Pigments associated with the flagellum ofEuglena gracilis

The pigments associated with the flagellum of the phytoflagellateEuglena gracllis were characterized by HPLC. The pigment pattern of the wild-type strain was compared with a set of white mutants which did not display phototaxis and photoaccumulation in response to blue light. Flagella of the wild type contained FMN and FAD. Two mutants which lacked the stigma but retained a small paraxonemal body (PAB) contained less flavins. The whiteEuglena mutant FB, which retained a residual stigma and also a PAB, and the white phytoflagellateAstasia longa, a close relative ofEuglena, had normal amounts of flagellar flavins. Cells and flagella ofEuglena wild type contained an unldentified pterin-like pigment, called Pt₁₆, which was substantially reduced inAstasia and theEuglena mutants. A third pigment, designated P₅₂₈ with major absorption at 528 nm and fluorescence emission at 550 nm was present mainly in flagella. The association of the three pigment types with flagella and their respective alterations in the white strains indicates their possible role in photoreception. Dedicated to Pill-Soon Song on the occasion of his 60th birthday.     

Male pheromones and their reception by females are co-adapted to affect mating success in two subspecies of brown rats

Pheromonal communication plays a key role in the sociosexual behavior of rodents. The coadaptation between pheromones and chemosensory systems has been well illustrated in insects but poorly investigated in rodents and other mammals. We aimed to investigate whether coadaptation between male pheromones and female reception might have occurred in brown rats Rattus norvegicus. We recently reported that major urinary protein (MUP) pheromones are associated with male mating success in a brown rat subspecies, R. n. humiliatus (Rnh). Here, we discovered that MUPs were less polymorphic and occurred at much lower concentrations in males of a parapatric subspecies, R. n. caraco (Rnc), than in Rnh males, and found no association between pheromones and paternity success. Moreover, the observation of Rnc males that experienced chronic dyadic encounters and established dominance–submission relationships revealed that the dominant males achieved greater mating success than the subordinate males, but their MUP levels did not differ by social status. These findings suggest that male mating success in Rnc rats is related to social rank rather than to pheromone levels and that low concentration of MUPs might not be a reliable signal for mate choice in Rnc rats, which is different from the findings obtained in Rnh rats. In addition, compared with Rnh females, Rnc females exhibited reduced expression of pheromone receptor genes, and a lower number of vomeronasal receptor neurons were activated by MUP pheromones, which imply that the female chemosensory reception of pheromones might be structurally and functionally coadapted with male pheromone signals in brown rats.     

The reflex mechanism underlying the neuromuscular effects of whole-body vibration: Is it the tonic vibration reflex?

Objectives:Whole-body vibration (WBV) is applied to the sole of the foot, whereas local mechanical vibration (LMV) is applied directly to the muscle or tendon. The time required for the mechanical stimulus to reach the muscle belly is longer for WBV. Therefore, the WBV-induced muscular reflex (WBV-IMR) latency may be longer than the tonic vibration reflex (TVR) latency. The aim of this study was to determine whether the difference between WBV-IMR and TVR latencies is due to the distance between the vibration application point and the target muscle.Methods:Eight volunteers participated in this study. The soleus reflex response was recorded during WBV, LMVs, and tendon tap. LMVs were applied to the Achilles tendon and sole of the foot. The latencies were calculated using the cumulative averaging technique.Results:The latency (33.4±2.8 ms) of the soleus reflex induced by the local foot vibration was similar to the soleus TVR latency (30.9±3.2 ms) and T-reflex (32.0±2.4 ms) but significantly shorter than the latency of the soleus WBV-IMR (42.3±3.4 ms) (F_(3,21)=27.46, p=0.0001, partial η²=0.797).Conclusions:The present study points out that the neuronal circuitries of TVR and WBV-IMR are different.     

The control of body size in insects

Control mechanisms that regulate body size and tissue size have been sought at both the cellular and organismal level. Cell-level studies have revealed much about the control of cell growth and cell division, and how these processes are regulated by nutrition. Insulin signaling is the key mediator between nutrition and the growth of internal organs, such as imaginal disks, and is required for the normal proportional growth of the body and its various parts. The insulin-related peptides of insects do not appear to control growth by themselves, but act in conjunction with other hormones and signaling molecules, such as ecdysone and IDGFs. Size regulation cannot be understood solely on the basis of the mechanisms that control cell size and cell number. Size regulation requires mechanisms that gather information on a scale appropriate to the tissue or organ being regulated. A new model mechanism, using autocrine signaling, is outlined by which tissue and organ size regulation can be achieved. Body size regulation likewise requires a mechanism that integrates information at an appropriate scale. In insects, this mechanism operates by controlling the secretion of ecdysone, which is the signal that terminates the growth phase of development. The mechanisms for size assessment and the pathways by which they trigger ecdysone secretion are diverse and can be complex. The ways in which these higher-level regulatory mechanisms interact with cell- and molecular- level mechanisms are beginning to be elucidated.     

