[Physiological assessment and management of post-COVID patients with normal cardiopulmonary imaging and functional tests]. / Valoración fisiológica y manejo de pacientes post-COVID con pruebas funcionales cardiopulmonares y de imagen normales.

OBJECTIVE: Contributing to elucidate the pathophysiology of dyspnoea and exertion intolerance in post-COVID syndrome patients with normal cardiopulmonary imaging and functional tests at rest, while determining their fitness and level of endurance in order to individualize working parameters for physical rehabilitation. MATERIAL AND METHODS: After an anamnesis and clinical examination at rest, 27 subjects (50±11.9 years) (14 women) with post-COVID syndrome of more than 6 months of evolution performed a continuous maximal-incremental graded cardiopulmonary exercise test (CPET) with breath-by-breath gas-exchange monitoring and continuous ECG registration, on an electromagnetically braked cycle ergometer. The values obtained were compared with those of reference, gender or controls, using the Chi-square, t-Student or ANOVA test. RESULTS: The clinical examination at rest and the CPET were clinically normal and without adverse events. Reasons for stopping exercise were leg discomfort. It is only worth noting a BMI=29.9±5.8kg/m2 and a basal lactate concentration of 2.1±0.7mmol/L. The physiological assessment of endurance showed the following results relative to predicted VO2máx: 1)peakVO2=80.5±18.6%; 2)VO2 at ventilatory threshold1 (VO2VT1): 46.0±12.9%; 3)VO2VT2: 57.2±16.4%; 4)working time in acidosis: 5.6±3,0minutes; and 5)maximum lactate concentration: 5.1±2.2mmol/L. CONCLUSIONS: The CPET identified limited aerobic metabolism and early increase in glycolytic metabolism as causes of dyspnoea and exercise intolerance, determined fitness for physical rehabilitation, and individualized it based on the level of endurance.

Effect of tetrahydroquinoline derivatives on the intracellular Ca2+ homeostasis in breast cancer cells (MCF-7) and its relationship with apoptosis / Efecto de derivados de tetrahidroquinolinas sobre la homeostasis del Ca2+ intracelular en células de cáncer de mama (MCF-7) y su relación con la apoptosis

Abstract Tetrahydroquinoline derivatives are interesting structures exhibiting a wide range of biological activities, including antitumor effects. In this investigation, the effect of the synthesized tetrahydroquinolines JS-56 and JS-92 on apoptosis, intracellular Ca2+ concentration ([Ca2+]i), and the sarco(endo)plasmic reticulum Ca2+-ATPase (SERCA) activity was determined on MCF-7 breast cancer cells. Colorimetric assays were used to assess MCF-7 cells viability and SERCA activity. Fura-2 and rhodamine 123 were used to measure the intracellular Ca2+ concentration and the mitochondrial electrochemical potential, respec tively. TUNEL assay was used to analyze DNA fragmentation, while caspase activity and NF-κB-dependent gene expression were assessed by luminescence. In silico models were used for molecular docking analysis. These compounds increase intracellular Ca2+ concentration; the main contribution is the Ca2+ entry from the extracellular milieu. Both JS-56 and JS-92 inhibit the activity of SERCA and dissipate the mitochondrial electrochemical potential through processes dependent and independent of the Ca2+ uptake by this organelle. Furthermore, JS-56 and JS-92 generate cytotoxicity in MCF-7 cells. The effect of JS-92 is higher than JS-56. Both compounds activate caspases 7 and 9, cause DNA fragmentation, and potentiate the effect of phorbol 12-myristate-13-acetate on NF-κB-dependent gene expression. Molecular docking analysis suggests that both compounds have a high interaction for SERCA, similar to thapsigargin. Both tetrahydroquinoline derivatives induced cell death through a combination of apoptotic events, increase [Ca2+]i, and inhibit SERCA activity by direct interaction.

Resumen Los derivados de tetrahidroquinolina son estructuras interesantes que exhiben una amplia gama de actividades biológicas, incluyendo efectos antitumorales. Se determinó el efecto de las tetrahidroquinolinas sintetizadas JS-56 y JS-92 sobre la apoptosis, concentración intracelular de Ca2+ ([Ca2+]i) y la actividad Ca2+-ATPasa del retículo sarco(endo)plásmico (SERCA) en células de cáncer de mama MCF-7. Se usaron ensayos colorimétricos para evaluar la viabilidad de las células MCF-7 y la actividad SERCA. Se emplearon Fura-2 y rodamina 123 para medir la concentración de Ca2+ intracelular y el potencial electroquímico mitocondrial, respectivamente. El ensayo TUNEL se utilizó para analizar la fragmentación del ADN, mientras que la actividad de caspasas y la expresión génica dependiente de NF-κB se evaluaron mediante luminiscencia. Modelos in silico permitieron el análisis del acoplamiento molecular. Estos compuestos aumentan la concentración de Ca2+ intracelular; la principal contribución es la entrada de Ca2+ desde el medio extracelular. Tanto JS-56 como JS-92 inhiben la actividad de SERCA y disipan el potencial electroquímico mitocondrial a través de procesos dependientes e independientes de la captación de Ca2+ por este orgánulo. Además, JS-56 y JS-92 generan citotoxicidad en células MCF-7. El efecto de JS-92 es mayor que JS-56. Ambos compuestos activan las caspasas 7 y 9, provocan la fragmentación del ADN y potencian el efecto del 12-miristato-13-acetato de forbol en la expresión génica dependiente de NF-κB. El análisis de acoplamiento molecular sugiere que ambos compuestos tienen una alta interacción con SERCA, similar a la tapsigargina. Ambos derivados de tetrahidroquinolina indujeron la muerte celular a través de una combinación de eventos apoptóticos, aumento de [Ca2+]i e inhibición de la actividad SERCA por interacción directa.

