Your search keyword '"Emanuela Piermarini"' showing total 17 results

1. Human mini brains and spinal cords in a dish: Modeling strategies, current challenges, and prospective advances

Author

Simeon Kofman, Neha Mohan, Xiaohuan Sun, Larisa Ibric, Emanuela Piermarini, and Liang Qiang

Subjects

Biochemistry, QD415-436

Abstract

Engineered three-dimensional (3D) in vitro and ex vivo neural tissues, also known as “mini brains and spinal cords in a dish,” can be derived from different types of human stem cells via several differentiation protocols. In general, human mini brains are micro-scale physiological systems consisting of mixed populations of neural progenitor cells, glial cells, and neurons that may represent key features of human brain anatomy and function. To date, these specialized 3D tissue structures can be characterized into spheroids, organoids, assembloids, organ-on-a-chip and their various combinations based on generation procedures and cellular components. These 3D CNS models incorporate complex cell-cell interactions and play an essential role in bridging the gap between two-dimensional human neuroglial cultures and animal models. Indeed, they provide an innovative platform for disease modeling and therapeutic cell replacement, especially shedding light on the potential to realize personalized medicine for neurological disorders when combined with the revolutionary human induced pluripotent stem cell technology. In this review, we highlight human 3D CNS models developed from a variety of experimental strategies, emphasize their advances and remaining challenges, evaluate their state-of-the-art applications in recapitulating crucial phenotypic aspects of many CNS diseases, and discuss the role of contemporary technologies in the prospective improvement of their composition, consistency, complexity, and maturation.

Published

2022

2. A cellular approach to understanding and treating Gulf War Illness

Author

Alessia Niceforo, Philip L Yates, Alvin V. Terry, Kimberly Sullivan, Emanuela Piermarini, Ramnik S. Gill, Peter W. Baas, Ankita Patil, Liang Qiang, Wayne D. Beck, Patrick M. Callahan, and Xiaohuan Sun

Subjects

Male, Sarin, Induced Pluripotent Stem Cells, Hippocampus, Article, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Glutamatergic, Animals, Humans, Medicine, Premovement neuronal activity, Persian Gulf Syndrome, Rats, Wistar, Molecular Biology, Cells, Cultured, Veterans, Nerve agent, Neurons, Pharmacology, Memory Disorders, business.industry, Cell Differentiation, Cell Biology, CA3 Region, Hippocampal, humanities, Gulf War, Rats, Disease Models, Animal, Regimen, chemistry, Immunology, Molecular Medicine, business, Toxicant, Hormone, medicine.drug

Abstract

Gulf War Illness (GWI), a disorder suffered by approximately 200,000 veterans of the first Gulf War, was caused by exposure to low-level organophosphate pesticides and nerve agents in combination with battlefield stress. To elucidate the mechanistic basis of the brain-related symptoms of GWI, human-induced pluripotent stem cells (hiPSCs) derived from veterans with or without GWI were differentiated into forebrain glutamatergic neurons and then exposed to a Gulf War (GW) relevant toxicant regimen consisting of a sarin analog and cortisol, a human stress hormone. Elevated levels of total and phosphorylated tau, reduced microtubule acetylation, altered mitochondrial dynamics/transport, and decreased neuronal activity were observed in neurons exposed to the toxicant regimen. Some of the data are consistent with the possibility that some veterans may have been predisposed to acquire GWI. Wistar rats exposed to a similar toxicant regimen showed a mild learning and memory deficit, as well as cell loss and tau pathology selectively in the CA3 region of the hippocampus. These cellular responses offer a mechanistic explanation for the memory loss suffered by veterans with GWI and provide a cell-based model for screening drugs and developing personalized therapies for these veterans.

Published

2021

3. Modeling gain-of-function and loss-of-function components of SPAST-based hereditary spastic paraplegia using transgenic mice

Author

Emanuela Piermarini, Seyma Akarsu, Theresa Connors, Matthias Kneussel, Michael A Lane, Gerardo Morfini, Arzu Karabay, Peter W Baas, and Liang Qiang

Subjects

Adenosine Triphosphatases, Mice, Knockout, Spastin, Spastic Paraplegia, Hereditary, Mice, Transgenic, General Medicine, Mice, Loss of Function Mutation, Gain of Function Mutation, Mutation, Genetics, Animals, Humans, Original Article, Molecular Biology, Genetics (clinical)

Abstract

Hereditary spastic paraplegia (HSP) is a disease in which dieback degeneration of corticospinal tracts, accompanied by axonal swellings, leads to gait deficiencies. SPG4-HSP, the most common form of the disease, results from mutations of human spastin gene (SPAST), which is the gene that encodes spastin, a microtubule-severing protein. The lack of a vertebrate model that recapitulates both the etiology and symptoms of SPG4-HSP has stymied the development of effective therapies for the disease. hSPAST-C448Y mice, which express human mutant spastin at the ROSA26 locus, display corticospinal dieback and gait deficiencies but not axonal swellings. On the other hand, mouse spastin gene (Spast)-knockout (KO) mice display axonal swellings but not corticospinal dieback or gait deficiencies. One possibility is that reduced spastin function, resulting in axonal swellings, is not the cause of the disease but exacerbates the toxic effects of the mutant protein. To explore this idea, Spast-KO and hSPAST-C448Y mice were crossbred, and the offspring were compared with the parental lines via histological and behavioral analyses. The crossbred animals displayed axonal swellings as well as earlier onset, worsened gait deficiencies and corticospinal dieback compared with the hSPAST-C448Y mouse. These results, together with observations on changes in histone deacetylases 6 and tubulin modifications in the axon, indicate that each of these three transgenic mouse lines is valuable for investigating a different component of the disease pathology. Moreover, the crossbred mice are the best vertebrate model to date for testing potential therapies for SPG4-HSP.

