T.J. McFarland

Non-Invasive Stem Cell Therapy in a Rat Model for Retinal Degeneration and Vascular Pathology

Background Retinitis pigmentosa (RP) is characterized by progressive night blindness, visual field loss, altered vascular permeability and loss of central vision. Currently there is no effective treatment available except gene replacement therapy has shown promise in a few patients with specific gene defects. There is an urgent need to develop therapies that offer generic neuro-and vascular-protective effects with non-invasive intervention. Here we explored the potential of systemic administration of pluripotent bone marrow-derived mesenchymal stem cells (MSCs) to rescue vision and associated vascular pathology in the Royal College Surgeons (RCS) rat, a well-established animal model for RP. Methodology/Principal Findings Animals received syngeneic MSCs (1×106 cells) by tail vein at an age before major photoreceptor loss. Principal results: both rod and cone photoreceptors were preserved (5–6 cells thick) at the time when control animal has a single layer of photoreceptors remained; Visual function was significantly preserved compared with controls as determined by visual acuity and luminance threshold recording from the superior colliculus; The number of pathological vascular complexes (abnormal vessels associated with migrating pigment epithelium cells) and area of vascular leakage that would ordinarily develop were dramatically reduced; Semi-quantitative RT-PCR analysis indicated there was upregulation of growth factors and immunohistochemistry revealed that there was an increase in neurotrophic factors within eyes of animals that received MSCs. Conclusions/Significance These results underscore the potential application of MSCs in treating retinal degeneration. The advantages of this non-invasive cell-based therapy are: cells are easily isolated and can be expanded in large quantity for autologous graft; hypoimmunogenic nature as allogeneic donors; less controversial in nature than other stem cells; can be readministered with minor discomfort. Therefore, MSCs may prove to be the ideal cell source for auto-cell therapy for retinal degeneration and other ocular vascular diseases.

Subretinal Transplantation of Forebrain Progenitor Cells in Nonhuman Primates: Survival and Intact Retinal Function

PURPOSE Cell-based therapy rescues retinal structure and function in rodent models of retinal disease, but translation to clinical practice will require more information about the consequences of transplantation in an eye closely resembling the human eye. The authors explored donor cell behavior using human cortical neural progenitor cells (hNPC(ctx)) introduced into the subretinal space of normal rhesus macaques. METHODS hNPC(ctx) transduced with green fluorescent protein (hNPC(ctx)-GFP) were delivered bilaterally into the subretinal space of six normal adult rhesus macaques under conditions paralleling those of the human operating room. Outcome measures included clinical parameters of surgical success, multifocal electroretinogram (mfERG), and histopathologic analyses performed between 3 and 39 days after engraftment. To test the effects of GFP transduction on cell bioactivity, hNPC(ctx)-GFP from the same batch were also injected into Royal College of Surgeons (RCS) rats and compared with nonlabeled hNPC(ctx). RESULTS Studies using RCS rats indicated that GFP transduction did not alter the ability of the cells to rescue vision. After cells were introduced into the monkey subretinal space by a pars plana transvitreal approach, the resultant detachment was rapidly resolved, and retinal function showed little or no disturbance in mfERG recordings. Retinal structure was unaffected and no signs of inflammation or rejection were seen. Donor cells survived as a single layer in the subretinal space, and no cells migrated into the inner retina. CONCLUSIONS Human neural progenitor cells can be introduced into a primate eye without complication using an approach that would be suitable for extrapolation to human patients.

Natural History and Histology in a Rat Model of Laser-Induced Photothrombotic Retinal Vein Occlusion

Purpose: To observe temporal changes in retinal physiology and histology in a rat model of laser-induced retinal vein occlusion (RVO). Methods: Ophthalmoscopy, fundus photography, and fluorescein angiography (FA) were performed following laser-induced central retinal vein occlusion (CRVO) and branch retinal vein occlusion (BRVO) immediately after laser treatment and at 3 and 6 hr and 2, 4, 7, 14, and 21 days. Retinal histology was examined at 4, 7, 14, and 21 days. Full-field electroretinogram was recorded from both eyes simultaneously at day 4. Results: For CRVO and BRVO, reperfusion of occluded branch veins was observed 1 to 2 days after treatment. Despite complete reperfusion of branch veins, retinal edema and hemorrhages peaked on day 4, and by day 14, treated retinas appeared pale and edematous upon ophthalmoscopy. In BRVO animals, retinal hemorrhages were limited to the vein-occluded region, although edema was more widespread and, to a limited extent, involved the untreated hemi-retina. Significant GCL cell loss was observed in both CRVO and BRVO groups after day 14. Regional analysis showed that relative GCL loss was greatest in the peripheral retina in BRVO group. Electroretinography disclosed moderate to severe functional deficits in photoreceptors, bipolar, and amacrine and ganglion cells. Conclusion: Laser-induced RVO in rats results in targeted vascular occlusion that persisted for 1 to 2 days. Functional deficits were evident and significant GCL cell loss was seen, notably within peripheral retina of the BRVO model. This reproducible model provides a valuable tool for the study of the molecular events associated with retinal ischemia and cell death.

