SELEX with modified nucleotides.

Aptamers, a promising new class of therapeutics, are single-stranded oligonucleotides generated via an in vitro selection process that bind to and inhibit the activity of target proteins in a manner similar to therapeutic antibodies. In order to enhance the drug-like character of aptamers, oligonucleotide libraries containing modified nucleotides are increasingly being used for selection. Principally, the choice of modifications aims to increase aptamer potency by enhancing nuclease-resistance, or increasing target affinity by providing more target recognition functionality or generating more stable aptamer structures.

Complex target SELEX.

Aptamers are non-naturally occurring structured oligonucleotides that may bind to small molecules, peptides, and proteins. Typically, aptamers are generated by an in vitro selection process referred to as SELEX (systematic evolution of ligands by exponential enrichment). Aptamers that bind with high affinity and specificity to proteins that reside on the cell surface have potential utility as therapeutic antagonists, agonists, and diagnostic agents. When the target protein requires the presence of the cell membrane (e.g., G-protein-coupled receptors, ion channels) or a co-receptor to fold properly, it is difficult or impossible to program the SELEX experiment with purified, soluble protein target. Recent advances in which the useful range of SELEX has been extended from comparatively simple purified forms of soluble proteins to complex mixtures of proteins in membrane preparations or in situ on the surfaces of living cells offer the potential to discover aptamers against previously intractable targets. Additionally, in cases in which a cell-type specific diagnostic is sought, the most desirable target on the cell surface may not be known. Successful application of aptamer selection techniques to complex protein mixtures can be performed even in the absence of detailed target knowledge and characterization. This Account presents a review of recent work in which membrane preparations or whole cells have been utilized to generate aptamers to cell surface targets. SELEX experiments utilizing a range of target "scaffolds" are described, including cell fragments, parasites and bacteria, viruses, and a variety of human cell types including adult mesenchymal stem cells and tumor lines. Complex target SELEX can enable isolation of potent and selective aptamers directed against a variety of cell-surface proteins, including receptors and markers of cellular differentiation, as well as determinants of disease in pathogenic organisms, and as such should have wide therapeutic and diagnostic utility.

2'-Deoxy purine, 2'-O-methyl pyrimidine (dRmY) aptamers as candidate therapeutics.

Aptamers are short oligonucleotides that fold into well-defined three-dimensional architectures thereby enabling specific binding to molecular targets such as proteins. To be successful as a novel therapeutic modality, it is important for aptamers to not only bind their targets with high specificity and affinity, but also to exhibit favorable properties with respect to in vivo stability, cost-effective synthesis, and tolerability (i.e., safety). We describe methods for generating aptamers comprising 2 - deoxy purines and 2 -O-methyl pyrimidines (dRmY) that broadly satisfy many of these additional constraints. Conditions under which dRmY transcripts can be efficiently synthesized using mutant T7 RNA polymerases have been identified and used to generate large libraries from which dRmY aptamers to multiple target proteins, including interleukin (IL)-23 and thrombin, have been successfully discovered using the SELEX process. dRmY aptamers are shown to be highly nuclease-resistant, long-lived in vivo, efficiently synthesized, and capable of binding protein targets in a manner that inhibits their biologic activity with K(D) values in the low nM range. We believe that dRmY aptamers have considerable potential as a new class of therapeutic aptamers.

A novel strategy for selection of allosteric ribozymes yields RiboReporter sensors for caffeine and aspartame.

We have utilized in vitro selection technology to develop allosteric ribozyme sensors that are specific for the small molecule analytes caffeine or aspartame. Caffeine- or aspartame-responsive ribozymes were converted into fluorescence-based RiboReporter trade mark sensor systems that were able to detect caffeine or aspartame in solution over a concentration range from 0.5 to 5 mM. With read-times as short as 5 min, these caffeine- or aspartame-dependent ribozymes function as highly specific and facile molecular sensors. Interestingly, successful isolation of allosteric ribozymes for the analytes described here was enabled by a novel selection strategy that incorporated elements of both modular design and activity-based selection methods typically used for generation of catalytic nucleic acids.

ADP-specific sensors enable universal assay of protein kinase activity.

Two molecular sensors that specifically recognize ADP in a background of over 100-fold molar excess of ATP are described. These sensors are nucleic-acid based and comprise a general method for monitoring protein kinase activity. The ADP-aptamer scintillation proximity assay is configured in a single-step, homogeneous format while the allosteric ribozyme (RiboReporter) sensor generates a fluorescent signal upon ADP-dependent ribozyme self-cleavage. Both systems perform well when configured for high-throughput screening and have been used to rediscover a known protein kinase inhibitor in a high-throughput screening format.

A fibronectin scaffold approach to bispecific inhibitors of epidermal growth factor receptor and insulin-like growth factor-I receptor.

Engineered domains of human fibronectin (Adnectins™) were used to generate a bispecific Adnectin targeting epidermal growth factor receptor (EGFR) and insulin-like growth factor-I receptor (IGF-IR), two transmembrane receptors that mediate proliferative and survival cell signaling in cancer. Single-domain Adnectins that specifically bind EGFR or IGF-IR were generated using mRNA display with a library containing as many as 10 ( 13) Adnectin variants. mRNA display was also used to optimize lead Adnectin affinities, resulting in clones that inhibited EGFR phosphorylation at 7 to 38 nM compared to 2.6 µM for the parental clone. Individual, optimized, Adnectins specific for blocking either EGFR or IGF-IR signaling were engineered into a single protein (EI-Tandem Adnectin). The EI-Tandems inhibited phosphorylation of EGFR and IGF-IR, induced receptor degradation, and inhibited down-stream cell signaling and proliferation of human cancer cell lines (A431, H292, BxPC3 and RH41) with IC 50 values ranging from 0.1 to 113 nM. Although Adnectins bound to EGFR at a site distinct from those of anti-EGFR antibodies cetuximab, panitumumab and nimotuzumab, like the antibodies, the anti-EGFR Adnectins blocked the binding of EGF to EGFR. PEGylated EI-Tandem inhibited the growth of both EGFR and IGF-IR driven human tumor xenografts, induced degradation of EGFR, and reduced EGFR phosphorylation in tumors. These results demonstrate efficient engineering of bispecific Adnectins with high potency and desired specificity. The bispecificity may improve biological activity compared to monospecific biologics as tumor growth is driven by multiple growth factors. Our results illustrate a technological advancement for constructing multi-specific biologics in cancer therapy.

Novel therapeutic modalities to address nondrugable protein interaction targets.

Small molecule drugs are relatively effective in working on 'drugable' targets such as GPCRs, ion channels, kinases, proteases, etc but ineffective at blocking protein-protein interactions that represent an emerging class of 'nondrugable' central nervous system (CNS) targets. This article provides an overview of novel therapeutic modalities such as biologics (in particular antibodies) and emerging oligonucleotide therapeutics such as antisense, small-interfering RNA, and aptamers. Their key properties, overall strengths and limitations, and their utility as tools for target validation are presented. In addition, issues with regard to CNS targets as it relates to the blood-brain barrier penetration are discussed. Finally, examples of their application as therapeutics for the treatment of pain and some neurological disorders such as Alzheimer's disease, multiple sclerosis, Huntington's disease, and Parkinson's disease are provided.