Role of stretch-activated channels on the stretch-induced changes of rat atrial myocytes

The role of stretch-activated channels (SACs) on the stretch-induced changes of rat atrial myocytes was studied using a computer model that incorporated various ion channels and transporters including SACs. A relationship between the extent of the stretch and the activation of SACs was formulated in the model based on experimental findings to reproduce changes in electrical activity and Ca²⁺ transients by stretch. Action potentials (APs) were significantly changed by the activation of SACs in the model simulation. The duration of the APs decreased at the initial fast phase and increased at the late slow phase of repolarisation. The resting membrane potential was depolarised from −82 to −70 mV. The Ca²⁺ transients were also affected. A prolonged activation of SACs in the model gradually increased the amplitude of the Ca²⁺ transients. The removal of Ca²⁺ permeability through SACs, however, had little effect on the stretch-induced changes in electrical activity and Ca²⁺ transients in the control condition. In contrast, the removal of the Na⁺ permeability nearly abolished these stretch-induced changes. Plotting the peaks of the Ca²⁺ transients during the activation of the SACs along a time axis revealed that they follow the time course of the Na_i⁺ concentration. The Ca²⁺ transients were not changed when the Na_i⁺ concentration was fixed to a control value (5.4 mM). These results predicted by the model suggest that the influx of Na⁺ rather than Ca²⁺ through SACs is more crucial to the generation of stretch-induced changes in the electrical activity and associated Ca²⁺ transients of rat atrial myocytes.     

About the formation of an image in the inverted retina of the eye

Possible distortions of images of an object by the layer of nerve cells have been analyzed. It has been shown that, based on microoscillations of the visual apparatus, it is possible to propose the procedures of processing the arising diffraction scattering spectra and isolating from these spectra initial images that do not contradict the available morphological and neurophysiological data.     

Variation of Hexose 1-P Uridylyltransferase and UDP-Gal Pyrophosphorylase in Bifidobacterium bifidum Culture

Taste is indispensable for vertebrate to find a proper way of living by selection of foods at their discretion. It is also a mainstay in the construction of human culture and the food industry, but no systematic information is available regarding the molecular logic of taste signaling and associated chemical entities. Against this backdrop, our research had bumble beginnings in the 1990s and then traced a unique path of development revealing major signaling pathways involving G protein-coupled receptors, Gαi2, PLC-β2, IP₃R3, PLA2IIa, TRPM5, KCNQ1, etc. The validity of our studies on the molecular biology of taste was verified by material science in the case of an enigmatic protein, neoculin, which converts sourness to sweetness. The study should provide new information for better understanding of taste-taste interactions which are important in food design.     

Mechanosensitive potassium channels in locust muscle membrane

Patch clamp recordings have been made from adult locust (Schistocerca gregaria) muscle membrane to study the mechanosensitivity of potassium channels (BK and IK) in cell-attached patches by transiently applying measured pressures to the contents of the patch pipettes. The aim of the investigations was to demonstrate a novel gating behaviour by pressure of the BK channel in contrast to the familiar behaviour of the IK channel. The open probability (p ₀) of the IK channel increased rapidly in response to a pressure step and monotonically during a pressure ramp. This gating was readily repeatable and rapidly reversible. The relationship between ln[p ₀/(1–p ₀)] and transmembrane pressure was linear. In comparison, p ₀ for the BK channel was also increased by pressure, but its gating was delayed, cumulative, and hysteretic. Received: 12 July 1998 / Revised version: 7 October 1998 / Accepted: 7 October 1998     

Flow sensing by pinniped whiskers

Beside their haptic function, vibrissae of harbour seals (Phocidae) and California sea lions (Otariidae) both represent highly sensitive hydrodynamic receptor systems, although their vibrissal hair shafts differ considerably in structure. To quantify the sensory performance of both hair types, isolated single whiskers were used to measure vortex shedding frequencies produced in the wake of a cylinder immersed in a rotational flow tank. These measurements revealed that both whisker types were able to detect the vortex shedding frequency but differed considerably with respect to the signal-to-noise ratio (SNR). While the signal detected by sea lion whiskers was substantially corrupted by noise, harbour seal whiskers showed a higher SNR with largely reduced noise. However, further analysis revealed that in sea lion whiskers, each noise signal contained a dominant frequency suggested to function as a characteristic carrier signal. While in harbour seal whiskers the unique surface structure explains its high sensitivity, this more or less steady fundamental frequency might represent the mechanism underlying hydrodynamic reception in the fast swimming sea lion by being modulated in response to hydrodynamic stimuli impinging on the hair.