Peptoid origins

Peptoid oligomers were initially developed as part of a larger basic research effort to accelerate the drug-discovery process in the biotech/biopharma industry. Their ease of synthesis, stability, and structural similarity to polypeptides made them ideal candidates for the combinatorial discovery of novel peptidomimetic drug candidates. Diverse libraries of short peptoid oligomers provided one of the first demonstrations in the mid-1990s that high-affinity ligands to pharmaceutically relevant receptors could be discovered from combinatorial libraries of synthetic compounds. The solid-phase submonomer method of peptoid synthesis was so efficient and general that it soon became possible to explore the properties of longer polypeptoid chains in a variety of areas beyond drug discovery (e.g., diagnostics, drug delivery, and materials science). Exploration into protein-mimetic materials soon followed, with the fundamental goal of folding a non-natural sequence-specific heteropolymer into defined secondary or tertiary structures. This effort first yielded the peptoid helix and much later the peptoid sheet, both of which are secondary-structure mimetics that are close relatives to their natural counterparts. These crucial discoveries have brought us closer to building proteinlike structure and function from a non-natural polymer and have provided great insight into the rules governing polymer and protein folding. The accessibility of peptoid synthesis to chemists and nonchemists alike, along with a lack of information-rich non-natural polymers available to study, has led to a rapid growth in the field of peptoid science by many new investigators. This work provides an overview of the initial discovery and early developments in the peptoid field.     

From peptide-based material science to protein fibrils: discipline convergence in nanobiology

This paper illustrates the merits of convergence in nanobiology of two seemingly disparate fields, material science and computational biology. Traditionally, material science has been a discipline involving design and fabrication of synthetic polymers consisting of repeating units. Collaboration with synthetic organic chemists allowed design of new polymers, with a range of altered conformations. Yet, naturally occurring proteins are also materials. Their varied sequences and structures should enrich material science providing more complex shapes, scaffolds and chemical properties. For material scientists, the enhanced coverage of chemical space obtained by integrating proteins and synthetic organic chemistry through the introduction of non-natural residues allows a range of new useful potential applications.     

Beyond de novo protein design--de novo design of non-natural folded oligomers

The mystery of how a protein sequence specifies a unique structure has intrigued chemists, leading to the design and study of foldamers, non-natural oligomeric molecules that adopt well-defined structures. Recently, the sequence specificity of the various regular repeating structures has been revealed for bioinspired foldamers and such foldamers have been created to adopt helical bundle tertiary structures. One major strategy for the generation of abiotic foldamers has involved molecular design of the monomer geometry. These advances in foldamer research may lead to future applications in biomedical and materials science.     

Genetic engineering of structural protein polymers.

Genetic and protein engineering are components of a new polymer chemistry that provide the tools for producing macromolecular polyamide copolymers of diversity and precision far beyond the current capabilities of synthetic polymer chemistry. The genetic machinery allows molecular control of chemical and physical chain properties. Nature utilizes this control to formulate protein polymers into materials with extraordinary mechanical properties, such as the strength and toughness of silk and the elasticity and resilience of mammalian elastin. The properties of these materials have been attributed to the presence of short repeating oligopeptide sequences contained in the proteins, fibroin, and elastin. We have produced homoblock protein polymers consisting exclusively of silk-like crystalline blocks and elastin-like flexible blocks. We have demonstrated that each homoblock polymer as produced by microbial fermentation exhibits measurable properties of crystallinity and elasticity. Additionally, we have produced alternating block copolymers of various amounts of silk-like and elastin-like blocks, ranging from a ratio of 1:4 to 2:1, respectively. The crystallinity of each copolymer varies with the amount of crystalline block interruptions. The production of fiber materials with custom-engineered mechanical properties is a potential outcome of this technology.     

