The Repetitive Landscape of the Barley Genome

While transposable elements (TEs) comprise the bulk of plant genomic DNA, how they contribute to genome structure and organization is still poorly understood. Especially, in large genomes where TEs make the majority of genomic DNA, it is still unclear whether TEs target specific chromosomal regions or whether they simply accumulate where they are best tolerated. The barley genome with its vast repetitive fraction is an ideal system to study chromosomal organization and evolution of TEs. Genes make only about 2% of the genome, while over 80% is derived from TEs. The TE fraction is composed of at least 350 different families. However, 50% of the genome is comprised of only 15 high-copy TE families, while all other TE families are present in moderate or low-copy numbers. The barley genome is highly compartmentalized with different types of TEs occupying different chromosomal “niches”, such as distal, interstitial or proximal regions of chromosome arms. Furthermore, gene space represents its own distinct genomic compartment that is enriched in small non-autonomous DNA transposons, suggesting that these TEs specifically target promoters and downstream regions. Some TE families also show a strong preference to insert in specific sequence motifs which may, in part, explain their distribution. The family-specific distribution patterns result in distinct TE compositions of different chromosomal compartments.Peer reviewe

The Complete Genome of Propionibacterium freudenreichii CIRM-BIA1T, a Hardy Actinobacterium with Food and Probiotic Applications

Background: Propionibacterium freudenreichii is essential as a ripening culture in Swiss-type cheeses and is also considered for its probiotic use [1]. This species exhibits slow growth, low nutritional requirements, and hardiness in many habitats. It belongs to the taxonomic group of dairy propionibacteria, in contrast to the cutaneous species P. acnes. The genome of the type strain, P. freudenreichii subsp. shermanii CIRM-BIA1 (CIP 103027T), was sequenced with an 11-fold coverage. Methodology/Principal Findings: The circular chromosome of 2.7 Mb of the CIRM-BIA1 strain has a GC-content of 67% and contains 22 different insertion sequences (3.5% of the genome in base pairs). Using a proteomic approach, 490 of the 2439 predicted proteins were confirmed. The annotation revealed the genetic basis for the hardiness of P. freudenreichii, as the bacterium possesses a complete enzymatic arsenal for de novo biosynthesis of aminoacids and vitamins (except panthotenate and biotin) as well as sequences involved in metabolism of various carbon sources, immunity against phages, duplicated chaperone genes and, interestingly, genes involved in the management of polyphosphate, glycogen and trehalose storage. The complete biosynthesis pathway for a bifidogenic compound is described, as well as a high number of surface proteins involved in interactions with the host and present in other probiotic bacteria. By comparative genomics, no pathogenicity factors found in P. acnes or in other pathogenic microbial species were identified in P. freudenreichii, which is consistent with the Generally Recognized As Safe and Qualified Presumption of Safety status of P. freudenreichii. Various pathways for formation of cheese flavor compounds were identified: the Wood-Werkman cycle for propionic acid formation, amino acid degradation pathways resulting in the formation of volatile branched chain fatty acids, and esterases involved in the formation of free fatty acids and esters. Conclusions/Significance: With the exception of its ability to degrade lactose, P. freudenreichii seems poorly adapted to dairy niches. This genome annotation opens up new prospects for the understanding of the P. freudenreichii probiotic activity

IRAP, a retrotransposon-based marker system for the detection of somaclonal variation in barley

The retrotransposon-based marker system, inter-retrotransposon amplified polymorphism (IRAP), and inter-simple sequence repeats (ISSRs) were used to detect somaclonal variation induced by tissue culture. IRAPs use a single primer designed to amplify out from the 5′ LTR sequence of the BARE-1 retrotransposon combined with a degenerate 3′ anchor, similar to that of ISSR primers. We analysed DNA polymorphisms in 147 primary regenerants and parental controls from three cultivars of barley (Hordeum vulgare). The ISSR marker system generated an average of 218 bands per primer, with 29 polymorphisms of which 12 were novel non-parental bands. In comparison, the IRAP system generated an average of 121 bands per primer, with 15 polymorphisms of which nine were novel non-parental bands. Polymorphism detected for IRAP and ISSR markers was more than twofold higher in Golden Promise than Mackay and Tallon cultivars. However, there was no significant difference in the frequency of novel non-parental bands. Cluster analysis revealed that the level of polymorphism and genetic variability detected was comparable between IRAP and ISSR markers. This suggests that retrotransposon-based marker systems, such as IRAP, based on retrotransposons such as BARE-1, are valuable tools for the detailed characterisation of mutation profiles that arise during tissue culture. Their use should improve our understanding of processes influencing mutation and somaclonal variation and allow for the design of methods that yield fewer genome changes in applications where maintaining clonal integrity is important