Project description:A draft genome sequence for a urinary isolate of Nosocomiicoccus ampullae (UMB0853) was investigated. The size of the genome was 1,578,043 bp, with an observed G+C content of 36.1%. Annotation revealed 10 rRNA sequences, 40 tRNA genes, and 1,532 protein-coding sequences. Genome coverage was 727× and consisted of 32 contigs, with an N50 of 109,831 bp.
Project description:Here, we present the circular and complete genome sequences of the Nosocomiicoccus ampullae isolate 19-00310 and type strain DSM 19163. To our knowledge, these represent the first complete, circular chromosomes in the entire genus. Sequencing of a growth-adapted mutant suggests iron availability as a factor for growth improvement.
Project description:We performed whole transcriptome analysis of the ampullae, the primary site of EAV persistence, derived from long-term carrier stallions to understand the molecular signature of persistent infection. We demonstrated that long-term persistence is characterized by a local CD8+ T lymphocyte response predominantly driven by the transcription factors EOMES and NFATC2.We showed that EAV persistence is associated with an enhanced expression of CXCL16/CXCR6 in infiltrating lymphocytes. Furthermore, we established a link between the CXCL16 genotype and the gene expression profile at the site of persistence following EAV infection. Co-expression network analysis identified CXCL16 as a “hub” gene, likely driving a specific transcriptional network.
Project description:In 1678, Stefano Lorenzini first described a network of organs of unknown function in the torpedo ray-the ampullae of Lorenzini (AoL). An individual ampulla consists of a pore on the skin that is open to the environment, a canal containing a jelly and leading to an alveolus with a series of electrosensing cells. The role of the AoL remained a mystery for almost 300 years until research demonstrated that skates, sharks, and rays detect very weak electric fields produced by a potential prey. The AoL jelly likely contributes to this electrosensing function, yet the exact details of this contribution remain unclear. We measure the proton conductivity of the AoL jelly extracted from skates and sharks. The room-temperature proton conductivity of the AoL jelly is very high at 2 ± 1 mS/cm. This conductivity is only 40-fold lower than the current state-of-the-art proton-conducting polymer Nafion, and it is the highest reported for a biological material so far. We suggest that keratan sulfate, identified previously in the AoL jelly and confirmed here, may contribute to the high proton conductivity of the AoL jelly with its sulfate groups-acid groups and proton donors. We hope that the observed high proton conductivity of the AoL jelly may contribute to future studies of the AoL function.