Contribution of the eighth transmembrane segment to the function of the CFTR chloride channel pore.

Our molecular understanding of the cystic fibrosis transmembrane conductance regulator (CFTR)-the chloride channel that is mutated in cystic fibrosis-has been greatly enhanced by a number of recent atomic-level structures of the protein in different conformations. One surprising aspect of these structures was the finding that the eighth of CFTR's 12 membrane-spanning segments (TM8) appeared close to the channel pore. Although functional evidence supports a role for other TMs in forming the pore, such a role for TM8 has not previously been reported. Here, we use patch-clamp recording to investigate the functional role of TM8. Using substituted cysteine accessibility mutagenesis, we find that three amino acid side-chains in TM8 (Y913, Y914, and Y917) are exposed to the extracellular, but not the intracellular, solution. Cysteine cross-linking experiments suggest that Y914 and Y917 are in close proximity to L102 (TM1) and F337 (TM6), respectively, suggesting that TM8 contributes to the narrow selectivity filter region of the pore. Different amino acid substitutions suggest that Y914, and to a lesser extent Y917, play important roles in controlling anion flux through the open channel. Furthermore, substitutions that reduce side-chain volume at Y917 severely affect channel gating, resulting in a channel with an extremely unstable open state. Our results suggest that pore-lining TM8 is among the most important TMs controlling the permeation phenotype of the CFTR channel, and also that movement of TM8 may be critically involved in channel gating.

Conformational change of the extracellular parts of the CFTR protein during channel gating.

Cystic fibrosis can be treated by potentiators, drugs that interact directly with the cystic fibrosis transmembrane conductance regulator (CFTR) Cl- channel to increase its open probability. These substances likely target key conformational changes occurring during channel opening and closing, however, the molecular bases of these conformational changes, and their susceptibility to manipulation are poorly understood. We have used patch clamp recording to identify changes in the three-dimensional organization of the extracellularly accessible parts of the CFTR protein during channel opening and closing. State-dependent formation of both disulfide bonds and Cd2+ bridges occurred for pairs of cysteine side-chains introduced into the extreme extracellular ends of transmembrane helices (TMs) 1, 6, and 12. Between each of these three TMs, we found that both disulfide bonds and metal bridges formed preferentially or exclusively in the closed state and that these inter-TM cross-links stabilized the closed state. These results indicate that the extracellular ends of these TMs are close together when the channel is closed and that they separate from each other when the channel opens. These findings identify for the first time key conformational changes in the extracellular parts of the CFTR protein that can potentially be manipulated to control channel activity.

Ca2+ is a key factor in α-synuclein-induced neurotoxicity.

Aggregation of α-synuclein leads to the formation of oligomeric intermediates that can interact with membranes to form pores. However, it is unknown how this leads to cell toxicity in Parkinson's disease. We investigated the species-specific effects of α-synuclein on Ca(2+) signalling in primary neurons and astrocytes using live neuronal imaging and electrophysiology on artificial membranes. We demonstrate that α-synuclein induces an increase in basal intracellular Ca(2+) in its unfolded monomeric state as well as in its oligomeric state. Electrophysiology of artificial membranes demonstrated that α-synuclein monomers induce irregular ionic currents, whereas α-synuclein oligomers induce rare discrete channel formation events. Despite the ability of monomeric α-synuclein to affect Ca(2+) signalling, it is only the oligomeric form of α-synuclein that induces cell death. Oligomer-induced cell death was abolished by the exclusion of extracellular Ca(2+), which prevented the α-synuclein-induced Ca(2+) dysregulation. The findings of this study confirm that α-synuclein interacts with membranes to affect Ca(2+) signalling in a structure-specific manner and the oligomeric ß-sheet-rich α-synuclein species ultimately leads to Ca(2+) dysregulation and Ca(2+)-dependent cell death.

Osmotic regulation of the mitochondrial permeability transition pore investigated by light scattering, fluorescence and electron microscopy techniques.

