Effect of the powerful plasticity of the tert-butyl side chain on the conformational equilibrium of ascidiacyclamides.

Ascidiacyclamide [cyclo(-Ile1,5 -oxazoline2,6 -d-Val3,7 -thiazole4,8 -)2 ] is a cytotoxic cyclic peptide from ascidian. Through structural analyses using monosubstituted analogues (Xaa1 : Ala, 2-aminobutyric acid, Val, cyclohexylglycine, and phenylglycine), we previously demonstrated the conformational equilibrium between its square and folded forms. As the bulkiness of the Xaa1 residue side chain was reduced, spontaneous folding was promoted, and the cytotoxicity decreased accordingly. In the present study, five disubstituted analogues in which a tert-leucine residue (Tle) was incorporated at the 5-position of the abovementioned monosubstituted analogues were synthesized, after which their structures were analyzed using X-ray diffraction, circular dichroism (CD) spectral measurements, and 1 H NMR-based quantitative analysis. The side chains of the Tle and Ile residues are structural isomers of one another, and the Tle residue bearing the tert-butyl group can be expected to play a role as a building block. In fact, peptides incorporating Tle5 exhibited much less spontaneous folding than their Ile5 counterparts in both crystal and solution. Increases in enthalpy and entropy due to the tert-butyl group during the folding process resulted in increased conformational free energy (ΔG°). The powerful plasticity of the tert-butyl group would stabilize the square form relating with cytotoxicity.

Reduction Effect of Calcium Alginate on Blood Triglyceride Levels Causing the Inhibition of Hepatic and Total Body Accumulation of Fat in Rats.

In this study, rats were fed a high-fat diet containing calcium alginate (Ca-Alg) for 5 weeks to examine the effects of Ca-Alg on lipid metabolism including triglyceride (TG) levels in the blood. We also investigated the mechanism of the TG-reducing effect of Alg in vitro. Rats were randomized into 5 groups: high-fat diet group (14% (w/w) lard, HF); three Ca-Alg-containing diet groups (2.5, 5 or 10% (w/w) Ca-Alg) and a resistant maltodextrin (RMD) diet group as a positive control (with 5% (w/w) RMD). The 10% Ca-Alg group showed a significant reduction of body weight increase from the 7th day. In addition, the increase of TG in blood was significantly suppressed, and the amount of TG excreted in feces was increased. Increase of body fat mass was in the order HF > RMD > Ca-Alg 2.5% > Ca-Alg 5% > Ca-Alg 10%, while the total weight of the extracted fat tissues was significantly reduced in the RMD, 5% and 10% Ca-Alg groups. Hepatic pathology showed clear circular vacuoles apparently representing TG accumulation in the HF group, while fewer vacuoles were seen in the Ca-Alg groups. The results of in vitro experiments indicated that Ca-Alg does not directly inhibit lipase activity, but may suppress absorption of TG by forming non-absorbable macromolecular micelles containing TG. These results suggest that Ca-Alg promotes excretion and suppresses absorption of TG, leading to reduced blood TG levels, and decreased hepatic and total body accumulation of fat. The findings should be helpful for designing future clinical trials.

Relationship between Physical Parameters of Various Metal Ions and Binding Affinity for Alginate.

We investigated the relationship between the physical parameters of various metal ions, including toxic metal ions, and the binding affinity of these metal ions for alginate (Alg). The binding constant, K, of Sr2+ was the highest among all tested metal ions. The order of K values was: Sr2+>Pb2+>Tb3+>Dy3+>Ca2+>Cd2+>Mg2+>Fe2+>Fe3+>Co2+>Al3+>Ni2+>Cs+>Cu2+>Ag+>Li+>K+. The metal ions showing the highest K values had ionic radii within the range of about 90-120 pm. Moreover, the K values of divalent or trivalent metal ions tended to be higher than those of monovalent ions. The number of binding sites per 1 mg of Alg (n) was highest for K+, followed by Pb2+ and Cs+. The order of affinity (calculated as the product of n and K) was Pb2+>Dy3+>Tb3+>Sr2+>Ca2+>Mg2+>Cd2+>Fe2+, Fe3+>Cs+>Al3+>Co2+>Ni2+>Cu2+>Ag+>K+>Li+. Our results support the idea that Alg would be effective as an excretion accelerator and/or absorption inhibitor for various toxic metal ions.

