Identifying the Protein Interactions of the Cytosolic Iron-Sulfur Cluster Targeting Complex Essential for Its Assembly and Recognition of Apo-Targets.

The cytosolic iron-sulfur cluster assembly (CIA) system assembles iron-sulfur (FeS) cluster cofactors and inserts them into >20 apoprotein targets residing in the cytosol and nucleus. Three CIA proteins, called Cia1, Cia2, and Met18 in yeast, form the targeting complex responsible for apo-target recognition. There is little information about the structure of this complex or its mechanism of CIA substrate recognition. Herein, we exploit affinity co-purification and size exclusion chromatography to determine the subunit connectivity and stoichiometry of the CIA targeting complex. We conclude that Cia2 is the organizing center of the targeting complex, which contains one Met18, two Cia1, and four Cia2 polypeptides. To probe target recognition specificity, we utilize the CIA substrates Leu1 and Rad3 as well as the Escherichia coli FeS-binding transcription factor FNR (fumerate nitrate reductase). We demonstrate that both of the yeast CIA substrates are recognized, whereas the bacterial protein is not. Thus, while the targeting complex exhibits flexible target recognition in vitro, it cannot promiscuously recognize any FeS protein. Additionally, we demonstrate that the full CIA targeting complex is required to stably bind Leu1 in vitro, whereas the Met18-Cia2 subcomplex is sufficient to recognize Rad3. Together, these results allow us to propose a unifying model for the architecture of this highly conserved complex and demonstrate what component or subcomplexes are vital for target identification.

Defining the domains of Cia2 required for its essential function in vivo and in vitro.

The cytosolic iron-sulfur cluster assembly (CIA) system biosynthesizes iron-sulfur (FeS) cluster cofactors for cytosolic and nuclear proteins. The yeast Cia2 protein is the central component of the targeting complex which identifies apo-protein targets in the final step of the pathway. Herein, we determine that Cia2 contains five conserved motifs distributed between an intrinsically disordered N-terminal domain and a C-terminal domain of unknown function 59 (DUF59). The disordered domain is dispensible for binding the other subunits of the targeting complex, Met18 and Cia1, and the apo-target Rad3 in vitro. While in vivo assays reveal that the C-terminal domain is sufficient to support viability, several phenotypic assays indicate that deletion of the N-terminal domain negatively impacts CIA function. We additionally establish that Glu208, located within a conserved motif found only in eukaryotic DUF59 proteins, is important for the Cia1-Cia2 interaction in vitro. In vivo, E208A-Cia2 results in a diminished activity of the cytosolic iron sulfur cluster protein, Leu1 but only modest effects on hydroxyurea or methylmethane sulfonate sensitivity. Finally, we demonstrate that neither of the two highly conserved motifs of the DUF59 domain are vital for any of Cia2's interactions in vitro yet mutation of the DPE motif in the DUF59 domain results in a nonfunctional allele in vivo. Our observation that four of the five highly conserved motifs of Cia2 are dispensable for targeting complex formation and apo-target binding suggests that Cia2 is not simply a protein-protein interaction mediator but it likely possesses an additional, currently cryptic, function during the final cluster insertion step of CIA.