Claudia Bazzini

Mechanisms Sensing and Modulating Signals Arising From Cell Swelling

Cell volume alterations are involved in numerous cellular events like epithelial transport, metabolic processes, hormone secretion, cell migration, proliferation and apoptosis. Above all it is a need for every cell to counteract osmotic cell swelling in order to avoid cell damage. The defence against excess cell swelling is accomplished by a reduction of the intracellular osmolarity by release of organic- or inorganic osmolytes from the cell or by synthesis of osmotically less active macromolecules from their specific subunits. De-spite the large amount of experimental data that has accumulated, the intracellular mechanisms underlying the sensing of cell volume perturbations and the activation of volume compensatory processes, commonly summarized as regulatory volume decrease (RVD), are still only partly revealed. Moving into this field opens a complex scenario of molecular rearrangements and interactions involving intracellular messengers such as calcium, phosphoinositides and inositolphosphates as well as phosphoryla-tion/dephosphorylation processes and cytoskeletal reorganization with marked cell type- and tissue specific variations. Even in one and the same cell type significant differences regarding the activated pathways during RVD may be evident. This makes it virtually im-possible to unambigously define common sensing- and sinaling pathways used by differ-ent cells to readjust their celll volume, even if all these pathways converge to the activa-tion of comparatively few sets of effectors serving for osmolyte extrusion, including ion channels and transporters. This review is aimed at providing an insight into the manifold cellular mechanisms and alterations occuring during cell swelling and RVD.

Molecular and functional aspects of anionic channels activated during regulatory volume decrease in mammalian cells

Abstract. The ability of cells to readjust their volume after swelling, a phenomenon known as regulatory volume decrease (RVD), is a fundamental biological achievement guaranteeing survival and function of cells under osmotic stress. This article reviews the mechanisms of RVD in mammalian cells with special emphasis on the activation of ion channels during RVD.

Expression and subcellular localization of the AQP8 and AQP1 water channels in the mouse gall-bladder epithelium

Background information. Transepithelial transport of water is one of the most distinctive functions by which the gall‐bladder rearranges its bile content. Water is reabsorbed from the gall‐bladder lumen during fasting, whereas it is secreted into the lumen following meal ingestion. Nevertheless, the molecular mechanism by which water is transported across the gall‐bladder epithelium remains mostly unclear.

Fast Fluorometric Method for Measuring Pendrin (SLC26A4) Cl-/I- Transport Activity

Malfunction of the SLC26A4 protein leads to Pendred syndrome, characterized by sensorineural hearing loss, often associated with mild thyroid dysfunction and goiter. It is generally assumed that SLC26A4 acts as a chloride/anion exchanger, which in the thyroid gland transports iodide, and in the inner ear contributes to the conditioning of the endolymphatic fluid. Here we describe a fast fluorometric method able to be used to functionally scrutinize SLC26A4 and its mutants described in Pendred syndrome. The validation of the method was done by functionally characterizing the chloride/iodide transport of SLC26A4, and a mutant, i.e. SLC26A4S28R, which we previously described in a patient with sensorineural hearing loss, hypothyroidism and goiter. Using the fluorometric method we describe here we can continuously monitor and quantify the iodide or chloride amounts transported by the cells, and we found that the transport capability of the SLC26A4S28R mutant protein is markedly reduced if compared to wild-type SLC26A4.

Functional Characterization of Wild-Type and a Mutated Form of SLC26A4 Identified in a Patient with Pendred Syndrome

Background: Malfunction of the SLC26A4 protein leads to prelingual deafness often associated with mild thyroid dysfunction and goiter. It is assumed that SLC26A4 acts as a chloride/anion exchanger responsible for the iodide organification in the thyroid gland, and conditioning of the endolymphatic fluid in the inner ear. Methods: Chloride uptake studies were made using HEK293-Phoenix cells expressing human wild type SLC26A4 (pendrin) and a mutant (SLC26A4S28R) we recently described in a patient with hypothyroidism, goiter and sensorineural hearing loss. Results: Experiments are summarized showing the functional characterization of wild type SLC26A4 and a mutant (S28R), which we described recently. This mutant protein is transposed towards the cell membrane, however, its transport capability is markedly reduced if compared to wild-type SLC26A4. Furthermore, we show that the SLC26A4 induced chloride uptake in HEK293-Phoenix cells competes with iodide, and, in addition, that the chloride uptake can be blocked by NPPB and niflumic acid, whereas DIDS is ineffective. Conclusions: The functional characteristics of SLC26A4S28R we describe here, are consistent with the clinical phenotype observed in the patient from which the mutant was derived.