AMPK signaling and its targeting in cancer progression and treatment.

The intrinsic mechanisms sensing the imbalance of energy in cells are pivotal for cell survival under various environmental insults. AMP-activated protein kinase (AMPK) serves as a central guardian maintaining energy homeostasis by orchestrating diverse cellular processes, such as lipogenesis, glycolysis, TCA cycle, cell cycle progression and mitochondrial dynamics. Given that AMPK plays an essential role in the maintenance of energy balance and metabolism, managing AMPK activation is considered as a promising strategy for the treatment of metabolic disorders such as type 2 diabetes and obesity. Since AMPK has been attributed to aberrant activation of metabolic pathways, mitochondrial dynamics and functions, and epigenetic regulation, which are hallmarks of cancer, targeting AMPK may open up a new avenue for cancer therapies. Although AMPK is previously thought to be involved in tumor suppression, several recent studies have unraveled its tumor promoting activity. The double-edged sword characteristics for AMPK as a tumor suppressor or an oncogene are determined by distinct cellular contexts. In this review, we will summarize recent progress in dissecting the upstream regulators and downstream effectors for AMPK, discuss the distinct roles of AMPK in cancer regulation and finally offer potential strategies with AMPK targeting in cancer therapy.

Organ dysfunction syndrome and mitochondrial adaptation in the septic patient. / Síndrome de disfunción de órganos y adaptación mitocondrial en el paciente séptico.

The ability to maintain an adequate energy balance and to respond and adapt to environmental stress at the cellular level are cornerstones for the survival and evolution of organisms. Therefore, in the presence of various factors, a cellular protection response is triggered by activation of mitochondrial function-dependent signaling. However, this essential reaction for individual cell survival can be detrimental to organ function (maladaptation), transforming the close balance between the two into the pathogenetic axis of organ dysfunction and eventual recovery in septic patients. Macrocirculatory and microcirculatory disruption undoubtedly contributes to organ dysfunction in the early stage of septic shock, while intrinsic metabolic-bioenergetic failure (cytopathic hypoxia) perpetuates inadequate cellular function. Therefore, mitochondrial dysfunction is a key process in the induction of multiple organ dysfunction syndrome in the septic patient. This syndrome can be considered as a complex hypometabolic adaptive phenomenon in the face of excessive and prolonged inflammatory stimulus to achieve regulation of energy homeostasis and preservation of organ function. In the future, there should be a transition from the current consensus therapeutic options, which are limited to control of the infectious focus, hemodynamic and life support, to metabolic resuscitation based on the molecular and genetic alterations triggered by the infection.

Piedra angular para la sobrevida y la evolución de los organismos es su capacidad de mantener un adecuado balance energético, así como también que las células respondan y se adapten al estrés ambiental. Por ello, ante la presencia de diversos factores se origina una respuesta de protección celular mediante la activación de señalización dependiente de la función mitocondrial. Sin embargo, esta reacción, esencial para la supervivencia individual de las células, puede ser perjudicial para la función orgánica (adaptación inadecuada), transformando el estrecho equilibrio entre ambas en el eje patogénico de la disfunción orgánica y su eventual recuperación en el paciente séptico. Las alteraciones macrocirculatorias y microcirculatorias contribuyen, indudablemente, a la disfunción orgánica en la etapa precoz del choque séptico, mientras que la falla metabólica-bioenergética intrínseca (hipoxia citopática) perpetúa una función celular inadecuada. Por lo tanto, la disfunción mitocondrial es un proceso clave en la inducción del síndrome de disfunción multiorgánica en el paciente séptico. Este síndrome puede considerarse como un complejo fenómeno adaptativo hipometabólico ante un estímulo inflamatorio excesivo y prolongado, para lograr la regulación de la homeostasis energética y la preservación de la función de los órganos. En el futuro, debería producirse una transición entre las opciones terapéuticas actuales consensuadas, que se limitan al control del foco infeccioso y el soporte hemodinámico y vital, hacia una reanimación metabólica basada en las alteraciones moleculares y genéticas desencadenadas por la infección.

