The mechano-gated K<Subscript>2P</Subscript> channel TREK-1

The versatility of neuronal electrical activity is largely conditioned by the expression of different structural and functional classes of K⁺ channels. More than 80 genes encoding the main K⁺ channel alpha subunits have been identified in the human genome. Alternative splicing, heteromultimeric assembly, post-translational modification and interaction with auxiliary regulatory subunits further increase the molecular and functional diversity of K⁺ channels. Mammalian two-pore domain K⁺ channels (K_2P) make up one class of K⁺ channels along with the inward rectifiers and the voltage- and/or calcium-dependent K⁺ channels. Each K_2P channel subunit is made up of four transmembrane segments and two pore-forming (P) domains, which are arranged in tandem and function as either homo- or heterodimeric channels. This novel structural arrangement is associated with unusual gating properties including “background” or “leak” K⁺ channel activity, in which the channels show constitutive activity at rest. In this review article, we will focus on the lipid-sensitive mechano-gated K_2P channel TREK-1 and will emphasize on the polymodal function of this “unconventional” K⁺ channel. EBSA Satellite meeting: Ion channels, Leeds, July 2007.     

Effect of mental fatigue on induced tremor in human knee extensors

In this study, the effects of mental fatigue on mechanically induced tremor at both a low (3–6 Hz) and high (8–12 Hz) frequency were investigated. The two distinct tremor frequencies were evoked using two springs of different stiffness, during 20 s sustained contractions of the knee extensor muscles at 30% maximum voluntary contraction (MVC) before and after 100 min of a mental fatigue task, in 12 healthy (29 ± 3.7 years) participants. Mental fatigue resulted in a 6.9% decrease in MVC and in a 9.4% decrease in the amplitude of the agonist muscle EMG during sustained 30% MVC contractions in the induced high frequency only. Following the mental fatigue task, the coefficient of variation and standard deviation of the force signal decreased at 8–12 Hz induced tremor by 31.7% and 35.2% respectively, but not at 3–6 Hz induced tremor. Similarly, the maximum value and area underneath the peak in the power spectrum of the force signal decreased by 55.5% and 53.1% respectively in the 8–12 Hz range only. In conclusion, mental fatigue decreased mechanically induced 8–12 Hz tremor and had no effect on induced 3–6 Hz tremor. We suggest that the reduction could be attributed to the decreased activation of the agonist muscles.     

Abdominal stretch reception in Dipetalogaster maximus (Hemiptera: Reduviidae)

Each half abdominal segment in 5th-instar larvae of the giant bloodsucking reduviid, Dipetalogaster maximus, contains 3 stretch receptor neurones, one associated with the tergosternal muscles, one with the ventral intersegmental muscles and one with the dorsal intersegmental muscles. Each of the three receptors respond phasically to the onset of stretch in its respective muscle group, but none show persistent activity upon prolonged stretch. By contrast, stretch of the main abdominal nerves (which run between the thoracic ganglion and the ventral intersegmental muscles of each abdominal segment) is accompanied by a prolonged and sustained pattern of discharge by an as yet unidentified neurone, the rate of discharge being proportional to the degree of stretch. In life, the abdominal nerves become stretched to about 145% of their resting length when the larva takes a bloodmeal. Thus it appears that in Dipetalogaster stretch of the abdominal nerves themselves is the only mechanism for stretch reception after a blood meal.     

Microtubule patterning in apical epidermal cells ofVinca minor preceding leaf emergence

Summary Serial thin sectioning for electron microscopy was carried out on the cortical cytoplasm of surface cells of the apical dome ofVinca minor. The cellulose reinforcement pattern in the outer epidermal walls forming this surface is known to correlate well with the decussate phyllotaxis pattern. The purpose of this study was to determine the location of microtubules immediately under these epidermal walls as a first step toward finding out how the cellulose pattern arises. First, correspondence between the patterns of microtubules and cellulose was checked. Second, the role of potential orienting cues for the alignment of microtubule arrays in specific cells was evaluated.Microtubule arrays which were well or moderately ordered (70% of the total interphase cells) generally had alignment parallel to the adjacent leaf base, as has been seen for cellulose. The aligned features or cues potentially correlating with a given array were: (1) orientation and length of the previous anticlinal cross-wall, (2) alignment of microtubules in adjacent cells, and (3) direction of inferred stretch, parallel to the nearby leaf bases. All three features were found to agree with the microtubule alignment in 17 of 34 cells with ordered arrays. At least two features agreed in 33 of the 34 cases. All 34 cells with ordered arrays had at least one feature parallel to the array. Random association between microtubule orientation and these features would lead to such correlations less than 0.01% of the time. Thirty percent of the interphase cells showed no obvious order. Most of these cells were located in the central linear corridor region of the apex. The unordered cells were more likely than the ordered cells to have more than one orientation specified by the potential cues; i.e., no single orientation parallel to all of the cues existed. This indicates that uniformity of the orientation cues may be as important as their direction.     

Sexual competition in sagebrush crickets: must males hear calling rivals?

