Traceless and site-specific ubiquitination of recombinant proteins.

Protein ubiquitination is a post-translational modification that regulates almost all aspects of eukaryotic biology. Here we discover the first routes for the efficient site-specific incorporation of δ-thiol-L-lysine (7) and δ-hydroxy-L-lysine (8) into recombinant proteins, via evolution of a pyrrolysyl-tRNA synthetase/tRNA(CUA) pair. We combine the genetically directed incorporation of 7 with native chemical ligation and desulfurization to yield an entirely native isopeptide bond between substrate proteins and ubiquitin. We exemplify this approach by demonstrating the synthesis of a ubiquitin dimer and the first synthesis of ubiquitinated SUMO.

Early protein evolution: building domains from ligand-binding polypeptide segments.

It has been suggested that in the early evolution of proteins, segments of polypeptide, unable to fold in isolation, may have collapsed together to form folded proto-domains. We wondered whether the incorporation of segments with a pre-existing binding activity into a folded domain could, by fixing the ligand binding conformation and/or providing additional contacts, lead to large affinity improvements and provide an evolutionary advantage. As a model, we took a segment of polypeptide from hen egg lysozyme that in the native protein forms the binding interface with the monoclonal antibodies HyHEL5 and F10 (KD=60 pM). When expressed in bacteria the isolated segment was unfolded, readily proteolysed and only bound weakly to the antibodies (KD>1 microM). We then combined the segment with random genomic segments to create a repertoire of chimaeric polypeptides displayed on filamentous bacteriophage. By use of proteolysis (to select folded polypeptide) and anti-lysozyme antibodies (to select an active conformation) we isolated a folded dimeric protein with an enhanced antibody affinity (KD=400 pM). Unexpectedly the dimer also incorporated a single heme molecule (KD=33 nM) that stabilised the dimer (Tm=59 degrees C with heme, 35 degrees C without heme). These results show that the binding affinities of flexible polypeptide segments can be greatly enhanced on protein folding, and that the folding can be stabilised by prosthetic groups. This supports the hypothesis that sub-domain polypeptide segments with functional activities may have contributed to domain creation in early evolution.

Folding and stability of a primitive protein.

We have previously attempted to simulate domain creation in early protein evolution by recombining polypeptide segments from non-homologous proteins, and we have described the structure of one such de novo protein, 1b11, a segment-swapped tetramer with novel architecture. Here, we have analyzed the thermodynamic stability and folding kinetics of the 1b11 tetramer and its monomeric and dimeric intermediates, and of 1b11 mutants with changes at the domain interface. Denatured 1b11 polypeptides fold into transient, folded monomers with marginal stability (DeltaG<1kcalmol(-1)) which convert rapidly ( approximately 6x10(4)M(-1)s(-1)) into dimers (DeltaG=9.8kcal/mol) and then more slowly ( approximately 3M(-1)s(-1)) into tetramers (DeltaG=28kcalmol(-1)). Segment swapping takes place during dimerization, as suggested by mass spectroscopic analysis of covalently linked peptides derived from proteolysis of a disulfide-linked dimer. Our results confirm that segment swapping and associated oligomerization are both powerful ways of stabilizing proteins, and we suggest that this may have been a feature of early protein evolution.

A segment of cold shock protein directs the folding of a combinatorial protein.

It has been suggested that protein domains evolved by the non-homologous recombination of building blocks of subdomain size. In earlier work we attempted to recapitulate domain evolution in vitro. We took a polypeptide segment comprising three beta-strands in the monomeric, five-stranded beta-barrel cold shock protein (CspA) of Escherichia coli as a building block. This segment corresponds to a complete exon in homologous eukaryotic proteins and includes residues that nucleate folding in CspA. We recombined this segment at random with fragments of natural proteins and succeeded in generating a range of folded chimaeric proteins. We now present the crystal structure of one such combinatorial protein, 1b11, a 103-residue polypeptide that includes segments from CspA and the S1 domain of the 30S ribosomal subunit of E. coli. The structure reveals a segment-swapped, six-stranded beta-barrel of unique architecture that assembles to a tetramer. Surprisingly, the CspA segment retains its structural identity in 1b11, recapitulating its original fold and deforming the structure of the S1 segment as necessary to complete a barrel. Our work provides structural evidence that (i) random shuffling of nonhomologous polypeptide segments can lead to folded proteins and unique architectures, (ii) many structural features of the segments are retained, and (iii) some segments can act as templates around which the rest of the protein folds.

A native-like artificial protein from antisense DNA.

We describe the creation of folded chimaeric proteins by combining a designed polypeptide segment (bait) derived from a beta-sheet of a human antibody variable domain with random polypeptide segments encoded by human cDNA fragments. The repertoire of polypeptides was displayed on the surface of filamentous bacteriophage and folded polypeptides were selected by proteolysis. One of these, 2a6, was readily expressed in the Escherichia coli cytoplasm as a soluble and protease-resistant protein and could be purified after heating the bacterial lysate to 90 degrees C. Soluble 2a6 is dimeric and its CD spectrum is consistent with components of both alpha and beta structure. 2a6 cooperatively and reversibly unfolds by heat or urea with a folding energy of 11.4 kcal mol(-1) for the transition between folded dimer and unfolded monomer and its refolding steps proceed without the formation of detectable aggregates. Its stability and folding properties are therefore typical of native proteins. Sequence analysis revealed that the cDNA segment in 2a6 was recruited from the antisense strand of a human gene, suggesting that antisense sequences can provide a reservoir for the evolution of soluble and stable proteins.