Diferencias fenotípicas de fibroblastos gingivales en sujetos con hiperplasia gingival idiopática frente a sujetos periodontalmente sanos: estudio piloto / Phenotypic differences of gingival fibroblasts in subjects with idiopathic gingival hyperplasia versus periodontally healthy subjects: a pilot study

Objetivo: identificar, describir y diferenciar las características fenotípicas de los fibroblastos gingivales (FGs) en pacientes con hiperplasia gingival idiopática (HGI) e individuos periodontalmente sanos. Métodos: los FGs fueron aislados a partir de tejido gingival de individuos periodontalmente sanos (n=2) y pacientes con HGI (n=2). Los FGs se cultivaron en el medio DMEM (Dulbecco's Modified of Eagle Medium) a 37°C con 5% de CO2. La identificación y localización de la actina, vimentina y mitocondrias en FGs fue realizada y evaluada microscópicamente mediante inmunofluorescencia con anticuerpos monoclonales. La capacidad de migración de los FGs en los pacientes con HGI e individuos sanos también fue estudiada. Resultados: todos los FGs fueron mononucleares, fusiformes y con prolongaciones citoplasmáticas visibles. La faloidina permitió identificar una densa red de actina en los FGs de pacientes con HGI, contrariamente a los FGs de individuos periodontalmente sanos. La vimentina y mitocondrias fueron identificadas en los FGs de individuos sanos y pacientes con HGI sin ninguna alteración en su expresión y localización. La migración de la monocapa de los FGs indicó una actividad de migración celular importante en los FGs de los pacientes con HGI, en relación a los FGs de los individuos periodontalmente sanos. Conclusión: los FGs de pacientes con HGI conservan características fenotípicas celulares similares a los FGs de individuos periodontalmente sanos. Sin embargo, los FGs de pacientes con HGI simulan tener una mayor capacidad migratoria que amerita ser explorada en futuros trabajos de investigación.

Objective: To identify and to describe the phenotypic characteristics of gingival fibroblasts from patients with idiopathic gingival hyperplasia (IGH) and periodontally healthy individuals. Methods: Gingival fibroblasts (GFs) were isolated from gingival tissue from periodontally healthy individuals (n=2) and patients with IGH (n=2). The GFs were grown in DMEM (Dulbecco's Modified of Eagle Medium) at 37°C with 5% CO2. The identification and location of actin, vimentin and mitochondria in GFs were performed and evaluated microscopically by immunofluorescence with monoclonal antibodies. The migration capacity of GFs from IGH and healthy individuals was also studied. Results: All the GFs were mononuclear, fusiform and with visible cytoplasmic extensions. The phalloidin allowed to identify a dense actin network in the GFs of patients with IGH, contrary to the GFs of periodontally healthy individuals. Vimentin and mitochondria were identified in the GFs of healthy individuals and patients with IGH without any alteration in their expression and location. Monolayer migration of GFs indicates significant cell migration activity in the GFs of patients with IGH in relation to the GFs of periodontally healthy individuals. Conclusion: GFs from patients with IGH retain cellular phenotypic characteristic similar to GFs from periodontally healthy individuals. However, the GFs of patients with IGH simulate having a greater migratory capacity that deserves to be explored in future research works.

Procedimiento para la infusión de mitocondrias autólogas por la arteria carótida en el cerebro porcino

Las mitocondrias son organelas complejas que desempeñan un papel fundamental en la célula, la disfunción mitocondrial puede ocasionar daños celulares significativos o la muerte. Estudios previos han demostrado los prometedores efectos terapéuticos del trasplante de mitocondrias autólogas a un tejido cardiaco isquémico, sin embargo, pocos estudios han evaluado los efectos in vivo de la infusión de mitocondrias en el cerebro. El presente trabajo tiene como objetivo dar a conocer el procedimiento para la infusión vía carótida de mitocondrias autólogas en cerebros porcinos. Mediante esta técnica de infusión, proponemos que una administración selectiva y mínimamente invasiva es factible y puede proporcionar beneficios en el tratamiento de diversas patologías del sistema nervioso central.

Mitochondria are complex organelles that play a critical role within the cell; mitochondrial dysfunction can result in significant cell damage or death. Previous studies have demonstrated the promising therapeutic effects of autologous mitochondria transplantation into ischemic cardiac tissue; however, few studies have examined the in vivo effects of mitochondria infusion into the brain. The aim of this study is to report a procedure for carotid infusion of autologous mitochondria into porcine brains. By using this infusion technique, we propose that a selective and minimally invasive administration is feasible and may provide benefits in the treatment of various central nervous system disorders.

Qualitative and quantitative ultrastructural analysis of the mitochondria from adrenal gland cortex under the action of viperidae family snake venoms / Análisis ultrastructural cualitativo y cuantitativo de la mitocondria de la glándula adrenal bajo la acción de los venenos de serpientes de la familia viperidae

SUMMARY: The Viperidae venoms are composed of a mixture of constituents with enzymatic and non-enzymatic actions, which act on ultrastructural components of cells and tissues. Here, the number of mitochondria, mitochondrial area and the number of mitochondrial cristae from adrenal glands cortex treated with snake venoms were tested after 3, 6 and 24 hours of venom injections. The mitochondria quantitative changes showed a statistically significant decrease, in the number of mitochondria past 3, 6 and 24 h. There was an increase in the mitochondrial area after 6 h, where Crotalus vegrandis venom did not present significant differences with Crotalus pifanorum or Bothrops venezuelensis venoms. After 24 h, there was an escalation of mitochondrial area in all tested venoms. The number of mitochondrial cristae after 3 h did not present important differences with the control treatment. After 6 h, the number of mitochondrial cristae initiated to decrease under the activities of the 3 venoms action, until 24 h of observation. In the qualitative observations it was possible to witness an intense damage of the mitochondria, with loss and swelling of membranes, disappearance of cristae and the appearance of myelin figures, which started at 3 h after the Crotalus and Bothrops venoms injections. These damages probably were due to cytotoxic effects of phospholipases, metalloproteases and/or other proteolytic activities present in Viperidae snake venoms, being more evident in Crotalus venoms. As far as we know, these results define a novel finding that suggest that Viperidae snake venoms are extremely toxic to mammalian mitochondria.