Published

2021

4. New hypothesis for the etiology of SPAST‐ based hereditary spastic paraplegia

Author

Emanuela Piermarini, Peter W. Baas, and Liang Qiang

Subjects

Male, Genetics, 0303 health sciences, Spastic Paraplegia, Hereditary, Hereditary spastic paraplegia, Mechanism (biology), Mutant, Cell Biology, Disease, Biology, Spastin, medicine.disease, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Etiology, medicine, Humans, Female, Haploinsufficiency, Gene, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Mutations of the SPAST gene are the chief cause of hereditary spastic paraplegia. Controversy exists in the medical community as to whether the etiology of the disease is haploinsufficiency or toxic gain-of-function properties of the mutant spastin proteins. In recognition of strong reasons that support each possible mechanism, here we present a novel perspective, based in part on new studies with mouse models and in part on the largest study to date on patients with the disease. We posit that haploinsufficiency does not cause the disease but makes the corticospinal tracts vulnerable to a second hit, which is usually the mutant spastin proteins but could also be proteins generated by mutations of other genes that may or may not cause the disease on their own.

Published

2019

5. Hereditary spastic paraplegia: gain-of-function mechanisms revealed by new transgenic mouse

Author

Gerardo Morfini, Lanfranco Leo, Guillermo M. Alexander, Hemalatha Muralidharan, Michelle Swift, Terry Heiman-Patterson, Laura E Hennessy, Liang Qiang, Emanuela Piermarini, Peter W. Baas, Wenqian Yu, Philip L Yates, Michael A. Lane, Theresa Connors, Lyandysha V. Zholudeva, and Silvia Fernandes

Subjects

0301 basic medicine, Genetically modified mouse, Spastin, Hereditary spastic paraplegia, Mutant, Mice, Transgenic, Haploinsufficiency, Biology, medicine.disease_cause, Axonal Transport, Microtubules, Mice, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Genetics, medicine, Animals, Molecular Biology, Genetics (clinical), Neurons, Mutation, Spastic Paraplegia, Hereditary, General Medicine, medicine.disease, Axons, Cell biology, Disease Models, Animal, 030104 developmental biology, Haplotypes, Gain of Function Mutation, Knockout mouse, Mutant Proteins, General Article, 030217 neurology & neurosurgery

Abstract

Mutations of the SPAST gene, which encodes the microtubule-severing protein spastin, are the most common cause of hereditary spastic paraplegia (HSP). Haploinsufficiency is the prevalent opinion as to the mechanism of the disease, but gain-of-function toxicity of the mutant proteins is another possibility. Here, we report a new transgenic mouse (termed SPAST(C448Y) mouse) that is not haploinsufficient but expresses human spastin bearing the HSP pathogenic C448Y mutation. Expression of the mutant spastin was documented from fetus to adult, but gait defects reminiscent of HSP (not observed in spastin knockout mice) were adult onset, as is typical of human patients. Results of histological and tracer studies on the mouse are consistent with progressive dying back of corticospinal axons, which is characteristic of the disease. The C448Y-mutated spastin alters microtubule stability in a manner that is opposite to the expectations of haploinsufficiency. Neurons cultured from the mouse display deficits in organelle transport typical of axonal degenerative diseases, and these deficits were worsened by depletion of endogenous mouse spastin. These results on the SPAST(C448Y) mouse are consistent with a gain-of-function mechanism underlying HSP, with spastin haploinsufficiency exacerbating the toxicity of the mutant spastin proteins. These findings reveal the need for a different therapeutic approach than indicated by haploinsufficiency alone.

Published

2018

6. The cytoskeletal arrangements necessary to neurogenesis

Author

Emanuela Piermarini, Fiorella Piemonte, Enrico Bertini, Claudia Compagnucci, and Antonella Sferra

Subjects

0301 basic medicine, Nervous system, Neurite, Neurogenesis, Cellular differentiation, Induced Pluripotent Stem Cells, Models, Neurological, Review, Biology, Cell fate determination, tubulins, 03 medical and health sciences, 0302 clinical medicine, Neurites, medicine, Animals, Humans, Cytoskeleton, Induced pluripotent stem cell, Cell Proliferation, Neurons, cytoskeleton, Cell Differentiation, Cell biology, 030104 developmental biology, medicine.anatomical_structure, nervous system, Oncology, induced pluripotent stem cells (iPSCs), Stem cell, actin, 030217 neurology & neurosurgery

Abstract

During the process of neurogenesis, the stem cell committed to the neuronal cell fate starts a series of molecular and morphological changes. The understanding of the physio-pathology of mechanisms controlling the molecular and morphological changes occurring during neuronal differentiation is fundamental to the development of effective therapies for many neurologic diseases. Unfortunately, our knowledge of the biological events occurring in the cell during neuronal differentiation is still poor. In this study, we focus preliminarily on the relevance of the cytoskeletal rearrangements, which earlier drive the morphology of the neuronal precursors, and later the migrating/mature neurons. In fact, neuritogenesis, neurite branching, outgrowth and retraction are seminal to the development of a fully functional nervous system. With this in mind, we highlight the importance of iPSC technology to study the processes of cytoskeletal-driven morphological changes during neuronal differentiation.

