Instantaneous ion configurations in the K+ ion channel selectivity filter revealed by 2D IR spectroscopy.

Potassium channels are responsible for the selective permeation of K+ ions across cell membranes. K+ ions permeate in single file through the selectivity filter, a narrow pore lined by backbone carbonyls that compose four K+ binding sites. Here, we report on the two-dimensional infrared (2D IR) spectra of a semisynthetic KcsA channel with site-specific heavy (13C18O) isotope labels in the selectivity filter. The ultrafast time resolution of 2D IR spectroscopy provides an instantaneous snapshot of the multi-ion configurations and structural distributions that occur spontaneously in the filter. Two elongated features are resolved, revealing the statistical weighting of two structural conformations. The spectra are reproduced by molecular dynamics simulations of structures with water separating two K+ ions in the binding sites, ruling out configurations with ions occupying adjacent sites.

Bioinspired Artificial Sodium and Potassium Ion Channels.

In Nature, all biological systems present a high level of compartmentalization in order to carry out a wide variety of functions in a very specific way. Hence, they need ways to be connected with the environment for communication, homeostasis equilibrium, nutrition, waste elimination, etc. The biological membranes carry out these functions; they consist of physical insulating barriers constituted mainly by phospholipids. These amphipathic molecules spontaneously aggregate in water to form bilayers in which the polar groups are exposed to the aqueous media while the non-polar chains self-organize by aggregating to each other to stay away from the aqueous media. The insulating properties of membranes are due to the formation of a hydrophobic bilayer covered at both sides by the hydrophilic phosphate groups. Thus, lipophilic molecules can permeate the membrane freely, while the small charged or very hydrophilic molecules require the assistance of other membrane components in order to overcome the energetic cost implied in crossing the non-polar region of the bilayer. Most of the large polar species (such as oligosaccharides, polypeptides or nucleic acids) cross into and out of the cell via endocytosis and exocytosis, respectively. Nature has created a series of systems (carriers and pores) in order to control the balance of small hydrophilic molecules and ions. The most important structures to achieve these goals are the ionophoric proteins that include the channel proteins, such as the sodium and potassium channels, and ionic transporters, including the sodium/potassium pumps or calcium/sodium exchangers among others. Inspired by these, scientists have created non-natural synthetic transporting structures to mimic the natural systems. The progress in the last years has been remarkable regarding the efficient transport of Na(+) and K(+) ions, despite the fact that the selectivity and the ON/OFF state of the non-natural systems remain a present and future challenge.

Engineering K+ channels using semisynthesis.

Potassium channels conduct K(+) ions selectively and at very high rates. Central to the function of K(+) channels is a structural unit called the selectivity filter. In the selectivity filter, a row of four K(+) binding sites are created using mainly the backbone carbonyl oxygen atoms. Due to the involvement of the protein backbone, site-directed mutagenesis is of limited utility in investigating the selectivity filter. In order to overcome this limitation, we have developed a semisynthetic approach, which permits the use of chemical synthesis to manipulate the selectivity filter. In this chapter, we describe the protocols that we have developed for the semisynthesis of the K(+) channel, KcsA. We anticipate that the protocols described in this chapter will also be applicable for the semisynthesis of other integral membrane proteins of interest.

Hyperpolarization-activated cation current Ih of dentate gyrus granule cells is upregulated in human and rat temporal lobe epilepsy.

The hyperpolarization-activated cation current I(h) is an important regulator of neuronal excitability and may contribute to the properties of the dentate gyrus granule (DGG) cells, which constitute the input site of the canonical hippocampal circuit. Here, we investigated changes in I(h) in DGG cells in human temporal lobe epilepsy (TLE) and the rat pilocarpine model of TLE using the patch-clamp technique. Messenger-RNA (mRNA) expression of I(h)-conducting HCN1, 2 and 4 isoforms was determined using semi-quantitative in-situ hybridization. I(h) density was ∼1.8-fold greater in DGG cells of TLE patients with Ammon's horn sclerosis (AHS) as compared to patients without AHS. The magnitude of somatodendritic I(h) was enhanced also in DGG cells in epileptic rats, most robustly during the latent phase after status epilepticus and prior to the occurrence of spontaneous epileptic seizures. During the chronic phase, I(h) was increased ∼1.7-fold. This increase of I(h) was paralleled by an increase in HCN1 and HCN4 mRNA expression, whereas HCN2 expression was unchanged. Our data demonstrate an epilepsy-associated upregulation of I(h) likely due to increased HCN1 and HCN4 expression, which indicate plasticity of I(h) during epileptogenesis and which may contribute to a compensatory decrease in neuronal excitability of DGG cells.

