A second-generation system for unbiased reading frame selection

Reading frame selection of nucleic acids has important implications for protein engineering and genomics. Current methods are limited because selection of the gene of interest inevitably depends on the solubility of its translated product. Here we report the construction of the pInSALect vector, which provides strict reading frame selection without concomitant selection for protein solubility or folding. This plasmid incorporates the cis-splicing VMA intein sequence from Saccharomyces cerevisiae to facilitate the post-translational self-excision of the protein of interest, thereby eliminating potential aggregation problems. Results from two libraries of chimeric glycinamide ribonucleotide formyltransferases confirm the superior performance of pInSALect over existing reading frame selection systems.     

Isolating recombinant antibodies against specific protein morphologies using atomic force microscopy and phage display technologies

Isolation of antibodies to antigens that are either unstable, exist in multiple morphologies or have very limited availability can be prohibitively difficult. Here we describe a novel technique combining the capabilities of phage display antibody technology and atomic force microscopy (AFM) that is used to isolate antibody fragments that bind to a specific morphology of the target antigen, alpha-synuclein. AFM imaging allows us to both visualize the presence and morphology of the target antigen as well as to monitor the efficiency of each step in the bio-panning process. We demonstrate that phage displayed antibodies specific to the target antigen morphology can be isolated after only two rounds of selection. The target antigen, alpha-synuclein, has been correlated with the Parkinson's disease (PD). Accumulation of alpha-synuclein fibrillar aggregates into Lewy body inclusions is a hallmark feature of PD. While alpha-synuclein can form several different aggregate morphologies including oligomers, protofibrils and fibrils, the role of these morphologies in the progression of PD is not known. The successful selection of the recombinant antibody described here can have potential therapeutic value since the single-chain fragment variable (scFv) can be expressed intracellularly to control folding and toxicity of the specific protein aggregates.     

Optimal protein library design using recombination or point mutations based on sequence-based scoring functions

In this paper, we introduce and test two new sequence-based protein scoring systems (i.e. S1, S2) for assessing the likelihood that a given protein hybrid will be functional. By binning together amino acids with similar properties (i.e. volume, hydrophobicity and charge) the scoring systems S1 and S2 allow for the quantification of the severity of mismatched interactions in the hybrids. The S2 scoring system is found to be able to significantly functionally enrich a cytochrome P450 library over other scoring methods. Given this scoring base, we subsequently constructed two separate optimization formulations (i.e. OPTCOMB and OPTOLIGO) for optimally designing protein combinatorial libraries involving recombination or mutations, respectively. Notably, two separate versions of OPTCOMB are generated (i.e. model M1, M2) with the latter allowing for position-dependent parental fragment skipping. Computational benchmarking results demonstrate the efficacy of models OPTCOMB and OPTOLIGO to generate high scoring libraries of a prespecified size.     

Two-dimensional surface display of functional groups on a beta-helical antifreeze protein scaffold

We tested a disulfide-rich antifreeze protein as a potential scaffold for design or selection of proteins with the capability of binding periodically organized surfaces. The natural antifreeze protein is a beta-helix with a strikingly regular two-dimensional grid of threonine side chains on its ice-binding face. Amino acid substitutions were made on this face to replace blocks of native threonines with other amino acids spanning the range of beta-sheet propensities. The variants, displaying arrays of distinct functional groups, were studied by mass spectrometry, reversed-phase high performance liquid chromatography, thiol reactivity and circular dichroism and NMR spectroscopies to assess their structures and stabilities relative to wild type. The mutants are well expressed in bacteria, despite the potential for mis-folding inherent in these 84-residue proteins with 16 cysteines. We demonstrate that most of the mutants essentially retain the native fold. This disulfide bonded beta-helical scaffold, thermally stable and remarkably tolerant of amino acid substitutions, is therefore useful for design and engineering of macromolecules with the potential to bind various targeted ordered material surfaces.     

