Background: Bacterial soft rot caused by members of the soft rot Pectobacteriaceae afflicts plant production of both vegetable and ornamental crops. Recent outbreaks highlight Dickeya sp. in the etiology of this disease in potatoes. Since there is a lack of control strategies for these diseases, alternative approaches have been suggested, including the use of biological control mediated by bacteriophages (phages). However, phages infecting many of these members are still undiscovered or poorly described. Materials and Methods: Two phages targeting Dickeya dadantii subsp. dadantii (NCPPB 4097) were isolated from household organic waste and purified. They were then further characterized using whole-genome sequencing and comparative genomics, transmission electron microscopy, latent period and burst size. Results: Dickeya phage Sucellus displayed Siphovirus morphology and had a genome of 39,826 bp with very limited similarity to any previously described phages. Dickeya phage Amaethon had a Podovirus morphology with a genome comprising 41,436 bp and limited similarity to phages in the Kafuna genus. The phages exhibited burst sizes of app. 94 and 240 virions per cell with latent periods of 91 and 86 minutes for Sucellus and Amaethon, respectively. While both phages had similar adsorption efficiencies and latent periods, the rise periods for the two phages diverged markedly, highlighting an odd growth pattern. Conclusions: Together, the two phages isolated here expand the known diversity of phages infecting the important plant pathogen D. dadantii. As they both share limited similarity to previously described groups of phages, they likely constitute novel genera within their respective groups. Copyright 2020, Mary Ann Liebert, Inc., publishers.
Background: Bacterial soft rot caused by members of the soft rot Pectobacteriaceae afflicts plant production of both vegetable and ornamental crops. Recent outbreaks highlight Dickeya sp. in the etiology of this disease in potatoes. Since there is a lack of control strategies for these diseases, alternative approaches have been suggested, including the use of biological control mediated by bacteriophages (phages). However, phages infecting many of these members are still undiscovered or poorly described. Materials and Methods: Two phages targeting Dickeya dadantii subsp. dadantii (NCPPB 4097) were isolated from household organic waste and purified. They were then further characterized using whole-genome sequencing and comparative genomics, transmission electron microscopy, latent period and burst size. Results: Dickeya phage Sucellus displayed Siphovirus morphology and had a genome of 39,826 bp with very limited similarity to any previously described phages. Dickeya phage Amaethon had a Podovirus morphology with a genome comprising 41,436 bp and limited similarity to phages in the Kafuna genus. The phages exhibited burst sizes of app. 94 and 240 virions per cell with latent periods of 91 and 86 minutes for Sucellus and Amaethon, respectively. While both phages had similar adsorption efficiencies and latent periods, the rise periods for the two phages diverged markedly, highlighting an odd growth pattern. Conclusions: Together, the two phages isolated here expand the known diversity of phages infecting the important plant pathogen D. dadantii. As they both share limited similarity to previously described groups of phages, they likely constitute novel genera within their respective groups. Copyright 2020, Mary Ann Liebert, Inc., publishers.
Authors: Rebekah A Frampton; Corinda Taylor; Angela V Holguín Moreno; Sandra B Visnovsky; Nicola K Petty; Andrew R Pitman; Peter C Fineran Journal: Appl Environ Microbiol Date: 2014-01-31 Impact factor: 4.792
Authors: Sophie Kittler; Samuel Fischer; Amir Abdulmawjood; Gerhard Glünder; Günter Klein Journal: Appl Environ Microbiol Date: 2013-09-27 Impact factor: 4.792