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3. Characterization of an eutherian gene cluster generated after transposon domestication identifies Bex3 as relevant for advanced neurological functions

Author

Navas-Pérez, Enrique, Vicente-García, Cristina, Mirra, Serena, Burguera, Demian, Fernàndez-Castillo, Noèlia, Ferrán, José Luis, López-Mayorga, Macarena, Alaiz-Noya, Marta, Suárez-Pereira, Irene, Antón-Galindo, Ester, Ulloa, Fausto, Herrera-Úbeda, Carlos, Cuscó, Pol, Falcón-Moya, Rafael, Rodríguez-Moreno, Antonio, D’Aniello, Salvatore, Cormand, Bru, Marfany, Gemma, Soriano, Eduardo, Carrión, Ángel M., Carvajal, Jaime J., and Garcia-Fernàndez, Jordi

Published
2020
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4. A mammalian-specific Alex3/Gαq protein complex regulates mitochondrial trafficking, dendritic complexity, and neuronal survival.

Author

Izquierdo-Villalba, Ismael, Mirra, Serena, Manso, Yasmina, Parcerisas, Antoni, Rubio, Javier, Del Valle, Jaume, Gil-Bea, Francisco J., Ulloa, Fausto, Herrero-Lorenzo, Marina, Verdaguer, Ester, Benincá, Cristiane, Castro-Torres, Rubén D., Rebollo, Elena, Marfany, Gemma, Auladell, Carme, Navarro, Xavier, Enríquez, José A., López de Munain, Adolfo, Soriano, Eduardo, and Aragay, Anna M.

Subjects
AMPA receptors, MOLECULAR motor proteins, MITOCHONDRIAL proteins, G protein coupled receptors, MITOCHONDRIA, HEAT shock proteins, MOTOR neurons, WNT signal transduction
Abstract

Mitochondrial dynamics and trafficking are essential to provide the energy required for neurotransmission and neural activity. We investigated how G protein–coupled receptors (GPCRs) and G proteins control mitochondrial dynamics and trafficking. The activation of Gαq inhibited mitochondrial trafficking in neurons through a mechanism that was independent of the canonical downstream PLCβ pathway. Mitoproteome analysis revealed that Gαq interacted with the Eutherian-specific mitochondrial protein armadillo repeat–containing X-linked protein 3 (Alex3) and the Miro1/Trak2 complex, which acts as an adaptor for motor proteins involved in mitochondrial trafficking along dendrites and axons. By generating a CNS-specific Alex3 knockout mouse line, we demonstrated that Alex3 was required for the effects of Gαq on mitochondrial trafficking and dendritic growth in neurons. Alex3-deficient mice had altered amounts of ER stress response proteins, increased neuronal death, motor neuron loss, and severe motor deficits. These data revealed a mammalian-specific Alex3/Gαq mitochondrial complex, which enables control of mitochondrial trafficking and neuronal death by GPCRs. Editor's summary: The elongated morphology of neurons means that mitochondria must be trafficked over long distances to support energy-intensive processes in multiple subcellular compartments. Izquierdo-Villalba et al. found that mitochondrial trafficking in neurons required the interaction of the G protein Gαq with the mitochondrial protein Alex3. Gαq enhanced the binding of Alex3 to mitochondrial trafficking proteins that mediate anterograde traffic. Expression of a constitutively active form of Gαq in neurons from mice with a CNS-specific deficiency in Alex3 revealed that Gαq was necessary for the role of Alex3 in mitochondrial trafficking and distribution and dendritic arborization. These results raise the intriguing possibility that the activity of Gαq-coupled receptors can affect mitochondrial trafficking in neurons through the Gαq/Alex3 complex. —Wei Wong [ABSTRACT FROM AUTHOR]

Published
2024
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5. From Beach to the Bedside: Harnessing Mitochondrial Function in Human Diseases Using New Marine-Derived Strategies.

Author

Mirra, Serena and Marfany, Gemma

Subjects
*CELL physiology, *EUKARYOTIC cells, *MITOCHONDRIA, *MARINE natural products, *MARINE ecology, *HOMEOSTASIS, *NEURODEGENERATION, *MARINE biodiversity
Abstract

Mitochondria are double-membrane organelles within eukaryotic cells that act as cellular power houses owing to their ability to efficiently generate the ATP required to sustain normal cell function. Also, they represent a "hub" for the regulation of a plethora of processes, including cellular homeostasis, metabolism, the defense against oxidative stress, and cell death. Mitochondrial dysfunctions are associated with a wide range of human diseases with complex pathologies, including metabolic diseases, neurodegenerative disorders, and cancer. Therefore, regulating dysfunctional mitochondria represents a pivotal therapeutic opportunity in biomedicine. Marine ecosystems are biologically very diversified and harbor a broad range of organisms, providing both novel bioactive substances and molecules with meaningful biomedical and pharmacological applications. Recently, many mitochondria-targeting marine-derived molecules have been described to regulate mitochondrial biology, thus exerting therapeutic effects by inhibiting mitochondrial abnormalities, both in vitro and in vivo, through different mechanisms of action. Here, we review different strategies that are derived from marine organisms which modulate specific mitochondrial processes or mitochondrial molecular pathways and ultimately aim to find key molecules to treat a wide range of human diseases characterized by impaired mitochondrial function. [ABSTRACT FROM AUTHOR]

Published
2024
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7. CERKL , a Retinal Dystrophy Gene, Regulates Mitochondrial Transport and Dynamics in Hippocampal Neurons.

