Mitochondrial proteomic profile of complex IV deficiency fibroblasts: rearrangement of oxidative phosphorylation complex/supercomplex and other metabolic pathways / Perfil proteómico mitocondrial de los fibroblastos con deficiencia del complejo IV: reordenamiento del complejo/supercomplejo de la fosforilación oxidativa y otras vías metabólicas

Abstract: Background: Mitochondriopathies are multisystem diseases affecting the oxidative phosphorylation (OXPHOS) system. Skin fibroblasts are a good model for the study of these diseases. Fibroblasts with a complex IV mitochondriopathy were used to determine the molecular mechanism and the main affected functions in this disease. Methods: Skin fibroblast were grown to assure disease phenotype. Mitochondria were isolated from these cells and their proteome extracted for protein identification. Identified proteins were validated with the MitoMiner database. Results: Disease phenotype was corroborated on skin fibroblasts, which presented a complex IV defect. The mitochondrial proteome of these cells showed that the most affected proteins belonged to the OXPHOS system, mainly to the complexes that form supercomplexes or respirosomes (I, III, IV, and V). Defects in complex IV seemed to be due to assembly issues, which might prevent supercomplexes formation and efficient substrate channeling. It was also found that this mitochondriopathy affects other processes that are related to DNA genetic information flow (replication, transcription, and translation) as well as beta oxidation and tricarboxylic acid cycle. Conclusions: These data, as a whole, could be used for the better stratification of these diseases, as well as to optimize management and treatment options.

Resumen: Introducción: Las mitocondriopatías son enfermedades multisistémicas que afectan el funcionamiento de la fosforilación oxidativa (OXPHOS). Un buen modelo de estudio para estas enfermedades es el cultivo primario de fibroblastos. En este trabajo se utilizaron fibroblastos con mitocondriopatía del complejo IV para determinar cuáles son las principales funciones afectadas en esta enfermedad. Métodos: Se realizaron cultivos primarios de fibroblastos para corroborar el fenotipo de la enfermedad. Las mitocondrias se aislaron de estas células y se extrajo su proteoma para su identificación. Las proteínas identificadas se validaron con la base de datos de MitoMiner. Resultados: Los fibroblastos conservaron el fenotipo de la enfermedad que incluye un defecto del complejo IV. El proteoma mitocondrial de estas células mostró que las proteínas más afectadas pertenecen al sistema de OXPHOS, principalmente los complejos que forman supercomplejos o respirosomas (I, III, IV y V). El defecto en el complejo IV al parecer se debió a problemas de ensamblaje que pueden evitar la formación de los supercomplejos y la eficiente canalización de sustratos. También se observó que esta mitocondriopatía afecta otros procesos relacionados con el flujo de información genética del DNA (replicación, transcripción y traducción), así como con la beta oxidación y el ciclo de los ácidos tricarboxílicos (TCA). Conclusiones: En conjunto, estos datos podrían utilizarse para una mejor clasificación de estas enfermedades, así como para la optimización de las opciones de manejo y tratamiento.

Mitochondrial proteomic profile of complex IV deficiency fibroblasts: rearrangement of oxidative phosphorylation complex/supercomplex and other metabolic pathways.

BACKGROUND: Mitochondriopathies are multisystem diseases affecting the oxidative phosphorylation (OXPHOS) system. Skin fibroblasts are a good model for the study of these diseases. Fibroblasts with a complex IV mitochondriopathy were used to determine the molecular mechanism and the main affected functions in this disease. METHODS: Skin fibroblast were grown to assure disease phenotype. Mitochondria were isolated from these cells and their proteome extracted for protein identification. Identified proteins were validated with the MitoMiner database. RESULTS: Disease phenotype was corroborated on skin fibroblasts, which presented a complex IV defect. The mitochondrial proteome of these cells showed that the most affected proteins belonged to the OXPHOS system, mainly to the complexes that form supercomplexes or respirosomes (I, III, IV, and V). Defects in complex IV seemed to be due to assembly issues, which might prevent supercomplexes formation and efficient substrate channeling. It was also found that this mitochondriopathy affects other processes that are related to DNA genetic information flow (replication, transcription, and translation) as well as beta oxidation and tricarboxylic acid cycle. CONCLUSIONS: These data, as a whole, could be used for the better stratification of these diseases, as well as to optimize management and treatment options.

