Temperature change does not affect force between regulated actin filaments and heavy meromyosin in single-molecule experiments

The temperature dependence of sliding velocity, force and the number of cross-bridges was studied on regulated actin filaments (reconstituted thin filaments) when they were placed on heavy meromyosin (HMM) attached to a glass surface. The regulated actin filaments were used because our previous study on muscle fibres demonstrated that the temperature effect was much reduced in the absence of regulatory proteins. A fluorescently labelled thin filament was attached to the gelsolin-coated surface of a polystyrene bead. The bead was trapped by optical tweezers, and HMM–thin filament interaction was performed at 20–35°C to study the temperature dependence of force at the single-molecule level. Our experiments showed that there was a small increase in force with temperature  ( Q ₁₀= 1.43)  and sliding velocity  ( Q ₁₀= 1.46)  . The small increase in force was correlated with the small increase in the number of cross-bridges  ( Q ₁₀= 1.49)  , and when force was divided by the number of cross-bridges, the result did not depend on the temperature  ( Q ₁₀= 1.03)  . These results demonstrate that the force each cross-bridge generates is fixed and independent of temperature. Our additional experiments demonstrate that tropomyosin (Tm) in the presence of troponin (Tn) and Ca²⁺ enhances both force and velocity, and a truncated mutant, Δ23Tm, diminishes force and velocity. These results are consistent with the hypothesis that Tm in the presence of Tn and Ca²⁺ exerts a positive allosteric effect on actin to make actomyosin linkage more secure so that larger forces can be generated.     

Temperature enhances exocytosis efficiency at the mouse inner hair cell ribbon synapse

Hearing relies on fast and sustained neurotransmitter release from inner hair cells (IHCs) onto the afferent auditory nerve fibres. The temperature dependence of Ca²⁺ current and transmitter release at the IHCs ribbon synapse has not been investigated thus far. To assess the influence of temperature on calcium-triggered exocytosis, patch-clamp recordings of voltage-gated L-type Ca²⁺ influx and exocytic membrane capacitance changes were performed at room (25°C) and physiological (35–37°C) temperatures. An increase in temperature within this range increased the L-type Ca²⁺ current amplitude of IHCs ( Q ₁₀= 1.3) and accelerates the activation kinetics. Fast exocytosis, probed by 20 ms depolarization, was enhanced at physiological temperature with a Q ₁₀ of 2.1. The amplitude of fast release was elevated disproportionately to the increase in Ca²⁺ influx. In contrast, the rate of sustained exocytosis (exocytic rate between 20 and 100 ms of depolarization) did not show a significant increase at physiological temperature. Altogether, these data indicate that the efficiency of fast exocytosis is higher at physiological temperature than at room temperature and suggest that the number of readily releasable vesicles available at the active zone is higher at physiological temperature.     

Temperature dependence of the force-generating process in single fibres from frog skeletal muscle

Generation of force and shortening in striated muscle is due to the cyclic interactions of the globular portion (the head) of the myosin molecule, extending from the thick filament, with the actin filament. The work produced in each interaction is due to a conformational change (the working stroke) driven by the hydrolysis of ATP on the catalytic site of the myosin head. However, the precise mechanism and the size of the force and length step generated in one interaction are still under question. Here we reinvestigate the endothermic nature of the force-generating process by precisely determining, in tetanised intact frog muscle fibres under sarcomere length control, the effect of temperature on both isometric force and force response to length changes. We show that raising the temperature: (1) increases the force and the strain of the myosin heads attached in the isometric contraction by the same amount (∼70 %, from 2 to 17 °C); (2) increases the rate of quick force recovery following small length steps (range between −3 and 2 nm (half-sarcomere)⁻¹) with a Q ₁₀ (between 2 and 12 °C) of 1.9 (releases) and 2.3 (stretches); (3) does not affect the maximum extent of filament sliding accounted for by the working stroke in the attached heads (10 nm (half-sarcomere)⁻¹). These results indicate that in isometric conditions the structural change leading to force generation in the attached myosin heads can be modulated by temperature at the expense of the structural change responsible for the working stroke that drives filament sliding. The energy stored in the elasticity of the attached myosin heads at the plateau of the isometric tetanus increases with temperature, but even at high temperature this energy is only a fraction of the mechanical energy released by attached heads during filament sliding.     

