Every cell is equipped with a protein quality control system to ensure the proper
function of proteins. This is essential for both cell maintenance and the generation of
new and healthy cells. In this thesis, the budding yeast Saccharomyces cerevisiae is
used as a model to study both spatial quality control and the management of the
protein involved in Huntington’s disease. The role of the actin cytoskeleton in both
these processes has been the special focus of the thesis.
Earlier studies established a role for the histone deacetylase Sir2 and the actin
cytoskeleton in the asymmetrical inheritance of damaged proteins by the mother cell,
as cells either lacking SIR2 or subjected to a transient collapse of the actin
cytoskeleton, fail in this segregation process. In this thesis the protein disaggregase
Hsp104, the polarisome complex, and the molecular chaperone CCT were identified
as additional factors having important functions in the asymmetric segregation of
damaged proteins. CCT is an essential, cytosolic folding machine, vital for the
production of native actin. The actin folding capacity of CCT appears to be regulated
by Sir2. Without this regulation the cell suffers from a reduction in native actin
molecules, which could affect the integrity of actin cytoskeletal structures. The
polarisome complex ensures actin polymerization at the bud tip and the establishment
of a retrograde actin cable flow from the bud to the mother. Our data show that the
presence of a functional actin cytoskeleton allows for Hsp104, associated with protein
aggregates, to use the actin cytoskeleton as a scaffold and prevent the inheritance of
damaged and aggregated proteins by the daughter. The retention of damaged protein
within the mother cell is important for the rejuvenation of the daughter cell, as a
daughter being born with increased damage suffer from a reduced life span
