Project description:The cornea is the transparent tissue covering the anterior part of the eye. Its main roles are to convey the light toward the retina, and to act as a protective barrier against infection or injury for the eye. The transparency of the cornea is a crucial component of its functionality and is the result of specific architecture and cell arrangements. The inner layer of the cornea is the endothelium, composed of a monolayer of endothelial cells. The next layer is the stroma, representing about two third of the thickness of the cornea, and is mainly composed of a specifically arranged extracellular matrix, secreted by few keratocytes1–4. Finally, the external layer is a life-long renewed pluristratified epithelium. The regulated epithelial homeostasis, crucial to maintain the corneal transparency, relies on stem and progenitor cells5. To coordinate epithelial homeostasis and healing, and to adequately respond to any change in the corneal environment, this tissue is highly innervated6,7. The corneal innervation is mainly composed of A and C sensory fibres whose cell bodies are located in the ophthalmic branch of the trigeminal ganglion8. Those fibres penetrate the corneal stroma from the periphery, as bundles of fibres branching and spreading within the stroma9. When entering in the epithelium, the fibres branche again and radiate horizontally to form the subbasal plexus. Finally, the sensory fibres shift orientation to reach the top of the epithelium, where they end up as free nerve endings6,7. There are three classes of fibres innervating the cornea: the mechano-nociceptors, the cold sensing neurons and the polymodal nociceptors, reacting respectively to mechanical, thermal and chemical stimuli10,11. Stimuli transduction is not the only role of the corneal innervation, as these fibres have a crucial role on epithelial homeostasis through the secretion of trophic factors essential for epithelial cell survival12. Due to its localization, the cornea is highly exposed to ultraviolet radiation and high oxygen tension, making it particularly vulnerable to mitochondrial defects13. These defects can be either inherited or non-inherited. Inherited forms result from mutations in mitochondrial DNA (mtDNA) or nuclear gene defects affecting mitochondrial function14. Inherited mitochondrial dysfunction is a key factor in the progression of Fuchs endothelial corneal dystrophy (FECD) and keratoconus13,15,16. Non-inherited mitochondrial dysfunction, on the other hand, can occur due to spontaneous mtDNA mutations or somatic mutations that accumulate with age, rendering the mitochondrial metabolism less efficient with time17. To date, the impact of inherited mitochondrial dysfunctions on corneal epithelium physiology has not been extensively studied. Case reports have linked mitochondrial diseases to corneal cloudiness18,19, perforation20 and edema21. Furthermore, mitochondrial defect was associated to inflammatory context and ROS production in ocular surface pathologies13,22. Despite these studies, the direct effect of mitochondrial disfunction on corneal biology remains elusive. Among the known pathologies originating from an inherited mitochondrial dysfunction, the dominant optic atrophy (DOA) is an inherited blinding disease caused by the degenescence of the retinal cell ganglions forming the optic nerve23. The mutation of the gene OPA1 is responsible for the majority of the DOA diagnostics. OPA1 gene encodes for a mitochondrial protein involved in the fusion process and is essential to maintain the organelle integrity. Generally, optic neuropathy is the characteristic syndrome for DOA, but a subset of patients, called dominant optic atrophy plus (DOA+), also declare extra-ocular syndromes such as ataxia, deafness and peripheral neuropathies24,25. A mouse model, bearing the OPA1delTTAG mutation, recapitulates the degenerative syndromes encountered in DOA+ patients25.. While DOA is associated with lens cloudiness, no report has linked DOA to ocular surface defects. Here, we investigated the impact of OPA1 delTTAG mutation on mouse cornea as its structure includes a large amout of sensory fibres that are crucial to maintain corneal homeostasis.

Project description:Regulation of quiescence is essential for adult stem cell maintenance, longevity and sustained regeneration potential. Our studies have uncovered that physiological and transient changes in mitochondrial shape regulate the quiescent state of adult muscle stem cells (MuSCs). We show that mitochondria in MuSCs rapidly fragment in response to an activation stimulus, via a systemic HGF/mTOR mechanism, to drive the exit from deep quiescence. Deletion of the mitochondrial fusion protein OPA1 and forced mitochondrial fragmentation is sufficient to transition MuSCs into G-alert quiescence causing premature activation and depletion upon a stimulus. Loss of OPA1 activates a glutathione (GSH) redox signaling pathway that promotes cell-cycle progression, myogenic gene expression and commitment. MuSCs with chronic OPA1 loss and mitochondrial fragmentation, leading to mitochondrial dysfunction, continue to reside in a primed state but acquire severe cell cycle defects. Additionally, we provide evidence that OPA1 decline and impaired mitochondrial dynamics may contribute to age-related MuSC dysfunction. These findings reveal a fundamental role for OPA1 and mitochondrial dynamics in establishing the quiescent state and activation potential of adult stem cells.

Project description:Inherited mitochondrial dysfunction triggered by OPA1 mutation impacts the sensory innervation fibre identity, functionality and regenerative potential in the cornea

Project description:Mitochondria are critical for metabolic homeostasis of the liver, and thus, mitochondrial dysfunction is a major cause of liver diseases. Optic atrophy 1 (OPA1) is a mitochondrial fusion protein that also plays a role in cristae shaping. Hence, the OPA1 gene disruption has been shown to cause mitochondrial dysfunction. However, the role of OPA1 in liver function is poorly understood. In this study, we deleted OPA1 in fully developed mouse liver and examined its effect.