The structural basis of the increase in isometric force production with temperature in frog skeletal muscle

X-ray diffraction patterns were recorded from isolated single fibres of frog skeletal muscle during isometric contraction at temperatures between 0 and 17°C. Isometric force was 43 ± 2% (mean ± s.e.m. , n = 10) higher at 17°C than 0°C. The intensity of the first actin layer line increased by 57 ± 18% ( n = 5), and the ratio of the intensities of the equatorial 1,1 and 1,0 reflections by 20 ± 7% ( n = 10), signalling radial or azimuthal motions of the myosin head domains. The M3 X-ray reflection from the axial repeat of the heads along the filaments was 27 ± 4% more intense at 17°C, suggesting that the heads became more perpendicular to the filaments. The ratio of the intensities of the higher and lower angle peaks of the M3 reflection ( R _M3) was 0.93 ± 0.02 ( n = 5) at 0°C and 0.77 ± 0.02 at 17°C. These peaks are due to interference between the two halves of each myosin filament, and the R _M3 decrease shows that heads move towards the midpoint of the myosin filament at the higher temperature. Calculations based on a crystallographic model of the heads indicated that the observed R _M3 change corresponds to tilting of their light-chain domains by 9 deg, producing an axial displacement of 1.4 nm, which is equal to that required to strain the actin and myosin filaments under the increased force. We conclude that the higher force generated by skeletal muscle at higher temperature can be accounted for by axial tilting of the myosin heads.     

Change in contractile properties of human muscle in relationship to the loss of power and slowing of relaxation seen with fatigue

Slow relaxation from an isometric contraction is characteristic of acutely fatigued muscle and is associated with a decrease in the maximum velocity of unloaded shortening ( V _max) and both these phenomena might be due to a decreased rate of cross bridge detachment. We have compared the change in relaxation rate with that of various parameters of the force–velocity relationship over the course of an ischaemic series of fatiguing contractions and subsequent recovery using the human adductor pollicis muscle working in vivo at approximately 37°C in nine healthy young subjects. Maximal isometric force ( F ₀) decreased from 91.0 ± 1.9 to 58.3 ± 3.5 N (mean ± s.e.m. ). Maximum power decreased from 53.6 ± 4.0 to 17.7 ± 1.2 (arbitrary units) while relaxation rate declined from −10.3 ± 0.38 to −2.56 ± 0.29 s⁻¹. V _max showed a smaller relative change from 673 ± 20 to 560 ± 46 deg s⁻¹ and with a time course that differed markedly from that of slowing of relaxation, showing very little change until late in the series of contractions. Curvature of the force–velocity relationship increased ( a/F ₀ decreasing from 0.22 ± 0.02 to 0.11 ± 0.02) with fatigue and with a time course that was similar to that of the loss of power and the slowing of relaxation. It is concluded that for human muscle working at a normal physiological temperature the change in curvature of the force–velocity relationship with fatigue is a major cause of loss of power and may share a common underlying mechanism with the slowing of relaxation from an isometric contraction.     

Reactive oxygen species reduce myofibrillar Ca2+ sensitivity in fatiguing mouse skeletal muscle at 37°C

The mechanisms of muscle fatigue were studied in small muscle bundles and single fibres isolated from the flexor digitorum brevis of the mouse. Fatigue caused by repeated isometric tetani was accelerated at body temperature (37°C) when compared to room temperature (22°C). The membrane-permeant reactive oxygen species (ROS) scavenger, Tiron (5 m m ), had no effect on the rate of fatigue at 22°C but slowed the rate of fatigue at 37°C to that observed at 22°C. Single fibres were microinjected with indo-1 to measure intracellular calcium. In the accelerated fatigue at 37°C the tetanic [Ca²⁺]_i did not change significantly and the decline of maximum Ca²⁺-activated force was similar to that observed at 22°C. The cause of the greater rate of fatigue at 37°C was a large fall in myofibrillar Ca²⁺ sensitivity. In the presence of Tiron, the large fall in Ca²⁺ sensitivity was abolished and the usual decline in tetanic [Ca²⁺]_i was observed. This study confirms the importance of ROS in fatigue at 37°C and shows that the mechanism of action of ROS is a decline in myofibrillar Ca²⁺ sensitivity.     

