Human mitochondrial chaperone (mtHSP70) and cysteine desulfurase (NFS1) bind preferentially to the disordered conformation, whereas co-chaperone (HSC20) binds to the structured conformation of the iron-sulfur cluster scaffold protein (ISCU).

Human ISCU is the scaffold protein for mitochondrial iron-sulfur (Fe-S) cluster biogenesis and transfer. NMR spectra have revealed that ISCU populates two conformational states; that is, a more structured state (S) and a partially disordered state (D). We identified two single amino acid substitutions (D39V and N90A) that stabilize the S-state and two (D39A and H105A) that stabilize the D-state. We isolated the two constituent proteins of the human cysteine desulfurase complex (NFS1 and ISD11) separately and used NMR spectroscopy to investigate their interaction with ISCU. We found that ISD11 does not interact directly with ISCU. By contrast, NFS1 binds preferentially to the D-state of ISCU as does the NFS1-ISD11 complex. An in vitro Fe-S cluster assembly assay showed that [2Fe-2S] and [4Fe-4S] clusters are assembled on ISCU when catalyzed by NFS1 alone and at a higher rate when catalyzed by the NFS1-ISD11 complex. The DnaK-type chaperone (mtHSP70) and DnaJ-type co-chaperone (HSC20) are involved in the transfer of clusters bound to ISCU to acceptor proteins in an ATP-dependent reaction. We found that the ATPase activity of mtHSP70 is accelerated by HSC20 and further accelerated by HSC20 plus ISCU. NMR studies have shown that mtHSP70 binds preferentially to the D-state of ISCU and that HSC20 binds preferentially to the S-state of ISCU.

[2Fe-2S]-ferredoxin binds directly to cysteine desulfurase and supplies an electron for iron-sulfur cluster assembly but is displaced by the scaffold protein or bacterial frataxin.

Escherichia coli [2Fe-2S]-ferredoxin (Fdx) is encoded by the isc operon along with other proteins involved in the 'house-keeping' mechanism of iron-sulfur cluster biogenesis. Although it has been proposed that Fdx supplies electrons to reduce sulfane sulfur (S(0)) produced by the cysteine desulfurase (IscS) to sulfide (S(2-)) as required for the assembly of Fe-S clusters on the scaffold protein (IscU), direct experimental evidence for the role of Fdx has been lacking. Here, we show that Fdx (in either oxidation state) interacts directly with IscS. The interaction face on Fdx was found to include residues close to its Fe-S cluster. In addition, C328 of IscS, the residue known to pick up sulfur from the active site of IscS and deliver it to the Cys residues of IscU, formed a disulfide bridge with Fdx in the presence of an oxidizing agent. Electrons from reduced Fdx were transferred to IscS only in the presence of l-cysteine, but not to the C328S variant. We found that Fdx, IscU, and CyaY (the bacterial frataxin) compete for overlapping binding sites on IscS. This mutual exclusion explains the mechanism by which CyaY inhibits Fe-S cluster biogenesis. These results (1) show that reduced Fdx supplies one electron to the IscS complex as S(0) is produced by the enzymatic conversion of Cys to Ala and (2) explain the role of Fdx as a member of the isc operon.

Solution structure of the 2A protease from a common cold agent, human rhinovirus C2, strain W12.

Human rhinovirus strains differ greatly in their virulence, and this has been correlated with the differing substrate specificity of the respective 2A protease (2Apro). Rhinoviruses use their 2Apro to cleave a spectrum of cellular proteins important to virus replication and anti-host activities. These enzymes share a chymotrypsin-like fold stabilized by a tetra-coordinated zinc ion. The catalytic triad consists of conserved Cys (C105), His (H34), and Asp (D18) residues. We used a semi-automated NMR protocol developed at NMRFAM to determine the solution structure of 2Apro (C105A variant) from an isolate of the clinically important rhinovirus C species (RV-C). The backbone of C2 2Apro superimposed closely (1.41-1.81 Å rmsd) with those of orthologs from RV-A2, coxsackie B4 (CB4), and enterovirus 71 (EV71) having sequence identities between 40% and 60%. Comparison of the structures suggest that the differential functional properties of C2 2Apro stem from its unique surface charge, high proportion of surface aromatics, and sequence surrounding the di-tyrosine flap.