RESUMEN: Los venenos de Viperidae tienen acciones enzimáticas y no enzimáticas, que actúan sobre la estructura celular. Aquí se probaron, a las 3, 6 y 24 horas de la inyección del veneno, el número de mitocondrias, el área mitocondrial y el número de crestas mitocondriales de la corteza de las glándulas adrenales. Los cambios cuantitativos de las mitocondrias mostraron una disminución en el número de mitocondrias a las 3, 6 y 24 h. Hubo un aumento en el área mitocondrial a las 6 h, donde el veneno de la serpiente Crotalus vegrandis no presentó diferencias significativas con los venenos de Crotalus pifanorum o Bothrops venezuelensis. Después de 24 h, hubo un aumento del área mitocondrial en todos los venenos. El número de crestas mitocondriales a las 3 h no presentó alteraciones o diferencias importantes con el tratamiento de control. Después de 6 h, el número de crestas mitocondriales comenzó a disminuir bajo la acción de los 3 venenos, hasta las 24 h de observación. En las observaciones cualitativas se observó un daño intenso de las mitocondrias, con pérdida y edema de las membranas, desaparición de las cristae y aparición de figuras mielínicas, que comenzó a las 3 h después de las inyecciones de veneno de Crotalus y Bothrops. Estos daños se debieron factiblemente a los efectos citotóxicos de componentes proteolíticos de los venenos. Creemos que estos resultados definen un nuevo y original hallazgo, que sugiere que los venenos de serpiente Viperidae son extremadamente tóxicos para las mitocondrias de mamíferos.

Vitamin D-mitochondria cross-talk could modulate the signaling pathway involved in hypertension development: a translational integrative overview. / La interacción vitamina D-mitocondria podría modular el camino de señalización involucrado en el desarrollo de la hipertensión: una visión integrativa translacional.

Vitamin D deficiency is a worldwide pandemic and results in osteoporosis, hypertension, and other cardiovascular diseases. At the cellular level, it produces significant oxidative stress, inflammatory markers, and mitochondrial damage. There is increasing evidence about the role of vitamin D in the regulation of the renin-angiotensin-aldosterone system (RAAS). Moreover, there is evidence of involvement in cardiovascular complications, as well as in the immune system disorders. Vitamin D values below 25ng/mL are related to an increase in vascular tone mediated by smooth muscle contraction. Furthermore, it can produce direct effects on vascular smooth muscle cells, RAAS over-regulation, modulation of calcium metabolism, and secondary hyperparathyroidism. All this predisposes patients to develop hypertrophy of the left ventricle and vascular wall, causing hypertension. In this work, a review is presented of the main mechanisms involved in the development of hypertension due to vitamin D deficiency. Among them are the link established between the levels of extra-mitochondrial inorganic phosphate, its main regulatory hormones -such as vitamin D-, the cardiovascular system, reactive oxygen species, and mitochondrial metabolism. The role of the mitochondrial vitamin D receptor and the regulation of the respiratory chain could influence arterial remodelling since its activation would reduce oxidative damage and preserve cell life. However, there are aspects not yet understood about the intricate signalling network that appeared simple in experimental trials, but complex in clinical studies. In this way, the completion of new studies as VITAL, could clarify, and thus support or refute the possible benefits of vitamin D in hypertensive cardiovascular disease.

Mitochondrial Homeostasis and Signaling in Parkinson's Disease.

The loss of dopaminergic (DA) neurons in the substantia nigra leads to a progressive, long-term decline of movement and other non-motor deficits. The symptoms of Parkinson's disease (PD) often appear later in the course of the disease, when most of the functional dopaminergic neurons have been lost. The late onset of the disease, the severity of the illness, and its impact on the global health system demand earlier diagnosis and better targeted therapy. PD etiology and pathogenesis are largely unknown. There are mutations in genes that have been linked to PD and, from these complex phenotypes, mitochondrial dysfunction emerged as central in the pathogenesis and evolution of PD. In fact, several PD-associated genes negatively impact on mitochondria physiology, supporting the notion that dysregulation of mitochondrial signaling and homeostasis is pathogenically relevant. Derangement of mitochondrial homeostatic controls can lead to oxidative stress and neuronal cell death. Restoring deranged signaling cascades to and from mitochondria in PD neurons may then represent a viable opportunity to reset energy metabolism and delay the death of dopaminergic neurons. Here, we will highlight the relevance of dysfunctional mitochondrial homeostasis and signaling in PD, the molecular mechanisms involved, and potential therapeutic approaches to restore mitochondrial activities in damaged neurons.

[An integral view of cancer (III). Evaluation of new biomarkers and treatment strategies]. / Una visión integral del cáncer (III). Evaluación de nuevos biomarcadores y posibilidades de intervención.

We propose a comprehensive approach to oncological disease, based on a systemic consideration of biology, health and disease. Our two previous review articles focused on tumour microenvironment and the discovery of new biomarkers; here we discuss the practical application of these principles to pathology, through the identification, evaluation and quantitative analysis of new prognostic and predictive factors (Immunoscore, TIME). We also consider the clinical use of promising, better tolerated treatments, such as immunotherapy. The integrative pathologist now has access to the latest improved oncology stratification tools designed to identify effective treatment strategies, based on the natural evolution of clinical and scientific knowledge that transcend the gene-centric theory of cancer.

