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Abstract

Proof of concept for MERTK gene replacement therapy has been demonstrated using different viral vectors in the Royal College of Surgeon (RCS) rat, a well characterized model of recessive retinitis pigmentosa that contains a mutation in the Mertk gene. MERTK plays a key role in renewal of photoreceptor outer segments (OS) by phagocytosis of shed OS tips. Mutations in MERTK cause impaired phagocytic activity and accumulation of OS debris in the interphotoreceptor space that ultimately leads to photoreceptor cell death. In the present study, we conducted a series of preclinical potency and GLP-compliant safety evaluations of an adeno-associated virus type 2 (AAV2) vector expressing human MERTK cDNA driven by the retinal pigment epithelium–specific, VMD2 promoter. We demonstrate the potency of the vector in RCS rats by improved electroretinogram (ERG) responses in treated eyes compared with contralateral untreated controls. Toxicology and biodistribution studies were performed in Sprague–Dawley (SD) rats injected with two different doses of AAV vectors and buffer control. Delivery of vector in SD rats did not result in a change in ERG amplitudes of rod and cone responses relative to balanced salt solution control–injected eyes, indicating that administration of AAV vector did not adversely affect normal retinal function. In vivo fundoscopic analysis and postmortem retinal morphology of the vector-injected eyes were normal compared with controls. Evaluation of blood smears showed the lack of transformed cells in the treated eyes. All injected eyes and day 1 blood samples were positive for vector genomes, and all peripheral tissues were negative. Our results demonstrate the potency and safety of the AAV2-VMD2-hMERTK vector in animal models tested. A GMP vector has been manufactured and is presently in clinical trial.

Conlon and colleagues report results from a series of preclinical potency and safety evaluations of an AAV2 vector expressing human mer proto-oncogene tyrosine kinase (MERTK) cDNA driven by a retinal pigment epithelium-specific VMD2 promoter (AAV2-VMD2-hMERTK). They demonstrate that a single injection of this vector is effective in a rat model of recessive retinitis pigmentosa, whereas biodistribution studies indicate that vector is not spread outside the eye.

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References

Alexander

J.J.

, Hauswirth

W.W.

2008. Adeno-associated viral vectors and the retina. Adv. Exp. Med. Biol., 613:121–128.

Bainbridge

J.W.

, Smith

A.J.

, Barker

S.S.

et al. 2008. Effect of gene therapy on visual function in Leber's congenital amaurosis. N. Engl. J. Med., 358:2231–2239.

Bok

, Hall

M.O.

1971. The role of the pigment epithelium in the etiology of inherited retinal dystrophy in the rat. J. Cell Biol., 49:664–682.

Boye

S.E.

, Boye

S.L.

, Lewin

A.S.

, Hauswirth

W.W.

2013. A comprehensive review of retinal gene therapy. Mol Ther., 21:503–519.

Charbel

I.P.

, Bolz

H.J.

, Ebermann

et al. 2009. Characterisation of severe rod-cone dystrophy in a consanguineous family with a splice site mutation in the MERTK gene. Br. J. Ophthalmol., 93:920–925.

Cideciyan

A.V.

, Aleman

T.S.

, Boye

S.L.

et al. 2008. Human gene therapy for RPE65 isomerase deficiency activates the retinoid cycle of vision but with slow rod kinetics. Proc. Natl. Acad. Sci. U.S.A., 105:15112–15117.

D'Cruz

P.M.

, Yasumura

, Weir

et al. 2000. Mutation of the receptor tyrosine kinase gene Mertk in the retinal dystrophic RCS rat. Hum. Mol. Genet., 9:645–651.

Dowling

J.E.

, Sidman

R.L.

1962. Inherited retinal dystrophy in the rat. J. Cell Biol., 14:73–109.

Flotte

T.R.

, Conlon

T.J.

, Mueller

2011. Preclinical study design for rAAV. Methods Mol. Biol., 807:317–337.

10.