Regulación antitrombótica por la fibrinólisis / Antithrombotic regulation by fibrinolytic system

In this work it is emphasized the presence of the fibrinolitico system in different physiological mechanisms, specially in the antithrombotic regulation of the hemostasis. It is described: the mechanism of activation of plasminogen by their activators as much on the fibrin as in the cells surface; the inhibition of the activators in different metabolic alterations.

[Antithrombotic regulation by fibrinolytic system]. / Regulación antitrombótica por la fibrinólisis.

In this work it is emphasized the presence of the fibrinolitico system in different physiological mechanisms, specially in the antithrombotic regulation of the hemostasis. It is described: the mechanism of activation of plasminogen by their activators as much on the fibrin as in the cells surface; the inhibition of the activators in different metabolic alterations.

Genética y biología molecular de las cardiopatías congénitas y adquiridas / Genetics and molecular biology of the congenital, and acquired heart disease

El corazón es el primer órgano que se forma y funciona en el embrión, de tal suerte que todos los eventos subsecuentes en la vida del organismo dependen de la habilidad de este órgano para atender las demandas de oxígeno y nutrientes que éste requiere. Las anormalidades en la formación del corazón, la forma más común de defectos humanos al nacimiento, afecta al 1 % de los nacidos vivos, y su frecuencia en abortos espontáneos se eleva diez veces más. La patofisiología de este tipo de malformaciones congénitas se ha venido enriqueciendo en los últimos años con el conocimiento del Proyecto Genoma Humano; debido al gran avance que se ha producido en el conocimiento genético y molecular de los diferentes genes y cromosomas que suelen ser afectados y muchas veces heredados para producir una enfermedad congénita en general. Esta revisión trata de enfocar su atención sobre la información extraída de los análisis genéticos y moleculares en el diagnóstico, tratamiento y entendimiento de la patogénesis de las enfermedades cardiovasculares pediátricas, dirigidas tanto por los más comunes defectos cardíacos congénitos o heredados, como por los desórdenes esporádicos o adquiridos.

The heart is the first organ to form and function in the embryo, and all subsequent events in the life of the organism depend on the heart's ability to match its output with the organism's demands for oxygen and nutrients. Abnormalities in heart formation, the most common form of human birth defects, afflict nearly 1% of newborns, and their frequency in spontaneously aborted pregnancies is estimated to be tenfold higher. With the completion of the sequencing of the human genome, molecular genetic efforts directed at finding genes for monogenic traits have accelerated dramatically. Breakthroughs in molecular genetic technology have just begun to be applied in pediatric cardiology stemming from the use of chromosomal mapping and the identification of genes involved in both the primary etiology and as significant risk factors in the development of cardiac and vascular abnormalities. This review will focus on information provided by molecular and genetic analysis in the diagnosis, treatment and overall heart disorders.

[Genetics and molecular biology of the congenital, and acquired heart disease]. / Genética y biología molecular de las cardiopatías congénitas y adquiridas.

The heart is the first organ to form and function in the embryo, and all subsequent events in the life of the organism depend on the heart's ability to match its output with the organism's demands for oxygen and nutrients. Abnormalities in heart formation, the most common form of human birth defects, afflict nearly 1% of newborns, and their frequency in spontaneously aborted pregnancies is estimated to be tenfold higher. With the completion of the sequencing of the human genome, molecular genetic efforts directed at finding genes for monogenic traits have accelerated dramatically. Breakthroughs in molecular genetic technology have just begun to be applied in pediatric cardiology stemming from the use of chromosomal mapping and the identification of genes involved in both the primary etiology and as significant risk factors in the development of cardiac and vascular abnormalities. This review will focus on information provided by molecular and genetic analysis in the diagnosis, treatment and overall heart disorders.