Conditional Activation of Protein Therapeutics by Templated Removal of Peptide Nucleic Acid Masking Groups

Interleukin-2 (IL-2)-based therapeutics are emerging as treatments for immunotherapy; however, systemic activation of immune cells hampers their success. Chemically controlling the activity of potent cytokines could mitigate unwanted T cell stimulation and widen their therapeutic window. In this study, we developed a strategy for the conditional activation of proteins utilizing removable peptide nucleic acid (PNA) masking groups. Site-specific installation of "Lock"-PNAs containing a cleavage thioester linkage enabled steric blockage of receptor binding sites. Rapid unmasking and activation were performed by the addition of a complementary "Key"-PNA containing a cysteine (Cys) residue, which forms a PNA-PNA duplex leading to a proximity-accelerated cleavage step and release of the active protein. We exemplified the versatility of this methodology on de novo cytokine neoleukin-2/15 (Neo-2/15) through the preparation of PNA conjugates including homodimers, PNA-stapled conjugates, and dual PNA-bridged dimers. All constructs were effectively unmasked at low micromolar concentrations. Further, we demonstrated the conditional activation of a masked conjugate of Neo-2/15 in binding studies to the IL-2 receptors and in an ex vivo T cell signaling assay displaying a 480-fold potency increase upon activation. Finally, we extended the strategy to a designed ankyrin repeat protein (DARPin) activating the human CD40 receptor demonstrating successful masking and unmasking.

Supramolecular multiplexes from collagen mimetic peptide-PNA(GGG)3 conjugates and C-rich DNA: pH-induced reversible switching from triplex-duplex to triplex-i-motif

Peptides are well known for forming nanoparticles, while DNA duplexes, triplexes and tetraplexes create rigid nanostructures. Accordingly, the covalent conjugation of peptides to DNA/RNA produces hybrid self-assembling features and may lead to interesting nano-assemblies distinct from those of their individual components. Herein, we report the preparation of a collagen mimetic peptide incorporating lysine in its backbone, with alkylamino side chains radially conjugated with G-rich PNA [collagen-(PNA-GGG)3]. In the presence of complementary C-rich DNA (dCCCTTTCCC) at neutral pH, the collagen mimetic triplexes were interconnected by PNA-GGG : DNA-CCC duplexes, leading to the formation of larger assemblies of nanostructures. Upon decreasing the pH to 4.5, the dissociation of the triplex-duplex assembly released the protonated C-rich DNA, which immediately folded into an i-motif. With an increase in the pH to 7.2 (neutral), the i-motif unfolded into linear DNA, which reformed the PNA-GGG : DNA-CCC duplex interconnecting the collagen triplexes. The pH-induced switching of the assembly and disassembly was reversible over a few cycles. The hybrid collagen-(PNAGGG)3 : DNA-C3T3C3 triplex-duplex and the individual components of the assembly including the i-motif were characterized by UV and CD melting, fluorescence, TEM and gel electrophoresis. The pH-induced reversible switching was established by the changes in the CD and fluorescence properties. Peptide-DNA conjugates have wide applications in both biology and materials science, ranging from therapeutics and drug delivery to diagnostics and molecular switches. Thus, the prototype ensemble of the triplex peptide-PNA conjugate and its duplex with DNA described herein has potential for elaboration into rationally designed systems by varying the PNA/DNA sequences to trap functional ligands/drugs for release in pH-controlled environments.

Facile Strategy to Output Fluorescein from Nucleic Acid Interactions

Biomolecular operations, which involve the conversion of molecular signals or interactions into specific functional outputs, are fundamental to the field of biology and serve as the important foundation for the design of diagnostic and therapeutic systems. To maximize their functionalities and broaden their applicability, it is crucial to develop novel outputs and facile chemical transformation methods. With this aim, in this study, we present a straightforward method for converting nucleic acid signals into fluorescein outputs that exhibit a wide range of functionalities. This operation is designed through a DNA-templated reaction based on riboflavin-photocatalyzed oxidation of dihydrofluorescein, which is readily prepared by simple NaBH4 reduction of the fluorescein with no complicated chemical caging steps. The templated photooxidation exhibits high efficiency (kapp = 2.7 × 10-3/s), generating a clear fluorescein output signal distinguishable from a low background, originating from the high stability of the synthesized dihydrofluorescein. This facile and efficient operation allows the nucleic acid-initiated activation of various fluorescein functions, such as fluorescence and artificial oxidase activity, which are applied in the design of novel bioanalytical systems, including fluorescent and colorimetric DNA sensors. The operation presented herein would expand the scope of biomolecular circuit systems for diagnostic and therapeutic applications.