Commentary on mitochondrial stereology in transmission electron microscopy / Comentario sobre estereología mitocondrial en microscopía electrónica de transmisión

Mitochondria (m) are responsible for the energy availability of cells, and their analysis is indicated for example, in studies related to metabolism and oxidative stress. The direct measurement of mitochondria (morphometry) is biased because of the section obliquity and position relative to the mitochondria length (non-equatorial cut). Therefore, stereology is an appropriate technique to evaluate mitochondria. However, before beginning the study, it is necessary to consider the premises to obtain random and uniform samples to be analyzed stereology. Mitochondria must have the chance to appear in all the possibilities of cut and orientation in the micrographs. The number of micrographs to be analyzed will depend on the distribution and occupation of mitochondria in the cell. After this is resolved, a proposal is the estimation of the following stereological data: volume density (Vv), surface density (Sv), and mean cross-sectional area (A). Overlapping a known test area at each micrograph, the density by area of mitochondria is estimated (NAT). Vv [m] can easily be estimated by point-counting (Vv = Pp/PT; Pp are the points hitting the structure, PT are the number of points of the test system). Sv is estimated overlaying a test-line (LT) on the micrographs and counting the intersections of the lines (I) with the outer membrane (om), inner membrane (im), and crests (c), thus, Sv [om], Sv [im], Sv [c] (Sv = 2I / LT). A [m] is obtained as the ratio: A = Vv / 2NAT.

Las mitocondrias (m) son responsables de la disponibilidad de energía de las células, y su análisis está indicado, por ejemplo, en estudios relacionados con el metabolismo y el estrés oxidativo. La medición directa de las mitocondrias (morfometría) está sesgada debido a la oblicuidad de la sección y la posición relativa a la longitud de las mitocondrias (corte no ecuatorial). Por lo tanto, la estereología es una técnica apropiada para evaluar las mitocondrias. Sin embargo, antes de comenzar el estudio, es necesario considerar las premisas para obtener muestras aleatorias y uniformes para analizar estereológicamente. Es esencial que las mitocondrias tengan la posibilidad de aparecer en todas las posibilidades de corte y orientación en las micrografías. El número de micrografías que se analizarán dependerá de la distribución y ocupación de las mitocondrias en la célula. Una vez resuelto esto, una propuesta es la estimación de los siguientes datos estereológicos: densidad de volumen (Vv), densidad de superficie (Sv) y área de sección transversal media (A). Superponiendo un área de prueba conocida en cada micrografía, se estima la densidad por área de mitocondrias (NAT). Vv [m] se puede estimar fácilmente contando puntos (Vv = Pp / PT; Pp son los puntos que llegan a la estructura, PT son el número de puntos del sistema de prueba). Sv se estima superponiendo una línea de prueba (LT) en las micrografías y contando las intersecciones de las líneas (I) con la membrana externa (om), la membrana interna (im) y las crestas (c), por lo tanto, Sv [om], Sv [im], Sv [c] (Sv = 2I / LT). A [m] se obtiene como la relación: A = Vv / 2NAT.

MOTOR NEURON LOSS IN AGING AND AMYOTROPHIC LATERAL SCLEROSIS: DIFFERENT FUSE LENGTHS, SAME EXPLOSION.

Advanced age and amyotrophic lateral sclerosis (ALS) are both associated with a loss of motor neurons resulting in muscle fiber atrophy and muscle weakness. Aging associated muscle fiber atrophy and weakening is termed sarcopenia, but the association with motor neuron loss is not as clearly established as in ALS, probably related to the prolonged time course of aging-related changes. Although aging and ALS effects on limb muscle strength and neuromotor performance are serious, such effects on the diaphragm muscle can be life threatening. Converging evidence indicates that larger phrenic motor neurons, innervating more fatigable type IIx and/or IIb diaphragm muscle fibers (fast fatigue intermediate, FInt and fast fatigable, FF motor units) are more susceptible to degeneration with both aging and ALS compared to smaller phrenic motor neurons innervating type I and IIa diaphragm muscle fibers (slow and fast fatigue resistant motor units, respectively). The etiology of ALS and age-related loss of motor neurons appears to involve mitochondrial function and neuroinflammation, both chronic and acute exacerbation. How mitochondrial dysfunction, neuroinflammation and motor neuron size intersect is the focus of continuing investigation.

