ABSTRACT: Protein quality controls (PQC) systems rely on three main activities to prevent the accumulation of misfolded proteins upon stress conditions and aging: refolding, degradation and sequestration. In Saccharomyces cerevisiae the Hsp70 chaperone system plays a central role in protein refolding, while degradation is predominantly executed by the ubiquitin proteasome system (UPS). The sequestrases Hsp42 and Btn2 deposit misfolded proteins in cytosolic and nuclear inclusions. This activity prevents exhaustion of limited Hsp70 resources by restricting the accessibility of misfolded proteins upon sequestration. Sequestrase mutants therefore show negative genetic interactions with yeast Hsp70 co-chaperone mutants (fes1D hsp104D, DD) that suffer from low Hsp70 capacity. Growth of DDbtn2D mutants is highly temperature-sensitive and results in proteostasis breakdown at non-permissive temperatures. Here, we probed for the role of the UPS system in maintaining protein homeostasis in DDbtn2D cells, affected in two major PQC branches. We show that DDD cells induce expression of diverse stress-related pathways including the UPS to counteract the proteostasis defects. UPS dependent degradation of the stringent Hsp70 substrate Luciferase in the mutant cells mirrors such compensatory activities of the PQC system. However, the enhanced UPS activity does not improve but aggravates the phenotypes of DDbtn2D cells. Reducing UPS activity in the mutant by lowering the levels of functional 26S proteasomes improved growth, increased refolding yield of the Luciferase reporter and attenuated global stress responses. This indicates that an imbalance between Hsp70-dependent refolding and UPS-mediated degradation activities strongly affects protein homeostasis of yeast Hsp70 capacity mutants and contributes to their severe growth phenotypes.