Published

2016

7. Nrf2-Inducers Counteract Neurodegeneration in Frataxin-Silenced Motor Neurons: Disclosing New Therapeutic Targets for Friedreich’s Ataxia

Author

Anna Pastore, Sara Petrillo, Rosalba Carrozzo, Fiorella Piemonte, Gessica Vasco, Tommaso Schirinzi, Enrico Bertini, and Emanuela Piermarini

Subjects

Male, 0301 basic medicine, sulforaphane, Pharmacology, Friedreich’s Ataxia, environment and public health, lcsh:Chemistry, chemistry.chemical_compound, Isothiocyanates, Iron-Binding Proteins, Child, lcsh:QH301-705.5, Cells, Cultured, Spectroscopy, Motor Neurons, dimethyl fumarate, biology, Neurodegeneration, General Medicine, respiratory system, Computer Science Applications, Neuroprotective Agents, Biochemistry, Sulfoxides, Female, medicine.symptom, Adult, Ataxia, Adolescent, NF-E2-Related Factor 2, Neuroprotection, Article, Nrf2, Catalysis, Inorganic Chemistry, 03 medical and health sciences, Downregulation and upregulation, medicine, Humans, Physical and Theoretical Chemistry, Molecular Biology, Transcription factor, oxidative stress, inducers, Activator (genetics), Organic Chemistry, Fibroblasts, medicine.disease, Oxidative Stress, 030104 developmental biology, lcsh:Biology (General), lcsh:QD1-999, chemistry, Friedreich Ataxia, Frataxin, biology.protein, Sulforaphane

Abstract

Oxidative stress is actively involved in Friedreich’s Ataxia (FA), thus pharmacological targeting of the antioxidant machinery may have therapeutic value. Here, we analyzed the relevance of the antioxidant phase II response mediated by the transcription factor Nrf2 on frataxin-deficient cultured motor neurons and on fibroblasts of patients. The in vitro treatment of the potent Nrf2 activator sulforaphane increased Nrf2 protein levels and led to the upregulation of phase II antioxidant enzymes. The neuroprotective effects were accompanied by an increase in neurites’ number and extension. Sulforaphane (SFN) is a natural compound of many diets and is now being used in clinical trials for other pathologies. Our results provide morphological and biochemical evidence to endorse a neuroprotective strategy that may have therapeutic relevance for FA. The findings of this work reinforce the crucial importance of Nrf2 in FA and provide a rationale for using Nrf2-inducers as pharmacological agents.

Published

2017

8. Frataxin Deficiency Leads to Reduced Expression and Impaired Translocation of NF-E2-Related Factor (Nrf2) in Cultured Motor Neurons

Author

Fiorella Piemonte, Sara Petrillo, Emanuela Piermarini, Valentina D'Oria, Enrico Bertini, Lorena Travaglini, Barbara Carletti, Stefania Petrini, and Chiara Priori

Subjects

Pathology, medicine.medical_specialty, Ataxia, NF-E2-Related Factor 2, medicine.disease_cause, Neuroprotection, Article, Nrf2, Catalysis, lcsh:Chemistry, Inorganic Chemistry, Mice, Cell Line, Tumor, Iron-Binding Proteins, medicine, Animals, Humans, oxidative stress, Physical and Theoretical Chemistry, lcsh:QH301-705.5, Molecular Biology, Transcription factor, Spectroscopy, Motor Neurons, Regulation of gene expression, FRDA, Messenger RNA, frataxin, biology, Organic Chemistry, Iron-binding proteins, General Medicine, respiratory system, NSC34 neurons, Computer Science Applications, Cell biology, GSSG, Gene Expression Regulation, lcsh:Biology (General), lcsh:QD1-999, Friedreich Ataxia, Frataxin, biology.protein, medicine.symptom, Oxidative stress

Abstract

Oxidative stress has been implicated in the pathogenesis of Friedreich's Ataxia (FRDA), a neurodegenerative disease caused by the decreased expression of frataxin, a mitochondrial protein responsible of iron homeostasis. Under conditions of oxidative stress, the activation of the transcription factor NF-E2-related factor (Nrf2) triggers the antioxidant cellular response by inducing antioxidant response element (ARE) driven genes. Increasing evidence supports a role for the Nrf2-ARE pathway in neurodegenerative diseases. In this study, we analyzed the expression and the distribution of Nrf2 in silenced neurons for frataxin gene. Decreased Nrf2 mRNA content and a defective activation after treatment with pro-oxidants have been evidenced in frataxin-silenced neurons by RT-PCR and confocal microscopy. The loss of Nrf2 in FRDA may greatly enhance the cellular susceptibility to oxidative stress and make FRDA neurons more vulnerable to injury. Our findings may help to focus on this promising target, especially in its emerging role in the neuroprotective response.

