The protein-labeling reagent FLASH-EDT2 binds not only to CCXXCC motifs but also non-specifically to endogenous cysteine-rich proteins.

FLASH-EDT2--4',5'-bis(1,3,2-dithioarsolan-2-yl)fluorescein-(1,2-ethanedithiol)2--has been reported to fluoresce only after binding with high affinity to a specific tetracysteine motif (CCXXCC, "Cys4") and thus to provide a technique for labeling recombinant proteins in vivo (Griffin et al. Science 281:269-272). We have attempted to use FLASH-EDT2 as a site-specific label of the II-III loop of the dihydropyridine receptor (DHPR) in skeletal muscle. Upon expression in dysgenic myotubes (which lack endogenous alpha1s), an alpha1s mutated to contain CCRECC in the II-III loop was able to produce L-type calcium currents and to mediate skeletal-type excitation-contraction (EC) coupling, but FLASH-EDT2 labeling revealed no difference from non-transfected dysgenic myotubes. HeLa-S3 cells transfected with Cys4-containing calmodulin were significantly more fluorescent than non-transfected cells, whereas the difference between transfected and non-transfected cells was less apparent for CHO-K and HEK 293 cells. Because the fluorescence of non-transfected cells increased substantially after treatment with FLASH-EDT2, it suggested the possibility that FLASH binds to endogenous cysteine-containing proteins. This finding was confirmed in cuvette experiments in which FLASH-EDT2 fluorescence was observed after FLASH-EDT, was added to protein homogenates from myotubes or cell lines. The enhanced fluorescence was abolished by pretreatment of cells or cell homogenates with coumarine maleimide (CPM), which modifies cysteine residues covalently. Thus, enhanced FLASH fluorescence appears to occur both after binding to an introduced Cys4 motif and to endogenous, cysteine-containing proteins. Therefore, FLASH-EDT2 may be useful only for labeling those recombinant proteins that express at a very high level.

Identification of the pH sensor and activation by chemical modification of the ClC-2G Cl- channel.

Rabbit and human ClC-2G Cl- channels are voltage sensitive and activated by protein kinase A and low extracellular pH. The objective of the present study was to investigate the mechanism involved in acid activation of the ClC-2G Cl- channel and to determine which amino acid residues play a role in this acid activation. Channel open probability (Po) at +/-80 mV holding potentials increased fourfold in a concentration-dependent manner with extracellular H+ concentration (that is, extracellular pH, pHtrans), with an apparent acidic dissociation constant of pH 4.95 +/- 0.27. 1-Ethyl-3(3-dimethylaminopropyl)carbodiimide-catalyzed amidation of the channel with glycine methyl ester increased Po threefold at pHtrans 7.4, at which the channel normally exhibits low Po. With extracellular pH reduction (protonation) or amidation, increased Po was due to a significant increase in open time constants and a significant decrease in closed time constants of the channel gating, and this effect was insensitive to applied voltage. With the use of site-directed mutagenesis, the extracellular region EELE (amino acids 416-419) was identified as the pH sensor and amino acid Glu-419 was found to play the key or predominant role in activation of the ClC-2G Cl- channel by extracellular acid.

Characterization of the human pH- and PKA-activated ClC-2G(2 alpha) Cl- channel.

A ClC-2G(2 alpha) Cl- channel was identified to be present in human lung and stomach, and a partial cDNA for this Cl- channel was cloned from a human fetal lung library. A full-length expressible human ClC-2G(2 alpha) cDNA was constructed by ligation of mutagenized expressible rabbit ClC-2G(2 alpha) cDNA with the human lung ClC-2G(2 alpha) cDNA, expressed in oocytes, and characterized at the single-channel level. Adenosine 3',5'-cyclic monophosphate-dependent protein kinase (PKA) treatment increased the probability of opening of the channel (Po). After PKA activation, the channel exhibited a linear (r = 0.99) current-voltage curve with a slope conductance of 22.1 +/- 0.8 pS in symmetric 800 mM tetraethylammonium chloride (TEACl; pH 7.4). Under fivefold gradient conditions of TEACl, a reversal potential of +21.5 +/- 2.8 mV was measured demonstrating anion-to-cation discrimination. As previously demonstrated for the rabbit ClC-2G(2 alpha) Cl- channel, the human analog, hClC-2G(2 alpha), was active at pH 7.4 as well as when the pH of the extracellular face of the channel (trans side of the bilayer; pHtrans) was asymmetrically reduced to pH 3.0. The extent of PKA activation was dependent on pHtrans. With PKA treatment, Po increased fourfold with a pHtrans of 7.4 and eightfold with a pHtrans of 3.0. Effects of sequential PKA addition followed by pHtrans reduction on the same channel suggested that the PKA- and pH-dependent increases in channel Po were separable and cumulative. Northern analysis showed ClC-2G(2 alpha) mRNA to be present in human adult and fetal lung and adult stomach, and quantitative reverse transcriptase-polymerase chain reaction showed this channel to be present in the adult human lung and stomach at about one-half the level found in fetal lung. The findings of the present study suggest that the ClC-2G(2 alpha) Cl- channel may play an important role in Cl- transport in the fetal and adult human lung.

Triadic Ca2+ modulates charge movement in skeletal muscle.

