Stably folded de novo proteins from a designed combinatorial library

Binary patterning of polar and nonpolar amino acids has been used as the key design feature for constructing large combinatorial libraries of de novo proteins. Each position in a binary patterned sequence is designed explicitly to be either polar or nonpolar; however, the precise identities of these amino acids are varied extensively. The combinatorial underpinnings of the "binary code" strategy preclude explicit design of particular side chains at specified positions. Therefore, packing interactions cannot be specified a priori. To assess whether the binary code strategy can nonetheless produce well-folded de novo proteins, we constructed a second-generation library based upon a new structural scaffold designed to fold into 102-residue four-helix bundles. Characterization of five proteins chosen arbitrarily from this new library revealed that (1) all are alpha-helical and quite stable; (2) four of the five contain an abundance of tertiary interactions indicative of well-ordered structures; and (3) one protein forms a well-folded structure with native-like features. The proteins from this new 102-residue library are substantially more stable and dramatically more native-like than those from an earlier binary patterned library of 74-residue sequences. These findings demonstrate that chain length is a crucial determinant of structural order in libraries of de novo four-helix bundles. Moreover, these results show that the binary code strategy--if applied to an appropriately designed structural scaffold--can generate large collections of stably folded and/or native-like proteins.     

Use of bioinformatics to predict a function for the GS element in Mycobacterium avium subspecies paratuberculosis

Filamentous bacteriophages are nonlytic, male-specific bacteriophages which infect Escherichia coli carrying an F-episome. The molecular mechanism of infection remains elusive, including the role of the major coat protein pVIII. In order to evaluate the contributions of major coat protein pVIII in the process of infection, two phage display libraries were generated. One library consisted of random amino acids at positions 2, 4, 5, 8, 11 and 12 of the N-terminus of major coat protein pVIII. The second library was generated by randomizing these positions as well as position 1. All these residues were previously shown to be exposed at the surface of the virions by being accessible to ligands. The infectivity of randomly selected mutant phages was analyzed. The present results demonstrate that phages modified at these positions can be correctly assembled and secreted into the exoplasm, although the efficiency was slightly lower than that of wild-type phage. Their infectivity varied greatly, and a general structural pattern underlying infectivity did not emerge. However, residual differences were observed between infectious and defective phage; in general, uncharged polar amino acids present at positions 5 and 11 of the N-terminus of pVIII reduced phage infectivity, whereas polar residues at position 8 facilitated infection. The first position of pVIII is remarkably critical for infection; when this alanine was substituted with other residues, most of the phages lost their infectivity. These results shed new light on the true complexity of random peptide pVIII phage display libraries.     

Comparison of the frequency of functional SH3 domains with different limited sets of amino acids using mRNA display

Although modern proteins consist of 20 different amino acids, it has been proposed that primordial proteins consisted of a small set of amino acids, and additional amino acids have gradually been recruited into the genetic code. This hypothesis has recently been supported by comparative genome sequence analysis, but no direct experimental approach has been reported. Here, we utilized a novel experimental approach to test a hypothesis that native-like globular proteins might be easily simplified by a set of putative primitive amino acids with retention of its structure and function than by a set of putative new amino acids. We performed in vitro selection of a functional SH3 domain as a model from partially randomized libraries with different sets of amino acids using mRNA display. Consequently, a library rich in putative primitive amino acids included a larger number of functional SH3 sequences than a library rich in putative new amino acids. Further, the functional SH3 sequences were enriched from the primitive library slightly earlier than from a randomized library with the full set of amino acids, while the function and structure of the selected SH3 proteins with the primitive alphabet were comparable with those from the 20 amino acid alphabet. Application of this approach to various combinations of codons in protein sequences may be useful not only for clarifying the precise order of the amino acid expansion in the early stages of protein evolution but also for efficiently creating novel functional proteins in the laboratory.     

Specific locations of hydrophilic amino acids in constructed transmembrane ligands of the platelet-derived growth factor beta receptor

