What drives activation-dependent shifts in the force–length curve?

Skeletal muscles are rarely recruited maximally during movement. However, much of our understanding of muscle properties is based on studies using maximal activation. The effect of activation level on skeletal muscle properties remains poorly understood. Muscle optimum length increases with decreased activation; however, the mechanism responsible is unclear. Here, we attempted to determine whether length-dependent calcium effects, or the effect of absolute force underpin this shift. Fixed-end contractions were performed in frog plantaris muscles at a range of lengths using maximal tetanic (high force, high calcium), submaximal tetanic (low force, high calcium) and twitch (low force, low calcium) stimulation conditions. Peak force and optimum length were determined in each condition. Optimum length increased with decreasing peak force, irrespective of stimulation condition. Assuming calcium concentration varied as predicted, this suggests that absolute force, rather than calcium concentration, underpins the effect of activation level on optimum length. We suggest that the effect of absolute force is due to the varying effect of the internal mechanics of the muscle at different activation levels. These findings have implications for our understanding of in vivo muscle function and suggest that mechanical interactions within muscle may be important determinants of force at lower levels of activation.     

The DNA–DNA spacing in gemini surfactants–DOPE–DNA complexes

Gemini surfactants from the homologous series of alkane-α,ω-diyl-bis(dodecyldimethylammonium bromide) (CnCS12, number of spacer carbons n = 2 – 12) and dioleoylphosphatidylethanolamine (DOPE) were used for cationic liposome (CL) preparation. CLs condense highly polymerized DNA creating complexes. Small-angle X-ray diffraction identified them as condensed lamellar phase L_α^C in the studied range of molar ratios CnGS12/DOPE in the temperature range 20 – 60 °C. The DNA–DNA distance (d_DNA) is studied in dependence to CnGS12 spacer length and membrane surface charge density. The high membrane surface charge densities (CnGS12/DOPE = 0.35 and 0.4 mol/mol) lead to the linear dependence of d_DNA vs. n correlating with the interfacial area of the CnGS12 molecule.     

Improvements to Hoang et al.'s method for measuring passive length–tension properties of human gastrocnemius muscle in vivo

While the passive mechanical properties of a musculo-articular complex can be determined using the relationship between the articular angle and the passive torque developed in resistance to motion, the properties of different structures of the musculo-articular complex cannot be easily assessed. Recently, an elegant method has been proposed to estimate the passive length–tension properties of gastrocnemius muscle–tendon unit (Hoang et al., 2005). In the present paper, two improvements of this method are proposed to decrease the number of parameters required to assess the passive length–tension relationship from 9 to 2. Furthermore, these two parameters have physical meaning as they represent a passive muscle–tendon stiffness index (α) and the muscle–tendon slack length (l₀). α and l₀ are relevant clinical parameters to study the chronic effects of aging, training protocols or neuromuscular pathologies on the passive mechanical properties of the muscle–tendon unit. Eight healthy subjects performed passive loading/unloading cycles at 5°/s with knee angle at 6 knee angles to assess the torque–angle relationships and to apply the modified method. Numerical optimization was used to minimize the squared error between the experimental and the modeled relationships. The experiment was performed twice to assess the reliability of α and l₀ across days. The results showed that the reliability of the two parameters was good (α: ICC=0.82, SEM=6.1 m^?1, CV=6.3% and l₀: ICC=0.83, SEM=0.29 cm, CV=0.9%). Using a sensitivity analysis, it was shown that the numerical solution was unique. Overall, the findings may provide increased interest in the method proposed by Hoang et al. (2005).     

