Marian Renwick scite author profile

PurposeTemporal and reversible control of protein expression in vivo is a central goal for many gene therapies, especially for strategies involving proteins that are detrimental to physiology if constitutively expressed. Accordingly, we explored whether protein abundance in the mouse retina could be effectively controlled using a destabilizing Escherichia coli dihydrofolate reductase (DHFR) domain whose stability is dependent on the small molecule, trimethoprim (TMP).MethodsWe intravitreally injected wild-type C57BL6/J mice with an adeno-associated vector (rAAV2/2[MAX]) constitutively expressing separate fluorescent reporters: DHFR fused to yellow fluorescent protein (DHFR.YFP) and mCherry. TMP or vehicle was administered to mice via oral gavage, drinking water, or eye drops. Ocular TMP levels post treatment were quantified by LC-MS/MS. Protein abundance was measured by fundus fluorescence imaging and western blotting. Visual acuity, response to light stimulus, retinal structure, and gene expression were evaluated after long-term (3 months) TMP treatment.ResultsWithout TMP, DHFR.YFP was efficiently degraded in the retina. TMP achieved ocular concentrations of ∼13.6 μM (oral gavage), ∼331 nM (drinking water), and ∼636 nM (eye drops). Oral gavage and TMP eye drops stabilized DHFR.YFP as quickly as 6 hours, whereas continuous TMP drinking water could stabilize DHFR.YFP for ≥3 months. Stabilization was completely and repeatedly reversible following removal/addition of TMP in all regimens. Long-term TMP treatment had no impact on retina function/structure and had no effect on >99.9% of tested genes.ConclusionsThis DHFR-based conditional system is a rapid, efficient, and reversible tool to effectively control protein expression in the retina.

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Non-antibiotic Small-Molecule Regulation of DHFR-Based Destabilizing Domains In Vivo

Peng

Chau

Phetsang

et al. 2019

Molecular Therapy - Methods & Clinical Development

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The E. coli dihydrofolate reductase (DHFR) destabilizing domain (DD), which shows promise as a biologic tool and potential gene therapy approach, can be utilized to achieve spatial and temporal control of protein abundance in vivo simply by administration of its stabilizing ligand, the routinely prescribed antibiotic trimethoprim (TMP). However, chronic TMP use drives development of antibiotic resistance (increasing likelihood of subsequent infections) and disrupts the gut microbiota (linked to autoimmune and neurodegenerative diseases), tempering translational excitement of this approach in model systems and for treating human diseases. Herein, we identified a TMP-based, non-antibiotic small molecule, termed 14a (MCC8529), and tested its ability to control multiple DHFRbased reporters and signaling proteins. We found that 14a is non-toxic and can effectively stabilize DHFR DDs expressed in mammalian cells. Furthermore, 14a crosses the blood-retinal barrier and stabilizes DHFR DDs expressed in the mouse eye with kinetics comparable to that of TMP (%6 h). Surprisingly, 14a stabilized a DHFR DD in the liver significantly better than TMP did, while having no effect on the mouse gut microbiota. Our results suggest that alternative small-molecule DHFR DD stabilizers (such as 14a) may be ideal substitutes for TMP in instances when conditional, non-antibiotic control of protein abundance is desired in the eye and beyond.

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Fibulin-3 knockout mice demonstrate corneal dysfunction but maintain normal retinal integrity

et al. 2020

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Fibulin-3 (F3) is an extracellular matrix glycoprotein found in basement membranes across the body. An autosomal dominant R345W mutation in F3 causes a macular dystrophy resembling dry age-related macular degeneration (AMD), whereas genetic removal of wild-type (WT) F3 protects mice from sub-retinal pigment epithelium (RPE) deposit formation. These observations suggest that F3 is a protein which can regulate pathogenic sub-RPE deposit formation in the eye. Yet the precise role of WT F3 within the eye is still largely unknown. We found that F3 is expressed throughout the mouse eye (cornea, trabecular meshwork (TM) ring, neural retina, RPE/choroid, and optic nerve). We next performed a thorough structural and functional characterization of each of these tissues in WT and homozygous (F3−/−) knockout mice. The corneal stroma in F3−/− mice progressively thins beginning at 2 months, and the development of corneal opacity and vascularization starts at 9 months, which worsens with age. However, in all other tissues (TM, neural retina, RPE, and optic nerve), gross structural anatomy and functionality were similar across WT and F3−/− mice when evaluated using SD-OCT, histological analyses, electron microscopy, scotopic electroretinogram, optokinetic response, and axonal anterograde transport. The lack of noticeable retinal abnormalities in F3−/− mice was confirmed in a human patient with biallelic loss-of-function mutations in F3. These data suggest that (i) F3 is important for maintaining the structural integrity of the cornea, (ii) absence of F3 does not affect the structure or function of any other ocular tissue in which it is expressed, and (iii) targeted silencing of F3 in the retina and/or RPE will likely be well-tolerated, serving as a safe therapeutic strategy for reducing sub-RPE deposit formation in disease.

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Utility of the DHFR-based destabilizing domain across mouse models of retinal degeneration and aging

et al. 2022

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Sufficient Activity of the Ubiquitin Proteasome System in Aged Mice and During Retinal Degeneration Supports DHFR-Based Conditional Control of Protein Abundance in the Retina

Peng

Ramadurgum²,

Woodard³

et al. 2021

Preprint

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The Escherichia coli dihydrofolate reductase (DHFR) destabilizing domain (DD) serves as a promising approach to conditionally regulate protein abundance in a variety of tissues. In the absence of TMP, a DHFR stabilizer, the DD is degraded by the ubiquitin proteasome system (UPS). To test whether this approach could be effectively applied to a wide variety of aged and disease-related ocular mouse models, which may have a compromised UPS, we evaluated the DHFR DD system in aged mice (up to 24 mo), a light-induced retinal degeneration (LIRD) model, and two genetic models of retinal degeneration (rd2 and Abca4-/- mice). Aged, LIRD, and Abca4-/- mice all had similar proteasomal activities and high-molecular weight ubiquitin levels compared to control mice. However, rd2 mice displayed compromised chymotrypsin activity compared to control mice. Nonetheless, the DHFR DD was effectively degraded in all model systems, including rd2 mice. Moreover, TMP increased DHFR DD-dependent retinal bioluminescence in all mouse models, however the fold induction was slightly, albeit significantly, lower in Abca4-/- mice. Thus, the destabilized DHFR DD-based approach allows for efficient control of protein abundance in aged mice and retinal degeneration mouse models, laying the foundation to use this strategy in a wide variety of mice for the conditional control of gene therapies to potentially treat multiple eye diseases.

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Marian Renwick

A Destabilizing Domain Allows for Fast, Noninvasive, Conditional Control of Protein Abundance in the Mouse Eye – Implications for Ocular Gene Therapy

Non-antibiotic Small-Molecule Regulation of DHFR-Based Destabilizing Domains In Vivo

Fibulin-3 knockout mice demonstrate corneal dysfunction but maintain normal retinal integrity

Utility of the DHFR-based destabilizing domain across mouse models of retinal degeneration and aging

Sufficient Activity of the Ubiquitin Proteasome System in Aged Mice and During Retinal Degeneration Supports DHFR-Based Conditional Control of Protein Abundance in the Retina

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