Better explicating the strengths and shortcomings of these models will help refine projections and improve transparency in the years ahead.
Image credit: Witsawat.S.
Contributed by Richard L. Sidman, January 4, 2016 (sent for review December 7, 2015; reviewed by Herbert Chen, James Howe, and Raphael E. Pollock)
Significance
There are literally thousands of biologically active, clinically relevant peptide motifs in mammalian species. Surprisingly, however, despite this abundance of potential peptide reagents for ligand-directed delivery, applications for targeted gene therapy are generally lacking. Here we used a hybrid AAV/phage (AAVP) vector for octreotide ligand-directed therapeutic gene delivery to pancreatic neuroendocrine tumors in a transgenic mouse model that faithfully recapitulates the cognate human disease. This platform is readily available for a translational clinical trial. In a broader context, this proof-of-concept work establishes a unique targeting paradigm in which existing ligand/receptors may be exploited in nature while minimizing or eliminating several rate-limiting steps of conventional phage display library selection that require cumbersome experimental discovery work.
Abstract
Patients with inoperable or unresectable pancreatic neuroendocrine tumors (NETs) have limited treatment options. These rare human tumors often express somatostatin receptors (SSTRs) and thus are clinically responsive to certain relatively stable somatostatin analogs, such as octreotide. Unfortunately, however, this tumor response is generally short-lived. Here we designed a hybrid adeno-associated virus and phage (AAVP) vector displaying biologically active octreotide on the viral surface for ligand-directed delivery, cell internalization, and transduction of an apoptosis-promoting tumor necrosis factor (TNF) transgene specifically to NETs. These functional attributes of AAVP-TNF particles displaying the octreotide peptide motif (termed Oct-AAVP-TNF) were confirmed in vitro, in SSTR type 2-expressing NET cells, and in vivo using cohorts of pancreatic NET-bearing Men1 tumor-suppressor gene KO mice, a transgenic model of functioning (i.e., insulin-secreting) tumors that genetically and clinically recapitulates the human disease. Finally, preclinical imaging and therapeutic experiments with pancreatic NET-bearing mice demonstrated that Oct-AAVP-TNF lowered tumor metabolism and insulin secretion, reduced tumor size, and improved mouse survival. Taken together, these proof-of-concept results establish Oct-AAVP-TNF as a strong therapeutic candidate for patients with NETs of the pancreas. More broadly, the demonstration that a known, short, biologically active motif can direct tumor targeting and receptor-mediated internalization of AAVP particles may streamline the potential utility of myriad other short peptide motifs and provide a blueprint for therapeutic applications in a variety of cancers and perhaps many nonmalignant diseases as well.
Footnotes
- ↵1To whom correspondence may be addressed. Email: richard_sidman{at}hms.harvard.edu, rpasqual{at}salud.unm.edu, or warap{at}salud.unm.edu.
↵2R.P. and W.A. contributed equally to this work.
Author contributions: T.L.S., M.C.-V., C.A.B., S.K.L., R.L.S., R.P., and W.A. designed research; T.L.S., Z.Y., M.C.-V., C.S.C., A.A., and M.-H.C. performed research; T.L.S., Z.Y., A.A., M.-H.C., and J.G.G. contributed new reagents/analytic tools; T.L.S., Z.Y., M.C.-V., C.S.C., A.A., M.-H.C., J.G.G., S.K.L., R.L.S., R.P., and W.A. analyzed data; and T.L.S., M.C.-V., S.K.L., R.L.S., R.P., and W.A. wrote the paper.
Reviewers: H.C., University of Alabama; J.H., University of Iowa Carver College of Medicine; and R.E.P., Ohio State University Wexner Medical Center.
Conflict of interest statement: J.G.G., S.K.L., R.P., and W.A. are founders of and equity holders in AAVP BioSystems. R.P. and W.A. are inventors listed on patent applications related to this work and will be entitled to standard royalties if licensing and/or commercialization occurs. The University of New Mexico Health Sciences Center currently manages these arrangements in accordance with its established institutional conflict of interest policy.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1525709113/-/DCSupplemental.
Freely available online through the PNAS open access option.
Oct-AAVP-TNF for pancreatic neuroendocrine tumors
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