Effects of chitin and its soluble derivatives on survival of Vibrio cholerae O1 at low temperature.

Chitin concentrations greater than 0.04% (wt/wt) protected cholera vibrios against killing at low temperature. This protective effect was detected with both the soluble form of chitin, glycol chitin, and the insoluble particulate form of chitin. Some amino acids or peptides also showed the same protective effect.     

Regulation of redox states of plasma proteins by metabolism and transport of glutathione and related compounds

Glutathione is one of the most abundant naturally occurring thiols in living organisms and is synthesized in its reduced from (GSH). GSH has been known to play a fundamental role in cellular events in different cells and tissues, including protection of organisms against oxidative stress. The two peptide linkages of GSH are sequentially degraded by -glutamyltransferase and peptidases that hydrolyze the cysteinylglycine bond; all these enzymes are localized on the outer surface of cell membranes. The turnover of GSH in animals can be understood on the basis of the following three factors: (1) synthesis of GSH occurs exclusively intracellularly, while its degradation occurs predominantly extracellularly; (2) plasma membranes of many tissues and cells have secretory transport systems for GSH and its derivatives; (3) levels of the transferase, a key enzyme for GSH degradation, differ from one tissue to another. Thus, GSH released from tissues with low transferase activity (such as the liver) must be transferred for its rapid turnover to tissues with high enzyme activity (such as the kidney). Further studies on the states of thiol compounds transported via the circulation should be relevant to the understanding of the full scope and physiological significance of the interorgan cooperation of GSH metabolism. Many enzymes and proteins have free SH and disulfide groups within molecules. Function, stability, and in vivo fate of these macromolecules could be affected significantly by their redox state. Although cells and tissues have enzymic defense mechanisms against oxidative stress, the mechanism by which the homeostasis of the redox state of extracellular compartments (such as plasma, urine, bile, etc.) is maintained remains obscure. Plasma mercaptoalbumin (M-Alb) has 17 disulfide bonds and one free cysteinyl residue (Cys-34). This free thiol group can form mixed disulfides with low-molecular weight compounds, such as GSH and cysteine, to generate nonmercaptoalbumin (NM-Alb). Thus, when titrated by several different thiol reagents, less than 1 mole of free SH group (0.4–0.7) was usually detected per mole albumin. The ratio of M-Alb to NM-Alb in plasma samples varies significantly from one sample to another. Many plasma proteins in nonalbumin fractions also formed mixed disulfides with GSH and cysteine. The extent of mixed disulfide formation and the ratio of M-Alb to NM-Alb appeared to change markedly, depending on the redox state of the organisms. The present paper describes the mode of interorgan metabolism and transport of GSH and related compounds, the mechanism by which the redox state of albumin and other plasma proteins is controlled, and their biological significance in healthy and diseased conditions in normal and analbuminemic mutant rats.This article was presented during the proceedings of the International Conference on Macromolecular Structure and Function, held at the National Defence Medical College, Tokorozawa, Japan, December 1985.     

Identification and endothelin-induced activation of multiple extracellular signal-regulated kinases in aortic smooth muscle cells.

In order to explore intracellular signaling pathways of the mitogenic action of endothelin (ET), we examined the effect of ET on activities of extracellular signal-regulated kinases (ERKs) in rat aortic smooth muscle cells (SMCs). Treatment of rat aortic SMCs with ET-1 increased kinase activities toward myelin basic protein (MBP). Both 43- and 41-kDa proteins were activated when kinase assays were done in MBP-containing polyacrylamide gels after SDS-PAGE. These proteins were identified as ERK1 and ERK2 with immunoprecipitation and immunoblotting using antipeptide antibodies, respectively. These results indicate that ERKs mediate signal transduction by ET.     

Pore size and negative charge as structural determinants of permeability in the Torpedo nicotinic acetylcholine receptor channel.