Mitochondrial permeability transition (PT) is a phenomenon of an increase of the inner membrane permeability in response to an excessive matrix calcium accumulation. PTP is caused by the opening of the large weakly selective channel. Molecular composition and regulation of permeability transition pore (PTP) are not well understood. Here we used isolated mitochondria to investigate dependence of PTP activation on the osmotic pressure. We found that in low osmotic strength solution calcium-induced PTP is significantly inhibited. We propose that this effect is linked to the changes in the curvature of the mitochondrial inner membrane. This interpretation is consistent with the idea about the importance of ATP synthase dimerization in modulation of the PTP activity.

Contribution of a leucine residue in the first transmembrane segment to the selectivity filter region in the CFTR chloride channel.

The anion selectivity and conductance of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel are determined predominantly by interactions between permeant anions and the narrow region of the channel pore. This narrow region has therefore been described as functioning as the "selectivity filter" of the channel. Multiple pore-lining transmembrane segments (TMs) have previously been shown to contribute to the selectivity filter region. However, little is known about the three-dimensional organization of this region, or how multiple TMs combine to determine its functional properties. In the present study we have used patch clamp recording to identify changes in channel function associated with the formation of disulfide cross-links between cysteine residues introduced into different TMs within the selectivity filter. Cysteine introduced at position L102 in TM1 was able to form disulfide bonds with F337C and T338C in TM6, two positions that are known to play key roles in determining anion permeation properties. Consistent with this proximal arrangement of L102, F337 and T338, different mutations at L102 altered anion selectivity and conductance properties in a way that suggests that this residue plays an important role in determining selectivity filter function, albeit a much lesser role than that of F337. These results suggest an asymmetric three-dimensional arrangement of the key selectivity filter region of the pore, as well as having important implications regarding the molecular mechanism of anion permeation.

Modulation of mitochondrial ion transport by inorganic polyphosphate - essential role in mitochondrial permeability transition pore.

Inorganic polyphosphate (polyP) is a biopolymer of phosphoanhydride-linked orthophosphate residues. PolyP is involved in multiple cellular processes including mitochondrial metabolism and cell death. We used artificial membranes and isolated mitochondria to investigate the role of the polyP in mitochondrial ion transport and in activation of PTP. Here, we found that polyP can modify ion permeability of de-energised mitochondrial membranes but not artificial membranes. This permeability was selective for Ba2+ and Ca2+ but not for other monovalent and bivalent cations and can be blocked by inhibitors of the permeability transition pore - cyclosporine A or ADP. Lower concentrations of polyP modulate calcium dependent permeability transition pore opening. Increase in polyP concentrations and elongation chain length of the polymer causes calcium independent swelling in energized conditions. Physiologically relevant concentrations of inorganic polyP can regulate calcium dependent as well calcium independent mitochondrial permeability transition pore opening. This raises the possibility that cytoplasmic polyP can be an important contributor towards regulation of the cell death.

Cytoplasmic pathway followed by chloride ions to enter the CFTR channel pore.

Most ATP-binding cassette (ABC) proteins function as ATP-dependent membrane pumps. One exception is the cystic fibrosis transmembrane conductance regulator (CFTR), an ABC protein that functions as a Cl(-) ion channel. As such, the CFTR protein must form a continuous pathway for the movement of Cl(-) ions from the cytoplasm to the extracellular solution when in its open channel state. Extensive functional investigations have characterized most parts of this Cl(-) permeation pathway. However, one region remains unexplored-the pathway connecting the cytoplasm to the membrane-spanning pore. We used patch clamp recording and extensive substituted cysteine accessibility mutagenesis to identify amino acid side-chains in cytoplasmic regions of CFTR that lie close to the pathway taken by Cl(-) ions as they pass from the cytoplasm through this pathway. Our results suggest that Cl(-) ions enter the permeation pathway via a single lateral tunnel formed by the cytoplasmic parts of the protein, and then follow a fairly direct central pathway towards the membrane-spanning parts of the protein. However, this pathway is not lined continuously by any particular part of the protein; instead, the contributions of different cytoplasmic regions of the protein appear to change as the permeation pathway approaches the membrane, which appears to reflect the ways in which different cytoplasmic regions of the protein are oriented towards its central axis. Our results allow us to define for the first time the complete Cl(-) permeation pathway in CFTR, from the cytoplasm to the extracellular solution.

Spermine selectively inhibits high-conductance, but not low-conductance calcium-induced permeability transition pore.

