ABSTRACT
Em seu ambiente natural, as condições de água e temperatura são altamente variáveis, e podem afetar a sobrevivência, o crescimento e reprodução das plantas. Para sobreviver em tais condições, as plantas respondem, desenvolvendo uma complexa rede de sinalização em nível molecular, celular e bioquímico. A regulação gênica em nível de transcrição é um dos principais pontos no controle dos processos biológicos, sendo que os fatores de transcrição (TFs) desempenham um papel fundamental nesse processo. A família AP2/ERF é uma grande família de TFs específico de plantas que compartilham um domínio conservado de ligação ao DNA. Essa família de TFs incluía proteínas da subfamília DREB que desempenham um papel crucial na resposta das plantas a estresses abióticos, reconhecendo o elemento responsivo à desidratação com um motivo central A/GCCGAC. As proteínas da subfamília de fatores de resposta ao etileno estão envolvidas em respostas aos estresses bióticos e abióticos, reconhecendo o elemento cis-acting AGCCGCC denominado GCC-box. Nesta revisão foi discutido o papel dos TFs AP2/ERF em condições de estresse abiótico e suas implicações funcionais em estudos de expressão gênica. A compreensão dos determinantes genéticos da tolerância aos estresses abióticos constitui um passo importante nos programas de melhoramento genético.
In their natural environment, temperature and water conditions are highly variable and may affect the survival, growth and reproduction of plants. In order to survive under such conditions, plants respond by developing a complex network of signaling at molecular, cellular and biochemical level. The gene regulation at the transcription level is one of the major points in the control of biological processes, and transcription factors play a key role in this process. The AP2/ERF family is a large family of plant-specific transcription factors that share a conserved DNA-binding domain. This transcription factor family includes a subfamily of DREB proteins that plays a crucial role in the plant response to abiotic stresses, recognizing the dehydration responsive element with a central motif A/GCCGAC. The proteins from the subfamily of ethylene response factors are involved in responses to biotic and abiotic stresses recognizing the cis-acting element AGCCGCC called GCC-box. In this review, the authors discuss the role of AP2/ERF transcription factors in abiotic stress conditions and their functional implications in gene expression studies. Understanding the genetic determinants of abiotic stress tolerance is an important step in breeding programs.
En su ambiente natural, las condiciones del agua y temperatura son altamente variables, y pueden afectar la supervivencia, el crecimiento y reproducción de las plantas. Para sobrevivir en tales condiciones, las plantas responden, desarrollando una compleja red de señalización en nivel molecular, celular y bioquímico. La regulación génica en nivel de transcripción es uno de los principales puntos en el control de los procesos biológicos, considerando que los factores de transcripción (TFs) desempeñan un papel importante en ese proceso. La familia AP2/ERF es una gran familia de TFs específico de plantas que comparten un dominio conservado de unión al ADN. Esa familia de TFs incluye proteínas de la subfamilia DREB que desempeñan un papel crucial en la respuesta de las plantas a estreses abióticos, reconociendo el elemento responsivo a la deshidratación con un motivo central A/GCCGAC. Las proteínas de la subfamilia de factores de respuesta al etileno están involucradas en respuestas a los estreses bióticos y abióticos, reconociendo el elemento cis-acting AGCCGCC denominado GCC-box. En esta revisión se discutió el papel de los TFs AP2/ERF en condiciones de estrés abiótico y sus implicaciones funcionales en estudios de expresión génica. La comprensión de los determinantes genéticos de tolerancia a estreses abióticos constituye un paso importante en los programas de mejoramiento genético.
