Abstract
Prions are molecules characterized by self-propagation, which can undergo a conformational switch leading to the creation of new prions. Prion proteins have originally been associated with the development of mammalian pathologies; however, recently they have been shown to contribute to the environmental adaptation in a variety of prokaryotic and eukaryotic organisms. Bacteriophages are widespread and represent the important regulators of microbiota homeostasis and have been shown to be diverse across various bacterial families. Here, we examined whether bacteriophages contain prion-like proteins and whether these prion-like protein domains are involved in the regulation of homeostasis. We used a computational algorithm, prion-like amino acid composition, to detect prion-like domains in 370,617 publicly available bacteriophage protein sequences, which resulted in the identification of 5040 putative prions. We analyzed a set of these prion-like proteins, and observed regularities in their distribution across different phage families, associated with their interactions with the bacterial host cells. We found that prion-like domains could be found across all phages of various groups of bacteria and archaea. The results obtained in this study indicate that bacteriophage prion-like proteins are predominantly involved in the interactions between bacteriophages and bacterial cell, such as those associated with the attachment and penetration of bacteriophage in the cell, and the release of the phage progeny. These data allow the identification of phage prion-like proteins as novel regulators of the interactions between bacteriophages and bacterial cells.
Highlights
Prions were demonstrated to play important roles in eukaryotes and prokaryotes, and they have been intensively studied during the last decade (Alberti et al, 2009)
The presence of prionogenic domains (PrDs) was analyzed in all bacteriophage proteins using the prion-like amino acid composition (PLAAC) prion prediction program based on the hidden Markov model (HMM) and trained using the known PrDs, by identifying the compositional bias toward N and Q residues
The results of our study underline the necessity of characterizing bacteriophages and we propose here that the all bacteriophage genes should be known as the phagobiome
Summary
Prions were demonstrated to play important roles in eukaryotes and prokaryotes, and they have been intensively studied during the last decade (Alberti et al, 2009). Prions are characterized by a process in which the infectious form of prion (PrPSc) interacts with the endogenous PrPs, catalyzing the transformation of the endogenous molecule into misfolded PrPSc aggregates (Ma and Lindquist, 2002). This was first observed in mammals, and the pathological deposition of insoluble protein aggregates was shown to be associated with the development of a number of human diseases, including scrapie, Creutzfeldt-Jakob disease, Alzheimer’s disease, Parkinson’s disease, amyloidosis, and other (Collinge, 2001; Wemheuer et al, 2017). One of the best-known forms of PrPs are amyloid proteins that, in addition to the role of infectious agents, were shown to be an important component of many physiological processes in eukaryotes and prokaryotes (Westergard et al, 2007; Sabate et al, 2015; Walker et al, 2016).
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