Load‐sensitive coupling of proton translocation and torque generation in the bacterial flagellar motor

The Salmonella flagellar motor consists of a rotor and about a dozen stator elements. Each stator element, consisting of MotA and MotB, acts as a proton channel to couple proton flow with torque generation. A highly conserved Asp33 residue of MotB is directly involved in the energy coupling mechanism, but it remains unknown how it carries out this function. Here, we show that the MotB(D33E) mutation dramatically alters motor performance in response to changes in external load. Rotation speeds of the MotA/B(D33E) and MotA(V35F)/B(D33E) motors were markedly slower than the wild‐type motor and fluctuated considerably at low load but not at high load, whereas the rotation rate of the wild‐type motor was stable at any load. At low load, pausing events were frequently observed in both mutant motors. The proton conductivities of these mutant stator channels in their ‘unplugged’ forms were only half of the conductivity of the wild‐type channel. These results suggest that the D33E mutation induces a load‐dependent inactivation of the MotA/B complex. We propose that the stator element is a load‐sensitive proton channel that efficiently couples proton translocation with torque generation and that Asp33 of MotB is critical for this co‐ordinated proton translocation.     

Effect of diabetes on aortic nitric oxide synthesis in spontaneously hypertensive rats; does captopril modulate this effect?

Nitric oxide (NO) is a potent regulator in the cardiovascular system; it is generated by the nitric oxide synthase (NOS) family of proteins. NO produced in endothelial cells plays a crucial role in vascular functions. The aim of this study was to clarify the effect of diabetes on aortic NO synthesis in a model of genetic hypertension and determine whether captopril modulates this effect. Diabetes was induced in ten weeks old spontaneously hypertensive rats (SHR) by streptozotocin injection. The rats were allocated into 3 groups: control group 1, non-diabetic SHR; group 2, diabetic SHR; group 3, diabetic SHR group receiving captopril at 80 mg/kg in drinking water for 4 weeks. Mean blood pressure (MBP) was measured once a week by tail-cuff method. Aortic NO metabolities (nitrite/nitrate) and endothelial NOS (NOS-3) were assayed by Griess reaction and by immunoblotting and immunohistochemistry, respectively. There was a significant decrease in nitrite/nitrate (NOx) in aortas of diabetic SHR compared with controls. The decrease of aortic NOx in diabetic SHR was accompanied by a decrease in NOS-3 expression. Captopril treatment reduced MBP without affecting either NOx level or NOS-3 expression in aortas of diabetic SHR. We conclude that STZ-induced diabetes decreased NO in aortas of SHR that may reflect endothelial cell dysfunction; captopril administration decreased MBP without affecting NO level in aortas of diabetic SHR which suggest that the blood pressure-lowering effects of captopril were independent of NO.     

A kinetic analysis of the electrogenic pump ofChara corallina: IV. Temperature dependence of the pump activity

Summary The sigmoidal current-voltage curve (i _p -V curve) of the electrogenic H⁺-pump of theChara membrane was simulated satisfactorily with a simple reaction kinetic model which assumed consecutive changes in state of H⁺-ATPase. Four rate constants, i.e., forward and backward ones in voltage-dependent and-independent steps could be evaluated from the data. The emf of the pump (E _p ), the voltage at which the pump current changes its sign, varies only slightly with temperature. However, the pump current (i _p ) is highly temperature dependent, and there-fore the conductance (g _p ) of the pump, calculated as the chord conductance from thei _p-V curve, is also highly voltage dependent having a peak at a level somewhat less negative than the resting potential. In contrast tog _p , the conductance (i _p ) of the passive channel does not change appreciably with temperature. Arrhenius plots ofg _p and also of the rate constants showed a clear bend at about 19°C. Great temperature dependence of the kinetic parameters offers useful information on the pumping mechanism of theChara membrane.     

Populational Heterogeneity vs. Temporal Fluctuation in Escherichia coli Flagellar Motor Switching

The dynamic switching of the bacterial flagellar motor regulates cell motility in bacterial chemotaxis. It has been reported under physiological conditions that the switching bias of the flagellar motor undergoes large temporal fluctuations, which reflects noise propagating in the chemotactic signaling network. On the other hand, nongenetic heterogeneity is also observed in flagellar motor switching, as a large group of switching motors show different switching bias and frequency under the same physiological condition. In this work, we present simultaneous measurement of groups of Escherichia coli flagellar motor switching and compare them to long time recording of single switching motors. Consistent with previous studies, we observed temporal fluctuations in switching bias in long time recording experiments. However, the variability in switching bias at the populational level showed much higher volatility than its temporal fluctuation. These results suggested stable individuality in E. coli motor switching. We speculate that uneven expression of key regulatory proteins with amplification by the ultrasensitive response of the motor can account for the observed populational heterogeneity and temporal fluctuations.     