A system based on specific protein-RNA interactions for analysis of target protein-protein interactions in vitro: successful selection of membrane-bound Bak-Bcl-xL proteins in vitro

Ribosome display systems are very effective and powerful tools for in vitro screening of transcribed mRNAs that encode proteins (or peptides) with specific (known or unknown) functions. We have modified such a system by exploiting the interaction between a tandemly fused MS2 coat-protein (MSp) dimer and the RNA sequence of the corresponding specific binding motif, C-variant (or Cv). We placed the MSp dimer at the N-terminus of a nascent protein and the Cv binding motif was attached to the 5' end of the protein's mRNA. This configuration enhanced the stability of the ribosome-mRNA complex. We demonstrate here that this improved ribosome display system provides an effective method for identifying the gene for a protein that binds to a protein of interest. We visualized the formation of polysome complexes in this advanced polysome display by atomic force microscopy (AFM) and found that the AFM images of polysomes in our system were different from those observed in the case of conventional ribosome display systems. Our results suggest that our technology might usefully complement yeast two-hybrid assays.     

The cystine knot of a squash-type protease inhibitor as a structural scaffold for Escherichia coli cell surface display of conformationally constrained peptides

The Ecballium elaterium trypsin inhibitor II (EETI-II), a memberof the squash family of protease inhibitors, is composed of28 amino acid residues and is a potent inhibitor of trypsin.Its compact structure is defined by a triple-stranded antiparallelß-sheet, which is held together by three intramoleculardisulfide bonds forming a cystine knot. In order to explorethe potential of the EETI-II peptide to serve as a structuralscaffold for the presentation of randomized oligopeptides, weconstructed two EETI-II derivatives, where the six-residue inhibitorloop was replaced by a 13-residue epitope of Sendai virus L-proteinand by a 17-residue epitope from human bone Gla-protein. EETI-IIand derived variants were produced via fusion to maltose bindingprotein MalE. By secretion of the fusion into the periplasmicspace, fully oxidized and correctly folded EETI-II was obtainedin high yield. EETI-II and derived variants could be presentedon the Escherichia coli outer membrane by fusion to truncatedLpp'–OmpA', which comprises the first nine residues ofmature lipoprotein plus the membrane spanning ß-strandfrom residues 46–66 of OmpA protein. Gene expression wasunder control of the strong and tightly regulated tetA promoter/operator.Cell viability was found to be drastically reduced by high levelexpression of Lpp'–OmpA'–EETI-II fusion protein.To restore cell viability, net accumulation of fusion proteinin the outer membrane was reduced to a tolerable level by introductionof an amber codon at position 9 of the lpp' sequence and utilizingan amber suppressor strain as expression host. Cells expressingEETI-II variants containing an epitope were shown to be surfacelabeled with the respective monoclonal antibody by indirectimmunofluorescence corroborating the cell surface exposure ofthe epitope sequences embedded in the EETI-II cystine knot scaffold.Cells displaying a particular epitope sequence could be enriched10⁷-fold by combining magnetic cell sorting with fluorescence-activatedcell sorting. These results demonstrate that E.coli cell surfacedisplay of conformationally constrained peptides tethered tothe EETI-II cystine knot scaffold has the potential to becomean effective technique for the rapid isolation of small peptidemolecules from combinatorial libraries that bind with high affinityto acceptor molecules.     

Development of an optimized expression system for the screening of antibody libraries displayed on the Escherichia coli surface

