1,721,099 research outputs found
Functional asymmetry in phosphate transport and its regulation in opossum kidney cells: parathyroid hormone inhibition.
No full textThe sidedness (apical vs basolateral) of the inhibitory of phosphate (Pi) transport by parathyroid hormone (PTH) was investigated in opossum kidney (OK)-cell monolayers grown on permeant support. PTH was found to regulate the activity of only the apical Na Pi cotransporter, having no effect on the basolateral transport systems. Transport inhibition was approximately 100-fold more sensitive to apical PTH application (Kd: 5 x 10(-12) M) than to basolateral application (Kd: 5 x 10(-10) M). The time-course of the inhibitory response was identical from the two cell surfaces, with half-maximum inhibition occurring at about 20 min and almost full inhibition by 90 min. Experiments on diffusion and degradation demonstrated that the difference in Kd at the two cell surfaces was not due to differential metabolism or diffusion. Tests of cooperativity between the apical and basolateral regulatory events at intermediate concentrations suggested that the presence of PTH on one side of the monolayer reduced the scope of response from the other side. At maximum doses of PTH (10(-7)-10(-8) M) the transport inhibition from either side was equal and not additive. We conclude that in OK-cell monolayers grown on permeant support only apical Na/Pi co-transport is sensitive to PTH inhibition and that PTH receptor properties may be different on the apical and basolateral surfaces
Functional asymmetry of phosphate transport and its regulation in opossum kidney cells: phosphate transport.
No full textThe polarized distribution of phosphate (Pi) transport systems in a continuous renal cell line derived from opossum kidney (OK) was measured in monolayers grown on permeant filter support. When cultured on collagen-coated nitrocellulose filters, OK cells formed tight, functionally polarized monolayers. Three Pi transport systems were identified in these monolayers: one apical sodium (Na)-dependent system and two systems on the basolateral surface, one Na-dependent and one Na-independent. The apical system was high-affinity (Km = 0.4 mM Pi), low-capacity (Jmax = 1100 pmol Pi/mg protein per minute) with a Na:Pi stoichiometry greater than 1 (n = 3) and a high interaction coefficient (KNa = 105 mM Na). On the basolateral surface the Na-independent system comprised about 30% of the total Pi transport at this surface. Both basolateral systems were of low affinity (Km: Na-independent, 2.6 mM; Na-dependent, 5.2 mM) and high capacity (Jmax: Na-independent, 2100; Na-dependent, 2400 pmol/mg protein per minute). The basolateral Na-dependent system had a Nai stoichiometry of 1 and a relatively low interaction coefficient (KNa = 25 mM Na). Only the basolateral Na-independent system was inhibitable by 4,4'-diisothiocyanostilbene-2,2'-disulphonic acid (DIDS). These results are compatible with a net vectorial transcellular transport of Pi from the apical through the basolateral cell surfaces. The presence of a basolateral Na-dependent system may reflect additional metabolic requirements that cannot be met only by apical influx. Taken together, these results demonstrate the ability to grow cell monolayers successfully, displaying polarized transport activities similar to in situ
Role of pHi, and proton transporters in oncogene-driven neoplastic transformation
No full textThe change of a normal, healthy cell to a transformed cell is the first step in the evolutionary arc of a cancer. While the role of oncogenes in this 'passage' is well known, the role of ion transporters in this critical step is less known and is fundamental to our understanding the early physiological processes of carcinogenesis. Cancer cells and tissues have an aberrant regulation of hydrogen ion dynamics leading to a reversal of the normal tissue intracellular to extracellular pH gradient (ΔpHi to ΔpHe). When this perturbation in pH dynamics occurs during carcinogenesis is less clear. Very early studies using the introduction of different oncogene proteins into cells observed a concordance between neoplastic transformation and a cytoplasmic alkalinization occurring concomitantly with a shift towards glycolysis in the presence of oxygen, i.e. 'Warburg metabolism'. These processes may instigate a vicious cycle that drives later progression towards fully developed cancer where the reversed pH gradient becomes ever more pronounced. This review presents our understanding of the role of pH and the NHE1 in driving transformation, in determining the first appearance of the cancer 'hallmark' characteristics and how the use of pharmacological approaches targeting pH/NHE1 may open up new avenues for efficient treatments even during the first steps of cancer development
pH regulators in invadosomal functioning: Proton delivery for matrix tasting.
