Thermodynamics of folding and binding in an affibody:affibody complex

Affibody binding proteins are selected from phage-displayed libraries of variants of the 58 residue Z domain. Z(Taq) is an affibody originally selected as a binder to Taq DNA polymerase. The anti-Z(Taq) affibody was selected as a binder to Z(Taq) and the Z(Taq):anti-Z(Taq) complex is formed with a dissociation constant K(d)=0.1 microM. We have determined the structure of the Z(Taq):anti-Z(Taq) complex as well as the free state structures of Z(Taq) and anti-Z(Taq) using NMR. Here we complement the structural data with thermodynamic studies of Z(Taq) and anti-Z(Taq) folding and complex formation. Both affibody proteins show cooperative two-state thermal denaturation at melting temperatures T(M) approximately 56 degrees C. Z(Taq):anti-Z(Taq) complex formation at 25 degrees C in 50 mM NaCl and 20 mM phosphate buffer (pH 6.4) is enthalpy driven with DeltaH degrees (bind) = -9.0 (+/-0.1) kcal mol(-1)(.) The heat capacity change DeltaC(P) degrees (,bind)=-0.43 (+/-0.01) kcal mol(-1) K(-1) is in accordance with the predominantly non-polar character of the binding surface, as judged from calculations based on changes in accessible surface areas. A further dissection of the small binding entropy at 25 degrees C (-TDeltaS degrees (bind) = -0.6 (+/-0.1) kcal mol(-1)) suggests that a favourable desolvation of non-polar surface is almost completely balanced by unfavourable conformational entropy changes and loss of rotational and translational entropy. Such effects can therefore be limiting for strong binding also when interacting protein components are stable and homogeneously folded. The combined structure and thermodynamics data suggest that protein properties are not likely to be a serious limitation for the development of engineered binding proteins based on the Z domain.     

Phage-based molecular directed evolution yields multiple tandem human IgA affibodies with intramolecular binding avidity

Affibodies are a group of affinity proteins that are based on a 58-amino-acid residue protein domain derived from one of the IgG-binding domains of staphylococcal protein A. A single human IgA affibody with high IgA affinity has been generated by directed evolution. It remains interesting whether tandem IgA affibody proteins could increase binding capacity. Here, we report the generation of multiple tandem IgA affibodies by directed evolution using a combinatorial phage library displaying the IgA affibody A1 and/or A2 linked with three random amino acids. These affibodies exhibited markedly increased IgA binding capacity, as shown by enzyme linked immunosorbent assay, immunoblotting and surface plasmon resonance assays. We further showed that these tandem IgA affibodies displayed preferential binding to intact IgA molecules compared to individual IgA chain, suggesting intramolecular binding avidity. Our data demonstrates that artificial multiple tandem human IgA affibodies with relevant biological binding avidity were successfully yielded by phage-based molecular evolution. These results have broad implications for the design and development of binding proteins that target important biological molecules.     

Anti-idiotypic protein domains selected from protein A-based affibody libraries

Three pairs of small protein domains showing binding behavior in analogy with anti-idiotypic antibodies have been selected using phage display technology. From an affibody protein library constructed by combinatorial variegation of the Fc binding surface of the 58 residue staphylococcal protein A (SPA)-derived domain Z, affibody variants have been selected to the parental SPA scaffold and to two earlier identified SPA-derived affibodies. One selected affibody (Z(SPA-1)) was shown to recognize each of the five domains of wild-type SPA with dissociation constants (K(D)) in the micromolar range. The binding of the Z(SPA-1) affibody to its parental structure was shown to involve the Fc binding site of SPA, while the Fab-binding site was not involved. Similarly, affibodies showing anti-idiotypic binding characteristics were also obtained when affibodies previously selected for binding to Taq DNA polymerase and human IgA, respectively, were used as targets for selections. The potential applications for these types of affinity pairs were exemplified by one-step protein recovery using affinity chromatography employing the specific interactions between the respective protein pair members. These experiments included the purification of the Z(SPA-1) affibody from a total Escherichia coli cell lysate using protein A-Sepharose, suggesting that this protein A/antiprotein A affinity pair could provide a basis for novel affinity gene fusion systems. The use of this type of small, robust, and easily expressed anti-idiotypic affibody pair for affinity technology applications, including self-assembled protein networks, is discussed.     