De novo designed protein transduction domain mimics from simple synthetic polymers

Protein transduction domains (PTDs) that readily transverse cellular membranes are of great interest and are attractive tools for the intracellular delivery of bioactive molecules. Learning to program synthetic polymers and oligomers with the appropriate chemical information to capture adequately the biological activity of proteins is critical to our improved understanding of how these natural molecules work. In addition, the versatility of these synthetic mimics provides the opportunity to discover analogs with superior properties compared with their native sequences. Here we report the first detailed structure-activity relationship of a new PTD family of polymers based on a completely abiotic backbone. The synthetic approach easily allows doubling the density of guanidine functional groups, which increases the transduction efficiency of the sequences. Cellular uptake studies on three different cell lines (HEK 293T, CHO, and Jurkat T cells) confirm that these synthetic analogs are highly efficient novel protein transduction domain mimics (PTDMs), which are more effective than TAT(49-57) and nonaarginine (R9) and also highlight the usefulness of polymer chemistry at the chemistry-biology interface.     

Incorporation of artificial receptors into a protein/peptide surface: a strategy for on/off type of switching of semisynthetic enzymes

Recent developments in new bioorganic methodologies have greatly facilitated the site-specific incorporation of non-natural amino acids into the protein framework. It is now desirable for chemists to explore promising concepts based on chemistry for regulation and extension of functions of naturally occurring enzymes using non-natural molecules, in order to promote the new trends in protein/enzyme engineering. This article demonstrates that the concepts of host-guest (or supramolecular) chemistry, which have been developed over the last few decades, provide powerful tools for the artificial control of the functions of native proteins and enzymes.     

Engineering supramolecular artificial edifices designed for a specific function

The Langmuir-Blodgett technique and its variants (alternate layers, self-organising mixtures, the semi-amphiphilic technique, the peculiar solid state chemistry in L.B. films) are collective methods which allow physical chemists, with a very small amount of synthetic chemistry, to build up molecular assemblies exhibiting not only the properties of each of their components, but also extra properties which arise from the architecture: cooperativity, anomalous chemical properties, molecular recognition, etc. These new tailored molecular edifices are the basic “brick” of tomorrow's molecular electronics and fine chemistry. These strategies are exemplified here by two active supramolecular edifices which have been successfully designed and built up: an artificial dioxygen trap based on the same principle as hemoglobin, and one molecule thick conductors. Promising applied results have already been obtained in the field of gas sensing with these new conductors, owing to molecular architectural amplification.     

Biological synthesis of circular polypeptides

Here, we review the use of different biochemical approaches for biological synthesis of circular or backbone-cyclized proteins and peptides. These methods allow the production of circular polypeptides either in vitro or in vivo using standard recombinant DNA expression techniques. Protein circularization can significantly impact protein engineering and research in protein folding. Basic polymer theory predicts that circularization should lead to a net thermodynamic stabilization of a folded protein by reducing the entropy associated with the unfolded state. Protein cyclization also provides a valuable tool for exploring the effects of topology on protein folding kinetics. Furthermore, the biological production of cyclic polypeptides makes possible the production of cyclic polypeptide libraries. The generation of such libraries, which was previously restricted to the domain of synthetic chemists, now offers biologists access to highly diverse and stable molecular libraries for probing protein structure and function.     

Ice shaping properties, similar to that of antifreeze proteins, of a zirconium acetate complex

The control of the growth morphologies of ice crystals is a critical issue in fields as diverse as biomineralization, medicine, biology, civil or food engineering. Such control can be achieved through the ice-shaping properties of specific compounds. The development of synthetic ice-shaping compounds is inspired by the natural occurrence of such properties exhibited by antifreeze proteins. We reveal how a particular zirconium acetate complex is exhibiting ice-shaping properties very similar to that of antifreeze proteins, albeit being a radically different compound. We use these properties as a bioinspired approach to template unique faceted pores in cellular materials. These results suggest that ice-structuring properties are not exclusive to long organic molecules and should broaden the field of investigations and applications of such substances.     

