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J Fischbarg (2010)
Fluid transport across leaky epithelia: central role of the tight junction, and supporting role of aquaporinsPhysiol Rev, 90
AE Hill (1975)
Solute-solvent coupling in epithelia: a critical examination of the standing-gradient osmotic flow theoryProc R Soc Lond B, 190
S Hodson, F Miller (1976)
The bicarbonate ion pump in the endothelium which regulates the hydration of the rabbit corneaJ Physiol, 263
S Hodson (1974)
The regulation of corneal hydration by a salt pump requiring the presence of sodium and bicarbonate ionsJ Physiol, 236
M Hemlin (1995)
Fluid flow across the jejunal epithelia in vivo elicited by d-c current: effects of mesenteric nerve stimulationActa Physiol Scand, 155
RT Mathias, H Wang (2005)
Local osmosis and isotonic transportJ Membr Biol, 208
J Fischbarg (2003)
On the mechanism of fluid transport across corneal endothelium and epithelia in generalJ Exp Zool A, 300
J Bednarz, M Teifel, P Friedl, K Engelmann (2000)
Immortalization of human corneal endothelial cells using electroporation protocol optimized for human corneal endothelial and human retinal pigment epithelial cellsActa Ophthalmol Scand, 78
N Montalbetti, J Fischbarg (2009)
Frequency spectrum of transepithelial potential difference reveals transport-related oscillationsBiophys J, 97
S McLaughlin, RT Mathias (1985)
Electro-osmosis and the reabsorption of fluid in renal proximal tubulesJ Gen Physiol, 85
J Fischbarg, FP Diecke (2005)
The 9th world multi-conference on sytemics, cybernetics and informatics
K Kuang, M Yiming, Q Wen, Y Li, L Ma, P Iserovich, AS Verkman, J Fischbarg (2004)
Fluid transport across cultured layers of corneal endothelium from aquaporin-1 null miceExp Eye Res, 78
FP Diecke, Q Wen, J Kong, K Kuang, J Fischbarg (2004)
Immunocytochemical localization of Na+-HCO3- cotransporters in fresh and cultured bovine corneal endothelial cellsAm J Physiol, 286
B Cvenkel, S Stunf, I Srebotnik Kirbis, M Strojan Flezar (2015)
Symptoms and signs of ocular surface disease related to topical medication in patients with glaucomaClin Ophthalmol, 9
OA Candia, LJ Alvarez (2008)
Fluid transport phenomena in ocular epitheliaProg Retin Eye Res, 27
JM Sanchez, Y Li, A Rubashkin, P Iserovich, Q Wen, JW Ruberti, RW Smith, D Rittenband, K Kuang, FPJ Diecke, J Fischbarg (2002)
Evidence for a central role for electro-osmosis in fluid transport by corneal endotheliumJ Membr Biol, 187
FP Diecke, L Ma, P Iserovich, J Fischbarg (2007)
Corneal endothelium transports fluid in the absence of net solute transportBiochim Biophys Acta, 1768
MH Chang, WH Karasov (2004)
Absorption and paracellular visualization of fluorescein, a hydrosoluble probe, in intact house sparrows (Passer domesticus)Zoology (Jena), 107
JA Bonanno (2012)
Molecular mechanisms underlying the corneal endothelial pumpExp Eye Res, 95
A Rubashkin, P Iserovich, J Hernandez, J Fischbarg (2005)
Epithelial fluid transport: protruding macromolecules and space charges can bring about electro-osmotic coupling at the tight junctionsJ Membr Biol, 208
A Lyslo, S Kvernes, K Garlid, SK Ratkje (1985)
Ionic transport across corneal endotheliumActa Ophthalmol (Copenh), 63
EH Larsen (2002)
Hans H. Ussing–scientific work: contemporary significance and perspectivesBiochim Biophys Acta, 1566
AE Hill, B Shachar-Hill, Y Shachar-Hill (2004)
What are aquaporins for?J Membr Biol, 197
VI Cacace, N Montalbetti, C Kusnier, MP Gomez, J Fischbarg (2011)
Wavelet analysis of corneal endothelial electrical potential difference reveals cyclic operation of the secretory mechanismPhys Rev E, 84
J Fischbarg, FP Diecke, P Iserovich, A Rubashkin (2006)
The role of the tight junction in paracellular fluid transport across corneal endothelium. Electro-osmosis as a driving forceJ Membr Biol, 210
M Hirsch, G Renard, JP Faure, Y Pouliquen (1977)
Study of the ultrastructure of the rabbit corneal endothelium by the freeze-fracture technique: apical and lateral junctionsExp Eye Res, 25
PM Narula, M Xu, K Kuang, R Akiyama, J Fischbarg (1992)
Fluid transport across cultured bovine corneal endothelial cell monolayersAm J Physiol, 262
K Oshio, H Watanabe, Y Song, AS Verkman, GT Manley (2005)
Reduced cerebrospinal fluid production and intracranial pressure in mice lacking choroid plexus water channel Aquaporin-1Faseb J, 19
C Sofia Hernandez, E Gonzalez, G Whittembury (1995)
The paracellular channel for water secretion in the upper segment of the Malpighian tubule of Rhodnius prolixusJ Membr Biol, 148
DM Maurice (1972)
The location of the fluid pump in the corneaJ Physiol, 221
We have presented prior evidence suggesting that fluid transport results from electro-osmosis at the intercellular junctions of the corneal endothelium. Such phenomenon ought to drag other extracellular solutes. We have investigated this using fluorescein-Na2 as an extracellular marker. We measured unidirectional fluxes across layers of cultured human corneal endothelial (HCE) cells. SV-40-transformed HCE layers were grown to confluence on permeable membrane inserts. The medium was DMEM with high glucose and no phenol red. Fluorescein-labeled medium was placed either on the basolateral or the apical side of the inserts; the other side carried unlabeled medium. The inserts were held in a CO2 incubator for 1 h (at 37 °C), after which the entire volume of the unlabeled side was collected. After that, label was placed on the opposite side, and the corresponding paired sample was collected after another hour. Fluorescein counts were determined with a (Photon Technology) DeltaScan fluorometer (excitation 380 nm; emission 550 nm; 2 nm bwth). Samples were read for 60 s. The cells utilized are known to transport fluid from the basolateral to the apical side, just as they do in vivo in several species. We used 4 inserts for influx and efflux (total: 20 1-h periods). We found a net flux of fluorescein from the basolateral to the apical side. The flux ratio was 1.104 ± 0.056. That difference was statistically significant (p = 0.00006, t test, paired samples). The endothelium has a definite restriction at the junctions. Hence, an asymmetry in unidirectional fluxes cannot arise from osmosis, and can only point instead to paracellular solvent drag. We suggest, once more, that such drag is due to electro-osmotic coupling at the paracellular junctions.
The Journal of Membrane Biology – Springer Journals
Published: Mar 17, 2016
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