Characterization of the cross-bridge force-generating step using inorganic phosphate and BDM in myofibrils from rabbit skeletal muscles

The inhibitory effects of inorganic phosphate (P_i) on isometric force in striated muscle suggest that in the ATPase reaction P_i release is coupled to force generation. Whether P_i release and the power stroke are synchronous events or force is generated by an isomerization of the quaternary complex of actomyosin and ATPase products (AM.ADP.P_i) prior to the following release of P_i is still controversial. Examination of the dependence of isometric force on [P_i] in rabbit fast (psoas; 5-15 °C) and slow (soleus; 15-20 °C) myofibrils was used to test the two-step hypothesis of force generation and P_i release. Hyperbolic fits of force-[P_i] relations obtained in fast and slow myofibrils at 15 °C produced an apparent asymptote as [P_i]∞ of 0.07 and 0.44 maximal isometric force (i.e. force in the absence of P_i) in psoas and soleus myofibrils, respectively, with an apparent K _d of 4.3 m m in both. In each muscle type, the force-[P_i] relation was independent of temperature. However, 2,3-butanedione 2-monoxime (BDM) decreased the apparent asymptote of force in both muscle types, as expected from its inhibition of the force-generating isomerization. These data lend strong support to models of cross-bridge action in which force is produced by an isomerization of the AM.ADP.P_i complex immediately preceding the P_i release step.     

Tidal volume, cardiac output and functional residual capacity determine end-tidal CO2 transient during standing up in humans

In man assuming the upright position, end-tidal P _CO2 ( P _ETCO2 ) decreases. With the rising interest in cerebral autoregulation during posture change, which is known to be affected by P _ETCO2 , we sought to determine the factors leading to hypocapnia during standing up from the supine position. To study the contribution of an increase in tidal volume ( V _T ) and breathing frequency, a decrease in stroke volume (SV), a ventilation–perfusion ( V/Q ) gradient and an increase in functional residual capacity (FRC) to hypocapnia in the standing position, we developed a mathematical model of the lung to follow breath-to-breath variations in P _ETCO2 . A gravity-induced apical-to-basal V/Q gradient in the lung was modelled using nine lung segments. We tested the model using an eight-subject data set with measurements of V _T , pulmonary O₂ uptake and breath-to-breath lumped SV. On average, the P _ETCO2 decreased from 40 mmHg to 36 mmHg after 150 s standing. Results show that the model is able to track breath-to-breath P _ETCO2 variations ( r ²= 0.74, P < 0.05). Model parameter sensitivity analysis demonstrates that the decrease in P _ETCO2 during standing is due primarily to increased V _T , and transiently to decreased SV and increased FRC; a slight gravity-induced V/Q mismatch also contributes to the hypocapnia. The influence of cardiac output on hypocapnia in the standing position was verified in experiments on human subjects, where first breathing alone, and then breathing, FRC and V/Q were controlled.     

A-Type potassium currents active at subthreshold potentials in mouse cerebellar purkinje cells

Voltage-dependent and calcium-independent K⁺ currents were whole-cell recorded from cerebellar Purkinje cells in slices. Tetraethylammonium (TEA, 4 m m ) application isolated an A-type K⁺ current ( I _{k ( a )}) with a peak amplitude, at +20 mV, of about one third of the total voltage-dependent and calcium-independent K⁺ current. The I _{k ( a )} activated at about −60 mV, had a V _0.5 of activation of −24.9 mV and a V _0.5 of inactivation of −69.2 mV. The deactivation time constant at −70 mV was 3.4 ± 0.4 ms, while the activation time constant at +20 mV was 0.9 ± 0.2 ms. The inactivation kinetics was weakly voltage dependent, with two time constants; those at +20 mV were 19.3 ± 3.1 and 97.6 ± 9.8 ms. The recovery from inactivation had two time constants of 60.8 ms (78.4%) and 962.3 ms (21.6%). The I _{k ( a )} was blocked by 4-aminopyridine with an IC₅₀ of 67.6 μM. Agitoxin-2 (2 n m ) blocked 17.4 ± 2.1% of the I _{k ( a )}. Flecainide completely blocked the I _{k ( a )} with a biphasic effect with IC₅₀ values of 4.4 and 183.2 μM. In current-clamp recordings the duration of evoked action potentials was affected neither by agitoxin-2 (2 n m ) nor by flecainide (3 μM), but action potentials that were already broadened by TEA were further prolonged by 4-aminopyridine (100 μM). The amplitude of the hyperpolarisation at the end of depolarising steps was reduced by all these blockers.     