The permeability transition pore (PTP) is a large channel of the mitochondrial inner membrane, the opening of which is the central event in many types of stress-induced cell death. PTP opening is induced by elevated concentrations of mitochondrial calcium. It has been demonstrated that spermine and other polyamines can delay calcium-induced swelling of isolated mitochondria, suggesting their role as inhibitors of the mitochondrial PTP. Here we further investigated the mechanism by which spermine inhibits the calcium-induced, cyclosporine A (CSA) -sensitive PTP by using three indicators: 1) calcium release from the mitochondria detected with calcium green, 2) mitochondrial membrane depolarization using TMRM, and 3) mitochondrial swelling by measuring light absorbance. We found that despite calcium release and membrane depolarization, indicative of PTP activation, mitochondria underwent only partial swelling in the presence of spermine. This was in striking contrast to the high-amplitude swelling detected in control mitochondria and in mitochondria treated with the PTP inhibitor CSA. We conclude that spermine selectively prevents opening of the high-conductance state, while allowing activation of the lower conductance state of the PTP. We propose that the existence of lower conductance, stress-induced PTP might play an important physiological role, as it is expected to allow the release of toxic levels of calcium, while keeping important molecules (e.g., NAD) within the mitochondrial matrix.

Polystyrene nanoparticle exposure induces ion-selective pores in lipid bilayers.

A diverse range of molecular interactions can occur between engineered nanomaterials (ENM) and biomembranes, some of which could lead to toxic outcomes following human exposure to ENM. In this study, we adapted electrophysiology methods to investigate the ability of 20nm polystyrene nanoparticles (PNP) to induce pores in model bilayer lipid membranes (BLM) that mimic biomembranes. PNP charge was varied using PNP decorated with either positive (amidine) groups or negative (carboxyl) groups, and BLM charge was varied using dioleoyl phospholipids having cationic (ethylphosphocholine), zwitterionic (phosphocholine), or anionic (phosphatidic acid) headgroups. Both positive and negative PNP induced BLM pores for all lipid compositions studied, as evidenced by current spikes and integral conductance. Stable PNP-induced pores exhibited ion selectivity, with the highest selectivity for K(+) (PK/PCl~8.3) observed when both the PNP and lipids were negatively charged, and the highest selectivity for Cl(-) (PK/PCl~0.2) observed when both the PNP and lipids were positively charged. This trend is consistent with the finding that selectivity for an ion in channel proteins is imparted by oppositely charged functional groups within the channel's filter region. The PK/PCl value was unaffected by the voltage-ramp method, the pore conductance, or the side of the BLM to which the PNP were applied. These results demonstrate for the first time that PNP can induce ion-selective pores in BLM, and that the degree of ion selectivity is influenced synergistically by the charges of both the lipid headgroups and functional groups on the PNP.

Tetra-arylborate lipophilic anions as targeting groups.

Tetraphenylborate (TPB) anions traverse membranes but are excluded from mitochondria by the membrane potential (Δψ). TPB-conjugates also distributed across membranes in response to Δψ, but surprisingly, they rapidly entered cells. They accumulated within lysosomes following endocystosis. This pH-independent targeting of lysosomes makes possible new classes of probe and bioactive molecules.

Role of polyphosphate in regulation of the Streptomyces lividans KcsA channel.

We examine the hypotheses that the Streptomyces lividans potassium channel KcsA is gated at neutral pH by the electrochemical potential, and that its selectivity and conductance are governed at the cytoplasmic face by interactions between the KcsA polypeptides and a core molecule of inorganic polyphosphate (polyP). The four polypeptides of KcsA are postulated to surround the end unit of the polyP molecule with a collar of eight arginines, thereby modulating the negative charge of the polyP end unit and increasing its preference for binding monovalent cations. Here we show that KcsA channels can be activated in planar lipid bilayers at pH 7.4 by the chemical potential alone. Moreover, one or both of the C-terminal arginines are replaced with residues of progressively lower basicity-lysine, histidine, valine, asparagine-and the effects of these mutations on conductance and selectivity for K(+) over Mg(2+) is tested in planar bilayers as a function of Mg(2+) concentration and pH. As the basicity of the C-terminal residues decreases, Mg(2+) block increases, and Mg(2+) becomes permeant when medium pH is greater than the pI of the C-terminal residues. The results uphold the premise that polyP and the C-terminal arginines are decisive elements in KcsA channel regulation.