Polypeptide library screening technologies are critically dependentupon the characteristics of the expression system employed.A comparative analysis of the lpp–lac, tet and araBAD promoterswas performed to determine the importance of tight regulationand expression level in library screening applications. Thesurface display of single-chain antibody (scFv) in Escherichiacoli as an Lpp–OmpA' fusion was monitored using a fluorescentlytagged antigen in conjunction with flow cytometry. In contrastto the lpp–lac promoter, both tet and araBAD promoterscould be tightly repressed. Tight regulation was found to beessential for preventing rapid depletion of library clones expressingfunctional scFv and thus for maintaining the initial librarydiversity. Induction with subsaturating inducer concentrationsyielded mixed populations of uninduced and fully induced cellsfor both the tet and araBAD expression systems. In contrast,homogeneous expression levels were obtained throughout the populationusing saturating inducer concentrations and could be adjustedby varying the induction time and plasmid copy number. Underoptimal induction conditions for the araBAD system, proteinexpression did not compromise either cell viability or librarydiversity. This expression system was used to screen a libraryof random scFv mutants specific for digoxigenin for clones exhibitingimproved hapten dissociation kinetics. Thus, an expression systemhas been developed which allows library diversity to be preservedand is generally applicable to the screening of E.coli surfacedisplayed libraries.     

A new protein conjugate that replaces the use of secondary antibodies engineered from the two staphylococcal enzymes protein A and 6-phospho-{beta}-galactosidase

The lacG gene encoding the 6-phospho-ß-galactosidase(E.C.3.2.1.85) of Staphylococcus aureus was fused to the proteinA gene in the plasmid pRIT2T. Escherichia coli cells containingthis plasmid produce a fusion protein with both IgG bindingand 6-phospho-ß-galactosidase activities after heatinduction. The recombinant gene was overexpressed and the hybridprotein was purified to homogeneity in high yield. The chimericprotein was shown to have almost identical enzymatic characteristicsto pure 6-phospho-ß-galactosidase. This result leadsto the conclusion that a free N-terminus of the 6-phospho-ß-galactosidaseis not required for biological activity. The hybrid proteinof protein A and 6-phospho-ß-galactosidase was usedas an enzyme conjugate in enzyme-linked immunosorbent assays(ELISA). The experiments presented demonstrate that the 6-phospho-ß-galactosidaseis a suitable fusion partner in various diagnostic applicationswhere an unique biological activity is required.     

Synthesis and mutagenesis of an IgG-binding protein based upon protein A of Staphylococcus aureus

A novel protein able to bind with high affinity to the Fc fragmentof IgG from a variety of animals has been produced by a genesynthesis approach. The IgG binding is accomplished by the presenceof a single or two consecutive domains based upon domain B fromprotein A of Staphylo-coccus aureus. The IgG-binding moietyis fused to a peptide containing 21, 53 or 81 amino acids derivedfrom the N-terminus of bovine DNase I. The latter is presentto guide the expression of the protein in Escherichia coli intoan inclusion body. This facilitates the high expression andrecovery of the IgG-binding domains. The binding activity ofthis fusion protein is very close to that of the native proteinA. Site-directed mutagenesis of the fusion protein and subsequentidentification of changed binding interactions is reported.     

A knowledge-based scoring function based on residue triplets for protein structure prediction

One of the general paradigms for ab initio protein structure prediction involves sampling the conformational space such that a large set of decoy (candidate) structures are generated and then selecting native-like conformations from those decoys using various scoring functions. In this study, based on a physical/geometric approach first suggested by Banavar and colleagues, we formulate a knowledge-based scoring function, which uses the radii of curvature formed among triplets of residues in a protein conformation. By analyzing its performance on various decoy sets, we determine a good set of parameters--the distance cutoff and the number of distance bins--to use for configuring such a function. Furthermore, we investigate the effect of using various approaches for compiling the prior distribution on the performance of the knowledge-based function. Possible extensions to the current form of the residue triplet scoring function are discussed.     

A simple approach for protein structure discrimination based on the network pattern of conserved hydrophobic residues

Evolutionarily conserved hydrophobic residues at the core of protein structures are generally assumed to play a structural role in protein folding and stability. Recent studies have implicated that their importance to protein structures is uneven, with a few of them being crucial and the rest of them being secondary. In this work, we explored the possibility of employing this feature of native structures for discriminating non-native structures from native ones. First, we developed a network tool to quantitatively measure the structural contributions of individual amino acid residues. We systematically applied this method to diverse fold-type sets of native proteins. It was confirmed that this method could grasp the essential structural features of native proteins. Next, we applied it to a number of decoy sets of proteins. The results indicate that such an approach indeed identified non-native structures in most test cases. This finding should be of help for the investigation of the fundamental problem of protein structure prediction.     

