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ABSTRACT: We report the in vitro selection of DNA aptamers that bind to histone H4 proteins acetylated at lysine 16. The best aptamer identified in this selection binds to the target protein with a K(d) of 21 nM and discriminates against both the nonacetylated protein and histone H4 proteins acetylated at lysine 8. Comparative binding assays performed with a chip-quality antibody reveal that this aptamer binds to the acetylated histone target with similar affinity to a commercial antibody but shows significantly greater specificity (15-fold versus 2400-fold) for the target molecule. This result demonstrates that aptamers that are both modification and location specific can be generated to bind specific protein post-translational modifications.
Journal of the American Chemical Society 05/2009; 131(18):6330-1. · 9.91 Impact Factor
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ABSTRACT: Recent advances in de novo protein evolution have made it possible to create synthetic proteins from unbiased libraries that fold into stable tertiary structures with predefined functions. However, it is not known whether such proteins will be functional when expressed inside living cells or how a host organism would respond to an encounter with a non-biological protein. Here, we examine the physiology and morphology of Escherichia coli cells engineered to express a synthetic ATP-binding protein evolved entirely from non-biological origins. We show that this man-made protein disrupts the normal energetic balance of the cell by altering the levels of intracellular ATP. This disruption cascades into a series of events that ultimately limit reproductive competency by inhibiting cell division. We now describe a detailed investigation into the synthetic biology of this man-made protein in a living bacterial organism, and the effect that this protein has on normal cell physiology.
PLoS ONE 01/2009; 4(10):e7385. · 4.09 Impact Factor
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ABSTRACT: Biocatalysts provide an economical and energy-efficient alternative to traditional chemical manufacturing processes. For processes where biocatalysts currently do not exist or existing protein catalysts function poorly, there is a tremendous need to discover new protein catalysts that function in industrial settings. The protein engineering community has traditionally relied on cell-based techniques in 96-well format to evolve new catalysts or improve existing enzymes.
This review examines recent progress made in many display technologies, providing powerful alternatives for generating novel enzymes with altered specificity or altogether new types of function.
Library creation methods and display technologies that are commonly used in conjunction with enzyme evolution are discussed.
We conclude with an expert opinion on future trans-disciplinary approaches that combine directed evolution with computational design as novel platforms for rapidly discovering new types of catalytic function.
Expert opinion on biological therapy 09/2008; 8(8):1087-98. · 3.22 Impact Factor
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ChemBioChem 07/2008; 9(9):1361-3. · 3.94 Impact Factor
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ABSTRACT: Structural DNA nanotechnology relies on Watson-Crick base pairing rules to assemble DNA motifs into diverse arrangements of geometric shapes and patterns. While substantial effort has been devoted to expanding the programmability of natural DNA, considerably less attention has been given to the development of nucleic acid structures based on non-natural DNA polymers. Here we describe the use of glycerol nucleic acid (GNA), a simple polymer based on an acyclic repeating unit, as an alternative genetic material for assembling nucleic acid nanostructures independent of RNA or DNA recognition. We synthesized two 4-helix junctions based entirely on GNA self-pairing and showed that GNA provides easy access to highly stable nanostructures with left- and right-handed helical configurations.
Journal of the American Chemical Society 06/2008; 130(18):5846-7. · 9.91 Impact Factor
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ABSTRACT: Recognition imaging microscopy is an analytical technique used to map the topography and chemical identity of specific protein molecules present in complex biological samples. The technique relies on the use of antibodies tethered to the cantilever tip of an AFM probe to detect cognate antigens deposited onto a mica surface. Despite the power of this technique to resolve single molecules with nanometer-scale spacing, the recognition step remains limited by the availability of suitable quality antibodies. Here we report the in vitro selection and recognition imaging of anti-histone H4 aptamers. In addition to identifying aptamers to highly basic proteins, these results suggest that aptamers provide an efficient, cost-effective route to highly selective affinity reagents for recognition imaging microscopy.
