Structural basis for efficient chromophore communication and energy transfer in a constructed didomain protein scaffold.

The construction of useful functional biomolecular components not currently part of the natural repertoire is central to synthetic biology. A new light-capturing ultra-high-efficiency energy transfer protein scaffold has been constructed by coupling the chromophore centers of two normally unrelated proteins: the autofluorescent protein enhanced green fluorescent protein (EGFP) and the heme-binding electron transfer protein cytochrome b(562) (cyt b(562)). Using a combinatorial domain insertion strategy, a variant was isolated in which resonance energy transfer from the donor EGFP to the acceptor cyt b(562) was close to 100% as evident by virtually full fluorescence quenching on heme binding. The fluorescence signal of the variant was also sensitive to the reactive oxygen species H(2)O(2), with high signal gain observed due to the release of heme. The structure of oxidized holoprotein, determined to 2.75 Å resolution, revealed that the two domains were arranged side-by-side in a V-shape conformation, generating an interchromophore distance of ~17 Å (14 Å edge-to-edge). Critical to domain arrangement is the formation of a molecular pivot point between the two domains as a result of different linker sequence lengths at each domain junction and formation of a predominantly polar interdomain interaction surface. The retrospective structural analysis has provided an explanation for the basis of the observed highly efficient energy transfer through chromophore arrangement in the directly evolved protein scaffold and provides an insight into the molecular principles by which to design new proteins with coupled functions.

Regulation of beta-lactamase activity by remote binding of heme: functional coupling of unrelated proteins through domain insertion.

Coupling the activities of normally disparate proteins into one functional unit has significant potential in terms of constructing novel switching components for synthetic biology or as biosensors. It also provides a means of investigating the basis behind transmission of conformation events between remote sites that is integral to many biological processes, including allostery. Here we describe how the structures and functions of two normally unlinked proteins, namely, the heme binding capability of cytochrome b(562) and the antibiotic degrading beta-lactamase activity of TEM, have been coupled using a directed evolution domain insertion approach. The important small biomolecule heme directly modulates in vivo and in vitro the beta-lactamase activity of selected integral fusion proteins. The presence of heme decreased the concentration of ampicillin tolerated by Escherichia coli and the level of in vitro hydrolysis of nitrocefin by up to 2 orders of magnitude. Variants with the largest switching magnitudes contained insertions at second-shell sites that abut key catalytic residues. Spectrophotometry confirmed that heme bound to the integral fusion proteins in a manner similar to that of cytochrome b(562). Circular dichroism suggested that only subtle structural changes rather than gross folding-unfolding events were responsible for modulating beta-lactamase activity, and size exclusion chromatography confirmed that the integral fusion proteins remained monomeric in both the apo and holo forms. Thus, by sampling a variety of insertion positions and linker sequences, we are able to couple the functions of two unrelated proteins by domain insertion.

Expanded chemical diversity sampling through whole protein evolution.

A directed evolution method has been developed that allows random substitution of a contiguous trinucleotide sequence for TAG throughout a target gene for use in conjunction with an expanded genetic code. Using TEM-1 beta-lactamase and enhanced green fluorescent protein as targets, protein variants were identified whose functional phenotype was rescued in vivo when co-expressed with orthogonal tRNA-aminoacyl-tRNA synthase pairs that insert p-iodophenylalanine in response to UAG. Sequencing of the selected clones that retained the target protein function revealed that >90% of the variants contained in-frame TAG codons distributed throughout the target gene. Such an approach will allow broader sampling of new chemical diversity by proteins, so opening new avenues for studying biological systems and for adapting proteins for biotechnological applications. A common set of reagents allows the method to be used on different protein systems and in combination with an array of different unnatural amino acids, so helping to reveal the true potential for engineering proteins through expanded chemical diversity sampling.

Linking the functions of unrelated proteins using a novel directed evolution domain insertion method.

We have successfully developed a new directed evolution method for generating integral protein fusions comprising of one domain inserted within another. Creating two connections between the insert and accepting parent domain can result in the inter-dependence of the separate protein activities, thus providing a general strategy for constructing molecular switches. Using an engineered transposon termed MuDel, contiguous trinucleotide sequences were removed at random positions from the bla gene encoding TEM-1 beta-lactamase. The deleted trinucleotide sequence was then replaced by a DNA cassette encoding cytochrome b(562) with differing linking sequences at each terminus and sampling all three reading frames. The result was a variety of chimeric genes encoding novel integral fusion proteins that retained TEM-1 activity. While most of the tolerated insertions were observed in loops, several also occurred close to the termini of alpha-helices and beta-strands. Several variants conferred a switching phenotype on Escherichia coli, with bacterial tolerance to ampicillin being dependent on the presence of haem in the growth medium. The magnitude of the switching phenotype ranged from 4- to 128-fold depending on the insertion position within TEM-1 and the linker sequences that join the two domains.