The 44 amino acid E5 transmembrane protein is the primary oncogene product of bovine papillomavirus. Homodimers of the E5 protein activate the cellular PDGF beta receptor tyrosine kinase by binding to its transmembrane domain and inducing receptor dimerization, resulting in cellular transformation. To investigate the role of transmembrane hydrophilic amino acids in receptor activation, we constructed a library of dimeric small transmembrane proteins in which 16 transmembrane amino acids of the E5 protein were replaced with random, predominantly hydrophobic amino acids. A low level of hydrophilic amino acids was encoded at each of the randomized positions, including position 17, which is an essential glutamine in the wild-type E5 protein. Library proteins that induced transformation in mouse C127 cells stably bound and activated the PDGF beta receptor. Strikingly, 35% of the transforming clones had a hydrophilic amino acid at position 17, highlighting the importance of this position in activation of the PDGF beta receptor. Hydrophilic amino acids in other transforming proteins were found adjacent to position 17 or at position 14 or 21, which are in the E5 homodimer interface. Approximately 22% of the transforming proteins lacked hydrophilic amino acids. The hydrophilic amino acids in the transforming clones appear to be important for driving homodimerization, binding to the PDGF beta receptor, or both. Interestingly, several of the library proteins bound and activated PDGF beta receptor transmembrane mutants that were not activated by the wild-type E5 protein. These experiments identified transmembrane proteins that activate the PDGF beta receptor and revealed the importance of hydrophilic amino acids at specific positions in the transmembrane sequence. Our identification of transformation-competent transmembrane proteins with altered specificity suggests that this approach may allow the creation and identification of transmembrane proteins that modulate the activity of a variety of receptor tyrosine kinases.     

The Trp cage motif as a scaffold for the display of a randomized peptide library on bacteriophage T7

Phage libraries displaying linear or disulfide-constrained peptides often yield weak binders, upon screening against a target, and must be optimized to improve affinity. The disadvantages of libraries based on larger complex proteins, such as single chain antibodies, have stimulated interest in the development of smaller nonimmunoglobulin protein scaffolds. A promising candidate is the Trp cage motif, a 20-residue C-terminal sequence of exendin-4. Amino acid substitution within the Trp cage resulted in a 20-mer peptide recognized as an ultrafast cooperative folding miniprotein, with ideal characteristics for the discovery of small structured nonimmunoglobulin motifs having a stable tertiary structure. Although we were unable to display the Trp cage on M13 phage, successful display was achieved using the lytic T7 phage. Interestingly, mutations were observed at a frequency dependent on display valency. A Trp cage library designed with randomized amino acids at seven solvent-exposed positions was developed from 1.6 x 10(9) primary clones in T7Select10-3b. DNA sequencing of 109 library clones revealed 38% mutants and 16% truncations by TAG codons at randomized positions. Amino acid frequencies were largely within expected bounds and DIVAA analysis revealed that the library had an average diversity of 0.67. Utility of the library was demonstrated by identification of HPQ containing Trp cage miniproteins, which bound streptavidin, and AAADPYAQWLQSMGPHSGRPPPR, which bound to human bronchial epithelial cells. A high complexity library based on the Trp cage miniprotein has demonstrated potential for identifying novel cell and protein binding peptides that could be used for the delivery of therapeutic molecules or as target-specific therapeutic agents.     

Role of hydrophobic clusters in the stability of alpha-helical coiled coils and their conversion to amyloid-like beta-sheets

We designed a library of short peptides using standard rules for coiled-coil assembly. Depending on the composition of amino acids in the non-interacting region of the coiled coil (positions b, c, and f) these peptides are able to convert from alpha-helical to beta-sheet secondary structure. This type of transition is observed in amyloid-like proteins and is a key feature associated with many types of neurodegenerative diseases. Studies on peptides that are 14 amino acids in length indicated that positioning hydrophobic amino acids at an f position within a heptad repeat accelerated the rate of conformational conversion as compared to that at a c position. We believe that this occurs because of the formation of a hydrophobic pocket that preferentially stabilizes beta-sheets over alpha-helices. This effect was also observed in longer 21 amino acid peptides. Our study shows that the relative rates of structural conversion correlate with the formation of a continuous three-amino-acid hydrophobic patch consisting of amino acids in the d, f, and a positions and not on the secondary structure propensities of the individual amino acids. The sequence-structure relationship observed in this study will be used to help understand the mechanism of amyloid fiber formation and design future coiled-coil and beta-sheet-forming peptide systems.     

Sequence analysis and membrane partitioning energies of alpha-helical antimicrobial peptides

Sequences of 221 alpha-helical antimicrobial peptides (alphaAMPs) were compared and 63-166 of them were selected and analyzed using Perl programs. The results showed that aliphatic amino acids Gly, Leu, Ala, Ile and two positively charged amino acids Lys and Arg were composed of more than 63% of the first 20 residues of alphaAMPs. The weighed mean membrane partitioning energies at positions from 1 to 25 of alphaAMPs were calculated. Profile of the partitioning energies suggests oblique membrane insertion and an amphipathic alpha-helical structure of the N-terminus of alphaAMP (residues from 1 to 13), a bend structure at positions 13 and 14, and a less structured C-terminus that parallels the surface of the membrane. These structural features are in good agreement with the experimentally determined membrane structure of hemagglutinin fusion peptide from influenza virus. We hypothesize that this (N-terminal oblique alpha-helix)-central bend-(C-terminus) could be a common structural motif of membrane-disruptive peptides.     