Cholesterol-Lowering Effect of Calcium Alginate in Rats.

We examined whether calcium alginate (Ca-Alg) reduces blood cholesterol levels in rats fed a high-cholesterol diet. First, we examined taurocholate adsorption in vitro by various types of sodium alginate (Na-Alg). High molecular-weight, guluronic acid-rich Na-Alg showed the greatest adsorption of taurocholate, and therefore the corresponding Ca-Alg was chosen for the in vivo study. Rats were fed a high-cholesterol diet or a Ca-Alg-containing diet for 2 weeks. Body weight and diet intake were measured, and the general condition of the animals was monitored during this period. After 14 d, the plasma concentration of cholesterol, portal plasma concentration of bile acid, and bile acid in feces were measured. The plasma concentration of cholesterol was significantly reduced in rats fed a 2% Ca-Alg-containing diet. Furthermore, the portal concentration of bile acid was significantly lowered in the 2% Ca-Alg group. A tendency for a Ca-Alg concentration-dependent increase in fecal excretion of bile acid was also seen, although it was not statistically significant. While several changes in biochemical parameters and histopathological findings were observed, all the values remained within the physiological range. These results indicate that Ca-Alg is effective in reducing plasma cholesterol. A possible mechanism would be enhanced fecal excretion of bile acid due to reduced intestinal reabsorption, which in turn might stimulate bile acid synthesis from cholesterol in the liver, leading to a decrease in plasma cholesterol.

Alginate enhances excretion and reduces absorption of strontium and cesium in rats.

Alginate (ALA), which is an intercellular polysaccharide associated with brown algae, is used as a food additive, a health food and a medicine. Here, we first examined the adsorption of strontium (Sr) and cesium (Cs) by ALA in vitro, and then evaluated the effects of ALA on absorption and excretion of Sr and Cs in rats, in order to evaluate its potential usefulness for minimizing radiation damage from materials released after a nuclear accident. Both Sr and Cs were concentration-dependently adsorbed by sodium alginate (ALA-Na) in vitro. In rats given diet containing either ALA-Na or calcium alginate (ALA-Ca) for two weeks, the plasma concentration of Sr gradually decreased compared with the controls (normal diet); however, in the case of Cs, the plasma concentration was decreased only in the ALA-Ca group, but not the ALA-Na group. Moreover, we examined the effect of preadministration of diet containing either ALA-Na or ALA-Ca on absorption of Sr and Cs administered orally as the chloride salts to rats. Absorption of both Sr and Cs was reduced in the ALA-Ca group, while absorption of only Sr was reduced in the ALA-Na group. Safety assessments indicated that ALA-Ca is safer than ALA-Na. These results indicate that ALA-Ca reduces absorption and promotes excretion of both Sr and Cs, while ALA-Na does so only for Sr.

Comparison of the activities of various alginates to induce TNF-alpha secretion in RAW264.7 cells.

We compared the abilities of alginate polymers having different molecular sizes and compositions to induce the secretion of tumor necrosis factor (TNF)-alpha in RAW264.7 cells. The molecular sizes and alpha-L-guluronate/beta-D-mannuronate (M/G) ratios of highly purified alginate polymers used in this study were 9000-38 000 and 1.50-3.17, respectively. Among the alginates tested, I-S, which had the highest molecular weight, showed the most potent TNF-alpha-inducing activity. The M/G ratio also seemed to influence this activity, and, among alginates with similar molecular sizes, alginates with a higher M/G ratio tended to show higher activity. Interestingly, the enzymatic depolymerization of I-S with bacterial alginate lyase resulted in a dramatic increase in the TNF-alpha-inducing activity. Such an effect of enzymatic digestion was also observed in a relatively low-molecular-weight alginate (ULV-3), which originally had very low TNF-alpha-inducing activity. Furthermore, the inhibition profiles of the TNF-alpha-inducing activity of enzymatically digested I-S shown by three specific mitogen-activated protein (MAP) kinase inhibitors differed from those of intact I-S. These results suggest that the underlying mechanism of the TNF-alpha-inducing activity of enzymatically depolymerized alginate oligomers is not necessarily the same as that of original alginate polymer.