ABSTRACT
The high conductance voltage- and Ca(2+)-activated K(+) channel is one of the most broadly expressed channels in mammals. This channel is named BK for 'big K' because of its single-channel conductance that can be as large as 250 pS in 100 mm symmetrical K(+). BK channels increase their activity by membrane depolarization or an increase in cytosolic Ca(2+). One of the key features that defines the behaviour of BK channels is that neither Ca(2+) nor voltage is strictly necessary for channel activation. This and several other observations led to the idea that both Ca(2+) and voltage increase the open probability by an allosteric mechanism. In this type of mechanism, the processes of voltage sensor displacement, Ca(2+) binding and pore opening are independent equilibria that interact allosterically with each other. These allosteric interactions in BK channels reside in the structural characteristics of the BK channel in the sense that voltage and Ca(2+) sensors and the pore need to be contained in different structures or 'modules'. Through electrophysiological, mutagenesis, biochemical and fluorescence studies these modules have been identified and, more important, some of the interactions between them have been unveiled. In this review, we have covered the main advances achieved during the last few years in the elucidation of the structure of the BK channel and how this is related with its function as an allosteric protein.
Subject(s)
Large-Conductance Calcium-Activated Potassium Channels/chemistry , Large-Conductance Calcium-Activated Potassium Channels/physiology , Allosteric Regulation/physiology , Animals , Humans , Large-Conductance Calcium-Activated Potassium Channels/metabolism , Potassium Channels, Calcium-Activated/chemistry , Potassium Channels, Calcium-Activated/metabolism , Potassium Channels, Calcium-Activated/physiology , Protein Structure, Secondary , Protein Structure, Tertiary , Structure-Activity RelationshipABSTRACT
Although a unifying characteristic common to all transient receptor potential (TRP) channel functions remains elusive, they could be described as tetramers formed by subunits with six transmembrane domains and containing cation-selective pores, which in several cases show high calcium permeability. TRP channels constitute a large superfamily of ion channels, and can be grouped into seven subfamilies based on their amino acid sequence homology: the canonical or classic TRPs, the vanilloid receptor TRPs, the melastatin or long TRPs, ankyrin (whose only member is the transmembrane protein 1 [TRPA1]), TRPN after the nonmechanoreceptor potential C (nonpC), and the more distant cousins, the polycystins and mucolipins. Because of their role as cellular sensors, polymodal activation and gating properties, many TRP channels are activated by a variety of different stimuli and function as signal integrators. Thus, how TRP channels function and how function relates to given structural determinants contained in the channel-forming protein has attracted the attention of biophysicists as well as molecular and cell biologists. The main purpose of this review is to summarize our present knowledge on the structure of channels of the TRP ion channel family. In the absence of crystal structure information for a complete TRP channel, we will describe important protein domains present in TRP channels, structure-function mutagenesis studies, the few crystal structures available for some TRP channel modules, and the recent determination of some TRP channel structures using electron microscopy.
Subject(s)
TRPC Cation Channels/chemistry , TRPC Cation Channels/metabolism , Animals , Humans , Models, Biological , TRPC Cation Channels/geneticsABSTRACT
Ion channels activate by sensing stimuli such as membrane voltage, ligand binding or temperature and transduce this information into conformational changes that open the channel pore. Thus, a key question in understanding ion channel function is how do the protein domains involved in sensing stimuli (sensors) and opening the pore (gates) communicate. In this regard, transient receptor potential (TRP) channels that confer thermosensation [A. Dhaka, V. Viswanath, A. Patapoutian, TRP ion channels and temperature sensation, Annu. Rev. Neurosci. 29 (2006) 135-161; I.S. Ramsey, M. Delling, D.E. Clapham, An introduction to TRP channels, Annu. Rev. Physiol. 68 (2006) 619-647] (thermoTRP; Q(10)>10) are unique to the extent that they integrate a variety of physical and chemical stimuli. In some cases such as, for example, the vanilloid receptor TRPV1 [M.J. Caterina, M.A. Schumacher, M. Tominaga, T.A. Rosen, J.D. Levine, D. Julius, The capsaicin receptor: a heat-activated ion channel in the pain pathway, Nature 389 (1997) 816-824] and TRPA1 [G.M. Story, A.M. Peier, A.J. Reeve, S.R. Eid, J. Mosbacher, T.R. Hricik, T.J. Earley, A.C. Hergarden, D.A. Andersson, S.W. Hwang, P. McIntyre, T. Jegla, S. Bevan, A. Patapoutian, ANKTM1, a TRP-like channel expressed in nociceptive neurons, is activated by cold temperatures, Cell 112 (2003) 819-829; S. Jordt, D. Julius, Molecular basis for species-specific sensitivity to "hot" chilli peppers, Cell 108 (2002) 421-430] the integration of these stimuli elicit pain [M. Tominaga, M.J. Caterina, A.B. Malmberg, T.A. Rosen, H. Gilbert, K. Skinner, B.E. Raumann, A.I. Basbaum, D. Julius, The cloned capsaicin receptor integrates multiple pain-producing stimuli, Neuron 21 (1998) 531-543; M. Bandell, A. Dubin, M. Petrus, A. Orth, J. Mathur, S. Hwang, A. Patapoutian, High-throughput random mutagenesis screen reveals TRPM8 residues specifically required for activation by menthol, Nat. Neurosci. 9 (2006) 466-468; S. Zurborg, B. Yurgionas, JA. Jira, O. Caspani, P.A. Heppenstall, Direct activation of the ion channel TRPA1 by Ca(2+), Nat. Neurosci. 10 (2007) 277-279]. These stimuli include voltage, pH, agonist binding, and temperature. Understanding how each of these distinct physiological signals regulate channel opening will be informative about the mechanical linkages that can act either independently or in concert to influence channel activation. In this paper we show that thermoTRP channel-forming proteins are modular in the sense that certain structure or structures (modules) confer temperature-dependent regulation, whereas others confer voltage-dependent regulation. We also discuss the thermodynamic basis of heat and cold activation in an effort to elucidate what confer to these channels the capability to be gated by temperature directly.