The stability and unfolding of an IgG binding protein based upon the B domain of protein A from Staphylococcus aureus probed by tryptophan substitution and fluorescence spectroscopy

The stability and unfolding of an immunoglobulin (Ig) G bindingprotein based upon the B domain of protein A (SpAB) from Staphylococcusaureus were studied by substituting tryptophan residues at strategiclocations within each of the three a-helical regions (al-a3)of the domain. The role of the C-terminal helix, a3, was investigatedby generating two protein constructs, one corresponding to thecomplete SpAB, the other lacking a part of ct3; the Trp substitutionswere made in both one-and two-domain versions of each of theseconstructs. The fluorescence properties of each of the single-tryptophanmutants were studied in the native state and as a function ofguanidine-HCl-mediated unfolding, and their IgG binding activitieswere determined by a competitive enzyme-linked immunosorbentassay. The free energies of folding and of binding to IgG foreach mutant were compared with those for the native domains.The effect of each substitution upon the overall structure andupon the IgG binding interface was modelled by molecular graphicsand energy minimization. These studies indicate that (i) 3 contributesto the overall stability of the domain and to the formationof the IgG binding site in l and 2, and (ii) al unfolds first,followed by 2 and 3 together.     

Hydrophobic regions on protein surfaces: definition based on hydration shell structure and a quick method for their computation

The hydrophobic part of the solvent-accessible surface of atypical monomeric globular protein consists of a single, largeinterconnected region formed from faces of apolar atoms andconstituting –60% of the solvent-accessible surface area.Therefore, the direct delineation of the hydrophobic surfacepatches on an atom-wise basis is impossible. Experimental dataindicate that, in a two-state hydration model, a protein canbe considered to be unified with its first hydration shell inits interaction with bulk water. We show that, if the surfacearea occupied by water molecules bound at polar protein atomsas generated by AUTOSOL is removed, only about two-thirds ofthe hydrophobic part of the protein surface remains accessibleto bulk solvent. Moreover, the organization of the hydrophobicpart of the solvent-accessible surface experiences a drasticchange, such that the single interconnected hydrophobic regiondisintegrates into many smaller patches, i.e. the physical definitionof a hydrophobic surface region as unoccupied by first hydrationshell water molecules can distinguish between hydrophobic surfaceclusters and small interconnecting channels. It is these remaininghydrophobic surface pieces that probably play an important rolein intraand intermolecular recognition processes such as ligandbinding, protein folding and protein–protein associationin solution conditions. These observations have led to the developmentof an accurate and quick analytical technique for the automaticdetermination of hydrophobic surface patches of proteins. Thistechnique is not aggravated by the limiting assumptions of themethods for generating explicit water hydration positions. Formationof the hydrophobic surface regions owing to the structure ofthe first hydration shell can be computationally simulated bya small radial increment in solvent-accessible polar atoms,followed by calculation of the remaining exposed hydrophobicpatches. We demonstrate that a radial increase of 0.35–0.50Å resembles the effect of tightly bound water on the organizationof the hydrophobic part of the solvent-accessible surface.     

A novel method for predicting transmembrane segments in proteins based on a statistical analysis of the SwissProt database: the PRED-TMR algorithm

We present a novel method that predicts transmembrane domainsin proteins using solely information contained in the sequenceitself. The PRED-TMR algorithm described, refines a standardhydrophobicity analysis with a detection of potential termini(`edges', starts and ends) of transmembrane regions. This allowsone both to discard highly hydrophobic regions not delimitedby clear start and end configurations and to confirm putativetransmembrane segments not distinguishable by their hydrophobiccomposition. The accuracy obtained on a test set of 101 non-homologoustransmembrane proteins with reliable topologies compares wellwith that of other popular existing methods. Only a slight decreasein prediction accuracy was observed when the algorithm was appliedto all transmembrane proteins of the SwissProt database (release35). A WWW server running the PRED-TMR algorithm is availableat http://o2.db.uoa.gr/PRED-TMR/     