The effect of nanoparticle size on endocytosis dynamics depends on membrane–nanoparticle interaction

Molecular simulation studies on the interaction between nanoparticles (NPs) and cell membranes have been limited by small NP size of several nanometres. In this work, by using a simplified lipid model, we study the endocytosis of large NPs with a size being enlarged to 37.5 nm. It is found that the effect of NP size on endocytosis dynamics depends on the membrane–NP interaction. As the interaction strength between NP and lipid changes, different wrapping modes are observed. For the system with weak membrane–NP attraction, the wrapping process is controlled by the membrane bending, and thus large size of NPs (within the range of NP size we studied) would promote the wrapping dynamics. While for the case with strong membrane–NP adhesion, the wrapping process is dominated by lipid diffusion and small NPs show a larger wrapping rate. In this wrapping mode, the membrane–NP adhesion drives small NPs to move towards the membrane as the wrapping process proceeds. For relatively larger NPs, however, the membrane moves towards the NPs instead. We also find that for the second wrapping mode, the rapid wrapping rate, especially with the hydrophobic ligands on the hydrophilic NP would impose significant perturbations on membrane stability, and consequently, membrane pores may be induced during the process of NP endocytosis.     

The excitation–contraction coupling mechanism in skeletal muscle

First coined by Alexander Sandow in 1952, the term excitation–contraction coupling (ECC) describes the rapid communication between electrical events occurring in the plasma membrane of skeletal muscle fibres and Ca²⁺ release from the SR, which leads to contraction. The sequence of events in twitch skeletal muscle involves: (1) initiation and propagation of an action potential along the plasma membrane, (2) spread of the potential throughout the transverse tubule system (T-tubule system), (3) dihydropyridine receptors (DHPR)-mediated detection of changes in membrane potential, (4) allosteric interaction between DHPR and sarcoplasmic reticulum (SR) ryanodine receptors (RyR), (5) release of Ca²⁺ from the SR and transient increase of Ca²⁺ concentration in the myoplasm, (6) activation of the myoplasmic Ca²⁺ buffering system and the contractile apparatus, followed by (7) Ca²⁺ disappearance from the myoplasm mediated mainly by its reuptake by the SR through the SR Ca²⁺ adenosine triphosphatase (SERCA), and under several conditions movement to the mitochondria and extrusion by the Na⁺/Ca²⁺ exchanger (NCX). In this text, we review the basics of ECC in skeletal muscle and the techniques used to study it. Moreover, we highlight some recent advances and point out gaps in knowledge on particular issues related to ECC such as (1) DHPR-RyR molecular interaction, (2) differences regarding fibre types, (3) its alteration during muscle fatigue, (4) the role of mitochondria and store-operated Ca²⁺ entry in the general ECC sequence, (5) contractile potentiators, and (6) Ca²⁺ sparks.     

Experimental determination of sarcomere force–length relationship in type-I human skeletal muscle fibers

The objectives of this study were to measure the active and passive force–length (F–L) relationships in type-I human single muscle fibers and to compare the results to predictions from the sliding filament model (the “standard model”). We measured isometric forces in chemically skinned fibers at different sarcomere lengths (SLs) in separate maximal activations. The experimental tolerance interval for optimal SL was calculated to be (2.37, 2.95 μm), which included the prediction by the standard model (2.64, 2.81 μm). Average passive slack length was 2.22±0.08 μm, and the passive F–L relationship was well described by an exponential function. Best fit lines were used to estimate the ascending and descending limbs from the active F–L data using the average SL obtained from a digital image of the fiber. The experimental descending limb was also estimated using the shortest SL to address the possible effects of sarcomere inhomogeneity (SI). The experimental slopes of the ascending and descending limbs, 0.42 F_o/μm and ?0.52 F_o/μm (vs. ?0.55 F_o/μm with the shortest SL) respectively, F_o being the maximal isometric force, were significantly less in magnitude than those from the standard model. These results suggested that the difference between experimental and standard models was not fully explained by SI and other factors could be important. The broader experimental F–L curve compared to the standard model implies that human muscle has functionally a wider operating length range where its force-generating capacity is not compromised.     

Undamped oscillations in prey–predator models on a finite size lattice

Sustained oscillation is frequently observed in population dynamics of biospecies. The oscillation comes not only from deterministic but also from stochastic characteristics. In the present article, we deal with a finite size lattice which contains prey and predator. The interaction between a pair of lattice points is carried out by two different methods; local and global interactions. In the former, interaction occurs between adjacent sites, while in the latter interaction takes place between any pair of lattice sites. It is found that both systems exhibit undamped oscillations. The amplitude of oscillation decreases with the increase of the total lattice sites. In the case of global interaction, we can present a stochastic differential equation which is composed of two factors, i.e., the Lotka–Volterra equation with density dependence and noise term. The quantitative agreement between theory and simulation results of global interaction is almost perfect. The stochastic theory qualitatively expresses characteristics of sustainable oscillation for local interaction.     

