ABSTRACT
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
Subject(s)
Calcium/analysis , Nutritional Status , Mitochondrial Dynamics , Cell Death/immunology , Myoblasts/classification , Mitochondria/chemistryABSTRACT
Para caracterizar a Febre Hemorrágica da Dengue no fígado através da resposta inflamatória, de citocinas e a morte celular dos hepatócitos foram analisados 17 casos de óbito no Brasil de 1999 a 2001, utilizando-se imuno-histoquímica e microscopia eletrônica. Foi observado que as lesões, o infiltrado inflamatório e a expressão de citocinas na FHD localizam-se em zona acinar 2 e o principal mecanismo de morte celular é a apoptose / To characterize the dengue hemorrhagic fever in the liver it were analyzed the inflammatory response, cytokines and the cellular death of hepatocytes by immunohistochemistry and electronic microscopy in 17 cases of death in Brazil from 1999 to 2001. It was observed that the injuries, inflammatory infiltrated and the expression of cytokines were localized in the midzone and the main mechanism of cellular death...
Subject(s)
Humans , Male , Female , Infant , Child, Preschool , Child , Adolescent , Adult , Middle Aged , Cytokines/analysis , Inflammation/immunology , Phenotype , Apoptosis/immunology , Severe Dengue/pathology , Liver/pathology , Immunohistochemistry , Microscopy, Electron , Cell Death/immunologyABSTRACT
Dendritic cells (DCs) play a key role in activating the immune response against invading pathogens as well as dying cells or tumors. Although the immune response can be initiated by the phagocytic activity by DCs, the molecular mechanism involved in this process has not been fully investigated. Trp-Lys-Tyr-Met-Val-Met-NH2 (WKYMVM) stimulates the activation of phospholipase D (PLD) via Ca2+ increase and protein kinase C activation in mouse DC cell line, DC2.4. WKYMVM stimulates the phagocytic activity, which is inhibited in the presence of N-butanol but not t-butanol in DC2.4 cells. Furthermore, the addition of phosphatidic acid, an enzymatic product of PLD activity, enhanced the phagocytic activity in DC2.4 cells. Since at least two of formyl peptide receptor (FPR) family (FPR1 and FPR2) are expressed in DC2.4 as well as in mouse bone marrow-derived dendritic cells, this study suggests that the activation of FPR family by WKYMVM stimulates the PLD activity resulting in phagocytic activity in DC2.4 cells.
Subject(s)
Animals , Mice , 1-Butanol/pharmacology , Bone Marrow Cells/cytology , Calcium Signaling/drug effects , Cell Death/immunology , Cell Line , Communicable Diseases/immunology , Dendritic Cells/immunology , Neoplasms/immunology , Oligopeptides/pharmacology , Phagocytosis/drug effects , Phosphatidic Acids/pharmacology , Phospholipase D/metabolism , Receptors, Formyl Peptide/metabolism , tert-Butyl Alcohol/pharmacologyABSTRACT
Sensitivity of Fas expressing tumor cells (high levels in Hut78 & Jurkat; low levels in P815) toward the cytotoxic Con-A (5 microg/ml) activated spleen cells from young (12 to 16 week old males) and old (2 year old males) mice were studied. The spleen cells from young mice activated for a day showed high levels of cytotoxic activity against Hut78 and Jurkat cell lines but not against P815 cells. The cytotoxic activity against P815 cells were detected in the spleen cells from old but not young mice following a longer period of Con-A activation (three days). Comparable levels of cytotoxic activity against Hut78 and Jurkat cells were observed in the spleen cells from both young and old mice following three days of activation. Treatment of Hut78 cells with anti-Fas antibody affected the tumor cells become resistant against the cytotoxic activity of the spleen cells from young mice in a dose dependent manner however P815 cells were not affect by the anti-Fas antibody treatment. These results show that there are differences in the sensitivity of target tumor cells toward Con-A induced cytotoxic spleen cells from young and old mouse. Mitogen-induced cytotoxic lymphocytes from young mouse spleen appear to kill targets through mechanisms involving Fas antigen, specially, in early stage (1 day) of activation. Old mouse spleen cells generated high levels of cytotoxic cells in later phase (3 days), which appear to kill through Fas-unrelated mechanisms.
Subject(s)
Humans , Mice , Age Factors , Animals , fas Receptor/immunology , Cell Death/immunology , Cells, Cultured , Concanavalin A , Cytotoxicity Tests, Immunologic , Flow Cytometry , Gene Expression Regulation/immunology , Jurkat Cells , Mice, Inbred Strains , Mitogens , Spleen/immunology , T-Lymphocytes/immunologyABSTRACT
The present study was carried out to mechanistically view a possible correlation between the process of, conjugate formation and its relation to target cell death. AK-5 killing is mediated by CD8+ natural killer cells through ADCC. Immune effectors on exposure to antibody primed AK-5 tumor cells formed tight conjugates. Ability of various cell types (NK, T, monocytes and macrophages) to form conjugates was evaluated. Marked increase in the number of NK cells binding to the target as compared to the other cell types was observed. Cytotoxicity of free and bound effectors against antibody tagged AK-5 cells demonstrated a reduced cytotoxic ability of the former in contrast to a significantly high lytic potential of the bound effectors. The results highlight the requirement for priming of NK cells which mediate killing of AK-5 tumor and provide additional evidence that formation of stable conjugates acts as the first signal for triggering lymphocyte activation and effective target cell lysis.