Gene therapy for proliferative ocular diseases

Proliferative ocular diseases encompass a wide variety of pathological processes with adverse cellular differentiation, proliferation and migration as common features. Pathologies may involve neovascular responses associated with diabetic retinopathy, retinopathy of prematurity or age-related macular degeneration. These diseases are quite prevalent and account for substantial visual impairment and blindness worldwide. Although treatment strategies are largely surgical, advances in our understanding of the proteins crucial to cell transdifferentiation, proliferation and migration, along with better gene transfer techniques, have greatly increased the potential for biological treatment options. In this report, the most common proliferative ocular vascular diseases and existing therapeutic modalities will be reviewed and an overview of possible gene therapy options will be discussed, along with potential candidate genes.

Recombinant Filaggrin Is Internalized and Processed to Correct Filaggrin Deficiency

This study was designed to engineer a functional filaggrin (FLG) monomer linked to a cell-penetrating peptide (RMR) and to test the ability of this peptide to penetrate epidermal tissue as a therapeutic strategy for genetically determined atopic dermatitis (AD). A single repeat of the murine filaggrin gene (Flg) was covalently linked to a RMR motif and cloned into a bacterial expression system for protein production. Purified FLG+RMR (mFLG+RMR) was applied in vitro to HEK-293T cells and a reconstructed human epidermis (RHE) tissue model. Immunochemistry demonstrated RMR-dependent cellular uptake of FLG+RMR in a dose- and time-dependent manner in HEK cells. Immunohistochemical staining of the RHE model identified penetration of FLG+RMR to the stratum granulosum, the epidermal layer at which FLG deficiency is thought to be pathologically relevant. In vivo application of FLG+RMR to FLG-deficient flaky tail (ft/ft) mice skin demonstrated internalization and processing of recombinant FLG+RMR to restore the normal phenotype. These results suggest that topically applied RMR-linked FLG monomers are able to penetrate epidermal tissue, be internalized into the appropriate cell type, and be processed to a size similar to wild-type functional barrier peptides to restore necessary barrier function, and prove to be therapeutic for patients with AD.

BEVACIZUMAB LEVELS IN BREAST MILK AFTER LONG-TERM INTRAVITREAL INJECTIONS.

Purpose: The purpose of this study is to determine whether bevacizumab is detectable in the breast milk of nursing mothers. Methods: Breast milk samples were collected from 2 patients receiving monthly intravitreal bevacizumab injections for choroidal neovascularization over the course of 16 months. Enzyme-linked immunosorbent assay and Western blot analysis was used to determine the levels of bevacizumab in the milk samples. Results: An enzyme-linked immunosorbent assay was developed using antibodies specific to bevacizumab in which the sensitivity threshold was 3 ng/mL. All breast milk samples assayed from the two patients actively undergoing treatment did not have detectable levels of bevacizumab. Samples collected 1.5 hours and 7 hours after an injection and 2 randomly chosen samples were negative by Western blot analysis. Conclusion: A sensitive assay to detect bevacizumab in breast milk samples assayed suggests that intravitreal injections do not result in detectable bevacizumab in breast milk.

Analysis of extracellular RNA in cerebrospinal fluid

ABSTRACT We examined the extracellular vesicle (EV) and RNA composition of pooled normal cerebrospinal fluid (CSF) samples and CSF from five major neurological disorders: Alzheimer’s disease (AD), Parkinson’s disease (PD), low-grade glioma (LGG), glioblastoma multiforme (GBM), and subarachnoid haemorrhage (SAH), representing neurodegenerative disease, cancer, and severe acute brain injury. We evaluated: (I) size and quantity of EVs by nanoparticle tracking analysis (NTA) and vesicle flow cytometry (VFC), (II) RNA yield and purity using four RNA isolation kits, (III) replication of RNA yields within and between laboratories, and (IV) composition of total and EV RNAs by reverse transcription–quantitative polymerase chain reaction (RT-qPCR) and RNA sequencing (RNASeq). The CSF contained ~106 EVs/μL by NTA and VFC. Brain tumour and SAH CSF contained more EVs and RNA relative to normal, AD, and PD. RT-qPCR and RNASeq identified disease-related populations of microRNAs and messenger RNAs (mRNAs) relative to normal CSF, in both total and EV fractions. This work presents relevant measures selected to inform the design of subsequent replicative CSF studies. The range of neurological diseases highlights variations in total and EV RNA content due to disease or collection site, revealing critical considerations guiding the selection of appropriate approaches and controls for CSF studies.