La edad avanzada y la esclerosis lateral amiotrofica (ALS) están asociadas con una pérdida de neuronas motoras que produce atrofia de las fibras musculares y debilidad muscular. El envejecimiento asociado a atrofia y debilitamiento de las fibras musculares se denomina sarcopenia, pero la asociación con la pérdida de neuronas motoras no está tan claramente establecida como en la ALS, hecho probablemente relacionado con el curso prolongado de los cambios que ocurren durante el envejecimiento. Aunque el envejecimiento y los efectos de la ALS sobre la fuerza muscular de las extremidades y el rendimiento neuromotor son graves, tales efectos sobre el músculo del diafragma pueden ser potencialmente mortales. La evidencia convergente indica que las neuronas motoras frénicas más grandes, que inervan fibras musculares de diafragma tipo IIx y / o IIb más fatigables (unidades motoras FF de fatiga rápida intermedia, FInt y fatigable rápida) son más susceptibles a la degeneración con el envejecimiento y la ALS en comparación con las neuronas motoras más pequeñas del nervio frénico que inervan las fibras musculares del diafragma tipo I y IIa (unidades motoras lentas y rápidas resistentes a la fatiga, respectivamente). La etiología de la ALS y la pérdida de neuronas motoras relacionadas con la edad parece implicar la función mitocondrial y la neuroinflamación, tanto la exacerbación crónica como la aguda. La forma en que se cruzan la disfunción mitocondrial, la neuroinflamación y el tamaño de la neurona motora es el foco de una continua investigación.

Emerging evidence for crosstalk between Nrf2 and mitochondria in physiological homeostasis and in heart disease.

Nrf2 regulates redox homeostasis in cells by coordinately regulating a range of antioxidant enzymes and proteins. An increase in oxidative stress is one of the hallmarks of aging, and Nrf2 protein levels and activity decrease with aging. Decreased mitochondrial functions, such as decreased ATP production, also occur with aging, leading to the increased generation of reactive oxygen species (ROS) and oxidative stress. Thus, understanding the relationships between Nrf2 and the mitochondria is important for clarifying the regulatory mechanisms of aging. It is becoming clear that Nrf2 is activated in a tissue-specific manner in response to mitochondrial or NADPH oxidase-generated ROS. As the heart consists of postmitotic cells that utilize ATP produced mainly by mitochondrial oxidative phosphorylation, cardiomyocytes are equipped with highly sophisticated mitochondrial quality control mechanisms. Consistent with these findings, it has been reported that Nrf2 in the heart is regulated via a specific translational mechanism and that Nrf2 activation confers cardioprotective effects in various disease models. Thus, Nrf2 is a promising target for anti-aging strategies to combat age-related heart diseases, such as age-related cardiomyopathy.

Brain oxidative damage in murine models of neonatal hypoxia/ischemia and reoxygenation.

The brain is one of the main organs affected by hypoxia and reoxygenation in the neonatal period and one of the most vulnerable to oxidative stress. Hypoxia/ischemia and reoxygenation leads to impairment of neurogenesis, disruption of cortical migration, mitochondrial damage and neuroinflammation. The extent of the injury depends on the clinical manifestation in the affected regions. Preterm newborns are highly vulnerable, and they exhibit severe clinical manifestations such as intraventricular hemorrhage (IVH), retinopathy of prematurity (ROP) and diffuse white matter injury (DWMI) among others. In the neonatal period, the accumulation of high levels of reactive oxygen species exacerbated by the immature antioxidant defense systems in represents cellular threats that, if they exceed or bypass physiological counteracting mechanisms, are responsible of significant neuronal damage. Several experimental models in mice mimic the consequences of perinatal asphyxia and the use of oxygen in the reanimation process that produce brain injury. The aim of this review is to highlight brain damage associated with oxidative stress in different murine models of hypoxia/ischemia and reoxygenation.

Dinámica mitocondrial en las enfermedades neurodegenerativas.

Neurodegenerative diseases are a group of heterogeneous diseases characterized by a gradual, progressive and selective decrease in nervous system functions. The etiology of these pathologies remains unknown; however, mitochondrial function has been proposed as a common factor that could be involved in the establishment of these diseases, owing to the high energy requirement neurons have in order to carry out their physiological functions. Mitochondria are extremely dynamic organelles that can change their morphology and function in response to different physiological stimuli and, for this reason, mitochondrial dynamics have started being studied as one of cell survival main regulators. This event comprises different processes, such as the generation of new mitochondria and their elimination when they are no longer functional, as well as mitochondrial fusion and fission processes and the traffic of these organelles within the cellular environment. All these processes are highly regulated, and their main purpose is optimal functionality of mitochondria and cellular homeostasis.

Las enfermedades neurodegenerativas son un grupo heterogéneo caracterizado por la disminución gradual, progresiva y selectiva de las funciones del sistema nervioso. La etiología de estas patologías aún se desconoce, sin embargo, se ha propuesto que la función mitocondrial pudiese estar participando en el establecimiento de estas enfermedades, debido al alto requerimiento energético que tienen las neuronas para realizar sus funciones fisiológicas. La mitocondria es un organelo dinámico que puede cambiar su morfología y función en respuesta a diferentes estímulos fisiológicos, por ello se ha empezado a estudiar a la dinámica mitocondrial como uno de los principales reguladores de la supervivencia celular. Este evento comprende diferentes procesos como la generación de nuevas mitocondrias y su eliminación cuando ya no son funcionales, así como los procesos de fusión y fisión mitocondrial y el tráfico de estos organelos en el entorno celular. Todos estos procesos son altamente regulados y tienen como finalidad la óptima funcionalidad de la mitocondria y la homeostasis celular.