Monitored whole gene in vitro evolution of an anti-hRaf-1 affibody molecule towards increased binding affinity

The use of library technologies for the generation of affinity proteins often includes an affinity maturation step, based on the construction of secondary libraries from which second generation variants with improved affinities are selected. Here, we describe for the first time the affinity maturation of affibody molecules based on step-wise in vitro molecular evolution, involving cycles of error-prone PCR (epPCR) amplification for the introduction of diversity over the entire 58-residue three-helix bundle structure and ribosome display (RD) for the selection of improved variants. The model affibody molecule for the process was Z(RAF322), binding with a 1.9μm equilibrium dissociation constant (K(D)) to human Raf-1 (hRaf-1), a protein kinase of central importance in the MAPK/ERK proliferation pathway. The molecular evolution process was followed on both gene and protein levels via DNA sequencing and a biosensor-based binding analysis of pools of selected variants. After two cycles of diversification and selection, a significant increase in binding response of selected pools was seen. DNA sequencing showed that a dominant alanine to valine substitution had been effectively enriched, and was found in 83% of all selected clones, either alone or in combination with other enriched substitutions. The evolution procedure resulted in variants showing up to 26-fold increases in affinity to the hRaf-1 target. Noteworthy, for the two variants showing the highest affinities, substitutions were also found in affibody framework positions, corresponding to regions of the protein domain not addressed by traditional affibody molecule affinity maturation strategies. Interestingly, thermal melting point (T(m)) analyses showed that an increased affinity could be associated with both higher and lower T(m) values. All investigated variants showed excellent refolding properties and selective binding to hRaf-1, as analysed using a multiplexed bead-based binding assay, making them potentially valuable affinity reagents for cell biology studies.     

Staphylococcal display for combinatorial protein engineering of a head-to-tail affibody dimer binding the Alzheimer amyloid-β peptide

We have previously generated an affibody molecule for the disease-associated amyloid beta (Aβ) peptide, which has been shown to inhibit the formation of various Aβ aggregates and revert the neurotoxicity of Aβ in a fruit fly model of Alzheimer's disease. In this study, we have investigated a new bacterial display system for combinatorial protein engineering of the Aβ-binder as a head-to-tail dimeric construct for future optimization efforts, e.g. affinity maturation. Using the bacterial display platform, we have: (i) demonstrated functional expression of the dimeric binder on the cell surface, (ii) determined the affinity and investigated the pH sensitivity of the interaction, (iii) demonstrated the importance of an intramolecular disulfide bond through selections from a cell-displayed combinatorial library, as well as (iv) investigated the effects from rational truncation of the N-terminal part of the affibody molecule on surface expression level and Aβ binding. Overall, the detailed engineering and characterization of this promising Aβ-specific affibody molecule have yielded valuable insights concerning its unusual binding mechanism. The results also demonstrated that our bacterial display system is a suitable technology for future protein engineering and characterization efforts of homo- or heterodimeric affinity proteins.     

Site-specific and reversible anchoring of active proteins onto cellulose using a cellulosome-like complex

Protein engineering strategies facilitating controlled and spontaneous assembly of macromolecular complexes are of great interest for the design of artificial multi-enzyme systems of pre-defined composition. Here we have combined affinity proteins from different sources to achieve specific and reversible anchoring of affinity domain-tagged reporter proteins to a cellulose-anchored fusion protein. The design principle mimics the architecture of macromolecular cellulosome complexes produced by some cellulolytic microbes. A fusion protein between a cellulose-binding module (CBM1Cel6A) of the Trichoderma reesei cellobiohydrolase Cel6A and a five-domain staphylococcal protein A (SPA) was constructed to serve as platform for docking of easily detectable reporter proteins onto cellulose surfaces. In turn, the reporter proteins were produced as fusions to two copies of a SPA-binding affinity protein (an affibody denoted Z(SPA-1)), selected from a phage display library constructed by combinatorial protein engineering. In a series of experiments, involving repeated washing and low pH elution, affinity-tagged Enhanced Green Fluorescent Protein (EGFP) and Fusarium solani pisi lipase cutinase reporter proteins were both found to be specifically directed from solution to the same region of a cellulose filter paper where SPA-CBM1Cel6A fusion protein had been previously applied. This showed that the SPA-CBM1Cel6A fusion protein had been stably anchored to the cellulose surface without loss of binding capacity and that the interaction between SPA and the Z(SPA-1) affibody domains was selective. The generality of this biospecificity-driven system for assembly applications is discussed.     