The effects of intracellular Ca2+ changes on charge movement in frog skeletal muscle were investigated using high concentrations (10-20 mmol/l) of buffers with different abilities to buffer Ca2+ at distances close to the SR Ca2+ release channels. In BAPTA compared with EGTA perfused fibers, charge movement was attenuated and lacked the characteristic kinetic features (I beta and I gamma) of E-C coupling charge movements. Qmax decreased by 9 nC/microF, Vmid was shifted 1-6 mV to more negative potentials, and the steepness factor increased by 3-5 mV. Results of varying the holding potential suggested that BAPTA decreases the amount of charge available to move upon depolarization. Raising intracellular Ca2+ to micromolar levels at a fixed BAPTA concentration prevented the decline in Qmax, suggesting that intracellular Ca2+ can modulate the amount of charge that is in the resting or available state. The different results obtained with BAPTA and EGTA can be explained by the greater ability of BAPTA to buffer dynamic Ca2+ changes at distances close to the release sites. These results are consistent with the proposals that an intracellular Ca2+ site on or near the dihydropyridine receptor, termed here the 'availability site', modulates the amount of charge available to move upon depolarization and is normally populated by Ca2+ released into the triad junction during activity.

Stimulation-dependent redistribution of charge movement between unavailable and available states.

A previous study (Stroffekova and Heiny 1997) demonstrated that changes in resting, intracellular free Ca2+ can modulate the amount of charge which is available to move upon depolarization and do excitation-contraction-coupling (E-C coupling). Charge movement reflects voltage-driven conformational changes of the dihydropyridine receptor which couple membrane excitation to Ca2+ release from the sarcoplasmic reticulum (SR) and contractile activation (c.f. review: Melzer et al. 1995). The present study demonstrates that dynamic changes in free Ca2+ that occur in the triadic gap during SR Ca2+ release can likewise produce a stimulation-dependent increase in the amount of available charge. Thus this modulation occurs in the physiological range of Ca2+ changes that occur in the triad during normal muscle activity. The modulation of charge movement by intracellular Ca2+ was rapid and maintained; it occurred within 2-3 suprathreshold depolarizations and remained for 5-10 minutes. It could be prevented by intracellular BAPTA and by depleting the SR of Ca2+, but not by EGTA or agents known to alter ion channel phosphorylation. These results are explained by a model in which a Ca2+ binding site on or near the voltage-sensor is normally populated by Ca2+ ions released into the triadic junction during activity and modulates the distribution of voltage sensors between available and unavailable states.

A surface potential change in the membranes of frog skeletal muscle is associated with excitation-contraction coupling.

1. Voltage changes and intramembrane charge movements in the transverse tubule membranes (T-system) of frog fast twitch muscle fibres were compared using the potentiometric dye WW-375 and a Vaseline-gap voltage clamp. As shown previously, the potentiometric dye reports a dynamic surface potential change that occurs on the myoplasmic face of the T-system membranes when the macroscopic potential applied across the surface membrane exceeds the mechanical threshold (about -60 mV). 2. The voltage dependence of the extra surface potential change and charge movement were found to be similar. Both activated with a sigmoid voltage dependence centred around -35 to -40 mV, and saturated at voltages above 0 mV. Both processes inactivated upon sustained depolarization, with a mid-point for inactivation of -40 mV. 3. Pharmacological agents which alter charge movement and excitation-contraction (E-C) coupling altered the non-linear surface potential change in a parallel manner. Perchlorate, which potentiates charge movement and E-C coupling, slowed the activation and deactivation of both charge movement and the non-linear surface potential change at voltages above -40 mV, and shifted the voltage dependence of both processes by 13 14 mV to more negative voltages. Dantrolene, which depresses charge movement and E-C coupling, shifted the voltage dependence of both processes to more positive voltages. Nifedipine, which suppresses charge movement and E-C coupling, reduced the magnitude of both charge movement and the non-linear surface potential change. 4. The non-linear surface potential change remained after the sarcoplasmic reticulum (SR) was depleted of Ca2+, suggesting that it is not a consequence of Ca2+ release. 5. These results suggest that the non-linear surface potential change is closely associated with movements of the voltage sensor (dihydropyridine (DHP) receptor) that control E-C coupling and/or signal transduction across the triadic junction. We propose that the movement of charged intramembrane domains of the DHP receptor which generate charge movement drive a subsequent movement of charged intracellular molecular domains that move within about 1 nm of the T-system membrane to generate a measurable change in surface charge. For example, the postulated mobile surface charges could be on an intracellular domain of the voltage sensor or closely associated protein, or could be a charged molecular domain of a protein that associates/dissociates with T-system membrane or DHP receptor during E-C coupling.

Functional expression of the cystic fibrosis transmembrane conductance regulator in yeast.

Recombinant human cystic fibrosis transmembrane conductance regulator (CFTR) has been produced in a Saccharomyces cerevisiae expression system used previously to produce transport ATPases with high yields. The arrangement of the bases in the region immediately upstream from the ATG start codon of the CFTR is extremely important for high expression levels. The maximal CFTR expression level is about 5-10% of that in Sf9 insect cells as judged by comparison of immunoblots. Upon sucrose gradient centrifugation, the majority of the CFTR is found in a light vesicle fraction separated from the yeast plasma membrane in a heavier fraction. It thus appears that most of expressed CFTR is not directed to the plasma membrane in this system. CFTR expressed in yeast has the same mobility (ca. 140 kDa) as recombinant CFTR produced in Sf9 cells in a high resolution SDS-PAGE gel before and after N-glycosidase F treatment, suggesting that it is not glycosylated. The channel function of the expressed CFTR was measured by an isotope flux assay in isolated yeast membrane vesicles and single channel recording following reconstitution into planar lipid bilayers. In the isotope flux assay, protein kinase A (PKA) increased the rate of 125I- uptake by about 30% in membrane vesicles containing the CFTR, but not in control membranes. The single channel recordings showed that a PKA-activated small conductance anion channel (8 pS) with a linear I-V relationship was present in the CFTR membranes, but not in control membranes. These results show that the human CFTR has been expressed in functional form in yeast. With the reasonably high yield and the ability to grow massive quantities of yeast at low cost, this CFTR expression system may provide a valuable new source of starting material for purification of large quantities of the CFTR for biochemical studies.