Cell-free biology: exploiting the interface between synthetic biology and synthetic chemistry

Just as synthetic organic chemistry once revolutionized the ability of chemists to build molecules (including those that did not exist in nature) following a basic set of design rules, cell-free synthetic biology is beginning to provide an improved toolbox and faster process for not only harnessing but also expanding the chemistry of life. At the interface between chemistry and biology, research in cell-free synthetic systems is proceeding in two different directions: using synthetic biology for synthetic chemistry and using synthetic chemistry to reprogram or mimic biology. In the coming years, the impact of advances inspired by these approaches will make possible the synthesis of nonbiological polymers having new backbone compositions, new chemical properties, new structures, and new functions.     

The selectivity of protein‐imprinted gels and its relation to protein properties: A computer simulation study

Polymer‐based protein recognition systems have enormous potential within clinical and diagnostic fields due to their reusability, biocompatibility, ease of manufacturing, and potential specificity. Imprinted polymer matrices have been extensively studied and applied as a simple technique for creating artificial polymer‐based recognition gels for a target molecule. Although this technique has been proven effective when targeting small molecules (such as drugs), imprinting of proteins have so far resulted in materials with limited selectivity due to the large molecular size of the protein and aqueous environment. Using coarse‐grained molecular simulation, we investigate the relation between protein makeup, polymer properties, and the selectivity of imprinted gels. Nonspecific binding that results in poor selectivity is shown to be strongly dependent on surface chemistry of the template and competitor proteins as well as on polymer chemistry. Residence time distributions of proteins diffusing within the gels provide a transparent picture of the relation between polymer constitution, protein properties, and the nonspecific interactions with the imprinted gel. The pronounced effect of protein surface chemistry on imprinted gel specificity is demonstrated.     

The role played by modified bioinspired surfaces in interfacial properties of biomaterials

The success of a biomaterial relies on an appropriate interaction between the surface of that biomaterial and the surrounding environment; more specifically, the success of a biomaterial depends on how fluids, proteins, and cells interact with the foreign material. For this reason, the surface properties of biomaterial, such as composition, charge, wettability, and roughness, must be optimized for a desired application to be achieved. In this review we highlight different bioinspired approaches that are used to manipulate and fine-tune the interfacial properties of biomaterials. Inspired by noteworthy natural processes, researchers have developed materials with a functional anatomy that range from hierarchical hybrid structures to self-cleaning interfaces. In this review we focus on (1) the creation of particles and modified surfaces inspired by the structure and composition of biogenic mineralized tissues, (2) the development of biofunctional coatings, (3) materials inspired by biomembranes and proteins, and (4) the design of superwettable materials. Our intention is to point out different bioinspired methodologies that have been used to design materials for biomedical applications and to discuss how interfacial properties modified by manipulation of these materials determine their final biological response. Our objective is to present future research directions and to highlight the potential of bioinspired materials. We hope this review will provide an understanding of the interplay between interfacial properties and biological response so that successful biomaterials can be achieved.     

Recent advances in the in vitro evolution of nucleic acids

Molecular evolution allows chemists and biologists to generate nucleic acids with tailor-made binding or catalytic activities. Recent examples of nucleic acid evolution in vitro provide insights into natural ribozyme evolution and also demonstrate potential applications of evolved DNA and RNA molecules. Efforts to expand the scope of nucleic acid evolution are also underway, including the development of novel methods for exploring nucleic acid sequence-space and the incorporation of non-natural chemical functionality into nucleic acid libraries.     

Opportunities at the interface of chemistry and biology

The combination of the tools and principles of chemistry, together with the tools of modern molecular biology, allow us to create complex synthetic and natural molecules, and processes with novel biological, chemical and physical properties. This article illustrates the tremendous opportunity that lies at this interface of chemistry and biology by describing a number of examples, ranging from efforts to expand the genetic code of living organisms to the use of combinatorial methods to generate biologically active synthetic molecules.     

