Biosíntesis de coenzima Q: mantenimiento de la homeostasis redx y adaptación metabólica

El coenzima Q es el único lípido antioxidante endógenamente sintetizado en todos los organismos eucariotas. Se localiza en las membranas celulares formando parte de la cadena de transporte de electrones y fosforilación oxidativa. La restricción calórica modula los componentes grasos de la membrana como medida adaptativa contra el daño oxidativo de patologías y los procesos de envejecimiento. El objetivo de este trabajo es estudiar el efecto del componente graso de la dieta (aceite de ternera, aceite de soja y aceite de pescado) y la restricción calórica a corto plazo sobre el sistema del coenzima Q en tejidos mitóticos y postmitóticos de ratones jóvenes. Después de un mes de intervención dietética sacrificamos los ratones y determinamos en el hígado, riñón, cerebro, músculo y corazón. los niveles de coenzima Q (CoQ9 y CoQ10) mediante HPLC de fase reversa y medimos los niveles de expresión de los genes que codifican los enzimas específicos de la vía de síntesis del coenzima Q mediante RT-PCR a tiempo real. Se cuantificaron además, los niveles de proteína de Coq2p y Coq3p en las tres intervenciones. Los resultados obtenidos demuestran que: (1) La heterogénea distribución del Q se encuentra asociada a un perfil de expresión de los genes COQ, cuyos niveles de transcritos son mayores en aquellos órganos que contienen más coenzima Q. (2) La dieta enriquecida con ácidos poliinsaturados omega-3 de pescado induce la expresión de los genes COQ en todos los tejidos. (3) La restricción calórica a corto utiliza la vía de síntesis del coenzima Q para alterar el metabolismo energético, aunque la adaptación a nivel transcripcional es específica de tejido. (4) La proteína Coq3p aumenta en aquellos tejidos donde la RC disminuye consistentemente el contenido de CoQ9 y CoQ10.(5) El riñón es el órgano que más responde a la restricción calórica y al efecto añadido del componente graso de la dieta. En restricción calórica desciende el contenido de coenzima Q y las grasas más insaturadas acentúan este efecto. La expresión de los genes COQ muestra una tendencia general a disminuir en el riñón ante un entorno calórico reducido, predominantemente cuando la dieta se encuentra enriquecida con grasas más susceptibles de peroxidación. (6) El sistema de coenzima Q (niveles totales y ratio de las dos isoformas) muestra una menor homogeneidad a nivel interindividual en órganos que presentan una mayor accesibilidad a los componentes de la dieta, como es el caso del hígado. En el extremo opuesto, la gran homogeneidad interindividual del cerebro en cuanto a las variaciones del contenido de coenzima Q y de la relación CoQ9/CoQ10, así como la falta de respuesta a la dieta, apoyan la necesidad de mantener un rango homeostático muy estrecho del sistema del coenzima Q. (7) Los cambios provocados por la restricción calórica en la relación CoQ9/CoQ10 no se explican con el efecto que ejerce esta manipulación de la dieta sobre la expresión de los genes COQ1 (mSPS1, mDLP1), responsables de determinar la longitud de la cola isoprenoide

Loss of glutathione redox homeostasis impairs proteostasis by inhibiting autophagy-dependent protein degradation

In the presence of aggregation-prone proteins, the cytosol and endoplasmic reticulum (ER) undergo a dramatic shift in their respective redox status, with the cytosol becoming more oxidized and the ER more reducing. However, whether and how changes in the cellular redox status may affect protein aggregation is unknown. Here, we show that C. elegans loss-of-function mutants for the glutathione reductase gsr-1 gene enhance the deleterious phenotypes of heterologous human, as well as endogenous worm aggregation-prone proteins. These effects are phenocopied by the GSH-depleting agent diethyl maleate. Additionally, gsr-1 mutants abolish the nuclear translocation of HLH-30/TFEB transcription factor, a key inducer of autophagy, and strongly impair the degradation of the autophagy substrate p62/SQST-1::GFP, revealing glutathione reductase may have a role in the clearance of protein aggregates by autophagy. Blocking autophagy in gsr-1 worms expressing aggregation-prone proteins results in strong synthetic developmental phenotypes and lethality, supporting the physiological importance of glutathione reductase in the regulation of misfolded protein clearance. Furthermore, impairing redox homeostasis in both yeast and mammalian cells induces toxicity phenotypes associated with protein aggregation. Together, our data reveal that glutathione redox homeostasis may be central to proteostasis maintenance through autophagy regulation.Ministerio de Economía y Competitividad BFU2016–78265-P, BFU2016– 79313-P, MDM-2016–0687, BFU2015–64408-PInstituto de Salud Carlos III PI11/ 00072, CPII16/00004, PI14/00949, PI17/0001

Loss of glutathione redox homeostasis impairs proteostasis by inhibiting autophagy-dependent protein degradation

