Effects of the Rho GTPase‐activating toxin CNF1 on fibroblasts derived from Rett syndrome patients: A pilot study

The bacterial product CNF1, through its action on the Rho GTPases, is emerging as a modulator of crucial signalling pathways involved in selected neurological diseases characterized by mitochondrial dysfunctions. Mitochondrial impairment has been hypothesized to have a key role in paramount mechanisms underlying Rett syndrome (RTT), a severe neurologic rare disorder. CNF1 has been already reported to have beneficial effects in mouse models of RTT. Using human RTT fibroblasts from four patients carrying different mutations, as a reliable disease-in-a-dish model, we explored the cellular and molecular mechanisms, which can underlie the CNF1-induced amelioration of RTT deficits. We found that CNF1 treatment modulates the Rho GTPases activity of RTT fibroblasts and induces a considerable re-organization of the actin cytoskeleton, mainly in stress fibres. Mitochondria of RTT fibroblasts show a hyperfused morphology and CNF1 decreases the mitochondrial mass leaving substantially unaltered the mitochondrial dynamic. From a functional perspective, CNF1 induces mitochondrial membrane potential depolarization and activation of AKT in RTT fibroblasts. Given that mitochondrial quality control is altered in RTT, our results are suggestive of a reactivation of the damaged mitochondria removal via mitophagy restoration. These effects can be at the basis of the beneficial effects of CNF1 in RTT.

[1]  C. Fiorentini,et al.  Treatment with the Bacterial Toxin CNF1 Selectively Rescues Cognitive and Brain Mitochondrial Deficits in a Female Mouse Model of Rett Syndrome Carrying a MeCP2-Null Mutation , 2021, International journal of molecular sciences.

[2]  H. Saini,et al.  The role of SQSTM1 (p62) in mitochondrial function and clearance in human cortical neurons , 2021, Stem cell reports.

[3]  F. Buss,et al.  Motor proteins at the mitochondria–cytoskeleton interface , 2021, Journal of cell science.

[4]  C. Cervellati,et al.  Impaired mitochondrial quality control in Rett Syndrome. , 2021, Archives of biochemistry and biophysics.

[5]  E. Marsh,et al.  Multisystem comorbidities in classic Rett syndrome: a scoping review , 2020, BMJ paediatrics open.

[6]  D. Valenti,et al.  The Anti-Diabetic Drug Metformin Rescues Aberrant Mitochondrial Activity and Restrains Oxidative Stress in a Female Mouse Model of Rett Syndrome , 2020, Journal of clinical medicine.

[7]  C. Cervellati,et al.  Proteomic profiling reveals mitochondrial alterations in Rett syndrome. , 2020, Free radical biology & medicine.

[8]  C. Fiorentini,et al.  Cnf1 Variants Endowed with the Ability to Cross the Blood–Brain Barrier: A New Potential Therapeutic Strategy for Glioblastoma , 2020, Toxins.

[9]  A. Coppola,et al.  Neurophysiological Signatures of Motor Impairment in Patients with Rett Syndrome , 2020, Annals of Neurology.

[10]  G. Valacchi,et al.  The complexity of Rett syndrome models: Primary fibroblasts as a disease-in-a-dish reliable approach , 2019 .

[11]  Song Han,et al.  Leveraging the genetic basis of Rett syndrome to ascertain pathophysiology , 2019, Neurobiology of Learning and Memory.

[12]  C. Fiorentini,et al.  The Bacterial Protein CNF1 as a Potential Therapeutic Strategy against Mitochondrial Diseases: A Pilot Study , 2018, International journal of molecular sciences.

[13]  M. Cookson,et al.  AKT signalling selectively regulates PINK1 mitophagy in SHSY5Y cells and human iPSC-derived neurons , 2018, Scientific Reports.

[14]  Mriganka Sur,et al.  Rett syndrome: insights into genetic, molecular and circuit mechanisms , 2018, Nature Reviews Neuroscience.

[15]  M. Justice,et al.  Rett syndrome: a neurological disorder with metabolic components , 2018, Open Biology.

