Functional and comparative genome analysis of novel virulent actinophages belonging to Streptomyces flavovirens

Prophage induction can facilitate the in vitro dispersal of multicellular Streptomyces structures

Streptomyces are renowned for their prolific production of specialized metabolites with applications in medicine and agriculture. These multicellular bacteria present a sophisticated developmental cycle and play a key role in soil ecology. Little is known about the impact of Streptomyces phage on bacterial physiology. In this study, we investigated the conditions governing the expression and production of "Samy", a prophage found in Streptomyces ambofaciens ATCC 23877. This siphoprophage is produced simultaneously with the activation of other mobile genetic elements. Remarkably, the presence and production of Samy increases bacterial dispersal under in vitro stress conditions. Altogether, this study unveiled a new property of a bacteriophage infection in the context of multicellular aggregate dynamics.

Genome dynamics, codon usage patterns and influencing factors in Aeromonas hydrophila phages

In the present study, genome characteristics and codon usage patterns of 44 Aeromonas hydrophila phages were studied. Phage genomes varied from 30.8 to 262.0 kb with mean±SD and median values of 111.3 ± 81.4 kb and 79.4 kb, respectively. Though the great variation in phage GC contents (35.1-62.2%) was observed, GC contents of all phages (except two phages) were significantly less than the GC content (62.4 ± 5.6%) of the host. The effective number of codons (ENC) values of phage genes ranged from 27.7 to 61 with a mean±SD value of 47.4 ± 6.8. Out of a total 5773 phage genes, 207 (3.6%), 3,528 (61.1%) and 2,012 (34.9%) genes had strong (ENC < 35), moderate (35 < ENC < 50) and low (ENC ≥ 50) codon usage bias, respectively. During relative synonymous codon usage (RSCU) analysis, shared usage of preferred codons was also observed between the phages and host. During codon adaptation index (CAI) analysis, 1028 (17.8%) phage genes showed significant adaptation towards the host. Among these genes, 797 (78.0%) genes encoded hypothetical proteins or proteins of unknown function; whereas 118 (12%) genes encoded the phage structural and packaging proteins. Segregation of ENC, RSCU and CAI analysis results based on genome size also indicated that codon usage bias was more prominent in phages with small genomes. Correlation, neutrality and GC3 versus ENC analyzes indicated a more dominant role of natural selection in shaping the codon usage patterns of A. hydrophila phages. The findings of the current study could be useful from evolutionary and host-pathogen interaction perspectives leading to efficient utilization of phages for therapeutic and other applications.

Phages for Africa: The Potential Benefit and Challenges of Phage Therapy for the Livestock Sector in Sub-Saharan Africa

One of the world’s fastest-growing human populations is in Sub-Saharan Africa (SSA), accounting for more than 950 million people, which is approximately 13% of the global population. Livestock farming is vital to SSA as a source of food supply, employment, and income. With this population increase, meeting this demand and the choice for a greater income and dietary options come at a cost and lead to the spread of zoonotic diseases to humans. To control these diseases, farmers have opted to rely heavily on antibiotics more often to prevent disease than for treatment. The constant use of antibiotics causes a selective pressure to build resistant bacteria resulting in the emergence and spread of multi-drug resistant (MDR) organisms in the environment. This necessitates the use of alternatives such as bacteriophages in curbing zoonotic pathogens. This review covers the underlying problems of antibiotic use and resistance associated with livestock farming in SSA, bacteriophages as a suitable alternative, what attributes contribute to making bacteriophages potentially valuable for SSA and recent research on bacteriophages in Africa. Furthermore, other topics discussed include the creation of phage biobanks and the challenges facing this kind of advancement, and the regulatory aspects of phage development in SSA with a focus on Kenya.

The Isolation and Characterization of Kronos, a Novel Caulobacter Rhizosphere Phage that is Similar to Lambdoid Phages

Despite their ubiquity, relatively few bacteriophages have been characterized. Here, we set out to explore Caulobacter bacteriophages (caulophages) in the rhizosphere and characterized Kronos, the first caulophage isolated from the rhizosphere. Kronos is a member of the Siphoviridae family since it has a long flexible tail. In addition, an analysis of the Kronos genome indicated that many of the predicted proteins were distantly related to those of bacteriophages in the lambdoid family. Consistent with this observation, we were able to demonstrate the presence of cos sites that are similar to those found at the ends of lambdoid phage genomes. Moreover, Kronos displayed a relatively rare head and tail morphology compared to other caulophages but was similar to that of the lambdoid phages. Taken together, these data indicate that Kronos is distantly related to lambdoid phages and may represent a new Siphoviridae genus.

Genome Sequences of Five Streptomyces Bacteriophages Forming Cluster BG

Cluster BG of the actinobacteriophage was formed upon discovery of five novel bacteriophages isolated by enrichment from their host, Streptomyces griseus subsp. griseus strain ATCC 10137. Four members of this cluster (BabyGotBac, Maih, TP1605, and YDN12) share over 89% average nucleotide identity, while the other (Xkcd426) has only 72% similarity to other cluster members.