Design of High-Affinity Metal-Controlled Protein Dimers.

The ability to precisely control protein complex formation has high utility in the expanding field of biomaterials. Driving protein-protein binding through metal-ligand bridging interactions is a promising method of achieving this goal. Furthermore, the capacity to precisely regulate both complex formation and dissociation enables additional control not available with constitutive protein complexes. Here we describe the design of three metal-controlled protein dimers that are completely monomeric in the absence of metal yet form high-affinity symmetric homodimers in the presence of zinc sulfate. The scaffold used for the designed dimers is the ß1 domain of streptococcal protein G. In addition to forming high-affinity dimers in the presence of metal, the complexes also dissociate upon addition of EDTA. Biophysical characterization revealed that the proteins maintain relatively high thermal stability, bind with high affinity, and are completely monodisperse in the monomeric and dimeric states. High-resolution crystal structures revealed that the dimers adopt the target structure and that the designed metal-binding histidine residues successfully bind zinc and function to drive dimer formation.

Characterizing substrate selectivity of ubiquitin C-terminal hydrolase-L3 using engineered α-linked ubiquitin substrates.

The ubiquitin-proteasome system (UPS) is highly complex and entails the concerted actions of many enzymes that function to ubiquitinate proteins targeted to the proteasome as well as enzymes that remove and recycle ubiquitin for additional rounds of proteolysis. Ubiquitin C-terminal hydrolase-L3 (UCH-L3) is a human cytosolic deubiquitinase whose precise biological function is not known. It is believed to hydrolyze small peptides or chemical adducts from the C-terminus of ubiquitin that may be remnant from proteasomal processing. In addition, UCH-L3 is a highly effective biotechnological tool that is used to produce small or unstable peptides/proteins recalcitrant to production in Escherichia coli expression systems. Previous research, which explored the substrate selectivity of UCH-L3, demonstrated a substrate size limitation for proteins/peptides expressed as α-linked C-terminal fusions to ubiquitin and also suggested that an additional substrate property may affect UCH-L3 hydrolysis [ Larsen , C. N. et al. (1998) Biochemistry 37 , 3358 - 3368 ]. Using a series of engineered protein substrates, which are similar in size yet differ in secondary structure, we demonstrate that thermal stability is a key factor that significantly affects UCH-L3 hydrolysis. In addition, we show that the thermal stabilities of the engineered substrates are not altered by fusion to ubiquitin and offer a possible mechanism as to how ubiquitin affects the structural and unfolding properties of natural in vivo targets.

Combined use of experimental and computational screens to characterize protein stability.

One of the primary goals of protein design is to engineer proteins with improved stability. Protein stability is a key issue for chemical, biotechnology and pharmaceutical industries. The development of robust proteins/enzymes with the ability to withstand the potentially harsh conditions of industrial operations is of high importance. A number of strategies are currently being employed to achieve this goal. Two particular approaches, (i) directed evolution and (ii) computational protein design, are quite powerful yet have only recently been combined or applied and analyzed in parallel. In directed evolution, libraries of variants are searched experimentally for clones possessing the desired properties. With computational methods, protein design algorithms are utilized to perform in silico screening for stable protein sequences. Here, we used gene libraries of an unstable variant of streptococcal protein G (Gbeta1) and an in vivo screening method to identify stabilized variants. Many variants with notably increased thermal stabilities were isolated and characterized. Concomitantly, computational techniques and protein design algorithms were used to perform in silico screening of the same destabilized variant of Gbeta1. The combined use, and critical analysis, of these methods promises to advance the field of protein design.

A de novo designed protein protein interface.

As an approach to both explore the physical/chemical parameters that drive molecular self-assembly and to generate novel protein oligomers, we have developed a procedure to generate protein dimers from monomeric proteins using computational protein docking and amino acid sequence design. A fast Fourier transform-based docking algorithm was used to generate a model for a dimeric version of the 56-amino-acid beta1 domain of streptococcal protein G. Computational amino acid sequence design of 24 residues at the dimer interface resulted in a heterodimer comprised of 12-fold and eightfold variants of the wild-type protein. The designed proteins were expressed, purified, and characterized using analytical ultracentrifugation and heteronuclear NMR techniques. Although the measured dissociation constant was modest ( approximately 300 microM), 2D-[(1)H,(15)N]-HSQC NMR spectra of one of the designed proteins in the absence and presence of its binding partner showed clear evidence of specific dimer formation.

