Project description:Diapause is a reversible developmental arrest faced by many organisms in harsh environments. Annual killifish present this mechanism in three possible stages of development. Killifish are freshwater teleosts from Africa and America that live in ephemeral ponds, which dry up in the dry season. The juvenile and adult populations die, and the embryos remain buried in the bottom mud until the next rainy season. Thus, species survival is entirely embryo-dependent, and they are perhaps the most remarkable extremophile organisms among vertebrates. The aim of the present study was to gather information about embryonic diapauses with the use of a “shotgun” proteomics approach in diapause III and prehatching Austrolebias charrua embryos. Our results provide insight into the molecular mechanisms of diapause III. We detected a diapause-dependent change in a large group of proteins involved in different functions, such as metabolic pathways and stress tolerance, as well as proteins related to DNA repair and epigenetic modifications. Furthermore, we observed a diapauseassociated switch in cytoskeletal proteins. This first glance into global protein expression differences between prehatching and diapause III could provide clues regarding the induction/maintenance of this developmental arrest in A. charrua embryos. There appears to be no single mechanism underlying diapause and the present data expand our knowledge of the molecular basis of diapause regulation. This information will be useful for future comparative approaches among different diapauses in annual killifish and/or other organisms that experience developmental arrest.

Project description:Quantification of gene expression at different dvelopmental stages of the short-lived killifish Nothobranchius furzeri GRZ strain.

Project description:We quantified gene expression in three different strains of the short-lived killifish Nothobranchius furzeri during aging.

Project description:Aging individuals exhibit a pervasive decline in adaptive immune function, with important implications for health and lifespan. Previous studies have found a pervasive loss of immune-repertoire diversity in human peripheral blood; however, little is known about repertoire aging in other immune compartments, or in species other than humans. Here, we perform the first study of immune-repertoire aging in an emerging model of vertebrate aging, the African turquoise killifish (Nothobranchius furzeri). Despite their extremely short lifespans, these killifish exhibit complex and individualised heavy-chain repertoires, with a generative process capable of producing millions of distinct productive sequences. Whole-body killifish repertoires decline rapidly in within-individual diversity with age, while between-individual variability increases. Large, expanded B-cell clones exhibit far greater diversity loss with age than small clones, suggesting an important difference in the age-sensitivity of different B cell populations. Compared to the whole body, the immune repertoires of isolated intestinal samples exhibit much more dramatic age-related phenotypes, apparently due to an elevated prevalence of age-sensitive expanded clones. Our results highlight the importance of organ-specific dynamics in adaptive immunosenescence.

Project description:In this work we took 9 samples from brain and 6 samples from muscle of the African turquoise killifish (Nothobranchius furzeri) at 3.5, 8.5 and 14 weeks. Total RNA was sequenced and circRNAs were detected.

Project description:The RNA-seq data contain 3 tissues (brain, liver, skin) of N. furzeri strains MZM-0410 and GRZ plus 2 biological replicates of brain of 6 other killifish species. Jena Centre for Systems Biology of Ageing - JenAge (www.jenage.de)

Project description:Here, we performed a longitudinal study of genome-wide gene expression in the short-lived killifish Nothobranchius furzeri (MZM-0410 strain) and correlated variations in transcript abundance at two time points during early adult life with age at death.

Project description:Turquoise killifish (Nothobranchius furzeri) gut microbiota

Project description:Fasting-refeeding paradigms result in drastic shifts in metabolism and gene expression patterns. The effect of fasting-refeeding changes between young and old individuals. We sought to decipher the changes in response to fasting-refeeding in young and old animals by profiling gene expression in adipose tissue of killifish Nothobranchius furzeri.

Project description:PTM landscape characterization during aging in the short-lived killifish N. furzeri.