Published

2013

9. Frataxin silencing alters microtubule stability in motor neurons: implications for Friedreich's ataxia

Author

Anna Pastore, Ezio Giorda, Fiorella Piemonte, Jessica D’Amico, Enrico Bertini, Stefania Petrini, Graziella Cappelletti, Daniele Cartelli, Giulia Tozzi, Emanuela Piermarini, and Claudia Compagnucci

Subjects

0301 basic medicine, Ataxia, Neurite, macromolecular substances, Microtubules, Antioxidants, 03 medical and health sciences, Mice, 0302 clinical medicine, Microtubule, Iron-Binding Proteins, Genetics, medicine, Neurites, Gene silencing, Animals, Humans, Gene Silencing, Cytoskeleton, Molecular Biology, Genetics (clinical), Cells, Cultured, Motor Neurons, biology, Glutathione Disulfide, Iron-binding proteins, General Medicine, Axons, Cell biology, Oxidative Stress, 030104 developmental biology, Tubulin, Friedreich Ataxia, biology.protein, Frataxin, medicine.symptom, 030217 neurology & neurosurgery

Abstract

To elucidate the pathogenesis of axonopathy in Friedreich's Ataxia (FRDA), a neurodegenerative disease characterized by axonal retraction, we analyzed the microtubule (MT) dynamics in an in vitro frataxin-silenced neuronal model (shFxn). A typical feature of MTs is their "dynamic instability", in which they undergo phases of growth (polymerization) and shrinkage (depolymerization). MTs play a fundamental role in the physiology of neurons and every perturbation of their dynamicity is highly detrimental for neuronal functions. The aim of this study is to determine whether MTs are S-glutathionylated in shFxn and if the glutathionylation triggers MT dysfunction. We hypothesize that oxidative stress, determined by high GSSG levels, induces axonal retraction by interfering with MT dynamics. We propose a mechanism of the axonopathy in FRDA where GSSG overload and MT de-polymerization are strictly interconnected. Indeed, using a frataxin-silenced neuronal model we show a significant reduction of neurites extension, a shift of tubulin toward the unpolymerized fraction and a consistent increase of glutathione bound to the cytoskeleton. The live cell imaging approach further reveals a significant decrease in MT growth lifetime due to frataxin silencing, which is consistent with the MT destabilization. The in vitro antioxidant treatments trigger the axonal re-growth and the increase in stable MTs in shFxn, thus contributing to identify new neuronal targets of oxidation in this disease and providing a novel approach for antioxidant therapies.

Published

2016

10. Cytoskeletal dynamics during in vitro neurogenesis of induced pluripotent stem cells (iPSCs)

Author

Enrico Bertini, Fiorella Piemonte, Alessia Niceforo, Stefania Petrini, Emanuela Piermarini, Claudia Compagnucci, Rossella Borghi, and Antonella Sferra

Subjects

0301 basic medicine, Nervous system, Neurogenesis, Induced Pluripotent Stem Cells, Context (language use), Biology, Microtubules, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Neural Stem Cells, Tubulin, medicine, Humans, Cytoskeleton, Intermediate filament, Induced pluripotent stem cell, Molecular Biology, Cells, Cultured, Cell Biology, Actin Cytoskeleton, 030104 developmental biology, Cell metabolism, medicine.anatomical_structure, biology.protein, Neuroscience, 030217 neurology & neurosurgery

Abstract

Patient-derived induced pluripotent stem cells (iPSCs) provide a novel tool to investigate the pathophysiology of poorly known diseases, in particular those affecting the nervous system, which has been difficult to study for its lack of accessibility. In this emerging and promising field, recent iPSCs studies are mostly used as "proof-of-principle" experiments that are confirmatory of previous findings obtained from animal models and postmortem human studies; its promise as a discovery tool is just beginning to be realized. A recent number of studies point to the functional similarities between in vitro neurogenesis and in vivo neuronal development, suggesting that similar morphogenetic and patterning events direct neuronal differentiation. In this context, neuronal adhesion, cytoskeletal organization and cell metabolism emerge as an integrated and unexplored processes of human neurogenesis, mediated by the lack of data due to the difficult accessibility of the human neural tissue. These observations raise the necessity to understand which are the players controlling cytoskeletal reorganization and remodeling. In particular, we investigated human in vitro neurogenesis using iPSCs of healthy subjects to unveil the underpinnings of the cytoskeletal dynamics with the aim to shed light on the physiologic events controlling the development and the functionality of neuronal cells. We validate the iPSCs system to better understand the development of the human nervous system in order to set the bases for the future understanding of pathologies including developmental disorders (i.e. intellectual disability), epilepsy but also neurodegenerative disorders (i.e. Friedreich's Ataxia). We investigate the changes of the cytoskeletal components during the 30days of neuronal differentiation and we demonstrate that human neuronal differentiation requires a (time-dependent) reorganization of actin filaments, intermediate filaments and microtubules; and that immature neurons present a finely regulated localization of Glu-, Tyr- and Acet-TUBULINS. This study advances our understanding on cytoskeletal dynamics with the hope to pave the way for future therapies that could be potentially able to target cytoskeletal based neurodevelopmental and neurodegenerative diseases.