Author

García-Arroyo, Rocío, Marfany, Gemma, and Mirra, Serena

Subjects
RETINAL degeneration, MITOCHONDRIA, CENTRAL nervous system, HIPPOCAMPUS (Brain), NEURONS, RETINA
Abstract

Mutations in the Ceramide Kinase-like (CERKL) gene cause retinal dystrophies, characterized by progressive degeneration of retinal neurons, which eventually lead to vision loss. Among other functions, CERKL is involved in the regulation of autophagy, mitochondrial dynamics, and metabolism in the retina. However, CERKL is nearly ubiquitously expressed, and it has been recently described to play a protective role against brain injury. Here we show that Cerkl is expressed in the hippocampus, and we use mouse hippocampal neurons to explore the impact of either overexpression or depletion of CERKL on mitochondrial trafficking and dynamics along axons. We describe that a pool of CERKL localizes at mitochondria in hippocampal axons. Importantly, the depletion of CERKL in the CerklKD/KO mouse model is associated with changes in the expression of fusion/fission molecular regulators, induces mitochondrial fragmentation, and impairs axonal mitochondrial trafficking. Our findings highlight the role of CERKL, a retinal dystrophy gene, in the regulation of mitochondrial health and homeostasis in central nervous system anatomic structures other than the retina. [ABSTRACT FROM AUTHOR]

Published
2022
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8. Ubiquitin Specific Protease USP48 Destabilizes NF-κB/p65 in Retinal Pigment Epithelium Cells.

Author

Mirra, Serena, Sánchez-Bellver, Laura, Casale, Carmela, Pescatore, Alessandra, and Marfany, Gemma

Subjects
*DEUBIQUITINATING enzymes, *RHODOPSIN, *MACULAR degeneration, *CHROMATOPHORES, *TUMOR necrosis factors, *TRANSCRIPTION factors
Abstract

Activation of NF-κB transcription factor is strictly regulated to accurately direct cellular processes including inflammation, immunity, and cell survival. In the retina, the modulation of the NF-κB pathway is essential to prevent excessive inflammatory responses, which plays a pivotal role in many retinal neurodegenerative diseases, such as age-related macular degeneration (AMD), diabetic retinopathy (DR), and inherited retinal dystrophies (IRDs). A critical cytokine mediating inflammatory responses in retinal cells is tumor necrosis factor-alpha (TNFα), leading to the activation of several transductional pathways, including NF-κB. However, the multiple factors orchestrating the appropriate regulation of NF-κB in retinal cells still remain unclear. The present study explores how the ubiquitin-specific protease 48 (USP48) downregulation impacts the stability and transcriptional activity of NF-κB/p65 in retinal pigment epithelium (RPE), at both basal conditions and following TNFα stimulation. We described that USP48 downregulation stabilizes p65. Notably, the accumulation of p65 is mainly detectable in the nuclear compartment and it is accompanied by an increased NF-κB transcriptional activity. These results delineate a novel role of USP48 in negatively regulating NF-κB in retinal cells, providing new opportunities for therapeutic intervention in retinal pathologies. [ABSTRACT FROM AUTHOR]

Published
2022
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10. Mitochondrial gymnastics in retinal cells: a resilience mechanism against oxidative stress and neurodegeneration

Author

Mirra, Serena and Marfany i Nadal, Gemma

Subjects
Malalties de la retina, Estrès oxidatiu, Diabetic retinopathy, Oxidative stress, Retinopatia diabètica, Retinal diseases
Abstract

Inherited retinal dystrophies (IRDs) are a broad group of neurodegenerative disorders associated with reduced or deteriorating visual system. In the retina, cells are under constant oxidative stress, leading to elevated reactive oxygen species (ROS) generation that induces mitochondrial dysfunction and alteration of the mitochondrial network. This mitochondrial dysfunction combined with mutations in mitochondrial DNA and nuclear genes makes photoreceptors and retinal ganglion cells more susceptible to cell death. In this minireview, we focus on mitochondrial dynamics and their contribution to neuronal degeneration underlying IRDs, with particular attention to Leber hereditary optic neuropathy (LHON) and autosomal dominant optic atrophy (DOA), and propose targeting cell resilience and mitochondrial dynamics modulators as potential therapeutic approaches for retinal disorders.