Electrostatic Tuning of Anion Attraction from the Cytoplasm to the Pore of the CFTR Chloride Channel.

Anions enter from the cytoplasm into the channel pore of the cystic fibrosis transmembrane conductance regulator (CFTR) Cl- channel not via a central pathway but via a single lateral portal or fenestration. High Cl- conductance is dependent on electrostatic attraction of cytoplasmic Cl- ions by four positively charged amino acid side-chains located within this portal. Here we use a mutagenic approach to investigate the functional effects of transplanting or supplementing these positive charges at nearby portal-lining sites. Using patch clamp recording, we find that the functionally important positive charges at K190 and R303 can be transplanted to four nearby sites (N186, L197, W356, and A367) with little loss of Cl- conductance. Introduction of additional positive charge at these sites had almost no effect on Cl- conductance, but did increase the sensitivity to channel block by intracellular suramin and Pt(NO2)42- anions. We suggest that it is the number of positive charges within the portal, rather than their exact location, that is the most important factor influencing Cl- conductance. The portal appears well optimized in terms of charge distribution to maximize Cl- conductance.

Changes in lipid membranes may trigger amyloid toxicity in Alzheimer's disease.

Amyloid-beta peptides (Aß), implicated in Alzheimer's disease (AD), interact with the cellular membrane and induce amyloid toxicity. The composition of cellular membranes changes in aging and AD. We designed multi-component lipid models to mimic healthy and diseased states of the neuronal membrane. Using atomic force microscopy (AFM), Kelvin probe force microscopy (KPFM) and black lipid membrane (BLM) techniques, we demonstrated that these model membranes differ in their nanoscale structure and physical properties, and interact differently with Aß1-42. Based on our data, we propose a new hypothesis that changes in lipid membrane due to aging and AD may trigger amyloid toxicity through electrostatic mechanisms, similar to the accepted mechanism of antimicrobial peptide action. Understanding the role of the membrane changes as a key activating amyloid toxicity may aid in the development of a new avenue for the prevention and treatment of AD.

The cardioprotective effect of uridine and uridine-5'-monophosphate: the role of the mitochondrial ATP-dependent potassium channel.

The activity of mitochondrial ATP-dependent potassium channel (mitoKATP) of rat heart and liver mitochondria was shown to decrease during aging. This partially explains the increase of risk of ischemia at a mature age since mitoKATP activation provides cardioprotection. We demonstrated that uridine-5'-diphosphate (UDP) possesses the property to activate mitoKATP. At a concentration of 30 microM, it reactivated mitoKATP in mitochondria, and 5-hydroxydecanoate (5-HD) eliminated this effect. In experimental animals, UDP precursors uridine and uridine-5'-monophosphate (UMP) (both 30 mg/kg, administered intravenously 5 min before coronary occlusion) decreased the myocardium ischemic alteration index (1.9 and 3.5 times, respectively) and the T-wave amplitude within 60 min after occlusion. Both effects were inhibited by Glibenclamide (Glib) and 5-HD. UMP and uridine decreased the number of premature ventricular beats 5.6 and 1.9 times and the duration of ventricular tachycardia 9.4 and 4.1 times, respectively. Glib and 5-HD inhibited the anti-arrhythmic parameters, 5-HD being less effective. Uridine and UMP decreased the duration of fibrillation 10.8 and 3.6 times, respectively, and this effect was not abolished by Glib and 5-HD. Thus, uridine and UMP, which are the precursors of UDP in the cell, possess cardioprotective properties. MitoKATP prevents mainly ischemic injuries and partially rhythm disorders.

Resolving the native conformation of Escherichia coli OmpA.