The Related Transcriptional Enhancer Factor-1 Isoform, TEAD4216, Can Repress Vascular Endothelial Growth Factor Expression in Mammalian Cells

Increased cellular production of vascular endothelial growth factor (VEGF) is responsible for the development and progression of multiple cancers and other neovascular conditions, and therapies targeting post-translational VEGF products are used in the treatment of these diseases. Development of methods to control and modify the transcription of the VEGF gene is an alternative approach that may have therapeutic potential. We have previously shown that isoforms of the transcriptional enhancer factor 1-related (TEAD4) protein can enhance the production of VEGF. In this study we describe a new TEAD4 isoform, TEAD4216, which represses VEGF promoter activity. The TEAD4216 isoform inhibits human VEGF promoter activity and does not require the presence of the hypoxia responsive element (HRE), which is the sequence critical to hypoxia inducible factor (HIF)-mediated effects. The TEAD4216 protein is localized to the cytoplasm, whereas the enhancer isoforms are found within the nucleus. The TEAD4216 isoform can competitively repress the stimulatory activity of the TEAD4434 and TEAD4148 enhancers. Synthesis of the native VEGF165 protein and cellular proliferation is suppressed by the TEAD4216 isoform. Mutational analysis indicates that nuclear or cytoplasmic localization of any isoform determines whether it acts as an enhancer or repressor, respectively. The TEAD4216 isoform appears to inhibit VEGF production independently of the HRE required activity by HIF, suggesting that this alternatively spliced isoform of TEAD4 may provide a novel approach to treat VEGF-dependent diseases.

31. EncorStat®: A Human Donor Cornea Genetically Engineered To Resist Rejection in High Risk Patients

Corneal transplantation is one of the most successful transplant procedures because of the relatively immune-privileged status of the eye and the avascularity of the cornea. However, normal corneal immune privilege can be eroded by neovascularization by providing a route of entry for immune-mediating cells, leading to subsequent irreversible immunological rejection of the corneal graft, the most common reason for graft failure. In high risk patients, which account for >20% of the 100,000 transplants carried out worldwide each year, the rejection rate can be very high (50-90%), particularly if there is pre-existing vascularization of the recipient corneal bed. In these patients the prognosis is extremely poor, with grafts failing at an accelerating rate to the point where patients are no longer considered suitable for further transplants and are left blind, despite an otherwise healthy eye. It is therefore not surprising that neovascularization (both pre- and post-grafting) is a significant risk factor for corneal graft failure. Neovascularization is thus an attractive target to prevent corneal graft failure due to rejection.EncorStat® is a human donor cornea modified prior to transplant by the ex vivo delivery of the genes encoding secretable forms of the angiostatic human proteins, endostatin and angiostatin, by a lentiviral vector, derived from the Equine Infectious Anaemia Virus (EIAV), which prevents subsequent rejection by suppressing neovascularization.Modified rabbit corneas have been evaluated in two different models of corneal graft rejection, a highly aggressive model in which rejection is driven by the retention of thick graft sutures, and a less aggressive model in which rejection is driven by pre-vascularizing the recipient corneal bed prior to surgery. In this latter model thin sutures are used to secure the graft that are removed two weeks following surgery, which is more analogous to the clinical setting. The process to generate EncorStat® corneas has been optimized to secrete substantial and persistent levels of angiostatic proteins with very little shedding of residual vector. These corneas substantially suppress corneal neovascularization, opacity and subsequent rejection in both rabbit models of cornea graft rejection.The non-clinical data to be presented support the evaluation of EncorStat® corneas in a First-in-Man trial. With support from the UK Technology Strategy Board (Innovate UK), this trial will be conducted in 2016, following completion of non-clinical safety studies and GMP vector manufacture this year. An outline of this clinical trial design will also be presented.

Angiogenic Gene Therapy for the Treatment of Retinopathies

In the past decade, advances in vector design and delivery have helped guide gene therapy technologies from the laboratory to clinical trials. These technologies are poised to tackle a key problem in opthalmology: pathologic angiogenesis. Gene transfer techonologies offer the potential for highly regulated and sustained delivery of a therapeutic agent, and may have the potential to arrest a pathological process prior to the evolution of a soluble angiogenic factor. Multiple biologic effectors of agiogenesis have been investigated as potential therapeutic targets, including Vascular endothelial cell growth factor (VEGF) and the VEGF receptor, angiopoietin 1 and 2, tissue inhibitor of matrix metalloproteinases-3 (Timp-3), angiostatin, Pigment Epithelial-Derived Factor (PEDF), and endostatin. Data from experimental models in these systems has been encouraging, and the experience gained from ongoing ocular gene therapy trials in non-angiogenic disease will be instructive. In the first human angiogenic gene therapy trial for a neovascular retinopathy, PEDF expressed in an adenoviral vector demonstrated a reasonable safety profile and proof of concept. Cell-based and siRNA technologies are also under clinical investigation, and, together with gene therapy, may provide breakthrough treatments for diseases that cause much of the world’s blindness.