Published
2019

11. Under pressure: Cerebrospinal fluid contribution to the physiological homeostasis of the eye.

Author

Mirra, Serena, Marfany, Gemma, and Garcia-Fernàndez, Jordi

Subjects
*CEREBROSPINAL fluid, *FLUID pressure, *SUBARACHNOID space, *CEREBRAL ventricles, *CENTRAL nervous system, *LOCUS coeruleus, *CENTRAL nervous system physiology, *HOMEOSTASIS
Abstract

The cerebrospinal fluid (CSF) is a waterly, colorless fluid contained within the brain ventricles and the cranial and spinal subarachnoid spaces. CSF physiological functions range from hydromechanical protection of the central nervous system (CNS) to CNS modulation of developmental processes and regulation of interstitial fluid homeostasis. Optic nerve (ON) is surrounded by CSF circulating in the subarachnoid spaces and is exposed to both CSF (CSFP) and intra ocular (IOP) pressures, which converge at the lamina cribrosa (LC) as two opposite forces. The trans–lamina cribrosa pressure gradient (TLPG) is defined as IOP - CSFP and its alterations (due either to an elevation in IOP or a reduction in ICP) could result in structural damaging of the ON, including glaucomatous changes. The purpose of this review is to update the readers on the CSF contribution in controlling the functions/dysfunctions of ON by regulating homeostasis at LC. We also highlight emerging parallelisms regarding the expression of cilia-related genes in the regulation of common functions of body fluids in both brain and eye structures. [ABSTRACT FROM AUTHOR]

Published
2020
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12. Characterization of the Armcx/Almc10 gene family function in mitochondrial dynamics and neural development

Author

Mirra, Serena, Soriano García, Eduardo, and Universitat de Barcelona. Departament de Biologia Cel·lular

Subjects
Neurobiologia del desenvolupament, Spinal cord, Medul·la espinal, Neurobiología del desarrollo, Developmental neurobiology, Armcx/Armc10, Médula espinal, Mitocondris, Mitocondrias, Ciències Experimentals i Matemàtiques, Mitochondria
Abstract