Journal of the American Chemical Society 12/2007; 129(47):14568-9. · 9.91 Impact Factor
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ABSTRACT: Systematic investigation into the chemical etiology of ribose has led to the discovery of glycerol nucleic acid (GNA) and threose nucleic acid (TNA) as possible progenitor candidates of RNA in the origins of life. Coupled with their chemical simplicity, polymers for both systems are capable of forming stable Watson-Crick antiparallel duplex structures with themselves and RNA, thereby providing a mechanism for the transfer of genetic information between successive genetic systems. Investigation into whether both polymers arose independently or descended from a common evolutionary pathway would provide additional constraints on models that describe the emergence of a hypothetical RNA world. Here we show by thermal denaturation that complementary GNA and TNA mixed sequence polymers are unable, even after prolonged incubation times, to adopt stable helical structures by intersystem cross-pairing. This experimental observation suggests that GNA and TNA, whose structures derive from one another, were not consecutive polymers in the same evolutionary pathway to RNA.
Journal of Molecular Evolution 10/2007; 65(3):289-95. · 2.27 Impact Factor
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ABSTRACT: We present a structural and functional analysis of the evolutionary optimization of a non-biological protein derived from a library of random amino acid sequences. A series of previously described in vitro selection experiments transformed a low-affinity ancestral sequence into a stably folded, high affinity ATP binding protein structure. While the evolutionarily optimized protein differs from its ancestral sequence through the accumulation of 12 amino acid mutations, the means by which those mutations enhance the stability and functionality of the protein were not well understood. We used a combination of mutagenesis, biochemistry, and NMR spectroscopy to investigate the structural and functional significance of each mutation. We solved the three-dimensional structure of the folding optimized protein by solution NMR, which revealed a fourth strand of the beta-sheet of the alpha/beta-fold that was not observed in an earlier crystallographic analysis of a less stable version of the protein. The structural rigidity of the newly identified beta-strand was confirmed by T1, T2, and heteronuclear nuclear Overhauser enhancement (NOE) measurements. Biochemical experiments were used to examine point mutations that revert the optimized protein back to the ancestral residue at each of the 12 sites. A combination of structural and functional data was then used to interpret the significance of each amino acid mutation. The enhanced ATP affinity was largely due to the emergence of a patch of positive charge density on the protein surface, while the increased solubility resulted from several mutations that increased the hydrophilicity of the protein surface, thereby decreasing protein aggregation. One mutation may stabilize the hydrophobic face of the beta-sheet.
Journal of Molecular Biology 09/2007; 371(2):501-13. · 4.00 Impact Factor
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ABSTRACT: Phylogenetic profiling of amino acid substitution patterns in proteins has led many to conclude that most structural information is carried by interior core residues that are solvent inaccessible. This conclusion is based on the observation that buried residues generally tolerate only conserved sequence changes, while surface residues allow more diverse chemical substitutions. This notion is now changing as it has become apparent that both core and surface residues play important roles in protein folding and stability. Unfortunately, the ability to identify specific mutations that will lead to enhanced stability remains a challenging problem. Here we discuss two mutations that emerged from an in vitro selection experiment designed to improve the folding stability of a non-biological ATP binding protein. These mutations alter two solvent accessible residues, and dramatically enhance the expression, solubility, thermal stability, and ligand binding affinity of the protein. The significance of both mutations was investigated individually and together, and the X-ray crystal structures of the parent sequence and double mutant protein were solved to a resolution limit of 2.8 and 1.65 A, respectively. Comparative structural analysis of the evolved protein to proteins found in nature reveals that our non-biological protein evolved certain structural features shared by many thermophilic proteins. This experimental result suggests that protein fold optimization by in vitro selection offers a viable approach to generating stable variants of many naturally occurring proteins whose structures and functions are otherwise difficult to study.