Utilización de hidrolasas en la preparación de fármacos e intermedios homoquirales / Hydrolases use in the preparation of drugs and homochiral intermediates

La exquisita regio y estereoselectividad que presentan los biocatalizadores,amén de la buena sostenibilidad inherente a su empleo,permiten la realización de protocolos sintéticos difícilmente alcanzablespor las metodologías clásicas, a menos que se lleven a cabocostosos procesos de protección y desprotección. En este trabajo serevisan algunos ejemplos en los cuales las hidrolasas (las enzimas másempleadas dentro del ámbito de las Biotransformaciones) están implicadascomo biocatalizadores para la obtención del eutómero (esteroisómeroactivo, que presenta la actividad terapéutica deseada) biende diferentes fármacos quirales, o bien de precursores a través de loscuales se puedan sintetizar. Así, se comentarán distintos tipos de biotransformacionespara la obtención de compuestos con diferentesactividades: antivirales, anticancerosos, antihipertensivos, antiinflamatorios,etc, haciendo hincapié en la versatilidad y comodidad delempleo de los biocatalizadores en los pasos sintéticos descritos(AU)

The excellent regio and steroselectivity of biocatalysts, combinedwith their environmental friendly behaviour, make possible to carryout under biocatalytical conditions many processes which, conductedon strictly classical methodologies, would demand expensive andtedious protection and de-protection steps. In this work we reviewsome examples in which hydrolases (the most useful enzymes in theBiotransformations field) catalyse different reactions for synthesizingonly the therapeutically essential stereoisomer of differenthomochiral building blocks for drugs. Thus, processes leading toantiviral, anticancer, antihypertensive or antiinflammatory drugs,along with many others, are described, remarking the versatility andutility of the biocatalysts in the above-mentioned processes(AU)

Wrestling with native chemical ligation.

An improved method for the semisynthesis of a potassium channel involving native chemical ligation allows the introduction of short sequences containing non-canonical amino acids at any position within the polypeptide chain. The work enhances the technology available for a range of fundamental investigations of membrane proteins and for applications of membrane channels and pores in biotechnology.

Modular strategy for the semisynthesis of a K+ channel: investigating interactions of the pore helix.

Chemical synthesis is a powerful method for precise modification of the structural and electronic properties of proteins. The difficulties in the synthesis and purification of peptides containing transmembrane segments have presented obstacles to the chemical synthesis of integral membrane proteins. Here, we present a modular strategy for the semisynthesis of integral membrane proteins in which solid-phase peptide synthesis is limited to the region of interest, while the rest of the protein is obtained by recombinant means. This modular strategy considerably simplifies the synthesis and purification steps that have previously hindered the chemical synthesis of integral membrane proteins. We develop a SUMO fusion and proteolysis approach for obtaining the N-terminal cysteine containing membrane-spanning peptides required for the semisynthesis. We demonstrate the feasibility of the modular approach by the semisynthesis of full-length KcsA K(+) channels in which only regions of interest, such as the selectivity filter or the pore helix, are obtained by chemical synthesis. The modular approach is used to investigate the hydrogen bond interactions of a tryptophan residue in the pore helix, tryptophan 68, by substituting it with the isosteric analogue, beta-(3-benzothienyl)-l-alanine (3BT). A functional analysis of the 3BT mutant channels indicates that the K(+) conduction and selectivity of the 3BT mutant channels are similar to those of the wild type, but the mutant channels show a 3-fold increase in Rb(+) conduction. These results suggest that the hydrogen bond interactions of tryptophan 68 are essential for optimizing the selectivity filter for K(+) conduction over Rb(+) conduction.

Semisynthesis of K+ channels.

The ability to selectively conduct K(+) ions is central to the function of K(+) channels. Selection for K(+) and rejection of Na(+) takes place in a conserved structural element referred to as the selectivity filter. The selectivity filter consists of four K(+)-specific ion binding sites that are created using predominantly the backbone carbonyl oxygen atoms. Due to the involvement of the protein backbone, experimental manipulation of the ion binding sites in the selectivity filter is not possible using traditional site directed mutagenesis. The limited suitability of the site-directed mutagenesis for studies on the selectivity filter has motivated the development of a semisynthesis approach, which enables the use of chemical synthesis to manipulate the selectivity filter. In this chapter, we describe the protocols that are presently used in our laboratory for the semisynthesis of the bacterial K(+) channel, KcsA. We show the introduction of a spectroscopic probe into the KcsA channel using semisynthesis. We also review previous applications of semisynthesis in investigations of K(+) channels. While the protocols described in this chapter are for the KcsA K(+) channel, we anticipate that similar protocols will also be applicable for the semisynthesis of other integral membrane proteins.

Artificial ion channel formed by cucurbit[n]uril derivatives with a carbonyl group fringed portal reminiscent of the selectivity filter of K+ channels.

