Cholera toxin (CT) represents a class of ligands that binds preferentially to noncoated pits on the cell surface. In the present study, we have investigated the mechanism of endocytosis of this class of ligand and compared it to the classic coated pit mechanism. When either CT coupled to colloidal gold particles (CT-gold) or '251-labeled CT were incubated with 3T3 Li fibroblasts at 40C, both ligands bound in a preferential fashion to small noncoated pits on the cell surface. CT-gold surface-labeled cells were then incubated at 220C. The labeled ligand progressively moved into noncoated vesicles and a tubulovesicular compartment composed of a network of tubules and vesicles closely associated with multivesicular bodies but distinct from the Golgi complexes. The ligand next passed into multivesicular bodies. By contrast, Co2-macroglobulin (a2m)-gold initially localized preferentially to coated pits and subsequently to coated vesicles and tubulovesicular structures before associating with multivesicular bodies. To directly compare the intracellular pathway followed by CT-gold to that followed by a2m-gold, CT-gold (7 nm) was coincubated with r2m-gold (15 nm). By 10 min of incubation at 22°C, up to 66% of tubulovesicular units contained both ligands when analyzed in serial sections. Subsequently, both ligands were colocalized in multivesicular bodies. We conclude that CT-gold endocytosed via noncoated vesicles and a2m-gold endocytosed through coated vesicles subsequently associate with the same tubulovesicular units, multivesicular bodies, and lysosomes.
Anti-Müllerian hormone (AMH) has been detected by RIA in the follicular fluid of mature bovine ovaries and in incubation medium of bovine granulosa cells. Purification of AMH from two independent batches of follicular fluid was achieved with a yield of 11% and 15% respectively. Both ovarian and control testicular AMH produced near-complete regression of fetal rat Müllerian ducts exposed to it in culture at a final concentration of 200-300 mU/ml and were recognized by the same monoclonal and polyclonal antibodies. These findings indicate that adult mammalian granulosa cells are capable of producing immunoreactive and bioactive AMH at a rate apparently similar to that already demonstrated for mature Sertoli cells and add yet another item to the homologies reported between male and female somatic gonadal cells.
BackgroundOzone is a major secondary air pollutant often reaching high concentrations in urban areas under strong daylight, high temperature and stagnant high-pressure systems. Ozone in the troposphere is a pollutant that is harmful to the plant.Principal FindingsBy exposing cells to a strong pulse of ozonized air, an acute cell death was observed in suspension cells of Arabidopsis thaliana used as a model. We demonstrated that O3 treatment induced the activation of a plasma membrane anion channel that is an early prerequisite of O3-induced cell death in A. thaliana. Our data further suggest interplay of anion channel activation with well known plant responses to O3, Ca2+ influx and NADPH-oxidase generated reactive oxygen species (ROS) in mediating the oxidative cell death. This interplay might be fuelled by several mechanisms in addition to the direct ROS generation by O3; namely, H2O2 generation by salicylic and abscisic acids. Anion channel activation was also shown to promote the accumulation of transcripts encoding vacuolar processing enzymes, a family of proteases previously reported to contribute to the disruption of vacuole integrity observed during programmed cell death.SignificanceCollectively, our data indicate that anion efflux is an early key component of morphological and biochemical events leading to O3-induced programmed cell death. Because ion channels and more specifically anion channels assume a crucial position in cells, an understanding about the underlying role(s) for ion channels in the signalling pathway leading to programmed cell death is a subject that warrants future investigation.
Plants, like other organisms, are facing multiple mechanical constraints generated both in their tissues and by the surrounding environments. They need to sense and adapt to these forces throughout their lifetimes. To do so, different mechanisms devoted to force transduction have emerged. Here we focus on fascinating proteins: the mechanosensitive (MS) channels. Mechanosensing in plants has been described for centuries but the molecular identification of MS channels occurred only recently. This review is aimed at plant biologists and plant biomechanists who want to be introduced to MS channel identity, how they work and what they might do in planta? In this review, electrophysiological properties, regulations, and functions of well-characterized MS channels belonging to bacteria and animals are compared with those of plants. Common and specific properties are discussed. We deduce which tools and concepts from animal and bacterial fields could be helpful for improving our understanding of plant mechanotransduction. MS channels embedded in their plasma membrane are sandwiched between the cell wall and the cytoskeleton. The consequences of this peculiar situation are analyzed and discussed. We also stress how important it is to probe mechanical forces at cellular and subcellular levels in planta in order to reveal the intimate relationship linking the membrane with MS channel activity. Finally we will propose new tracks to help to reveal their physiological functions at tissue and plant levels.
Responses of cells to mechanical stress are thought to be critical in coordinating growth and development. Consistent with this idea, mechanically activated channels play important roles in animal development. For example, the PIEZO1 channel controls cell division and epithelial-layer integrity and is necessary for vascular development in mammals. In plants, the actual contribution of mechanoperception to development remains questionable because very few putative mechanosensors have been identified and the phenotypes of the corresponding mutants are rather mild. Here, we show that the Arabidopsis Defective Kernel 1 (DEK1) protein, which is essential for development beyond early embryogenesis, is associated with a mechanically activated Ca2+ current in planta, suggesting that perception of mechanical stress plays a critical role in plant development.
A rare form of male pseudohermaphroditism is characterized by the persistence of Müllerian derivatives in phenotypic males. To determine the etiology of this syndrome, we studied the expression of anti-Müllerian hormone (AMH) in six boys, including three brothers, with the persistent Müllerian duct syndrome. All except one presented with an inguinal hernia containing the Müllerian derivatives, and in two boys the hernial sac contained the contralateral testis. AMH was normally expressed in the testicular tissue of two patients, as shown by bioassay of anti-Müllerian activity and immunocytochemistry. The testicular tissue of the other patients had no detectable bioactive or immunoreactive AMH, yet they expressed AMH mRNA with a normal transcription initiation site and in the amount expected for their age. These results prove the heterogeneity of the persistent Müllerian duct syndrome and suggest that it may sometimes involve peripheral insensitivity to AMH.
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