Localization and regulation of trpv4 channels in CILIATED epithelia

Lorenzo Moldero, Ivan

24 July 2008

La neteja del moc i dels patògens dels pulmons, i el transport de gàmets i embrions en els òrgans reproductius de les femelles són funcions clau en els epitelis ciliats, tals com aquells que es troben presents en les vies respiratòries i l'oviducte. La taxa de transport mucociliar és funció de la freqüència de batut ciliar (CBF) i aquesta freqüència és augmentada per increments en la concentració de Ca2+ intracelul·lar. El canal catiònic "transient potential vanilloid 4" (TRPV4) intervé en l'entrada de Ca2+ en resposta a estímuls mecànics i osmòtics. L'expressió del TRPV4 en l'epiteli ciliat de les vies respiratòries i de l'oviducte és confirmada mitjançant la localització per immunofluorescència del canal iònic a la membrana apical de l'epiteli ciliat i polaritzat, allà on la senyalització de Ca2+ és requerida per la regulació de la CBF. Cèl·lules ciliades de la tràquea de ratolins TRPV4-/- no expressen el canal TRPV4, no responen a l'activador específic del TRPV4, el 4α-phorbol 12,13-didecanoate (4α-PDD) i presenten respostes de Ca2+ reduïdes a temperatures mitjanes (~25ºC- 8ºC), un altre estímul dels canals TRPV4. L'activació dels canals TRPV4 per solucions altament viscoses i per hypotonicitat depèn de l'activació de la via de la fosfolipasa A2(PLA2)i la subseqüent producció de àcid epoxieicosatrienoic (EET). En condicions de baixa activació de la PLA2, estímuls mecànics i hipotònics alliberen ATP per a l'activació de la via de la fosfolipasa C (PLC)-inositol trifosfat (IP3) per contribuir a l'activació dels canals TRPV4. Descrivim que el metabòlit IP3 sense ser un agonista per ell mateix, sensibilitza el TRPV4 per a l'activació de EET, essent aquest un mecanisme general. L'acoblament funcional entre els canals TRPV4 de la membrana plasmàtica i els receptors de IP3 (IP3R) és necessari tant per iniciar com mantenir la senyalització oscil·latòria del Ca2+ desencadenada per estímuls viscosos i hipotònics. Un dels principals activadors de la CBF, la adenosina-5'-trifosfat (ATP), desencadena una resposta cel·lular mediada per Ca2+ en la que es desencadena tant l'alliberament de Ca2+ des dels dipòsits intracel·lulars com l'entrada de Ca2+. És destacable la contribució de el TRPV4 en l'augment de la CBF mediada per ATP. És més, el nostre treball implica als canals TRPV4 exclusivament en l'entrada de Ca2+ activada per receptor (ROCE). Tot plegat, aquesta tesi doctoral mostra el paper dels canals TRPV4 en l'acoblament d'estímuls fisiològics tipus mecànic, osmòtic i químic a la regulació de la CBF en l'epiteli ciliat destinat al transport mucociliar. / Clearance of mucus and pathogenic agents from lungs and the transport of gametes and embryos in the female reproductive organs are key functions of ciliated epithelia such as those present in the airways and the oviduct. The rate of mucociliary transport is a function of ciliary beat frequency (CBF) and this, in turn, is increased by increases in intracellular calcium. Transient potential vanilloid 4 (TRPV4)cation channel mediates Ca2+ influx in response to mechanical and osmotic stimuli. TRPV4 expression in ciliated epithelia from airways and oviduct is confirmed by immunofluorescence localization of the channel at the apical membrane of the polarized ciliated epithelia, where the Ca2+ signalling is required for CBF regulation. Ciliated tracheal cells from TRPV4-/-mice show no TRPV4 expression, neither increases in intracellular Ca2+ and CBF in response to the TRPV4-specific activator 4α- phorbol 12,13- idecanoate (4α-PDD), and reduced responses to mild temperatures (~25ºC - 38ºC), another TRPV4-activating stimulus. TRPV4 gating by high viscous loads and hypotonicity depends on phospholipase A2 (PLA2) pathway activation and subsequent production of epoxyeicosatrienoic acid (EET). Under conditions of low PLA2 activation, mechanical and hypotonic stimuli use extracellular ATP release-mediated activation of phospholipase C (PLC)-inositol triphosphate(IP3)signalling to support TRPV4 gating. We describe that IP3, without being an agonist itself, sensitizes TRPV4 to EET activation. Besides, the functional coupling between plasma membrane TRPV4 channels and IP3 receptors (IP3R) is required to initiate and maintain the cellular oscillatory Ca2+ signal triggered by high viscous loads and hypotonic stimuli. One of the main CBF activators, adenosine-5'-triphosphate (ATP), triggers both Ca2+ release from intracellular Ca2+ stores and Ca2+ entry. Interestingly, TRPV4 contributes to ATP-induced increase in CBF. Furthermore, our work implicates TRPV4 channel exclusively in receptor-operated Ca2+ entry. Collectively, this PhD thesis shows the role of TRPV4 channels coupling physiologically relevant mechanical, hypotonic and chemical stimuli to CBF regulation in motile ciliary epithelia.