In the presence of aggregation-prone proteins, the cytosol and endoplasmic reticulum (ER) undergo a dramatic shift in their respective redox status, with the cytosol becoming more oxidized and the ER more reducing. However, whether and how changes in the cellular redox status may affect protein aggregation is unknown. Here, we show that C. elegans loss-of-function mutants for the glutathione reductase gsr-1 gene enhance the deleterious phenotypes of heterologous human, as well as endogenous worm aggregation-prone proteins. These effects are phenocopied by the GSH-depleting agent diethyl maleate. Additionally, gsr-1 mutants abolish the nuclear translocation of HLH-30/TFEB transcription factor, a key inducer of autophagy, and strongly impair the degradation of the autophagy substrate p62/SQST-1::GFP, revealing glutathione reductase may have a role in the clearance of protein aggregates by autophagy. Blocking autophagy in gsr-1 worms expressing aggregation-prone proteins results in strong synthetic developmental phenotypes and lethality, supporting the physiological importance of glutathione reductase in the regulation of misfolded protein clearance. Furthermore, impairing redox homeostasis in both yeast and mammalian cells induces toxicity phenotypes associated with protein aggregation. Together, our data reveal that glutathione redox homeostasis may be central to proteostasis maintenance through autophagy regulation.. The Spanish Ministry of Economy and Competitiveness supported EF-S and VG (BFU2016–78265-P), PA (BFU2016– 79313-P and MDM-2016–0687), and AM-V (BFU2015–64408-P). AM-V was also supported by the Instituto de Salud Carlos III (PI11/ 00072) and RPV-M (CPII16/00004, PI14/00949 and PI17/00011). All projects were cofinanced by the Fondo Social Europeo (FEDER). AM-V is a member of the GENIE and EU-ROS Cost Actions of the European Union and RPV-M is a Marie Curie Fellow (CIG322034, EU)

Loss of glutathione redox homeostasis impairs proteostasis by inhibiting autophagy-dependent protein degradation

Trabajo presentado en el VII Spanish Worm Meeting (SWN), celebrado en Castelldefels (Barcelona) el 28 y 29 de marzo de 2019.Peer reviewe

Mutational spectrum of GNAL, THAP1 and TOR1A genes in isolated dystonia: study in a population from Spain and systematic literature review

[Objective] We aimed to investigate the prevalence of TOR1A, GNAL and THAP1 variants as the cause of dystonia in a cohort of Spanish patients with isolated dystonia and in the literature.[Methods] A population of 2028 subjects (including 1053 patients with different subtypes of isolated dystonia and 975 healthy controls) from southern and central Spain was included. The genes TOR1A, THAP1 and GNAL were screened using a combination of high-resolution melting analysis and direct DNA resequencing. In addition, an extensive literature search to identify original articles (published before 10 August 2020) reporting mutations in TOR1A, THAP1 or GNAL associated to dystonia was performed.[Results] Pathogenic or likely pathogenic variants in TOR1A, THAP1 and GNAL were identified in 0.48%, 0.57% and 0.29% of our patients, respectively. Five patients carried the variation p.Glu303del in TOR1A. A very rare variant in GNAL (p.Ser238Asn) was found as a putative risk factor for dystonia. In the literature, variations in TOR1A, THAP1 and GNAL accounted for about 6%, 1.8% and 1.1% of published dystonia patients, respectively.[Conclusions] There is a different genetic contribution to dystonia of these three genes in our patients (about 1.3% of patients) and in the literature (about 3.6% of patients), probably due the high proportion of adult-onset cases in our cohort. As regards age at onset, site of dystonia onset, and final distribution, in our population there is a clear differentiation between DYT-TOR1A and DYT-GNAL, with DYT-THAP1 likely to be an intermediate phenotype.This work was supported by the Carlos III Health Institute-European Regional Development Fund (ISCIII-FEDER) [PI14/01823, PI16/01575, PI18/01898, PI19/01576], the Andalusian Regional Ministry of Economics, Innovation, Science and Employment [CVI-02526, CTS-7685], the Andalusian Regional Ministry of Health and Welfare [PI-0741-2010, PI-0471-2013, PE-0210-2018, PI-0459-2018, PE-0186-2019], and the Alicia Koplowitz and Mutua Madrileña Foundations. Pilar Gómez-Garre was supported by the "Miguel Servet" program [MSII14/00018] (from ISCIII-FEDER) and “Nicolás Monardes” program [C-0048-2017] (from the Andalusian Regional Ministry of Health). Silvia Jesús was supported by the "Juan Rodés" program [B-0007-2019] and Daniel Macías-García by the “Río Hortega” program [CM18/00142] (both from ISCIII-FEDER). María Teresa Periñán was supported by the Spanish Ministry of Education [FPU16/05061]. Cristina Tejera was supported by VPPI-US from the University of Seville.Peer reviewe