The Interaction between Beta 2-Microglobulin (ßm) and Purified Class-I Major Histocompatibility (MHC) Antigen

The function of MHC class-I molecules is to sample peptides from the intracellular environment and present them to CD8⁺ cytotoxic T lymphocytes. To understand the molecular details of the assembly (and disassembly) of peptide-ß₂m-class-I complexes a biochemical peptidc-class-I binding assay has been generated recently and this paper reports on a similar assay for the interaction between ß₂m and class I. As a model system human ß₂m binding to mouse class I was used. The assay is strictly biochemical using purified reagents which interact in solution and complex formation is determined by size separation. It is specific and highly sensitive. The observed affinity of the interaction, K_D, is close to 0.4 nw. The rate of association at 37 C is very fasi (the k_a is around 5 × 10⁴/M/s) whereas the dissociation is slow (the k_d is around 8 × 10⁻⁶/s); the ratio of dissociation to association yields a calculated K_D close to the observed value. At 37° C almost all of the purified class I participates in binding of the exogenously offered ß₂m showing that a considerable exchange of the endogenous ß₂m occurs. Finally, it was demonstrated that exogenous ß₂m enhances binding to MHC class-I of short perfectly-matching peplides as well as longer peptides.     

Binding of Helix Pomatia A Hemagglutinin to Human Erythrocytes and their Cells. Influence of Multivalent Interaction on Affinity

The binding of ¹²⁵I-labelled intact (hexavalent) and partially reduced (divalent) Helix pomatia A hemagglutinin to human A.₁, A.₂, A.₃, A₁B and A₂B erythrocytes, human lymphocytes, human lymphoblastoid and other tumor cell lines was investigated. The essential finding was that the association constants calculated for the interaction between hemagglutinin and A-erythrocytes were many orders of magnitude higher than the intrinsic association constant for the interaction between the hemagglutinin and the blood group A determinant. The latter value was 5–10³1/mole. The K-values for intact hemagglutinin and A and AB erythrocytes were in the order of 10¹⁰1/mole at 18–22 °C and pH 7.3. For partially reduced hemagglutinin the K-values were in the order of 5–10⁷ 1/mole. Multivalent interaction would seem to be the essential factor responsible for the high K-values in the cell binding experiments. Intact hemagglutinin reacted against A₁ and A₂ erythrocytes or against a human osteogenic sarcoma cell tine (2T) gave homogeneous binding curves in Scatchard's plot. Human lymphocytes and most lymphoblastoid cell lines lacked hemagglutinin receptors.     

Contractile effects of the exchange of cardiac troponin for fast skeletal troponin in rabbit psoas single myofibrils

The effects of the removal of fast skeletal troponin C (fsTnC) and its replacement by cardiac troponin C (cTnC) and the exchange of fast skeletal troponin (fsTn) for cardiac troponin (cTn) were measured in rabbit fast skeletal myofibrils. Electrophoretic analysis of myofibril suspensions indicated that replacement of fsTnC or exchange of fsTn with cTnC or cTn was about 90% complete in the protocols used. Mechanical measurements in single myofibrils, which were maximally activated by fast solution switching, showed that replacement of fsTnC with cTnC reduced the isometric tension, the rate of tension rise following a step increase in Ca²⁺ ( k _act ), and the rate of tension redevelopment following a quick release and restretch ( k _tr ), but had no effect on the kinetics of the fall in tension when the concentration of inorganic phosphate (P_i) was abruptly increased ( k _Pi(+)). These data suggest that the chimeric protein produced by cTnC replacement in fsTn alters those steps controlling the weak-to-strong crossbridge attachment transition. Inefficient signalling within the chimeric troponin may cause these changes. However, replacement of fsTn by cTn had no effect on maximal isometric tension, k _act or k _tr , suggesting that these mechanics are largely determined by the isoform of the myosin molecule. Replacement of fsTn by cTn, on the other hand, shifted the pCa₅₀ of the pCa-tension relationship from 5.70 to 6.44 and reduced the Hill coefficient from 3.3 to 1.4, suggesting that regulatory protein isoforms primarily alter Ca²⁺ sensitivity and the cooperativity of the force-generating mechanism.     