Novel artificial ion channels (1 and 2) based on CB[n] (n = 6 and 5, respectively) synthetic receptors with carbonyl-fringed portals (diameter 3.9 and 2.4 A, respectively) can transport proton and alkali metal ions across a lipid membrane with ion selectivity. Fluorometric experiments using large unilamellar vesicles showed that 1 mediates proton transport across the membranes, which can be blocked by a neurotransmitter, acetylcholine, reminiscent of the blocking of the K+ channels by polyamines. The alkali metal ion transport activity of 1 follows the order of Li+ > Cs+ approximately Rb+ > K+ > Na+, which is opposite to the binding affinity of CB[6] toward alkali metal ions. On the other hand, the transport activity of 2 follows the order of Li+ > Na+, which is also opposite to the binding affinity of 2 toward these metal ions, but virtually no transport was observed for K+, Rb+, and Cs+. It is presumably because the carbonyl-fringed portal size of 2 (diameter 2.4 A) is smaller than the diameters of these alkali metal ions. To determine the transport mechanism, voltage-clamp experiments on planar bilayer lipid membranes were carried out. The experiments showed that a single-channel current of 1 for Cs+ transport is approximately 5 pA, which corresponds to an ion flux of approximately 3 x 107 ions/s. These results are consistent with an ion channel mechanism. Not only the structural resemblance to the selectivity filter of K+ channels but also the remarkable ion selectivity makes this model system unique.

Semisynthesis and folding of the potassium channel KcsA.

In this contribution we describe the semisynthesis of the potassium channel, KcsA. A truncated form of KcsA, comprising the first 125 amino acids of the 160-amino acid protein, was synthesized using expressed protein ligation. This truncated form corresponds to the entire membrane-spanning region of the protein and is similar to the construct previously used in crystallographic studies on the KcsA protein. The ligation reaction was carried out using an N-terminal recombinant peptide alpha-thioester, corresponding to residues 1-73 of KcsA, and a synthetic C-terminal peptide corresponding to residues 74-125. Chemical synthesis of the C-peptide was accomplished by optimized Boc-SPPS techniques. A dual fusion strategy, involving glutathione-S-transferase (GST) and the GyrA intein, was developed for recombinant expression of the N-peptide alpha-thioester. The fusion protein, expressed in the insoluble form as inclusion bodies, was refolded and then cleaved successively to remove the GST tag and the intein, thereby releasing the N-peptide alpha-thioester. Following chemical ligation, the KcsA polypeptide was folded into the tetrameric state by incorporation into lipid vesicles. The correctness of the folded state was verified by the ability of the KcsA tetramer to bind to agitoxin-2. To our knowledge, this work represents the first reported semisynthesis of a polytopic membrane protein and highlights the potential application of native chemical ligation and expressed protein ligation for the (semi)synthesis of integral membrane proteins.

Design and characterization of a DNA-encoded, voltage-sensitive fluorescent protein.

Optical imaging of electrical activity has been suggested as a promising approach to investigate the multineuronal representation of information processing in brain tissue. While considerable progress has been made in the development of instrumentation suitable for high-speed imaging, intrinsic or extrinsic dye-mediated optical signals are often of limited use due to their slow response dynamics, low effective sensitivity, toxicity or undefined cellular origin. Protein-based and DNA-encoded voltage sensors could overcome these limitations. Here we report the design and generation of a voltage-sensitive fluorescent protein (VSFP) consisting of a voltage sensing domain of a potassium channel and a pair of cyan and yellow emitting mutants of green fluorescent protein (GFP). In response to a change in transmembrane voltage, the voltage sensor alters the amount of fluorescence resonance energy transfer (FRET) between the pair of GFP mutants. The optical signals respond in the millisecond time-scale of fast electrical signalling and are large enough to allow monitoring of voltage changes at the single cell level.

The structure and organization of synthetic putative membranous segments of ROMK1 channel in phospholipid membranes.

