Identification and characterization of the epithelial polarity receptor "Frizzled" in Hydra vulgaris.

The Wnt signaling pathway plays an important role in the specification of cell patterning during development in many species. Here we report the isolation and characterization of a putative Wnt receptor, Frizzled, in Hydra vulgaris. Analysis of the amino acid sequence of Frizzled in hydra reveals that this receptor contains many strong sequence similarities to other known Frizzled receptors. Hydra divergence is estimated to have occurred about one billion years ago; thus comparison of the Frizzled sequence of hydra with that of other species is likely to provide important information on the structure and function of those highly conserved regions. Northern and Southern blotting reveal that the Frizzled receptor in hydra has a 2.34-kb message size, and that it is encoded by a single gene. In situ hybridization using hydra frizzled as a probe reveals that the receptor message is restricted to the endoderm in adult hydra. This distribution supports the hypothesis that the Frizzled receptor is functioning in a pathway that controls cell differentiation in hydra.

Nerve cell differentiation in nerve-free tissue of epithelial hydra from precursor cells introduced by grafting. I. Tentacles and hypostome.

The differentiation of hydra nerve cells in the nerve-free tissue of epithelial hydra was examined in Hydra magnipapillata. Nerve cell precursors, the interstitial cells, were introduced into the upper half of epithelial hydra by grafting it onto the lower half of normal hydra. In the tentacles of grafted epithelial hydra, a small number of RF+ ganglion cells first appeared in the proximal area at 1.5 days after grafting, followed by the appearance of NV1+ sensory cells in the same area about a day later. In the following days, both neuron types appeared more numerously in more distal positions. The front boundary for each type moved gradually from the base to the tip of the tentacles in about 7 days. In the hypostome, a small number of RF+ ganglion cells first appeared in the apex at 1.5 days. More nerve cells appeared in the following days, eventually forming a cluster of RF+ sensory cells at the apex surrounded by numerous RF+ ganglion cells in the adjacent tissue. These results show that nerve cells do not differentiate randomly in the epithelial hydra host. Instead, differentiation occurs in a strongly region-specific manner in the same way as in normal hydra, suggesting that epithelial cells in each region provide different cues or signals to produce region-specific nerve cell distribution in normal hydra tissue.

[Application of quantitative assay for endotoxin using immobilized histidine and filtration plate to parenteral drugs].

We improved the Limulus amebocyte lysate (LAL) test for endotoxins in parenteral drugs using immobilized histidine and a filtration plate. In order to deal with many samples at the same time and to apply to a routine assay, we used a filtration plate having 96 wells instead of a filter unit with a working volume of 2 ml. LAL test-affecting substances which are contained in a parenteral drug were separated from endotoxins by adsorbing endotoxins on immobilized histidine in the well of a filtration plate. Then the absorbed endotoxins were allowed to react with LAL reagent in the same well. We defined that this method had the higher precision than conventional methods and was not influenced by the concentrations of endotoxin and parenteral drugs. Hence we examined the recovery of endotoxin spiked to 23 kinds of parenteral drugs by this method, as a result, 100 +/- 25% of recovery was obtained from 17 kinds of them.

Use of immobilized histidine in assay for endotoxin in patients with liver disease.

The Limulus amebocyte lysate (LAL) test has the disadvantage of being influenced by various inhibitors and activators. We have developed a method for the LAL reaction that involves the specific adsorption and isolation of endotoxin using a membrane filter unit and immobilized histidine; in this present study we used the method to measure endotoxin in the plasma of patients with acute or chronic liver disease. The adsorbed endotoxins are separated from LAL-inhibitors or -activators by the membrane filter unit, and their activity is directly assayed with the LAL reagent in a filter cup without any inhibition or activation. The study population consisted of 23 subjects, 3 with fulminant hepatitis and 20 with cirrhosis (9 with esophageal varices and 11 without). All 3 (100%) of the samples of plasma from patients with fulminant hepatitis were positive for endotoxin, as were the samples of 7 (78%) of the 9 patients with cirrhosis and esophageal varices, and 2 (18%) of the 11 patients with cirrhosis but without such varices. The results suggested that this method appears to be useful for assaying the concentration of endotoxin in patients with fulminant hepatitis or cirrhosis of the liver.

[Specific assay for endotoxin using immobilized histidine. Application to serum sample].

The amount of endotoxin in the serum was measured by the new assay method of endotoxin using a filtercup, Limulus amebocyte lysate, and immobilized histidine which is a specific adsorbent for endotoxin. The maximum recovery of endotoxin in the rabbit serum was obtained using acetate buffer (pH 5.5, mu = 0.1) for the adsorption. Using this buffer, various kinds of endotoxin in water were adsorbed quantitatively on immobilized histidine, and the activity of the adsorbed endotoxin was well recovered. The value of the amount of endotoxin in the bovine serum measured by the new assay method, which includes heat treatment (70 degrees C, 10 min) after separation followed by washing, was closer to that calculated from pyrogenic activities in rabbits than that measured by the PCA-Toxicolor method.