A MONOCARBOXYLATE TRANSPORTER MCT1 IS LOCATED AT THE BASOLATERAL POLE OF RAT JEJUNUM

We have functionally expressed and identified a monocarboxylate transporter (MCT1) from rat jejunal enterocyte and we provide evidence for its basolateral localization. Poly(A)+ RNA isolated from rat jejunum was injected into Xenopus laevis oocytes and expression of a proton‐lactate symporter was investigated by means of L‐[14C]lactate uptake. The existence of an endogenous capacity for L‐lactate transport was demonstrated; when, however, oocytes were injected with jejunal mRNA, an expressed L‐lactate uptake was seen which differed from the endogenous transporter since it was significantly pH dependent. After sucrose density gradient fractionation, the highest expression of the pH‐dependent lactate uptake was detected with the mRNA size fraction of about 2‐3 kb in length. The substrate specificity, stereoselectivity and sensitivity to pCMBS (an organomercurial thiol reagent that modifies cysteine residues) of the expressed transport were in good agreement with results previously obtained using isolated jejunal basolateral membranes. Using the reverse transcriptase‐polymerase chain reaction, the presence of mRNA coding for the MCT1 isoform was demonstrated in jejunal enterocytes. These data, together with previous results, suggest that MCT1 is a major route for lactate efflux across the basolateral membrane of rat jejunum; this is in contrast to current opinion which restricts the presence of MCT1 to the apical membrane of the whole small intestine.

The ICln interactome

The many different functional phenotypes described in mammalian cells can only be explained by an intense interaction of the underlying proteins, substantiated by the fact that the number of independently expressed proteins in living cells seems not to exceed 25 K, a number way too small to explain the >250 K different phenotypes on a one‐protein–one‐function base. Therefore, the study of the interactome of the different proteins is of utmost importance. Here, we describe the present knowledge of the ICln interactome. ICln is a protein, we cloned and whose function was reported to be as divers as (i) ion permeation, (ii) cytoskeletal organization, and (iii) RNA processing. The role of ICln in these different functional modules can be described best as being a ‘connector hub’ with ‘date hub’ function.

Ion transport across the gallbladder epithelium.

The function of the gallbladder is not only to store bile, but also to concentrate it during the interdigestive phase by means of salt-dependent water reabsorption. On the contrary, secretions of water and salt take place during the digestive phase. Dysregulation of ion absorption or secretion are common in many gallbladder diseases, such as colelithiasis. Transepithelial absorptions are determined by the Na+/K+ pump on the basolateral membrane, and by several apical membrane Na(+)-coupled transporters. Among these, some isoforms of Na+/H+ and Cl-/HCO3(-) exchangers have been studied. The presence of a Na(+)-Cl(-) simport has been molecularly and functionally characterized in some animal species. The ion transepithelial secretion is mainly dependent on an apical chloride transport attributable to a CFTR-like cAMP-activated channel with high permeability to HCO3(-). The apical membrane electrical potential is one of the factors influencing anion secretion and is maintained by the activity of cAMP-dependent K+ channels. The regulation of the activity of these channels is complex, because of their sensitivity to voltage, and to intracellular calcium and pH. The coordinated interplay underlying the regulation of transporters and channels needs to be clarified yet, as well as the interactions between transporters, channels and aquaporins.

ICln channels reconstituted in heart-lipid bilayer are selective to chloride.

Abstract. ICln is an ion channel cloned from renal epithelial cells. The reconstitution of the protein in 1,2-diphytanoyl-sn-glycero-3-phosphocholine (Diph-PC) bilayer membranes reveals potassium-selective channels, which become more chloride selective in the presence of calcium. Here we show that the ion selectivity of ICln also depends on the lipid environment in which the channels are reconstituted. Diph-PC is a synthetic lipid commonly used for reconstituting ion channels. However, since this lipid is not found in native membranes, we reconstituted the ICln ion channels in a polar heart-lipid extract. Using this lipid mixture the reconstituted ICln ion channels are chloride selective in the presence of calcium and an acidic pH. The relative ion selectivity of ICln under these conditions is similar to the cation versus anion selectivity of native ion channels activated by cell swelling.

Short- and long- term effects of cigarette smoke exposure on glutathione homeostasis in human bronchial epithelial cells.

Background: Cigarette smoke extract (CSE), a model for studying the effects of tobacco smoke in vivo and in vitro, induces cell oxidative stress and affects the antioxidative glutathione system. We evaluated the impact of CSE on airway epithelial cells and the possible cytoprotective effect of the mucolitic drug S-carboximethilcysteine lysine salt (S-CMC-Lys). Methods: Reduced glutathione (GSH) and reactive oxygen species (ROS) intracellular levels were evaluated by fluorimetry in human bronchial epithelial cells (16-HBE) and the expression and activity of enzymes of the GSH metabolic pathway were investigated by RT-PCR, Western blot and colorimetric assays. Results: CSE significantly increased cell mortality in a time and dose dependent manner, via an apoptosis-independent pathway. Short-term (3 hours) CSE exposure induced an increase in ROS levels and a GSH intracellular concentration drop. In parallel, the expression of glutathione peroxidases 2 and 3, glutathione reductase and glutamate-cysteine-ligase was increased. S-CMC-Lys was effective in counteracting these effects. Conclusion: CSE affects ROS levels, GSH concentration and GSH enzymes pathway. These effects can be to some extent reversed by S-CMC-Lys, that could represent a therapeutic tool to counteract CSE induced oxidative cellular injuries.