To gain an insight into the molecular basis of ion permeation mechanism through the nicotinic acetylcholine receptor (AChR) channel, we have determined permeability ratios of organic cations relative to Na+ of specifically mutated Torpedo californica AChR channels expressed in Xenopus oocytes. The mutations involved mainly the side chains of the amino acid residues in the intermediate ring, where mutations have been found to exert strong effects on single-channel conductance and ion selectivity among alkali metal cations. The results obtained reveal that both the size and the net charge of the side chains of the intermediate ring are involved in determining the permeability, and provide experimental evidence that the pore size at the intermediate ring is a critical determinant of permeability. Our findings further suggest that changes in net charge exert effects on permeability by affecting the pore size of the channel.     

Mechanisms of a conversion from membrane associated lysosomal acid phosphatase to content forms

We reported that membrane-associated APase (M-APase) is anchored in the lipid bilayer through its hydrophobic sequence close to the COOH-terminus [Biochem. Biophys. Res. Commun. (1989) 162, 1044-1053] and is released from lysosomal membranes into the lysosomal contents by limited proteolysis with cathepsin D [J. Biochem. (1990) 108, 287-291]. We here report the conversion process of M-APase to three forms of the content enzyme (C-APase I, II, and III) by assigning the COOH-terminus of each APase in lysosomes. The purified M-APase (67 kDa) was subjected to COOH-terminal determination after digestion with cathepsin D. The COOH-terminus of cathepsin D-digested M-APase (65 kDa) ended at the position of the 382nd leucine residue. The COOH-termini of C-APase I (48 kDa) and III (64 kDa) were also determined. Since the two enzymes ended at the same position of the 373rd alanine residue, this COOH-terminal is 9 amino acid residues shorter than that of cathepsin D-digested M-APase. Then, we compared NH2-terminal sequences of the three enzymes, and found that those of three enzymes are exactly the same. Therefore, protein portions of C-APase I and III proved to be identical. The above results indicate that in lysosomes M-APase is first hydrolyzed between amino acid residues 382 and 383 by cathepsin D, and after solubilization, the enzyme is converted to C-APase III by losing 9 amino acid residues by lysosomal carboxypeptidase(s). Molecular weight differences among three C-APases (III, 64 kDa; II, 55 kDa; I, 48 kDa) probably are due to different degrees of carbohydrate chain degradations as reported previously [J. Biochem. (1989) 105, 449-456].     

Receptor binding affinity and biological activity of C-terminal elongated forms of endothelin-1

Endothelin-1 (21 amino acids; ET-21) is considered to be derived from a precursor, proendothelin (38 amino acids; ET-38). In order to make the physiological significance of this conversion clear, we synthesized various C-terminal elongated derivatives of ET-21, such as ET-22, ET-23, ET-25, ET-31, ET-36 and ET-38 (each number implies the number of amino acid residues), and measured their receptor binding affinities and biological activities. When inhibition of [¹²⁵I]ET-21 binding to cultured rat smooth muscle cells (A10 cells) was measured, ET-21 inhibited with the highest affinity (IC₅₀ = 1.6 × 10⁻¹⁰ M) and the affinity of ET-38 was 30-fold less than that of ET-21. The binding affinities of the C-terminal elongated peptides were reduced with increasing number of amino acid residues, except for ET-22 whose affinity was lower than those of other peptides (IC₅₀ = 1.6 × 10⁻⁸ M). When contractions of rat aortic segments induced by these peptides were measured, ET-21 was the most potent (EC₅₀ = 2.8 × 10⁻¹⁰ M). All C-terminal elongated peptides, including ET-38, were more than 100-fold less active. It is noteworthy that ET-22 was the least potent peptide (EC₅₀ = 1.2 × 10⁻⁷ M). When bolus doses of C-terminal elongated peptides were administered to chemically denervated rats, the time-dependent change in blood pressure induced by each peptide was different from that induced by ET-21. Although ET-21 elicited a three phase depressor/pressor blood pressure response (an initial rapid hypotension, then a rapid transient hypertension followed by a slowly developing long-lasting hypertensive effect), the C-terminal elongated peptides, including ET-38, did not cause the initial transient hypotensive response. Very interestingly, the ability of the peptides to induce the rapid phase of hypertension in vivo does not seem to be correlated with the affinity of each peptide for the smooth muscle cell receptor, since the peptides with lower affinities for the smooth muscle receptor, such as ET-22, ET-23 and ET-25, showed more potent hypertensive effects. On the other hand, the slow and long-lasting hypertensive effect is likely to be related to the affinity of the compounds. The maximal hypertensive effects of cumulatively administered ET-21 derivatives were similar to those of ET-21. These results suggest that ET-21 is the most potent vasoconstrictor among the peptides and that the conversion from ET-38 to ET-21 may be important as an activation process.     