Target selectivity in EF-hand calcium binding proteins

EF-hand calcium binding proteins have remarkable sequence homology and structural similarity, yet their response to binding of calcium is diverse and they function in a wide range of biological processes. Knowledge of the fine-tuning of EF-hand protein sequences to optimize specific biochemical properties has been significantly advanced over the past 10 years by determination of atomic resolution structures. These data lay the foundation for addressing how functional selectivity is generated from a generic ionic signal. This review presents current ideas about the structural mechanisms that provide the selectivity of different EF-hand proteins for specific cellular targets, using S100 and calmodulin family proteins to demonstrate the critical concepts. Three factors contribute significantly to target selectivity: molecular architecture, response to binding of Ca(2+) ions, and the characteristics of target binding surfaces. Comparisons of calmodulin and S100 proteins provide insights into the role these factors play in facilitating the variety of binding configurations necessary for recognizing a diverse set of targets.     

昆虫嗅觉结合蛋白研究进展

嗅觉结合蛋白是嗅觉系统的第一个参与者,主要表达在嗅觉外周系统淋巴液中,负责识别、结合和转运气味和信息素分子到达嗅觉受体.近些年,随着各种生物新技术的应用,大量昆虫嗅觉结合蛋白被鉴定出来,其各种不同功能得到揭示.本文对近年来嗅觉结合蛋白的分子特征、蛋白结构、功能和应用等方面的研究进展进行总结和综述.总的来说,嗅觉结合蛋白...     

IQGAP1 and its binding proteins control diverse biological functions

IQGAP proteins have been identified in a wide spectrum of organisms, ranging from yeast to humans. The most extensively studied family member is the ubiquitously expressed scaffold protein IQGAP1, which participates in multiple essential aspects of mammalian biology. IQGAP1 mediates these effects by binding to and regulating the function of numerous interacting proteins. Over ninety proteins have been reported to associate with IQGAP1, either directly or as part of a larger complex. In this review, we summarise those IQGAP1 binding partners that have been identified in the last five years. The molecular mechanisms by which these interactions contribute to the functions of receptors and their signalling cascades, small GTPase function, cytoskeletal dynamics, neuronal regulation and intracellular trafficking are evaluated. The evidence that has accumulated recently validates the role of IQGAP1 as a scaffold protein and expands the repertoire of cellular activities in which it participates.     

Mammalian odorant binding proteins

Odorant binding proteins (OBPs) pertain to one of the most abundant classes of proteins found in the olfactory apparatus. OBPs are a sub-class of lipocalins, defined by their property of reversibly binding volatile chemicals, that we call 'odorants'. Numerous sequences of OBPs are now available, derived from protein sequencing from nasal mucus material, or from DNA sequences. The structural knowledge of OBPs has been improved too in recent years, with the availability of two X-ray structures. The physiological role of OBPs remains, however, essentially hypothetical, and most probably, not linked to a function of odor transport. The present knowledge on OBP biochemistry, sequence and structure will be examined here in relation to the different functional hypotheses proposed for OBPs.     

Alternative binding proteins: anticalins - harnessing the structural plasticity of the lipocalin ligand pocket to engineer novel binding activities

Antibodies are the paradigm for binding proteins, with their hypervariable loop region supported by a structurally rigid framework, thus providing the vast repertoire of antigen-binding sites in the immune system. Lipocalins are another family of proteins that exhibit a binding site with high structural plasticity, which is composed of four peptide loops mounted on a stable beta-barrel scaffold. Using site-directed random mutagenesis and selection via phage display against prescribed molecular targets, it is possible to generate artificial lipocalins with novel ligand specificities, so-called anticalins. Anticalins have been successfully selected both against small hapten-like compounds and against large protein antigens and they usually possess high target affinity and specificity. Their structural analysis has yielded interesting insights into the phenomenon of molecular recognition. Compared with antibodies, they are much smaller, have a simpler molecular architecture (comprising just one polypeptide chain) and they do not require post-translational modification. In addition, anticalins exhibit robust biophysical properties and can easily be produced in microbial expression systems. As their structure-function relationships are well understood, rational engineering of additional features such as site-directed pegylation or fusion with functional effector domains, dimerization modules or even with another anticalin, can be readily achieved. Thus, anticalins offer many applications, not only as reagents for biochemical research but also as a new class of potential drugs for medical therapy.     