[16]  M. D'Esposito,et al.  Retention of Mitochondria in Mature Human Red Blood Cells as the Result of Autophagy Impairment in Rett Syndrome , 2017, Scientific Reports.

[17]  E. Lacivita,et al.  Stimulation of the brain serotonin receptor 7 rescues mitochondrial dysfunction in female mice from two models of Rett syndrome , 2017, Neuropharmacology.

[18]  L. Mills,et al.  Mitochondrial Dysfunction in the Pathogenesis of Rett Syndrome: Implications for Mitochondria-Targeted Therapies , 2017, Front. Cell. Neurosci..

[19]  A. Bird,et al.  MeCP2 mutations: progress towards understanding and treating Rett syndrome , 2017, Genome Medicine.

[20]  C. Cervellati,et al.  OxInflammation in Rett syndrome. , 2016, The international journal of biochemistry & cell biology.

[21]  Morgan Sheng,et al.  Mechanisms of mitophagy: PINK1, Parkin, USP30 and beyond. , 2016, Free radical biology & medicine.

[22]  C. Fiorentini,et al.  CNF1 Enhances Brain Energy Content and Counteracts Spontaneous Epileptiform Phenomena in Aged DBA/2J Mice , 2015, PloS one.

[23]  R. Canese,et al.  Deficient Purposeful Use of Forepaws in Female Mice Modelling Rett Syndrome , 2015, Neural plasticity.

[24]  M. Tejada-Simon,et al.  Modulation of actin dynamics by Rac1 to target cognitive function , 2015, Journal of neurochemistry.

[25]  C. Fiorentini,et al.  Modulation of Rho GTPases rescues brain mitochondrial dysfunction, cognitive deficits and aberrant synaptic plasticity in female mice modeling Rett syndrome , 2015, European Neuropsychopharmacology.

[26]  C. Fiorentini,et al.  Mitochondrial free radical overproduction due to respiratory chain impairment in the brain of a mouse model of Rett syndrome: protective effect of CNF1. , 2015, Free radical biology & medicine.

[27]  E. Lacivita,et al.  Long-lasting beneficial effects of central serotonin receptor 7 stimulation in female mice modeling Rett syndrome , 2015, Front. Behav. Neurosci..

[28]  G. Laviola,et al.  Aberrant Rho GTPases signaling and cognitive dysfunction: In vivo evidence for a compelling molecular relationship , 2014, Neuroscience & Biobehavioral Reviews.

[29]  E. Lacivita,et al.  Pharmacological Stimulation of the Brain Serotonin Receptor 7 as a Novel Therapeutic Approach for Rett Syndrome , 2014, Neuropsychopharmacology.

[30]  R. Carrozzo,et al.  Enhancement of mitochondrial ATP production by the Escherichia coli cytotoxic necrotizing factor 1 , 2014, The FEBS journal.

[31]  P. Tam,et al.  Mitochondrial dysfunction in skeletal muscle of a mouse model of Rett Syndrome ( RTT ) : Implications for the disease phenotype . , 2014 .

[32]  M. Cookson,et al.  Hexokinase activity is required for recruitment of parkin to depolarized mitochondria. , 2014, Human molecular genetics.

[33]  C. Fiorentini,et al.  CNF1 Increases Brain Energy Level, Counteracts Neuroinflammatory Markers and Rescues Cognitive Deficits in a Murine Model of Alzheimer's Disease , 2013, PloS one.

[34]  C. Fiorentini,et al.  CNF1 Improves Astrocytic Ability to Support Neuronal Growth and Differentiation In vitro , 2012, PloS one.

[35]  C. Fiorentini,et al.  Modulation of RhoGTPases Improves the Behavioral Phenotype and Reverses Astrocytic Deficits in a Mouse Model of Rett Syndrome , 2012, Neuropsychopharmacology.

[36]  Odelia Y. N. Bongmba,et al.  Modulation of dendritic spines and synaptic function by Rac1: A possible link to Fragile X syndrome pathology , 2011, Brain Research.

[37]  M. Johnston,et al.  Bone Mass in Rett Syndrome: Association With Clinical Parameters and MECP2 Mutations , 2010, Pediatric Research.