A dual-affinity gene fusion system to express small recombinant proteins in a soluble form: expression and characterization of protein A deletion mutants

A novel gene fusion system to express and purify small recombinantproteins in Escherichia coli has been constructed. The conceptallows for affinity purification of soluble gene products bysequential albumin- and Zn²+-affinity chromatography. The dual-affinitysystem is well suited for expression of unstable proteins asonly full-length protein is obtained after purification andproteins gain proteolytic stability in the fusion protein. Herewe show that the dual-affinity approach can be used for theexpression of various unstable derivatives of a single IgG-bindingdomain based on staphylococcal protein A. Analysis of the proteolyticstabilities and the IgG-binding properties of the differentmutant proteins suggest that the model for the structure ofan IgG-binding domain must be re-evaluated.     

Modelling the structure of latexin-carboxypeptidase A complex based on chemical cross-linking and molecular docking

We have determined the three-dimensional structure of the protein complex between latexin and carboxypeptidase A using a combination of chemical cross-linking, mass spectrometry and molecular docking. The locations of three intermolecular cross-links were identified using mass spectrometry and these constraints were used in combination with a speed-optimised docking algorithm allowing us to evaluate more than 3 x 10(11) possible conformations. While cross-links represent only limited structural constraints, the combination of only three experimental cross-links with very basic molecular docking was sufficient to determine the complex structure. The crystal structure of the complex between latexin and carboxypeptidase A4 determined recently allowed us to assess the success of this structure determination approach. Our structure was shown to be within 4 A r.m.s. deviation of Calpha atoms of the crystal structure. The study demonstrates that cross-linking in combination with mass spectrometry can lead to efficient and accurate structural modelling of protein complexes.     

The influence of collector and bacterial cell surface properties on the deposition of oral streptococci in a parallel plate flow cell

Abstraet-The deposition of two strains of oral streptococci on collector surfaces with different surface free energies has been studied in a parallel plate flow cell at various buffer concentrations. One of the strains, Streptococcus salivarius HB, was characterized by the presence of proteinaceous surface appendages with lengths between 72 and 178 nm; whereas S. salivarius HB-C12, a spontaneous mutant of S. salivarius HB, was devoid of all surface appendages. Large differences were observed between the deposition rates of the two strains which were not predicted by theoretical calculations based on the convective diffusion equation using a DLVO-type potential function. This difference was attributed to the influence of the surface appendages of S. salivarius HB, which were absent on the mutant strain S. salivarius HB-C12. Furthermore, an additional attractive interaction, not accounted for in the DLVO theory, was needed in order to match the experimental deposition rates on the low surface free energy collector surfaces with theoretical predictions.     

Synthesis and functionality of poly(N-vinylalkylamide). X. A novel aqueous two-phase system based on thermosensitive polymers and dextran

The use of thermosensitive polymers in an aqueous two-phase system was studied. Poly(N-isopropylacrylamide) (PNIPAAm) and poly(N-vinylisobutyramide) (PNVIBA) were used as thermosensitive polymers. Both polymers could form aqueous two-phase with dextran, respectively. The phase diagrams of each system were successfully obtained. Using myoglobin as a model protein, a preliminary separation study was performed. The separation ability of both polymers was higher than that from the poly(ethylene glycol)-dextran system. Protein separation ability appeared to be related to the hydrophilic/hydrophobic balance of the polymers. Both PNVIBA and PNIPAAm rich phases maintained their thermosensitivity after two-phase formation. PNVIBA and PNIPAAm are useful as polymers for a functional aqueous two-phase system. © 1999 John Wiley & Sons, Inc. J Appl Polym Sci 73: 2545–2548, 1999