Templated Self-Assembly of Dynamic Peptide Nucleic Acids

Template-directed macromolecule synthesis is a hallmark of living systems. Inspired by this natural process, several fundamentally novel mechanisms for template-directed assembly of nucleic acid analogues have been developed. Although these approaches have broad significance, including potential applications in biotechnology and implications for the origins of life, there are unresolved challenges in how to characterize in detail the complex assembly equilibria associated with dynamic templated reactions. Here we describe mechanistic studies of template-directed dynamic assembly for thioester peptide nucleic acid (tPNA), an informational polymer that responds to selection pressures under enzyme-free conditions. To overcome some of the inherent challenges of mechanistic studies of dynamic oligomers, we designed, synthesized, and implemented tPNA-DNA conjugates. The DNA primer region affords a high level of control over the location and register of the tPNA backbone in relation to the template strand. We characterized the degree and kinetics of dynamic nucleobase mismatch correction at defined backbone positions. Furthermore, we report the fidelity of dynamic assembly in tPNA as a function of position along the peptide backbone. Finally, we present theoretical studies that explore the level of fidelity that can be expected for an oligomer having a given hybridization affinity in dynamic templated reactions and provide guidance for the future development of sequence self-editing polymers and materials. As our results demonstrate, the use of molecular conjugates of constitutionally static and dynamic polymers establishes a new methodology for expediting the characterization of the complex chemical equilibria that underlie the assembly of dynamic informational polymers.

Synthetic Nucleic Acid Analogues in Gene Therapy: An Update for Peptide-Oligonucleotide Conjugates

The main objective of this work is to provide an update on synthetic nucleic acid analogues and nanoassemblies as tools in gene therapy. In particular, the synthesis and properties of peptide-oligonucleotide conjugates (POCs), which have high potential in research and as therapeutics, are described in detail. The exploration of POCs has already led to fruitful results in the treatment of neurological diseases, lung disorders, cancer, leukemia, viral, and bacterial infections. However, delivery and in vivo stability are the major barriers to the clinical application of POCs and other analogues that still have to be overcome. This review summarizes recent achievements in the delivery and in vivo administration of synthetic nucleic acid analogues, focusing on POCs, and compares their efficiency.

Nucleic Acid Templated Reactions for Chemical Biology

Nucleic acid directed bioorthogonal reactions offer the fascinating opportunity to unveil and redirect a plethora of intracellular mechanisms. Nano- to picomolar amounts of specific RNA molecules serve as templates and catalyze the selective formation of molecules that 1) exert biological effects, or 2) provide measurable signals for RNA detection. Turnover of reactants on the template is a valuable asset when concentrations of RNA templates are low. The idea is to use RNA-templated reactions to fully control the biodistribution of drugs and to push the detection limits of DNA or RNA analytes to extraordinary sensitivities. Herein we review recent and instructive examples of conditional synthesis or release of compounds for in cellulo protein interference and intracellular nucleic acid imaging.

Peptide-DNA conjugates as tailored bivalent binders of the oncoprotein c-Jun

We describe a ds-oligonucleotide-peptide conjugate that is able to efficiently dismount preformed DNA complexes of the bZIP regions of oncoproteins c-Fos and c-Jun (AP-1), and therefore might be useful as disrupters of AP-1-mediated gene expression pathways.

Construction of semisynthetic DNA-protein conjugates with Phi X174 Gene-A* protein

DNA-protein conjugates have frequently been used as versatile molecular tools for a variety of applications in biotechnology to harness synergistic effects of DNA and protein functions. With applications for DNA-protein conjugates growing, easy-to-use and economical methods for the synthesis of DNA-protein conjugates are required. In this study, we developed a method for site-specific labeling of single-stranded DNA (ssDNA) to a recombinant protein of interest (POI) through the Gene-A* protein (Gene-A*) from bacteriophage phi X174, without any chemical modifications of ssDNA. Gene-A* protein is an enzyme that site-selectively cleaves an oligodeoxyribonucleotide (ODN) containing a Gene-A* recognition sequence, at which point a tyrosine residue of Gene-A* is bonded to the 5'-phosphoryl group of the cleavage site via a stable phosphotyrosine linkage. Here, we constructed three kinds of recombinant proteins fused to Gene-A*: N-terminally Gene-A*-fused enhanced green fluorescent protein (EGFP), C-terminally Gene-A*-fused EGFP, and N-terminally Gene-A*-fused firefly luciferase (FLuc). The reaction yields of DNA-protein conjugation catalyzed by the Gene-A* moiety reached 80-90% in the three proteins, and kinetic study revealed that the reaction achieved a steady state after 10 min. Moreover, dot blot analyses were performed to evaluate the hybridization and aptamer-forming ability of ssDNA conjugated to the Gene-A* moiety of a recombinant Gene-A*-FLuc protein. This study demonstrated that a strategy using recombinant proteins fused to Gene-A* could offer a versatile, rapid, easy-to-use, and economical platform for producing DNA-protein conjugates.

Synthesis of oligonucleotide-peptide conjugates for biomedical and technological applications

Oligonucleotide-peptide conjugates have attracted considerable interest especially for biomedical uses. In the first part of this chapter, we describe protocols for the stepwise synthesis of oligonucleotides carrying peptide sequences at the 3'-end on a single support. The resulting oligonucleotide-peptide conjugates may be used as exogenous effectors for the specific control of gene expression. In the second part of this chapter, detailed postsynthetic conjugation protocols to introduce peptide sequences into oligonucleotide sequences are also presented.