Functionally acceptable substitutions in two alpha-helical regions of lambda repressor

A method of targeted random mutagenesis has been used to investigate the informational content of 25 residue positions in two alpha-helical regions of the N-terminal domain of lambda repressor. Examination of the functionally allowed sequences indicates that there is a wide range in tolerance to amino acid substitution at these positions. At positions that are buried in the structure, there are severe limitations on the number and type of residues allowed. At most surface positions, many different residues and residue types are tolerated. However, at several surface positions there is a strong preference for hydrophilic amino acids, and at one surface position proline is absolutely conserved. The results reveal the high level of degeneracy in the information that specifies a particular protein fold.     

Engineering of the hydrophobic core of an alpha-helical coiled coil

The amino acid sequence that forms the alpha-helical coiled coil structure has a representative heptad repeat denoted by defgabc, according to their positions. Although the a and d positions are usually occupied by hydrophobic residues, hydrophilic residues at these positions sometimes play important roles in natural proteins. We have manipulated a few amino acids at the a and d positions of a de novo designed trimeric coiled coil to confer new functions to the peptides. The IZ peptide, which has four heptad repeats and forms a parallel triple-stranded coiled coil, has Ile at all of the a and d positions. We show three examples: (1) the substitution of one Ile at either the a or d position with Glu caused the peptide to become pH sensitive; (2) the metal ion induced alpha-helical bundles were formed by substitutions with two His residues at the d and a positions for a medium metal ion, and with one Cys residue at the a position for a soft metal ion; and (3) the AAB-type heterotrimeric alpha-helical bundle formation was accomplished by a combination of Ala and Trp residues at the a positions of different peptide chains. Furthermore, we applied these procedures to prepare an ABC-type heterotrimeric alpha-helical bundle and a metal ion-induced heterotrimeric alpha-helical bundle.     

Teaching an old scaffold new tricks: monobodies constructed using alternative surfaces of the FN3 scaffold

The fibronectin type III domain (FN3) has become one of the most widely used non-antibody scaffolds for generating new binding proteins. Because of its structural homology to the immunoglobulin domain, combinatorial libraries of FN3 designed to date have primarily focused on introducing amino acid diversity into three loops that are equivalent to antibody complementarity-determining regions. Here, we report an FN3 library that utilizes alternative positions for presenting amino acid diversity. We diversified positions on a β-sheet and surface loops that together form a concave surface. The new library produced binding proteins (termed "monobodies") to multiple target proteins, generally with similar efficacy as the original, loop-focused library. The crystal structure of a monobody generated from the new library in complex with its target, the Abl SH2 domain, revealed that a concave surface of the monobody, as intended in our design, bound to a convex surface of the target with the interface area being among the largest of published structures of monobody-target complexes. This mode of interaction differs from a common binding mode for single-domain antibodies and antibody mimics in which recognition loops recognize clefts in targets. Together, this work illustrates the utilization of different surfaces of a single immunoglobulin-like scaffold to generate binding proteins with distinct characteristics.     

Cytovillin, a microvillar Mr 75,000 protein. cDNA sequence, prokaryotic expression, and chromosomal localization

Cytovillin is a microvillar cytoplasmic peripheral membrane protein, with prominent expression in vivo in placental syncytiotrophoblasts and certain human tumors. Cytovillin cDNA was cloned from a human placental lambda gt11 library using affinity purified antibodies. The identity of cytovillin cDNA clones was confirmed by expression of cytovillin in Escherichia coli and using antibodies raised against the expressed fusion protein in comparison with antibodies against cytovillin purified from cultured human choriocarcinoma cells. In these cells Northern blotting analysis identified a major 3.5-kilobase cytovillin mRNA. The cDNA encodes a protein of 575 amino acids corresponding to a molecular weight of 68,084. According to secondary structure prediction, cytovillin is a hydrophilic protein with an extensive internal alpha-helical region ending in a sequence of 7 consecutive prolines. The predicted alpha-helical region showed limited homology to alpha-helical regions of cytoskeletal proteins and certain other proteins, but no extensive homologies were found in the cytovillin cDNA or the deduced amino acid sequence to other registered DNA or protein sequences. Southern blot analysis of a DNA panel of human mouse somatic cell hybrids localized the cytovillin gene to the end of the long arm of chromosome 6 (6q22-q27). Our results show that cytovillin is representative of a novel class of microvillar proteins.     