Monobodies and other synthetic binding proteins for expanding protein science

Synthetic binding proteins are constructed using nonantibody molecular scaffolds. Over the last two decades, in‐depth structural and functional analyses of synthetic binding proteins have improved combinatorial library designs and selection strategies, which have resulted in potent platforms that consistently generate binding proteins to diverse targets with affinity and specificity that rival those of antibodies. Favorable attributes of synthetic binding proteins, such as small size, freedom from disulfide bond formation and ease of making fusion proteins, have enabled their unique applications in protein science, cell biology and beyond. Here, we review recent studies that illustrate how synthetic binding proteins are powerful probes that can directly link structure and function, often leading to new mechanistic insights. We propose that synthetic proteins will become powerful standard tools in diverse areas of protein science, biotechnology and medicine.     

Evaluation of ((4-hydroxyphenyl)ethyl)maleimide for site-specific radiobromination of anti-HER2 affibody

Affibody molecules are a new class of small phage-display selected proteins using a scaffold domain of the bacterial receptor protein A. They can be selected for specific binding to a large variety of protein targets. An affibody molecule binding with high affinity to a tumor antigen HER2 was recently developed for radionuclide diagnostics and therapy in vivo. The use of the positron-emitting nuclide (76)Br (T(1/2) = 16.2 h) could improve the sensitivity of detection of HER2-expressing tumors. A site-specific radiobromination of a cysteine-containing variant of the anti-HER2 affibody, (Z(HER2:4))(2)-Cys, using ((4-hydroxyphenyl)ethyl)maleimide (HPEM), was evaluated in this study. It was found that HPEM can be radiobrominated with an efficiency of 83 +/- 0.4% and thereafter coupled to freshly reduced affibody with a yield of 65.3 +/- 3.9%. A "one-pot" labeling enabled the radiochemical purity of the conjugate to exceed 97%. The label was stable against challenge with large excess of nonlabeled bromide and in a high molar strength solution. In vitro cell tests demonstrated that radiobrominated affibody binds specifically to the HER2-expressing cell-line, SK-OV-3. Biodistribution studies in nude mice bearing SK-OV-3 xenografts have shown tumor accumulation of 4.8 +/- 2.2% IA/g and good tumor-to-normal tissue ratios.     

Magnesium fluoride-dependent binding of small G proteins to their GTPase-activating proteins.

GTPase-activating proteins (GAPs) enhance the intrinsic GTPase activity of small G proteins, such as Ras and Rho, by contributing a catalytic arginine to the active site. An intramolecular arginine plays a similar role in heterotrimeric G proteins. Aluminum fluoride activates the GDP form of heterotrimeric G proteins, and enhances binding of the GDP form of small G proteins to their GAPs. The resultant complexes have been interpreted as analogues of the transition state of the hydrolytic reaction. Here, equilibrium binding has been measured using scintillation proximity assays to provide quantitative information on the fluoride-mediated interaction of Ras and Rho proteins with their respective GAPs, neurofibromin (NF1) and RhoGAP. High-affinity fluoride-mediated complex formation between Rho.GDP and RhoGAP occurred in the absence of aluminum; however, under these conditions, magnesium was required. Additionally, the novel observation was made of magnesium-dependent, fluoride-mediated binding of Ras.GDP to NF1 in the absence of aluminum. Aluminum was required for complex formation when the concentration of magnesium was low. Thus, either aluminum fluoride or magnesium fluoride can mediate the high-affinity binding of Rho. GDP or Ras.GDP to GAPs. It has been reported that magnesium fluoride can activate heterotrimeric G proteins. Thus, magnesium-dependent fluoride effects might be a general phenomenon with G proteins. Moreover, these data suggest that some protein.nucleotide complexes previously reported to contain aluminum fluoride may in fact contain magnesium fluoride.     

Identification of DNA binding proteins from human cells

Eukaryotic DNA binding proteins have been observed indirectly by means of filter-binding assays, mobility shifts on nondenaturing gel electrophoresis, nucleolytic protection studies, and functional analyses. Transacting factors, presumably proteins, are implicated in regulation of gene expression at the promoter and enhancer. The identification of the polypeptide or polypeptides involved in DNA recognition and binding is an important, challenging problem. A general method is presented herein for the identification of proteins that bind DNA, based directly on the property of DNA binding. A nuclear protein extract, fractionated by ion-exchange chromatography, is assayed across the column for binding activity using nondenaturing polyacrylamide gel electrophoresis. Samples of column eluate that display binding activity are then subjected to nondenaturing gel electrophoresis in the presence or absence of substrate DNA. The nondenaturing gel strips are cut out and run orthogonally on discontinuous sodium dodecyl sulfate gels for the identification of proteins. A protein that undergoes a first-dimension mobility shift to the position of DNA bound to protein is the protein that bound the DNA. We have identified a pair of polypeptides from leukemic human cells of apparent molecular weights 70 and 85 kd that bind DNA as a complex.     