Regulatory sites for splicing in human basal ganglia are enriched for disease-relevant information

Genome-wide association studies have generated an increasing number of common genetic variants associated with neurological and psychiatric disease risk. An improved understanding of the genetic control of gene expression in human brain is vital considering this is the likely modus operandum for many causal variants. However, human brain sampling complexities limit the explanatory power of brain-related expression quantitative trait loci (eQTL) and allele-specific expression (ASE) signals. We address this, using paired genomic and transcriptomic data from putamen and substantia nigra from 117 human brains, interrogating regulation at different RNA processing stages and uncovering novel transcripts. We identify disease-relevant regulatory loci, find that splicing eQTLs are enriched for regulatory information of neuron-specific genes, that ASEs provide cell-specific regulatory information with evidence for cellular specificity, and that incomplete annotation of the brain transcriptome limits interpretation of risk loci for neuropsychiatric disease. This resource of regulatory data is accessible through our web server, http://braineacv2.inf.um.es/

Identification of novel risk loci, causal insights, and heritable risk for Parkinson's disease: a meta-analysis of genome-wide association studies

Background Genome-wide association studies (GWAS) in Parkinson's disease have increased the scope of biological knowledge about the disease over the past decade. We aimed to use the largest aggregate of GWAS data to identify novel risk loci and gain further insight into the causes of Parkinson's disease. Methods We did a meta-analysis of 17 datasets from Parkinson's disease GWAS available from European ancestry samples to nominate novel loci for disease risk. These datasets incorporated all available data. We then used these data to estimate heritable risk and develop predictive models of this heritability. We also used large gene expression and methylation resources to examine possible functional consequences as well as tissue, cell type, and biological pathway enrichments for the identified risk factors. Additionally, we examined shared genetic risk between Parkinson's disease and other phenotypes of interest via genetic correlations followed by Mendelian randomisation. Findings Between Oct 1, 2017, and Aug 9, 2018, we analysed 7·8 million single nucleotide polymorphisms in 37 688 cases, 18 618 UK Biobank proxy-cases (ie, individuals who do not have Parkinson's disease but have a first degree relative that does), and 1·4 million controls. We identified 90 independent genome-wide significant risk signals across 78 genomic regions, including 38 novel independent risk signals in 37 loci. These 90 variants explained 16–36% of the heritable risk of Parkinson's disease depending on prevalence. Integrating methylation and expression data within a Mendelian randomisation framework identified putatively associated genes at 70 risk signals underlying GWAS loci for follow-up functional studies. Tissue-specific expression enrichment analyses suggested Parkinson's disease loci were heavily brain-enriched, with specific neuronal cell types being implicated from single cell data. We found significant genetic correlations with brain volumes (false discovery rate-adjusted p=0·0035 for intracranial volume, p=0·024 for putamen volume), smoking status (p=0·024), and educational attainment (p=0·038). Mendelian randomisation between cognitive performance and Parkinson's disease risk showed a robust association (p=8·00 × 10−7). Interpretation These data provide the most comprehensive survey of genetic risk within Parkinson's disease to date, to the best of our knowledge, by revealing many additional Parkinson's disease risk loci, providing a biological context for these risk factors, and showing that a considerable genetic component of this disease remains unidentified. These associations derived from European ancestry datasets will need to be followed-up with more diverse data. Funding The National Institute on Aging at the National Institutes of Health (USA), The Michael J Fox Foundation, and The Parkinson's Foundation (see appendix for full list of funding sources)

Alterations in cholesterol metabolism as a risk factor for developing Alzheimer’s disease: Potential novel targets for treatment

Alzheimer's disease (AD) is the most common form of dementia and it is characterized by the deposition of amyloid-β (Aβ) plaques and neurofibrillary tangles in the brain. However, the complete pathogenesis of the disease is still unknown. High level of serum cholesterol has been found to positively correlate with an increased risk of dementia and some studies have reported a decreased prevalence of AD in patients taking cholesterol-lowering drugs. Years of research have shown a strong correlation between blood hypercholesterolemia and AD, however cholesterol is not able to cross the Blood Brain Barrier (BBB) into the brain. Cholesterol lowering therapies have shown mixed results in cognitive performance in AD patients, raising questions of whether brain cholesterol metabolism in the brain should be studied separately from peripheral cholesterol metabolism and what their relationship is. Unlike cholesterol, oxidized cholesterol metabolites known as oxysterols are able to cross the BBB from the circulation into the brain and vice-versa. The main oxysterols present in the circulation are 24S-hydroxycholesterol and 27-hydroxycholesterol. These oxysterols and their catalysing enzymes have been found to be altered in AD brains and there is evidence indicating their influence in the progression of the disease. This review gives a broad perspective on the relationship between hypercholesterolemia and AD, cholesterol lowering therapies for AD patients and the role of oxysterols in pathological and non-pathological conditions. Also, we propose cholesterol metabolites as valuable targets for prevention and alternative AD treatments.We thank the continuous support from Margaretha Af Ugglas Foundation, Stonhes Foundation and Foundation of Old Servants, the Swedish Medical Foundation (SSMF), Lindhés Advokatbyrå AB Foundation, the Karolinska Institutet Foundation for Research, the Swedish Research Council and StratNeuro.Peer reviewe