Effect of Intracellular pH on the Torque-Speed Relationship of Bacterial Proton-Driven Flagellar Motor

Bacterial flagella responsible for motility are driven by rotary motors powered by the electrochemical potential difference of specific ions across the cytoplasmic membrane. The stator of proton-driven flagellar motor converts proton influx into mechanical work. However, the energy conversion mechanism remains unclear. Here, we show that the motor is sensitive to intracellular proton concentration for high-speed rotation at low load, which was considerably impaired by lowering intracellular pH, while zero-speed torque was not affected. The change in extracellular pH did not show any effect. These results suggest that a high intracellular proton concentration decreases the rate of proton translocation and therefore that of the mechanochemical reaction cycle of the motor but not the actual torque generation step within the cycle by the stator-rotor interactions.     

Ecological aspects of bamboo flowering ecological studies of bamboo forests in Japan,XIII

Since 1953, we have conduced continuous field studies on the bamboo (Phyllostachys bambusoides) stands of Chiba. A part of these stands began flowering in 1960. The emergence of season-insensitive, short slender bamboo (similar to dwarf bamboo) precedes the bamboo flowering. The regenerative process is short slender bamboo with small leaves as undergrowth foretelling flowering (R's)→ regenerated, short slender bamboo with small leaves (Rs)→a new-generation of short, slender bamboo with large leaves (Rl)→a new generation of short, slender bamboo with medium-sized leaves (Rm)→a tall, regular growth of bamboo (T). Some of the short slender bamboo flower (R_f), but some of them do not flower (R_nf). The productive structure develops from the grassy type to the herbacious type after flowering (Rs→T). Leaf characteristics and dry matter distribution are measured according to the regenerating stages. The most characteristic stage, Rl, appears to play an important role in bamboo regeneration because of its large amount of photosynthetic biomass and the high photosynthetic rates. Rm is a miniature version of normal tall bamboo.     

Inhibition of Brain Type A Monoamine Oxidase and 5-Hydroxytryptamine Uptake by Two Amphetamine Metabolites, p-Hydroxyamphetamine and p-Hydroxynorephedrine

Two amphetamine metabolites, p-hydroxyamphetamine (p-OHA) and p-hydroxynorephedrine (p-OHN), selectively inhibited the A form of monoamine oxidase (MAO) in rat and mouse forebrain homogenates. Of these two metabolites, p-OHA inhibited MAO-A more strongly than p-OHN. This MAO-A-selective inhibition by p-OHA or p-OHN was found to be competitive with respect to deamination of its substrate, 5-hydroxytryptamine (5-HT). The degree of MAO-A inhibition was not changed by 90 min of preincubation of the enzyme preparations with either metabolite, and the activity inhibited by p-OHA after the preincubation recovered completely to the control level after repeated washing. Uptake of 5-HT or dopamine into mouse forebrain synaptosomes was highly reduced by both p-OHA and p-OHN. Both metabolites were more potent in reducing dopamine uptake than in reducing 5-HT uptake. In reduction of 5-HT and of dopamine uptake, p-OHA was more potent than p-OHN. These results indicate that p-OHA is a more selective inhibitor of brain MAO-A activity and 5-HT uptake than its subsequent metabolite, p-OHN. These two actions of p-OHA might, together with possible 5-HT efflux into the synaptic cleft, greatly contribute to head twitch, a brain 5-HT-mediated animal behavior induced by p-OHA.     

Populational Heterogeneity vs. Temporal Fluctuation in Escherichia coli Flagellar Motor Switching

The dynamic switching of the bacterial flagellar motor regulates cell motility in bacterial chemotaxis. It has been reported under physiological conditions that the switching bias of the flagellar motor undergoes large temporal fluctuations, which reflects noise propagating in the chemotactic signaling network. On the other hand, nongenetic heterogeneity is also observed in flagellar motor switching, as a large group of switching motors show different switching bias and frequency under the same physiological condition. In this work, we present simultaneous measurement of groups of Escherichia coli flagellar motor switching and compare them to long time recording of single switching motors. Consistent with previous studies, we observed temporal fluctuations in switching bias in long time recording experiments. However, the variability in switching bias at the populational level showed much higher volatility than its temporal fluctuation. These results suggested stable individuality in E. coli motor switching. We speculate that uneven expression of key regulatory proteins with amplification by the ultrasensitive response of the motor can account for the observed populational heterogeneity and temporal fluctuations.     

Hyaluronan Inhibits Tlr-4-Dependent RANKL Expression in Human Rheumatoid Arthritis Synovial Fibroblasts

The Toll-like receptor (TLR) signaling pathway is activated in synovial fibroblast cells in patients with rheumatoid arthritis (RA). The receptor activator of nuclear factor-κB (RANK) and its ligand, RANKL, are key molecules involved in the differentiation of osteoclasts and joint destruction in RA. Hyaluronan (HA) is a major extracellular component and an important immune regulator. In this study, we show that lipopolysaccharide (LPS) stimulation significantly increases RANKL expression via a TLR-4 signaling pathway. We also demonstrate that HA suppresses LPS-induced RANKL expression, which is dependent on CD44, but not intercellular adhesion molecule-1 (ICAM-1). Our study provides evidence for HA-mediated suppression of TLR-4-dependent RANKL expression. This could present an alternative target for the treatment of destructed joint bones and cartilages in RA.