The Armcx gene cluster arose by retrotransposition from a single Arm-containing gene (Armc10), and by subsequent short-range tandem duplications of a rapidly evolving region of the Eutherian X chromosome. In this work we analysed the expression of Armcx/Armc10 genes during embryonic development, describing their expression in the developing neural tissues. As yet shown for Alex3 protein, Armc10 also causes mitochondrial aggregation and/or tethering in neurons and HEK293 cells. In neurons, these processes are believed to serve to capture mitochondria at specific locations requiring high-energy and Ca2+ buffering conditions. The mechanism by which Alex3 and Armc10 cause mitochondrial aggregation may involve Mitofusins, as they both interact with Mfn1 and Mfn2. Nevertheless, we were unable to find evidence about the involvement of Alex3 protein in mitochondrial fusion. Alex3 and Armc10 interact with the KIF5/Miro/Trak2 complex (which controls mitochondrial dynamics in neurons), through a direct interaction with Miro1-2 and Trak2. Importantly, this interaction requires low Ca2+ concentrations. We suggest that the Ca2+-dependent conformational changes in Miro proteins are the essential mechanisms regulating the interaction between Alex3 and the Miro/Trak2complex. Thus, while low Ca2+ concentrations may favour the formation of KIF5/Miro/Trak2/Alex3 complex, increases in intracellular Ca2+ rapidly uncouple such complex (including Alex3), thereby arresting mitochondrial trafficking. The notion that Alex3 (and possibly also Armc10) interacts with the Miro/Trak2 complex when mitochondria are motile at low Ca2+ concentrations is further supported by our findings that knockdown of Alex3 (such as Armc10) results in a decrease in the percentages of motile mitochondria, similarly to what was observed in Miro/Trak2 loss-of-function. In conclusion, we described Alex3 and Armc10 as proteins with evolutionarily conserved functions in the regulation of mitochondrial dynamics and transport. However, gene-specific particularities are present, suggesting overlapping but differential levels and mechanism of regulation of mitochondrial dynamics and transport by Alex3 and Armc10 proteins and probably by the whole Armcx cluster. We next speculate that Alex3 (but also the whole Armcx cluster) could play a role in regulation of mitochondrial dynamics or function during neural development by regulating Wnt/β-catenin signaling pathway. Using the chicken spinal cord as physiological model, we found that Alex3 overexpression decreases TCF/LEF-transcriptional activity at basal condition and following Wnt3a or β-catenin induction, indicating that Alex3 substantially acts as an inhibitor of canonical Wnt/β-catenin pathway. Moreover, we showed that Alex3 is involved in both negative cell cycle regulation and induction of differentiation in chicken spinal cord, while Armc10 is only involved in negative cell cycle regulation. These differences between Alex3 and Armc10 overexpression effects on spinal cord developmental processes highlight functional divergences between the two proteins, suggesting that Alex3 may have acquired additional function respect to Armc10, phylogenetic ancestor of the whole Armcx gene cluster. The data collected in this study, describing Alex3 overexpression effects on spinal cord development, are coherent with the inhibitor function of Alex3 on Wnt/β-catenin pathway. However there is not sufficient evidence to sustain that these effects on progenitor cell cycle and neuronal differentiation are achieved by inhibition of Wnt/β-catenin pathway and further experiments are required to support this hypothesis. To shade light on the biological processes in which Alex3 can be involved (trough regulation of mitochondrial dynamics, regulation of Wnt/β-catenin pathway or new and different activity) we carried out a genome-wide analysis of changes in mRNA levels subjecting HEK293AD cells stably expressing Alex3GFP to microarray analysis. We found changes in global gene expression that involved key processes of cellular physiology, such as metabolic processes or cell cycle progression. However we are still far to identify the cellular and molecular mechanism by which Alex3 (and the whole Armcx/Armc10 cluster gene) acts in these processes. To achieve this goal it is essential to clarify Armcx/Armc10 function in nervous system development., Los genes Armcx pertenecen a una misma familia localizada en el cromosoma X y caracterizada por la posesión de dominios armadillo en su secuencia proteica. En este trabajo se ha analizado la expresión de los genes Armcx/Armc10 durante el desarrollo embrionario, en los tejidos neurales en desarrollo y en el cerebro adulto. A continuación se ha analizado localización subcellular de las proteínas Armc10 y Alex3 (codificada por el gen Armcx3), que se encontraron mayoritariamente localizadas a núcleo y mitocondria. La sobreexpresión de Armc10 y Alex3 provoca la agregación y/o “tethering” mitocondrial en las neuronas, donde estos procesos sirven para anclar estas organelas en localizaciones específicas que requieren una alta demanda de energía y unos requerimientos de taponamiento de Ca2+. En la base de nuestros datos bioquímicos y de los estudios funcionales proponemos un modelo en el que las proteínas Alex3 y Armc10 son reguladores positivos del tráfico mitocondrial, interaccionando directamente con los complejos Miro/Trak2. Además, como se muestra para el complejo KIF5/Miro/Trak2, el incremento de la actividad neuronal que conlleva a incrementos en Ca2+ es probablemente la causa del desensamblaje del complejo y de la parada mitocondrial en los lugares de neurotransmisión activa, completando por lo tanto los requerimientos bioenergéticos de la transmisión neuronal. A continuaciòn utilizamos la médula espinal de pollo como modelo fisiológico in vivo para explorar la función de Alex3 y Armc10 en el desarrollo neural. Se encontró que Alex3 cumple un papel regulador por inhibición de la vía de Wnt/β-catenina. También demostramos que Alex3 está involucrado tanto en la regulación negativa del ciclo celular como en la inducción de la diferenciación de precursores neuronales. Por otro lado, Armc10 sólo se encontrò implicado en la regulación negativa del ciclo celular. Estas diferencias entre los efectos de la sobreexpresión de Alex3 y Armc10 en procesos llave del desarrollo de la médula espinal, evidencian las divergencias funcionales entre las dos proteínas, sugiriendo que Alex3 puede haber adquirido funciones adicionales respecto a Armc10, ancestro filogenético del cluster Armcx. Globalmente nuestros datos sugieren que la vía de señalización de Wnt puede estar regulando procesos llave del desarrollo a través de las proteínas mitocondriales Alex3 y Armc10.

Published
2013

13. Function of Armcx3 and Armc10/SVH Genes in the Regulation of Progenitor Proliferation and Neural Differentiation in the Chicken Spinal Cord.

Author

Mirra, Serena, Ulloa, Fausto, Gutierrez-Vallejo, Irene, Martì, Elisa, and Soriano, Eduardo

Subjects
X chromosome, CHROMOSOMAL translocation, GENE expression, CELL proliferation, PROGENITOR cells
Abstract

The eutherian X-chromosome specific family of Armcx genes has been described as originating by retrotransposition from Armc10/SVH, a single Arm-containing somatic gene. Armcx3 and Armc10/SVH are characterized by high expression in the central nervous system and they play an important role in the regulation of mitochondrial distribution and transport in neurons. In addition, Armcx/Arm10 genes have several Armadillo repeats in their sequence. In this study we address the potential role of this gene family in neural development by using the chick neural tube as a model. We show that Armc10/SVH is expressed in the chicken spinal cord, and knocking-down Armc10/SVH by sh-RNAi electroporation in spinal cord reduces proliferation of neural precursor cells (NPCs). Moreover, we analyzed the effects of murine Armcx3 and Armc10 overexpression, showing that both proteins regulate progenitor proliferation, while Armcx3 overexpression also specifically controls neural maturation. We show that the phenotypes found following Armcx3 overexpression require its mitochondrial localization, suggesting a novel link between mitochondrial dynamics and regulation of neural development. Furthermore, we found that both Armcx3 and Armc10 may act as inhibitors of Wnt-β-catenin signaling. Our results highlight both common and differential functions of Armcx/Armc10 genes in neural development in the spinal cord. [ABSTRACT FROM AUTHOR]

Published
2016
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15. The Non-Canonical Wnt/PKC Pathway Regulates Mitochondrial Dynamics through Degradation of the Arm-Like Domain-Containing Protein Alex3.

