Browsing by Subject "Therapeutic"
Results Per Page
Sort Options
Item Open Access Achieving Cell-Specific Delivery of Multiple Oligonucleotide Therapeutics with Aptamer Chimeras(2012) Kotula, Jonathan WCurrent standard cancer treatments such as chemotherapeutics, and radiation therapy are nearly as likely to kill the patient as cure the cancer. Therapies that have such a narrow window of efficacy are necessary for the treatment of aggressive diseases, but safer alternatives must be created. By discovering novel therapeutics that target specific disease processes within specific diseased cells, while leaving healthy cells unaltered, we can improve the lives of millions of cancer sufferers and their families. A therapeutic's window of efficacy can be measured by the therapeutic index. For many anti-cancer therapeutics, the therapeutic index is very small, the dose of treatment that kills cancer cells and shrinks tumors is nearly the dose that causes toxicity. In cancer patients, this toxicity causes many serious conditions such as gastrointestinal distress, organ damage, and death.
Recently, the model of cancer treatment has evolved from non-specific cytotoxic agents to more selective therapeutics that target cellular processes necessary for cancer cell survival. If a therapy can be targeted to selectively bind and internalize targeted cells, its toxicity would only impact the targeted cells and healthy cells in the immediate vicinity, which would greatly reduce the toxic effects on the rest of the body. Targeting cancer cells can be done through cancer biomarkers, which are cell surface proteins, expressed exclusively, or are much more abundant on the surface of cancer cells than on somatic cells.
Advances in antibody and aptamer technology have enabled researchers to design those molecules to bind specifically to cancer cells, and deliver drugs that alter specific cellular processes. An aptamer designed to bind PSMA, a prostate cancer biomarker, only bound to a specific subset of cancer cells, and delivered a therapeutic siRNA that prevented a specific survival process from occurring. While this technology is promising, it is currently limited to targeting small subsets of cancer types. To generate an aptamer therapeutic that would have greater utility and efficacy, I have examined the properties of a nucleolin aptamer-mediated delivery system that targets multiple types of cancer cells, and delivers various oligonucleotide therapeutics.
The nucleolin aptamer targeted cancer cells by binding to membrane–associated nucleolin. Nucleolin, a conserved protein found in all eukaryotes, shuttles from the nucleus, through the cytoplasm to the cell membrane. Cancer cells express a far greater amount of membrane–associated nucleolin than somatic cells, making nucleolin an ideal cancer biomarker. The shuttling, and oligonucleotide binding attributes of the protein enable it to deliver aptamer chimeras from the cell surface to the nucleus. Therefore the nucleolin aptamer has unique access to the nuclei of cancer cells, and can deliver therapeutic oligonucleotide cargoes through nucleolin binding.
The nucleolin aptamer delivered splice–switching oligonucleotides, a form of antisense technology, improving their efficacy, and potentially increasing their therapeutic viability. The ability to deliver antisense oligonucleotides to the nuclei of cancer cells has the potential for other therapeutic possibilities including the inhibition of transcription with antisense triplexes.
The nucleolin aptamer can also deliver therapeutic aptamers. The nucleolin aptamer–β–arrestin aptamer chimera prevented the stem cell renewal phenotype necessary for leukemia progression in human patient tissue samples. The ability to effectively deliver therapeutic aptamers may lead to clinical applications for many of the aptamers that have been selected against intracellular targets including transcriptional activators.
Oligonucleotide research continues to advance our understanding of potentially therapeutic oligonucleotides. Long non–coding RNAs for example, may impact epigenetics, and transcription. Additionally, locked nucleic acids have been developed to improve binding affinity, thus increasing the efficacy of antisense oligonucleotides. In order to bring these discoveries into the clinic, they must be safely and specifically delivered to their target cells.
This work demonstrated that the nucleolin aptamer could deliver oligonucleotide therapeutics to specific cancer cells. Nucleolin aptamer chimeras have the potential to develop into safe and effective cancer therapies, thus improving the treatment options for cancer sufferers.
Item Open Access Development and Characterization of Monovalent and Bivalent RNA Aptamers Targeting the Common Pathway of Coagulation(2016) Soule, Erin ElizabethAnticoagulant agents are commonly used drugs to reduce blood coagulation in acute and chronic clinical settings. Many of these drugs target the common pathway of coagulation because it is critical for thrombin generation and disruption of this portion of the pathway has profound effects on the hemostatic process. Currently available drugs for these indications struggle with balancing desired activity with immunogenicity and poor reversibility or irreversibility in the event of hemorrhage. While improvements are being made with the current drugs, new drugs with better therapeutic indices are needed for surgical intervention and chronic indications to prevent thrombosis from occurring.
