The maxi-anion channels (MACs) are expressed in cells from mammals to amphibians with ~60% exhibiting a phenotype called Maxi-Cl. Maxi-Cl serves as the most efficient pathway for regulated fluxes of inorganic and organic anions including ATP However, its molecular entity has long been elusive. By subjecting proteins isolated from bleb membranes rich in Maxi-Cl activity to LC-MS/MS combined with targeted siRNA screening, CRISPR/Cas9-mediated knockout, and heterologous overexpression, we identified the organic anion transporter SLCO2A1, known as a prostaglandin transporter (PGT), as a key component of Maxi-Cl. Recombinant SLCO2A1 exhibited Maxi-Cl activity in reconstituted proteoliposomes. When SLCO2A1, but not its two disease-causing mutants, was heterologously expressed in cells which lack endogenous SLCO2A1 expression and Maxi-Cl activity, Maxi-Cl currents became activated. The charge-neutralized mutant became weakly cation-selective with exhibiting a smaller single-channel conductance. silencing and respectively, suppressed the release of ATP from swollen C127 cells and from Langendorff-perfused mouse hearts subjected to ischemia-reperfusion. These findings indicate that SLCO2A1 is an essential core component of the ATP-conductive Maxi-Cl channel.
A novel type of anion channel activated by extracellular acidification, called acid-sensitive outwardly rectifying (ASOR) anion channel, was shown to be involved in acidotoxic necrotic death in human epithelial cells. However, its biophysical property and molecular identity have remained elusive. In human epithelial HeLa cells, here, whole-cell currents of ASOR anion channel were found to be augmented by warm temperature, with a threshold temperature of 32 °C. Temperature sensitivity of the conductance was found to be high (with Q 10 of 8.8) in the range of body temperature, suggesting a possible involvement of a non-diffusion-limited process such as a transporter-mediated conduction. In this regard, it is interesting that a Cl(-)/H(+) antiporter ClC-3 has recently been proposed as a candidate for the ASOR channel. However, siRNA-mediated knockdown of hClC-3 failed to suppress ASOR currents in HeLa cells. Also, endogenous ASOR currents in HEK293T cells were not affected by overexpression of human or mouse ClC-3. Furthermore, functional expression of the ASOR channel was virtually absent in the cisplatin-resistant human cancer KCP-4 cell line despite the fact that molecular expression of ClC-3 was indistinguishable between KCP-4 cells and parental cisplatin-sensitive KB-3-1 cells which endogenously exhibit high activity of ASOR anion channels. These results indicate that the ASOR anion channel is highly sensitive to temperature and independent of ClC-3.
The maxi-anion channels (MACs) with a unitary conductance of 200-500 pS are detected in virtually every part of the whole body and found in cells from mammals to amphibia. The channels are normally silent but can be activated by physiologically/pathophysiologically relevant stimuli, such as osmotic, salt, metabolic, oxidative, and mechanical stresses, receptor activation, serum, heat, and intracellular Ca(2+) rise. In some MACs, protein dephosphorylation is associated with channel activation. Among MACs so far studied, around 60 % (designated here as Maxi-Cl) possess, in common, the following phenotypical biophysical properties: (1) unitary conductance of 300-400 pS, (2) a linear current-voltage relationship, (3) high anion-to-cation selectivity with PCl/Pcation of >8, and (4) inactivation at positive and negative potentials over a certain level (usually ±20 mV). The pore configuration of the Maxi-Cl is asymmetrical with extracellular and intracellular radii of ∼1.42 and ∼1.16 nm, respectively, and a medial constriction down to ∼0.55-0.75 nm. The classical function of MACs is control of membrane potential and fluid movement. Permeability to ATP and glutamate turns MACs to signaling channels in purinergic and glutamatergic signal transduction defining them as a perspective target for drug discovery. The molecular identification is an urgent task that would greatly promote the developments in this field. A possible relationship between these channels and some transporters is discussed.
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