Small things matter : of phages and antibiotic resistance conferring plasmids
Viruses and plasmids are small units of genetic material dependent on cells
either transiently or continuously. Intriguingly, stories of these small entities
intertwine in antibiotic resistance crisis. Horizontal gene transfer enables
bacteria to respond rapidly to chances in their environment. Anthropogenic
consumption of antibiotics induces the travel of resistance encoding genes
mainly as passengers of conjugative plasmids. In this thesis, I demonstrate that
clinically important resistance plasmids could evolutionarily rescue susceptible
bacteria under lethal antibiotic concentrations. If mobile resistance genes are
available in surrounding community, administration of high doses of antibiotic
might not be enough to treat some bacterial infections – calling for alternatives
to fight multi-resistant bacteria and interfere the spread and maintenance of
resistance. Phage therapy, utilization of bacterial viruses against bacteria, could
be one such avenue. In this thesis plasmid-depended phage PRD1 was studied
in itself and as a tool to be utilized against resistance plasmid carrying bacteria.
Blue native polyacrylamide gel electrophoresis revealed interaction between
two virus entry related membrane proteins and zymogram analysis overruled a
previous model of the lytic enzyme residing at the genome-packaging vertex.
Bacterial resistance to PRD1 was linked with either lost or impaired conjugation
ability, that could restore only when the initial resistance-conferring mutation
was a dynamic tandem repeat insertion. Promisingly, the reversion also
returned the susceptibility to the phage. Yet, as plasmid-dependent phages are
currently available only against some resistance plasmids, an alternative
approach, on-demand isolation of phages, was investigated against common
nosocomial pathogens. Staphylococcus, Acinetobacter and Enterococcus phages
were scarce in the environmental reservoir whereas phages against E. coli, K.
pneumoniae, P. aeruginosa and Salmonella strains could often be isolated as
needed. Altogether, different manifestations of phage-therapy may provide
answers to the current antibiotic resistance crisis.
...
Publisher
University of JyväskyläISBN
978-951-39-6766-6ISSN Search the Publication Forum
1456-9701Keywords
Metadata
Show full item recordCollections
- Väitöskirjat [3574]
License
Related items
Showing items with similar title or keywords.
-
Counteracting the horizontal spread of bacterial antibiotic resistance with conjugative plasmid-dependent bacteriophages
Ojala, Ville (University of Jyväskylä, 2016) -
Preceding Host History of Conjugative Resistance Plasmids Affects Intra- and Interspecific Transfer Potential from Biofilm
Jonsdottir, Ilmur; Given, Cindy; Penttinen, Reetta; Jalasvuori, Matti (American Society for Microbiology, 2023)Conjugative plasmids can confer antimicrobial resistance (AMR) to their host bacterium. The plasmids disperse even between distantly related host species, rescuing the host from otherwise detrimental effects of antibiotics. ... -
Beta-Lactam Sensitive Bacteria Can Acquire ESBL-Resistance via Conjugation after Long-Term Exposure to Lethal Antibiotic Concentration
Ruotsalainen, Pilvi; Given, Cindy; Penttinen, Reetta; Jalasvuori, Matti (MDPI, 2020)Beta-lactams are commonly used antibiotics that prevent cell-wall biosynthesis. Beta-lactam sensitive bacteria can acquire conjugative resistance elements and hence become resistant even after being exposed to lethal (above ... -
Conjugative ESBL plasmids differ in their potential to rescue susceptible bacteria via horizontal gene transfer in lethal antibiotic concentrations
Mattila, Sari; Ruotsalainen, Pilvi; Ojala, Ville; Tuononen, Timo; Hiltunen, Teppo; Jalasvuori, Matti (Nature Publishing Group; Japan Antibiotics Research Association, 2017) -
Black Queen Evolution and Trophic Interactions Determine Plasmid Survival after the Disruption of the Conjugation Network
Cairns, Johannes; Koskinen, Katariina; Penttinen, Reetta; Patinen, Tommi; Hartikainen, Anna; Jokela, Roosa; Ruusulehto, Liisa; Viitamäki, Sirja; Mattila, Sari; Hiltunen, Teppo; Jalasvuori, Matti (American Society for Microbiology, 2018)Mobile genetic elements such as conjugative plasmids are responsible for antibiotic resistance phenotypes in many bacterial pathogens. The ability to conjugate, the presence of antibiotics, and ecological interactions all ...