An Aptamer for Broad Cancer Targeting and Therapy.

Bethany Powell Gray,Ashley P Barry,David S Hsu,Bruce A Sullenger,Xirui Song,Matthew Levy,Christina Kratschmer

doi:10.3390/cancers12113217

Bethany Powell Gray, Ashley P Barry + Show 5 more

Open Access

https://doi.org/10.3390/cancers12113217

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Abstract

Simple SummaryRecent efforts to improve chemotherapy’s antitumor effects have increasingly focused on targeted therapies, where the drug is modified with an agent able to specifically deliver it to the tumor while limiting its accumulation in normal tissue. Aptamers, comprised of short pieces of RNA or DNA, are ideal for this type of drug targeting due in part to their ease of chemical synthesis. The E3 aptamer was previously conjugated to highly toxic chemotherapeutics and shown to target and treat prostate tumors. Here, we show that E3 is not limited to prostate cancer targeting but appears to broadly target cancer cells. E3 highly toxic drug conjugates also efficiently kill a broad range of cancer types, and E3 targets tumors that closely model patient tumors. Thus, the E3 aptamer appears to be a general agent for specific delivery of chemotherapy to tumors and should improve antitumor treatment while reducing unwanted toxicities in other tissues. Recent advances in chemotherapy treatments are increasingly targeted therapies, with the drug conjugated to an antibody able to deliver it directly to the tumor. As high-affinity chemical ligands that are much smaller in size, aptamers are ideal for this type of drug targeting. Aptamer-highly toxic drug conjugates (ApTDCs) based on the E3 aptamer, selected on prostate cancer cells, target and inhibit prostate tumor growth in vivo. Here, we observe that E3 also broadly targets numerous other cancer types, apparently representing a universal aptamer for cancer targeting. Accordingly, ApTDCs formed by conjugation of E3 to the drugs monomethyl auristatin E (MMAE) or monomethyl auristatin F (MMAF) efficiently target and kill a range of different cancer cells. Notably, this targeting extends to both patient-derived explant (PDX) cancer cell lines and tumors, with the E3 MMAE and MMAF conjugates inhibiting PDX cell growth in vitro and with the E3 aptamer targeting PDX colorectal tumors in vivo.

Highlights

The death rate among cancer patients in the United States has continually declined since 1991, reducing by almost 30% [1]
We show that the E3 monomethyl auristatin E (MMAE) and monomethyl auristatin F (MMAF) highly toxic drug conjugates can be used for efficient drug targeting and drug-induced cell killing against the different types of cancer cells that E3 targets, including patient-derived explant (PDX) colorectal cancer cells
We previously demonstrated that the synthesis of fluorescent dye-labeled E3 retains aptamer function and specificity for prostate cancer cells [12]

Summary

Introduction

The death rate among cancer patients in the United States has continually declined since 1991, reducing by almost 30% [1]. Half of this marked improvement is attributed to improvements in treatments, most notably the use of chemotherapy [2]. Given the marked success of chemotherapy, but still the clear need for improvement, extensive efforts have focused on increasing antitumor effects while concurrently reducing the dose-limiting toxicities that result from chemotherapeutic drug accumulation in normal tissue. While first-generation ADCs failed in the clinic (reviewed in [11]), these second-generation ADCs are succeeding due to newer, highly toxic chemotherapeutics coupled to the antibodies via more stable chemical linkers

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