Response linearity in primary auditory cortex of the ferret

The responses of neurons within the primary auditory cortex (A1) of the ferret elicited by broadband dynamic spectral ripple stimuli were examined over a range of ripple spectral densities and ripple velocities. The large majority of neurons showed modulated responses to these stimuli and responded most strongly at low ripple densities and velocities. The period histograms of their responses were subjected to Fourier analysis, and the ratio of the magnitudes of the f ₁ and f ₀ (DC) components of these responses were calculated to give a quantitative index of response linearity. For 82 out of 396 neurons tested (20.7%) this ratio remained above 1.0 over the entire range of ripple densities and velocities. These neurons were classified as 'consistently linear'. A further 134/396 (33.8%) of neurons maintained an f ₁/ f ₀ ratio above 1.0 for either a range of ripple densities at a fixed ripple velocity, or over a range of ripple velocities at a specific ripple density, and were classified as 'locally linear'. Interestingly, for the superficial layers of the primary auditory cortex, consistently linear and locally linear neurons outnumbered nonlinear neurons by a 2:1 ratio. The converse was true for the deep layers. Unlike in primary visual cortex, where f ₁/ f ₀ ratios have been reported to exhibit a bimodal distribution with a minimum at   f ₁/ f ₀≈ 1  , f ₁/ f ₀ ratios for A1 are unimodally distributed with a peak at   f ₁/ f ₀≈ 1  .     

Effects of tropomyosin internal deletion Δ23Tm on isometric tension and the cross-bridge kinetics in bovine myocardium

Tropomyosin (Tm) spans seven actin monomers and contains seven quasi-repeating, loosely similar regions, 1–7. Deletion of regions 2–3 decreases the in vitro sliding speed of synthetic filaments of actin-Tm-Troponin (Tn), and weakens Tm binding to the actin-myosin subfragment 1 (S1) complex (acto-S1). The thin filament was selectively removed from bovine myocardium by gelsolin, and the actin filament was reconstituted, followed by further reconstitution with Tm and Tn. In this reconstitution, full-length Tm (control) was compared with Tm internal deletion mutant Δ23Tm, which lacks residues 47–123 (regions 2–3). The effects of phosphate, MgATP, MgADP and Ca²⁺ were studied in Tm-reconstituted myocardium and Δ23Tm-reconstituted myocardium at pH 7.00 and 25 °C. In Δ23Tm, both isometric tension and stiffness were about 40 % of the control. The Hill factor with Δ23Tm, deduced from the pCa-tension plot, was 1.4 times that of the control, but the Ca²⁺ sensitivity was the same. Sinusoidal analysis indicated that the cross-bridge number in force-generating states was not decreased with Δ23Tm. We conclude that the thin filament cooperativity is increased with Δ23Tm, presumably because of the increased density of the Ca²⁺-binding sites. We further conclude that tension per cross-bridge is 40 % of control and stiffness per cross-bridge is 40 % of control in Δ23Tm. These results are consistent with the idea that Tm modifies the actin-myosin interface so as to increase the stereospecific interaction between moieties of actin and myosin. In Δ23Tm, the interface may not have a perfect stereospecific match so that the tension- and stiffness-generating capacity is greatly diminished.     

Influence of postexercise cooling techniques on heart rate variability in men

The reduction of core body temperature ( T _C) is vitally important in the treatment of hyperthermia; however, little is known regarding the impact of cooling treatments on the autonomic control of heart rate (HR). The aim of the present study was to examine the influence of three field-based hyperthermia treatments on the neural control of HR via heart rate variability (HRV). Following exercise-induced hyperthermia ( T _C∼40.0°C) in a warm environment (34.2 ± 0.5°C), nine healthy, active men were treated during recovery, in a randomized order, with intravenous cold saline infusion (IV) or ice packs (ICE) or fan cooling with intermittent water spray (FAN) for 40 min. During each treatment, HR dynamics via power spectral (VLF, LF, HF), Poincare plot (SD1, SD2), approximate entropy (ApEn) and short- (α₁) and long-term (α₂) fractal scaling analyses were determined every 10 min. At recovery onset, HR and T _C were similar between treatments and were significantly reduced over the 40 min recovery period. During recovery, HR and α₂ were significantly reduced from initial levels but were significantly greater for IV compared with ICE and FAN. In contrast, VLF, LF, HF, SD1, SD2 and ApEn increased during recovery, with all being significantly lower for IV compared with ICE and/or FAN. The present results demonstrated that IV, compared with ICE and FAN, resulted in significantly greater HR, reduced spectral and geometrical HRV, lower HR complexity and reduced long-term HR control, indicative of reduced vagal and/or increased sympathetic modulation. Specific treatments for exercise-induced hyperthermia may result in an altered sympathovagal balance that requires further examination.     

