Comparative biochemistry and physiology. C, Comparative pharmacology and toxicology最新文献

1. In all neurones freshly isolated from various brain regions of newborn, adult and aged rats, the T-type Ca2+ currents were elicited by step depolarizations to potentials more positive than -60 mV from a holding potential of -100 mV, and reached a peak in the current-voltage relationship around -30 mV. 2. The activation and inactivation processes were highly potential-dependent, and the latter was fitted by a single exponential function. 3. It was concluded that mammalian brain neurones possess a definite class of T-type Ca2+ channel characterized by both current kinetics and ion selectivity for Ca2+, Ba2+ and Sr2+. However, the pharmacological nature of the T-type Ca2+ channel differed from that in other tissues such as cardiac and smooth muscle cells, peripheral neurones, and cultured cells.

1. Catecholaminergic cells were grafted in the caudate nucleus of hemi-Parkinsonian model rats, and the following problems were discussed. 2. Phenotypic plasticity and development of catecholamine-producing cells. 3. Mechanism of motor recovery. 4. Trophic factor. 5. Regulation of immunological responses. 6. Long-term survival and security.

1. The anterior byssus retractor muscle (ABRM) of Mytilus edulis is innervated by at least two kinds of nerves, excitatory and relaxing nerves. The principal neurotransmitters released from these nerves have been shown to be acetylcholine and serotonin, respectively. 2. Some other monoamines, such as dopamine and octopamine, and various peptides, such as FMRFamide-related peptides, Mytilus inhibitory peptides, SCP-related peptides and a catch-relaxing peptide, may also be involved in the regulation of the muscle as neurotransmitters or neuromodulators. 3. The ABRM seems to be typical of invertebrate muscles controlled by multiple neurotransmitters and neuromodulators.

1. In situ hybridization histochemistry permits the study of specific mRNAs of neuropeptides, enzymes involved in the synthesis of neurotransmitters, receptors and proteins associated with glial cells in nervous tissue. 2. The central and peripheral nervous systems are composed of heterogeneous elements and specific regulatory mechanisms occur in specific cells. 3. This review will focus on the localization and regulation of different mRNAs in the nervous system from Drosophila to human, as revealed by in situ hybridization histochemistry.

We believed that GTP-binding protein (G-protein)-coupling receptor always transduces stimulatory signals to G-proteins. From our recent experiments using reconstitution techniques, however, it was revealed that some receptors transduce an inhibitory or no signal to G-proteins in specific tissues, despite some interaction between them. Here we discuss the molecular basis of mechanisms of such diverse modes of functional coupling between different subtypes of opioid receptors and G-proteins.

This article presents a brief review on the electrophysiological analysis of the structural aspects of the voltage-dependent SR (sarcoplasmic reticulum) K+ channel. In the first half, early attempts to determine the physical dimensions of the ion conducting mechanism such as the mouth, narrow tunnel, or ion selective filter of the channel, are reviewed. The depicted cartoon of the SR K+ channel, as an extremely short, busy district with a big mouth on each side, is quite similar to the recently-obtained reconstructed structural image of the acetylcholine receptor channel. In the latter half, we introduce our recent attempts to draw a physical image of the gating mechanism of the SR K+ channel. We examined, for example, the location of the gate and the voltage sensor, and the relationship between them. It is suggested that the gate and the sensor are connected tightly and that the sensor would be exposed to the surface of the lumen side of SR when the gate opens. Finally, the issue of substates in SR K+ channel is discussed. It is implied that the substrate-conductances reflect a partial occlusion of the pore by an intermediate-open gate.

The progress of the neurophysiological research in Japan during the past 45 years is related. Modern Japanese neurophysiology started immediately after the end of World War 2. The introduction of microelectrode techniques contributed greatly to most fields of Japanese neurophysiology. These techniques were used to study most neurophysiological phenomena: sensory physiology including vision, audition, chemical sensitivity, and other modalities; learning and memory. These techniques plus lesions, transplants, and behavioral physiology were used to study circadian rhythm, posture and motor control, and sex. These and other techniques were used to study neural plasticity, immunity, membrane excitability, pain and other psychophysiological functions. The disciplines advanced quickly into multidiscipline approaches into not only electrophysiological, but biophysical, biochemical and immunological research fields. From the past research results our neurophysiologists can be expected to advance rapidly toward further development in the future of Japanese neurophysiology.

The chemical features, pharmacological and biochemical characteristics of novel mammalian tachykinin peptides, neurokinin A and neurokinin B are described and are compared with those of substance P, a representative of tachykinin family.