Dinámica mitocondrial en las enfermedades neurodegenerativas / Mitochondrial dynamics in neurodegenerative diseases

Resumen Las enfermedades neurodegenerativas son un grupo heterogéneo caracterizado por la disminución gradual, progresiva y selectiva de las funciones del sistema nervioso. La etiología de estas patologías aún se desconoce, sin embargo, se ha propuesto que la función mitocondrial pudiese estar participando en el establecimiento de estas enfermedades, debido al alto requerimiento energético que tienen las neuronas para realizar sus funciones fisiológicas. La mitocondria es un organelo dinámico que puede cambiar su morfología y función en respuesta a diferentes estímulos fisiológicos, por ello se ha empezado a estudiar a la dinámica mitocondrial como uno de los principales reguladores de la supervivencia celular. Este evento comprende diferentes procesos como la generación de nuevas mitocondrias y su eliminación cuando ya no son funcionales, así como los procesos de fusión y fisión mitocondrial y el tráfico de estos organelos en el entorno celular. Todos estos procesos son altamente regulados y tienen como finalidad la óptima funcionalidad de la mitocondria y la homeostasis celular.

Abstract Neurodegenerative diseases are a group of heterogeneous diseases characterized by a gradual, progressive and selective decrease in nervous system functions. The etiology of these pathologies remains unknown; however, mitochondrial function has been proposed as a common factor that could be involved in the establishment of these diseases, owing to the high energy requirement neurons have in order to carry out their physiological functions. Mitochondria are extremely dynamic organelles that can change their morphology and function in response to different physiological stimuli and, for this reason, mitochondrial dynamics have started being studied as one of cell survival main regulators. This event comprises different processes, such as the generation of new mitochondria and their elimination when they are no longer functional, as well as mitochondrial fusion and fission processes and the traffic of these organelles within the cellular environment. All these processes are highly regulated, and their main purpose is optimal functionality of mitochondria and cellular homeostasis.

Effects of nutritional status on mitochondrial Ca2+ handling / Efeitos do estado nutricional no manejo de Ca2+ mitocondrial

Mitochondria are central players in cell metabolism, responsible for the vast majority of ATP production in most cells. Although originally thought to be passive organelles focused only in keeping cellular ATP at adequate levels, complex interplay between mitochondrial function and cell signaling has been largely recognized over the last decades. Not surprisingly, given their role, changes in nutritional status promoted by chronic interventions like caloric restriction or short-term situations like fasting in animals or nutrient deprivation in cultured cells are one of the main factors that can activate those signaling mechanisms. One particular way in which this mitochondria-cell crosstalk can occur is through mitochondrial Ca2+ handling, a process in which Ca2+ signals generated by the cell are able to translate into elevations in mitochondrial matrix [Ca2+] due to the presence of the mitochondrial Ca2+ uniporter in the organelle. While the impact of mitochondrial Ca2+ handling on cellular function has been widely studied, the conditions which can modulate the process of mitochondrial Ca2+ handling itself are still not well characterized. In this work, we sought to test the effects of different interventions linked to nutritional status on mitochondrial Ca2+ handling. We found that caloric restriction, physiological fasting and modulations of mitochondrial dynamics resulted in modulation of mitochondrial Ca2+ handling through changes in their maximal Ca2+ retention capacity or Ca2+ uptake rates. These changes were, measured by following mitochondrial Ca2+ uptake using different strategies, employing the fluorescent Ca2+ probe Ca2+ Green 5N for experiments in isolated mitochondria and permeabilized cells and the cytosolic probe Fura2-AM in intact cells. Caloric restriction resulted in higher calcium uptake and retention in liver mitochondria, protecting against pathological conditions of Ca2+ overload during ischemia/reperfusion. On the other hand, overnight and short term fasting resulted in lower mitochondrial Ca2+ retention and oxidative phosphorylation capacity in the liver. Modulating mitochondrial morpholoy in C2C12 myoblasts showed that more fragmented mitochondria were less capable of taking up Ca2+, while more fusioned mitochondria showed the opposite phenotype. This modulation in Ca2+ handling through changes in mitochondrial morphology interfered with the process of Store-Operated Ca2+ entry in the cells, showing that these modulations can have impacts in physiological contexts as well. Overall, this work both establishes novel mechanisms of modulation of mitochondrial Ca2+ handling and demonstrates their relevance both in pathology and normal cellular physiology

