Project description:Alzheimer’s disease (AD) is a progressive neurodegenerative disorder. Oligomers of Amyloid-β peptides (Aβ) are thought to play a pivotal role in AD pathogenesis, yet the mechanisms involved remain unclear. Two major isoforms of Aβ associated with AD are Aβ40 and Aβ42, the latter being more prone to form oligomers and toxic. Humanized yeast models are currently applied to unravel the cellular mechanisms behind Aβ toxicity. Here, we took a systems biology approach to study two yeast AD models which expressed either Aβ40 or Aβ42 in bioreactor cultures. Strict control of oxygen availability and culture pH, strongly affected the chronological lifespan and reduced confounding effects of variations during cell growth. Reduced growth rates and biomass yields were observed upon expression of Aβ42, indicating a redirection of energy from growth to maintenance. Quantitative physiology analyses furthermore revealed reduced mitochondrial functionality and ATP generation in Aβ42 expressing cells, which matched with observed aberrant fragmented mitochondrial structures. Genome-wide expression levels analysis showed that Aβ42 expression triggers strong ER stress and unfolded protein responses (UPR). Expression of Aβ40 induced only mild ER stress, leading to activation of UPR target genes that cope with misfolded proteins, which resulted in hardly affected physiology. The combination of well-controlled cultures and AD yeast models strengthen our understanding of how cells translate different levels of Aβ toxicity signals into particular cell fate programs, and further enhance their role as a discovery platform to identify potential therapies.
Project description:Mitochondria fulfil many essential roles in eukaryotic cells, yet some of their molecular mechanisms are still unexplored. Although 99% of the mitochondrial proteins are imported from the cytosol, mitochondria have their own DNA, transcription and translation machinery. The Saccharomyces cerevisiae mitochondrial DNA contains 11 polycistronic transcripts that encode 2 ribosomal subunits, 24 tRNAs and 9 genes, which can be spliced in alternative ways to yield different proteins. There are still many unresolved questions about mitochondrial genes and their splicing, including how gene expression and splicing is affected by different growth conditions and what role introns play in mitochondrial physiology. In the present study, we aimed to elucidate this by developing an RNA-sequencing method for mitochondrial RNA using Nanopore technology.