Abstract
Translocase of IM (inner membrane; Tim)9 and Tim10 are essential homologue proteins of the mitochondrial intermembrane space (IMS) and form a stable hexameric Tim9–Tim10 complex there. Redox-switch of the four conserved cysteine residues plays a key role during the biogenesis of these proteins and, in turn, the Tim proteins play a vital chaperone-like role during import of mitochondrial membrane proteins. However, the functional mechanism of the small Tim chaperones is far from solved and it is unclear whether the individual proteins play specific roles or the complex functions as a single unit. In the present study, we examined the requirement and role for the individual disulfide bonds of Tim9 on cell viability, complex formation and stability using yeast genetic, biochemical and biophysical methods. Loss of the Tim9 inner disulfide bond led to a temperature-sensitive phenotype and degradation of both Tim9 and Tim10. The growth phenotype could be suppressed by deletion of the mitochondrial i-AAA (ATPases associated with diverse cellular activities) protease Yme1, and this correlates strongly with stabilization of the Tim10 protein regardless of Tim9 levels. Formation of both disulfide bonds is not essential for Tim9 function, but it can facilitate the formation and improve the stability of the hexameric Tim9–Tim10 complex. Furthermore, our results suggest that the primary function of Tim9 is to protect Tim10 from degradation by Yme1 via assembly into the Tim9–Tim10 complex. We propose that Tim10, rather than the hexameric Tim9–Tim10 complex, is the functional form of these proteins.
Highlights
Translocase of IM9 and Tim10 are essential members of the ‘small translocase of inner membrane (Tim)’ protein family of the mitochondrial intermembrane space (IMS)
This result suggests that the growth defect of the tim9C2,3S mutant is caused by protein degradation by the Yme1 protease and to further investigate this we examined whether YME1 deletion caused a generalized increase in Tim9 levels
We found that the levels of Tim9 in mitochondria purified from WT yeast were not significantly increased by deletion of YME1 (Figure 2B)
Summary
Translocase of IM (inner membrane; Tim)9 and Tim10 are essential members of the ‘small Tim’ ( known as ‘Tiny Tim’) protein family of the mitochondrial intermembrane space (IMS). We tested the requirements for the inner and outer disulfide bonds of Tim9 as well as the effects of yme1 deletion on cell growth, Tim9–Tim10 complex formation and protein stability, using various yeast genetic and protein characterization methods.
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