hypotonicity

viscosity

ATP

TRPV4

receptor operated-calcium entry

ion channel

TRP superfamily

inositol-1 4 5-triphosphate

phospholipase A2

ciliary cell culture

patch-clamp

immunofluorescence

calcium imaging

cell volume regulation

ciliary beat frequency

ciliated epithelia

mucus transport

cilia

oviduct

airways

61

616.2

The Mechanics of Mitotic Cell Rounding

Stewart, Martin

29 June 2012

During mitosis, adherent animal cells undergo a drastic shape change, from essentially flat to round, in a process known as mitotic cell rounding (MCR). The aim of this thesis was to critically examine the physical and biological basis of MCR. The experimental part of this thesis employed a combined optical microscope-atomic force microscope (AFM) setup in conjunction with flat tipless cantilevers to analyze cell mechanics, shape and volume. To this end, two AFM assays were developed: the constant force assay (CFA), which applies constant force to cells and measures the resultant height, and the constant height assay (CHA), which confines cell height and measures the resultant force. These assays were deployed to analyze the shape and mechanical properties of single cells trans-mitosis. The CFA results showed that cells progressing through mitosis could increase their height against forces as high as 50 nN, and that higher forces can delay mitosis in HeLa cells. The CHA results showed that mitotic cells confined to ~50% of their normal height can generate forces around 50-100 nN without disturbing mitotic progression. Such forces represent intracellular pressures of at least 200 Pascals and cell surface tensions of around 10 nN/µm. Using the CHA to compare mitotic cell rounding with induced cell rounding, it was observed that the intracellular pressure of mitotic cells is at least 3-fold higher than rounded interphase cells. To investigate the molecular basis of the mechanical changes inherent in mitotic cell rounding, inhibitors and toxins were used to pharmacologically dissect the role of candidate cellular processes. These results implicated the actomyosin cortex and osmolyte transporters, the most prominent of which is the Na+/H+ exchanger, in the maintenance of mechanical properties and intracellular hydrostatic pressure. Observations on blebbing cells under the cantilever supported the idea that the actomyosin cortex is required to sustain hydrostatic pressure and direct this pressure into cell shape changes. To gain further insight into the relationship between actomyosin activity and intracellular pressure, dynamic perturbation experiments were conducted. To this end, the CHA was used to evaluate the pressure and volume of mitotic cells before, during and after dynamic perturbations that included tonic shocks, influx of specific inhibitors, and exposure to pore-forming toxins. When osmotic pressure gradients were depleted, pressure and volume decreased. When the actomyosin cytoskeleton was abolished, cell volume increased while rounding pressure decreased. Conversely, stimulation of actomyosin cortex contraction triggered an increase in rounding pressure and a decrease in volume. Taken together, the dynamic perturbation results demonstrated that the actomyosin cortex contracts against an opposing intracellular pressure and that this relationship sets the surface tension, pressure and volume of the cell. The discussion section of this thesis provides a comprehensive overview of the physical basis of MCR by amalgamating the experimental results of this thesis with the literature. Additionally, the biochemal signaling pathways and proteins that drive MCR are collated and discussed. An exhaustive and unprecedented synthesis of the literature on cell rounding (approx. 750 papers as pubmed search hits on “cell rounding”, April 2012) reveals that the spread-to-round transition can be thought of in terms of a surface tension versus adhesion paradigm, and that cell rounding can be physically classified into four main modes, of which one is an MCR-like category characterized by increased actomyosin cortex tension and diminution of focal adhesions. The biochemical pathways and signaling patterns that correspond with these four rounding modes are catalogued and expounded upon in the context of the relevant physiology. This analysis reveals cell rounding as a pertinent topic that can be leveraged to yield insight into core principles of cell biophysics and tissue organization. It furthermore highlights MCR as a model problem to understand the adhesion versus cell surface tension paradigm in cells and its fundamentality to cell shape, mechanics and physiology.

info:eu-repo/classification/ddc/570

ddc:570