Opportunities at the interface of chemistry and biology

The combination of the tools and principles of chemistry, together with the tools of modern molecular biology, allow us to create complex synthetic and natural molecules, and processes with novel biological, chemical and physical properties. This article illustrates the tremendous opportunity that lies at this interface of chemistry and biology by describing a number of examples, ranging from efforts to expand the genetic code of living organisms to the use of combinatorial methods to generate biologically active synthetic molecules.     

Opportunities at the interface of chemistry and biology

The combination of the tools and principles of chemistry, together with the tools of modern molecular biology, allow us to create complex synthetic and natural molecules, and processes with novel biological, chemical and physical properties. This article illustrates the tremendous opportunity that lies at this interface of chemistry and biology by describing a number of examples, ranging from efforts to expand the genetic code of living organisms to the use of combinatorial methods to generate biologically active synthetic molecules.     

Synthetic biology: lessons from the history of synthetic organic chemistry

The mid-nineteenth century saw the development of a radical new direction in chemistry: instead of simply analyzing existing molecules, chemists began to synthesize them--including molecules that did not exist in nature. The combination of this new synthetic approach with more traditional analytical approaches revolutionized chemistry, leading to a deep understanding of the fundamental principles of chemical structure and reactivity and to the emergence of the modern pharmaceutical and chemical industries. The history of synthetic chemistry offers a possible roadmap for the development and impact of synthetic biology, a nascent field in which the goal is to build novel biological systems.     

Elucidating the molecular mechanisms underlying cellular response to biophysical cues using synthetic biology approaches

ABSTRACT

The use of synthetic surfaces and materials to influence and study cell behavior has vastly progressed our understanding of the underlying molecular mechanisms involved in cellular response to physicochemical and biophysical cues. Reconstituting cytoskeletal proteins and interfacing them with a defined microenvironment has also garnered deep insight into the engineering mechanisms existing within the cell. This review presents recent experimental findings on the influence of several parameters of the extracellular environment on cell behavior and fate, such as substrate topography, stiffness, chemistry and charge. In addition, the use of synthetic environments to measure physical properties of the reconstituted cytoskeleton and their interaction with intracellular proteins such as molecular motors is discussed, which is relevant for understanding cell migration, division and structural integrity, as well as intracellular transport. Insight is provided regarding the next steps to be taken in this interdisciplinary field, in order to achieve the global aim of artificially directing cellular response.     

Biocatalysis in natural products chemistry

The properties of enzymes and microbial cells as biocatalysts useful in natural products chemistry are discussed from the perspective of the chemical transformations they catalyse. Attention is focused on numerous reactions of value to natural products chemists, including the acyloin condensation, Baeyer-Villiger oxidation, regio- and enantioselective ester hydrolyses, oxidations of aromatic and non-aromatic substrates, oxidoreduction and O- and N-dealkylations. Compounds considered in this review include amino acids, alkaloids, antibiotics, coumarins, naphthoquinones, quassinoids, rotenoids and mono-, sesqui-, di- and triterpenoid substrates. The value of biocatalysis compared with traditional chemical catalysis is considered within the broad framework of natural products chemistry, and the potential for using immobilized enzyme and cell technology is presented.     

Synthesis and characterization of multiblock copolymers based on spider dragline silk proteins

Spider dragline silk with its superlative tensile properties provides an ideal system to study the relationship between morphology and mechanical properties of a structural protein. Accordingly, we synthesized two hybrid multiblock copolymers by condensing poly(alanine) [(Ala)(5)] blocks of the structural proteins (spidroin MaSp1 and MaSp2) of spider dragline silk with different oligomers of isoprene (2200 and 5000 Da) having reactive end groups. The synthetic multiblock polymer displayed similar secondary structure to that of natural spidroin, the peptide segment forming a beta-sheet structure. These multiblock polymers showed a significant solubility in the component solvents. Moreover, the copolymer which contains the short polyisoprene segment would aggregate into a micellar-like structure, as observed by TEM.