Sage Journals: Discover world-class research

Abstract

Replication-competent (oncolytic) adenoviruses (OAV) can be adapted as vectors for the delivery of therapeutic genes, with the aim of extending the antitumor effect beyond direct cytolysis. Transgene expression using these vectors is usually intense but short-lived, and repeated administrations are hampered by the rapid appearance of neutralizing antibodies (NAbs). We have studied the performance of monocytes as cell carriers to improve transgene expression in cancer models established in athymic mice and immunocompetent Syrian hamsters. Human and hamster monocytic cell lines (MonoMac6 and HM-1, respectively) were loaded with replication-competent adenovirus-expressing luciferase. Intravenous administration of these cells caused a modest increase in transgene expression in tumor xenografts, but this effect was virtually lost in hamsters. In contrast, intratumoral administration of HM-1 cells allowed repeated cycles of expression and achieved partial protection from NAbs in preimmunized hamsters bearing pancreatic tumors. To explore the therapeutic potential of this approach, HM-1 cells were loaded with a hypoxia-inducible OAV expressing the immunostimulatory cytokine interleukin-12 (IL-12). Three cycles of treatment achieved a significant antitumor effect in the hamster model, and transgene expression was detected following each administration, in contrast with the rapid neutralization of the free virus. We propose monocytes as carriers for multiple intratumoral administrations of armed OAVs.

Get full access to this article

View all access options for this article.

References

Ahmed

A.U.

, Rolle

C.E.

, Tyler

M.A.

et al. 2010. Bone marrow mesenchymal stem cells loaded with an oncolytic adenovirus suppress the anti-adenoviral immune response in the cotton rat model. Mol. Ther., 18:1846–1856.

Ahmed

A.U.

, Tyler

M.A.

, Thaci

et al. 2011. A comparative study of neural and mesenchymal stem cell-based carriers for oncolytic adenovirus in a model of malignant glioma. Mol. Pharm., 8:1559–1572.

Alemany

, Cascallo

2009. Oncolytic viruses from the perspective of the immune system. Future Microbiol., 4:527–536.

Appaiahgari

M.B.

, Pandey

R.M.

, Vrati

2007. Seroprevalence of neutralizing antibodies to adenovirus type 5 among children in India: implications for recombinant adenovirus-based vaccines. Clin. Vaccine Immunol., 14:1053–1055.

Bortolanza

, Alzuguren

, Bunuales

et al. 2007. Human adenovirus replicates in immunocompetent models of pancreatic cancer in Syrian hamsters. Hum Gene Ther., 18:681–90.

Bortolanza

, Bunuales

, Alzuguren

et al. 2009a. Deletion of the E3-6.7K/gp19K region reduces the persistence of wild-type adenovirus in a permissive tumor model in Syrian hamsters. Cancer Gene Ther., 16:703–712.

Bortolanza

, Bunuales

, Otano

et al. 2009b. Treatment of pancreatic cancer with an oncolytic adenovirus expressing interleukin-12 in Syrian hamsters. Mol Ther., 17:614–622.

Breitbach

C.J.

, Burke

, Jonker

et al. 2011. Intravenous delivery of a multi-mechanistic cancer-targeted oncolytic poxvirus in humans. Nature, 477:99–102.

Dwyer

R.M.

, Kerin

M.J.

2010. Mesenchymal stem cells and cancer: tumor-specific delivery vehicles or therapeutic targets? Hum. Gene Ther., 21:1506–1512.

10.

Eager

R.M.

, Nemunaitis

2011. Clinical development directions in oncolytic viral therapy. Cancer Gene Ther., 18:305–317.

11.

Fontanellas

, Hervas-Stubbs

, Mauleon

et al. 2010. Intensive pharmacological immunosuppression allows for repetitive liver gene transfer with recombinant adenovirus in nonhuman primates. Mol. Ther., 18:754–765.

12.

Fueyo

, Gomez-Manzano

, Alemany

et al. 2000. A mutant oncolytic adenovirus targeting the Rb pathway produces anti-glioma effect in vivo. Oncogene., 19:2–12.

13.

Hawkins

L.K.

