Investigation of bacteriophages in intensive care units

28.10.2019: Phages are a special form of virus that may prove effective as a new weapon against bacterial infections, especially in places where antibiotics fail due to multidrug resistance. The solution is not that easy, however. Phages not only infect bacteria; they may also develop a synergistic relationship with them, enabling the bacteria to persist for longer periods. Against this critical background, researchers from Vetmeduni Vienna and the private Karl Landsteiner University of Health Sciences have now published the world’s first study on the coexistence of phages and bacteria in intensive care units (ICUs).

It is general knowledge that, unfortunately, ICUs are critical locations for the transmission of dangerous microorganisms. What is less known is that bacteria may develop a synergistic relationship with a special form of virus called bacteriophages that allows the bacteria to develop new survival strategies.

Viruses and bacteria in the ICU

A research team led by Friederike Hilbert from the Department of Farm Animals and Veterinary Public Health at Vetmeduni Vienna and Cátia Pacífico from the private Karl Landsteiner University of Health Sciences have for the first time investigated the relationship between bacteriophages and bacteria in an intensive care unit. The researchers isolated Staphylococcus aureus from the surroundings of all patients examined but failed to detect lytic phages of either Staphylococcus or Escherichia coli in any of the samples. Despite the absence of lytic bacteriophages, two of the clinical isolates studied contained mitomycin C-inducible prophages. The study also highlights the problem of multidrug resistant bacteria in ICUs. Due to the use of virucidal disinfectants, phages were not viable in this study.

Friend or foe: bacteriophage viruses deserving of more attention

This study is particularly exciting because of the phages that were investigated. Not only can they prolong the persistence of bacteria, they can also kill them. Phages have therefore attracted interest as potential biocontrol agents, and bacteriophage-based products may be effective at eliminating or reducing the bacterial load in critical settings such as hospitals. The phages isolated in this study, however, show that further investigation is necessary on the functional diversity and impact of bacteriophages as well as their association with the bacteria living in the same environment. The findings from such studies will help to understand phage ecology and critically assess phage applications in the future.

Study enabled by technological progress

The study was made possible by several recent advances, in particular the development of high-throughput sequencing technologies enabling the complete characterization of microbiomes – not only bacteria but also viruses. Moreover, the scientific community is increasingly turning its attention to how microorganisms interact with the environment and with one another. Unlike the present study, previous work on the bacterial colonization of ICUs had not considered the role of bacteriophages.

Phages: constant, but little-known human companions

Phages are the most abundant members of the human virome and are present in every community examined. Their wide distribution in the environment impacts both viral diversification and the bacterial host, shaping microbial communities towards an expanded functional diversity of the ecosystems. So-called lytic phages kill their bacterial host cell, while temperate bacteriophages (or lysogenic phages) either integrate into the bacterial genome (forming a so-called prophage) or exist as a plasmid in the bacterial cytoplasm. The existence of prophages in the bacterial genome acts as a supplementary gene pool of horizontally transferred genes that confers higher fitness to the bacteria, for example thanks to the presence of virulence genes, antimicrobial resistance genes and/or survival factors.

The article “Characterization of Bacteria and Inducible Phages in an Intensive Care Unit” by Cátia Pacífico, Miriam Hilbert, Dmitrij Sofka, Nora Dinhopl, Ildiko-Julia Pap, Christoph Aspöck and Friederike Hilbert was published in the Journal of Clinical Medicine. 1

 

Further information


 

Scientific Contact

Friederike Hilbert

Unit of Food Hygiene and Technology

University of Veterinary Medicine Vienna (Vetmeduni Vienna)

T +43 1 25077-3316

Email to Friederike Hilbert

 

Cátia Pacífico

Unit of Food Hygiene and Technology

University of Veterinary Medicine Vienna (Vetmeduni Vienna)

Email an Cátia Pacífico


 

Released by

Nina Grötschl

Science Communication / Corporate Communications

University of Veterinary Medicine Vienna (Vetmeduni Vienna)

T +43 1 25077-1187

Mail to Nina Grötschl


 

Press Photo

Bacteriophages © Dinhopl
Bacteriophages © Dinhopl 2

 

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