Molecular diversity in engineered protein libraries.

Engineered protein libraries, defined here as a collection of different mutant variants of a single specific protein, are intentionally designed to be rich in molecular diversity and can span ranges from as little as 400 different variants to greater than 10(12) members per library. The goal of engineering libraries is to generate new protein variants, identified upon screening, that possess desired novel properties. Exploitation of the natural organization of the genetic code has led to 'focused' libraries that are lower in overall complexity yet biased towards variants with preferred biophysical properties. An emerging trend, in which computational algorithms are blended with in vivo screens, is also leading towards greater and more rapid success in the field of protein design.

Exploiting elements of transcriptional machinery to enhance protein stability.

The correlation between protein structure and function is well established, yet the role stability/flexibility plays in protein function is being explored. Here, we describe an in vivo screen in which the thermal stability of a test protein is correlated directly to the transcriptional regulation of a reporter gene. The screen readout is independent of the function of the test protein, proteolytic resistance, solubility or propensity to aggregate indiscriminately, and is thus dependent solely on the overall stability of the test protein. The system entails the use of an engineered chimeric construct that consists of three covalently linked domains; a constant N-terminal DNA-binding domain, a variable central test protein, and a constant C-terminal transcriptional activation domain. The test proteins are mutant variants of the beta1 domain of streptococcal protein G that span fairly evenly a thermal stability range from as low as 38 degrees C to above 100 degrees C. When the chimeric construct contains a test variant of low thermal stability, the reporter gene is up-regulated to a greater extent relative to that of more stable/less flexible variants. A panel of nine Gbeta1 mutant variants was used to benchmark the screen, and spectroscopic methods were employed to characterize the thermal and structural properties of each variant accurately. The screen was combined with in silico methods to interrogate a library of randomized variants for selection of mutants of greater structural integrity.

DNA fingerprint analysis of three short tandem repeat (STR) loci for biochemistry and forensic science laboratory courses.

We have devised and implemented a DNA fingerprinting module for an upper division undergraduate laboratory based on the amplification and analysis of three of the 13 short tandem repeat loci that are required by the Federal Bureau of Investigation Combined DNA Index System (FBI CODIS) data base. Students first collect human epithelial (cheek) cells using sterile buccal swabs and then utilize commercially available kits and materials to extract genomic DNA. This is followed by the PCR amplification of three specific short tandem repeat loci (i.e. CSF1PO, TPOX, THO1). Polyacrylamide gel electrophoresis is used to resolve the allelic bands associated with the three short tandem repeat loci, and the results are statistically analyzed in the context of human population genetics. In addition, DNA was collected from a family, and the children's allele sets were compared with those of the parents to help illustrate paternal and maternal relatedness. This module enables students to use the materials and methods employed by actual law enforcement agencies and therefore can be used for laboratory exercises in traditional biochemistry curricula as well as for the growing field of forensic science and education.

Adaptation of a fast Fourier transform-based docking algorithm for protein design.

Designing proteins with novel protein/protein binding properties can be achieved by combining the tools that have been developed independently for protein docking and protein design. We describe here the sequence-independent generation of protein dimer orientations by protein docking for use as scaffolds in protein sequence design algorithms. To dock monomers into sequence-independent dimer conformations, we use a reduced representation in which the side chains are approximated by spheres with atomic radii derived from known C2 symmetry-related homodimers. The interfaces of C2-related homodimers are usually more hydrophobic and protein core-like than the interfaces of heterodimers; we parameterize the radii for docking against this feature to capture and recreate the spatial characteristics of a hydrophobic interface. A fast Fourier transform-based geometric recognition algorithm is used for docking the reduced representation protein models. The resulting docking algorithm successfully predicted the wild-type homodimer orientations in 65 out of 121 dimer test cases. The success rate increases to approximately 70% for the subset of molecules with large surface area burial in the interface relative to their chain length. Forty-five of the predictions exhibited less than 1 A C(alpha) RMSD compared to the native X-ray structures. The reduced protein representation therefore appears to be a reasonable approximation and can be used to position protein backbones in plausible orientations for homodimer design.

A designed protein interface that blocks fibril formation.