Acceleration of AMPA receptor kinetics underlies temperature-dependent changes in synaptic strength at the rat calyx of Held

It is well established that synaptic transmission declines at temperatures below physiological, but many in vitro studies are conducted at lower temperatures. Recent evidence suggests that temperature-dependent changes in presynaptic mechanisms remain in overall equilibrium and have little effect on transmitter release at low transmission frequencies. Our objective was to examine the postsynaptic effects of temperature. Whole-cell patch-clamp recordings from principal neurons in the medial nucleus of the trapezoid body showed that a rise from 25°C to 35°C increased miniature EPSC (mEPSC) amplitude from −33 ± 2.3 to −46 ± 5.7 pA ( n = 6) and accelerated mEPSC kinetics. Evoked EPSC amplitude increased from −3.14 ± 0.59 to −4.15 ± 0.73 nA with the fast decay time constant accelerating from 0.75 ± 0.09 ms at 25°C to 0.56 ± 0.08 ms at 35°C. Direct application of glutamate produced currents which similarly increased in amplitude from −0.76 ± 0.10 nA at 25°C to −1.11 ± 0.19 nA 35°C. Kinetic modelling of fast AMPA receptors showed that a temperature-dependent scaling of all reaction rate constants by a single multiplicative factor ( Q ₁₀= 2.4) drives AMPA channels with multiple subconductances into the higher-conducting states at higher temperature. Furthermore, Monte Carlo simulation and deconvolution analysis of transmission at the calyx of Held showed that this acceleration of the receptor kinetics explained the temperature dependence of both the mEPSC and evoked EPSC. We propose that acceleration in postsynaptic AMPA receptor kinetics, rather than altered presynaptic release, is the primary mechanism by which temperature changes alter synaptic responses at low frequencies.     

Sensitivity limits for voltage control of P2Y receptor-evoked Ca2+ mobilization in the rat megakaryocyte

G-protein-coupled receptor signalling has been suggested to be voltage dependent in a number of cell types; however, the limits of sensitivity of this potentially important phenomenon are unknown. Using the non-excitable rat megakaryocyte as a model system, we now show that P2Y receptor-evoked Ca²⁺ mobilization is controlled by membrane voltage in a graded and bipolar manner without evidence for a discrete threshold potential. Throughout the range of potentials studied, the peak increase in intracellular Ca²⁺ concentration ([Ca²⁺]_i) in response to depolarization was always larger than the maximal reduction in [Ca²⁺]_i following an equivalent amplitude hyperpolarization. Significant [Ca²⁺]_i increases were observed in response to small amplitude (<5 mV, 5 s duration) or short duration (25 ms, 135 mV) depolarizations. Individual cardiac action potential waveforms were also able to repeatedly potentiate P2Y receptor-evoked Ca²⁺ release and the response to trains of normally paced stimuli fused to generate prolonged [Ca²⁺]_i increases. Furthermore, elevation of the temperature to physiological levels (36°C) resulted in a more sustained depolarization-evoked Ca²⁺ increase compared with more transient or oscillatory responses at 20–24°C. The ability of signalling via a G-protein-coupled receptor to be potentiated by action potential waveforms and small amplitude depolarizations has broad implications in excitable and non-excitable tissues.     