The acoustic signals produced by male crickets and katydidsfunction in part for the maintenance of territories, broadcastareas within which males have exclusive access to sexually receptivefemales. Although it is widely assumed that a male's abilityto hear and respond appropriately to calling neighbors is vitalto his mating success, this hypothesis has never been experimentallychallenged. We tested this hypothesis by experimentally deafeningmale sagebrush crickets (Cyphoderris strepitans) and comparingtheir mating success with that of untreated and sham-treatedcontrol males. Despite the fact that deafened males had a reducedability to detect nearby rivals, we found no difference in themating success of deafened and control males in experimentsconducted over two years (1991 and 1993). We further examinedthe importance of signal detection to male spacing by establishingexperimental populations consisting exclusively of either deafenedmales or hearing controls, whose nearest-neighbor distanceshad been experimentally compressed. Assuming that calling functionsin part to repel rivals, we predicted that hearing males wouldspace themselves out more rapidly in the nights following theirrelease. However, in only two of four replicates were nearest-neighbordistances significantly different across treatments. We concludethat, in contrast to the mating systems of other acoustic Orthoptera:(1) male mating success is not contingent on auditory inputfrom calling rivals, (2) signaling in sagebrush crickets mayfunction only sporadically in territorial maintenance, and (3)calling occasionally mediates spacing of males in natural populations,but this effect may vary either over the course of the breedingseason or between populations. We attribute these results tothe unique mating system of C. strepitans. a short, highly synchronizedbreeding season coupled with a high male mating investment anda super-abundance of calling sites conspire against investmentin territorial maintenance, but instead favor a form of acousticallymediated scramble competition.     

Stretch-activated chloride,potassium, and calcium channels coexisting in plasma membranes of guard cells of Vicia faba L.

Mechanosensitive ion channels in the plasma membrane of Vicia faba guard cell protoplasts were studied by use of the patch clamp technique. Stretch-activated (SA) channels in outside-out patches were analyzed for channel conductance, kinetics and ion selectivity. We found three distinct SA channels, permeable to Cl^–, K⁺ and Ca²⁺ and distinguishable from spontaneous (non-SA) channels for these ions on the basis of conductance, kinetics, and voltage-dependence, as well as sensitivity to membrane stretch. In the attached patch configuration, light suction (2 to 10 kPa) reversibly induced channel opening with multiple amplitudes and complex kinetics. The open probability for SA channels increased nonlinearly with pipette suction. In guard cells in situ, these SA channels may mediate ion transport across the plasma membrane directly, as well as influence the activity of non-SA channels via effects on membrane voltage and cytoplasmic calcium. Through such effects, SA channels likely influence volume and turgor regulation of guard cells, and thereby control of leaf gas exchange.Abbreviations EK equilibrium potential for potassium transport - E_Cl equilibrium potential for chloride transport - SA stretchactivated Dedicated to the 80. birthday of Franz HedrichSupported by a grant from the Deutsche Forschungsgemeinschaft to R.H. and a Department of Energy grant to D.J.C. gratefully acknowledges a John S. Guggenheim Fellowship and Fulbright Kommission Senior Professor Award. We thank Ingrid Baumann and Angela Schön for technical assistance, and Klaus Raschke and Heiner Busch for spirited discussions and support.     

Differential effects of stretch and compression on membrane currents and [Na+]c in ventricular myocytes

Mechano-electrical feedback was studied in the single ventricular myocytes. A small fraction (approximately 10%) of the cell surface could be stretched or compressed by a glass stylus. Stretch depolarised, shortened the action potential and induced extra systoles. Stretch activated non-selective cation currents (I_ns) showed a linear voltage dependence, a reversal potential of 0 mV, a pure cation selectivity, and were blocked by 8 μM Gd³⁺ or 30 μM streptomycin. Stretch reduced Ca²⁺ and K⁺ (I_K) currents. Local compression of broadwise attached cells activated I_K but not I_ns. Cytochalasin D or colchicin, thought to disrupt the cytoskeleton, suppressed the mechanosensitivity of I_ns and I_K. During stretch, the cytosolic sodium concentration increased with spatial heterogeneities, local hotspots with [Na⁺]_c>24 mM appeared close to surface membrane and t-tubules (pseudoratiometric imaging using Sodium Green fluorescence). Electronprobe microanalysis confirmed this result and indicated that stretch increased total sodium [Na] in cell compartments such as mitochondria, nuclear envelope and nucleus. Our results obtained by local stretch differ from those obtained by end-to-end stretch (literature). We speculate that channels may be activated not only by axial but also by shear stress, and, that stretch can activate channels outside the deformed sarcomeres via second messenger.     

Mechano-electric feedback and atrial fibrillation

Atrial fibrillation frequently occurs under conditions associated with atrial dilatation suggesting a role of mechano-electric feedback in atrial arrhythmogenesis. Although atrial arrhythmias may be due both to abnormal focal activity and reentrant mechanisms, the majority of sustained atrial arrhythmias have been ascribed to reentrant activity. Atrial stretch may contribute to focal arrhythmias by inducing afterdepolarizations and to reentrant arrhythmias by increasing the atrial surface, by shortening the refractory period and/or slowing the conduction velocity and by increasing their spatial dispersion. Experimental and clinical studies have demonstrated that changes in mechanical loading conditions may modulate the electrophysiological properties of the atria. These studies have, for the most part, involved the effects of acute stretch on atrial refractoriness. While studies in humans and intact animals yield divergent results due to the variety of loading conditions and neurohumoral influences, experimental studies in isolated preparations clearly show that atrial refractory period and action potential duration at early levels of repolarization shorten by acute atrial dilatation. Both experimental and human studies have shown that acute atrial stretch is arrhythmogenic and may induce triggered premature beats and atrial fibrillation.