Oxidative protein folding: many different ways to introduce disulfide bonds

Redox-assisted protein folding systems in eukaryotic parasites

SIGNIFICANCE

The cysteine (Cys) residues of proteins play two fundamentally important roles. They serve as sites of post-translational redox modifications as well as influence the conformation of the protein through the formation of disulfide bonds.

RECENT ADVANCES

Redox-related and redox-associated protein folding in protozoan parasites has been found to be a major mode of regulation, affecting myriad aspects of the parasitic life cycle, host-parasite interactions, and the disease pathology. Available genome sequences of various parasites have begun to complement the classical biochemical and enzymological studies of these processes. In this article, we summarize the reversible Cys disulfide (S-S) bond formation in various classes of strategically important parasitic proteins, and its structural consequence and functional relevance.

CRITICAL ISSUES

Molecular mechanisms of folding remain under-studied and often disconnected from functional relevance.

FUTURE DIRECTIONS

The clinical benefit of redox research will require a comprehensive characterization of the various isoforms and paralogs of the redox enzymes and their concerted effect on the structure and function of the specific parasitic client proteins.

Chemical synthesis of circular proteins

Circular proteins, once thought to be rare, are now commonly found in plants. Their chemical synthesis, once thought to be difficult, is now readily achievable. The enabling methodology is largely due to the advances in entropic chemical ligation to overcome the entropy barrier in coupling the N- and C-terminal ends of large peptide segments for either intermolecular ligation or intramolecular ligation in end-to-end cyclization. Key elements of an entropic chemical ligation consist of a chemoselective capture step merging the N and C termini as a covalently linked O/S-ester intermediate to permit the subsequent step of an intramolecular O/S-N acyl shift to form an amide. Many ligation methods exploit the supernucleophilicity of a thiol side chain at the N terminus for the capture reaction, which makes cysteine-rich peptides ideal candidates for the entropy-driven macrocyclization. Advances in desulfurization and modification of the thiol-containing amino acids at the ligation sites to other amino acids add extra dimensions to the entropy-driven ligation methods. This minireview describes recent advances of entropy-driven ligation to prepare circular proteins with or without a cysteinyl side chain.

The four cysteines ring motif in proteins

Disulfide bonds play fundamental roles in proteins. This work is devoted to highly rare motifs containing disulfide bonds. A search for four cysteines, forming a 16-atom membered ring (4CR) embodying two disulfide bonds, was carried out against all entries in the Protein Data Bank. Searching the crystallographic subset, only few protein molecules, all dimeric, were found to embody this peculiar structural feature, which establishes a covalent link between two different polypeptide chains. In contrast, in a peptide studied in solution by NMR, the four cysteines moiety includes only residues from one chain. A comparative analysis provided evidence for similarity and difference. It emerged that 4CR motif is highly rare and may serve to gain a specialized function.

Disulfide-linked protein folding pathways

Determining the mechanism by which proteins attain their native structure is an important but difficult problem in basic biology. The study of protein folding is difficult because it involves the identification and characterization of folding intermediates that are only very transiently present. Disulfide bond formation is thermodynamically linked to protein folding. The availability of thiol trapping reagents and the relatively slow kinetics of disulfide bond formation have facilitated the isolation, purification, and characterization of disulfide-linked folding intermediates. As a result, the folding pathways of several disulfide-rich proteins are among the best known of any protein. This review discusses disulfide bond formation and its relationship to protein folding in vitro and in vivo.

Characterisation of the components of the thioredoxin system in the archaeon Sulfolobus solfataricus

The thioredoxin system is a redox machinery widely distributed in nature and involved in several cellular functions. It is constituted of thioredoxin reductase (Trx-B), its protein substrate thioredoxin (Trx-A) and NADPH. We have previously characterised a Trx-B from the hyperthermophile Sulfolobus solfataricus (SsTrx-B3) (Ruocco et al. in Biochimie 86:883-892, 2004). As in the genome of this archaeon, the gene coding for another Trx-B (SsTrx-B2) and for two Trx-A (SsTrx-A1, SsTrx-A2) have been putatively identified, these proteins were obtained as recombinant forms and characterised. SsTrx-B2, different from SsTrx-B3, did not elicit a thioredoxin reductase activity. S. solfataricus possessed only one Trx-B (SsTrx-B3), which had two thioredoxins (SsTrx-A1 and SsTrx-A2) as substrates. These latter showed a homodimeric structure and catalysed insulin reduction using either DTT or NADPH/SsTrx-B3 as electron donors. In addition, the electron transfer between SsTrx-B3 and either SsTrx-A1 or SsTrx-A2 was fully reversible, thus allowing the determination of the redox potential of the thioredoxin system in S. solfataricus. Among the two thioredoxins, SsTrx-A2 appeared slightly more active and stable than SsTrx-A1. These data, besides shedding light on thioredoxin system in S. solfataricus, will contribute to add further information on this key enzyme system in Archaea.

Insights into the structural variation between pentapeptide repeat proteins--crystal structure of Rfr23 from Cyanothece 51142

Cyanothece sp. PCC 51142 contains 35 pentapeptide repeat proteins (PRPs), proteins that contain a minimum of eight tandem repeated five-residues (Rfr) of the general consensus sequence A[N/D]LXX. Published crystal structures of PRPs show that the tandem pentapeptide repeats adopt a type of right-handed quadrilateral beta-helix called an Rfr-fold. To characterize how structural features of Rfr-folds might vary with different amino acid sequences, the crystal structure of Cyanothece Rfr23 (174 residues) was determined at 2.4A resolution. The structure is dominated by an Rfr-fold capped at the N-terminus with a nine-residue alpha-helix (M26(*)-E34). The Rfr-fold of Rfr23 contains four structural features previously unobserved in Rfr-folds. First, Rfr23 is composed entirely of type II beta-turns. Second, the pentapeptide repeats are not consecutive in the primary amino acid sequence. Instead, Rfr23 contains 24-residues protruding outside one corner of the first complete N-terminal coil of the Rfr-fold (L56-P79) (24-residue insertion). Third, a disulfide bond between C39 and C42 bridges the beta-turn between the first and second pentapeptide repeats in the first coil (disulfide bracket). NMR spectroscopy indicates that the reduction of the disulfide bracket with the addition of DTT destroys the entire Rfr-fold. Fourth, a single-residue perturbs the Rfr-fold slightly in the last coil between the C-terminal two pentapeptide repeats (single-residue bulge).