ABSTRACT
Growth factors, insulin signaling and nutrients are important regulators of β-cell mass and function. The events linking these signals to regulation of β-cell mass are not completely understood. Recent findings indicate that mTOR pathway integrates signals from growth factors and nutrients with transcription, translation, cell size, cytoskeleton remodeling and mitochondrial metabolism. mTOR is a part of two distinct complexes; mTORC1 and mTORC2. The mammalian TORC1 is sensitive to rapamycin and contains Raptor, deptor, PRAS40 and the G protein β-subunit-like protein (GβL). mTORC1 activates key regulators of protein translation; ribosomal S6 kinase (S6K) and eukaryote initiation factor 4E-binding protein 1. This review summarizes current findings about the role of AKT/mTORC1 signaling in regulation of pancreatic β cell mass and proliferation. mTORC1 is a major regulator of β-cell cycle progression by modulation of cyclins D2, D3 and cdk4/cyclin D activity. These studies uncovered key novel pathways controlling cell cycle progression in β-cells in vivo. This information can be used to develop alternative approaches to expand β-cell mass in vivo and in vitro without the risk of oncogenic transformation. The acquisition of such knowledge is critical for the design of improved therapeutic strategies for the treatment and cure of diabetes as well as to understand the effects of mTOR inhibitors in β-cell function.
Factores de crecimiento y nutrientes son reguladores muy importantes de la masa y función de las células β, pero las vías de señalización que unen estas señales a estos procesos no han sido completamente elucidadas. Estudios recientes han demostrado que la proteína mTOR integra señales provenientes de factores de crecimiento y disponibilidad de nutrientes con procesos celulares como transcripción, traducción, organización del citoesqueleto y metabolismo mitocondrial. mTOR puede hacer parte de dos complejos diferentes, mTORC1 y mTORC2. En el complejo mTORC1, la proteina mTOR la cual es sensible a rapamicina y se encuentra asociada a las proteínas Raptor, G β L, deptor y PRAS40, activa reguladores claves en la síntesis de proteínas, tales como la proteína cinasa ribosomal S6 (S6K) y la proteína de unión al factor eucariótico de iniciación 4E. El presente trabajo recopila información reciente sobre la participación de la vía de señalización AKT/mTORC1 en la regulación de la proliferación y masa de las células β del páncreas. mTORC1 regula la progresión del ciclo celular en células β, mediante la modulación de los niveles de las ciclinas D2 y D3 y la actividad del complejo Cdk4/ ciclina D. Estos estudios que revelan nuevos puntos de control del ciclo celular en células β, pueden ser utilizados en el desarrollo de nuevos enfoques para expandir la masa de células β, sin el riesgo de inducir una transformación oncogénica. Los resultados relacionados en el presente trabajo aportan información muy valiosa para el desarrollo de nuevas estrategias terapéuticas para el tratamiento la diabetes tipo 2.
Subject(s)
Humans , Cell Proliferation , Signal Transduction , Cell Cycle , Diabetes Mellitus , Islets of LangerhansABSTRACT
Em seu ambiente natural, as condições de água e temperatura são altamente variáveis, e podem afetar a sobrevivência,o crescimento e reprodução das plantas. Para sobreviver em tais condições, as plantas respondem, desenvolvendouma complexa rede de sinalização em nível molecular, celular e bioquímico. A regulação gênica em nível de transcrição éum dos principais pontos no controle dos processos biológicos, sendo que os fatores de transcrição (TFs) desempenham umpapel fundamental nesse processo. A família AP2/ERF é uma grande família de TFs específico de plantas que compartilhamum domínio conservado de ligação ao DNA. Essa família de TFs incluía proteínas da subfamília DREB que desempenhamum papel crucial na resposta das plantas a estresses abióticos, reconhecendo o elemento responsivo à desidratação com ummotivo central A/GCCGAC. As proteínas da subfamília de fatores de resposta ao etileno estão envolvidas em respostas aosestresses bióticos e abióticos, reconhecendo o elemento cis-acting AGCCGCC denominado GCC-box. Nesta revisão foi discutidoo papel dos TFs AP2/ERF em condições de estresse abiótico e suas implicações funcionais em estudos de expressãogênica. A compreensão dos determinantes genéticos da tolerância aos estresses abióticos constitui um passo importante nosprogramas de melhoramento genético.
