Long non-coding RNA CHCHD4P4 promotes epithelial-mesenchymal transition and inhibits cell proliferation in calcium oxalate-induced kidney damage

Kidney stone disease is a major cause of chronic renal insufficiency. The role of long non-coding RNAs (lncRNAs) in calcium oxalate-induced kidney damage is unclear. Therefore, we aimed to explore the roles of lncRNAs in glyoxylate-exposed and healthy mouse kidneys using microarray technology and bioinformatics analyses. A total 376 mouse lncRNAs were differentially expressed between the two groups. Using BLAST, 15 lncRNA homologs, including AU015836 and CHCHD4P4, were identified in mice and humans. The AU015836 expression in mice exposed to glyoxylate and the CHCHD4P4 expression in human proximal tubular epithelial (HK-2) cells exposed to calcium oxalate monohydrate were analyzed, and both lncRNAs were found to be upregulated in response to calcium oxalate. To further evaluate the effects of CHCHD4P4 on the cell behavior, we constructed stable CHCHD4P4-overexpressing and CHCHD4P4-knockdown HK-2 cells. The results showed that CHCHD4P4 inhibited cell proliferation and promoted the epithelial-mesenchymal transition in kidney damage and fibrosis caused by calcium oxalate crystallization and deposition. The silencing of CHCHD4P4 reduced the kidney damage and fibrosis and may thus be a potential molecular target for the treatment of kidney stones.

Purificação e caracterização da VDAC de mitocôndrias corticais aviares: identificação de modificações pós-traducionais nas porinas neuronais murinas e aviares / Purification and characterization of avian cortical mitochondrial VDAC: identification of post-translational modifications of rat and avian neuronal porins

A VDAC é uma porina presente na MME cuja função é crucial no metabolismo energético, sobrevivência e morte celular. A caracterização da VDAC torna-se importante para a compreensão das inter-relações da mitocôndria com os diferentes componentes citosólicos, tais como a HK. A ligação HK-VDAC favorece a utilização do ATP intramitocondrial em células neuronais, a HK cerebral pode interagir de formas diferentes com a VDAC, o que resulta em diferentes sítios de ligação (sítios A e B). Os variados papéis metabólicos das isoformas da VDAC podem ser explicados pela presença de alterações pós-traducionais. No presente trabalho purificamos a VDAC1 mitocondrial neuronal proveniente de cérebro aviar. Paralelamente, comprovamos que a presença de múltiplas formas das VDACs 1 e 2 em cérebros murino e aviar, seja devida à presença de modificações pós-traducionais, nomeadamente a fosforilação. A proteína isolada apresentou peso molecular de 30KDa. Quando submetida à eletroforese e posteriormente à coloração para a identificação de fosfoproteínas, a mesma mostrou-se desfosforilada. O conhecimento da presença, ou ausência de fosforilação das VDACs, reside na importância de estabelecer-se as bases moleculares ligadas à existência de sítios A e B nas mitocôndrias neuronais.

VDAC (voltage-dependent anion channel) is a pore forming protein from outer mitochondrial membrane. It has key functions on energetic metabolism, and cell death and survival. VDAC characterization is important for understanding mitochondrial interactions with cytosolic proteins, such as hexokinase (HK). HK-VDAC interaction supports preferential access to intramitochondrial ATP in neural cells. Brain HK interacts in different ways with VDAC. It results in two HK binding sites (A and B). VDAC isoforms differential metabolic roles may be explained by the presence of post-translational modifications. In this study we purified avian neuronal mitochondrial VDAC1. At same time we showed that VDACs 1 and 2 pI heterogeneity in rat and avian brains is due to phosphorylation. Purified VDAC had a molecular weight of 30 KDa. The purified VDAC submitted to phosphorylated protein staining on gel, was dephosphorylated. The knowledge of presence or absence of VDAC phosphorylation is important for understanding the molecular nature basis of A and B HK binding sites in brain mitochondria.

Implementación de un método mediante el uso de sustratos tritiados comoherramienta diagnóstica de la deficiencia de OCTN2 / Implementation of a method using tritiated substrates as a diagnostic tool for OCTN2 deficiency

Introducción: El transporte de carnitina dentro de la célula es mediado por el transportador mitocondrial de los ácidos grasos de cadena larga. La deficiencia primaria de carnitina se debe a una deficiencia del transportador OCTN2. Objetivos: El presente estudio tuvo como objetivo el análisis de las tasas de oxidación de sustratos tritiados por fibroblastos de pacientes que presentaban deficiencia primaria de carnitina y controles. Materiales y métodos: Fibroblastos de pacientes y controles se incubaron con [3H]-palmitato y [3H]-miristato y se determinó la oxidación de los mismos en nmol/h/mg proteína. Resultados: Encontrßndose deficiente la oxidación de sustratos tritiados en mßs de 60% por parte de los fibroblastos procedentes de los pacientes que presentaban la deficiencia de OCTN2. Conclusión: Esta técnica modificada permite el diagnóstico in vitro de la deficiencia primaria de carnitina.

Introduction: The transport of carnitine into the cell is mediated by a high-affinity sodium-dependent plasmalemmal carnitine transporter, OCTN2. Carnitine is a zwitterion essential for the mitochondrial oxidation of long-chain fatty acids. Primary carnitine deficiency is a consequence of the deficiency of OCTN2. Objective: The objective of the present study was to analyse the oxidation rate of tritiated substrates by fibroblasts from patients suffering OCTN2 deficiency and controls. Materials and methods: Fibroblasts from patients and controls were incubated with [3H]-palmitate and [3H]-miristate and the oxidation of these substrates were measured in nmol/hour/mg protein. Results: We found depressed the oxidation of tritiated substrates in fibroblasts from patients suffering the deficiency of OCTN2 in more than 60%.Conclusion: This modified technique enables us the in vitro diagnosis or primary carnitine deficiency.

A mechanistic view of mitochondrial death decision pores

Mitochondria increase their outer and inner membrane permeability to solutes, protons and metabolites in response to a variety of extrinsic and intrinsic signaling events. The maintenance of cellular and intraorganelle ionic homeostasis, particularly for Ca2+, can determine cell survival or death. Mitochondrial death decision is centered on two processes: inner membrane permeabilization, such as that promoted by the mitochondrial permeability transition pore, formed across inner membranes when Ca2+ reaches a critical threshold, and mitochondrial outer membrane permeabilization, in which the pro-apoptotic proteins BID, BAX, and BAK play active roles. Membrane permeabilization leads to the release of apoptogenic proteins: cytochrome c, apoptosis-inducing factor, Smac/Diablo, HtrA2/Omi, and endonuclease G. Cytochrome c initiates the proteolytic activation of caspases, which in turn cleave hundreds of proteins to produce the morphological and biochemical changes of apoptosis. Voltage-dependent anion channel, cyclophilin D, adenine nucleotide translocase, and the pro-apoptotic proteins BID, BAX, and BAK may be part of the molecular composition of membrane pores leading to mitochondrial permeabilization, but this remains a central question to be resolved. Other transporting pores and channels, including the ceramide channel, the mitochondrial apoptosis-induced channel, as well as a non-specific outer membrane rupture may also be potential release pathways for these apoptogenic factors. In this review, we discuss the mechanistic models by which reactive oxygen species and caspases, via structural and conformational changes of membrane lipids and proteins, promote conditions for inner/outer membrane permeabilization, which may be followed by either opening of pores or a rupture of the outer mitochondrial membrane.