Mitocôndrias possuem um papel central no metabolismo das células, sendo responsáveis pela maioria da produção de ATP na maioria dos tipos celulares. Embora originalmente se pensasse nas mitocôndrias como organelas estáticas, focadas somente em manter os níveis adequados de ATP na célula, a interação entre a função mitocondrial e a sinalização celular tem sido fortemente reconhecida nas ultimas décadas. Dado este papel, não é surpreendente que mudanças no estado nutricional, tanto crônicas como na restrição calórica quanto em situações como o jejum em animais e a privação de nutrientes em cultura de células foram demonstradas como sendo um dos principais fatores que podem ativar estes mecanismos de sinalização. Uma das formas em que esta interação entre a mitocôndria e a célula ocorre é através do manejo de Ca2+ mitocondrial, um processo em que sinais de Ca2+ gerados pela célula podem resultar em aumentos na [Ca2+] na matriz mitocondrial devido à presença do uniportador de Ca2+ mitocondrial na organelaEmbora o impacto do manejo de Ca2+ mitocondrial na função da célula tenha sido amplamente estudado, a regulação do processo de manejo de Ca2+ mitocondrial em si não é bem conhecida. Neste trabalho, nós nos propusemos a testar os efeitos de diferentes intervenções ligadas ao estado nutricional no manejo de Ca2+ mitocondrial e o possível impacto destas modulações nacapacidade de retenção e na taxa de captação de Ca2+ mitochondrial. As intervenções estudadas foram a restrição calórica, jejum e mudanças na dinâmica mitocondrial, e todas elas resultando em mudanças no manejo de Ca2+ mitocondrial, que foram medidos acompanhando a captação de Ca2+ em mitocôndrias isoladas ou células permeabilizadas utilizando a sonda Ca2+ Green 5N e em células intactas utilizando a sonda de Ca2+ citosólica Fura2-AM. Enquanto a restrição calórica resultou em uma maior capacidade de retenção de Ca2+ e em maiores taxas de captação, protegendo contra as condições patológicas de desregulação de Ca2+ observadas durante a isquemia/reperfusão, o jejum curto ou pela duração da noite resultou em uma diminuição na capacidade de retenção de Ca2+ e na oxidação fosforilativa mitocondriais. As mudanças observadas modulando a dinâmica mitocôndria (feitas utilizando-se mioblastos da linhagem C2C12) revelaram que mitocôndrias mais fragmentadas são menos capazes de captar Ca2+, enquanto mitocôndrias mais fusionadas possuem o fenótipo oposto. Essas mudanças no manejo de Ca2+ mitocondrial interferem com o processo de Store-Operated Ca2+ entry nestas células, demonstrando que essas modulações da captação de Ca2+ mitocondrial também podem ser relevantes em contextos fisiológicos. Em resumo, este trabalho ajudou a estabelecer novos mecanismos de modulação do manejo de Ca2+ mitocondrial que podem ser relevantes tanto em condições patológicas quanto na fisiologia normal das células

La teoría del estrés oxidativo como causa directa del envejecimiento celular / The theory of oxidative stress as a direct cause of cell aging

La pérdida de las capacidades funcionales, el envejecimiento y la muerte son inherentes a toda la materia viva debido a que el metabolismo y otros factores son causantes de la formación de sustancias que dañan irreparablemente los componentes de la arquitectura celular. Con el objetivo de actualizar sobre los últimos hallazgos que explican el papel del estrés oxidativo sobre el envejecimiento celular se realiza la presente revisión bibliográfica. Se concluyó que el oxígeno, necesario para la viabilidad celular, y otras sustancias exógenas muestran toxicidad pues dan lugar a la formación de los radicales libres, cuya acción es la causa fundamental del envejecimiento. Además, la administración de antioxidantes es muy importante para prevenir el envejecimiento y mejorar la calidad de vida de la población.

The loss of functional capacities, aging and death are inherent to all living matter due to metabolism and other factors causing the formation of substances which damage irreversibly cell structure components. With the objective of updating about the last findings which explain the role of oxidative stress on cell aging, a bibliographic review is done. It is concluded that oxygen which is necessary for cell viability and other exogenous substances show toxicity since they lead to the formation of free radicals whose action is the main cause of aging. In addition, the administration of anti- oxidants is very important to prevent aging and improve the population´s quality of life.

Cancer and mitochondrial function / El cáncer en la función mitochondrial

Abstract Metabolism alterations are associated with the loss of mitochondrial function in tumor cells. Current research discuss whether such loss is evident in function itself, or if cells can provide maximum stability to its functions. More studies are needed to determine the behavior of cancer in mitochondria. Tumor cells experience a limitation of oxygen and mutations in oncogenes, tumor suppressor genes and enzymes of the glycolytic pathway and/or mitochondrial oxidative metabolism, thus allowing the formation of aggressive cancer. This article is the result of a literature review of the scientific evidence that has been presented in the latest research on cancer and mitochondrial function.

Resumen Se ha descrito que algunas alteraciones del metabolismo están asociadas con la pérdida de función mitocondrial en células tumorales. Aún se discute si tal pérdida se evidencia en la función o si la célula brinda máxima estabilidad a sus funciones, se requieren más estudios para conocer el comportamiento del cáncer en la mitocondria. Cuando tiene limitación de oxígeno y mutaciones en oncogenes, genes supresores de tumor y enzimas de la vía glucolítica o del metabolismo oxidativo mitocondrial, la célula tumoral permite la formación de un cáncer agresivo. Este artículo es producto de la revisión bibliográfica de la evidencia científica que se ha presentado en las últimas investigaciones respecto al cáncer y la función mitocondrial.

Mitochondrial oxidative stress and cardiac ageing. / Estrés oxidativo mitocondrial y envejecimiento cardíaco.

According with different international organizations, cardiovascular diseases are becoming the first cause of death in western countries. Although exposure to different risk factors, particularly those related to lifestyle, contribute to the etiopathogenesis of cardiac disorders, the increase in average lifespan and aging are considered major determinants of cardiac diseases events. Mitochondria and oxidative stress have been pointed out as relevant factors both in heart aging and in the development of cardiac diseases such as heart failure, cardiac hypertrophy and diabetic cardiomyopathy. During aging, cellular processes related with mitochondrial function, such as bioenergetics, apoptosis and inflammation are altered leading to cardiac dysfunction. Increasing our knowledge about the mitochondrial mechanisms related with the aging process, will provide new strategies in order to improve this process, particularly the cardiovascular ones.