Protein fibril formation is implicated in many diseases, and therefore much effort has been focused toward the development of inhibitors of this process. In a previous project, a monomeric protein was computationally engineered to bind itself and form a heterodimer complex following interfacial redesign. One of the protein monomers, termed monomer-B, was unintentionally destabilized and shown to form macroscopic fibrils. Interestingly, in the presence of the designed binding partner, fibril formation was blocked. Here we describe the complete characterization of the amyloid properties of monomer-B and the inhibition of fiber formation by the designed binding partner, monomer-A. Both proteins are mutants of the betal domain of streptococcal protein-G. The free monomer-B protein forms amyloid-type fibrils, as determined by transmission electron microscopy and the change in fluorescence of Thioflavin T, an amyloid-specific dye. Fibril formation kinetics are influenced by pH, protein concentration, and seeding with preformed fibrils. Under all conditions tested, monomer-A was able to inhibit the formation of monomer-B fibrils. This inhibition is specific to the engineered interaction, as incubation of monomer-B with wild-type protein-G (a structural homologue) did not result in inhibition under the same conditions. Thus, this de novo-designed heterodimeric complex is an excellent model system for the study of protein-based fibril formation and inhibition. This system provides additional insight into the development of pharmaceuticals for amyloid disorders, as well as the potential use of amyloid fibrils for self-assembling nanostructures.

The LEF-1 high-mobility group domain undergoes a disorder-to-order transition upon formation of a complex with cognate DNA.

Lymphoid enhancer-binding factor-1 (LEF-1), a member of the high-mobility group (HMG) family of proteins, functions as an architectural transcription factor. In complex with its cognate DNA, the LEF-1 domain is highly ordered, and its NMR spectra are characteristic of a folded globular protein. In contrast, the uncomplexed protein exhibits NMR evidence of substantial conformational heterogeneity, although circular dichroism spectra indicate that much of the alpha-helical secondary structure of the DNA-bound state is retained in the free protein. Heteronuclear NMR experiments performed on the free LEF-1 domain reveal that helix II and helix III of the HMG domain are folded, although helix III is truncated at its C-terminal end relative to the DNA-bound protein. The major hydrophobic core between helices II and III appears to be formed, but the minor core near the C-terminus of helix III is unstructured in the free protein. Backbone resonances of helix I are undetectable, probably as a result of exchange broadening due to fluctuations between two or more conformations on a microsecond-to-millisecond time scale. On the basis of the circular dichroism spectrum, this region of the polypeptide appears to adopt helical structure but the helix is not fully stabilized in the absence of DNA. These findings argue that, prior to binding, bending, and distorting DNA, the HMG domain of LEF-1 exists in a segmentally disordered or partially folded state. Upon complex formation, the protein domain undergoes a cooperative folding transition with DNA to a highly ordered and well-folded state.

Structure of a beta-alanine-linked polyamide bound to a full helical turn of purine tract DNA in the 1:1 motif.

Polyamides composed of N-methylpyrrole (Py), N-methylimidazole (Im) and N-methylhydroxypyrrole (Hp) amino acids linked by beta-alanine (beta) bind the minor groove of DNA in 1:1 and 2:1 ligand to DNA stoichiometries. Although the energetics and structure of the 2:1 complex has been explored extensively, there is remarkably less understood about 1:1 recognition beyond the initial studies on netropsin and distamycin. We present here the 1:1 solution structure of ImPy-beta-Im-beta-ImPy-beta-Dp bound in a single orientation to its match site within the DNA duplex 5'-CCAAAGAGAAGCG-3'.5'-CGCTTCTCTTTGG-3' (match site in bold), as determined by 2D (1)H NMR methods. The representative ensemble of 12 conformers has no distance constraint violations greater than 0.13 A and a pairwise RMSD over the binding site of 0.80 A. Intermolecular NOEs place the polyamide deep inside the minor groove, and oriented N-C with the 3'-5' direction of the purine-rich strand. Analysis of the high-resolution structure reveals the ligand bound 1:1 completely within the minor groove for a full turn of the DNA helix. The DNA is B-form (average rise=3.3 A, twist=38 degrees ) with a narrow minor groove closing down to 3.0-4.5 A in the binding site. The ligand and DNA are aligned in register, with each polyamide NH group forming bifurcated hydrogen bonds of similar length to purine N3 and pyrimidine O2 atoms on the floor of the minor groove. Each imidazole group is hydrogen bonded via its N3 atom to its proximal guanine's exocyclic amino group. The important roles of beta-alanine and imidazole for 1:1 binding are discussed.