The hydropathy plot of ROMK1, an inwardly rectifying K+ channel, suggests that the channel contains two transmembrane domains (M1 and M2) and a linker between them with significant homology to the H5 pore region of voltage-gated K+ channels. To gain structural information on the pore region of the ROMK1 channel, we used a spectrofluorimetric approach and characterized the structure, the organization state, and the ability of the putative membranous domains of the ROMK1 channel to self-assemble and coassemble within lipid membranes. Circular dichroism (CD) spectroscopy revealed that M1 and M2 adopt high alpha-helical structures in egg phosphatidylcholine small unilamellar vesicles and 40% trifluoroethanol (TFE)/water, whereas H5 is not alpha-helical in either egg phosphatidylcholine small unilamellar vesicles or 40% TFE/water. Binding experiments with 4-fluoro-7-nitrobenz-2-oxa-1,3-diazole (NBD)-labeled peptide demonstrated that all of the peptides bind to zwitterionic phospholipid membranes with partition coefficients on the order of 10(5) M-1. Tryptophan quenching experiments using brominated phospholipids revealed that M1 is dipped into the hydrophobic core of the membrane. Resonance energy transfer (RET) measurements between fluorescently labeled pairs of donor (NBD)/acceptor (rhodamine) peptides revealed that H5 and M2 can self-associate in their membrane-bound state, but M1 cannot. Moreover, the membrane-associated nonhelical H5 serving as a donor can coassemble with the alpha-helical M2 but not with M1, and M1 can coassemble with M2. No coassembly was observed between any of the segments and a membrane-embedded alpha-helical control peptide, pardaxin. The results are discussed in terms of their relevance to the proposed topology of the ROMK1 channel, and to general aspects of molecular recognition between membrane-bound polypeptides.

Coassembly of synthetic segments of shaker K+ channel within phospholipid membranes.

Increasing evidence suggests that membrane-embedded hydrophobic segments can interact within the phospholipid milieu of the membrane with varying degrees of specificity and thus contribute to the folding and oligomerization of proteins. We have used synthetic peptides corresponding to segments from the hydrophobic core of the Shaker potassium channel as a model system to study interactions between membrane-embedded segments. Three synthetic segments of the Shaker K+ channel, comprising the hydrophobic S2, S3, and S4 sequences, were used, and their secondary structure, their interactions with, and orientation within phospholipid membranes were examined. Secondary structure studies revealed that though S3 and S4 both adopt certain fractions of alpha-helical structures in membrane mimetic environments, the alpha-helical content of S3 is lower. Both S3 and S4 bind strongly to zwitterionic phospholipids, with partition coefficients in the order of 10(4) and 10(5) M-1. ATR-FTIR studies showed that while the S4 peptide is oriented parallel to the membrane surface, S3 tends to a more transmembranal orientation. Enzymatic cleavage experiments demonstrated that the presence of S3 induces some change in the proteolytic accessibility of the S4 segment. Resonance energy transfer measurements, done in high lipid/peptide molar ratios, revealed that S3 and S4 cannot self-associate in zwitterionic phospholipid vesicles but can associate with each other and with the S2 segment of the channel. Furthermore, S3 does not interact with the homologous S4 region from the first repeat of the eel sodium channel, demonstrating specificity in the interactions. These results are in line with data indicating that functionally important interactions indeed exist between the negatively charged S2 and S3 regions and the positively charged S4 region [Papazian, D. M., et al (1995) Neuron 14, 1293-1301; Planells-Cases, R., et al. (1994) Proc. Natl. Acad. Sci. U.S.A. 92, 9422-9426]. From a broader point of view, these results provide further support to the notion that interactions (either specific or nonspecific) may exist between transmembrane segments of integral membrane proteins and therefore can contribute to their assembly and organization.

Synthetic S-2 and H-5 segments of the Shaker K+ channel: secondary structure, membrane interaction, and assembly within phospholipid membranes.

Current models of voltage-activated K+ channels predict that the channels are formed by the coassembly of four polypeptide monomers, each of which consists of six transmembrane segments (S1-S6) and long terminal domains. The aqueous pores are thought to be composed of the conserved H-5 regions contributed by four monomers. In this study, two putative membrane-embedded segments of the Shaker K+ channel were synthesized. One segment corresponds to the putative, transmembrane helix S-2 (amino acids 275-300), and the other corresponds to the highly conserved 12 amino acid residues within the H-5 region [amino acids 432-443, designated (12)H-5]. Structural and functional characterization at elevated lipid/peptide molar ratios (> 3000:1) was performed on the two segments, as well as on a previously synthesized 21 amino acid long peptide with a sequence resembling the entire H-5 region (designated (21)H-5) (Peled & Shai, 1993). Circular dichroism spectroscopy revealed that S-2 adopts predominantly alpha-helical structure in both trifluoroethanol and 35 mM SDS (78% or 99%, respectively), while (12)H-5 and (21)H-5 adopt low alpha-helical structure only in the presence of 35 mM SDS. Functional characterization demonstrated that S-2 and (12)H-5 segments bind to zwitterionic phospholipids, with partition coefficients on the order of 10(4) M-1. Resonance energy transfer measurements, between donor/acceptor-labeled pairs of peptides, revealed that the peptides self-associate in their membrane-bound state, which may correlate with the existence of functional interactions between the conserved (12)H-5 regions of different subunits of K+ channels (Kirsch et al., 1993).(ABSTRACT TRUNCATED AT 250 WORDS)