[38]  C. Fiorentini,et al.  Escherichia coli Cytotoxic Necrotizing Factor 1 (CNF1): Toxin Biology, in Vivo Applications and Therapeutic Potential , 2010, Toxins.

[39]  N. C. Schanen,et al.  Mecp2 deficiency decreases bone formation and reduces bone volume in a rodent model of Rett syndrome. , 2009, Bone.

[40]  F. Inagaki,et al.  Structural basis of target recognition by Atg8/LC3 during selective autophagy , 2008, Genes to cells : devoted to molecular & cellular mechanisms.

[41]  R. Youle,et al.  Parkin is recruited selectively to impaired mitochondria and promotes their autophagy , 2008, The Journal of cell biology.

[42]  L. Ricceri,et al.  Mouse models of Rett syndrome: from behavioural phenotyping to preclinical evaluation of new therapeutic approaches , 2008, Behavioural pharmacology.

[43]  T. Mizushima,et al.  Structural Basis for Sorting Mechanism of p62 in Selective Autophagy* , 2008, Journal of Biological Chemistry.

[44]  Z. Elazar,et al.  The N-terminus and Phe52 residue of LC3 recruit p62/SQSTM1 into autophagosomes , 2008, Journal of Cell Science.

[45]  H. Zoghbi,et al.  Specific mutations in Methyl-CpG-Binding Protein 2 confer different severity in Rett syndrome , 2008, Neurology.

[46]  Masaaki Komatsu,et al.  Homeostatic Levels of p62 Control Cytoplasmic Inclusion Body Formation in Autophagy-Deficient Mice , 2007, Cell.

[47]  Huda Y. Zoghbi,et al.  The Story of Rett Syndrome: From Clinic to Neurobiology , 2007, Neuron.

[48]  C. Fiorentini,et al.  Cytotoxic Necrotizing Factor 1 Prevents Apoptosis via the AKT/IKK pathway: Role of NF-κB and Bcl-2 , 2007 .

[49]  L. Van Aelst,et al.  Rho GTPases, dendritic structure, and mental retardation. , 2005, Journal of neurobiology.

[50]  R. Jaenisch,et al.  Expression of MeCP2 in postmitotic neurons rescues Rett syndrome in mice. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[51]  R. Cantor,et al.  Phenotypic manifestations of MECP2 mutations in classical and atypical rett syndrome , 2004, American journal of medical genetics. Part A.

[52]  P. Boquet,et al.  CNF1 Exploits the Ubiquitin-Proteasome Machinery to Restrict Rho GTPase Activation for Bacterial Host Cell Invasion , 2002, Cell.

[53]  R. Wong,et al.  Activity-dependent regulation of dendritic growth and patterning , 2002, Nature Reviews Neuroscience.

[54]  R. Yuste,et al.  Regulation of dendritic spine morphology by the rho family of small GTPases: antagonistic roles of Rac and Rho. , 2000, Cerebral cortex.

[55]  Ann Y. Nakayama,et al.  Small GTPases Rac and Rho in the Maintenance of Dendritic Spines and Branches in Hippocampal Pyramidal Neurons , 2000, The Journal of Neuroscience.

[56]  K. Aktories,et al.  The Rho-deamidating cytotoxic necrotizing factor 1 from Escherichia coli possesses transglutaminase activity. Cysteine 866 and histidine 881 are essential for enzyme activity. , 1998, The Journal of biological chemistry.

[57]  Richard Threadgill,et al.  Regulation of Dendritic Growth and Remodeling by Rho, Rac, and Cdc42 , 1997, Neuron.

[58]  C. Fiorentini,et al.  Toxin-induced activation of the G protein p21 Rho by deamidation of glutamine , 1997, Nature.

[59]  M. Mann,et al.  Gln 63 of Rho is deamidated by Escherichia coli cytotoxic necrotizing factor-1 , 1997, Nature.

[60]  A. Teebi,et al.  Rett Syndrome: A Mitochondrial Disease? , 1990, Journal of child neurology.