Gal

, Li

, Thompson

D.A.

et al. 2000. Mutations in MERTK, the human orthologue of the RCS rat retinal dystrophy gene, cause retinitis pigmentosa. Nat. Genet., 26:270–271.

11.

Hartong

D.T.

, Berson

E.L.

, Dryja

T.P.

2006. Retinitis pigmentosa. Lancet, 368:1795–1809.

12.

Ksantini

, Lafont

, Bocquet

et al. 2012. Homozygous mutation in MERTK causes severe autosomal recessive retinitis pigmentosa. Eur. J. Ophthalmol., 22:647–653.

13.

Linger

R.M.

, Keating

A.K.

, Earp

H.S.

, Graham

D.K.

2008. TAM receptor tyrosine kinases: biologic functions, signaling, and potential therapeutic targeting in human cancer. Adv. Cancer Res., 100:35–83.

14.

Mackay

D.S.

, Henderson

R.H.

, Sergouniotis

P.I.

et al. 2010. Novel mutations in MERTK associated with childhood onset rod-cone dystrophy. Mol. Vis., 16:369–377.

15.

Maguire

A.M.

, Simonelli

, Pierce

E.A.

et al. 2008. Safety and efficacy of gene transfer for Leber's congenital amaurosis. N. Engl. J. Med., 358:2240–2248.

16.

Mullen

R.J.

, LaVail

M.M.

1976. Inherited retinal dystrophy: primary defect in pigment epithelium determined with experimental rat chimeras. Science, 192:799–801.

17.

Ostergaard

, Duno

, Batbayli

et al. 2011. A novel MERTK deletion is a common founder mutation in the Faroe Islands and is responsible for a high proportion of retinitis pigmentosa cases. Mol. Vis., 17:1485–1492.

18.

Pang

J.J.

, Deng

W.T.

, Dai

et al. 2012. AAV-mediated cone rescue in a naturally occurring mouse model of CNGA3-achromatopsia. PLoS One, 7:e35250.

19.

Rivolta

, Sharon

, DeAngelis

M.M.

et al. 2002. Retinitis pigmentosa and allied diseases: numerous diseases, genes, and inheritance patterns. Hum. Mol. Genet., 11:1219–1227.

20.

Shahzadi

, Riazuddin

S.A.

, Ali

et al. 2010. Nonsense mutation in MERTK causes autosomal recessive retinitis pigmentosa in a consanguineous Pakistani family. Br. J. Ophthalmol., 94:1094–1099.

21.

Smith

A.J.

, Schlichtenbrede

F.C.

, Tschernutter

et al. 2003. AAV-mediated gene transfer slows photoreceptor loss in the RCS rat model of retinitis pigmentosa. Mol. Ther., 8:188–195.

22.

Strick

D.J.

, Vollrath

2010. Focus on molecules: MERTK. Exp. Eye Res., 91:786–787.

23.

Thompson

D.A.

, McHenry

C.L.

, Li

et al. 2002. Retinal dystrophy due to paternal isodisomy for chromosome 1 or chromosome 2, with homoallelism for mutations in RPE65 or MERTK, respectively. Am. J. Hum. Genet., 70:224–229.

24.

Tschernutter

, Schlichtenbrede

F.C.

, Howe

et al. 2005. Long-term preservation of retinal function in the RCS rat model of retinitis pigmentosa following lentivirus-mediated gene therapy. Gene Ther., 12:694–701.

25.

Tschernutter

, Jenkins

S.A.

, Waseem

N.H.

et al. 2006. Clinical characterisation of a family with retinal dystrophy caused by mutation in the Mertk gene. Br. J. Ophthalmol., 90:718–723.

26.

Vollrath

, Feng

, Duncan

J.L.

et al. 2001. Correction of the retinal dystrophy phenotype of the RCS rat by viral gene transfer of Mertk. Proc. Natl. Acad. Sci. U.S.A., 98:12584–12589.

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Preclinical Potency and Safety Studies of an AAV2-Mediated Gene Therapy Vector for the Treatment of MERTK Associated Retinitis Pigmentosa

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