With 18 monoclonal antibody (mAb) products currently on the market and more than 100 in clinical trials, it is clear that engineered antibodies have come of age as biopharmaceuticals. In fact, by 2008, engineered antibodies are predicted to account for >30% of all revenues in the biotechnology market. Smaller recombinant antibody fragments (for example, classic monovalent antibody fragments (Fab, scFv)) and engineered variants (diabodies, triabodies, minibodies and single-domain antibodies) are now emerging as credible alternatives. These fragments retain the targeting specificity of whole mAbs but can be produced more economically and possess other unique and superior properties for a range of diagnostic and therapeutic applications. Antibody fragments have been forged into multivalent and multi-specific reagents, linked to therapeutic payloads (such as radionuclides, toxins, enzymes, liposomes and viruses) and engineered for enhanced therapeutic efficacy. Recently, single antibody domains have been engineered and selected as targeting reagents against hitherto immunosilent cavities in enzymes, receptors and infectious agents. Single-domain antibodies are anticipated to significantly expand the repertoire of antibody-based reagents against the vast range of novel biomarkers being discovered through proteomics. As this review aims to show, there is tremendous potential for all antibody fragments either as robust diagnostic reagents (for example in biosensors), or as nonimmunogenic in vivo biopharmaceuticals with superior biodistribution and blood clearance properties.
Genetic information storage and processing rely on just two polymers, DNA and RNA. Whether their role reflects evolutionary history or fundamental functional constraints is unknown. Using polymerase evolution and design, we show that genetic information can be stored in and recovered from six alternative genetic polymers (XNAs) based on simple nucleic acid architectures not found in nature. We also select XNA aptamers, which bind their targets with high affinity and specificity, demonstrating that beyond heredity, specific XNAs have the capacity for Darwinian evolution and for folding into defined structures. Thus, heredity and evolution, two hallmarks of life, are not limited to DNA and RNA but are likely to be emergent properties of polymers capable of information storage.The nucleic acids DNA and RNA provide the molecular basis for all life through their unique ability to store and propagate information. To better understand these singular properties and discover relevant parameters for the chemical basis of molecular information encoding, nucleic acid structure has been dissected by systematic variation of nucleobase, sugar and backbone moieties (1-7).These studies have revealed the profound influence of backbone, sugar and base chemistry on nucleic acid properties and function. Crucially, only a small subset of chemistries allows information transfer through base pairing with DNA or RNA, a prerequisite for crosstalk with extant biology. However, base pairing alone cannot conclusively determine the capacity of a given chemistry to serve as a genetic system, as hybridization need not preserve information content (8). A more thorough examination of candidate genetic polymers' potential for information storage, propagation and evolution requires a system for replication which would allow a systematic exploration of the informational, evolutionary and functional potential of synthetic genetic polymers and open up applications ranging from biotechnology to material science.In principle, informational polymers can be synthesized and replicated chemically (9) with advances in the non-enzymatic polymerization of mononucleotides (10) (11, 12) enabling model selection experiments (13). Nevertheless, chemical polymerization remains relatively inefficient. On the other hand, enzymatic polymerization has been hindered by the stringent substrate selectivity of polymerases. Despite progress in understanding the determinants of polymerase substrate specificity and in engineering polymerases with expanded substrate spectra (7), most unnatural nucleotide analogues are poor polymerase substrates at full substitution, both as nucleotides for polymer synthesis and as templates for reverse transcription. Notable exceptions are 2′OMe-DNA and TNA. 2′OMe-DNA is present in eukaryotic rRNAs, is well-tolerated by natural reverse transcriptases (RTs) and has been shown to support heredity and evolution at near full substitution (14). TNA allowed polymer synthesis and evolution in a three letter system (15) but only limited re...
Bivalent and bispecific antibodies and their fragments have immense potential for practical application.
A critical event in the origin of life is thought to have been the emergence of an RNA molecule capable of replicating a primordial RNA "genome." Here we describe the evolution and engineering of an RNA polymerase ribozyme capable of synthesizing RNAs of up to 95 nucleotides in length. To overcome its sequence dependence, we recombined traits evolved separately in different ribozyme lineages. This yielded a more general polymerase ribozyme that was able to synthesize a wider spectrum of RNA sequences, as we demonstrate by the accurate synthesis of an enzymatically active RNA, a hammerhead endonuclease ribozyme. This recapitulates a central aspect of an RNA-based genetic system: the RNA-catalyzed synthesis of an active ribozyme from an RNA template.
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