Evolution of the linear chromosomal DNA in Streptomyces: is genomic variability developmentally modulated?

Natural combinatorial biosynthesis involving two clusters for the synthesis of three pyrrolamides in Streptomyces netropsis

The pyrrolamides constitute a small family of secondary metabolites that are known for their ability to bind noncovalently to the DNA minor groove with some sequence specificity. To date, only a single pyrrolamide biosynthetic gene cluster has been reported, directing the synthesis of congocidine (netropsin) in Streptomyces ambofaciens. In this study, we improve our understanding of pyrrolamide biosynthesis through the identification and characterization of the gene cluster responsible for the production of distamycin in Streptomyces netropsis DSM40846. We discover that the strain produces two other pyrrolamides, the well-characterized congocidine and a congocidine/distamycin hybrid that we named disgocidine. S. netropsis DSM40846 genome analysis led to the identification of two distinct pyrrolamide-like biosynthetic gene clusters. We show here that these two clusters are reciprocally dependent for the production of the three pyrrolamide molecules. Furthermore, based on detailed functional analysis of these clusters, we propose a biosynthetic route to congocidine and distamycin and an updated model for pyrrolamide assembly. The synthesis of disgocidine, the distamycin/congocidine hybrid, appears to constitute the first example of "natural combinatorial biosynthesis" between two related biosynthetic pathways. Finally, we analyze the genomic context of the two biosynthetic gene clusters and suggest that the presently interdependent clusters result from the coevolution of two ancestral independent pyrrolamide gene clusters.

Genetic instability of whiG gene during the aerial mycelium development of Streptomyces ambofaciens ATCC23877 under different conditions of nitrogen limitations

In Streptomyces ambofaciens, white papillae that genetic instability events generate during aerial mycelium growth, give rise to Pig-pap mutants which are unable to sporulate and devoid of large genome rearrangement. Knowing that genetic and environmental factors can influence the number of papillae per colony, we investigated the effect of nutrient limitated conditions of growth on the formation of white papillae. We observed that under nitrogen limitation and, most particularly, under amino acid limitation, the number of papillae per colony dramatically increased. Most of the Pig-pap mutants deriving from such papillae displayed a mutation in the whiG gene, which encodes the sigma factor sigma(whiG) which is absolutely required for the sporulation process. In most cases, the mutation led to a loss of function. We showed that the Pig-pap mutants deriving from papillae appearing under usual growth conditions also frequently displayed null mutation of whiG too. As the whiG mutation ratio among the Pig-pap mutants isolated with or without nitrogen limited conditions did not change, the results described in this paper suggest that the production of papillae could constitute a response of S. ambofaciens to an amino acid limitation.

[The genome of alpha-proteobacteria : complexity, reduction, diversity and fluidity]

The alpha-proteobacteria displayed diverse and often unconventional life-styles. In particular, they keep close relationships with the eucaryotic cell. Their genomic organization is often atypical. Indeed, complex genomes, with two or more chromosomes that could be linear and sometimes associated with plasmids larger than one megabase, have been described. Moreover, polymorphism in genome size and topology as well as in replicon number was observed among very related bacteria, even in a same species. Alpha-proteobacteria provide a good model to study the reductive evolution, the role and origin of multiple chromosomes, and the genomic fluidity. The amount of new data harvested in the last decade should lead us to better understand emergence of bacterial life-styles and to build the conceptual basis to improve the definition of the bacterial species.

Once the circle has been broken: dynamics and evolution of Streptomyces chromosomes

Chromosomal instability has been a hallmark of Streptomyces genetics. Deletions and circularization often occur in the less-conserved terminal sequences of the linear chromosomes, which contain swarms of transposable elements and other horizontally transferred elements. Intermolecular recombination involving these regions also generates gross exchanges, resulting in terminal inverted repeats of heterogeneous size and context. The structural instability is evidently related to evolution of the Streptomyces chromosomes, which is postulated to involve linearization of hypothetical circular progenitors via integration of a linear plasmid. This scenario is supported by several bioinformatic analyses.