Project description:Characteristic structural details of the cornea are transparency, the absence of blood vessels, and the presence of numerous sensory nerve endings. The corneal epithelium is one of the most densely innervated tissues of the body. The characteristics of the cornea are established during fetal development, and are lost in adult life when the cornea regenerates after injury. The common reaction of the cornea to injury is the formation of opaque scars, the ingrowth of blood vessels, and distinct changes in the innervation pattern. Scar formation of the cornea is critically modulated by the expression of transforming growth factor-beta (TGF-beta). To identify genes that are important for corneal transparency, dense innervation and absence of blood vessels by comparing corneas from wildtype mice with those that are under the influence of high doses of TGF-beta. Transparency, dense innervation, and absence of blood vessels in the cornea all depend on the expression of a critical set of genes that are not expressed when TGF-beta is present. Mice were generated that overexpress TGF-beta under control of a strong lens-specific promoter. These mice developed opaque corneas that are vascularized and lack sensory nerves. In addition, these corneas were densely populated with cells expressing neural cell adhesion protein. RNA was isolated from corneas of transgenic animals and wildtype littermates in order to analyze differentially expressed genes and to identify those that are only expressed in transparent, avascular, and densely innervated wildtype corneas.

Project description:OPA1, a mitochondria-shaping protein controlling cristae biogenesis and respiration, is required for memory T cell function, but whether it affects intrathymic T cell development is unknown. Here we show that OPA1 is necessary for thymocyte maturation at the double negative (DN)3 stage when rearrangement of the T-cell receptor β (Tcrβ) locus occurs. By profiling mitochondrial function at different stages of thymocyte maturation, we find that DN3 cells rely on oxidative phosphorylation (OXPHOS). Consistently, Opa1 deletion during early T cell development impairs respiration of DN3 cells and reduces their number. Opa1-deficient DN3 cells indeed display stronger TCR signaling and are more prone to cell death. The surviving Opa1-/- thymocytes that reach the periphery as mature T cells display an Effector Memory phenotype even in the absence of antigenic stimulation but are unable to generate metabolically fit long-term memory T cells. Thus, mitochondrial defects early during T cell development affect mature T cell function.

Project description:OPA1 is a dynamin-related GTPase that plays a critial role in governing mitochondrial fusion, cristae structure, and energetics. Here we found that OPA1 functions as a postive regulator of a nonapoptotic form of cell death termed ferroptosis. Although we determined that the OPA1 GTPase activity is required to drive ferroptosis, the fusogenic activity of OPA1 is dispensable for ferroptosis execution. Mechanistically, our studies show that OPA1 promotes ferroptosis through distinct mechanisms involving the generation of mitochondrial reactive oxygen species and suppression of the integrated stress response.

Project description:Mitochondrial fusion and fission accompany adaptive responses to stress and altered metabolic demands. Inner membrane fusion and cristae morphogenesis depends on Optic Atrophy 1 (Opa1), which is expressed in different isoforms and is cleaved from a membrane-bound, long to a soluble, short form. Here, we have analyzed the physiological role of Opa1 isoforms and Opa1 processing by generating mouse lines expressing only one cleavable Opa1 isoform or a non-cleavable variant thereof. Our results show that expression of a single cleavable or non-cleavable Opa1 isoform preserves embryonic development and the health of adult mice. Opa1 processing is dispensable under metabolic and thermal stress, but prolongs lifespan and protects against mitochondrial cardiomyopathy in OXPHOS-deficient Cox10-/- mice. Mechanistically, loss of Opa1 processing disturbs the balance between mitochondrial biogenesis and mitophagy, suppressing cardiac hypertrophic growth in Cox10-/- hearts. Our results highlight the critical regulatory role of Opa1 processing, mitochondrial dynamics and metabolism for cardiac hypertrophy.

Project description:Characteristic structural details of the cornea are transparency, the absence of blood vessels, and the presence of numerous sensory nerve endings. The corneal epithelium is one of the most densely innervated tissues of the body. The characteristics of the cornea are established during fetal development, and are lost in adult life when the cornea regenerates after injury. The common reaction of the cornea to injury is the formation of opaque scars, the ingrowth of blood vessels, and distinct changes in the innervation pattern. Scar formation of the cornea is critically modulated by the expression of transforming growth factor-beta (TGF-beta). To identify genes that are important for corneal transparency, dense innervation and absence of blood vessels by comparing corneas from wildtype mice with those that are under the influence of high doses of TGF-beta. Transparency, dense innervation, and absence of blood vessels in the cornea all depend on the expression of a critical set of genes that are not expressed when TGF-beta is present. Mice were generated that overexpress TGF-beta under control of a strong lens-specific promoter. These mice developed opaque corneas that are vascularized and lack sensory nerves. In addition, these corneas were densely populated with cells expressing neural cell adhesion protein. RNA was isolated from corneas of transgenic animals and wildtype littermates in order to analyze differentially expressed genes and to identify those that are only expressed in transparent, avascular, and densely innervated wildtype corneas. Keywords: TGF-beta overexpression

Project description:We have generated human induced Pluripotent Stem cells (hiPSc) from two individuals with OPA1 haploinsufficiency, and one control donor, using Sendai virus-mediated delivery of reprogramming factors. hiPSc lines have been screened using SNP array to assess chromosomal stability (alongside the fibroblast lines from which they derived), and validation of the pluripotency of the hiPSc lines is provided by Pluritest assessment of transcriptome datasets, prior to differentiation to dopaminergic neuronal clutures and downstream functional assays. Mitochondrial fragmentation in iPSC-derived dopaminergic neurons with OPA1 haploinsufficiency underpins increased apoptosis and syndromic Parkinsonism.