Published

2016

11. Biallelic Mutations in TBCD, Encoding the Tubulin Folding Cofactor D, Perturb Microtubule Dynamics and Cause Early-Onset Encephalopathy

Author

Elisabetta Flex, Maria Lisa Dentici, Alessandro Capuano, Fiorella Piemonte, Marco Tartaglia, Giovanna Carpentieri, Charlotte A. Haaxma, Enrico Bertini, Jean Baptiste Le Pichon, Isabelle Thiffault, Bruno Dallapiccola, Anna A. Ivanova, Antonella Sferra, Joshua W. Francis, Marcello Niceta, Margaret G. Au, Kara L. Levine, Emanuela Piermarini, Ganka Douglas, David A. Koolen, Andrea Ciolfi, Emily G. Farrow, Carol J Saunders, Richard A. Kahn, John M. Graham, Frank Baas, Giovanni Chillemi, R. Pfundt, Balasubramanian Chandramouli, Simone Pizzi, Serena Cecchetti, Genome Analysis, and ANS - Cellular & Molecular Mechanisms

Subjects

0301 basic medicine, Male, Microcephaly, Protein Folding, Cell division, Adolescent, Population, Spindle Apparatus, Biology, Microtubules, Microtubule polymerization, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Tubulin, Report, Genetics, medicine, Humans, Age of Onset, Cytoskeleton, education, Genetics (clinical), Alleles, Cell Proliferation, education.field_of_study, Brain Diseases, Neurodegeneration, Brain, Infant, Fibroblasts, medicine.disease, Disorders of movement Donders Center for Medical Neuroscience [Radboudumc 3], Spindle apparatus, Cell biology, 030104 developmental biology, Child, Preschool, Mutation, Female, Microtubule-Associated Proteins, 030217 neurology & neurosurgery, Rare cancers Radboud Institute for Health Sciences [Radboudumc 9], Molecular Chaperones, Protein Binding

Abstract

Item does not contain fulltext Microtubules are dynamic cytoskeletal elements coordinating and supporting a variety of neuronal processes, including cell division, migration, polarity, intracellular trafficking, and signal transduction. Mutations in genes encoding tubulins and microtubule-associated proteins are known to cause neurodevelopmental and neurodegenerative disorders. Growing evidence suggests that altered microtubule dynamics may also underlie or contribute to neurodevelopmental disorders and neurodegeneration. We report that biallelic mutations in TBCD, encoding one of the five co-chaperones required for assembly and disassembly of the alphabeta-tubulin heterodimer, the structural unit of microtubules, cause a disease with neurodevelopmental and neurodegenerative features characterized by early-onset cortical atrophy, secondary hypomyelination, microcephaly, thin corpus callosum, developmental delay, intellectual disability, seizures, optic atrophy, and spastic quadriplegia. Molecular dynamics simulations predicted long-range and/or local structural perturbations associated with the disease-causing mutations. Biochemical analyses documented variably reduced levels of TBCD, indicating relative instability of mutant proteins, and defective beta-tubulin binding in a subset of the tested mutants. Reduced or defective TBCD function resulted in decreased soluble alpha/beta-tubulin levels and accelerated microtubule polymerization in fibroblasts from affected subjects, demonstrating an overall shift toward a more rapidly growing and stable microtubule population. These cells displayed an aberrant mitotic spindle with disorganized, tangle-shaped microtubules and reduced aster formation, which however did not alter appreciably the rate of cell proliferation. Our findings establish that defective TBCD function underlies a recognizable encephalopathy and drives accelerated microtubule polymerization and enhanced microtubule stability, underscoring an additional cause of altered microtubule dynamics with impact on neuronal function and survival in the developing brain.

Published

2016

12. High concentrations of H2O2trigger hypertrophic cascade and phosphatase and tensin homologue (PTEN) glutathionylation in H9c2 cardiomyocytes

Author

Nadia Panera, Valerio Nobili, Emanuela Piermarini, Enrico Bertini, Fiorella Piemonte, Daniela Gnani, Stefania Petrini, Anna Pastore, and Anna Alisi

Subjects

0301 basic medicine, Clinical Biochemistry, Phosphatase, Down-Regulation, Cardiomegaly, Biology, Pathology and Forensic Medicine, Muscle hypertrophy, Cell Line, 03 medical and health sciences, Downregulation and upregulation, Gene expression, Tensin, PTEN, Animals, Humans, Cardiomyocytes, Hydrogen peroxide, Hypertrophy, Pten, Glutathione, Hydrogen Peroxide, Myocytes, Cardiac, PTEN Phosphohydrolase, Phosphorylation, Rats, Signal Transduction, Molecular Biology, 2734, Medicine (all), 030104 developmental biology, biology.protein, Cancer research, Signal transduction

