Revisiting the roles of VHR/DUSP3 phosphatase in human diseases

Protein tyrosine phosphatases have long been considered key regulators of biological processes and are therefore implicated in the origins of various human diseases. Heterozygosity, mutations, deletions, and the complete loss of some of these enzymes have been reported to cause neurodegenerative diseases, autoimmune syndromes, genetic disorders, metabolic diseases, cancers, and many other physiological imbalances. Vaccinia H1-related phosphatase, also known as dual-specificity phosphatase 3, is a protein tyrosine phosphatase enzyme that regulates the phosphorylation of the mitogen-activated protein kinase signaling pathway, a central mediator of a diversity of biological responses. It has been suggested that vaccinia H1-related phosphatase can act as a tumor suppressor or tumor-promoting phosphatase in different cancers. Furthermore, emerging evidence suggests that this enzyme has many other biological functions, such as roles in immune responses, thrombosis, hemostasis, angiogenesis, and genomic stability, and this broad spectrum of vaccinia H1-related phosphatase activity is likely the result of its diversity of substrates. Hence, fully identifying and characterizing these substrate-phosphatase interactions will facilitate the identification of pharmacological inhibitors of vaccinia H1-related phosphatase that can be evaluated in clinical trials. In this review, we describe the biological processes mediated by vaccinia H1-related phosphatase, especially those related to genomic stability. We also focus on validated substrates and signaling circuitry with clinical relevance in human diseases, particularly oncogenesis

Butyrate Protects Mice from Clostridium difficile-Induced Colitis through an HIF-1-Dependent Mechanism

Antibiotic-induced dysbiosis is a key factor predisposing intestinal infection by Clostridium difficile. Here, we show that interventions that restore butyrate intestinal levels mitigate clinical and pathological features of C. difficile-induced colitis. Butyrate has no effect on C. difficile colonization or toxin production. However, it attenuates intestinal inflammation and improves intestinal barrier function in infected mice, as shown by reduced intestinal epithelial permeability and bacterial translocation, effects associated with the increased expression of components of intestinal epithelial cell tight junctions. Activation of the transcription factor HIF-1 in intestinal epithelial cells exerts a protective effect in C. difficile-induced colitis, and it is required for butyrate effects. We conclude that butyrate protects intestinal epithelial cells from damage caused by C. difficile toxins via the stabilization of HIF-1, mitigating local inflammatory response and systemic consequences of the infection

Cloning of ACTH receptor from mouse Y1 adrenocortical cells and expression in to mouse 3T3 fibroblasts and AR-1 cells for the study of signal transduction pathways.

O hormônio adrenocorticotrópico, ACTH, regula função (esteroidogênese) e proliferação das células da córtex das glândulas adrenais através de um único receptor específico, ACTHR, que pertence à superfamília GPCR (G-protein coupled receptors). Embora o ACTHR tenha sido clonado há 8 anos, os mecanismos moleculares das ações mitogênica e anti-mitogênica de ACTH permanecem obscuros, cuja elucidação é objeto de estudo deste trabalho. A abordagem experimental consistiu na clonagem do ACTHR de células adrenocorticais Y-1 de camundongo e expressão funcional em fibroblastos 3T3 e células AR-1. Clones transfectantes, expressando estavelmente ACTHR, mostraram-se responsivos a ACTH através de: a) ativação de adenilato ciclase e b) indução de genes das famílias fos e jun. Por outro lado, medidas de síntese de DNA e proliferação celular indicam que ACTH não tem nenhum efeito mitogênico ou anti-mitogênico nos transfectantes ACTHR. O gene c-fos foi usado como alvo para testar vias de transdução de sinal ativadas por ACTH nos transfectantes 3T3 ACTHR. Estes testes mostraram que PKA, PKC e MAPK tem pouca ou nenhuma participação na indução de c-fos por ACTH nos clones 3T3 ACTHR, sugerindo que ACTHR pode ativar vias ainda não identificadas e motivando a busca de novas vias ativadas por ACTH nas células Y-1. Verificou-se que células Y-1 apresentam níveis constitutivamente elevados de AKT/PKB ativada (fosforilada), dependentes de PI3K e SRC, e que ACTH promove rápida desfosforilação de AKT via Gs/Adenilato Ciclase/cAMP/PKA. Ao promover a inativação de AKT, ACTH promove simultaneamente a indução da proteína p27'IND.Kip1', um mecanismo que contribui para a atividade anti-mitogênica de ACTH.The adrenocorticotropic hormone, ACTH, regulates both function and proliferation of adrenocortical cells binding to a specific receptor, ACTHR, which belongs to superfamily of GPCR (G-protein coupled receptors). ACTHR was cloned a few years ago, but the molecular mechanisms underlying the mitogenic and anti-mitogenic actions of ACTH remain unknown, whose elucidation is aim of this project. The experimental approach was to clone the ACTHR from mouse Y-1 adrenocortical cells and to express the functional receptor in Balb 3T3 fibroblasts and AR-1 cells. Transfectant clones stably expressing the ACTHR respond to ACTH treatments by: a) adenylate cyclase activation and b) induction of fos and jun genes. On the other hand, experiments of DNA synthesis and cellular proliferation showed that ACTH has not mitogenic or anti-mitogenic effects in ACTHR transfectants. c-fos gene was used as a target to test signal transduction pathways activated by ACTH into 3T3 ACTHR transfectants. The results showed that PKA, PKC and MAPK have no relevant contribution on the ACTH c-fos induction in 3T3 ACTHR transfectants suggesting that ACTHR can activate signal transduction pathways still not identified. This conclusion prompted us to search for another signal transduction pathways triggered by ACTHR in Y-1 adrenocortical cells. This search led to the detection of high constitutive levels of activated AKT/PKB in Y-1 adrenocortical cells, which are dependent on PI3K and SRC. ACTH causes a strong and rapid downregulation of activated AKT in a Gs/Adenylate Cyclase/cAMP/PKA dependent manner. Apparently, dephosphorylation of AKT promoted by ACTH releases transcription factors that induce p27'IND.Kip1', a likely mechanism underlying ACTH anti-mitogenic effects in adrenocortical cells

Cloning of ACTH receptor from mouse Y1 adrenocortical cells and expression in to mouse 3T3 fibroblasts and AR-1 cells for the study of signal transduction pathways.