Human immunoglobulin A (IgA)-specific ligands from combinatorial engineering of protein A.

Affinity reagents capable of selective recognition of the different human immunoglobulin isotypes are important detection and purification tools in biotechnology. Here we describe the development and characterization of affinity proteins (affibodies) showing selective binding to human IgA. From protein libraries constructed by combinatorial mutagenesis of a 58-amino-acid, three-helix bundle domain derived from the IgG-binding staphylococcal protein A, variants showing IgA binding were selected by using phage display technology and IgA monoclonal antibodies (myeloma) as target molecules. Characterization of selected clones by biosensor technology showed that five out of eight investigated affibody variants were capable of IgA binding, with dissociation constants (K(d)) in the range between 0.5 and 3 microm. One variant (Z(IgA1)) showing the strongest binding affinity was further analyzed, and showed that human IgA subclasses (IgA(1) and IgA(2)) as well as secretory IgA were recognized with similar efficiencies. No detectable cross-reactivity towards human IgG, IgM, IgD or IgE was observed. The potential use of the Z(IgA1) affibody as a ligand in affinity chromatography applications was first demonstrated by selective recovery of IgA protein from a spiked Escherichia coli total cell lysate, using an affinity column containing a divalent head-to-tail Z(IgA1) affibody dimer construct as a ligand. In addition, efficient affinity recovery of IgA from unconditioned human plasma was also demonstrated.     

RNA binding strategies of ribosomal proteins.

Structures of a number of ribosomal proteins have now been determined by crystallography and NMR, though the complete structure of a ribosomal protein-rRNA complex has yet to be solved. However, some ribosomal protein structures show strong similarity to well-known families of DNA or RNA binding proteins for which structures in complex with cognate nucleic acids are available. Comparison of the known nucleic acid binding mechanisms of these non-ribosomal proteins with the most highly conserved surfaces of similar ribosomal proteins suggests ways in which the ribosomal proteins may be binding RNA. Three binding motifs, found in four ribosomal proteins so far, are considered here: homeodomain-like alpha-helical proteins (L11), OB fold proteins (S1 and S17) and RNP consensus proteins (S6). These comparisons suggest that ribosomal proteins combine a small number of fundamental strategies to develop highly specific RNA recognition sites.     

Interaction of Alzheimer's A beta peptide with an engineered binding protein--thermodynamics and kinetics of coupled folding-binding

The oligomerization and aggregation of the amyloid-β (Aβ) peptide, a cleavage product of the amyloid precursor protein predominantly 40 or 42 amino acids in length, has been implicated in the pathogenesis of Alzheimer's disease. The identification of Aβ-binding agents, e.g., antibodies or peptides, constitutes a promising therapeutic approach. However, the amount of structural and biophysical data on the underlying Aβ interactions is currently very limited. We have earlier determined the structure of Aβ(1-40) in complex with the affibody protein Z_Aβ3, a selected binding protein based on a three-helix bundle scaffold (Z domain). Z_Aβ3 is a dimer of affibody subunits linked via a disulfide bridge involving a selected cysteine mutation at position 28. Z_Aβ3 binds to the central and C-terminal part of Aβ (residues 17-36), which adopts a β-hairpin conformation in the complex. Here we present a detailed biophysical analysis of the Z_Aβ3:Aβ(1-40) interaction, employing NMR, circular dichroism spectroscopy, 8-anilino-1-naphthalenesulfonic acid and tyrosine fluorescence, size-exclusion chromatography, thermal denaturation profiles and isothermal titration calorimetry. We conclude that (i) free Z_Aβ3 is characterized by conformational exchange and the loss of helix 1 of the three-helix bundle scaffold; (ii) a high-energy barrier is associated with the conversion of an initial Z_Aβ3:Aβ(1-40) recognition complex into the native complex structure, entailing slow binding kinetics; (iii) both Aβ and Z_Aβ3 fold upon binding, which, e.g., becomes manifest in the binding thermodynamics that feature a large negative change in heat capacity; (iv) the C28-disulfide does not merely afford dimerization, but its impact on the binding interfaces of the affibody subunits and Aβ is a prerequisite for tight binding. The extensive folding coupled to binding observed here likely constitutes an obligate feature of biomolecular interactions involving the central and C-terminal part of Aβ. Options for improvement of Z_Aβ binding proteins are discussed.