Expression of α5 (CD49e) and α6 (CD49f) Integrin Subunits on T Cells in the Circulation and the Lamina Propria of Normal and Inflammatory Bowel Disease Colonic Mucosa

Intestinal lamina propria T cells are believed to be derived, via the systemic circulation, from gut-associated lymphoid tissue. After migration into the lamina propria, T cells are capable of luminally directed migration following the loss of surface epithelial cells. For adhesion and migration within the extracellular matrix, T cells are likely to utilize the integrin family of adhesion molecules. The aim of this study was to quantitatively and qualitatively investigate the expression of α₅ and α₆ integrin subunits on the surface of human T cells that: (a) migrated out of the lamina propria, (b) remained resident within the matrix and (c) were present in the circulation. In both subpopulations of CD4 and CD8-positive T cells, from both normal and inflamed (inflammatory bowel disease) colonic mucosa, there were significantly fewer α₅ and α₆-positive cells than in the peripheral blood. In addition, there were significantly fewer α₆ integrin molecules on the surface of CD4 and CD8-positive lamina propria T-cell subpopulations, compared with those in the circulation. Our studies suggest that, following migration into the lamina propria, there is down-regulation of α₅ and α₆ integrin-subunit expression on the surface of T cells. Molecules other than members of very late activation antigen-5 (VLA-5) (α₅β₁) and VLA-6 (α₆β₁) families of adhesion molecules are likely to be important in interactions with extracellular components in the lamina propria of normal and inflamed human colonic mucosa.     

Neurokinin-1 receptor desensitization to consecutive microdialysis infusions of substance P in human skin

Unloaded shortening velocity ( V ₀) of human triceps surae muscle was measured in vivo by applying the 'slack test', originally developed for determining V ₀ of single muscle fibres, to voluntary contractions at varied activation levels (ALs). V ₀ was measured from 10 subjects at five different ALs defined as a fraction (5, 10, 20, 40 and 60%) of the maximum voluntary contraction (MVC) torque. Although individual variability was apparent, V ₀ tended to increase with AL  ( R ²= 0.089; P = 0.035)  up to 60%MVC (8.6 ± 2.6 rad s⁻¹). This value of V ₀ at 60%MVC was comparable to the maximum shortening velocity of plantar flexors reported in the previous studies. Electromyographic analysis showed that the activities of soleus, medial gastrocnemius and lateral gastrocnemius muscles increased with AL during isometric contraction and after the application of quick release in a similar manner. Also, it showed that the activity of an antagonist, tibialis anterior muscle, was negligible, even though a slight increase took place after the quick release of agonist. Correlation analysis showed that there were no significant correlations between V ₀ and MVC torque normalized with respect to body mass, although the correlation coefficient was relatively high at low ALs. The results suggest that in human muscle, V ₀ represents the unloaded velocity of the fastest muscle fibres recruited, and increases with AL possibly because of progressive recruitment of faster fibres. Individual variability may be explained, at least partially, by the difference in fibre-type composition.     

Cerebral non-oxidative carbohydrate consumption in humans driven by adrenaline

During brain activation, the decrease in the ratio between cerebral oxygen and carbohydrate uptake (6 O₂/(glucose +  ¹/₂  lactate); the oxygen–carbohydrate index, OCI) is attenuated by the non-selective β-adrenergic receptor antagonist propranolol, whereas OCI remains unaffected by the β₁-adrenergic receptor antagonist metroprolol. These observations suggest involvement of a β₂-adrenergic mechanism in non-oxidative metabolism for the brain. Therefore, we evaluated the effect of adrenaline (0.08 μg kg⁻¹ min⁻¹ i.v. for 15 min) and noradrenaline (0.5, 0.1 and 0.15 μg kg⁻¹ min⁻¹ i.v. for 20 min) on the arterial to internal jugular venous concentration differences (a-v diff) of O₂, glucose and lactate in healthy humans. Adrenaline ( n = 10) increased the arterial concentrations of O₂, glucose and lactate ( P < 0.05) and also increased the a-v diff for glucose from 0.6 ± 0.1 to 0.8 ± 0.2 m m (mean ± s.d. ; P < 0.05). The a-v diff for lactate shifted from a net cerebral release to an uptake and OCI was lowered from 5.1 ± 1.5 to 3.6 ± 0.4 ( P < 0.05) indicating an 8-fold increase in the rate of non-oxidative carbohydrate uptake during adrenaline infusion ( P < 0.01). Conversely, noradrenaline ( n = 8) did not affect the OCI despite an increase in the a-v diff for glucose ( P < 0.05). These results support that non-oxidative carbohydrate consumption for the brain is driven by a β₂-adrenergic mechanism, giving neurons an abundant provision of energy when plasma adrenaline increases.