ABSTRACT
Los hepatocitos son células epiteliales polarizadas que, al ser aisladas y cultivadas, pierden la polaridad y las propiedades de célula diferenciada. El cultivo de células hepáticas como esferoides permite obtener estructuras con organización de tipo tisular. En este trabajo se analizó estructural y funcionalmente la polaridad de esferoides porcinos. Para ello, las células hepáticas porcinas fueron aisladas y cultivadas en agitación constante. La actividad metabólica de los esferoides fue probada mediante el metabolismo de diazepam y de amonio, así como con síntesis de albúmina. Sus características estructurales mostraron la polaridad de las células. Fueron observados paquetes de fibras de colágeno distribuidas irregularmente y fibras reticulares en formahomogénea en todo el volumen del esferoide. Se hallaron células Ck19+ formando estructuras tipo ducto biliar, así como también _ y _-cateninas y pan-cadherinas en diferentes zonas, especialmente en las laminas externas, con características de epitelio cuboidal. Por microscopía electrónica de barrido se observaron estructuras muy compactas con superficie lisa, y por microscopía electrónica de transmisión, canalículos biliares con microvellosidades, uniones tight, zonula adherens y desmosomas. Las organelas celulares como mitocondrias, núcleos, nucleolos, peroxisomas, retículo endoplásmico estaban bien conservadas. Una compleja red de canalículos biliares fue observada mediante la incorporación y excreción de un análogo de sal biliar fluorescente. El análisis de los ácidos biliares excretados mostró un patrón normal. La morfología y funcionalidad de los esferoides puede aportar un modelo apropiado para aplicaciones en las que es primordial mantener las funciones específicas del hígado, como un dispositivo de hígado bioartificial.
Hepatocytes are epithelial cells that show a complex polarity in vivo. However, hepatocytes isolated and cultured in vitro normally lose both their differentiated properties and polarity. Culturing hepatocyte spheroids seems to be the accurate approach to maintain tissue level of organization. The structural and functional polaritiesof pig liver spheroids were analyzed in this work. Swine liver cells were isolated and cultured as spheroids. Their metabolic activity was proved through the metabolism of diazepam, ammonium and synthesis of albumin. Several structural features show the presence of polarity in the cells inside the spheroids. Reticular and collagen fibers, as well as Ck19(+) cells forming duct-like structures were found. _eta and _-catenins and pancadherins were positive in different regions of the spheroids, mainly in the outer cell layers, which have cuboidal epithelia features. The scanning electron microscopy showed a tightly compacted architecture, with smooth surface. The transmission electron microscopy analysis showed bile canaliculi with microvilli, tight junctions, zonula adherens and desmosome-like junctions. Wellmaintained cellular organelles, as mitochondria, nucleus,nucleolus, peroxisomes, endoplasmic reticulum, were seen in the spheroids. A complex inner bile canaliculinetwork was shown by using a fluorescent bile acid analogue incorporated and excreted by the spheroids. Furthermore, excretion of a normal pattern of bile acids was demonstrated. The morphology and functionality of the spheroids may provide an appropriate model for applications where the maintenance of liver-specific functions is crucial, as a bioartificial liver device.
Subject(s)
Animals , Cell Polarity/physiology , Hepatocytes/cytology , Hepatocytes/physiology , Spheroids, Cellular/cytology , Spheroids, Cellular/physiology , Albumins/metabolism , Diazepam/metabolism , Fluorescent Antibody Technique , Hepatocytes/metabolism , Immunohistochemistry , Microscopy, Electron , Spheroids, Cellular/metabolism , Swine , Urea/metabolismABSTRACT
Cell fate decisions are governed by a complex interplay between cell-autonomous signals and stimuli from the surrounding tissue. In vivo cells are connected to their neighbors and to the extracellular matrix forming a complex three-dimensional (3-D) microenvironment that is not reproduced in conventional in vitro systems. A large body of evidence indicates that mechanical tension applied to the cytoskeleton controls cell proliferation, differentiation and migration, suggesting that 3-D in vitro culture systems that mimic the in vivo situation would reveal biological subtleties. In hematopoietic tissues, the microenvironment plays a crucial role in stem and progenitor cell survival, differentiation, proliferation, and migration. In adults, hematopoiesis takes place inside the bone marrow cavity where hematopoietic cells are intimately associated with a specialized three 3-D scaffold of stromal cell surfaces and extracellular matrix that comprise specific niches. The relationship between hematopoietic cells and their niches is highly dynamic. Under steady-state conditions, hematopoietic cells migrate within the marrow cavity and circulate in the bloodstream. The mechanisms underlying hematopoietic stem/progenitor cell homing and mobilization have been studied in animal models, since conventional two-dimensional (2-D) bone marrow cell cultures do not reproduce the complex 3-D environment. In this review, we will highlight some of the mechanisms controlling hematopoietic cell migration and 3-D culture systems.