G5 Doctoral dissertation (article)
Interacting microbes, a source for antimicrobial resistance propagation (2021)
Mikrobien väliset vuorovaikutukset antibioottivastustuskyvyn leviämistä ajavana voimana
Koskinen, K. (2021). Interacting microbes, a source for antimicrobial resistance propagation [Doctoral dissertation]. Jyväskylän yliopisto. JYU Dissertations, 413. http://urn.fi/URN:ISBN:978-951-39-8787-9
JYU authors or editors
Publication details
All authors or editors: Koskinen, Katariina
eISBN: 978-951-39-8787-9
Journal or series: JYU Dissertations
eISSN: 2489-9003
Publication year: 2021
Number in series: 413
Number of pages in the book: 1 verkkoaineisto (65 sivua, 33 sivua useina numerointijaksoina, 21 numeroimatonta sivua)
Publisher: Jyväskylän yliopisto
Place of Publication: Jyväskylä
Publication country: Finland
Publication language: English
Persistent website address: http://urn.fi/URN:ISBN:978-951-39-8787-9
Publication open access: Openly available
Publication channel open access: Open Access channel
Abstract
Microbial communities are highly abundant part of our biosphere and act as a source for the vast interactional network. This web of interactions not only affects the microbial behavior but also extends its causation to the human life as well. One of the most urgent threats microbes possess globally is antimicrobial resistance. Microbial communities consist of multiple participants, their metabolites, and the surrounding environment. In this thesis contribution of bacteria, their conjugative resistance plasmids, bacteriophages, and protozoa is studied in both microbial community settings and simplified assemblies. The effect of microbial interactions to the spread of antibiotic resistant bacteria and antibiotic resistance gene carrying conjugative plasmid persistence are examined in the thesis as well as the potential of bacteriophage therapy in overcoming antimicrobial resistance crisis. One of the main findings is the effect of both protozoan predation and leakiness of antibiotic resistance mechanisms that promote antibiotic resistance plasmid persistence in the multi-trophic community rather than the surrounding antibiotic pressure. Also, the both genomic and phenotypic characteristics were evaluated, to investigate the differences in the distribution patterns of multi-drug resistant bacteria. Found drought tolerance highly associated with the epidemical successfulness status of the studied strains. The interactions between bacteria and bacteriophages were further studied and the host spectrum of tectiviruses was expanded to consider four additional genera. Also, three novel phages with possible therapeutic potential against clinical host sample were characterized both genetically and morphologically. Furthermore, this group of phages was found to interact between each other throughout the susceptibility-shifting host. For its part this thesis broadens up the vision of microbial community relevance in antimicrobial resistance prevention and cure, as well as gives an insight to overcome the crisis antimicrobial resistance cause.
Keywords: pathogens; microbes; microbiome; bacteria; protozoa; plasmids; horizontal gene transfer; antibiotic resistance; bacteriophages; interaction
Free keywords: antimicrobial resistance; bacteria; bacteriophages; conjugative plasmids; microbial communities; protozoa
Contributing organizations
Ministry reporting: Yes
Reporting Year: 2021