Construction of "small-intelligent" focused mutagenesis libraries using well-designed combinatorial degenerate primers

Site-saturation mutagenesis is a powerful tool for protein optimization due to its efficiency and simplicity. A degenerate codon NNN or NNS (K) is often used to encode the 20 standard amino acids, but this will produce redundant codons and cause uneven distribution of amino acids in the constructed library. Here we present a novel "small-intelligent" strategy to construct mutagenesis libraries that have a minimal gene library size without inherent amino acid biases, stop codons, or rare codons of Escherichia coli by coupling well-designed combinatorial degenerate primers with suitable PCR-based mutagenesis methods. The designed primer mixture contains exactly one codon per amino acid and thus allows the construction of small-intelligent mutagenesis libraries with one gene per protein. In addition, the software tool DC-Analyzer was developed to assist in primer design according to the user-defined randomization scheme for library construction. This small-intelligent strategy was successfully applied to the randomization of halohydrin dehalogenases with one or two randomized sites. With the help of DC-Analyzer, the strategy was proven to be as simple as NNS randomization and could serve as a general tool to efficiently randomize target genes at positions of interest.     

Discovering structural correlations in alpha-helices.

We have developed a new representation for structural and functional motifs in protein sequences based on correlations between pairs of amino acids and applied it to alpha-helical and beta-sheet sequences. Existing probabilistic methods for representing and analyzing protein sequences have traditionally assumed conditional independence of evidence. In other words, amino acids are assumed to have no effect on each other. However, analyses of protein structures have repeatedly demonstrated the importance of interactions between amino acids in conferring both structure and function. Using Bayesian networks, we are able to model the relationships between amino acids at distinct positions in a protein sequence in addition to the amino acid distributions at each position. We have also developed an automated program for discovering sequence correlations using standard statistical tests and validation techniques. In this paper, we test this program on sequences from secondary structure motifs, namely alpha-helices and beta-sheets. In each case, the correlations our program discovers correspond well with known physical and chemical interactions between amino acids in structures. Furthermore, we show that, using different chemical alphabets for the amino acids, we discover structural relationships based on the same chemical principle used in constructing the alphabet. This new representation of 3-dimensional features in protein motifs, such as those arising from structural or functional constraints on the sequence, can be used to improve sequence analysis tools including pattern analysis and database search.     

Extension of biochemical functions by the introduction of nonnatural amino acids and artificial nucleic acid analogs.

Extension of biochemical functions has been attempted by introducing nonatural amino acids and artificial nucleic acid analogs. Nonnatural amino acids have been linked to tRNAs and the amino-acylated tRNAs were added to E. coli in vitro protein synthesizing system to produce nonnatural mutant proteins. The positions of the nonnatural amino acids have been assigned by the 4-base codons, like CGGG and AGGU. The extended codons have been introduced at a specific position or at random positions on a DNA. In the latter case, a DNA library that contains a single 4-base codon at random positions can be obtained. The combination of these new techniques opens a way to the introduction of artificial functions to biochemical systems.     

噬菌体短肽库的构建及其随机短肽的多样性

噬菌体短肽库是将随机合成的寡核苷酸序列通过与单链噬菌体外壳蛋白基因融合,从而将随机短肽表达于噬菌体的表面。将体外随机化学合成的寡聚核苷酸序列重组到单价噬菌体表达载体,构建了噬菌体短肽库,证明其库容为２×１０￣７集落形成单位（ｃｆｕ）,重组率为９３％。同时将１１个随机克隆进行序列测定,证实其寡聚核苷酸序列和氨基酸的分布几乎是完全随机的,其多样性可以满足特异性短肽筛选的要求。     

High-affinity human antibodies from phage-displayed synthetic Fab libraries with a single framework scaffold

Phage-displayed synthetic antibody libraries were built on a single human framework by introducing synthetic diversity at solvent-exposed positions within the heavy chain complementarity-determining regions (CDRs). The design strategy of mimicking natural diversity using tailored codons had been validated previously with scFv libraries, which produced antibodies that bound to antigen, murine vascular endothelial growth factor (mVEGF), with affinities in the 100nM range. To improve library performance, we constructed monovalent and bivalent antigen-binding fragment (Fab) libraries, and explored different CDR-H3 diversities by varying the amino acid composition and CDR length. A Fab with sub-nanomolar affinity for mVEGF was obtained from a library with CDR-H3 diversity designed to contain all 20 naturally occurring amino acids. We then expanded the library by increasing the variability of CDR-H3 length and using tailored codons that mimicked the amino acid composition of natural CDR-H3 sequences. The library was tested against a panel of 13 protein antigens and high-affinity Fabs were obtained for most antigens. Furthermore, the heavy chain of an anti-mVEGF clone was recombined with a library of light chain CDRs, and the affinity was improved from low nanomolar to low picomolar. The results demonstrated that high-affinity human antibodies can be generated from libraries with completely synthetic CDRs displayed on a single scaffold.     