Assay of endotoxin in human plasma using immobilized histidine, Limulus amoebocyte lysate and chromogenic substrate.

The Limulus amoebocyte lysate test for endotoxin is inhibited or enhanced by many substances. It is particularly difficult to determine endotoxin in plasma. In order to overcome this problem, we have modified the specific endotoxin assay method by using a membrane filter unit, a chromogenic Limulus amoebocyte lysate reagent, and immobilized histidine (which is a specific adsorbent for endotoxins). This immobilized histidine method consists of the endotoxin adsorption step on immobilized histidine, the separation step, in which Limulus amoebocyte lysate-interfering substances are removed, and the Limulus amoebocyte lysate test. Preheating of plasma samples (40-fold dilution with distilled water, at 100 degrees C for 7.5 min) was necessary, and it was necessary to dilute the sample more than 100-fold for the adsorption step. Under these conditions, the fraction of endotoxin recovered from plasma by the immobilized histidine method was almost 1. Moreover, by increasing the sample volume and extending the Limulus amoebocyte lysate reaction time, the sensitivity could be increased. By using the immobilized histidine method, 50-200 units/l of endotoxin in plasma samples can be accurately assayed. The method was used for the determination of plasma endotoxin in rabbits.

[Studies on angiotensin I converting enzyme (ACE): inhibitory effect of imidapril, a novel ACE inhibitor (II). Inhibition of various tissue ACEs ex vivo].

The antihypertensive mechanism of imidapril was investigated in relation to its inhibition of ACE activities in the serum, thoracic-abdominal aorta, lung, kidney, heart and brain from adult spontaneously hypertensive rats (SHRs). In comparison with normotensive rats (NTRs), the ACE activities in the aorta, heart, brain and lung were higher, while those in the serum and kidney were considerably lower. Imidapril (2 mg/kg) showed remarkable inhibitions within 6 hr in all tissues, except for the brain, after a single oral administration. Consecutive administration of imidapril (2 mg/kg/day) for 30 days produced inhibitions in all tissues. The inhibitions in the serum, aorta and lung were greater, and the duration of inhibition in the aorta, brain and lung were longer. Blood pressure declined gradually until 6 hr, and the reductions were significant at 24 hr after the single and chronic administrations. Imidapril (0.5 mg/kg, ineffective on normal blood pressure) inhibited ACE activities in NTRs similarly. Enalapril at the same dose exhibited less ACE inhibition and antihypertension. These results suggest that the ACE inhibition in the serum, lung and aorta by imidapril correlate with the antihypertension in SHRs; especially, the lung and vascular ACE inhibitions play an important role in the duration of antihypertension in SHRs.

Nerve ring of the hypostome in hydra. I. Its structure, development, and maintenance.

The anatomy and developmental dynamics of the nerve ring in the hypostome of Hydra oligactis were examined immunocytochemically with an antiserum against a neuropeptide and with neuron-specific monoclonal antibodies. The nerve ring is unique in the mesh-like nerve net of hydra. It is a distinct neuronal complex consisting of a thick nerve bundle running circumferentially at the border between the hypostome and tentacle zone. Immunostaining showed that the nerve ring was heterogeneous and contained at least four different subsets of neurons. During head regeneration and budding, the nerve ring appeared only after the nerve net of ganglion and sensory cells had formed. Every epithelial cell is continuously displaced with neurons toward either head or foot in an adult hydra. However, the ectoderm in the immediate vicinity of, and including, the nerve ring constitutes a stationary zone that is not displaced. Tissue immediately above this zone is displaced toward the tip of the hypostome, while tissue below is displaced along the tentacles. Correspondingly, the production of new neurons in the ring as measured by their differentiation kinetics is much slower than in surrounding areas. Thus, the nerve ring is static and stable in contrast to the dynamic features of the nerve net of hydra.

[Studies on angiotensin I converting enzyme (ACE) inhibitory effect of imidapril. (I). Inhibition of various tissue ACEs in vitro].

Imidapril is a newly synthesized non-sulfhydryl-containing angiotensin I converting enzyme (ACE) inhibitor. The present study describes the inhibitory effects of imidapril and its active metabolite 6366A on ACEs from various tissues and compares its effects to those of captopril, enalapril and enalaprilat in vitro. 6366A inhibited swine renal and human serum ACEs with an inhibition constant (Ki) of 0.067 nM and 0.04 nM, respectively. These values were 3 to 18 times more potent than those of the other inhibitors. The kinetic study showed that 6366A exerted competitive type inhibition. The ACE inhibition (IC50 values) of 6366A, enalaprilat and the structurally related compounds (6366DM and 6366PY) were compared in homogenates of lung, aorta, heart, brain and kidney from spontaneously hypertensive rats (SHRs) and Wistar Kyoto rats (WKYs). The inhibitory effects of 6366A on all tissue ACEs from SHRs and WKYs were the most potent among these compounds. And the inhibitory potencies of these compounds were correlated with their chemical structure. The present results suggest that 6366A may show a strong inhibitory effect on ACEs from several tissues and species due to its chemical characteristics.

Specific assay for endotoxin using immobilized histidine, Limulus amoebocyte lysate and a chromogenic substrate.