O hormônio adrenocorticotrópico, ACTH, regula função (esteroidogênese) e proliferação das células da córtex das glândulas adrenais através de um único receptor específico, ACTHR, que pertence à superfamília GPCR (G-protein coupled receptors). Embora o ACTHR tenha sido clonado há 8 anos, os mecanismos moleculares das ações mitogênica e anti-mitogênica de ACTH permanecem obscuros, cuja elucidação é objeto de estudo deste trabalho. A abordagem experimental consistiu na clonagem do ACTHR de células adrenocorticais Y-1 de camundongo e expressão funcional em fibroblastos 3T3 e células AR-1. Clones transfectantes, expressando estavelmente ACTHR, mostraram-se responsivos a ACTH através de: a) ativação de adenilato ciclase e b) indução de genes das famílias fos e jun. Por outro lado, medidas de síntese de DNA e proliferação celular indicam que ACTH não tem nenhum efeito mitogênico ou anti-mitogênico nos transfectantes ACTHR. O gene c-fos foi usado como alvo para testar vias de transdução de sinal ativadas por ACTH nos transfectantes 3T3 ACTHR. Estes testes mostraram que PKA, PKC e MAPK tem pouca ou nenhuma participação na indução de c-fos por ACTH nos clones 3T3 ACTHR, sugerindo que ACTHR pode ativar vias ainda não identificadas e motivando a busca de novas vias ativadas por ACTH nas células Y-1. Verificou-se que células Y-1 apresentam níveis constitutivamente elevados de AKT/PKB ativada (fosforilada), dependentes de PI3K e SRC, e que ACTH promove rápida desfosforilação de AKT via Gs/Adenilato Ciclase/cAMP/PKA. Ao promover a inativação de AKT, ACTH promove simultaneamente a indução da proteína p27'IND.Kip1', um mecanismo que contribui para a atividade anti-mitogênica de ACTH.The adrenocorticotropic hormone, ACTH, regulates both function and proliferation of adrenocortical cells binding to a specific receptor, ACTHR, which belongs to superfamily of GPCR (G-protein coupled receptors). ACTHR was cloned a few years ago, but the molecular mechanisms underlying the mitogenic and anti-mitogenic actions of ACTH remain unknown, whose elucidation is aim of this project. The experimental approach was to clone the ACTHR from mouse Y-1 adrenocortical cells and to express the functional receptor in Balb 3T3 fibroblasts and AR-1 cells. Transfectant clones stably expressing the ACTHR respond to ACTH treatments by: a) adenylate cyclase activation and b) induction of fos and jun genes. On the other hand, experiments of DNA synthesis and cellular proliferation showed that ACTH has not mitogenic or anti-mitogenic effects in ACTHR transfectants. c-fos gene was used as a target to test signal transduction pathways activated by ACTH into 3T3 ACTHR transfectants. The results showed that PKA, PKC and MAPK have no relevant contribution on the ACTH c-fos induction in 3T3 ACTHR transfectants suggesting that ACTHR can activate signal transduction pathways still not identified. This conclusion prompted us to search for another signal transduction pathways triggered by ACTHR in Y-1 adrenocortical cells. This search led to the detection of high constitutive levels of activated AKT/PKB in Y-1 adrenocortical cells, which are dependent on PI3K and SRC. ACTH causes a strong and rapid downregulation of activated AKT in a Gs/Adenylate Cyclase/cAMP/PKA dependent manner. Apparently, dephosphorylation of AKT promoted by ACTH releases transcription factors that induce p27'IND.Kip1', a likely mechanism underlying ACTH anti-mitogenic effects in adrenocortical cells

Revisiting the roles of VHR/DUSP3 phosphatase in human diseases

Protein tyrosine phosphatases have long been considered key regulators of biological processes and are therefore implicated in the origins of various human diseases. Heterozygosity, mutations, deletions, and the complete loss of some of these enzymes have been reported to cause neurodegenerative diseases, autoimmune syndromes, genetic disorders, metabolic diseases, cancers, and many other physiological imbalances. Vaccinia H1-related phosphatase, also known as dual-specificity phosphatase 3, is a protein tyrosine phosphatase enzyme that regulates the phosphorylation of the mitogen-activated protein kinase signaling pathway, a central mediator of a diversity of biological responses. It has been suggested that vaccinia H1-related phosphatase can act as a tumor suppressor or tumor-promoting phosphatase in different cancers. Furthermore, emerging evidence suggests that this enzyme has many other biological functions, such as roles in immune responses, thrombosis, hemostasis, angiogenesis, and genomic stability, and this broad spectrum of vaccinia H1-related phosphatase activity is likely the result of its diversity of substrates. Hence, fully identifying and characterizing these substrate-phosphatase interactions will facilitate the identification of pharmacological inhibitors of vaccinia H1-related phosphatase that can be evaluated in clinical trials. In this review, we describe the biological processes mediated by vaccinia H1-related phosphatase, especially those related to genomic stability. We also focus on validated substrates and signaling circuitry with clinical relevance in human diseases, particularly oncogenesis