, Johnson

, Bauzon

et al. 2001. Gene delivery from the E3 region of replicating human adenovirus: evaluation of the 6.7 K/gp19 K region. Gene Ther., 8:1123–1131.

14.

Heise

, Hermiston

, Johnson

et al. 2000. An adenovirus E1A mutant that demonstrates potent and selective systemic anti-tumoral efficacy. Nat Med., 6:1134–1139.

15.

Josiah

D. T.

, Zhu

, Dreher

et al. 2010. Adipose-derived stem cells as therapeutic delivery vehicles of an oncolytic virus for glioblastoma. Mol Ther., 18:377–385.

16.

Lei

, Shen

F.B.

, Chang

J.H.

et al. 2009. An oncolytic adenovirus expressing granulocyte macrophage colony-stimulating factor shows improved specificity and efficacy for treating human solid tumors. Cancer Gene Ther., 16:33–43.

17.

Liu

, Russell

S.J.

, Peng

K.W.

2010. Systemic therapy of disseminated myeloma in passively immunized mice using measles virus-infected cell carriers. Mol Ther., 18:1155–1164.

18.

Murdoch

, Lewis

C.E.

2005. Macrophage migration and gene expression in response to tumor hypoxia. Int. J. Cancer., 117:701–708.

19.

Muthana

, Giannoudis

, Scott

S.D.

et al. 2011. Use of macrophages to target therapeutic adenovirus to human prostate tumors. Cancer Res., 71:1805–1815.

20.

Narvaiza

, Aparicio

, Vera

et al. 2006. Effect of adenovirus-mediated RNA interference on endogenous microRNAs in a mouse model of multidrug resistance protein 2 gene silencing. J. Virol., 80:12236–12247.

21.

Penuelas

, Mazzolini

, Boan

J.F.

et al. 2005. Positron emission tomography imaging of adenoviral-mediated transgene expression in liver cancer patients. Gastroenterology, 128:1787–1795.

22.

Raykov

, Rommelaere

2008. Potential of tumour cells for delivering oncolytic viruses. Gene Ther., 15:704–710.

23.

Senzer

N. N.

, Kaufman

H. L.

, Amatruda

et al. 2009. Phase II clinical trial of a granulocyte-macrophage colony-stimulating factor-encoding, second-generation oncolytic herpesvirus in patients with unresectable metastatic melanoma. J. Clin. Oncol., 27:5763–5771.

24.

Sprangers

M.C.

, Lakhai

, Koudstaal

et al. 2003. Quantifying adenovirus-neutralizing antibodies by luciferase transgene detection: addressing preexisting immunity to vaccine and gene therapy vectors. J. Clin. Microbiol., 41:5046–5052.

25.

Sun

, Zhang

, Feng

et al. 2011. Epidemiology of adenovirus type 5 neutralizing antibodies in healthy people and AIDS patients in Guangzhou, southern China. Vaccine, 29:3837–3841.

26.

Thomas

M.A.

, Spencer

J.F.

, La Regina

M.C.

et al. 2006. Syrian hamster as a permissive immunocompetent animal model for the study of oncolytic adenovirus vectors. Cancer Res., 66:1270–1276.

27.

Thorne

S.H.

, Liang

, Sampath

et al. 2010. Targeting localized immune suppression within the tumor through repeat cycles of immune cell-oncolytic virus combination therapy. Mol Ther., 18:1698–1705.

28.

Thorner

A.R.

, Vogels

, Kaspers

et al. 2006. Age dependence of adenovirus-specific neutralizing antibody titers in individuals from sub-Saharan Africa. J. Clin. Microbiol., 44:3781–3783.

29.

Zabala

, Alzuguren

, Benavides

et al. 2009. Evaluation of bioluminescent imaging for noninvasive monitoring of colorectal cancer progression in the liver and its response to immunogene therapy. Mol. Cancer, 8:2.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.05 MB

0.03 MB

0.04 MB

Evaluation of Monocytes as Carriers for Armed Oncolytic Adenoviruses in Murine and Syrian Hamster Models of Cancer

Abstract

Get full access to this article

References

Supplementary Material