Stability of plant mRNAs depends on the length of the 3′-untranslated region

Eukaryotic mRNAs that prematurely terminate translation are recognized and degraded by nonsense mediated decay (NMD). This degradation pathway is well studied in animal and yeast cells. The data available imply that NMD also takes place in plants. However, the molecular mechanism of recognition and degradation of plant RNAs containing premature terminator codon (PTC) is not known. Here we report that in plant cells this mechanism involves the recognition of the sizes of the 3'-untranslated regions (3'UTR). Plant 3'UTRs longer than 300 nucleotides induce mRNA instability. Contrary to mammalian and yeast cells, this destabilization does not depend on the presence of any specific sequences downstream of the terminator codon. Unlike nuclear-produced mRNAs, plant virus vector long 3'UTR-containing RNAs, which are synthesized directly in the cytoplasm, are stable and translated efficiently. This shows that RNAs produced in the cytoplasm by viral RNA-dependent RNA polymerase are able to avoid the proposed mechanism.     

Freshwater bacterioplankton richness in oligotrophic lakes depends on nutrient availability rather than on species–area relationships

A central goal in ecology is to grasp the mechanisms that underlie and maintain biodiversity and patterns in its spatial distribution can provide clues about those mechanisms. Here, we investigated what might determine the bacterioplankton richness (BR) in lakes by means of 454 pyrosequencing of the 16S rRNA gene. We further provide a BR estimate based upon a sampling depth and accuracy, which, to our knowledge, are unsurpassed for freshwater bacterioplankton communities. Our examination of 22 669 sequences per lake showed that freshwater BR in fourteen nutrient-poor lakes was positively influenced by nutrient availability. Our study is, thus, consistent with the finding that the supply of available nutrients is a major driver of species richness; a pattern that may well be universally valid to the world of both micro- and macro-organisms. We, furthermore, observed that BR increased with elevated landscape position, most likely as a consequence of differences in nutrient availability. Finally, BR decreased with increasing lake and catchment area that is negative species–area relationships (SARs) were recorded; a finding that re-opens the debate about whether positive SARs can indeed be found in the microbial world and whether positive SARs can in fact be pronounced as one of the few ‘laws'' in ecology.     

The RyR–ClCa–VDCC axis contributes to spontaneous tone in urethral smooth muscle

Current therapies including pharmaceutical intervention and surgery have limited efficacy on stress urinary incontinence (SUI). One type of SUI is due to low intraurethral pressure caused by the disabled contraction of urethral smooth muscle (USM). However, the molecular mechanisms underlying the motility of USM remain unknown. Here, we show that USM represents spontaneous tone after stretching in humans and mice. Deletion of TMEM16A in the smooth muscle of mice abolishes spontaneous urethral tone. Furthermore, Cl_Ca currents and [Ca²⁺]_i in TMEM16A^SMKO mice were largely impaired. Inhibitors of ryanodine receptor (RyR), TMEM16A encoded calcium-activated chloride channel (Cl_Ca) and L-type voltage-dependent calcium channel (VDCC) fully prevented spontaneous tone accompanied by a significant decrease of intracellular calcium concentration ([Ca²⁺]_i). In summary, RyR–Cl_Ca–VDCC signaling contributes to spontaneous USM tone. This finding may provide a new promising approach for women with stress SUI who reject surgery.     