Abstract

Cardiac hypertrophy occurs in response to different stimuli and is mainly characterized by an enlargement of cardiomyocyte size. During hypertrophy, cardiomyocytes undergo not only radical changes of the cellular architecture but also activation of signaling cascades that counteract the atrophy genes. Experimental studies highlighted that chronic low concentrations of H2O2, induce a hypertrophic phenotype, while higher levels of H2O2 promote apoptosis. In this study, we explored the early and long-term hypertrophic effects of high concentrations of H2O2 on H9c2 rat cardiomyocytes. We found that 2-h stimulation with 200μM H2O2 caused an early dramatic reduction of cell viability, accompanied, 5-days later, by increased cell size and up-regulation of atrial natriuretic peptide transcription. This hypertrophic phenotype is associated to increased Akt phosphorylation and a consequent reduction of the FOXO3a and atrogin-1 gene expression. Moreover, we observed that H2O2 caused the overexpression of miR-212/miR-132 cluster concomitantly to a down-regulation of PTEN transcript without changes in its protein expression. Noteworthy, we found that the treatment of cardiomyocytes with H2O2 further led to an increase of oxidized glutathione and glutathionylation of proteins, including PTEN. In conclusion, our results permit to reconstruct the molecular cascade triggering the cardiomyocyte hypertrophy upon high concentrations of H2O2.

Published

2016

13. Frataxin Silencing Inactivates Mitochondrial Complex I in NSC34 Motoneuronal Cells and Alters Glutathione Homeostasis

Author

Alessandra Torraco, Rosalba Carrozzo, Anna Pastore, Sara Petrillo, Barbara Carletti, Fiorella Piemonte, Lorena Travaglini, Giulia Tozzi, Enrico Bertini, Marco Sparaco, and Emanuela Piermarini

Subjects

Friedreich’s ataxia, Mitochondrion, Catalysis, Article, lcsh:Chemistry, Inorganic Chemistry, Small hairpin RNA, Mice, RNA interference, Cell Line, Tumor, Iron-Binding Proteins, medicine, Gene silencing, Animals, Homeostasis, Physical and Theoretical Chemistry, RNA, Small Interfering, mitochondrial enzymes, lcsh:QH301-705.5, Molecular Biology, Spectroscopy, Cell Proliferation, Motor Neurons, Electron Transport Complex I, biology, Cell growth, Organic Chemistry, Neurodegeneration, neurodegeneration, Iron-binding proteins, General Medicine, medicine.disease, Molecular biology, Glutathione, Computer Science Applications, Mitochondria, Oxidative Stress, lcsh:Biology (General), lcsh:QD1-999, Friedreich Ataxia, Frataxin, biology.protein, RNA Interference, glutathione, oxidative stress

Abstract

Friedreich’s ataxia (FRDA) is a hereditary neurodegenerative disease characterized by a reduced synthesis of the mitochondrial iron chaperon protein frataxin as a result of a large GAA triplet-repeat expansion within the first intron of the frataxin gene. Despite neurodegeneration being the prominent feature of this pathology involving both the central and the peripheral nervous system, information on the impact of frataxin deficiency in neurons is scant. Here, we describe a neuronal model displaying some major biochemical and morphological features of FRDA. By silencing the mouse NSC34 motor neurons for the frataxin gene with shRNA lentiviral vectors, we generated two cell lines with 40% and 70% residual amounts of frataxin, respectively. Frataxin-deficient cells showed a specific inhibition of mitochondrial Complex I (CI) activity already at 70% residual frataxin levels, whereas the glutathione imbalance progressively increased after silencing. These biochemical defects were associated with the inhibition of cell proliferation and morphological changes at the axonal compartment, both depending on the frataxin amount. Interestingly, at 70% residual frataxin levels, the in vivo treatment with the reduced glutathione revealed a partial rescue of cell proliferation. Thus, NSC34 frataxin silenced cells could be a suitable model to study the effect of frataxin deficiency in neurons and highlight glutathione as a potential beneficial therapeutic target for FRDA.

Published

2014

14. Transglutaminase 2 transamidation activity during first-phase insulin secretion: natural substrates in INS-1E

Author

Stefano La Rosa, Emanuela Piermarini, Massimo Alessio, Ornella Massa, Federico Bertuzzi, Giovanni Nardo, Claudia Marsella, Tania Massignan, Lucia Russo, Giovanna Finzi, Valentina Bonetto, and Pierre Maechler

Subjects

G protein, Endocrinology, Diabetes and Metabolism, medicine.medical_treatment, Biology, Glucagon, Mass Spectrometry, Substrate Specificity, 03 medical and health sciences, 0302 clinical medicine, Endocrinology, GTP-Binding Proteins, Insulin receptor substrate, Cell Line, Tumor, Insulin-Secreting Cells, Insulin Secretion, Internal Medicine, medicine, Animals, Humans, Insulin, Protein Glutamine gamma Glutamyltransferase 2, ddc:612, 030304 developmental biology, 0303 health sciences, Transglutaminases, Glucagon secretion, Actin remodeling, General Medicine, Rats, medicine.anatomical_structure, Glucose, Biochemistry, Beta cell, Pancreas, 030217 neurology & neurosurgery

