The microRNA biogenesis machinery: regulation by steroid hormones and alterations in cancer.

MicroRNAs are a class of non-coding RNAs that regulate gene expression at the post-transcriptional level. The major proteins of the canonical microRNA biogenesis pathway in human are: Drosha, DGCR8, DDX5, DDX17, Exportin 5, Dicer and Argonaute 2. Recent studies suggest that gene expression of some canonical microRNA biogenesis components could be regulated by steroid hormones. Furthermore, various alterations in microRNA biogenesis have been associated with diseases like cancer. Due to the importance of microRNAs in cell physiology, the study of the factors that regulate or affect their biogenesis is critical.

Apocynin protects against neurological damage induced by quinolinic acid by an increase in glutathione synthesis and Nrf2 levels.

Apocynin (APO) is a well-known NADPH oxidase (NOX) inhibitor. However, several studies have reported its ability to increase glutathione (GSH) levels. Due to GSH is a major non-enzymatic antioxidant in brain, the aim of this study was to evaluate, in the striatum of control and quinolinic acid (QUIN) injected rats, the effect of APO administration on: (1) GSH levels, (2) activity of some enzymes involved in the GSH metabolism, and (3) nuclear factor erythroid-2-related factor 2 (Nrf2) mRNA levels. Animals received QUIN 240nmol in right striatum and APO (5mg/kg, i.p.), 30min before and 60min after intrastriatal injection. APO treatment prevented the QUIN-induced histological damage to the striatum. In control rats, APO treatment increased GSH and Nrf2 mRNA levels and the activities of gamma-glutamylcysteine ligase (γ-GCL), glutathione-S-transferase (GST) and glutathione peroxidase (GPx). On the other hand, APO treatment prevented the QUIN-induced decrease in GSH and Nrf2 levels, and in γ-GCL and GPx activities. These data indicate that APO is able to increase GSH levels and the activity of proteins involved in its metabolism, which could be associated with its ability to increase the Nrf2 mRNA levels.

Ether a go-go potassium channels as human cervical cancer markers.

Ether a go-go (EAG) potassium channels display oncogenic properties. In normal tissues, EAG mRNA is almost exclusively expressed in brain, but it is expressed in several somatic cancer cell lines, including HeLa, from cervix. Antisense experiments against eag reduce cell proliferation in some cancer cell lines, and inhibition of EAG-mediated currents has been suggested to decrease cell proliferation in a melanoma cell line. Because of the potential clinical relevance of EAG, we investigated EAG mRNA expression in the following fresh samples from human uterine cervix: 5 primary cultures obtained from cancerous biopsies, 1 cancerous fresh tissue, and 12 biopsies of control normal tissue. All of the control cervical samples came from patients with negative pap smears. Reverse transcription-PCR and Southern-blot experiments revealed eag expression in 100% of the cancerous samples and in 33% of the normal biopsies. Immunochemistry experiments showed the presence of EAG channel protein in cells from the primary cultures and in cervical cancer biopsies sections from the same patients. In addition, we looked for EAG-mediated currents in the cultures from cervical cancer cells. Here we show for the first time EAG channel activity in human tumors. Patch-clamp recordings showed typical EAG-mediated currents modulated by magnesium and displaying a pronounced Cole-Moore shift. Because EAG expression and channel activity have been suggested to be important in cell proliferation, our findings strongly support the idea of considering EAG as a tumor marker as well as a potential membrane therapeutic target for cervical cancer.

Estrogens and human papilloma virus oncogenes regulate human ether-à-go-go-1 potassium channel expression.