The effects of gastrocnemius–soleus muscle forces on ankle biomechanics during triple arthrodesis

This paper presents a finite element model of the ankle, taking into account the effects of muscle forces, determined by a musculoskeletal analysis, to investigate the contact stress distribution in the tibio-talar joint in patients with triple arthrodesis and in normal subjects. Forces of major ankle muscles were simulated and corresponded well with the trend of their EMG signals. These forces were applied to the finite element model to obtain stress distributions for patients with triple arthrodesis and normal subjects in three stages of the gait cycle, i.e. heel strike, midstance, and heel rise. The results demonstrated that the stress distribution patterns of the tibio-talar joint in patients with triple arthrodesis differ from those of normal subjects in investigated gait cycle stages. The mean and standard deviations for maximum stresses in the tibo-talar joint in the stance phase for patients and normal subjects were 9.398e7 ± 1.75e7 and 7.372e7 ± 4.43e6 Pa, respectively. The maximum von Mises stresses of the tibio-talar joint for all subjects in the stance phase found to be on the lateral side of the inferior surface of the joint. The results also indicate that, in patients with triple arthrodesis, increasing gastrocnemius–soleus muscle force reduces the stress on the medial malleolus compared with normal subjects. Most of stresses in this area are between 45 and 109 kPa, and will decrease to almost 32 kPa in patients after increasing of 40% in gastrocnemius–soleus muscle force.     

Mechanical principles of effects of botulinum toxin on muscle length–force characteristics: An assessment by finite element modeling

Recent experiments involving muscle force measurements over a range of muscle lengths show that effects of botulinum toxin (BTX) are complex e.g., force reduction varies as a function of muscle length. We hypothesized that altered conditions of sarcomeres within active parts of partially paralyzed muscle is responsible for this effect. Using finite element modeling, the aim was to test this hypothesis and to study principles of how partial activation as a consequence of BTX affects muscle mechanics. In order to model the paralyzing effect of BTX, only 50% of the fascicles (most proximal, or middle, or most distal) of the modeled muscle were activated. For all muscle lengths, a vast majority of sarcomeres of these BTX-cases were at higher lengths than identical sarcomeres of the BTX-free muscle. Due to such “longer sarcomere effect”, activated muscle parts show an enhanced potential of active force exertion (up to 14.5%). Therefore, a muscle force reduction originating exclusively from the paralyzed muscle fiber populations, is compromised by the changes of active sarcomeres leading to a smaller net force reduction. Moreover, such “compromise to force reduction” varies as a function of muscle length and is a key determinant of muscle length dependence of force reduction caused by BTX. Due to longer sarcomere effect, muscle optimum length tends to shift to a lower muscle length. Muscle fiber–extracellular matrix interactions occurring via their mutual connections along full peripheral fiber lengths (i.e., myofascial force transmission) are central to these effects. Our results may help improving our understanding of mechanisms of how the toxin secondarily affects the muscle mechanically.     

The stimulation of arginine transport by TNFα in human endothelial cells depends on NF-κB activation

In human saphenous vein endothelial cells (HSVECs), tumor necrosis factor-α (TNFα) and bacterial lipopolysaccharide (LPS), but neither interferon γ (IFNγ) nor interleukin 1β (IL-1β), stimulate arginine transport. The effects of TNFα and LPS are due solely to the enhancement of system y⁺ activity, whereas system y⁺L is substantially unaffected. TNFα  causes an increased expression of SLC7A2/CAT-2B gene while SLC7A1/CAT-1 expression is not altered by the cytokine. The suppression of PKC-dependent transduction pathways, obtained with the inhibitor chelerytrhine, the inhibitor peptide of PKCζ isoform, or chronic exposure to phorbol esters, does not prevent TNFα effect on arginine transport. Likewise, ERK, JNK, and p38 MAP kinases are not involved in the cytokine effect, since arginine transport stimulation is unaffected by their specific inhibitors. On the contrary, inhibitors of NF-κB pathway hinder the increase in CAT2B mRNA and the stimulation of arginine uptake. These results indicate that in human endothelial cells the activation of NF-κB pathway mediates the TNFα effects on arginine transport.     

Compression or tension? The stress distribution in the proximal femur

Background  

Questions regarding the distribution of stress in the proximal human femur have never been adequately resolved. Traditionally, by considering the femur in isolation, it has been believed that the effect of body weight on the projecting neck and head places the superior aspect of the neck in tension. A minority view has proposed that this region is in compression because of muscular forces pulling the femur into the pelvis. Little has been done to study stress distributions in the proximal femur. We hypothesise that under physiological loading the majority of the proximal femur is in compression and that the internal trabecular structure functions as an arch, transferring compressive stresses to the femoral shaft.