ABSTRACT
Primary cilia are organelles that are present on many different cell types, either transiently or permanently. They play a crucial role in receiving signals from the environment and passing these signals to other parts of the cell. In that way, they are involved in diverse processes such as adipocyte differentiation and olfactory sensation. Mutations in genes coding for ciliary proteins often have pleiotropic effects and lead to clinical conditions, ciliopathies, with multiple symptoms. In this study, we reviewed observations from ciliopathies with obesity as one of the symptoms. It shows that variation in cilia-related genes is itself not a major cause of obesity in the population but may be a part of the multifactorial aetiology of this complex condition. Both common polymorphisms and rare deleterious variants may contribute to the obesity risk. Genotype-phenotype relationships have been noticed. Among the ciliary genes, obesity differs with regard to severity and age of onset, which may relate to the influence of each gene on the balance between pro- and anti-adipogenic processes. Analysis of the function and location of the proteins encoded by these ciliary genes suggests that obesity is more linked to activities at the basal area of the cilium, including initiation of the intraflagellar transport, but less to the intraflagellar transport itself. Regarding the role of cilia, three possible mechanistic processes underlying obesity are described: adipogenesis, neuronal food intake regulation and food odour perception.
Subject(s)
Cilia/physiology , Obesity/etiology , Adipogenesis/physiology , Biological Transport , Cell Differentiation , Cilia/genetics , Genetic Variation , Humans , Mutation , Obesity/physiopathology , Risk FactorsABSTRACT
La bacteriosis vascular de yuca producida por la bacteria Xanthomonas axonopodis pv. manihotis (Xam) es una enfermedad limitante para la producción de yuca. Dentro de los primeros factores de patogenicidad identificados en esta bacteria se encuentra el gen PthB. La proteína PthB pertenece a la familia de efectores PthA/AvrBs3, que se caracterizan por presentar dominios NLS (Nuclear Localization Signal) y un dominio AAD (Acidic Activation Domain), lo cual sugiere que estas proteínas actúan como factores de transcripción. La identificación de las proteínas de yuca que interactúan con PthB permitiría dar luces sobre la función de esta proteína en la patogenicidad de esta bacteria. En este trabajo se clonó PthB en una fusión traduccional con el BD (Binding Domain) del factor de transcripción GAL4. Después de transformar este constructo en una cepa de levadura, se observó autoactivación de los genes reporteros, incluso a concentraciones altas de 3-AT. La eliminación del primer, segundo o de los dos NLS y del AAD no eliminaron la capacidad de autoactivación de los genes reporteros mediada por PthB. Estos resultados indican la imposibilidad de su utilización en un tamizaje de una librería de ADNc de yuca para identificar las proteínas que interactúan con PthB.
Cassava bacterial blight disease is caused by the gram-negative bacteria Xanthomonas axonopodis pv. manihotis (Xam), and constitutes one of the most important constraints for cassava production. One of the first determinants of pathogenicity identified in this bacterium is the PthB gene. The PthB protein belongs to the PthA/AvrBs3 family, characterized by the presence of Nuclear Localization Signal (NLS) and Acidic Activation (AAD) domains, suggesting that these proteins are transcription factors. The identification of cassava proteins interacting with PthB could give insights about the function of this protein in the pathogenicity of this bacterium. In this work we cloned PthB in the yeast two hybrid expression vector pLAW10, generating a fusion protein with the Binding Domain (BD) of the transcription factor GAL4. In this work, PthB was cloned in a translational fusion with Gal4-BD (DNA Binding Domain). After transforming this construct into a yeast strain, autoactivation of the reporter genes was observed, even at the highest concentrations of 3-AT. The deletion of the first, second or both NLS and the AAD did not eliminate the ability of autoactivation of PthB. These results show the impossibility of using PthB to screen a cassava cDNA library to identify the proteins interacting with PthB.
