Such is the case with bacterial resistance to tetracyclines, a phenotype often acquired through the horizontal gene transfer of tet genes between bacteria. The objective of this project was to analyze the bacterial diversity of tet resistance genes in soil from Miami-Dade County. Bacterial isolates were Gram-stained and the Kirby-Bauer antibiotic disk diffusion test was performed to determine each bacterium’s degree of resistance. The 16S rRNA gene from antibiotic-resistant isolates was amplified by PCR and sequenced to identify the isolates. All isolates’ tet genes were amplified by multiplex PCR, sequenced, and compared. Among eight isolates, three distinct species were positively identified based on their 16S rRNA sequences and four distinct tet genes were identified, though all tested susceptible to tetracycline via the Kirby-Bauer test. This project clarifies some aspects of the ecology of antibiotic resistance genes, their natural ecological function and the potential for the expansion of intrinsic multi-antibiotic resistance into new ecosystems and/or hosts.