Ether-à-go-go-1 (Eag1) potassium channels are potential tools for detection and therapy of numerous cancers. Here, we show human Eag1 (hEag1) regulation by cancer-associated factors. We studied hEag1 gene expression and its regulation by estradiol, antiestrogens, and human papillomavirus (HPV) oncogenes (E6/E7). Primary cultures from normal placentas and cervical cancer tissues; tumor cell lines from cervix, choriocarcinoma, keratinocytes, and lung; and normal cell lines from vascular endothelium, keratinocytes, and lung were used. Reverse transcription-PCR (RT-PCR) experiments and Southern blot analysis showed Eag1 expression in all of the cancer cell types, normal trophoblasts, and vascular endothelium, in contrast to normal keratinocytes and lung cells. Estradiol and antiestrogens regulated Eag1 in a cell type-dependent manner. Real-time RT-PCR experiments in HeLa cells showed that Eag1 estrogenic regulation was strongly associated with the expression of estrogen receptor-alpha. Eag1 protein was detected by monoclonal antibodies in normal placenta and placental blood vessels. Patch-clamp recordings in normal trophoblasts treated with estradiol exhibited potassium currents resembling Eag1 channel activity. Eag1 gene expression in keratinocytes depended either on cellular immortalization or the presence of HPV oncogenes. Eag1 protein was found in keratinocytes transfected with E6/E7 HPV oncogenes. Cell proliferation of E6/E7 keratinocytes was decreased by Eag1 antibodies inhibiting channel activity and by the nonspecific Eag1 inhibitors imipramine and astemizole; the latter also increased apoptosis. Our results propose novel oncogenic mechanisms of estrogen/antiestrogen use and HPV infection. We also suggest Eag1 as an early indicator of cell proliferation leading to malignancies and a therapeutic target at early stages of cellular hyperproliferation.

Transporte de aminoácidos zwitteriónicos en células de mamíferos / Zwitterionic amino acid transport in mammalian cell

El transporte de aminoácidos es un proceso de gran trascendencia metabólica ya que regula el flujo de aminoácidos entre la célula y el espacio extracelular. Los aminoácidos ingresan a las células de mamífero a través de proteínas de la membrana plasmática bien caracterizadas cinéticamente. El sistema A transporta aminoácidos zwitteriónicos de cadena lateral corta, y posiblemente participa en la regulación de la gluconeogénesis a partir de aminoácidos, especialmente alanina, así como también se le implica en la duplicación celular. El sistema N transporta aminoácidos con cadena lateral nitrogenada entre los que destacan la glutamina, importante en el control de la síntesis de proteínas. El sistema L permite el acceso de aminoácidos de cadena lateral larga como los aminoácidos aromáticos y de cadena ramificada. Este sistema generalmente constitutivo es crucial en el control del ingreso de estos aminoácidos hacia el cerebro, en donde algunos de ellos son precursores de neutrotransmisores. El transporte de aminoácidos se ha estudiado a nivel molecular partiendo de la clonación de los ácidos desoxirribonucleicos complementarios de varios transportadores, abriendo la posibilidad de realizar estudios estructurales y de regulación de su actividad y expresión. Se han descubierto isoformas de algunos transportadores de aminoácidos zwitteriónicos como el ASC, Gli, ß y de prolina, clasificados en una superfamilia de proteínas transportadoras de solutos que presentan de 6 a 12 dominios transmembrana. Esta revisión describe las generalidades del transporte de aminoácidos y de los adelantos recientes en el estudio de los sistemas de transporte de aminoácidos zwitteriónicos, enfatizando las características moleculares de los sistemas clonados y sus factores de regulación

Nuevos conocimientos del transporte de aminoácidos aniónicos y catiónicos / Advances in the study of anionic and cationic amino acid transport

En las células de mamíferos, los aminoácidos son captados por diferentes sistemas de transporte presentes en la membrana plasmática. Los sistemas de transporte originalmente se caracterizaron a través de estudios cinéticos y de competencias. Sin embargo, el asignamiento de algunos aminoácidos a un sistema de transporte específico había sido difícil. Con los avances en biología molecular ha sido posible identificar a las proteínas de los transportadores para aminoácidos específicos. En esta revisión se describen los sintomas de transporte para aminoácidos aniónicos y catiónicos que se han reportado a nivel molecular. Los aminoácidos aniónicos se movilizan principalmente a través de los sistemas XAG- y Xc-, los cuales son de particular relevancia en la inactivación de la transmisión nerviosa glutamatérgica en el cerebro y en la síntesis de glutation, respectivamente. Se han descrito cuatro isoformas cerebrales del sistema XAG- pertenecientes a la familia de transportadores de aminoácidos dependientes de Na+. Los sistemas de transporte para los aminoácidos catiónicos también reconocen sustratos zwitteriónicos, y los más estudiados son el y+, y+L, bº + y Bº + La regulación de la entrada de aminoácidos catiónicos tales como la arginina, lisina, y ornitina es importante en la biosíntesis de oxido nítrico, creatina, carnitina y poliaminas. La cisteinuría es un defecto hereditario asociado al sistema bº +