PLoS ONE 02/2007; 2(5):e467. · 4.09 Impact Factor
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Angewandte Chemie International Edition 02/2007; 46(17):3051-4. · 13.45 Impact Factor
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ABSTRACT: alpha-l-Threofuranosyl nucleoside triphosphates (tNTPs) are tetrafuranose nucleoside derivatives and potential progenitors of present-day beta-d-2'-deoxyribofuranosyl nucleoside triphosphates (dNTPs). Therminator DNA polymerase, a variant of the 9 degrees N DNA polymerase, is an efficient DNA-directed threosyl nucleic acid (TNA) polymerase. Here we report a detailed kinetic comparison of Therminator-catalyzed TNA and DNA syntheses. We examined the rate of single-nucleotide incorporation for all four tNTPs and dNTPs from a DNA primer-template complex and carried out parallel experiments with a chimeric DNA-TNA primer-DNA template containing five TNA residues at the primer 3'-terminus. Remarkably, no drop in the rate of TNA incorporation was observed in comparing the DNA-TNA primer to the all-DNA primer, suggesting that few primer-enzyme contacts are lost with a TNA primer. Moreover, comparison of the catalytic efficiency of TNA synthesis relative to DNA synthesis at the downstream positions reveals a difference of no greater than 5-fold in favor of the natural DNA substrate. This disparity becomes negligible when the TNA synthesis reaction mixture is supplemented with 1.25 mM MnCl(2). These results indicate that Therminator DNA polymerase can recognize both a TNA primer and tNTP substrates and is an effective catalyst of TNA polymerization despite changes in the geometry of the reactants.
Journal of the American Chemical Society 06/2005; 127(20):7427-34. · 9.91 Impact Factor
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ABSTRACT: Structural comparison of in vitro evolved proteins with biological proteins will help determine the extent to which biological proteins sample the structural diversity available in protein sequence space. We have previously isolated a family of nonbiological ATP binding proteins from an unconstrained random sequence library. One of these proteins was further optimized for high-affinity binding to ATP, but biophysical characterization proved impossible due to poor solubility. To determine if such nonbiological proteins can be optimized for improved folding stability, we performed multiple rounds of mRNA-display selection under increasingly denaturing conditions. Starting from a pool of protein variants, we evolved a population of proteins capable of binding ATP in 3 M guanidine hydrochloride. One protein was chosen for further characterization. Circular dichroism, tryptophan fluorescence, and (1)H-(15)N correlation NMR studies show that this protein has a unique folded structure.
Chemistry & Biology 07/2004; 11(6):865-74. · 5.83 Impact Factor
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ABSTRACT: Threose nucleic acid (TNA), which has a repeat unit one atom shorter than that of DNA, is capable of Watson-Crick base pairing with DNA, RNA, and TNA. Because of its chemical simplicity, TNA is considered to be a possible progenitor of RNA. As an initial step toward developing the molecular tools necessary to investigate the functional capabilities of TNA by in vitro selection, we have screened a variety of DNA polymerases for TNA synthesis activity on a DNA template. We wish to report that several polymerases show surprisingly good ability to synthesize TNA using alpha-l-threofuranosyl thymidine-3'-triphosphate as a substrate.
Journal of the American Chemical Society 09/2003; 125(31):9274-5. · 9.91 Impact Factor
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ABSTRACT: TNA, or threose nucleic acid, is capable of Watson-Crick base pairing with DNA, RNA, and TNA; coupled with its chemical simplicity, this suggests that TNA is a possible progenitor of RNA. As an initial step toward developing the molecular tools necessary to investigate the functional capabilities of TNA by in vitro selection, we have screened a variety of DNA polymerases for activity on a TNA template. We report that despite having a repeating unit that is one atom shorter than that of DNA, several polymerases showed surprisingly good ability to copy limited stretches of TNA.
Journal of the American Chemical Society 02/2003; 125(4):856-7. · 9.91 Impact Factor
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ABSTRACT: The Up.D base-pair (5-propynyl uracil.diaminopurine) is found to be more effective at non-enzymatic transcription than the corresponding natural T.A pair; under non-enzymatic reaction conditions where the natural T.A base-pair fails, a DNA template bearing Up efficiently directs the incorporation of D into a product RNA strand.
Chemical Communications 09/2002; · 6.17 Impact Factor
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