The Limulus amoebocyte lysate (LAL) test is inhibited or enhanced by many substances. In order to overcome this problem, a specific endotoxin assay method using a membrane filter unit, a chromogenic LAL reagent, and immobilized histidine (which is a specific adsorbent for endotoxins) was developed. Endotoxins are quantitatively adsorbed on immobilized histidine. The adsorbed endotoxins are separated from LAL-inhibiting or -enhancing substances by the membrane filter unit, and their activities are directly assayed with the LAL reagent in a filter cup without any inhibition or enhancement. The reproducibility and the accuracy of this method are high. This new endotoxin assay method using immobilized histidine can be used for the determination of endotoxins in a solution containing LAL-inhibiting or -enhancing substances such as amino acids and antibiotics, as an alternative to the more common gel-clot technique.

Specific assay for endotoxin using immobilized histidine and Limulus amebocyte lysate.

The LAL test is inhibited or enhanced by many substances. To overcome these problems, we have developed a specific endotoxin assay method using an ultrafiltration unit, a fluorometric LAL reagent, and immobilized histidine (which is a specific adsorbent for endotoxins). This method is composed of two steps. The first step is the adsorption of endotoxins. Using immobilized histidine, endotoxins are quantitatively adsorbed on the adsorbent, and the adsorbed endotoxins are separated from LAL-inhibiting or -enhancing substances by the ultrafiltration unit. The second step is the reaction of adsorbed endotoxins with the LAL reagent. The endotoxins adsorbed on immobilized histidine are directly reacted with the LAL reagent in a filter cup and show enough activity for assay. The reproducibility and the accuracy of this method are high, and the recovery of endotoxins from a sample solution is more than 95%. The new endotoxin assay method using immobilized histidine can be utilized for the determination of endotoxins in a solution containing LAL-inhibiting or -enhancing substances such as amino acids and antibiotics instead of requiring employment of the more common gel-clot technique.

Specific removal of endotoxin from protein solutions by immobilized histidine.

A method for reducing endotoxin contamination in various solutions by immobilized histidine is described. Immobilized histidine is a porous adsorbent suitable for the adsorption of endotoxin with a high affinity over a wide range of pH and temperature and at low ionic strength (gamma/2 less than or equal to 0.1). When a purified endotoxin originating from Escherichia coli UKT-B was studied, the apparent dissociation constant between endotoxin and the adsorbent was 7.3 X 10(-13) M. The adsorbent was able to remove various kinds of endotoxin originating from gram-negative bacteria; the concentration of endotoxin was reduced from 1000 to less than 0.01 ng/ml in water. It is shown that the adsorbent specifically adsorbs endotoxin provided that the adsorption conditions are properly selected. Some examples of the specific removal of endotoxin from high-molecular-weight physiologically active substances such as tumor necrosis factor and lysozyme are shown.

Characteristics and applications of adsorbents for pyrogen removal.

Characteristics and applications of immobilized histidine and immobilized histamine for pyrogen removal were investigated. Immobilized histidine showed a high affinity for pyrogen at low ionic strength and over a wide pH range. The adsorption capacity was 0.53 mg of lipopolysaccharide per milliliter of the adsorbent. The apparent dissociation constant was 1.57 X 10(-9) M. The adsorption of pyrogen to immobilized histidine decreased with increasing ionic strength, but pyrogen could be adsorbed even at ionic strengths of gamma/2 = 0.05-0.1, at which other substances were little adsorbed; that is, specific adsorption of pyrogen was observed. The adsorption of pyrogen could be increased at ionic strengths of gamma/2 = 0.05-0.1 by using a lower flow rate or a longer column length. Immobilized histidine and immobilized histamine could be used for the removal of natural pyrogens contaminating various useful low-molecular-weight compounds as well as high-molecular-weight compounds such as proteins.

Characteristics of immobilized histamine for pyrogen adsorption.

The characteristics of immobilized histamine for pyrogen adsorption were investigated. The adsorbent showed a high affinity for pyrogen at low ionic strength, at around neutral pH, at high temperature and at low flow-rates of a solution containing pyrogen. The adsorption capacity per millilitre of the adsorbent was 0.9 mg pyrogen. Immobilized histamine could be completely regenerated by washing with 0.2 M sodium hydroxide solution containing 10--30% ethanol followed by 1.5 M sodium chloride solution, or 0.2 M sodium hydroxide solution followed by 0.5% sodium deoxycholate solution, 0.2 M sodium hydroxide solution and 1.5 M sodium chloride solution.

Structure of a major oligosaccharide of Taka-amylase A.

The structures of a major oligosaccharide of Taka-amylase A, shown below, is proposed based on the results of chemical (methylation and acetolysis) and enzymatic (digestions with exo and endo-glycosidases) analyses. This structure is an amendment of that proposed by Yamaguchi et al. (1971) (J. Biochem. 70, 587-594), in which one more mannose residue is attached (Formula: see text) through an alpha 1,2 linkage to the mannose residue which is alpha 1,3-linked to the intermost mannose residue.