Author

Serrat, Román, López-Doménech, Guillermo, Mirra, Serena, Quevedo, Martí, Garcia-Fernàndez, Jordi, Ulloa, Fausto, Burgaya, Ferrán, and Soriano, Eduardo

Subjects
PROTEIN kinase C, GENETIC code, GENETIC regulation, BIOENERGETICS, CYTOCHEMISTRY, CELLULAR signal transduction, NEUROSCIENCES
Abstract

The regulation of mitochondrial dynamics is vital in complex cell types, such as neurons, that transport and localize mitochondria in high energy-demanding cell domains. The Armcx3 gene encodes a mitochondrial-targeted protein (Alex3) that contains several arm-like domains. In a previous study we showed that Alex3 protein regulates mitochondrial aggregation and trafficking. Here we studied the contribution of Wnt proteins to the mitochondrial aggregation and dynamics regulated by Alex3. Overexpression of Alex3 in HEK293 cells caused a marked aggregation of mitochondria, which was attenuated by treatment with several Wnts. We also found that this decrease was caused by Alex3 degradation induced by Wnts. While the Wnt canonical pathway did not alter the pattern of mitochondrial aggregation induced by Alex3, we observed that the Wnt/PKC non-canonical pathway regulated both mitochondrial aggregation and Alex3 protein levels, thereby rendering a mitochondrial phenotype and distribution similar to control patterns. Our data suggest that the Wnt pathway regulates mitochondrial distribution and dynamics through Alex3 protein degradation. [ABSTRACT FROM AUTHOR]

Published
2013
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16. NESCA: A new NEMO/IKKgamma and TRAF6 interacting protein.

Author

NAPOLITANO, GENNARO, MIRRA, SERENA, MONFREGOLA, JLENIA, LAVORGNA, ALFONSO, LEONARDI, ANTONIO, and URSINI, MATILDE VALERIA

Subjects
*NF-kappa B, *TRANSCRIPTION factors, *CELL death, *APOPTOSIS, *PROTEINS
Abstract

NEMO/IKKγ is the essential regulatory subunit of the IkB Kinase (IKK) complex, required for the activation of Nuclear Factor kB (NF-kB) in many physiological processes such as inflammation, immunity, apoptosis, or development. NEMO works at a converging point of the NF-kB pathway as it interacts with upstream signaling molecules to orchestrate its activation. Here we report on the identification of a novel NEMO-interacting protein, NESCA, an adapter molecule previously shown to be involved in the NGF-pathway via the TrkA receptor. We demonstrated that NESCA and NEMO interact by their N-terminal region. Beside to NEMO, we revealed that NESCA directly associates to the E3 ubiquitin ligase TRAF6, which in turn catalyzes NESCA polyubiquitination. Finally, we demonstrated that NESCA overexpression strongly inhibits TRAF6-mediated polyubiquitination of NEMO. In summary, our results highlight that NESCA represents a novel missing link in the NEMO-mediated NF-kB activation pathway. J. Cell. Physiol. 220: 410–417, 2009. © 2009 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published
2009
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17. Overexpression of CERKL Protects Retinal Pigment Epithelium Mitochondria from Oxidative Stress Effects.

Author

García-Arroyo, Rocío, Gavaldà-Navarro, Aleix, Villarroya, Francesc, Marfany, Gemma, and Mirra, Serena

Subjects
OXIDATIVE stress, MITOCHONDRIA, GENETIC overexpression, EPITHELIUM, RETINITIS pigmentosa, PHOTORECEPTORS, RHODOPSIN
Abstract

The precise function of CERKL, a Retinitis Pigmentosa (RP) causative gene, is not yet fully understood. There is evidence that CERKL is involved in the regulation of autophagy, stress granules, and mitochondrial metabolism, and it is considered a gene that is resilient against oxidative stress in the retina. Mutations in most RP genes affect photoreceptors, but retinal pigment epithelium (RPE) cells may be also altered. Here, we aimed to analyze the effect of CERKL overexpression and depletion in vivo and in vitro, focusing on the state of the mitochondrial network under oxidative stress conditions. Our work indicates that the depletion of CERKL increases the vulnerability of RPE mitochondria, which show a shorter size and altered shape, particularly upon sodium arsenite treatment. CERKL-depleted cells have dysfunctional mitochondrial respiration particularly upon oxidative stress conditions. The overexpression of two human CERKL isoforms (558 aa and 419 aa), which display different protein domains, shows that a pool of CERKL localizes at mitochondria in RPE cells and that CERKL protects the mitochondrial network—both in size and shape—against oxidative stress. Our results support CERKL being a resilient gene that regulates the mitochondrial network in RPE as in retinal neurons and suggest that RPE cell alteration contributes to particular phenotypic traits in patients carrying CERKL mutations. [ABSTRACT FROM AUTHOR]

Published
2021
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18. CERKL, a retinal dystrophy gene, regulates mitochondrial function and dynamics in the mammalian retina.