High-density DNA functionalization by a combination of Cu-catalyzed and cu-free click chemistry

We report the regioselective Cu-free click modification of styrene functionalized DNA with nitrile oxides. A series of modified oligodeoxynucleotides (nine base pairs) was prepared with increasing styrene density. 1,3-Dipolar cycloaddition with nitrile oxides allows the high density functionalization of the styrene modified DNA directly on the DNA solid support and in solution. This click reaction proceeds smoothly even directly in the DNA synthesizer and gives exclusively 3,5-disubstituted isoxazolines. Additionally, PCR products (300 and 900 base pairs) were synthesized with a styrene triphosphate and KOD XL polymerase. The click reaction on the highly modified PCR fragments allows functionalization of hundreds of styrene units on these large DNA fragments simultaneously. Even sequential Cu-free and Cu-catalyzed click reaction of PCR amplicons containing styrene and alkyne carrying nucleobases was achieved. This new approach towards high-density functionalization of DNA is simple, modular, and efficient.

Native chemical ligation in the synthesis of internally modified oligonucleotide-peptide conjugates

Peptide-oligonucleotide conjugates have frequently been synthesized to improve cellular delivery of antisense or antigene compounds, to allow the immobilization of peptide and protein conjugates on DNA arrays, or to decorate nucleic acid architectures with peptide functions. In such applications, the site of conjugation is of little importance, and peptides have predominantly been appended to one of the terminal ends of the oligonucleotide by using an oxime-, thioether-, or disulfide-linkage or native chemical ligation. We, herein, demonstrate the first coupling of peptides to sequence internal sites. This attachment mode provides better control of the spatial arrangement of peptides presented by self-assembled nucleic acid scaffolds. Internal modification requires special phosphoramidite building blocks that can be used in automated DNA synthesis. For this purpose, Fmoc/StBu-protected cysteine was attached via an aminopropargyl linker to the C5-position of uridine. The rigid triple bond conferred a high reactivity in native chemical ligation reactions of 5-6mer peptide thioesters with up to 15 nucleotides long oligonucleotides. The desired peptide-oligonucleotide conjugates were obtained in high yields after purification. UV melt experiments revealed that the peptide modification does not hamper nucleic acid hybridization. This finding marked an important step in our research program devoted to studies of multivalent presentation of peptides via modular assembly of nucleic acid complexes.

PNA zipper as a dimerization tool: development of a bZip mimic

The article describes the use of a PNA duplex (PNA zipper) as a tool to dimerize or bring in close proximity two polypeptides or protein domains. The amino acid sequence to be dimerized is covalently bound to complementary PNA sequences. Annealing of the PNA strands results in dimer formation. To test the ability of the "PNA-zipper" as a dimerization tool, we designed a GCN4 mimetic, where the leucine-zipper dimerization domain was replaced by the PNA zipper, whereas the basic DNA-binding domain was covalently attached to the PNA. The molecule was assembled by chemical ligation of the peptide corresponding to the DNA-binding domain of GCN4 modified with a succinyl thioester with two complementary PNAs harboring a cysteine residue. Electromobility-shift experiments show the ability of the PNA zipper-GCN4 to bind selected DNA duplexes. The PNA zipper-GCN4 binds both the TRE and CRE DNA sites, but it does not bind TRE and CRE mutants containing even a single base mutation, as the native GCN4. The ability to fold upon complexation with DNA was investigated by CD. A good correlation between the ability of the PNA zipper-GCN4 to fold into alpha helices and the ability to bind DNA was found.

DNA and RNA-controlled switching of protein kinase activity

Protein switches use the binding energy gained upon recognition of ligands to modulate the conformation and binding properties of protein segments. We explored whether the programmable nucleic acid mediated recognition might be used to design or mimic constraints that limit the conformational freedom of peptide segments. The aim was to design nucleic acid-peptide conjugates in which the peptide portion of the conjugate would change the affinity for a protein target upon hybridization. This approach was used to control the affinity of a PNA-phosphopeptide conjugate for the signal transduction protein Src kinase, which binds the cognate phosphopeptides in a linear conformation. Peptide-nucleic acid arms were attached to known peptide binders. The chimeric molecules were studied in three modes: 1) as single strands, 2) constrained by intermolecular hybridization (duplex formation) and 3) constrained by intramolecular hybridization (hairpin formation). Of note, duplexes that were designed to accommodate bulged peptide structures (for example, in hairpins or bulges) had lower binding affinities than duplexes in which the peptide was allowed to adopt a more relaxed conformation. Greater than 90-fold differences in binding affinities were observed. It was, thus, feasible to make use of DNA hybridization to reversibly switch from no to almost complete inhibition of Src-SH2-peptide binding, and vice versa. A series of DNA and PNA-based hybridization experiments revealed the importance of charges and conformational effects. Nucleic acid mediated switching was extended to the use of RNA; this enabled a regulation of the enzymatic activity of the Src kinase. The proof-of-principle results demonstrate for the first time that PNA-peptide chimeras can transduce changes of the concentration of a given RNA molecule to changes of the activity of a signal transduction enzyme.