No full textInvadosomes are actin-rich finger-like cellular structures sensing and interacting with the surrounding extracellular matrix (ECM) and involved in its proteolytic remodeling. Invadosomes are structures distinct from other adhesion complexes, and have been identified in normal cells that have to cross tissue barriers to fulfill their function such as leukocytes, osteoclasts and endothelial cells. They also represent features of highly aggressive cancer cells, allowing them to escape from the primary tumor, to invade surrounding tissues and to reach systemic circulation. They are localized to the ventral membrane of cells grown under 2-dimensional conditions and are supposed to be present all around cells grown in 3-dimensional matrices. Indeed invadosomes are key structures in physiological processes such as inflammation and the immune response, bone remodeling, tissue repair, but also in pathological conditions such as osteopetrosis and the development of metastases. Invadosomes are subdivided into podosomes, found in normal cells, and into invadopodia specific for cancer cells. While these two structures exhibit differences in organization, size, number and half-life, they share similarities in molecular composition, participation in cell-matrix adhesion and promoting matrix degradation. A key determinant in invadosomal function is the recruitment and release of proteases, such as matrix metalloproteinases (MMPs), serine proteases and cysteine cathepsins, together with their activation in a tightly controlled and highly acidic microenvironment. Therefore numerous pH regulators such as V-ATPases and Na(+)/H(+) exchangers, are found in invadosomes and are directly involved in their constitution as well as their functioning. This review focuses on the participation of pH regulators in invadosome function in physiological and pathological conditions, with a particular emphasis on ECM remodeling by osteoclasts during bone resorption and by cancer cells
Differential responsiveness of proliferation and cytokeratin release to stripped serum and oestrogen in the human breast cancer cell line, MCF-7.
No full textIn vitro research into hormone sensitivity and the relation to proliferation of cytokeratin release from cancer cells is scarce. Therefore, we examined the stimulation of proliferation and the release of cytokeratins in a breast cancer cell culture model. Cell growth was stimulated by 17 beta-oestradiol (10(-11) M), stripped serum (10%) and by the two together. Cytokeratin release was stimulated only by stripped serum, oestradiol having no effect. After long incubation periods (> 12 h), cytokeratin release also commenced in the control and oestradiol treatments. Release rate versus time analysis suggested that there are two different release processes. Cytokeratin release was first stimulated at a stripped serum concentration approximately 100 times lower than that which initiated proliferation. Pharmacological alteration of proliferation with cordyceptin resulted in growth changes without alterations in cytokeratin release. We conclude that cytokeratin release in these cells is unrelated to proliferation, independent of oestrogen action and probably in some way related to growth factor receptor function
Brush-border inositol transport by intestines of carnivorous and herbivorous teleosts
No full textTransport characteristics of myoinositol by isolated brush-border membrane vesicles of two fish, the herbivorous tilapia (Oreochromis mossambicus) and the carnivorous eel (Anguilla anguilla), were measured. [3H]myoinositol uptake by vesicles of both fish was stimulated by a transmembrane Na gradient, was electrogenic, and was inhibited by phloridzin. Kinetic analysis of myoinositol influx disclosed species differences (tilapia, K = 0.15 mM, J(max) = 0.2 nmol·mg protein-1·min-1; eel, K = 2.6 mM, J(max) = 0.8 nmol·mg protein-1·min-1). D-Glucose inhibition of myoinositol influx was shown to be noncompetitive. Additional inhibition studies with a range of sugars demonstrated that aldohexoses in the C-1 chair conformation were preferred substrates. Myoinositol had no effect on D-glucose transport. Preloading vesicles with myoinositol transstimulated [3H]myoinositol uptake, while the use of internal D-glucose was without effect. These results suggest that the intestinal brush border may have a pathway for myoinositol transport entirely separate from that for D-glucose but inhibited by D-glucose via binding to a regulator site on the myoinositol transporter. Markedly dissimilar influx kinetic constants suggest possible differences in myoinositol needs by carnivorous and herbivorous fish
Parathyroid hormone-induced alterations of protein content and phosphorylation in enriched apical membranes of opossum kidney cells.
No full textParathyroid hormone (PTH) reduces Na/Pi co-transport activity in opossum kidney (OK) cells in a process mediated by protein kinases A and C. Further, inactivation of Na/Pi transport involves irreversible inhibition, possibly via internalization, of the transport system. This study analyzed alterations of concentration and phosphorylation of membrane proteins of an apically enriched preparation induced by short (10 min) and long (3 h) term incubation with 10(-10) M PTH of monolayer cultures of the OK-cell line. To this end, an apically enriched membrane fraction was isolated from cells grown on Petri dishes and analyzed by two-dimensional gel electrophoresis. Long term exposure of the cells to PTH induced changes in apical protein concentration. Four proteins were found to be decreased and one protein was found to be increased in its concentration. Addition of 10(-10) M PTH to the cells led to transient phosphorylation of five proteins. In contrast to transient phosphorylation, phosphorylation of one protein increased over the time period of 3 h. Combined analysis of silver staining and autoradiography led to the detection of an acidic 35-kDa protein in which specific phosphorylation increased over a time period of hours. The results document for the first time alterations in apical membrane protein content and phosphorylation state mediated by PTH when added to an intact cellular system. It is concluded that the identified proteins represent possible candidates for being involved directly or indirectly in PTH alterations of membrane transport
PRESERVATION OF GLUCOSE-TRANSPORT AND ENZYME-ACTIVITY IN FISH INTESTINAL BRUSH-BORDER AND BASOLATERAL MEMBRANE-VESICLES
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