Author

Mirra, Serena, García-Arroyo, Rocío, B. Domènech, Elena, Gavaldà-Navarro, Aleix, Herrera-Úbeda, Carlos, Oliva, Clara, Garcia-Fernàndez, Jordi, Artuch, Rafael, Villarroya, Francesc, and Marfany, Gemma

Subjects
*RETINAL degeneration, *RETINAL ganglion cells, *RETINA, *MITOCHONDRIA, *VISION disorders
Abstract

The retina is a highly active metabolic organ that displays a particular vulnerability to genetic and environmental factors causing stress and homeostatic imbalance. Mitochondria constitute a bioenergetic hub that coordinates stress response and cellular homeostasis, therefore structural and functional regulation of the mitochondrial dynamic network is essential for the mammalian retina. CERKL (ceramide kinase like) is a retinal degeneration gene whose mutations cause Retinitis Pigmentosa in humans, a visual disorder characterized by photoreceptors neurodegeneration and progressive vision loss. CERKL produces multiple isoforms with a dynamic subcellular localization. Here we show that a pool of CERKL isoforms localizes at mitochondria in mouse retinal ganglion cells. The depletion of CERKL levels in Cerkl KD/KO (knockdown/knockout) mouse retinas cause increase of autophagy, mitochondrial fragmentation, alteration of mitochondrial distribution, and dysfunction of mitochondrial-dependent bioenergetics and metabolism. Our results support CERKL as a regulator of autophagy and mitochondrial biology in the mammalian retina. [Display omitted] • A pool of CERKL isoforms localize at mitochondria in mouse primary retinal cells. • Cerkl downregulation induces increased autophagy and alterations in mitochondrial network organization in the retina. • Mitochondrial function is impaired in Cerkl KD/KO retinas impacting mitochondrial-dependent bioenergetics. [ABSTRACT FROM AUTHOR]

Published
2021
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19. ARMCX3 Mediates Susceptibility to Hepatic Tumorigenesis Promoted by Dietary Lipotoxicity.

Author

Mirra, Serena, Gavaldà-Navarro, Aleix, Manso, Yasmina, Higuera, Mónica, Serrat, Román, Salcedo, María Teresa, Burgaya, Ferran, Balibrea, José Maria, Santamaría, Eva, Uriarte, Iker, Berasain, Carmen, Avila, Matias A., Mínguez, Beatriz, Soriano, Eduardo, Villarroya, Francesc, Columbano, Amedeo, and Timchenko, Nikolai

Subjects
*LIVER tumors, *FAT content of food, *LIVER, *ANIMAL experimentation, *APOPTOSIS, *CELL survival, *GENES, *DISEASE susceptibility, *CELL migration inhibition, *CELL proliferation, *CELL lines, *FATTY acids, *MICE
Abstract

Simple Summary: An excess fat in the liver enhances the susceptibility to hepatic cancer. We found that Armcx3, a protein only known to date to play a role in neural development, is strongly increased in mouse liver in response to lipid availability and proliferation-inducing insults. In patients, the levels of hepatic Armcx3 are also increased in conditions of high exposure of the liver to fat. We wanted to determine the role of Armcx3 in the hepatocarcinogenesis favored by a high-fat diet. We generated mice with genetically driven suppression of Armcx3, and we found that they were protected against experimentally induced hepatic cancer, especially in conditions of a high-fat diet. Armcx3 was also found to promote hepatic cell proliferation through the interaction with Sox9, a known proliferation factor in hepatocellular carcinoma. Armcx3 is identified as a novel factor in meditating propensity to liver cancer in conditions of high hepatic lipid insults. ARMCX3 is encoded by a member of the Armcx gene family and is known to be involved in nervous system development and function. We found that ARMCX3 is markedly upregulated in mouse liver in response to high lipid availability, and that hepatic ARMCX3 is upregulated in patients with NAFLD and hepatocellular carcinoma (HCC). Mice were subjected to ARMCX3 invalidation (inducible ARMCX3 knockout) and then exposed to a high-fat diet and diethylnitrosamine-induced hepatocarcinogenesis. The effects of experimental ARMCX3 knockdown or overexpression in HCC cell lines were also analyzed. ARMCX3 invalidation protected mice against high-fat-diet-induced NAFLD and chemically induced hepatocarcinogenesis. ARMCX3 invalidation promoted apoptotic cell death and macrophage infiltration in livers of diethylnitrosamine-treated mice maintained on a high-fat diet. ARMCX3 downregulation reduced the viability, clonality and migration of HCC cell lines, whereas ARMCX3 overexpression caused the reciprocal effects. SOX9 was found to mediate the effects of ARMCX3 in hepatic cells, with the SOX9 interaction required for the effects of ARMCX3 on hepatic cell proliferation. In conclusion, ARMCX3 is identified as a novel molecular actor in liver physiopathology and carcinogenesis. ARMCX3 downregulation appears to protect against hepatocarcinogenesis, especially under conditions of high dietary lipid-mediated hepatic insult. [ABSTRACT FROM AUTHOR]