Vibrio fluvialis andV. furnissii serotyping scheme for international use

A combination of two serotyping systems forVibrio fluvialis andV. furnissii, which were developed independently at the National Institute of Health (Tokyo) and Tokyo Metropolitan Research Laboratory of Public Health (Tokyo), was established as a single serotyping scheme comprising 35 O-antigen groups for international use.     

Micropropagation of ‘Yamatoimo’ Chinese yam (Dioscorea opposita) from immature leaves

A micropropagation system for Yamatoimo Chinese yam (Dioscorea opposita Thunb.) was developed. Immature leaves collected from virus-free plants growing in the greenhouse were cultured on MS medium supplemented with 8.9 M benzyladenine (BA), 3% (w/v) sucrose and 0.8% (w/v) agar. After 2–3 months, multiple buds that were clumps of green-colored bulbous structures including adventitious buds and meristematic regions 2–3 mm in diameter were formed on immature leaves. Transplanting clusters of multiple buds to fresh MS medium supplemented with 0.11 M -naphthaleneacetic acid (NAA), 0.89 M BA and 6% (w/v) sucrose was effective for inducing shoot formation, leading to plantlet formation. After 6 months, a large number of microtubers, about 3–7 mm diameter, were obtained.Abbreviations NAA -naphthaleneacetic acid - BA benzyladenine - MS Murashige and Skoog     

Involvement of the ribulosephosphate epimerase gene in the dnaA and dnaR functions for initiation of chromosome replication in Escherichia coli

Initiation of replication of the Escherichia coli chromosome is rendered temperature-sensitive by the dnaR130 mutation in the prs gene that encodes phosphoribosylpyrophosphate synthetase. The thermosensitivity of the dnaR mutant is suppressed by a spontaneous mutation in rpe , the gene encoding ribulosephosphate epimerase. Disruption of the rpe gene reverses the thermosensitive growth of the dnaR mutant. The rpe -disrupted dnaR mutant exhibits extensive DNA synthesis at low and high temperatures, as does the dnaR  ⁺ rpe disruptant and the dnaR  ⁺ rpe ⁺ strain. The thermoresistant DNA synthesis in the rpe dnaR double mutant is dnaA dependent, because the dnaA167 mutation renders the synthesis thermosensitive. The rpe -knockout mutation abolishes the ability of the dnaA115 allele to complement the defect of the dnaA167 mutant with or without the dnaR mutation and diminishes the dnaR -complementing ability of the dnaR224 allele. These results show that the rpe product is involved in the functions of the products of both dnaA and dnaR for initiation of replication of the bacterial chromosome.     

The use of heteronuclear cross-polarization for backbone assignment of 2H-, 15N- and 13C-labeled proteins: A pulse scheme for triple-resonance 4D correlation of sequential amide protons and 15N

Summary A new four-dimensional pulse scheme is described for the main-chain assignment of proteins by means of the J connectivity of the amide proton and nitrogen resonances of adjacent residues. Since the new experiment, 4D CP-HN(COCA)NH, involves heteronuclear cross-polarization for magnetization transfer from ¹³C=O to ¹⁵N via ¹³C, a relatively strong WALTZ-16 decoupling rf field is applied to ¹³C during magnetization transfer. Consequently, ¹³C is effectively decoupled from its attached ²H in the case of deuterated proteins, in the absence of a decoupling rf field for ²H. This efficiently improves the sensitivity of the experiment through ¹³C line narrowing. The experiment was performed on a randomly 60% deuterated protein, and the sensitivity of the final 4D spectrum was found to be excellent.