Abstract

Transglutaminase 2 (TG2) is a multifunctional protein with Ca(2+)-dependent transamidating and G protein activity. Previously, we reported that tgm2 -/- mice have an impaired insulin secretion and that naturally occurring TG2 mutations associated with familial, early-onset type 2 diabetes, show a defective transamidating activity. Aim of this study was to get a better insight into the role of TG2 in insulin secretion by identifying substrates of TG2 transamidating activity in the pancreatic beta cell line INS-1E. To this end, we labeled INS-1E that are capable of secreting insulin upon glucose stimulation in the physiologic range, with an artificial acyl acceptor (biotinamido-pentylamine) or donor (biotinylated peptide), in basal condition and after stimulus with glucose for 2, 5, and 8 min. Biotinylated proteins were analyzed by two-dimensional electrophoresis and mass spectrometry. In addition, subcellular localization of TG2 in human endocrine pancreas was studied by electron microscopy. Among several TG2's transamidating substrates in INS-1E, mass spectrometry identified cytoplasmic actin (a result confirmed in human pancreatic islet), tropomyosin, and molecules that participate in insulin granule structure (e.g., GAPDH), glucose metabolism, or [Ca(2+)] sensing (e.g., calreticulin). Physical interaction between TG2 and cytoplasmic actin during glucose-stimulated first-phase insulin secretion was confirmed by co-immunoprecipitation. Electron microscopy revealed that TG2 is localized close to insulin and glucagon granules in human pancreatic islet. We propose that TG2's role in insulin secretion may involve cytoplasmic actin remodeling and may have a regulative action on other proteins during granule movement. A similar role of TG2 in glucagon secretion is also suggested.

Published

2013

15. Distal spinal muscular atrophy and ataxia with cerebellar atrophy in two unrelated patients; a new phenotypic variant of HRD and recessive KCS syndrome related to TBCE

Author

Carlo Dionisi-Vici, Emanuela Piermarini, Teresa Rizza, Claudia Compagnucci, Adele D'Amico, Bruno Dallapiccola, Diego Martinelli, Marcello Niceta, Enrico Bertini, Sabina Barresi, Antonella Sferra, Ginevra Zanni, Daria Diodato, Giorgio Tasca, and Marco Tartaglia

Subjects

Pathology, medicine.medical_specialty, Ataxia, business.industry, Distal spinal muscular atrophy, Audiology, Phenotype, Neurology, Pediatrics, Perinatology and Child Health, Medicine, Cerebellar atrophy, Neurology (clinical), medicine.symptom, business, Genetics (clinical)

Published

2015

16. TBCE Mutations Cause Early-Onset Progressive Encephalopathy with Distal Spinal Muscular Atrophy

Author

Viviana Caputo, Emanuele Bellacchio, Carlo Dionisi-Vici, Vincenzo Nigro, Gilbert Baillat, Annalaura Torella, Andrea Ciolfi, Antonietta Coppola, Teresa Rizza, Marcello Niceta, Adele D'Amico, Antonella Sferra, Claudia Compagnucci, Enrico Bertini, Emanuela Piermarini, Georg Haase, Giorgio Tasca, Serena Cecchetti, Sabina Barresi, Marco Tartaglia, Ginevra Zanni, Daria Diodato, Enrico Tedeschi, Diego Martinelli, Bruno Dallapiccola, Elisabetta Flex, Medical Genetics and Pediatric Cardiology, IRCCS Ospedale Pediatrico Bambino Gesù [Roma], Institut de Neurosciences de la Timone (INT), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Department of Hematology, Oncology and Molecular Medicine, Istituto Superiore di Sanita [Rome], Centro di Ricerca per gli alimenti e la nutrizione ( CREA), Istituto Nazionale di Ricerca per gli Alimenti e la Nutrizione, Department of Experimental Medicine, Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Department of Cell Biology and Neurosciences, Department of Biochemistry, Biophysics and General Pathology, University of Naples Federico II, Division of Metabolism, Department of Craniofacial Development & Orthodontics, London Dental Institute (LDI), King‘s College London-King‘s College London, Ematologia, Oncologia e Medicina Molecolare, Istituto Superiore di Sanita', Sferra, Antonella, Baillat, Gilbert, Rizza, Teresa, Barresi, Sabina, Flex, Elisabetta, Tasca, Giorgio, D'Amico, Adele, Bellacchio, Emanuele, Ciolfi, Andrea, Caputo, Viviana, Cecchetti, Serena, Torella, Annalaura, Zanni, Ginevra, Diodato, Daria, Piermarini, Emanuela, Niceta, Marcello, Coppola, Antonietta, Tedeschi, Enrico, Martinelli, Diego, Dionisi Vici, Carlo, Nigro, Vincenzo, Dallapiccola, Bruno, Compagnucci, Claudia, Tartaglia, Marco, Haase, Georg, Bertini, Enrico, Istituto Superiore di Sanità (ISS), Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome] (UNIROMA), and University of Naples Federico II = Università degli studi di Napoli Federico II

