Insertion of an endogenous Jaagsiekte sheep retrovirus element into the BCO2 - gene abolishes its function and leads to yellow discoloration of adipose tissue in Norwegian Spælsau (Ovis aries).

BACKGROUND: The accumulation of carotenoids in adipose tissue leading to yellow fat is, in sheep, a heritable recessive trait that can be attributed to a nonsense mutation in the beta-carotene oxygenase 2 (BCO2) gene. However, not all sheep breeds suffering from yellow fat have this nonsense mutation, meaning that other functional mechanisms must exist. We investigated one such breed, the Norwegian spælsau. RESULTS: In spælsau we detected an aberration in BCO2 mRNA. Nanopore sequencing of genomic DNA revealed the insertion of a 7.9 kb endogenous Jaagsiekte Sheep Retrovirus (enJSRV) sequence in the first intron of the BCO2 gene. Close examination of its cDNA revealed that the BCO2 genes first exon was spliced together with enJSRV-sequence immediately downstream of a potential -AG splice acceptor site at enJSRV position 415. The hybrid protein product consists of 29 amino acids coded by the BCO2 exon 1, one amino acid coded by the junction sequence, followed by 28 amino acids arbitrary coded for by the enJSRV-sequence, before a translation stop codon is reached. CONCLUSIONS: Considering that the functional BCO2 protein consists of 575 amino acids, it is unlikely that the 58 amino acid BCO2/enJSRV hybrid protein can display any enzymatic function. The existence of this novel BCO2 allele represents an alternative functional mechanism accounting for BCO2 inactivation and is a perfect example of the potential benefits for searching for structural variants using long-read sequencing data.

Cell density dependent restriction of N2O reductase in denitrifying Pseudomonas spp., a potential driver of N2O emissions in natural systems.

Denitrification is a major biological source and sink for the ozone-depleting greenhouse gas N2. Thus, the respiratory physiology of denitrifiers and the mechanisms determining their propensity for accumulation of N-oxides are of fundamental interest. Here, we report a pervasive positive correlation between cell density and N2O accumulation in Pseudomonas aeruginosa and P. fluorescens F113. We show that this was a result of quorum sensing by comparing the P. aeruginosa PAO1-UW wild type to a rhlI/lasI knockout mutant able to sense, but not synthesize the N-acyl-homoserine lactones (AHL) of the Rhl and Las circuits. Neither the transcription of nosZ (encoding N2O reductase, N2OR) nor the abundance of peptides of known relevance to denitrification could explain the restriction of N2O reduction in AHL-affected cultures. However, a protein shown to be involved in synthesis and repair of iron-sulphur (Fe-S) centers under NO stress, CyaY, was significantly downregulated in the AHL producing wild type. This hints to a possible route of N2OR-suppression via compromised Fe-S centers in the ancillary protein NosR. While the exact mechanism remains obscure, it appears that quorum sensing driven restriction of N2OR activity is common. Thus, given its ubiquity among prokaryotes, and the potential for cross-species and -strain effects, quorum sensing is plausibly a driver of N2O emissions in a range of systems.