Browsing by Subject "faagiterapia"
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(2019)Antibiotic-resistant bacteria are an increasing threat to global health, caused by the excessive use of antibiotics and the lack of new antimicrobial agents being introduced to the market. New approaches to prevent and cure bacterial infections are needed to halt the growing crisis. One of the most promising alternatives is phage therapy which utilizes bacteriophages to target and kill pathogens with specificity. Pseudomonas aeruginosa is a common opportunistic pathogen that is intrinsically resistant to antibiotics, making it one of the most heavily studied targets of phage therapy. In this study, I characterized four P. aeruginosa phages, fHo-Pae01, PA1P1, PA8P1 and PA11P1, and evaluate their potency in therapeutic applications. Bioinformatic analysis of the genomes revealed the phages to be genetically highly similar and belonging to the Pbunavirus genus of the Myoviridae family. No genes encoding harmful toxins, antibiotic-resistance, or lysogeny were predicted. On the other hand, many of the predicted genes had unknown functions. The host ranges of the phages were assessed using 47 clinical P. aeruginosa strains and predicted host receptor binding tail proteins were compared. Some correlation between the host ranges and mutations in the tail proteins were observed but this alone was not sufficient to explain the differences in the host ranges. The recently isolated vB_PaeM_fHoPae01 (fHo-Pae01) phage was further characterized by a one-step growth curve and imaged with a promising atomic force microscopy method that had not been used before in the Skurnik group. Though the imaging results failed to provide any further knowledge of the phage, the 70-minute-long latent period of infection could be determined from the growth curve. Anion- exchange chromatography was found inefficient in purifying the fHo-Pae01 phage, so alternative methods such as endotoxin columns should be used when purifying these phages for patient use. In conclusion, all four phages appeared to be safe for therapeutic use based on current knowledge, and PA1P1 and PA11P1 were the most promising candidates due to their broad host ranges.
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Isolation and characterization of new bacteriophages against clinical Klebsiella pneumoniae strains (2023)The objective of this thesis was to isolate and characterize new bacteriophages (phages) against clinical Klebsiella pneumoniae strains for phage therapy. K. pneumoniae is causing an emerging threat to global health due to its broad antibiotic resistance profile and hypervirulent strains. New treatment options are urgently needed to defeat the crisis. Phage therapy could provide one option to treat multiresistant K. pneumoniae infections. In this thesis, five new phages were isolated and characterized from Finnish wastewater and Georgian river water against two clinical K. pneumoniae strains. The three phages from Georgian river water, fMtkKpn01, fMtkKpn03, and fMtkKpn04, resembled Drulisviruses based on phylogenetic analysis. The two phages from Finnish wastewater, fJoKpn03 and fJoKpn05 were phylogenetically distinct. fJoKpn03 couldn’t be classified. fJoKpn05 resembled Weberviruses. Based on sequence analysis, none of the phage genomes included any harmful genes that would prevent their use in phage therapy. All phages demonstrated a 6-hour total inhibition to host bacterial growth. Their host range was determined to be narrow, only infecting their respective host strains from the 80 bacterial strains tested. All the phages tolerated high pH well. fJoKpn03 was the only one tolerating very low pH. All phages showed a synergistic effect on the inhibition of bacterial growth when applied together with piperacillin. In conclusion, all five phages proved potential for phage therapy. They demonstrated inhibitory action against K. pneumoniae strains with capsule types against which there previously were no phages in our collection. Due to their narrow host range, they could be suited for personalized phage therapy or used in combination therapy with antibiotics to increase efficacy and duration of action. fJoKpn03 could provide an opportunity for oral administration due to its broad pH stability profile.
Now showing items 1-2 of 2