Published
2021
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20. A mammalian-specific Alex3/Gα q protein complex regulates mitochondrial trafficking, dendritic complexity, and neuronal survival.

Author

Izquierdo-Villalba I, Mirra S, Manso Y, Parcerisas A, Rubio J, Del Valle J, Gil-Bea FJ, Ulloa F, Herrero-Lorenzo M, Verdaguer E, Benincá C, Castro-Torres RD, Rebollo E, Marfany G, Auladell C, Navarro X, Enríquez JA, López de Munain A, Soriano E, and Aragay AM

Subjects
Animals, Mice, Mammals metabolism, Mitochondrial Proteins metabolism, Axons metabolism, Neurons metabolism
Abstract

Mitochondrial dynamics and trafficking are essential to provide the energy required for neurotransmission and neural activity. We investigated how G protein-coupled receptors (GPCRs) and G proteins control mitochondrial dynamics and trafficking. The activation of Gα q inhibited mitochondrial trafficking in neurons through a mechanism that was independent of the canonical downstream PLCβ pathway. Mitoproteome analysis revealed that Gα q interacted with the Eutherian-specific mitochondrial protein armadillo repeat-containing X-linked protein 3 (Alex3) and the Miro1/Trak2 complex, which acts as an adaptor for motor proteins involved in mitochondrial trafficking along dendrites and axons. By generating a CNS-specific Alex3 knockout mouse line, we demonstrated that Alex3 was required for the effects of Gα q on mitochondrial trafficking and dendritic growth in neurons. Alex3-deficient mice had altered amounts of ER stress response proteins, increased neuronal death, motor neuron loss, and severe motor deficits. These data revealed a mammalian-specific Alex3/Gα q mitochondrial complex, which enables control of mitochondrial trafficking and neuronal death by GPCRs.

Published
2024
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21. The Alter Retina: Alternative Splicing of Retinal Genes in Health and Disease.

Author

Aísa-Marín I, García-Arroyo R, Mirra S, and Marfany G

Subjects
Humans, Retina pathology, Alternative Splicing, Genetic Diseases, Inborn genetics, Genetic Diseases, Inborn metabolism, Genetic Diseases, Inborn pathology, Retina metabolism, Retinal Diseases genetics, Retinal Diseases metabolism, Retinal Diseases pathology
Abstract

Alternative splicing of mRNA is an essential mechanism to regulate and increase the diversity of the transcriptome and proteome. Alternative splicing frequently occurs in a tissue- or time-specific manner, contributing to differential gene expression between cell types during development. Neural tissues present extremely complex splicing programs and display the highest number of alternative splicing events. As an extension of the central nervous system, the retina constitutes an excellent system to illustrate the high diversity of neural transcripts. The retina expresses retinal specific splicing factors and produces a large number of alternative transcripts, including exclusive tissue-specific exons, which require an exquisite regulation. In fact, a current challenge in the genetic diagnosis of inherited retinal diseases stems from the lack of information regarding alternative splicing of retinal genes, as a considerable percentage of mutations alter splicing or the relative production of alternative transcripts. Modulation of alternative splicing in the retina is also instrumental in the design of novel therapeutic approaches for retinal dystrophies, since it enables precision medicine for specific mutations.

Published
2021
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22. A New Cerkl Mouse Model Generated by CRISPR-Cas9 Shows Progressive Retinal Degeneration and Altered Morphological and Electrophysiological Phenotype.

Author

Domènech EB, Andrés R, López-Iniesta MJ, Mirra S, García-Arroyo R, Milla S, Sava F, Andilla J, Loza-Álvarez P, de la Villa P, Gonzàlez-Duarte R, and Marfany G

Subjects
Animals, Cells, Cultured, DNA Mutational Analysis, Disease Models, Animal, Mice, Mice, Inbred C57BL, Phenotype, Phosphotransferases (Alcohol Group Acceptor) metabolism, Retinal Cone Photoreceptor Cells pathology, Retinal Degeneration metabolism, Retinal Degeneration pathology, Retinal Pigment Epithelium pathology, CRISPR-Cas Systems genetics, DNA genetics, Mutation, Phosphotransferases (Alcohol Group Acceptor) genetics, Retinal Cone Photoreceptor Cells metabolism, Retinal Degeneration genetics, Retinal Pigment Epithelium metabolism
Abstract