A class of therapeutics known as aptamers may be able to meet the need for safer anticoagulant agents. Aptamer are short single-stranded RNA oligonucleotides that adopt specific secondary and tertiary structures based upon their sequence. They can be generated to both enzymes and cofactors because they derive their inhibitory activity by blocking protein-protein interactions, rather than active site inhibition. They inhibit their target proteins with a high level of specificity and bind with high affinity to their target. Additionally, they can be reversed using two different antidote approaches, specific oligonucleotide antidotes, or with cationic, “universal” antidotes. The reversal of their activity is both rapid and durable.
The ability of aptamers to be generated to cofactors has been conclusively proven by generating an aptamer targeting the common pathway coagulation cofactor, Factor V (FV). We developed two aptamers with anticoagulant ability that bind to both FV and FVa, the active cofactor. Both aptamers were truncated to smaller functional sizes and had specific point mutant aptamers developed for use as controls. The anticoagulant activity of both aptamer-mutant pairs was characterized using plasma-based clotting assays and whole blood assays. The mechanism of action resulting in anticoagulant activity was assessed for one aptamer. The aptamer was found to block FVa docking to membrane surfaces, a mechanism not previously observed in any of our other anticoagulant aptamers.
To explore development of aptamers as anticoagulant agents targeting the common pathway for surgical interventions, we fused two anticoagulant aptamers targeting Factor X and prothrombin into a single molecule. The bivalent aptamer was truncated to a minimal size while maintaining robust anticoagulant activity. Characterization of the bivalent aptamer in plasma-based clotting assays indicated we had generated a very robust anticoagulant therapeutic. Furthermore, we were able to simultaneously reverse the activity of both aptamers with a single oligonucleotide antidote. This rapid and complete reversal of anticoagulant activity is not available in the antithrombotic agents currently used in surgery.
Item Open Access Development of RNA Aptamers and Antidotes as Antithrombotic Therapeutics(2012) Bompiani, KristinThrombosis, or pathological blood clot formation, is intimately associated with cardiovascular disease and is the leading cause of morbidity and mortality in the western world. Antithrombotics are commonly prescribed as prophylactic medications or as rapid onset anticoagulants in acute care clinical settings. Although a number of antithrombotics are clinically available, their use is limited by immunogenicity, toxicity, and inability to be controlled with an antidote in the event of hemorrhage. Therefore, new antithrombotics that are effective, yet can be rapidly controlled are urgently needed.
Aptamers are oligonucleotides that form complex secondary and tertiary structures based on intramolecular base pairing and nucleic acid folding that allows them to bind to molecular targets with high affinity and specificity. Aptamers can be isolated that bind to proteins, such as clotting proteins, and modulate protein function. However, unlike most currently used antithrombotics, aptamers can be directly controlled with an antidote and therefore represent a safer class of therapeutic agents.
To generate a novel anticoagulant, we developed an aptamer-antidote pair against prothrombin. Prothrombin is a blood protein that plays an essential role in clot formation. I truncated, optimized, and studied the mechanism of an aptamer that can bind to prothrombin and inhibit prothrombin function, thereby severely impeding clot formation. Moreover, to increase the safety profile of this anticoagulant aptamer, I developed an antidote that can quickly reverse aptamer function and restore normal clotting. This aptamer and antidote pair is the first antidote reversible anticoagulant that targets prothrombin and may prove to be a valuable clinical anticoagulant.
A number of anticoagulants are in development, and a wide debate regarding the optimal protein target for anticoagulation is underway. We have previously generated anticoagulant aptamers to human coagulation factor VII, factor IX, factor X, and prothrombin. I compared the effects of these four anticoagulant aptamers to determine their impact on thrombin generation and clot formation. Each aptamer exerts its own unique effect on thrombin generation/clot formation, depending on the role that its protein target plays in coagulation. These studies provide valuable data regarding target validation and the anticoagulant effects of different therapeutic aptamers.
Robust anticoagulation is required during acute clinical surgical procedures to treat thrombosis. Currently used anticoagulants have several untoward side effects and most are not antidote controllable. I tested the effects of combining two anticoagulant aptamers to assess potential drug synergy. Several combinations of two anticoagulant aptamers were synergistic and severely impaired blood clot formation. One specific pair of aptamers that targeted factor X (FX) and prothrombin in combination was extremely potent and could keep blood fluid in an ex vivo model of extracorporeal circulation. Additionally, this pair of aptamers could be functionally modulated with two different types of antidotes. In conjunction with antidote reversal, this strategy of combining aptamer anticoagulants may prove useful in a variety of highly prothrombotic acute clinical settings.
Finally, to explore the potential of aptamers to regulate platelet function, I isolated and characterized an aptamer toward platelet glycoprotein VI. Glycoprotein VI is a platelet surface receptor that plays a key role in platelet activation and platelet plug formation. I isolated several aptamers that bind to glycoprotein VI, and show that the lead aptamer binds to platelets with high affinity and causes platelet activation and aggregation. This aptamer could potentially be further developed for topical administration to manage bleeding, or for biomarker detection of soluble glycoprotein VI in patient plasma.