In their natural environment, temperature and water conditions are highly variable and may affect the survival,growth and reproduction of plants. In order to survive under such conditions, plants respond by developing a complexnetwork of signaling at molecular, cellular and biochemical level. The gene regulation at the transcription level is one of themajor points in the control of biological processes, and transcription factors play a key role in this process. The AP2/ERFfamily is a large family of plant-specific transcription factors that share a conserved DNA-binding domain. This transcriptionfactor family includes a subfamily of DREB proteins that plays a crucial role in the plant response to abiotic stresses, recognizingthe dehydration responsive element with a central motif A/GCCGAC. The proteins from the subfamily of ethyleneresponse factors are involved in responses to biotic and abiotic stresses recognizing the cis-acting element AGCCGCC calledGCC-box. In this review, the authors discuss the role of AP2/ERF transcription factors in abiotic stress conditions and theirfunctional implications in gene expression studies. Understanding the genetic determinants of abiotic stress tolerance is animportant step in breeding programs.
In their natural environment, temperature and water conditions are highly variable and may affect the survival,growth and reproduction of plants. In order to survive under such conditions, plants respond by developing a complexnetwork of signaling at molecular, cellular and biochemical level. The gene regulation at the transcription level is one of themajor points in the control of biological processes, and transcription factors play a key role in this process. The AP2/ERFfamily is a large family of plant-specific transcription factors that share a conserved DNA-binding domain. This transcriptionfactor family includes a subfamily of DREB proteins that plays a crucial role in the plant response to abiotic stresses, recognizingthe dehydration responsive element with a central motif A/GCCGAC. The proteins from the subfamily of ethyleneresponse factors are involved in responses to biotic and abiotic stresses recognizing the cis-acting element AGCCGCC calledGCC-box. In this review, the authors discuss the role of AP2/ERF transcription factors in abiotic stress conditions and theirfunctional implications in gene expression studies. Understanding the genetic determinants of abiotic stress tolerance is animportant step in breeding programs constituye un paso importante en los programas de mejoramiento genético.
Subject(s)
Aquatic Environment/analysis , Stress, Mechanical , Abiotic Factors , Plants/classificationABSTRACT
En la última década se ha aportado clara evidencia de que tanto nucleósidos como nucleótidos de adenina y uridina pueden funcionar como factores de señalización extracelular. Su acción es mediada por dos tipos principales de receptores de superficie denominados purinérgicos. Los receptores P1 se activan por adenosina, y son todos metabotrópicos, mientras que los receptores de nucleótidos (ATP, ADP, UTP y UDP) y nucleótidos-azúcares (UDP-glucosa y UDP-galactosa) pueden ser metabotrópicos (P2Y) o ionotrópicos (P2X). La importancia y complejidad de este sistema de señalización se evidencia por la diversidad de mecanismos de liberación de nucleótidos al medio extracelular y por la distribución ubicua de varios grupos de ectonucleotidasas capaces de catalizar la degradación y conversión de nucleótidos. Hasta el momento se han descrito y clonado una veintena de estos receptores que modulan una variedad de respuestas, como el impulso nervioso, la respuesta inflamatoria, la secreción de insulina, la regulación del tono vascular y la percepción del dolor. En la presente revisión se describen las características estructurales y farmacológicas de los receptores purinérgicos y se analiza la interacción dinámica entre estos receptores, los nucleósidos y nucleótidos, y las ectonucleotidasas, con especial atención a la dinámica de la agregación plaquetaria, la respuesta inmune y la hidratación de las mucosas respiratorias.
In the last decade evidence accumulated that nucleosides and nucleotides of both uridine and adenine can act as extracellular signaling factors. Their action is mediated by two main types of surface receptors commonly known as purinergic. P1 receptors are metabotropic and activated by adenosine, whereas receptors for nucleotides (ATP, ADP, UTP and UDP) and nucleotide-sugars (UDP-glucose and UDP-galactose) can be either metabotropic (P2Y) or ionotropic (P2X). The importance and complexity of this signaling system is evidenced by various mechanisms of nucleotide release, as well as by the ibiquitous distribution of various types of ectonucleotidases which catalyze and convert extracellular nucleotides. Up to now about twenty receptors have been cloned and found to modulate the nerve impulse, inflammatory response, insuline secretion, the regulation of the vascular tone and nociception, among other processes. In the present review we describe the main structural and pharmacological features of purinergic receptors, and analyze how the dynamic interaction between these receptors, nucleotides and nucleosides, and ectonucleotidases modulate several biological responses. Particular focus is given to platelet aggregation and thrombus formation, the immune response and the hydration of the mucosal linings of the respiratory tract.