Purpose: Close to 100 genes cause retinitis pigmentosa, a Mendelian rare disease that affects 1 out of 4000 people worldwide. Mutations in the ceramide kinase-like gene (CERKL) are a prevalent cause of autosomal recessive cause retinitis pigmentosa and cone-rod dystrophy, but the functional role of this gene in the retina has yet to be fully determined. We aimed to generate a mouse model that resembles the phenotypic traits of patients carrying CERKL mutations to undertake functional studies and assay therapeutic approaches., Methods: The Cerkl locus has been deleted (around 97 kb of genomic DNA) by gene editing using the CRISPR-Cas9 D10A nickase. Because the deletion of the Cerkl locus is lethal in mice in homozygosis, a double heterozygote mouse model with less than 10% residual Cerkl expression has been generated. The phenotypic alterations of the retina of this new model have been characterized at the morphological and electrophysiological levels., Results: This CerklKD/KO model shows retinal degeneration, with a decreased number of cones and progressive photoreceptor loss, poorly stacked photoreceptor outer segment membranes, defective retinal pigment epithelium phagocytosis, and altered electrophysiological recordings in aged retinas., Conclusions: To our knowledge, this is the first Cerkl mouse model to mimic many of the phenotypic traits, including the slow but progressive retinal degeneration, shown by human patients carrying CERKL mutations. This useful model will provide unprecedented insights into the retinal molecular pathways altered in these patients and will contribute to the design of effective treatments.

Published
2020
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23. Mitochondrial Gymnastics in Retinal Cells: A Resilience Mechanism Against Oxidative Stress and Neurodegeneration.

Author

Mirra S and Marfany G

Subjects
DNA, Mitochondrial genetics, Humans, Mitochondria physiology, Optic Atrophy, Autosomal Dominant pathology, Optic Atrophy, Hereditary, Leber pathology, Oxidative Stress, Retina cytology
Abstract

Inherited retinal dystrophies (IRDs) are a broad group of neurodegenerative disorders associated with reduced or deteriorating visual system. In the retina, cells are under constant oxidative stress, leading to elevated reactive oxygen species (ROS) generation that induces mitochondrial dysfunction and alteration of the mitochondrial network. This mitochondrial dysfunction combined with mutations in mitochondrial DNA and nuclear genes makes photoreceptors and retinal ganglion cells more susceptible to cell death. In this minireview, we focus on mitochondrial dynamics and their contribution to neuronal degeneration underlying IRDs, with particular attention to Leber hereditary optic neuropathy (LHON) and autosomal dominant optic atrophy (DOA), and propose targeting cell resilience and mitochondrial dynamics modulators as potential therapeutic approaches for retinal disorders.

Published
2019
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24. The Eutherian Armcx genes regulate mitochondrial trafficking in neurons and interact with Miro and Trak2.

Author

López-Doménech G, Serrat R, Mirra S, D'Aniello S, Somorjai I, Abad A, Vitureira N, García-Arumí E, Alonso MT, Rodriguez-Prados M, Burgaya F, Andreu AL, García-Sancho J, Trullas R, Garcia-Fernàndez J, and Soriano E

Subjects
Animals, Armadillo Domain Proteins genetics, Carrier Proteins genetics, Cell Line, Humans, Mitochondria genetics, Mitochondrial Proteins genetics, Multigene Family, Nerve Tissue Proteins genetics, Protein Binding, Protein Transport, rho GTP-Binding Proteins genetics, Armadillo Domain Proteins metabolism, Carrier Proteins metabolism, Evolution, Molecular, Mitochondria metabolism, Mitochondrial Proteins metabolism, Nerve Tissue Proteins metabolism, Neurons metabolism, rho GTP-Binding Proteins metabolism
Abstract

Brain function requires neuronal activity-dependent energy consumption. Neuronal energy supply is controlled by molecular mechanisms that regulate mitochondrial dynamics, including Kinesin motors and Mitofusins, Miro1-2 and Trak2 proteins. Here we show a new protein family that localizes to the mitochondria and controls mitochondrial dynamics. This family of proteins is encoded by an array of armadillo (Arm) repeat-containing genes located on the X chromosome. The Armcx cluster is unique to Eutherian mammals and evolved from a single ancestor gene (Armc10). We show that these genes are highly expressed in the developing and adult nervous system. Furthermore, we demonstrate that Armcx3 expression levels regulate mitochondrial dynamics and trafficking in neurons, and that Alex3 interacts with the Kinesin/Miro/Trak2 complex in a Ca(2+)-dependent manner. Our data provide evidence of a new Eutherian-specific family of mitochondrial proteins that controls mitochondrial dynamics and indicate that this key process is differentially regulated in the brain of higher vertebrates.

Published
2012
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