Calorie restriction modifies ubiquinone and COQ transcript levels in mouse tissues

9 páginas, 5 figuras, 1 tabla.We studied ubiquinone (Q), Q homologue ratio, and steady-state levels of mCOQ transcripts in tissues from mice fed ad libitum or under calorie restriction. Maximum ubiquinone levels on a protein basis were found in kidney and heart, followed by liver, brain, and skeletal muscle. Liver and skeletal muscle showed the highest Q9/Q10 ratios with significant interindividual variability. Heart, kidney, and particularly brain exhibited lower Q9/Q10 ratios and interindividual variability. In skeletal muscle and heart, the most abundant mCOQ transcript was mCOQ7, followed by mCOQ8, mCOQ2, mPDSS2, mPDSS1, and mCOQ3. In nonmuscular tissues (liver, kidney, and brain) the most abundant mCOQ transcript was mCOQ2, followed by mCOQ7, mCOQ8, mPDSS1, mPDSS2, and mCOQ3. Calorie restriction increased both ubiquinone homologues and mPDSS2 mRNA in skeletal muscle, but mCOQ7 was decreased. In contrast, Q9 and most mCOQ transcripts were decreased in heart. Calorie restriction also modified the Q9/Q10 ratio, which was increased in kidney and decreased in heart without alterations in mPDSS1 or mPDSS2 transcripts. We demonstrate for the first time that unique patterns of mCOQ transcripts exist in muscular and nonmuscular tissues and that Q and COQ genes are targets of calorie restriction in a tissue-specific way.This work was supported by NIH Grant 1R01AG028125-01A1 (to J.J.R., P.N., and J.M.V.), Junta de Andalucía Proyectos de Excelencia Grant CVI-00648 (to P.N.), Junta de Andalucía Proyectos de Excelencia Grant P09-CVI-4887 (to J.M.V.), a Junta de Andalucía Proyectos Internacionales grant (to J.M.V.), and BIO-276 (Junta de Andalucía and the University of Córdoba, to J.M.V.). C.P. was funded by Grant CVI-00648.Peer reviewe

Hepatic insulin-degrading enzyme regulates glucose and insulin homeostasis in diet-induced obese mice

© 2020 The Authors.The insulin-degrading enzyme (IDE) is a metalloendopeptidase with a high affinity for insulin. Human genetic polymorphisms in Ide have been linked to increased risk for T2DM. In mice, hepatic Ide ablation causes glucose intolerance and insulin resistance when mice are fed a regular diet. [Objective]: These studies were undertaken to further investigate its regulatory role in glucose homeostasis and insulin sensitivity in diet-induced obesity. [Methods]: To this end, we have compared the metabolic effects of loss versus gain of IDE function in mice fed a high-fat diet (HFD). [Results]: We demonstrate that loss of IDE function in liver (L-IDE-KO mouse) exacerbates hyperinsulinemia and insulin resistance without changes in insulin clearance but in parallel to an increase in pancreatic β-cell function. Insulin resistance was associated with increased FoxO1 activation and a ~2-fold increase of GLUT2 protein levels in the liver of HFD-fed mice in response to an intraperitoneal injection of insulin. Conversely, gain of IDE function (adenoviral delivery) improves glucose tolerance and insulin sensitivity, in parallel to a reciprocal ~2-fold reduction in hepatic GLUT2 protein levels. Furthermore, in response to insulin, IDE co-immunoprecipitates with the insulin receptor in liver lysates of mice with adenoviral-mediated liver overexpression of IDE. [Conclusions]: We conclude that IDE regulates hepatic insulin action and whole-body glucose metabolism in diet-induced obesity via insulin receptor levels.This work was supported by grants from the Ministerio de Economía, Industria y Competitividad: SAF2016-77871-C2-1-R to IC; SAF2016-77871-C2-2-R to GP; This work was supported by grants from the Ministerio de Ciencia e Innovación PID2019-110496RB-C21 to IC; PID2019-110496RB-C22 to GP. European Foundation for the Study of Diabetes (European Diabetes Research Programme on New Targets for Type 2 Diabetes supported by MSD-2017) to IC and GP. The project leading to these results has received funding from “la Caixa” Foundation, under agreement LCF/PR/PR18/51130007 to GP. This work was suppoted by grant from NIH GM115617 to ML