The native conformation of the 325-residue outer membrane protein A (OmpA) of Escherichia coli has been a matter of contention. A narrow-pore, two-domain structure has vied with a large-pore, single-domain structure. Our recent studies show that Ser163 and Ser167 of the N-terminal domain (1-170) are modified in the cytoplasm by covalent attachment of oligo-(R)-3-hydroxybutyrates (cOHBs), and further show that these modifications are essential for the N-terminal domain to be incorporated into planar lipid bilayers as narrow pores (≈ 80 pS, 1 m KCl, 22 °C). Here, we examined the potential effect(s) of periplasmic modifications on pore structure by comparing OmpA isolated from outer membranes (M-OmpA) with OmpA isolated from cytoplasmic inclusion bodies (I-OmpA). Chemical and Western blot analysis and 1H-NMR showed that segment 264-325 in M-OmpA, but not in I-OmpA, is modified by cOHBs. Moreover, a disulfide bond is formed between Cys290 and Cys302 by the periplasmic enzyme DsbA. Planar lipid bilayer studies indicated that narrow pores formed by M-OmpA undergo a temperature-induced transition into stable large pores (≈ 450 pS, 1 M KCl, 22 °C) [energy of activation (Ea) = 33.2 kcal·mol(-1)], but this transition does not occur with I-OmpA or with M-OmpA that has been exposed to disulfide bond-reducing agents. The results suggest that the narrow pore is a folding intermediate, and demonstrate the decisive roles of cOHB-modification, disulfide bond formation and temperature in folding OmpA into its native large-pore configuration.

Importance of oligo-R-3-hydroxybutyrates to S. lividans KcsA channel structure and function.

In the polyphosphate model of the Streptomyces lividans potassium channel KcsA, four polypeptides, each covalently modified by oligo-(R)-3-hydroxybutyrates (cOHB), surround a core molecule of inorganic polyphosphate (polyP). PolyP attracts, binds, and conducts K(+) in response to an electrochemical stimulus whilst the polypeptides govern access to polyP and regulate its selectivity. However, the role of cOHB has remained uncertain. Here we identify cOHB-conjugated residues in the ion pathway, S102 and S129, and mutate them to determine the influence of cOHB on channel properties. We find that the mutations have no discernible effect on tetramer formation or tetramer stability; however, cOHB influences polyP incorporation and/or retention, i.e. single mutants S102G and S129G contain ∼1/3 and double mutant S102G:S129G ≈ 1/2 as much polyP as wild-type. Moreover, planar lipid bilayer studies of wild-type and mutant proteins indicate that cOHB has a critical effect on channel function: at positive potentials, only ∼5% of S102G and S129G currents and <1% of S102G:S129G currents consist of well-structured channels; at negative potentials, S102G and S129G display only irregular conductance and S102G:S129G exhibits no conductance whatsoever. The results indicate that cOHB facilitates the incorporation and/or retention of polyP and plays a critical role in maintaining the flexible polyP molecule in an optimal transbilayer orientation for efficient K(+) transport.

Insight into the selectivity and gating functions of Streptomyces lividans KcsA.

Streptomyces lividans KcsA is a 160-aa polypeptide that oligomerizes to form a tetrameric potassium channel. The three-dimensional structure of the polypeptides has been established, but the selectivity and gating functions of the channel remain unclear. It has been shown that the polypeptides copurify with two homopolymers, poly[(R)-3-hydroxybutyrate] (PHB) and inorganic polyphosphate (polyP), which have intrinsic capacities for cation selection and transport. PHB/polyP complexes are highly selective for divalent cations when pH is greater than the pK(2) of polyP ( approximately 6.8), but this preference is lost when pH is < or =pK(2). It is postulated that KcsA polypeptides attenuate the divalent negative charge of the polyP end unit at physiological pH by strategic positioning of two C-terminal arginines. Here we mutate one or both of the C-terminal arginines and observe the effects on channel selectivity in planar lipid bilayers. We find that channels formed by KcsA polypeptides that retain a single C-terminal arginine remain highly selective for K(+) over Mg(2+), independent of medium pH; however, channels formed by KcsA polypeptides in which both C-terminal arginines have been replaced with neutral residues are selective for Mg(2+) when pH is >7 and for K(+) when pH is <7. Channel gating may be triggered by changes in the balance between the K(+) polyP(-) binding energy, the membrane potential, and the gradient force. The results reveal the importance of the C-terminal arginines to K(+) selectivity and argue for a supramolecular structure for KcsA in which the host polypeptides modify the cation preference of a guest PHB/polyP complex.