Subjects

0301 basic medicine, Male, Genetics, Genetics (clinical), [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, medicine.disease_cause, Microtubules, Microtubule polymerization, chemistry.chemical_compound, Mice, 0302 clinical medicine, Tubulin, Missense mutation, Age of Onset, Child, Mutation, Brain Diseases, Nocodazole, Neurodegeneration, Homozygote, Phenotype, 3. Good health, Italy, Female, Heterozygote, Adolescent, Spindle Apparatus, Biology, [SDV.GEN.GH] Life Sciences [q-bio]/Genetics/Human genetics, Muscular Atrophy, Spinal, 03 medical and health sciences, Young Adult, [SDV.MHEP.PED] Life Sciences [q-bio]/Human health and pathology/Pediatrics, Genetic, Microtubule, Report, medicine, Animals, Humans, [SDV.MHEP.PED]Life Sciences [q-bio]/Human health and pathology/Pediatrics, [SDV.NEU.NB] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Infant, Newborn, Infant, Heterozygote advantage, Fibroblasts, medicine.disease, Molecular biology, 030104 developmental biology, chemistry, [SDV.GEN.GH]Life Sciences [q-bio]/Genetics/Human genetics, 030217 neurology & neurosurgery, Molecular Chaperones

Abstract

International audience; Tubulinopathies constitute a family of neurodevelopmental/neurodegenerative disorders caused by mutations in several genes encodingtubulin isoforms. Loss-of-function mutations in TBCE, encoding one of the five tubulin-specific chaperones involved in tubulin foldingand polymerization, cause two rare neurodevelopmental syndromes, hypoparathyroidism-retardation-dysmorphism and Kenny-Caffeysyndrome. Although a missense mutation in Tbce has been associated with progressive distal motor neuronopathy in the pmn/pmn mice,no similar degenerative phenotype has been recognized in humans. We report on the identification of an early-onset and progressiveneurodegenerative encephalopathy with distal spinal muscular atrophy resembling the phenotype of pmn/pmn mice and caused bybiallelic TBCE mutations, with the c.464T>A (p.Ile155Asn) change occurring at the heterozygous/homozygous state in six affectedsubjects from four unrelated families originated from the same geographical area in Southern Italy. Western blot analysis of patientfibroblasts documented a reduced amount of TBCE, suggestive of rapid degradation of the mutant protein, similarly to what wasobserved in pmn/pmn fibroblasts. The impact of TBCE mutations on microtubule polymerization was determined using biochemical fractionationand analyzing the nucleation and growth of microtubules at the centrosome and extracentrosomal sites after treatment withnocodazole. Primary fibroblasts obtained from affected subjects displayed a reduced level of polymerized a-tubulin, similarly to tailfibroblasts of pmn/pmn mice. Moreover, markedly delayed microtubule re-polymerization and abnormal mitotic spindles with disorganizedmicrotubule arrangement were also documented. Although loss of function of TBCE has been documented to impact multipledevelopmental processes, the present findings provide evidence that hypomorphic TBCE mutations primarily drive neurodegeneration.

Published

2006

17. Systemic redox biomarkers in neurodegenerative diseases

Author

Fiorella Piemonte, Sara Petrillo, Anna Pastore, and Emanuela Piermarini

Subjects

Antioxidant, medicine.medical_treatment, Clinical Biochemistry, Disease, Biology, Protein glutathionylation, Protein oxidation, medicine.disease_cause, Antioxidants, Pathogenesis, chemistry.chemical_compound, medicine, Animals, Humans, Pharmacology, Neurodegeneration, Neurodegenerative Diseases, Glutathione, medicine.disease, Diet, Oxidative Stress, Biochemistry, chemistry, Cancer research, Oxidation-Reduction, Oxidative stress, Biomarkers

Abstract

Neurodegenerative diseases are characterized by a gradual and selective loss of neurons. ROS overload has been proved to occur early in this heterogeneous group of disorders, indicating oxidative stress as a primer factor underlying their pathogenesis. Given the importance of a better knowledge of the cause/effect of oxidative stress in the pathogenesis and evolution of neurodegeneration, recent efforts have been focused on the identification and determination of stable markers that may reflect systemic oxidative stress. This review provides an overview of these systemic redox biomarkers and their responsiveness to antioxidant therapies. Redox biomarkers can be classified as molecules that are modified by interactions with ROS in the microenvironment and antioxidant molecules that change in response to increased oxidative stress. DNA, lipids (including phospholipids), proteins and carbohydrates are examples of molecules that can be modified by excessive ROS in vivo. Some modifications have direct effects on molecule functions (e.g. to inhibit enzyme function), but others merely reflect the degree of oxidative stress in the local environment. Testing of redox biomarkers in neurodegenerative diseases has 3 important goals: 1) to confirm the presence or absence of systemic oxidative stress; 2) to identify possible underlying (and potentially reversible) causes of neurodegeneration; and 3) to estimate the severity of the disease and the risk of progression. Reflecting pathological processes occurring in the whole body, redox biomarkers may pinpoint novel therapeutic targets and lead to diagnose diseases before they are clinically evident.