The C-terminal tetrapeptide HWFW of the Chlorella HUP1 hexose/H(+)-symporter is essential for full activity and an alpha-helical structure of the C-terminus

C-terminal tails of plant hexose/H(+)-symporters of the major facilitator superfamily contain a highly conserved motif of four amino acids: HWFW. A deletion of these four amino acids in the Chlorella HUP1 protein leads to a decrease in transport activity by a factor of 3-4. The mutated tail is highly sensitive to trypsin; it does not show alpha-helical conformation in contrast to the wild type C-terminal peptide with an alpha-helical content of at least 15%. The production of monoclonal antibody 416B8 recognizing an epitope within the central loop of HUP1 protein has been a prerequisite for the experiments described.     

Segmented alpha-helical coiled-coil structure of the protein giardin from the Giardia cytoskeleton

The parasitic flagellate Giardia is the source of a filamentous protein, giardin, which binds to microtubules. The primary sequence of one giardin chain has been decoded from the base sequences of cDNAs isolated by antibody screens of a library constructed in the expression vector lambda gt11. The amino acid sequence favours a continuous alpha-helical fold for the protein without any inserts of a non-helical character. Analysis of apolar residue positions revealed 35 repeating heptads consistent with coiled-coil structure. This conformation relates giardin to the alpha-type fibrous proteins (k-m-e-f class) like tropomyosin and myosin (also found in Giardia). The giardin sequence has a regular series of skip residues like those at certain positions in the rod section of nematode myosin where the internal apolar seam of the coiled coil is shifted on the helix surface. The skips divide the giardin coil into quasi-equivalent structural segments about 4 nm in length, which might be domains for combining with tubulin subunits in the microtubule surface lattice.     

Amino acid sequence and gene organization of cytokeratin no. 19, an exceptional tail-less intermediate filament protein.

We have isolated a cDNA clone from a bovine bladder urothelium library which encodes the smallest intermediate filament (IF) protein known, i.e. the simple epithelial cytokeratin (equivalent to human cytokeratin 19) previously thought to have mol. wt 40,000. This clone was then used to isolate the corresponding gene from which we have determined the complete nucleotide sequence and deduced the amino acid sequence of the encoded protein. This cytokeratin of 399 amino acids (mol. wt 43,893) is identified as a typical acidic (type I) cytokeratin but differs from all other IF proteins in that it does not show the carboxyterminal, non-alpha-helical tail domain. Instead it contains a 13 amino acids extension of the alpha-helical rod. The gene encoding cytokeratin 19 is also exceptional. It contains only five introns which occur in positions corresponding to intron positions in other IF protein genes. However, an intron which in all other IF proteins demarcates the region corresponding to the transition from the alpha-helical rod into the non-alpha-helical tail is missing in the cytokeratin 19 gene. Using in vitro reconstitution of purified cytokeratin 19 we show that it reacts like other type I cytokeratins in that it does not form, in the absence of a type II cytokeratin partner, typical IF. Instead it forms 40-90 nm rods of 10-11 nm diameter which appear to represent lateral associations of a number of cytokeratin molecules. Our results demonstrate that the non-alpha-helical tail domain is not an indispensable feature of IF proteins. The gene structure of this protein provides a remarkable case of a correlation of a change in protein conformation with an exon boundary.     

In vitro selection for sense codon suppression

The universal genetic code links the 20 naturally occurring amino acids to the 61 sense codons. Previously, the UAG amber stop codon (a nonsense codon) has been used as a blank in the code to insert natural and unnatural amino acids via nonsense suppression. We have developed a selection methodology to investigate whether the unnatural amino acid biocytin could be incorporated into an mRNA display library at sense codons. In these experiments we probed a single randomized NNN codon with a library of 16 orthogonal, biocytin-acylated tRNAs. In vitro selection for efficient incorporation of the unnatural amino acid resulted in templates containing the GUA codon at the randomized position. This sense suppression occurs via Watson-Crick pairing with similar efficiency to UAG-mediated nonsense suppression. These experiments suggest that sense codon suppression is a viable means to expand the chemical and functional diversity of the genetic code.